
Article 1 
This Regulation lays down measures for the implementation of Regulation (EC) No 715/2007.
Article 2 
For the purposes of this Regulation, the following definitions shall apply:

((1)) ‘vehicle type with regard to emissions and vehicle repair and maintenance information’ means a group of vehicles which:

((a)) do not differ with respect to the criteria constituting an "interpolation family" as defined in point 5.6 of Annex XXI;
((b)) fall in a single "CO2 interpolation range" as defined in point 1.2.3.2 of sub-Annex 6 to Annex XXI;
((c)) do not differ with respect to any characteristics that have a non-negligible influence on tailpipe emissions, such as, but not limited to, the following:

— types and sequence of pollution control devices (e.g. three-way catalyst, oxidation catalyst, lean NOx trap, SCR, lean NOx catalyst, particulate trap or combinations thereof in a single unit);
— exhaust gas recirculation (with or without, internal/external, cooled/non-cooled, low/high pressure).
((2)) ‘EC type-approval of a vehicle with regard to emissions and vehicle repair and maintenance information’ means an EC type-approval of the vehicles contained in a ‘vehicle type with regard to emissions and vehicle repair and maintenance information’ with regard to their tailpipe emissions, crankcase emissions, evaporative emissions, fuel consumption and access to vehicle OBD and vehicle repair and maintenance information;
((3)) ‘odometer’ means that part of the odometer equipment which indicates to the driver the total distance recorded by the vehicle since its entry into service;
((4)) ‘starting aid’ means glow plugs, modifications to the injection timing and other devices which assist the engine to start without enrichment of the air/fuel mixture of the engine;
((5)) ‘engine capacity’ means either of the following:

((a)) for reciprocating piston engines, the nominal engine swept volume;
((b)) for rotary piston (Wankel) engines, double the nominal engine swept volume;
((6)) ‘periodically regenerating system’ means an exhaust emissions control device (e.g. catalytic converter, particulate trap) that requires a periodical regeneration process in less than 4 000 km of normal vehicle operation;
((7)) ‘original replacement pollution control device’ means a pollution control device or an assembly of pollution control devices whose types are indicated in Appendix 4 to Annex I to this Regulation but are offered on the market as separate technical units by the holder of the vehicle type-approval;
((8)) ‘type of pollution control device’ means catalytic converters and particulate filters which do not differ in any of the following essential aspects:

((a)) number of substrates, structure and material;
((b)) type of activity of each substrate;
((c)) volume, ratio of frontal area and substrate length;
((d)) catalyst material content;
((e)) catalyst material ratio;
((f)) cell density;
((g)) dimensions and shape;
((h)) thermal protection;
((9)) ‘mono fuel vehicle’ means a vehicle that is designed to run primarily on one type of fuel;
((10)) ‘mono fuel gas vehicle’ means a mono fuel vehicle that primarily runs on LPG, NG/biomethane, or hydrogen but may also have a petrol system for emergency purposes or starting only, where the petrol tank does not contain more than 15 litres of petrol;
((11)) ‘bi fuel vehicle’ means a vehicle with two separate fuel storage systems that can run part-time on two different fuels and is designed to run on only one fuel at a time;
((12)) ‘bi fuel gas vehicle’ means a bi fuel vehicle that can run on petrol and also on either LPG, NG/biomethane or hydrogen;
((13)) ‘flex fuel vehicle’ means a vehicle with one fuel storage system that can run on different mixtures of two or more fuels;
((14)) ‘flex fuel ethanol vehicle’ means a flex fuel vehicle that can run on petrol or a mixture of petrol and ethanol up to an 85 per cent ethanol blend (E85);
((15)) ‘flex fuel biodiesel vehicle’ means a flex fuel vehicle that can run on mineral diesel or a mixture of mineral diesel and biodiesel;
((16)) ‘hybrid electric vehicle’ (HEV) means a hybrid vehicle where one of the propulsion energy converters is an electric machine;
((17)) ‘properly maintained and used’ means, for the purpose of a test vehicle, that such a vehicle satisfies the criteria for acceptance of a selected vehicle laid down in section 2 of Appendix 3 to UN/ECE Regulation No 83;
((18)) ‘emission control system’ means, in the context of the OBD system, the electronic engine management controller and any emission-related component in the exhaust or evaporative system which supplies an input to or receives an output from this controller;
((19)) ‘malfunction indicator’ (MI) means a visible or audible indicator that clearly informs the driver of the vehicle in the event of a malfunction of any emission-related component connected to the OBD system, or of the OBD system itself;
((20)) ‘malfunction’ means the failure of an emission-related component or system that would result in emissions exceeding the limits in section 2.3 of Annex XI or if the OBD system is unable to fulfil the basic monitoring requirements set out in Annex XI;
((21)) ‘secondary air’ means the air introduced into the exhaust system by means of a pump or aspirator valve or other means that is intended to aid in the oxidation of HC and CO contained in the exhaust gas stream;
((22)) ‘driving cycle’, means, in respect of vehicle OBD systems, the engine start-up, driving mode where a malfunction would be detected if present, and engine shut-off;
((23)) ‘access to information’ means the availability of all vehicle OBD and vehicle repair and maintenance information, required for the inspection, diagnosis, servicing or repair of the vehicle.
((24)) ‘deficiency’ means, in the context of the OBD system, that up to two separate components or systems which are monitored contain temporary or permanent operating characteristics that impair the otherwise efficient OBD monitoring of those components or systems or do not meet all of the other detailed requirements for OBD;
((25)) ‘deteriorated replacement pollution control device’ means a pollution control device as defined in Article 3(11) of Regulation (EC) No 715/2007 that has been aged or artificially deteriorated to such an extent that it fulfils the requirements laid out in section 1 to Appendix 1 to Annex XI of UN/ECE Regulation No 83;
((26)) ‘vehicle OBD information’ means information relating to an on-board diagnostic system for any electronic system on the vehicle
((27)) ‘reagent’ means any product other than fuel that is stored on-board the vehicle and is provided to the exhaust after-treatment system upon request of the emission control system;
((28)) ‘mass in running order’ means the mass of the vehicle, with its fuel tank(s) filled to at least 90 per cent of its or their capacity/capacities, including the mass of the driver, fuel and liquids, fitted with the standard equipment in accordance with the manufacturer's specifications and, when they are fitted, the mass of the bodywork, the cabin, the coupling and the spare wheel(s) as well as the tools;
((29)) ‘engine misfire’ means lack of combustion in the cylinder of a positive ignition engine due to absence of spark, poor fuel metering, poor compression or any other cause;
((30)) ‘cold start system or device’ means a system which temporarily enriches the air/fuel mixture of the engine thus assisting the engine to start;
((31)) ‘power take-off operation or unit’ means an engine-driven output provision for the purposes of powering auxiliary, vehicle mounted, equipment;
((32)) ‘small volume manufacturers’ means vehicle manufacturers whose worldwide annual production is less than 10 000 units;
((33)) ‘Electric power train’ means a system consisting of one or more electric energy storage devices, one or more electric power conditioning devices and one or more electric machines that convert stored electric energy to mechanical energy delivered at the wheels for propulsion of the vehicle;
((34)) ‘Pure electric vehicle’ (PEV) means a vehicle equipped with a powertrain containing exclusively electric machines as propulsion energy converters and exclusively rechargeable electric energy storage systems as propulsion energy storage systems.
((35)) ‘Fuel cell’ means an energy converter transforming chemical energy (input) into electrical energy (output) or vice versa.
((36)) ‘Fuel cell vehicle’ (FCV) means a vehicle equipped with a powertrain containing exclusively fuel cell(s) and electric machine(s) as propulsion energy converter(s).
((37)) ‘net power’ means the power obtained on a test bench at the end of the crankshaft or its equivalent at the corresponding engine or motor speed with the auxiliaries, tested in accordance with Annex XX (Measurements of net power and the maximum 30 minutes power of electric drive train), and determined under reference atmospheric conditions;
((38)) ‘rated engine power (Prated)’ means maximum engine power in kW as per the requirements of Annex XX to this Regulation;
((39)) ‘maximum 30 minutes power’ means the maximum net power of an electric drive train at DC voltage as set out in paragraph 5.3.2. of UN/ECE Regulation No 85;
((40)) ‘cold start’ means, in the context of the in use performance ratio of OBD monitors, an engine coolant temperature or equivalent temperature at engine start less than or equal to 35 °C and less than or equal to 7 °C higher than ambient temperature, if available;
((41)) ‘Real driving emissions (RDE)’ means the emissions of a vehicle under its normal conditions of use;
((42)) ‘Portable emissions measurement system’ (PEMS) means a portable emissions measurement system meeting the requirements specified in Appendix 1 to Annex IIIA;
((43)) ‘Base Emission Strategy’, (‘BES’) means an emission strategy that is active throughout the speed and load operating range of the vehicle unless an Auxiliary Emission Strategy is activated;
((44)) ‘Auxiliary Emission Strategy’, (‘AES’) means an emission strategy that becomes active and replaces or modifies a BES for a specific purpose and in response to a specific set of ambient or operating conditions and only remains operational as long as those conditions exist.
((45)) ‘Fuel Storage System’ means devices which allow storing the fuel, comprising of the fuel tank, the fuel filler, the filler cap and the fuel pump;
((46)) ‘Permeability Factor (PF)’ means the hydrocarbon emissions as reflected in the permeability of the fuel storage system;
((47)) ‘Monolayer tank’ means a fuel tank constructed with a single layer of material;
((48)) ‘Multilayer tank’ means a fuel tank constructed with at least two different layered materials, one of which is impermeable to hydrocarbons, including ethanol;
Article 3 

1. In order to receive an EC type-approval with regard to emissions and vehicle repair and maintenance information, the manufacturer shall demonstrate that the vehicles comply with the requirements of this Regulation when tested in accordance with the test procedures specified in Annexes IIIA to VIII, XI, XIV, XVI, XX and XXI. The manufacturer shall also ensure that the reference fuels comply with the specifications set out in Annex IX.
2. Vehicles shall be subject to the tests specified in Figure I.2.4 of Annex I.
3. As an alternative to the requirements contained in Annexes II, V to VIII, XI, XVI and XXI, small volume manufacturers may request the granting of EC type-approval to a vehicle type which was approved by an authority of a third country on the basis of the legislative acts listed in section 2.1 of Annex I.The emissions tests for roadworthiness purposes set out in Annex IV, tests for fuel consumption and CO2 emissions set out in Annex XXI and the requirements for access to vehicle OBD and vehicle repair and maintenance information set out in Annex XIV shall be required to obtain EC type-approval with regard to emissions and vehicle repair and maintenance information under this paragraph.The approval authority shall inform the Commission of the circumstances of each type approval granted under this paragraph.
4. Specific requirements for inlets to fuel tanks and electronic system security are laid down in Section 2.2 and 2.3 of Annex I.
5. The manufacturer shall take technical measures so as to ensure that the tailpipe and evaporative emissions are effectively limited, in accordance with this Regulation, throughout the normal life of the vehicle and under normal conditions of use.These measures shall include ensuring that the security of hoses, joints and connections, used within the emission control systems, are constructed so as to conform with the original design intent.
6. The manufacturer shall ensure that the emissions test results comply with the applicable limit value under the specified test conditions of this Regulation.
7. For the Type 1 test set out in Annex XXI, vehicles that are fuelled with LPG or NG/biomethane shall be tested in the Type 1 test for variation in the composition of LPG or NG/biomethane, as set out in Annex XII. Vehicles that can be fuelled either with petrol or LPG or NG/biomethane shall be tested on both the fuels, tests on LPG or NG/biomethane being performed for variation in the composition of LPG or NG/biomethane, as set out in Annex XII.Notwithstanding the requirement of the previous sub-paragraph, vehicles that can be fuelled with either petrol or a gaseous fuel, but where the petrol system is fitted for emergency purposes or starting only and which the petrol tank cannot contain more than 15 litres of petrol will be regarded for the Type 1 test as vehicles that can only run on a gaseous fuel.
8. For the Type 2 test set out in Appendix 1 to Annex IV, at normal engine idling speed, the maximum permissible carbon monoxide content in the exhaust gases shall be that stated by the vehicle manufacturer. However, the maximum carbon monoxide content shall not exceed 0,3 % vol.At high engine idling speed, the carbon monoxide content by volume of the exhaust gases shall not exceed 0,2 %, with the engine speed being at least 2 000 min –1 and Lambda being 1 ± 0,03 or in accordance with the specifications of the manufacturer.
9. The manufacturer shall ensure that for the Type 3 test set out in Annex V, the engine's ventilation system does not permit the emission of any crankcase gases into the atmosphere.
10. The Type 6 test measuring emissions at low temperatures set out in Annex VIII shall not apply to diesel vehicles.However, when applying for type-approval, manufacturers shall present to the approval authority with information showing that the NOx after-treatment device reaches a sufficiently high temperature for efficient operation within 400 seconds after a cold start at – 7 °C as described in the Type 6 test.In addition, the manufacturer shall provide the approval authority with information on the operating strategy of the exhaust gas recirculation system (EGR), including its functioning at low temperatures.This information shall also include a description of any effects on emissions.The approval authority shall not grant type-approval if the information provided is insufficient to demonstrate that the after-treatment device actually reaches a sufficiently high temperature for efficient operation within the designated period of time.At the request of the Commission, the approval authority shall provide information on the performance of NOx after-treatment devices and EGR system at low temperatures.
11. The manufacturer shall ensure that, throughout the normal life of a vehicle which is type approved in accordance with Regulation (EC) No 715/2007, its emissions as determined in accordance with the requirements set out in Annex IIIA and emitted at an RDE test performed in accordance with that Annex, shall not exceed the values set out therein.Type approval in accordance with Regulation (EC) No 715/2007 may only be issued if the vehicle is part of a validated PEMS test family according to Appendix 7 of Annex IIIA.
Article 4 

1. The manufacturer shall ensure that all vehicles are equipped with an OBD system.
2. The OBD system shall be designed, constructed and installed on a vehicle so as to enable it to identify types of deterioration or malfunction over the entire life of the vehicle.
3. The OBD system shall comply with the requirements of this Regulation during normal conditions of use.
4. When tested with a defective component in accordance with Appendix 1 of Annex XI, the OBD system malfunction indicator shall be activated.The OBD system malfunction indicator may also activate during this test at levels of emissions below the OBD thresholds limits specified in section 2.3 of Annex XI.
5. The manufacturer shall ensure that the OBD system complies with the requirements for in-use performance set out in section 3 of Appendix 1 to Annex XI of this Regulation under all reasonably foreseeable driving conditions.
6. In-use performance related data to be stored and reported by a vehicle's OBD system according to the provisions of Section 7.6 of Appendix 1 to Annex XI of UN/ECE Regulation No 83 shall be made readily available by the manufacturer to national authorities and independent operators without any encryption.
Article 5 

1. The manufacturer shall submit to the approval authority an application for EC type-approval of a vehicle with regard to emissions and access to vehicle repair and maintenance information.
2. The application referred to in paragraph 1 shall be drawn up in accordance with the model of the information document set out in Appendix 3 to Annex I.
3. In addition, the manufacturer shall submit the following information:
(a) in the case of vehicles equipped with positive-ignition engines, a declaration by the manufacturer of the minimum percentage of misfires out of a total number of firing events that either would result in emissions exceeding the limits given in section 2.3 of Annex XI if that percentage of misfire had been present from the start of a type 1 test as chosen for the demonstration according to Annex XI to this Regulation or could lead to an exhaust catalyst, or catalysts, overheating prior to causing irreversible damage;
(b) detailed written information fully describing the functional operation characteristics of the OBD system, including a listing of all relevant parts of the emission control system of the vehicle that are monitored by the OBD system;
(c) a description of the malfunction indicator used by the OBD system to signal the presence of a fault to a driver of the vehicle;
(d) a declaration by the manufacturer that the OBD system complies with the provisions of section 3 of Appendix 1 to Annex XI relating to in-use performance under all reasonably foreseeable driving conditions;
(e) a plan describing the detailed technical criteria and justification for incrementing the numerator and denominator of each monitor that must fulfil the requirements of paragraphs 7.2 and 7.3. of Appendix 1 to Annex XI of UN/ECE Regulation No 83, as well as for disabling numerators, denominators and the general denominator under the conditions outlined in paragraph 7.7 of Appendix 1 to Annex XI of UN/ECE Regulation No 83;
(f) a description of the provisions taken to prevent tampering with and modification of the emission control computer, odometer including the recording of mileage values for the purposes of the requirements of Annexes XI and XVI;
(g) if applicable, the particulars of the vehicle family as referred to in Appendix 2 to Annex 11 to UN/ECE Regulation No 83;
(h) where appropriate, copies of other type-approvals with the relevant data to enable extension of approvals and establishment of deterioration factors.
4. For the purposes of point (d) of paragraph 3, the manufacturer shall use the model of manufacturer's certificate of compliance with the OBD in-use performance requirements set out in Appendix 7 of Annex I
5. For the purposes of point (e) of paragraph 3, the approval authority that grants the approval shall make the information referred to in that point available to the approval authorities or the Commission upon request.
6. For the purposes of points (d) and (e) of paragraph 3, approval authorities shall not approve a vehicle if the information submitted by the manufacturer is inappropriate for fulfilling the requirements of section 3 of Appendix 1 to Annex XI.Paragraphs 7.2, 7.3 and 7.7 of Appendix 1 to Annex XI of UN/ECE Regulation No 83 shall apply under all reasonably foreseeable driving conditions.For the assessment of the implementation of the requirements set out in these paragraphs, the approval authorities shall take into account the state of technology.
7. For the purposes of point (f) of paragraph 3, the provisions taken to prevent tampering with and modification of the emission control computer shall include the facility for updating using a manufacturer-approved programme or calibration.
8. For the tests specified in Figure I.2.4 of Annex I the manufacturer shall submit to the technical service responsible for the type-approval tests a vehicle representative of the type to be approved.
9. The application for type-approval of mono fuel, bi-fuel and flex-fuel vehicles shall comply with the additional requirements laid down in Sections 1.1 and 1.2 of Annex I.
10. Changes to the make of a system, component or separate technical unit that occur after a type-approval shall not automatically invalidate a type approval, unless its original characteristics or technical parameters are changed in such a way that the functionality of the engine or pollution control system is affected.
11. The manufacturer shall also provide an extended documentation package with the following information:
(a) information on the operation of all AES and BES, including a description of the parameters that are modified by any AES and the boundary conditions under which the AES operate, and indication of the AES or BES which are likely to be active under the conditions of the test procedures set out in this Regulation;
(b) a description of the fuel system control logic, timing strategies and switch points during all modes of operation.
(c) a description of the coastdown mode, if any, as referred to in paragraph 4.2.1.8.5. of Sub-Annex 4 to Annexe XXI, and a description of the vehicle's dynamometer operation mode, if any, as referred to in paragraph 1.2.4. of Sub-Annex 6 to Annex XXI.
12. The extended documentation package referred to in paragraph 11 (a) and (b) shall remain strictly confidential. It may be kept by the approval authority, or, at the discretion of the approval authority, may be retained by the manufacturer. In the case the manufacturer retains the documentation package, that package shall be identified and dated by the approval authority once reviewed and approved. It shall be made available for inspection by the approval authority at the time of approval or at any time during the validity of the approval.
Article 6 

1. If all the relevant requirements are met, the approval authority shall grant an EC type-approval and issue a type-approval number in accordance with the numbering system set out in Annex VII to Directive 2007/46/EC.Without prejudice to the provisions of Annex VII to Directive 2007/46/EC, Section 3 of the type-approval number shall be drawn up in accordance with Appendix 6 to Annex I to this Regulation.An approval authority shall not assign the same number to another vehicle type.
2. By way of derogation from paragraph 1, at the request of the manufacturer, a vehicle with an OBD system may be accepted for type-approval with regard to emissions and vehicle repair and maintenance information, even though the system contains one or more deficiencies such that the specific requirements of Annex XI are not fully met, provided that the specific administrative provisions set out in Section 3 of that Annex are complied with.The approval authority shall notify the decision to grant such a type approval to all approval authorities in the other Member States in accordance with the requirements set out in Article 8 of Directive 2007/46/EC.
3. When granting an EC type approval under paragraph 1, the approval authority shall issue an EC type-approval certificate using the model set out in Appendix 4 to Annex I.
Article 7 
Articles 13, 14 and 16 of Directive 2007/46/EC shall apply to any amendments to the type-approvals granted in accordance to Regulation (EC) No 715/2007.
At the manufacturer's request the provisions specified in Section 3 of Annex I shall apply without the need for additional testing only to vehicles of the same type.
Article 8 

1. Measures to ensure the conformity of production shall be taken in accordance with the provisions of Article 12 of Directive 2007/46/EC.In addition, the provisions laid down in Section 4 of Annex I to this Regulation and the relevant statistical method in Appendices 1 and 2 to that Annex shall apply.
2. Conformity of production shall be checked on the basis of the description in the type-approval certificate set out in Appendix 4 to Annex I to this Regulation.
Article 9 

1. Measures to ensure in-service conformity of vehicles type-approved under this Regulation shall be taken in accordance with Annex X to Directive 2007/46/EC and Annex II to this Regulation.
2. The in-service conformity measures shall be appropriate for confirming the functionality of the pollution control devices during the normal life of the vehicles under normal conditions of use as specified in Annex II to this Regulation.
3. The in-service conformity measures shall be checked for a period of up to 5 years of age or 100 000 km, whichever is the sooner.
4. The manufacturer shall not be obliged to carry out an audit of in-service conformity if the number of vehicles sold precludes obtaining sufficient samples to test. Therefore, an audit shall not be required if the annual sales of that vehicle type are less than 5 000 across the Union.However, the manufacturer of such small series vehicles shall provide the approval authority with a report of any emissions related warranty and repair claims and OBD faults as set out in paragraph 9.2.3 of UN/ECE Regulation No 83. In addition, the type-approval authority may require such vehicle types to be tested in accordance with Appendix 3 to UN/ECE Regulation No 83.
5. With regard to vehicles type-approved under this Regulation, where the approval authority is not satisfied with the results of the tests in accordance with the criteria defined in Appendix 4 to UN/ECE Regulation No 83, the remedial measures referred to in Article 30(1) and in Annex X to Directive 2007/46/EC shall be extended to vehicles in service belonging to the same vehicle type which are likely to be affected with the same defects in accordance with section 6 of Appendix 3 to UN/ECE Regulation No 83.The plan of remedial measures presented by the manufacturer according to section 6.1 of Appendix 3 to UN/ECE Regulation No 83 shall be approved by the approval authority. The manufacturer shall be responsible for the execution of the approved remedial plan.The approval authority shall notify its decision to all Member States within 30 days. Member States may require that the same plan of remedial measures be applied to all vehicles of the same type registered in their territory.
6. If an approval authority has established that a vehicle type does not conform to the applicable requirements of Appendix 3 to UN/ECE Regulation No 83, it shall notify without delay the Member State which granted the original type-approval in accordance with the requirements of Article 30(3) of Directive 2007/46/EC.Following that notification and subject to the provision of Article 30(6) of Directive 2007/46/EC, the approval authority which granted the original type-approval shall inform the manufacturer that a vehicle type fails to satisfy the requirements of these provisions and that certain measures are expected of the manufacturer. The manufacturer shall submit to that authority, within two months after this notification, a plan of measures to overcome the defects, the substance of which should correspond to the requirements of sections 6.1 to 6.8 of Appendix 3 to UN/ECE Regulation No 83. The approval authority which granted the original type-approval shall, within two months, consult the manufacturer in order to secure agreement on a plan of measures and on the carrying out the plan. If the approval authority which granted the original type-approval establishes that no agreement can be reached, the procedure pursuant to Article 30(3) and (4) of Directive 2007/46/EC shall be initiated.
Article 10 

1. The manufacturer shall ensure that replacement pollution control devices intended to be fitted to EC type-approved vehicles covered by the scope of Regulation (EC) No 715/2007 are EC type-approved, as separate technical units within the meaning of Article 10(2) of Directive 2007/46/EC, in accordance with Article 12, Article 13 and Annex XIII to this Regulation.Catalytic converters and particulate filters shall be considered to be pollution control devices for the purposes of this Regulation.The relevant requirements shall be deemed to be met if all the following conditions are fulfilled:
(a) the requirements of Article 13 are met;
(b) the replacement pollution control devices have been approved according to UN/ECE Regulation No 103.In the case referred to in the third subparagraph Article 14 shall also apply.
2. Original equipment replacement pollution control devices, which fall within the type covered by point 2.3 of the Addendum to Appendix 4 to Annex I and are intended for fitment to a vehicle to which the relevant type-approval document refers, do not need to comply with Annex XIII provided they fulfil the requirements of points 2.1 and 2.2 of that Annex.
3. The manufacturer shall ensure that the original pollution control device carries identification markings.
4. The identification markings referred to in paragraph 3 shall comprise the following:
(a) the vehicle or engine manufacturer's name or trade mark;
(b) the make and identifying part number of the original pollution control device as recorded in the information referred to in point 3.2.12.2 of Appendix 3 to Annex I.
Article 11 

1. The manufacturer shall submit to the approval authority an application for EC type-approval of a type of replacement pollution control device as a separate technical unit.The application shall be drawn up in accordance with the model of the information document set out in Appendix 1 to Annex XIII.
2. In addition to the requirements laid down in paragraph 1, the manufacturer shall submit to the technical service responsible for the type-approval test all of the following:
(a) a vehicle or vehicles of a type approved in accordance with this Regulation equipped with a new original equipment pollution control device;
(b) one sample of the type of the replacement pollution control device;
(c) an additional sample of the type of the replacement pollution control device, in the case of a replacement pollution control device intended to be fitted to a vehicle equipped with an OBD system.
3. For the purposes of point (a) of paragraph 2, the test vehicles shall be selected by the applicant with the agreement of the technical service.The test vehicles shall comply with the requirements set out in Section 3.2 of Annex 4a to UN/ECE Regulation No 83.The test vehicles shall respect all of the following requirements:
(a) they shall have no emission control system defects;
(b) any excessively worn out or malfunctioning emission-related original part shall be repaired or replaced;
(c) they shall be tuned properly and set to manufacturer's specification prior to emission testing.
4. For the purposes of points (b) and (c) of paragraph 2, the sample shall be clearly and indelibly marked with the applicant's trade name or mark and its commercial designation.
5. For the purposes of point (c) of paragraph 2, the sample shall have been deteriorated as defined under point (25) of Article 2.
Article 12 

1. If all the relevant requirements are met, the type approval authority shall grant an EC type-approval for replacement pollution control devices as separate technical unit and issue a type-approval number in accordance with the numbering system set out in Annex VII to Directive 2007/46/EC.The approval authority shall not assign the same number to another replacement pollution control device type.The same type-approval number may cover the use of that replacement pollution control device type on a number of different vehicle types.
2. For the purposes of paragraph 1, the approval authority shall issue an EC type-approval certificate established in accordance with the model set out in Appendix 2 to Annex XIII.
3. If the applicant for type-approval is able to demonstrate to the approval authority or technical service that the replacement pollution control device is of a type indicated in section 2.3 of the Addendum to Appendix 4 to Annex I, the granting of a type-approval shall not be dependent on verification of compliance with the requirements specified in section 4 of Annex XIII.
Article 13 

1. Manufacturers shall put in place the necessary arrangements and procedures, in accordance with Articles 6 and 7 of Regulation (EC) No 715/2007 and Annex XIV of this regulation, to ensure that vehicle OBD and vehicle repair and maintenance information is readily accessible.
2. Approval authorities shall only grant type-approval after receiving from the manufacturer a Certificate on Access to Vehicle OBD and Vehicle Repair and Maintenance Information.
3. The Certificate on Access to Vehicle OBD and Vehicle Repair and Maintenance Information shall serve as the proof of compliance with Article 6(7) of Regulation (EC) No 715/2007.
4. The Certificate on Access to Vehicle OBD and Vehicle Repair and Maintenance Information shall be drawn up in accordance with the model set out in Appendix 1 of Annex XIV.
5. If the vehicle OBD and vehicle repair and maintenance information is not available, or does not conform to Article 6 and 7 of Regulation (EC) No 715/2007 and Annex XIV of this Regulation, when the application for type-approval is made, the manufacturer shall provide that information within six months of the date of type approval.
6. The obligations to provide information within the period specified in paragraph 5 shall apply only if, following type-approval, the vehicle is placed on the market.When the vehicle is placed on the market more than six months after type-approval, the information shall be provided on the date on which the vehicle is placed on the market.
7. The approval authority may presume that the manufacturer has put in place satisfactory arrangements and procedures with regard to access to vehicle OBD and vehicle repair and maintenance information, on the basis of a completed Certificate on Access to Vehicle OBD and Vehicle Repair and Maintenance Information, providing that no complaint was made, and that the manufacturer provides this information within the period set out in paragraph 5.
8. In addition to the requirements for the access to OBD information that are specified in Section 4 of Annex XI, the manufacturer shall make available to interested parties the following information:
(a) relevant information to enable the development of replacement components which are critical to the correct functioning of the OBD system;
(b) information to enable the development of generic diagnostic tools.For the purposes of point (a), the development of replacement components shall not be restricted by: the unavailability of pertinent information, the technical requirements relating to malfunction indication strategies if the OBD thresholds are exceeded or if the OBD system is unable to fulfil the basic OBD monitoring requirements of this Regulation; specific modifications to the handling of OBD information to deal independently with vehicle operation on petrol or on gas; and the type-approval of gas-fuelled vehicles that contain a limited number of minor deficiencies.For the purposes of point (b), where manufacturers use diagnostic and test tools in accordance with ISO 22900 Modular Vehicle Communication Interface (MVCI) and ISO 22901 Open Diagnostic Data Exchange (ODX) in their franchised networks, the ODX files shall be accessible to independent operators via the web site of the manufacturer.
9. The Forum on Access to Vehicle Information (the Forum).The Forum shall consider whether access to information affects the advances made in reducing vehicle theft and shall make recommendations for improving the requirements relating to access to information. In particular, the Forum shall advise the Commission on the introduction of a process for approving and authorising independent operators by accredited organisations to access information on vehicle security.The Commission may decide to keep the discussions and findings of the Forum confidential.
Article 14 

1. An approval authority may, at any time, whether on its own initiative, on the basis of a complaint, or on the basis of an assessment by a technical service, check the compliance of a manufacturer with the provisions of Regulation (EC) No 715/2007, this Regulation, and the terms of the Certificate on Access to Vehicle OBD and Vehicle Repair and Maintenance Information.
2. Where an approval authority finds that the manufacturer has failed to comply with its obligations regarding access to vehicle OBD and vehicle repair and maintenance information, the approval authority which granted the relevant type approval shall take appropriate steps to remedy the situation.
3. The steps referred to in paragraph 2 may include withdrawal or suspension of type-approval, fines, or other measures adopted in accordance with Article 13 of Regulation (EC) No 715/2007.
4. The approval authority shall proceed to an audit in order to verify compliance by the manufacturer with the obligations concerning access to vehicle OBD and vehicle repair and maintenance information, if an independent operator or a trade association representing independent operators files a complaint to the approval authority.
5. When carrying out the audit, the approval authority may ask a technical service or any other independent expert to carry out an assessment to verify whether these obligations are met.
Article 15 

1. Until 31 August 2017 in the case of categories M1, M2 and category N1 class I vehicles, and until 31 August 2018 in the case of N1 vehicles of class II and III and category N2 vehicles manufacturers may request type-approval to be granted in accordance with this Regulation. Where such request is not made, Regulation (EC) No 692/2008 shall apply.
2. With effect from 1 September 2017 in the case of categories M1, M2 and category N1 class I vehicles, and from 1 September 2018 in the case of N1 vehicles of class II and III and category N2 vehicles, national authorities shall refuse, on grounds relating to emissions or fuel consumption, to grant EC type approval or national type approval, in respect to new vehicle types which do not comply with this Regulation.
3. With effect from 1 September 2018 in the case of categories M1, M2 and category N1 class I vehicles, and from 1 September 2019 in the case of N1 vehicles of class II and III and category N2 vehicles, national authorities shall, on grounds relating to emissions or fuel consumption, in the case of new vehicles which do not comply with this Regulation, consider certificates of conformity to be no longer valid for the purposes of Article 26 of Directive 2007/46/EC and shall prohibit the registration, sale or entry into service of such vehicles.
4. Until three years after the dates specified in Article 10(4) of Regulation (EC) No 715/2007 in the case of new vehicle types and four years after the dates specified in Article 10(5) of that Regulation in the case of new vehicles, the following provisions shall apply:
(a) the requirements of point 2.1 of Annex IIIA shall not apply;
(b) the requirements of Annex IIIA other than that in point 2.1, including the requirements with regard to RDE tests to be performed and data to be recorded and made available, shall apply only to new type approvals granted in accordance with Regulation (EC) No 715/2007 from 27 July 2017;
(c) the requirements of Annex IIIA shall not apply to type approvals granted to small volume manufacturers;
(d) where the requirements set out in Appendices 5 and 6 of Annex IIIA are satisfied for only one of the two data evaluation methods described in those Appendices, one additional RDE test shall be performed;where those requirements are again satisfied for only one method, the analysis of the completeness and normality shall be recorded for both methods and the calculation required by point 9.3 of Annex IIIA may be limited to the method for which the completeness and normality requirements are satisfied; the data of both RDE tests and of the analysis of the completeness and normality shall be recorded and made available for examining the difference in the results of the two data evaluation methods;
(e) the power at the wheels of the test vehicle shall be determined either by wheel hub torque measurement or from the CO2 mass flow using ‘Velines’ in accordance with point 4 of Appendix 6 to Annex IIIA.
5. Until 8 years after the dates given in Article 10(4) of Regulation (EC) No 715/2007:
(a) type 1/I tests performed and completed in accordance to Regulation (EC) No 692/2008 until 3 years after the dates given in Article 10(4) of Regulation (EC) No 715/2007 shall be valid for the purposes of fulfilling the requirements of Annex VII and/or Appendix 1 to Annex XI to this Regulation;
(b) procedures performed in accordance with section 3.13. of Annex III to Regulation (EC) No 692/2008 until 3 years after the dates given in Article 10(4) of Regulation (EC) 715/2007 shall be accepted by the approval authority for the purposes of fulfilling the requirements of the second paragraph of point 1.1 of Appendix 1 to Sub-Annex 6 to Annex XXI of this Regulation.
6. In order to ensure a fair treatment of previously existing type-approvals, the Commission shall examine the consequences of Chapter V of Directive 2007/46/EC for the purposes of this Regulation.
Article 16 
Directive 2007/46/EC is amended in accordance with Annex XVIII to this Regulation.
Article 17 
Regulation (EC) No 692/2008 is amended as follows:

((1)) In Article 6, paragraph 1, shall be replaced by the following text:
'
1. If all the relevant requirements are met, the approval authority shall grant an EC type-approval and issue a type-approval number in accordance with the numbering system set out in Annex VII to Directive 2007/46/EC.Without prejudice to the provisions of Annex VII to Directive 2007/46/EC, Section 3 of the type-approval number shall be drawn up in accordance with Appendix 6 to Annex I to this Regulation.An approval authority shall not assign the same number to another vehicle type.The requirements of Regulation (EC) No 715/2007 shall be deemed to be met if all the following conditions are fulfilled:
(a) the requirements of Article 3(10) of this Regulation are met;
(b) the requirements of Article 13 of this Regulation are met;
(c) the vehicle has been approved according to UN/ECE Regulations No 83, series of amendments 07; No 85 and its supplements, No 101, Revision 3 (comprising series of amendments 01 and their supplements) and in the case of compression ignition vehicles No 24 Part III, series of amendments 03.
(d) the requirements of Article 5(11) and (12) are met.'
((2)) the following Article 16a is added:
'
Article 16a 
With effect from 1 September 2017 in the case of categories M1, M2 and category N1 class I vehicles, and from 1 September 2018 in the case of N1 vehicles of class II and III and category N2 vehicles, this Regulation shall only apply for the purposes of assessing the following requirements of vehicles type-approved in accordance with this Regulation before those dates:

((a)) conformity of production in accordance with Article 8;
((b)) in-service conformity in accordance with Article 9;
((c)) access to vehicle OBD and vehicle repair and maintenance information in accordance with Article 13;
This Regulation shall also apply for the purposes of the correlation procedure set out in Commission Implementing Regulations (EU) 2017/1152 and (EU) 2017/1153.'
((3)) Annex I is amended in accordance with Annex XVII to this Regulation.
Article 18 
In Regulation (EU) No 1230/2012, Article 2(5) is replaced by the following:
'
((5)) “Mass of the optional equipment” means the maximum mass of the combinations of optional equipment which may be fitted to the vehicle in addition to the standard equipment in accordance with the manufacturer's specifications;'
Article 19 
Regulation (EC) No 692/2008 is repealed as from 1 January 2022.
Article 20 
This Regulation shall enter into force on the twentieth day following its publication in the Official Journal of the European Union.
This Regulation shall be binding in its entirety and directly applicable in all Member States.Done at Brussels, 1 June 2017.
For the Commission
The President
Jean-Claude JUNCKER
LIST OF ANNEXES

ANNEX I Administrative provisions for EC type-approval
Appendix 1 Verification of conformity of production for Type 1 test — statistical method
Appendix 2 Calculations for Conformity of Production for EVs
Appendix 3 Model information document
Appendix 4 Model EC type-approval certificate
Appendix 5 OBD related information
Appendix 6 EC type-approval certificate numbering system
Appendix 7 Manufacturer's certificate of compliance with OBD in-use performance requirements
Appendix 8a Type 1 test Test Report template (including ATCT) with minimum reporting requirements
Annex for reporting Co2mpass
Appendix 8b Road Load Test Report template with minimum reporting requirements
Appendix 8c Test Sheet template
ANNEX II In-service conformity
Appendix 1 In-service conformity check
Appendix 2 Statistical procedure for tailpipe emissions in-service conformity testing
Appendix 3 Responsibilities for in-service conformity
ANNEX IIIA Real Driving Emissions (RDE)
ANNEX IV Emissions data required at type-approval for roadworthiness purposes
Appendix 1 Measuring carbon monoxide emissions at engine idling speeds (Type 2 test)
Appendix 2 Measurement of smoke opacity
ANNEX V Verifying emissions of crankcase gases (Type 3 test)
ANNEX VI Determination of evaporative emissions (Type 4 test)
ANNEX VII Verifying the durability of pollution control devices (Type 5 test)
Appendix 1 Standard Bench Cycle (SBC)
Appendix 2 Standard Diesel Bench Cycle (SDBC)
Appendix 3 Standard Road Cycle (SRC)
ANNEX VIII Verifying the average exhaust emissions at low ambient temperatures (Type 6 test)
ANNEX IX Specifications of reference fuels
ANNEX X Reserved
ANNEX XI On-board diagnostics (OBD) for motor vehicles
Appendix 1 Functional aspects of OBD systems
Appendix 2 Essential characteristics of the vehicle family
ANNEX XII Type-Approval of vehicles fitted with eco-innovations and Determination of CO2 emissions and fuel consumption from N1 vehicles submitted to multi-stage type-approval
ANNEX XIII EC Type-approval of replacement pollution control devices as separate technical unit
Appendix 1 Model information document
Appendix 2 Model EC type-approval certificate
Appendix 3 Model EC type-approval mark
ANNEX XIV Access to vehicle OBD and vehicle repair and maintenance information
Appendix 1 Certificate of compliance
ANNEX XV Reserved
ANNEX XVI Requirements for vehicles that use a reagent for the exhaust after-treatment system
ANNEX XVII Amendments to Regulation (EC) No 692/2008
ANNEX XVIII Amendments to Directive 2007/46/EC
ANNEX XIX Amendments to Regulation (EU) No 1230/2012
ANNEX XX Measurement of net engine power
ANNEX XXI Type 1 emissions test procedures
ANNEX I
1.  1.1.  1.1.1. The additional requirements for granting of type-approval for mono fuel gas vehicles, and bi-fuel gas vehicles shall be those set out in sections 1, 2 and 3 and Appendices 1 and 2 to Annex 12 to UN/ECE Regulation No 83, with the exceptions set out below.
 1.1.2. The reference in paragraphs 3.1.2. and 3.1.4. of Annex 12 to UN/ECE Regulation No 83 to reference fuels of Annex 10a shall be understood as being reference to the appropriate reference fuel specifications in Section A of Annex IX to this Regulation.
 1.2. 
The additional requirements for granting of type-approval for flex fuel vehicles shall be those set out in paragraph 4.9. of UN/ECE Regulation No 83.

2.  2.1.  2.1.1. 
Legislative Act Requirements
The California Code of Regulations, Title 13, Sections 1961(a) and 1961(b)(1)(C)(1) applicable to 2001 and later model year vehicles, 1968.1, 1968.2, 1968.5, 1976 and 1975, published by Barclay’s Publishing Type-approval must be granted under the California Code of Regulations applicable to the most recent model year of light-duty vehicle. 2.2.  2.2.1. The requirements for inlets to fuel tanks shall be those specified in paragraphs 5.4.1. and 5.4.2. of Annex XXI and point 2.2.2 below.
 2.2.2. 

((a)) an automatically opening and closing, non-removable fuel filler cap,
((b)) design features which avoid excess evaporative emissions in the case of a missing fuel filler cap,
((c)) any other provision which has the same effect. Examples may include, but are not limited to, a tethered filler cap, a chained filler cap or one utilizing the same locking key for the filler cap as for the vehicle’s ignition. In this case the key shall be removable from the filler cap only in the locked condition.
 2.3.  2.3.1. The provisions for electronic system security shall be those specified in paragraph 5.5 of Annex XXI and points 2.3.2 and 2.3.3 below.
 2.3.2 In the case of mechanical fuel-injection pumps fitted to compression-ignition engines, manufacturers shall take adequate steps to protect the maximum fuel delivery setting from tampering while a vehicle is in service.
 2.3.3. Manufacturers shall effectively deter reprogramming of the odometer readings, in the board network, in any powertrain controller as well as in the transmitting unit for remote data exchange if applicable. Manufacturers shall include systematic tamper-protection strategies and write-protect features to protect the integrity of the odometer reading. Methods giving an adequate level of tamper protection shall be approved by the approval authority.
 2.4.  2.4.1. 

Figure I.2.4
Application of test requirements for type-approval and extensions
Vehicle category Vehicles with positive ignition engines including hybrids1 Vehicles with compression ignition engines including hybrids Pure electric vehicles Hydrogen fuel cell vehicles
 Mono fuel Bi-fuel3 Flex-fuel3   
Reference fuel Petrol(E10) LPG NG/Biomethane Hydrogen (ICE) Petrol (E10) Petrol (E10) Petrol (E10) Petrol (E10) Diesel(B7) 5 — Hydrogen (Fuel Cell)
LPG NG/Biomethane Hydrogen (ICE) 4 Ethanol(E85)
Gaseous pollutants(Type 1 test) Yes Yes Yes Yes4 Yes(both fuels) Yes(both fuels) Yes(both fuels) Yes(both fuels) Yes — —
PM(Type 1 test) Yes2 — — — Yes2(petrol only) Yes2(petrol only) Yes2(petrol only) Yes2(both fuels) Yes — —
PN Yes2 — — — Yes2(petrol only) Yes2(petrol only) Yes2(petrol only) Yes2(both fuels) Yes — —
Gaseous pollutants, RDE (Type 1A test) Yes Yes Yes Yes (4) Yes (both fuels) Yes (both fuels) Yes (both fuels) Yes (both fuels) Yes — —
PN, RDE (Type 1A test) Yes — — — Yes (both fuels) Yes (both fuels Yes (both fuels Yes (both fuels) Yes — —
Idle emissions(Type 2 test) Yes Yes Yes — Yes(both fuels) Yes(both fuels) Yes(petrol only) Yes(both fuels) — — —
Crankcase emissions(Type 3 test) Yes Yes Yes — Yes(petrol only) Yes(petrol only) Yes(petrol only) Yes(petrol only) — — —
Evaporative emissions(Type 4 test) Yes — — — Yes(petrol only) Yes(petrol only) Yes(petrol only) Yes(petrol only) — — —
Durability(Type 5 test) Yes Yes Yes Yes Yes(petrol only) Yes(petrol only) Yes(petrol only) Yes(petrol only) Yes — —
Low temperature emissions(Type 6 test) Yes — — — Yes(petrol only) Yes(petrol only) Yes(petrol only) Yes(both fuels) — — —
In-service conformity Yes Yes Yes Yes Yes(both fuels) Yes(both fuels) Yes(both fuels) Yes(both fuels) Yes — —
On-board diagnostics Yes Yes Yes Yes Yes Yes Yes Yes Yes — —
CO2 emissions, fuel consumption, electric energy consumption and electric range Yes Yes Yes Yes Yes(both fuels) Yes(both fuels) Yes(both fuels) Yes(both fuels) Yes Yes Yes
Smoke opacity — — — — — — — — Yes — —
Engine power Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes
3.  3.1.  3.1.1. The type-approval shall be extended to vehicles if they conform to the criteria of Article 2 (1).
 3.1.2. 
For Ki tests undertaken under Appendix 1 to Sub-Annex VI to Annex XXI (WLTP), the type-approval shall be extended to vehicles if they conform to the criteria of paragraph 5.9. of Annex XXI.

For Ki tests undertaken under Annex 13 of UN/ECE Regulation No 83 (NEDC) the type-approval shall be extended to vehicles according to the requirements of Section 3.1.4. of Annex I to Regulation (EC) No 692/2008.
 3.2.  3.2.1. 

3.2.1.1. The basic principle of fuel/air metering (e.g. single point injection) is the same.
3.2.1.2. The shape of the fuel tank and the material of the fuel tank and liquid fuel hoses are identical.
3.2.1.3. The worst-case vehicle with regard to the cross-section and approximate hose length shall be tested. Whether non-identical vapour/liquid separators are acceptable is decided by the technical service responsible for the type-approval tests.
3.2.1.4. The fuel tank volume is within a range of ± 10 %.
3.2.1.5. The setting of the fuel tank relief valve is identical.
3.2.1.6. The method of storage of the fuel vapour is identical, i.e. trap form and volume, storage medium, air cleaner (if used for evaporative emission control), etc.
3.2.1.7. The method of purging of the stored vapour is identical (e.g. air flow, start point or purge volume over the preconditioning cycle).
3.2.1.8. The method of sealing and venting of the fuel metering system is identical.
 3.2.2. 

3.2.2.1. different engine sizes;
3.2.2.2. different engine powers;
3.2.2.3. automatic and manual gearboxes;
3.2.2.4. two and four wheel transmissions;
3.2.2.5. different body styles; and
3.2.2.6. different wheel and tyre sizes.
 3.3.  3.3.1. The type-approval shall be extended to different vehicle types, provided that the vehicle, engine or pollution control system parameters specified below are identical or remain within the prescribed tolerances:
 3.3.1.1. Vehicle:

 Inertia category: the two inertia categories immediately above and any inertia category below.
 Total road load at 80 km/h: + 5 % above and any value below.
 3.3.1.2. 

((a)) engine cylinder capacity (± 15 %),
((b)) number and control of valves,
((c)) fuel system,
((d)) type of cooling system,
((e)) combustion process.
 3.3.1.3. Pollution control system parameters:

((a)) Catalytic converters and particulate filters:

 number of catalytic converters, filters and elements,
 size of catalytic converters and filters (volume of monolith ± 10 %),
 type of catalytic activity (oxidizing, three-way, lean NOx trap, SCR, lean NOx catalyst or other),
 precious metal load (identical or higher),
 precious metal type and ratio (± 15 %),
 substrate (structure and material),
 cell density,
 temperature variation of no more than 50 K at the inlet of the catalytic converter or filter. This temperature variation shall be checked under stabilized conditions at a vehicle speed of 120 km/h and the load setting of the type 1 test.
((b)) Air injection:

 with or without
 type (pulsair, air pumps, other(s))
((c)) EGR:

 with or without
 type (cooled or non-cooled, active or passive control, high pressure or low pressure).
 3.3.1.4. The durability test may be carried out using a vehicle, which has a different body style, gear box (automatic or manual) and size of the wheels or tyres, from those of the vehicle type for which the type-approval is sought.
 3.4.  3.4.1. 

((a)) engine accessories;
((b)) tyres;
((c)) equivalent inertia;
((d)) cooling system;
((e)) overall gear ratio;
((f)) transmission type; and
((g)) type of bodywork.
 3.5  3.5.1.  3.5.1.1. The type-approval shall be extended only to vehicles with a reference mass requiring the use of the next two higher equivalent inertia or any lower equivalent inertia.
 3.5.1.2. For category N vehicles, the approval shall be extended only to vehicles with a lower reference mass, if the emissions of the vehicle already approved are within the limits prescribed for the vehicle for which extension of the approval is requested.
 3.5.2.  3.5.2.1. The type-approval shall be extended to vehicles with different transmission ratios only under certain conditions.
 3.5.2.2. 
E=V2− V1∕V1

shall be determined where, at an engine speed of 1 000 min –1, V1 is the speed of the vehicle-type approved and V2 is the speed of the vehicle type for which extension of the approval is requested.
 3.5.2.3. If, for each transmission ratio, E ≤ 8 %, the extension shall be granted without repeating the type 6 test.
 3.5.2.4. If, for at least one transmission ratio, E > 8 %, and if, for each gear ratio, E ≤ 13 %, the type 6 test shall be repeated. The tests may be performed in a laboratory chosen by the manufacturer subject to the approval of the technical service. The report of the tests shall be sent to the technical service responsible for the type-approval tests.
 3.5.3. 
The type-approval shall be extended to vehicles with different reference masses and transmission ratios, provided that all the conditions prescribed in paragraphs 3.5.1 and 3.5.2 are fulfilled.

4.  4.1.  4.1.1. Every vehicle produced under a Type Approval according to this Regulation shall be so manufactured as to conform to the type approval requirements of this Regulation. The Manufacturer shall implement adequate arrangements and documented control plans and carry-out at specified intervals as given in this regulation the necessary emission and OBD tests to verify continued conformity with the approved type. The approval authority shall verify and agree with these arrangements and control plans of the manufacturer and perform audits and conduct emission and OBD tests at specific intervals, as given in this regulation, at the premises of the manufacturer, including production and test facilities as part of the product conformity and continued verification arrangements as described in Annex X of Directive 2007/46/EC.
 4.1.2. The manufacturer shall check the conformity of production by testing the emissions of pollutants (given in Table 2 of Annex I to Regulation (EC) No 715/2007), the emission of CO2 (along with the measurement of electric energy consumption, EC), the crankcase emissions, evaporative emissions and the OBD. The verification shall therefore include the tests of types 1, 3, 4 and the test for OBD, as described in section 2.4 of this Annex and the relevant annexes quoted therein. The specific procedures for conformity of production are set out in Sections 4.2 to 4.7 and Appendixes 1 and 2.
 4.1.3. For the purposes of the manufactures conformity of production check, the family means the CO2 interpolation family for tests of Type 1 and 3, includes for the Type 4 test the extensions described in paragraph 3.2 of this Annex and the OBD family with the extensions described in paragraph 3.3 of this Annex for the OBD tests.
 4.1.4. The frequency for product verification performed by the manufacturer shall be based on a risk assessment methodology consistent with the international standard ISO 31000:2009 — Risk Management — Principles and guidelines and at least for Type 1 with a minimum frequency of one verification per 5 000 vehicles produced per family or once per year, whichever comes first.
 4.1.5. 
For the purpose of this regulation the Approval Authority shall perform audits for verifying the manufacturers arrangements and documented control plans at the premises of the manufacturer on a risk assessment methodology consistent with the international standard ISO 31000:2009 — Risk Management — Principles and guidelines and, in all cases, with a minimum frequency of one audit per year.

If the Approval Authority is not satisfied with the auditing procedure of the manufacturer, physical test shall directly be carried out on production vehicles as described in Sections 4.2 to 4.9.
 4.1.6. 
In the case of the manufacturer running the physical tests, the Approval Authority shall witness the tests at the manufacturer's facility.
 4.1.7. The Approval Authority shall report the results of all audit checks and physical tests performed on verifying conformity of the manufacturers and file it for a period of minimum 10 years. These reports should be available for other type approval authorities and the European Commission on request.
 4.1.8. In case of non-conformity Article 30 of Directive 2007/46/EC shall apply.
 4.2.  4.2.1. The Type 1 test shall be carried out on production vehicles of a valid member of the CO2 interpolation family as described in the TA certificate. The limit values against which to check conformity for pollutants are set out in Table 2 of Annex I to Regulation (EC) No 715/2007. As regards CO2 emissions, the limit value shall be the value determined by the manufacturer for the selected vehicle in accordance with the interpolation methodology set out in Sub-Annex 7 of Annex XXI. The interpolation calculation shall be verified by the approval authority.
 4.2.2. A sample of three vehicles shall be selected at random in the family. After selection by the approval authority, the manufacturer shall not undertake any adjustment to the vehicles selected.
 4.2.2.1. The selection shall only include finalised production vehicles which have completed a maximum of 80 km and those vehicles will be referred to as zero km vehicles for the purposes of checking conformity against Type 1 test. The vehicle shall be tested on the appropriate WLTP cycle as described in Annex XXI to this Regulation notwithstanding the requirements for test repetitions, or km of vehicles. The test results shall be the values after all corrections according to this regulation are applied.
 4.2.3. The statistical method for calculating the test criteria is described in Appendix 1.
The production of a family shall be deemed to not conform when a fail decision is reached for one or more of the pollutants and CO2 values, according to the test criteria in Appendix 1.
The production of a family shall be deemed to conform once a pass decision is reached for all the pollutants and CO2 values according to the test criteria in Appendix 1.
When a pass decision has been reached for one pollutant, that decision shall not be changed by any additional tests carried out to reach a decision for the other pollutants and CO2 values.
If a pass decision is not reached for all the pollutants and CO2 values, a test shall be carried out on another vehicle, up to the maximum of 16 vehicles, and the procedure described in Appendix 1 for taking a pass or fail decision shall be repeated (see Figure I.4.2).

Figure I.4.2 4.2.4. At the request of the manufacturer and with the acceptance of the approval authority, tests may be carried out on a vehicle of the family with a maximum of 15 000 km in order to establish measured evolution coefficients EvC for pollutants/CO2 for each family. The running-in procedure shall be conducted by the manufacturer, who shall not to make any adjustments to these vehicles.
 4.2.4.1. In order to establish a measured evolution coefficient with a run-in vehicle the procedure shall be as follows:

((a)) the pollutants/CO2 shall be measured at a mileage of at most 80 km and at ‘x’ km of the first tested vehicle;
((b)) the evolution coefficient (EvC) of the pollutants/CO2 between 80 km and ‘x’ km shall be calculated as:
EvCmeas=values at ‘x’ km∕values at 80 km
((c)) the other vehicles in the interpolation family shall not be run in, but their zero km emissions/EC/CO2 shall be multiplied by the evolution coefficient of the first run-in vehicle. In this case, the values to be taken for testing as in Appendix 1 shall be:

((i)) the values at ‘x’ km for the first vehicle;
((ii)) the values at zero km multiplied by the relevant evolution coefficient for the other vehicles.
 4.2.4.2. All these tests shall be conducted with commercial fuel. However, at the manufacturer’s request, the reference fuels described in Annex IX may be used.
 4.2.4.3. When checking the conformity of production for CO2, as an alternative to the procedure mentioned in Section 4.2.4.1 the vehicle manufacturer may use a fixed evolution coefficient EvC of 0,98 and multiply all values of CO2 measured at zero km by this factor.
 4.2.5 Tests for conformity of production of vehicles fuelled by LPG or NG/biomethane may be performed with a commercial fuel of which the C3/C4 ratio lies between those of the reference fuels in the case of LPG, or of one of the high or low caloric fuels in the case of NG/biomethane. In all cases a fuel analysis shall be presented to the approval authority.
 4.2.6.  4.2.6.1. In the case of a vehicle type fitted with one or more eco-innovations, within the meaning of Article 12 of Regulation (EC) No 443/2009 for M1 vehicles or Article 12 of Regulation (EU) No 510/2011 for N1 vehicles, the conformity of production shall be demonstrated with respect to the eco-innovations, by checking the presence of the correct eco-innovation(s) in question.
 4.3.  4.3.1 Measures to ensure the conformity of production with regard to electric energy consumption (EC) shall be checked on the basis of the type-approval certificate set out in Appendix 4 to this Annex.
 4.3.2.  4.3.2.1. 
The break-off criterion for the conformity of production procedure shall be reached with having finished the first applicable WLTP test cycle.
 4.3.2.2. During this first applicable WLTP test cycle, the DC energy from the REESS(s) shall be measured according to the method described in Appendix 3 of Sub-Annex 8 to Annex XXI of this Regulation and divided by the driven distance in this applicable WLTP test cycle.
 4.3.2.3. The value determined according to paragraph 4.3.2.2 shall be compared to the value determined according to paragraph 1.2 of Appendix 2.
 4.3.2.4. Conformity for EC shall be checked using the statistical procedures described in Section 4.2 and Appendix 1. For the purposes of this conformity check, the terms pollutants/CO2 shall be replaced by EC.
 4.4.  4.4.1. Measures to ensure the conformity of production with regard to CO2 mass emission and electric energy consumption from OVC-HEV shall be checked on the basis of the description in the type-approval certificate set out in Appendix 4 to this Annex.
 4.4.2.  4.4.2.1. The vehicle shall be tested according to the charge-sustaining Type 1 test as described in paragraph 3.2.5. of Sub-Annex 8 to Annex XXI of this Regulation.
 4.4.2.2. During this test, the charge-sustaining CO2 mass emission shall be determined according to Table A8/5 of Sub-Annex 8 to Annex XXI of this Regulation and compared to the charge-sustaining CO2 mass emission according to paragraph 2.3 of Appendix 2.
 4.4.2.3. Conformity for CO2 emissions shall be checked using the statistical procedures described in Section 4.2 and Appendix 1.
 4.4.3.  4.4.3.1. 
The end of the charge-depleting Type 1 test procedure for the conformity of production procedure shall be reached with having finished the first applicable WLTP test cycle.
 4.4.3.2. During this first applicable WLTP test cycle, the DC energy from the REESS(s) shall be measured according to the method described in Appendix 3 of Sub-Annex 8 to Annex XXI of this Regulation and divided by the driven distance in this applicable WLTP test cycle.
 4.4.3.3. The value determined according to paragraph 4.5.3.2. of this Regulation shall be compared to the value determined according to paragraph 2.4. of Appendix 2.
 4.4.1.4. Conformity for EC shall be checked using the statistical procedures described in Section 4.2 and Appendix 1. For the purposes of this conformity check, the terms pollutants/CO2 shall be replaced by EC.
 4.5.  4.5.1. 

4.5.1.1. When the approval authority determines that the quality of production seems unsatisfactory, a vehicle shall be randomly taken from the family and subjected to the tests described in Annex V.
4.5.1.2. The production shall be deemed to conform if this vehicle meets the requirements of the tests described in Annex V.
4.5.1.3. If the vehicle tested does not satisfy the requirements of Section 4.5.1.1, a further random sample of four vehicles shall be taken from the same family and subjected to the tests described in Annex V. The tests may be carried out on vehicles which have completed a maximum of 15 000 km with no modifications.
4.5.1.4. The production shall be deemed to conform if at least three vehicles meet the requirements of the tests described in Annex V.
 4.6.  4.6.1. 

4.6.1.1. When the approval authority determines that the quality of production seems unsatisfactory, a vehicle shall be randomly taken from the family and subjected to the tests described in Annex VI, or at least as in paragraph 7 of Annex 7 of UN Regulation 83.
4.6.1.2. The production shall be deemed to conform if this vehicle meets the requirements of the tests described in Annex VI, or paragraph 7 of Annex 7 of UN Regulation 83 depending on the test performed.
4.6.1.3. If the vehicle tested does not satisfy the requirements of section 4.6.1.1, a further random sample of four vehicles shall be taken from the same family and subjected to the tests described in Annex VI, or at least as in paragraph 7 of Annex 7 of UN Regulation 83. The tests may be carried out on vehicles which have completed a maximum of 15 000 km with no modifications.
4.6.1.4. The production shall be deemed to conform if at least three vehicles meet the requirements of the tests described in Annex VI, or paragraph 7 of Annex 7 of UN Regulation 83 depending on the test performed.
 4.7.  4.7.1. 

4.7.1.1. When the approval authority determines that the quality of production seems unsatisfactory, a vehicle shall be randomly taken from the family and subjected to the tests described in Appendix 1 to Annex XI.
4.7.1.2. The production shall be deemed to conform if this vehicle meets the requirements of the tests described in Appendix 1 to Annex XI.
4.7.1.3. If the vehicle tested does not satisfy the requirements of section 4.7.1.1, a further random sample of four vehicles shall be taken from the same family and subjected to the tests described in Appendix 1 to Annex XI. The tests may be carried out on vehicles which have completed a maximum of 15 000 km with no modifications.
4.7.1.4. The production shall be deemed to conform if at least three vehicles meet the requirements of the tests described in Appendix 1 to Annex XI.

Appendix 1
1. This appendix describes the procedure to be used to verify the production conformity requirements for the Type 1 test for pollutants/CO2, including conformity requirements for PEVs and OVC-HEVs.

2. 
From the number of N tests: x1, x2, … xN, the average Xtests and the variance VAR are to be determined from all N measurements:

Xtests=x1+ x2+ x3+ …+ xN∕N

and

VAR=x1− Xtests2+x2− Xtests2+ …+xN− Xtests2∕N− 1

3. 

((i)) Pass the family if Xtests<A× L− VAR∕L
((ii)) Fail the family if Xtests>A× L−N− 3∕13× VAR∕L
((iii)) Take another measurement if:
A× L− VAR∕L≤Xtests<A× L−N− 3∕13× VAR∕L

For the measurement of pollutants the factor A is set at 1,05 in order to take into account inaccuracies in the measurements.

4. 
xi=CO2test− i∕CO2declared.

xi=ECtest− i∕ECDC, COP

In the case of CO2 and EC the factor A is set at 1.01 and the value for L is set at 1. So in the case of CO2 and EC the criteria are simplified to:


((i)) Pass the family if Xtests<A− VAR
((ii)) Fail the family if Xtests>A−N− 3∕13× VAR
((iii)) Take another measurement if:
A− VAR≤Xtests<A−N− 3∕13× VAR

The A values for pollutants, EC and CO2 will be reviewed and may change according to the available evidence. For this reason the Type Approval Authorities will need to provide the Commission with all relevant data at least for the initial period of 5 years.

Appendix 2
1.  1.1 ECDC− ind,COP=ECDC− L,COP+ Kind×ECDC− H,COP− ECDC− L,COP
where:

ECDC–ind,COPis the electric energy consumption of an individual vehicle for the conformity of production, Wh/km;ECDC–L,COPis the electric energy consumption of vehicle L for the conformity of production, Wh/km;ECDC–H,COPis the electric energy consumption of vehicle H for the conformity of production, Wh/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 1.2 
The following value shall be declared and used for verifying the conformity of production with respect to the electric consumption:
ECDC,COP=ECDC,CD,first WLTC× AFEC
where:

ECDC,COPis the electric energy consumption based on the REESS depletion of the first applicable WLTC test cycle provided for the verification during the conformity of production test procedure;ECDC,CD,first WLTCis the electric energy consumption based on the REESS depletion of the first applicable WLTC test cycle according to paragraph 4.3. of Sub-Annex 8 to Annex XXI, in Wh/km;AFECis the adjustment factor which compensates the difference between the charge-depleting electric energy consumption value declared after having performed the Type 1 test procedure during homologation and the measured test result determined during the conformity of production procedure

and
AFEC=ECWLTC,declaredECWLTC
where

ECWLTC,declaredis the declared electric energy consumption for PEVs according to paragraph 1.1.2.3. of Sub-Annex 6 of Annex XXIECWLTCis the measured electric energy consumption according to paragraph 4.3.4.2. of Sub-Annex 8 to Annex XXI.

2.  2.1 MCO2− ind,CS,COP=MCO2− L,CS,COP+ Kind×MCO2− H,CS,COP− MCO2− L,CS,COP
where:

MCO2–ind,CS,COPis the charge-sustaining CO2 mass emission of an individual vehicle for the conformity of production, g/km;MCO2–L,CS,COPis the charge-sustaining CO2 mass emission of vehicle L for the conformity of production, g/km;MCO2–H,CS,COPis the charge-sustaining CO2 mass emission of vehicle H for the conformity of production, g/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 2.2 ECDC− ind,CD,COP=ECDC− L,CD,COP+ Kind×ECDC− H,CD,COP− ECDC− L,CD,COP
where:

ECDC–ind,CD,COPis the charge-depleting electric energy consumption of an individual vehicle for the conformity of production, Wh/km;ECDC–L,CD,COPis the charge-depleting electric energy consumption of vehicle L for the conformity of production, Wh/km;ECDC–H,CD,COPis the charge-depleting electric energy consumption of vehicle H for the conformity of production, Wh/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 2.3 
The following value shall be declared and used for the verification of the conformity of production with respect to the charge-sustaining CO2 mass emission:
MCO2,CS,COP=MCO2,CS× AFCO2,CS
where:

MCO2,CS,COPis the charge-sustaining CO2 mass emission value of the charge-sustaining Type 1 test provided for the verification during the conformity of production test procedure;MCO2,CSis the charge-sustaining CO2 mass emission of the charge-sustaining Type 1 test according to paragraph 4.1.1. of Annex XXI, g/km;AFCO2,CSis the adjustment factor which compensates the difference between the value declared after having performed the Type 1 test procedure during homologation and the measured test result determined during the conformity of production procedure

And
AFCO2,CS=MCO2,CS,c,declaredMCO2,CS,c,6
where

MCO2,CS,c,declaredis the declared charge-sustaining CO2 mass emission of the charge-sustaining Type 1 test according to step 7 of Table A8/5 of Sub-Annex 8 to Annex XXI.MCO2,CS,c,6is the measured charge-sustaining CO2 mass emission of the charge-sustaining Type 1 test according to step 6 of Table A8/5 of Sub-Annex 8 to Annex XXI.
 2.4 
The following value shall be declared and used for verifying the conformity of production with respect to the charge-depleting electric energy consumption
ECDC,CD,COP=ECDC,CD,first WLTC× AFEC,AC,CD
where:

ECDC,CD,COPis the charge-depleting electric energy consumption based on the REESS depletion of the first applicable WLTC test cycle of the charge-depleting Type 1 test provided for the verification during the conformity of production test procedure;ECDC,CD,first WLTCis the charge-depleting electric energy consumption based on the REESS depletion of the first applicable WLTC test cycle of the charge-depleting Type 1 test according to paragraph 4.3. of Sub-Annex 8 to Annex XXI, Wh/km;AFEC,AC,CDis the adjustment factor for the charge-depleting electric energy consumption which compensates the difference between the value declared after having performed the Type 1 test procedure during homologation and the measured test result determined during the conformity of production procedure

and
AFEC,AC,CD=ECAC,CD,declaredECAC,CD
where

ECAC,CD,declaredis the declared charge-depleting electric energy consumption of the charge-depleting Type 1 test according to paragraph 1.1.2.3. of Sub-Annex 6 to Annex XXI.ECAC,CDis the measured charge-depleting electric energy consumption of the charge-depleting Type 1 test according to paragraph 4.3.1. of Sub-Annex 8 to Annex XXI.

Appendix 3
MODEL 
The following information, if applicable, must be supplied in triplicate and include a list of contents. Any drawings must be supplied in appropriate scale and in sufficient detail on size A4 or on a folder of A4 format. Photographs, if any, must show sufficient detail.

If the systems, components or separate technical units have electronic controls, information concerning their performance must be supplied.


0 GENERAL
0.1. Make (trade name of manufacturer): …
0.2. Type: …
0.2.1. Commercial name(s) (if available): …
0.4. Category of vehicle (c): …
0.8. Name(s) and address(es) of assembly plant(s): …
0.9. Name and address of the manufacturer's representative (if any): …
1 GENERAL CONSTRUCTION CHARACTERISTICS
1.1. Photographs and/or drawings of a representative vehicle/component/separate technical unit (1):
1.3.3. Powered axles (number, position, interconnection): …
2 MASSES AND DIMENSIONS (f) (g) (7)(in kg and mm) (Refer to drawing where applicable)
2.6. Mass in running order (h)
((a)) maximum and minimum for each variant: …
((b)) mass of each version (a matrix must be provided): …
2.8. Technically permissible maximum laden mass stated by the manufacturer (i) (3): …
3 PROPULSION ENERGY CONVERTER (k)
3.1. Manufacturer of the propulsion energy converter(s): …
3.1.1. Manufacturer's code (as marked on the propulsion energy converter or other means of identification): …
3.2. Internal combustion engine
3.2.1.1. Working principle: positive ignition/compression ignition/dual fuel (1)Cycle: four stroke/two stroke/rotary (1)
3.2.1.2. Number and arrangement of cylinders: …
3.2.1.2.1. Bore (1): … mm
3.2.1.2.2. Stroke (1): … mm
3.2.1.2.3. Firing order: …
3.2.1.3. Engine capacity (m): … cm3
3.2.1.4. Volumetric compression ratio (2): …
3.2.1.5. Drawings of combustion chamber, piston crown and, in the case of positive ignition engines, piston rings: …
3.2.1.6. Normal engine idling speed (2): … min–1
3.2.1.6.1. High engine idling speed (2): … min–1
3.2.1.8. Rated engine power (n): … kW at … min–1 (manufacturer's declared value)
3.2.1.9. Maximum permitted engine speed as prescribed by the manufacturer: … min–1
3.2.1.10. Maximum net torque (n): … Nm at … min–1 (manufacturer's declared value)
3.2.2. Fuel
3.2.2.1. Light-duty vehicles: Diesel/Petrol/LPG/NG or Biomethane/Ethanol (E85)/Biodiesel/Hydrogen/H2NG (1) (6)
3.2.2.1.1. RON, unleaded: …
3.2.2.4. Vehicle fuel type: Mono fuel, Bi fuel, Flex fuel (1)
3.2.2.5. Maximum amount of biofuel acceptable in fuel (manufacturer's declared value): … % by volume
3.2.4. Fuel feed
3.2.4.1. By carburettor(s): yes/no (1)
3.2.4.2. By fuel injection (compression ignition or dual fuel only): yes/no (1)
3.2.4.2.1. System description (common rail/unit injectors/distribution pump etc.): …
3.2.4.2.2. Working principle: direct injection/pre-chamber/swirl chamber (1)
3.2.4.2.3. Injection/Delivery pump
3.2.4.2.3.1. Make(s): …
3.2.4.2.3.2. Type(s): …
3.2.4.2.3.3. Maximum fuel delivery (1) (2): … mm3 /stroke or cycle at an engine speed of: … min–1 or, alternatively, a characteristic diagram: … (When boost control is supplied, state the characteristic fuel delivery and boost pressure versus engine speed)
3.2.4.2.4. Engine speed limitation control
3.2.4.2.4.2.1. Speed at which cut-off starts under load: … min–1
3.2.4.2.4.2.2. Maximum no-load speed: … min–1
3.2.4.2.6. Injector(s)
3.2.4.2.6.1. Make(s): …
3.2.4.2.6.2. Type(s): …
3.2.4.2.8. Auxiliary starting aid
3.2.4.2.8.1. Make(s): …
3.2.4.2.8.2. Type(s): …
3.2.4.2.8.3. System description: …
3.2.4.2.9. Electronic controlled injection: yes/no (1)
3.2.4.2.9.1. Make(s): …
3.2.4.2.9.2. Type(s):
3.2.4.2.9.3 Description of the system: …
3.2.4.2.9.3.1. Make and type of the control unit (ECU): …
3.2.4.2.9.3.1.1. Software version of the ECU: …
3.2.4.2.9.3.2. Make and type of the fuel regulator: …
3.2.4.2.9.3.3. Make and type of the air-flow sensor: …
3.2.4.2.9.3.4. Make and type of fuel distributor: …
3.2.4.2.9.3.5. Make and type of the throttle housing: …
3.2.4.2.9.3.6. Make and type or working principle of water temperature sensor: …
3.2.4.2.9.3.7. Make and type or working principle of air temperature sensor: …
3.2.4.2.9.3.8. Make and type or working principle of air pressure sensor: …
3.2.4.3. By fuel injection (positive ignition only): yes/no (1)
3.2.4.3.1. Working principle: intake manifold (single-/multi-point/direct injection (1) /other (specify): …
3.2.4.3.2. Make(s): …
3.2.4.3.3. Type(s): …
3.2.4.3.4. System description (In the case of systems other than continuous injection give equivalent details): …
3.2.4.3.4.1. Make and type of the control unit (ECU): …
3.2.4.3.4.1.1. Software version of the ECU: …
3.2.4.3.4.3. Make and type or working principle of air-flow sensor: …
3.2.4.3.4.8. Make and type of throttle housing: …
3.2.4.3.4.9. Make and type or working principle of water temperature sensor: …
3.2.4.3.4.10. Make and type or working principle of air temperature sensor: …
3.2.4.3.4.11. Make and type or working principle of air pressure sensor: …
3.2.4.3.5. Injectors
3.2.4.3.5.1. Make: …
3.2.4.3.5.2. Type: …
3.2.4.3.7. Cold start system
3.2.4.3.7.1. Operating principle(s): …
3.2.4.3.7.2. Operating limits/settings (1) (2): …
3.2.4.4. Feed pump
3.2.4.4.1. Pressure (2): … kPa or characteristic diagram (2): …
3.2.4.4.2. Make(s): …
3.2.4.4.3. Type(s): …
3.2.5. Electrical system
3.2.5.1. Rated voltage: … V, positive/negative ground (1)
3.2.5.2. Generator
3.2.5.2.1. Type: …
3.2.5.2.2. Nominal output: … VA
3.2.6. Ignition system (spark ignition engines only)
3.2.6.1. Make(s): …
3.2.6.2. Type(s): …
3.2.6.3. Working principle: …
3.2.6.6. Spark plugs
3.2.6.6.1. Make: …
3.2.6.6.2. Type: …
3.2.6.6.3. Gap setting: … mm
3.2.6.7. Ignition coil(s)
3.2.6.7.1. Make: …
3.2.6.7.2. Type: …
3.2.7. Cooling system: liquid/air (1)
3.2.7.1. Nominal setting of the engine temperature control mechanism: …
3.2.7.2. Liquid
3.2.7.2.1. Nature of liquid: …
3.2.7.2.2. Circulating pump(s): yes/no (1)
3.2.7.2.3. Characteristics: … or
3.2.7.2.3.1. Make(s): …
3.2.7.2.3.2. Type(s): …
3.2.7.2.4. Drive ratio(s): …
3.2.7.2.5. Description of the fan and its drive mechanism: …
3.2.7.3. Air
3.2.7.3.1. Fan: yes/no (1)
3.2.7.3.2. Characteristics: … or
3.2.7.3.2.1. Make(s): …
3.2.7.3.2.2. Type(s): …
3.2.7.3.3. Drive ratio(s): …
3.2.8. Intake system
3.2.8.1. Pressure charger: yes/no (1)
3.2.8.1.1. Make(s): …
3.2.8.1.2. Type(s): …
3.2.8.1.3. Description of the system (e.g. maximum charge pressure: … kPa; wastegate if applicable): …
3.2.8.2. Intercooler: yes/no (1)
3.2.8.2.1. Type: air-air/air-water (1)
3.2.8.3. Intake depression at rated engine speed and at 100 % load (compression ignition engines only)
3.2.8.4. Description and drawings of inlet pipes and their accessories (plenum chamber, heating device, additional air intakes, etc.): …
3.2.8.4.1. Intake manifold description (include drawings and/or photos): …
3.2.8.4.2. Air filter, drawings: … or
3.2.8.4.2.1. Make(s): …
3.2.8.4.2.2. Type(s): …
3.2.8.4.3. Intake silencer, drawings: … or
3.2.8.4.3.1. Make(s): …
3.2.8.4.3.2. Type(s): …
3.2.9. Exhaust system
3.2.9.1. Description and/or drawing of the exhaust manifold: …
3.2.9.2. Description and/or drawing of the exhaust system: …
3.2.9.3. Maximum allowable exhaust back pressure at rated engine speed and at 100 % load (compression ignition engines only): … kPa
3.2.10. Minimum cross-sectional areas of inlet and outlet ports: …
3.2.11. Valve timing or equivalent data
3.2.11.1. Maximum lift of valves, angles of opening and closing, or timing details of alternative distribution systems, in relation to dead centres. For variable timing system, minimum and maximum timing: …
3.2.11.2. Reference and/or setting ranges (1): …
3.2.12. Measures taken against air pollution
3.2.12.1. Device for recycling crankcase gases (description and drawings): …
3.2.12.2. Pollution control devices (if not covered by another heading)
3.2.12.2.1. Catalytic converter
3.2.12.2.1.1. Number of catalytic converters and elements (provide the information below for each separate unit): …
3.2.12.2.1.2. Dimensions, shape and volume of the catalytic converter(s): …
3.2.12.2.1.3. Type of catalytic action: …
3.2.12.2.1.4. Total charge of precious metals: …
3.2.12.2.1.5. Relative concentration: …
3.2.12.2.1.6. Substrate (structure and material): …
3.2.12.2.1.7. Cell density: …
3.2.12.2.1.8. Type of casing for the catalytic converter(s): …
3.2.12.2.1.9. Location of the catalytic converter(s) (place and reference distance in the exhaust line): …
3.2.12.2.1.10. Heat shield: yes/no (1)
3.2.12.2.1.11. Normal operating temperature range: … °C
3.2.12.2.1.12. Make of catalytic converter: …
3.2.12.2.1.13. Identifying part number: …
3.2.12.2.2. Sensors
3.2.12.2.2.1. Oxygen sensor: yes/no (1)
3.2.12.2.2.1.1. Make: …
3.2.12.2.2.1.2. Location: …
3.2.12.2.2.1.3. Control range: …
3.2.12.2.2.1.4. Type or working principle: …
3.2.12.2.2.1.5. Identifying part number: …
3.2.12.2.2.2. NOx sensor: yes/no (1)
3.2.12.2.2.2.1. Make: …
3.2.12.2.2.2.2. Type: …
3.2.12.2.2.2.3. Location
3.2.12.2.2.3. Particulate sensor: yes/no (1)
3.2.12.2.2.3.1. Make: …
3.2.12.2.2.3.2. Type: …
3.2.12.2.2.3.3. Location: …
3.2.12.2.3. Air injection: yes/no (1)
3.2.12.2.3.1. Type (pulse air, air pump, etc.): …
3.2.12.2.4. Exhaust gas recirculation (EGR): yes/no (1)
3.2.12.2.4.1. Characteristics (make, type, flow, high pressure/low pressure/combined pressure, etc.): …
3.2.12.2.4.2. Water-cooled system (to be specified for each EGR system e.g. low pressure/high pressure/combined pressure: yes/no (1)
3.2.12.2.5. Evaporative emissions control system (petrol and ethanol engines only): yes/no (1)
3.2.12.2.5.1. Detailed description of the devices: …
3.2.12.2.5.2. Drawing of the evaporative control system: …
3.2.12.2.5.3. Drawing of the carbon canister: …
3.2.12.2.5.4. Mass of dry charcoal: … g
3.2.12.2.5.5. Schematic drawing of the fuel tank with indication of capacity and material (petrol and ethanol engines only): …
3.2.12.2.5.6. Description and schematic of the heat shield between tank and exhaust system: …
3.2.12.2.6. Particulate trap (PT): yes/no (1)
3.2.12.2.6.1. Dimensions, shape and capacity of the particulate trap: …
3.2.12.2.6.2. Design of the particulate trap: …
3.2.12.2.6.3. Location (reference distance in the exhaust line): …
3.2.12.2.6.4. Make of particulate trap: …
3.2.12.2.6.5. Identifying part number: …
3.2.12.2.7 On-board-diagnostic (OBD) system: yes/no (1)
3.2.12.2.7.1. Written description and/or drawing of the MI: …
3.2.12.2.7.2. List and purpose of all components monitored by the OBD system: …
3.2.12.2.7.3. Written description (general working principles) for
3.2.12.2.7.3.1 Positive-ignition engines
3.2.12.2.7.3.1.1. Catalyst monitoring: …
3.2.12.2.7.3.1.2. Misfire detection: …
3.2.12.2.7.3.1.3. Oxygen sensor monitoring: …
3.2.12.2.7.3.1.4. Other components monitored by the OBD system: …
3.2.12.2.7.3.2. Compression-ignition engines: …
3.2.12.2.7.3.2.1. Catalyst monitoring: …
3.2.12.2.7.3.2.2. Particulate trap monitoring: …
3.2.12.2.7.3.2.3. Electronic fuelling system monitoring: …
3.2.12.2.7.3.2.5. Other components monitored by the OBD system: …
3.2.12.2.7.4. Criteria for MI activation (fixed number of driving cycles or statistical method): …
3.2.12.2.7.5. List of all OBD output codes and formats used (with explanation of each): …
3.2.12.2.7.6. The following additional information shall be provided by the vehicle manufacturer for the purposes of enabling the manufacture of OBD-compatible replacement or service parts and diagnostic tools and test equipment.
3.2.12.2.7.6.1. A description of the type and number of the preconditioning cycles used for the original type approval of the vehicle.
3.2.12.2.7.6.2. A description of the type of the OBD demonstration cycle used for the original type-approval of the vehicle for the component monitored by the OBD system.
3.2.12.2.7.6.3. A comprehensive document describing all sensed components with the strategy for fault detection and MI activation (fixed number of driving cycles or statistical method), including a list of relevant secondary sensed parameters for each component monitored by the OBD system. A list of all OBD output codes and format used (with an explanation of each) associated with individual emission related power-train components and individual non-emission related components, where monitoring of the component is used to determine MI activation, including in particular a comprehensive explanation for the data given in service $05 Test ID $21 to FF and the data given in service $06.In the case of vehicle types that use a communication link in accordance with ISO 15765-4 ‘Road vehicles, diagnostics on controller area network (CAN) — Part 4: requirements for emissions-related systems’, a comprehensive explanation for the data given in service $06 Test ID $00 to FF, for each OBD monitor ID supported, shall be provided.
3.2.12.2.7.6.4. The information required above may be defined by completing a table as described below.
3.2.12.2.7.6.4.1. Light-duty vehicles

Component Fault code Monitoring strategy Fault detection criteria MI activation criteria Secondary parameters Preconditioning Demonstration test
Catalyst P0420 Oxygen sensor 1 and sensor 2 signals Difference between sensor 1 and sensor 2 signals- 3rd cycle Engine speed load, A/F mode, catalyst temperature Two type I cycles Type I
3.2.12.2.8. Other system: …
3.2.12.2.8.2. Driver inducement system
3.2.12.2.8.2.3. Type of inducement system: no engine restart after countdown/no start after refuelling/fuel-lockout/performance restriction
3.2.12.2.8.2.4. Description of the inducement system
3.2.12.2.8.2.5. Equivalent to the average driving range of the vehicle with a complete tank of fuel: … km
3.2.12.2.10. Periodically regenerating system: (provide the information below for each separate unit)
3.2.12.2.10.1. Method or system of regeneration, description and/or drawing: …
3.2.12.2.10.2. The number of Type 1 operating cycles, or equivalent engine test bench cycles, between two cycles where regenerative phases occur under the conditions equivalent to Type 1 test (Distance ‘D’ in Figure A6.App1/1 in Appendix 1 to Sub-Annex 6 of Annex XXI to Regulation (EU) 2017/1151 or figure A13/1 in Annex 13 to UN/ECE Regulation 83 (as applicable)): …
3.2.12.2.10.2.1. Applicable Type 1 cycle (indicate the applicable procedure: Annex XXI, Sub-Annex 4 or UN/ECE Regulation 83): …
3.2.12.2.10.3. Description of method employed to determine the number of cycles between two cycles where regenerative phases occur: …
3.2.12.2.10.4. Parameters to determine the level of loading required before regeneration occurs (i.e. temperature, pressure etc.): …
3.2.12.2.10.5. Description of method used to load system in the test procedure described in paragraph 3.1., Annex 13 to UN/ECE Regulation 83: …
3.2.12.2.11. Catalytic converter systems using consumable reagents (provide the information below for each separate unit) yes/no (1)
3.2.12.2.11.1. Type and concentration of reagent needed: …
3.2.12.2.11.2. Normal operational temperature range of reagent: …
3.2.12.2.11.3. International standard: …
3.2.12.2.11.4. Frequency of reagent refill: continuous/maintenance (where appropriate):
3.2.12.2.11.5. Reagent indicator: (description and location)
3.2.12.2.11.6. Reagent tank
3.2.12.2.11.6.1. Capacity: …
3.2.12.2.11.6.2. Heating system: yes/no
3.2.12.2.11.6.2.1. Description or drawing
3.2.12.2.11.7. Reagent control unit: yes/no (1)
3.2.12.2.11.7.1. Make: …
3.2.12.2.11.7.2. Type: …
3.2.12.2.11.8. Reagent injector (make type and location): …
3.2.13. Smoke opacity
3.2.13.1. Location of the absorption coefficient symbol (compression ignition engines only): …
3.2.14. Details of any devices designed to influence fuel economy (if not covered by other items):.
3.2.15. LPG fuelling system: yes/no (1)
3.2.15.1. Type-approval number according to Regulation (EC) No 661/2009 (OJ L 200, 31.7.2009, p. 1): …
3.2.15.2. Electronic engine management control unit for LPG fuelling
3.2.15.2.1. Make(s): …
3.2.15.2.2. Type(s): …
3.2.15.2.3. Emission-related adjustment possibilities: …
3.2.15.3. Further documentation
3.2.15.3.1. Description of the safeguarding of the catalyst at switch-over from petrol to LPG or back: …
3.2.15.3.2. System lay-out (electrical connections, vacuum connections compensation hoses, etc.): …
3.2.15.3.3. Drawing of the symbol: …
3.2.16. NG fuelling system: yes/no (1)
3.2.16.1. Type-approval number according to Regulation (EC) No 661/2009: …
3.2.16.2. Electronic engine management control unit for NG fuelling
3.2.16.2.1. Make(s): …
3.2.16.2.2. Type(s): …
3.2.16.2.3. Emission-related adjustment possibilities: …
3.2.16.3. Further documentation
3.2.16.3.1. Description of the safeguarding of the catalyst at switch-over from petrol to NG or back: …
3.2.16.3.2. System lay-out (electrical connections, vacuum connections compensation hoses, etc.): …
3.2.16.3.3. Drawing of the symbol: …
3.2.18. Hydrogen fuelling system: yes/no (1)
3.2.18.1. EC type-approval number in accordance with Regulation (EC) No 79/2009: …
3.2.18.2. Electronic engine management control unit for hydrogen fuelling
3.2.18.2.1. Make(s): …
3.2.18.2.2. Type(s): …
3.2.18.2.3. Emission-related adjustment possibilities: …
3.2.18.3. Further documentation
3.2.18.3.1. Description of the safeguarding of the catalyst at switch-over from petrol to hydrogen or back: …
3.2.18.3.2. System lay-out (electrical connections, vacuum connections compensation hoses, etc.): …
3.2.18.3.3. Drawing of the symbol: …
3.2.19.4. Further documentation
3.2.19.4.1. Description of the safeguarding of the catalyst at switch-over from petrol to H2NG or back: …
3.2.19.4.2. System lay-out (electrical connections, vacuum connections compensation hoses, etc.): …
3.2.19.4.3. Drawing of the symbol: …
3.2.20. Heat storage information
3.2.20.1. Active heat storage device: yes/no (1)
3.2.20.1.1. Enthalpy: … (J)
3.2.20.2. Insulation materials
3.2.20.2.1. Insulation material: …
3.2.20.2.2. Insulation volume: …
3.2.20.2.3. Insulation weight: …
3.2.20.2.4. Insulation location: …
3.3. Electric machine
3.3.1. Type (winding, excitation): …
3.3.1.2. Operating voltage: … V
3.4. Combinations of propulsion energy converters
3.4.1. Hybrid electric vehicle: yes/no (1)
3.4.2. Category of hybrid electric vehicle: off-vehicle charging/not off-vehicle charging: (1)
3.4.3. Operating mode switch: with/without (1)
3.4.3.1. Selectable modes
3.4.3.1.1. Pure electric: yes/no (1)
3.4.3.1.2. Pure fuel consuming: yes/no (1)
3.4.3.1.3. Hybrid modes: yes/no (1)(if yes, short description): …
3.4.4. Description of the energy storage device: (REESS, capacitor, flywheel/generator)
3.4.4.1. Make(s): …
3.4.4.2. Type(s): …
3.4.4.3. Identification number: …
3.4.4.4. Kind of electrochemical couple: …
3.4.4.5. Energy: … (for REESS: voltage and capacity Ah in 2 h, for capacitor: J, …)
3.4.4.6. Charger: on board/external/without (1)
3.4.5. Electric machine (describe each type of electric machine separately)
3.4.5.1. Make: …
3.4.5.2. Type: …
3.4.5.3. Primary use: traction motor/generator (1)
3.4.5.3.1. When used as traction motor: single-/multimotors (number) (1): …
3.4.5.4. Maximum power: … kW
3.4.5.5. Working principle
3.4.5.5.5.1 Direct current/alternating current/number of phases: …
3.4.5.5.2. Separate excitation/series/compound (1)
3.4.5.5.3. Synchronous/asynchronous (1)
3.4.6. Control unit
3.4.6.1. Make(s): …
3.4.6.2. Type(s): …
3.4.6.3. Identification number: …
3.4.7. Power controller
3.4.7.1. Make: …
3.4.7.2. Type: …
3.4.7.3. Identification number: …
3.4.9. Manufacturer's recommendation for preconditioning: …
3.5. Manufacturer’s declared values for determination of CO2 emissions/fuel consumption/electric consumption/electric range and details of eco-innovations (where applicable) (o)
3.5.7. Manufacturer’s declared values
3.5.7.1. Test vehicle parameters
3.5.7.1.1 Vehicle high
3.5.7.1.1.1. Cycle Energy Demand (J): …
3.5.7.1.1.2. Road load coefficients
3.5.7.1.1.2.1. f0, N: …
3.5.7.1.1.2.2. f1, N/(km/h): …
3.5.7.1.1.2.3. f2, N/(km/h)2: …
3.5.7.1.2. Vehicle Low (if applicable)
3.5.7.1.2.1. Cycle Energy Demand (J)
3.5.7.1.2.2. Road load coefficients
3.5.7.1.2.2.1. f2, N: …
3.5.7.1.2.2.2. f1, N/(km/h): …
3.5.7.1.2.2.3. f2, N/(km/h)2: …
3.5.7.1.3. Vehicle M (if applicable)
3.5.7.1.3.1. Cycle Energy Demand (J)
3.5.7.1.3.2. Road load coefficients
3.5.7.1.3.2.1. f0, N: …
3.5.7.1.3.2.2. f1, N/(km/h): …
3.5.7.1.3.2.3. f2, N/(km/h)2: …
3.5.7.2. Combined CO2 mass emissions
3.5.7.2.1. CO2 mass emission for ICE
3.5.7.2.1.1. Vehicle High: … g/km
3.5.7.2.1.2. Vehicle low (if applicable): … g/km
3.5.7.2.2. Charge Sustaining CO2 mass emission for OVC-HEVs and NOVC-HEVs
3.5.7.2.2.1. Vehicle high: … g/km
3.5.7.2.2.2. Vehicle low (if applicable): … g/km
3.5.7.2.2.3. Vehicle M (if applicable): … g/km
3.5.7.2.3. Charge Depleting CO2 mass emission for OVC-HEVs
3.5.7.2.3.1. Vehicle high: … g/km
3.5.7.2.3.2. Vehicle low (if applicable): … g/km
3.5.7.2.3.3. Vehicle M (if applicable): … g/km
3.5.7.3. Electric range for electrified vehicles
3.5.7.3.1. Pure Electric Range (PER) for PEVs
3.5.7.3.1.1. Vehicle high: … km
3.5.7.3.1.2. Vehicle low (if applicable): … km
3.5.7.3.2. All Electric Range AER for OVC-HEVs
3.5.7.3.2.1. Vehicle high: … km
3.5.7.3.2.2. Vehicle low (if applicable): … km
3.5.7.3.2.3. Vehicle M (if applicable): … km
3.5.7.4. Charge Sustaining fuel consumption (FCCS) for FCHVs
3.5.7.4.1. Vehicle high: … kg/100 km
3.5.7.4.2. Vehicle low (if applicable): … kg/100 km
3.5.7.4.3. Vehicle M (if applicable): … kg/100 km
3.5.7.5. Electric energy consumption for electrified vehicles
3.5.7.5.1. Combined electric energy consumption (ECWLTC) for Pure electric vehicles
3.5.7.5.1.1. Vehicle high: … Wh/km
3.5.7.5.1.2. Vehicle low (if applicable): … Wh/km
3.5.7.5.2. UF-weighted charge-depleting electric consumption ECAC,CD (combined)
3.5.7.5.2.1. Vehicle high: … Wh/km
3.5.7.5.2.2. Vehicle low (if applicable): … Wh/km
3.5.7.5.2.3. Vehicle M (if applicable): … Wh/km
3.5.8. Vehicle fitted with an eco-innovation within the meaning of Article 12 of Regulation (EC) No 443/2009 for M1 vehicles or Article 12 of Regulation (EU) No 510/2011 for N1 vehicles: yes/no (1)
3.5.8.1. Type/Variant/Version of the baseline vehicle as referred to in Article 5 of Regulation (EU) No 725/2011 for M1 vehicles or Article 5 of Regulation (EU) No 427/2014 for N1 vehicles (if applicable): …
3.5.8.2. Existence of interactions between different eco-innovations: yes/no (1)
3.5.8.3. Emissions data related to the use of eco-innovations (repeat the table for each reference fuel tested) (w1)

Decision approving the eco-innovation (w2) Code of the eco-innovation (w3) 1. CO2 emissions of the baseline vehicle (g/km) 2. CO2 emissions of the eco-innovation vehicle (g/km) 3. CO2 emissions of the baseline vehicle under type 1 test-cycle (w4) 4. CO2 emissions of the eco-innovation vehicle under type 1 test-cycle 5. Usage factor (UF), i.e. temporal share of technology usage in normal operation conditions CO2 emissions savings ((1 – 2) – (3 – 4))*5
xxxx/201x       
       
       
Total CO2 emissions saving (g/km) (w5) 
(w) Eco-innovations.
(w1) Expand the table if necessary, using one extra row per eco-innovation.
(w2) Number of the Commission Decision approving the eco-innovation.
(w3) Assigned in the Commission Decision approving the eco-innovation.
(w4) Under agreement of the type-approval authority, if a modelling methodology is applied instead of the type 1 test cycle, this value shall be the one provided by the modelling methodology.
(w5) Sum of the CO2 emissions savings of each individual eco-innovation.
3.6. Temperatures permitted by the manufacturer
3.6.1. Cooling system
3.6.1.1. Liquid coolingMaximum temperature at outlet: … K
3.6.1.2. Air cooling
3.6.1.2.1. Reference point: …
3.6.1.2.2. Maximum temperature at reference point: … K
3.6.2. Maximum outlet temperature of the inlet intercooler: … K
3.6.3. Maximum exhaust temperature at the point in the exhaust pipe(s) adjacent to the outer flange(s) of the exhaust manifold or turbocharger: … K
3.6.4. Fuel temperatureMinimum: … K — maximum: … KFor diesel engines at injection pump inlet, for gas fuelled engines at pressure regulator final stage
3.6.5. Lubricant temperatureMinimum: … K — maximum: … K
3.8. Lubrication system
3.8.1. Description of the system
3.8.1.1. Position of lubricant reservoir: …
3.8.1.2. Feed system (by pump/injection into intake/mixing with fuel, etc.) (1)
3.8.2. Lubricating pump
3.8.2.1. Make(s): …
3.8.2.2. Type(s): …
3.8.3. Mixture with fuel
3.8.3.1. Percentage: …
3.8.4. Oil cooler: yes/no (1)
3.8.4.1. Drawing(s): … or
3.8.4.1.1. Make(s): …
3.8.4.1.2. Type(s): …
4 TRANSMISSION (p)
4.3. Moment of inertia of engine flywheel: …
4.3.1. Additional moment of inertia with no gear engaged: …
4.4. Clutch(es)
4.4.1. Type: …
4.4.2. Maximum torque conversion: …
4.5. Gearbox
4.5.1. Type (manual/automatic/CVT (continuously variable transmission)) (1)
4.5.1.1. Predominant mode: yes/no (1)
4.5.1.2. Best mode (if no predominant mode): …
4.5.1.3. Worst mode (if no predominant mode): …
4.5.1.4. Torque rating: …
4.5.1.5. Number of clutches: …
4.6. Gear ratios

Gear Internal gearbox ratios (ratios of engine to gearbox output shaft revolutions) Final drive ratio(s) (ratio of gearbox output shaft to driven wheel revolutions) Total gear ratios
Maximum for CVT   
1   
2   
3   
…   
Minimum for CVT   
Reverse   
4.7. Maximum vehicle design speed (in km/h) (q): …
6 SUSPENSION
6.6. Tyres and wheels
6.6.1. Tyre/wheel combination(s)
6.6.1.1. Axles
6.6.1.1.1. Axle 1: …
6.6.1.1.1.1. Tyre size designation
6.6.1.1.2. Axle 2: …
6.6.1.1.2.1. Tyre size designation
 etc.
6.6.2. Upper and lower limits of rolling radii
6.6.2.1. Axle 1: …
6.6.2.2. Axle 2: …
6.6.3. Tyre pressure(s) as recommended by the vehicle manufacturer: … kPa
9 BODYWORK
9.1. Type of bodywork using the codes defined in Part C of Annex II of Directive 2007/46/EC: …
9.10.3. Seats
9.10.3.1. Number of seating positions (s): …
16 ACCESS TO VEHICLE REPAIR AND MAINTENANCE INFORMATION
16.1. Address of principal website for access to vehicle repair and maintenance information: …
16.1.1. Date from which it is available (no later than 6 months from the date of type-approval): …
16.2. Terms and conditions of access to website: …
16.3. Format of the vehicle repair and maintenance information accessible through website: …

Appendix to information document
1.  1.1.  1.1.1. Make: …
 1.1.2. Type: …
 1.2.  1.2.1. Make: …
 1.2.2. 
(state percentage of oil in mixture if lubricant and fuel mixed)

2.  2.1. 

VL (if existing) VH
 2.2. Vehicle bodywork type (variant/version)
  2.2. Vehicle bodywork type (variant/version)

 2.3. Road load method used (measurement or calculation by road load family)
  2.3. Road load method used (measurement or calculation by road load family)

 2.4. Road load information from the test
  2.4. Road load information from the test

 2.4.1. Tyres make and type:
  2.4.1. Tyres make and type:

 2.4.2. Tyre dimensions (front/rear):
  2.4.2. Tyre dimensions (front/rear):

 2.4.4. Tyre pressure (front/rear) (kPa):
  2.4.4. Tyre pressure (front/rear) (kPa):

 2.4.5. Tyre rolling resistance (front/rear) (kg/t):
  2.4.5. Tyre rolling resistance (front/rear) (kg/t):

 2.4.6. Vehicle test mass (kg):
  2.4.6. Vehicle test mass (kg):

 2.4.7. Delta Cd.A compared to VH (m2)
 
 2.4.8. Road load coefficient f0, f1, f2
  2.4.8. Road load coefficient f0, f1, f2


Appendix 4
MODEL OF EC TYPE-APPROVAL CERTIFICATE 
Communication concerning the:


— EC type-approval (1),
— extension of EC type-approval (1),
— refusal of EC type-approval (1),
— withdrawal of EC type-approval (1),
— of a type of system/type of a vehicle with regard to a system (1) with regard to Regulation (EC) No 715/2007 (2) and Regulation (EU) 2017/1151 (3)

EC type-approval number: …

Reason for extension: …
 SECTION I  0.1. Make (trade name of manufacturer): …
 0.2. Type: …
 0.2.1. Commercial name(s) (if available): …
 0.3. Means of identification of type if marked on the vehicle (4)
 0.3.1. Location of that marking: …
 0.4. Category of vehicle (5)
 0.5. Name and address of manufacturer: …
 0.8. Name(s) and address(es) of assembly plant(s): …
 0.9. Representative of the manufacturer: …
 SECTION II —  0. Interpolation family identifier as defined in paragraph 5.0 of Annex XXI
 1. Additional information (where applicable): (see addendum)
 2. Technical service responsible for carrying out the tests: …
 3. Date of type 1 test report: …
 4. Number of the type 1 test report: …
 5. Remarks (if any): (see addendum)
 6. Place: …
 7. Date: …
 8. Signature: …


Attachments: Information package (6).

Addendum to EC type-approval certificate No …
Cross references to information in Test Report or Information Document should be avoided when completing the TA certificate.

0. 
1.  1.1. Mass of the vehicle in running order: …
 1.2. Maximum mass: …
 1.3. Reference mass: …
 1.4. Number of seats: …
 1.6. Type of bodywork:
 1.6.1. for M1, M2: saloon, hatchback, station wagon, coupé, convertible, multipurpose vehicle
 1.6.2. for N1, N2: lorry, van
 1.7. Drive wheels: front, rear, 4 × 4
 1.8. Pure electric vehicle: yes/no
 1.9. Hybrid electric vehicle: yes/no
 1.9.1. Category of Hybrid Electric vehicle: Off Vehicle Charging/Not Off Vehicle charging / Fuel Cell
 1.9.2. Operating mode switch: with/without
 1.10. Engine identification:
 1.10.1. Engine displacement:
 1.10.2. Fuel supply system: direct injection/indirect injection
 1.10.3. Fuel recommended by the manufacturer:
 1.10.4.1. Maximum power: kW at min–1
 1.10.4.2. Maximum torque: Nm at min–1
 1.10.5. Pressure charging device: yes/no
 1.10.6. Ignition system: compression ignition/positive ignition
 1.11. Power train (for pure electric vehicle or hybrid electric vehicle)
 1.11.1. Maximum net power: … kW, at: … to … min–1
 1.11.2. Maximum thirty minutes power: … kW
 1.11.3. Maximum net torque: … Nm, at … min–1
 1.12. Traction battery (for pure electric vehicle or hybrid electric vehicle)
 1.12.1. Nominal voltage: V
 1.12.2. Capacity (2 h rate): Ah
 1.13. Transmission: …, …
 1.13.1. Type of gearbox: manual/automatic/variable transmission
 1.13.2. Number of gear ratios:
 1.13.3. 
First gear: … Sixth gear: …
Second gear: … Seventh gear: …
Third gear: … Eighth gear: …
Fourth gear: … Overdrive: …
Fifth gear: …  1.13.4. Final drive ratio:
 1.14. 
Type: radial/bias/…

Dimensions: …

Rolling circumference under load:

Rolling circumference of tyres used for the Type 1 test

2.  2.1. 
Emissions classification: Euro 6

Type 1 test results, where applicable

Type approval number if not parent vehicle: …


Type 1 Result CO(mg/km) THC(mg/km) NMHC(mg/km) NOx(mg/km) THC + NOx(mg/km) PM(mg/km) PN(#.1011/km)
Measured (8) (9)       
Ki (*) (8) (10)     (11)  
Ki (+) (8) (10)     (11)  
Mean value calculated with Ki (M.Ki or M+Ki) (9)     (12)  
DF (+) (8) (10)       
DF (*) (8)(10)       
Final mean value calculated with Ki and DF (13)       
Limit value       

Repeat Test 1 table with the second test results.

Repeat Test 1 table with the third test results.

Repeat Test 1, test 2 (if applicable) and test 3 (if applicable) for Vehicle Low (if applicable), and VM (if applicable)

Dnumber of operating cycles between 2 cycles where regenerative phases occur: …dnumber of operating cycles required for regeneration: …

Applicable Type 1 cycle: (Annex XXI, Sub-Annex 4 or UN/ECE Regulation No 83): …


CO2 Emission (g/km) Combined
ATCT (14 °C) MCO2,Treg 
Type 1 (23 °C) MCO2,23° 
Family correction factor (FCF) 

Difference between engine coolant end temperature and average soak area temperature of the last 3 hours ΔT_ATCT (°C): …

The minimum soaking time tsoak_ATCT (s): …

Location of temperature sensor: …

Type 2: (including data required for roadworthiness testing):


Test CO value(% vol) Lambda (7) Engine speed(min–1) Engine oil temperature(°C)
Low idle test  N/A  
High idle test    

Type 3: …

Type 4: … g/test

Type 5
— Durability test: whole vehicle test/bench ageing test/none
— Deterioration factor DF: calculated/assigned
— Specify the values: …
— Applicable Type 1 cycle (Annex XXI, Sub-Annex 4 or UN/ECE Regulation No 83): …


Type 6 CO (g/km) THC (g/km)
Measured value  
 2.1.1. For bi fuel vehicles, the type 1 table shall be repeated for both fuels. For flex fuel vehicles, when the type 1 test is to be performed on both fuels according to Figure I.2.4 of Annex I, and for vehicles running on LPG or NG/Biomethane, either mono fuel or bi fuel, the table shall be repeated for the different reference gases used in the test, and an additional table shall display the worst results obtained. When applicable, in accordance with section 3.1.4 of Annex 12 to UN/ECE Regulation No 83, it shall be shown if the results are measured or calculated.
 2.1.2. Written description and/or drawing of the MI: …
 2.1.3. List and function of all components monitored by the OBD system: …
 2.1.4. Written description (general working principles) for: …
 2.1.4.1. Misfire detection: …
 2.1.4.2. Catalyst monitoring: …
 2.1.4.3. Oxygen sensor monitoring: …
 2.1.4.4. Other components monitored by the OBD system: …
 2.1.4.5. Catalyst monitoring: …
 2.1.4.6. Particulate trap monitoring: …
 2.1.4.7. Electronic fuelling system actuator monitoring: …
 2.1.4.8. Other components monitored by the OBD system: …
 2.1.5. Criteria for MI activation (fixed number of driving cycles or statistical method): …
 2.1.6. List of all OBD output codes and formats used (with explanation of each): …
 2.2.  2.3.  2.3.1. Original equipment catalytic converter tested to all relevant requirements of this Regulation yes/no
 2.4.  2.4.1. At steady engine speeds: See technical service test report number: …
 2.4.2.  2.4.2.1. Measured value of the absorption coefficient: … m–1
 2.4.2.2. Corrected value of the absorption coefficient: … m–1
 2.4.2.3. Location of the absorption coefficient symbol on the vehicle: …
 2.5.  2.5.1.  2.5.1.1.  2.5.1.1.1. Cycle Energy Demand: … J
 2.5.1.1.2.  2.5.1.1.2.1. f0, N: …
 2.5.1.1.2.2. f1, N/(km/h): …
 2.5.1.1.2.3. f2, N/(km/h)2: …
 2.5.1.1.3. 

CO2 Emission (g/km) Test Low Medium High Extra High Combined
MCO2,p,5 / MCO2,c,5 1     
2     
3     
MCO2,p,H / MCO2,c,H     
 2.5.1.1.4. 

Fuel consumption (l/100 km) or m3/100 km or kg/100 km (1) Low Medium High Extra High Combined
Final values FCp,H / FCc,H     
 2.5.1.2.  2.5.1.2.1. Cycle Energy Demand: … J
 2.5.1.2.2.  2.5.1.2.2.1. f0, N: …
 2.5.1.2.2.2. f1, N/(km/h): …
 2.5.1.2.2.3. f2, N/(km/h)2: …
 2.5.1.2.2. 

CO2 Emission (g/km) Test Low Medium High Extra High Combined
MCO2,p,5 / MCO2,c,5 1     
2     
3     
MCO2,p,L / MCO2,c,L     
 2.5.1.2.3. 

Fuel consumption (l/100 km) or m3/100 km or kg/100 km (1) Low Medium High Extra High Combined
Final values FCp,H / FCc,H     
 2.5.1.3. For vehicles powered by an internal combustion engine only which are equipped with periodically regenerating systems as defined in paragraph 6 of Article 2 of this Regulation, the test results shall be adjusted by the Ki factor as specified in Appendix 1 to Sub-Annex 6 of Annex XXI.
 2.5.1.3.1. 
Dnumber of operating cycles between 2 cycles where regenerative phases occur: …dnumber of operating cycles required for regeneration: …

Applicable Type 1 cycle (Annex XXI, Sub-Annex 4 or UN/ECE Regulation 83): …


 Low Mid High Extra High Combined
Ki (additive / multiplicative) (1)Values for CO2 and fuel consumption (10)     
 2.5.2.  2.5.2.1.  2.5.2.1.1. 
EC (Wh/km) Test City Combined
Calculated EC 1  
2  
3  
Declared value —  2.5.2.1.2. Total time out of tolerance for the conduct of the cycle: … sec
 2.5.2.2. 

PER (km) Test City Combined
Measured Pure Electric Range 1  
2  
3  
Declared value — 
 2.5.3. Externally chargeable (OVC) Hybrid Electric Vehicle:
 2.5.3.1. 

CO2 Emission (g/km) Test Low Medium High Extra High Combined
MCO2,p,5 / MCO2,c,5 1     
2     
3     
MCO2,p,H / MCO2,c,H     


CO2 Emission (g/km) Test Low Medium High Extra High Combined
MCO2,p,5 / MCO2,c,5 1     
2     
3     
MCO2,p,L / MCO2,c,L     


CO2 Emission (g/km) Test Low Medium High Extra High Combined
MCO2,p,5 / MCO2,c,5 1     
2     
3     
MCO2,p,M / MCO2,c,M     
 2.5.3.2. 

CO2 Emission (g/km) Test Combined
MCO2,CD 1 
2 
3 
MCO2,CD,H 


CO2 Emission (g/km) Test Combined
MCO2,CD 1 
2 
3 
MCO2,CD,L 


CO2 Emission (g/km) Test Combined
MCO2,CD 1 
2 
3 
MCO2,CD,M 
 2.5.3.3. CO2 mass emission (weighted, combined):

 Vehicle High: MCO2,weighted … g/km
 Vehicle Low (if applicable): MCO2,weighted … g/km
 Vehicle M (if applicable): MCO2,weighted … g/km
 2.5.3.4. 

Fuel Consumption (l/100 km) Low Medium High Extra High Combined
Final values FCp,H / FCc,H     


Fuel Consumption (l/100 km) Low Medium High Extra High Combined
Final values FCp,L / FCc,L     


Fuel Consumption (l/100 km) Low Medium High Extra High Combined
Final values FCp,M / FCc,M     
 2.5.3.5. 

Fuel consumption (l/100 km) Test Combined
FCCD 1 
2 
3 
FCCD,H 


Fuel consumption (l/100 km) Test Combined
FCCD 1 
2 
3 
FCCD,L 


Fuel consumption (l/100 km) Test Combined
FCCD 1 
2 
3 
FCCD,M 
 2.5.3.6. Fuel consumption (weighted, combined):

 Vehicle High: FCweighted … l/100 km
 Vehicle Low (if applicable): FCweighted … l/100 km
 Vehicle M (if applicable): FCweighted … l/100 km
 2.5.3.7. Ranges:
 2.5.3.7.1. 

AER (km) Test City Combined
AER values 1  
2  
3  
Final values AER  
 2.5.3.7.2. 

EAER (km) City Combined
EAER values  
 2.5.3.7.3. 

RCDA (km) Combined
RCDA values 
 2.5.3.7.4. 

RCDC (km) Test Combined
RCDC values 1 
2 
3 
Final values RCDC 
 2.5.3.8.  2.5.3.8.1. 

EC (Wh/km) Low Medium High Extra High City Combined
Electric consumption values      
 2.5.3.8.2. 

ECAC,CD (Wh/km) Test Combined
ECAC,CD values 1 
2 
3 
Final values ECAC,CD 
 2.5.3.8.3. 

ECAC,weighted (Wh/km) Test Combined
ECAC,weighted values 1 
2 
3 
Final values ECAC,weighted 
 2.6. 

Decision approving the eco-innovation (20) Code of the eco-innovation (21) Type 1/I cycle (22) 1. CO2 emissions of the baseline vehicle (g/km) 2. CO2 emissions of the eco-innovation vehicle (g/km) 3. CO2 emissions of the baseline vehicle under type 1 test-cycle (23) 4. CO2 emissions of the eco-innovation vehicle under type 1 test-cycle 5. Usage factor (UF) i.e. temporal share of technology usage in normal operation conditions CO2 emissions savings((1 - 2) - (3 - 4)) * 5
xxx/201x        
        
        
 Total CO2 emissions saving on NEDC (g/km) (24) 
 Total CO2 emissions saving on WLTP (g/km) (25) 
 2.6.1. General code of the eco-innovation(s): …

3.  3.1. Address of website for access to vehicle repair and maintenance information: …
 3.1.1. Date from which it is available (up to 6 months from the date of type approval): …
 3.2. Terms and conditions of access (i.e. duration of access, price of access on an hourly, daily, monthly, annual and per-transaction basis) to websites referred to in point 3.1): …
 3.3. Format of vehicle repair and maintenance information accessible through website referred to in point 3.1: …
 3.4. Manufacturer’s certificate on access to vehicle repair and maintenance information provided: …

4. 
Maximum engine net power of internal combustion engine, net power and maximum 30 minutes power of electric drive train
 4.1.  4.1.1. Engine speed (min–1) …
 4.1.2. Measured fuel flow (g/h) …
 4.1.3. Measured torque (Nm) …
 4.1.4. Measured power (kW) …
 4.1.5. Barometric pressure (kPa) …
 4.1.6. Water vapour pressure (kPa) …
 4.1.7. Intake air temperature (K) …
 4.1.8. Power correction factor when applied …
 4.1.9. Corrected power (kW) …
 4.1.10. Auxiliary power (kW) …
 4.1.11. Net power (kW) …
 4.1.12. Net torque (Nm) …
 4.1.13. Corrected specific fuel consumption (g/kWh) …
 4.2.  4.2.1.  4.2.2. Maximum net power: … kW, at … min–1
 4.2.3. Maximum net torque: … Nm, at … min–1
 4.2.4. Maximum net torque at zero engine speed: … Nm
 4.2.5. Maximum 30 minutes power: … kW
 4.2.6.  4.2.7. Test DC voltage: … V
 4.2.8. Working principle: …
 4.2.9. Cooling system:
 4.2.10.  4.2.11. 
5.  (2) OJ L 171, 29.6.2007, p. 1.
 (3) OJ L 175, 7.7.2017, p. 1.
 (4) If the means of identification of type contains characters not relevant to describe the vehicle, component or separate technical unit types covered by this information, such characters shall be represented in the documentation by the symbol ‘?’ (e.g. ABC??123??)
 (5) As defined in Annex II, Section A
 (6) As defined in article 3, paragraph 39 of Directive 2007/46/EC
 (8) Where applicable.
 (9) Round to 2 decimal places
 (10) Round to 4 decimal places
 (11) Not applicable
 (12) Mean value calculated by adding mean values (M.Ki) calculated for THC and NOx.
 (13) Round to 1 decimal place more than limit value.
 (20) Number of the Commission Decision approving the eco-innovation.
 (21) Assigned in the Commission Decision approving the eco-innovation.
 (22) Applicable Type 1 cycle: Annex XXI, Sub-Annex 4 or UN/ECE Regulation 83
 (23) If modelling is applied instead of the type 1 test-cycle, this value shall be the one provided by the modelling methodology.
 (24) Sum of the emissions saving of each individual eco-innovation on Type I according to UN/ECE Regulation 83.
 (25) Sum of the emissions saving of each individual eco-innovation on Type 1 according to Annex XXI, Sub-Annex 4 of this regulation

Appendix to the Addendum to the Type Approval Certificate
Transitional period (correlation output)
(Transitional provision):

1.  1.1  1.2.  1.2.1. 

CO2 Emission (g/km) Urban Extra Urban Combined
MCO2,NEDC_H,co2mpas   
 1.3.  1.3.1. 

CO2 Emission (g/km) Urban Extra Urban Combined
MCO2,NEDC_L,co2mpas   

2.  2.1.  2.1.1. 

CO2 Emission (g/km) Urban Extra Urban Combined
MCO2,NEDC_H,test   
 2.2.  2.2.1. 

CO2 Emission (g/km) Urban Extra Urban Combined
MCO2,NEDC_L,test   

3. 

Deviation factors Vehicle High Vehicle Low(if applicable)
De  

Appendix 5
1. The information required in this Appendix shall be provided by the vehicle manufacturer for the purposes of enabling the manufacture of OBD-compatible replacement or service parts and diagnostic tools and test equipment.

2. Upon request, the following information shall be made available to any interested component, diagnostic tools or test equipment manufacturer, on a non-discriminatory basis:

2.1. A description of the type and number of the preconditioning cycles used for the original type-approval of the vehicle;
2.2. A description of the type of the OBD demonstration cycle used for the original type-approval of the vehicle for the component monitored by the OBD system;
2.3. A comprehensive document describing all sensed components with the strategy for fault detection and MI activation (fixed number of driving cycles or statistical method), including a list of relevant secondary sensed parameters for each component monitored by the OBD system and a list of all OBD output codes and format used (with an explanation of each) associated with individual emission-related power-train components and individual non-emission related components, where monitoring of the component is used to determine MI activation. In particular, a comprehensive explanation for the data given in service $ 05 Test ID $ 21 to FF and the data given in service $ 06 shall be provided. In the case of vehicle types that use a communication link in accordance with ISO 15765-4 ‘Road vehicles — Diagnostics on Controller Area Network (CAN) — Part 4: Requirements for emissions-related systems’, a comprehensive explanation for the data given in service $ 06 Test ID $ 00 to FF, for each OBD monitor ID supported, shall be provided.
This information may be provided in the form of a table, as follows:
Component Fault code Monitoring strategy Fault detection criteria MI activation criteria Secondary parameters Preconditioning Demonstration test
Catalyst P0420 Oxygen sensor 1 and 2 signals Difference between sensor 1 and sensor 2 signals 3rd cycle Engine speed, engine load, A/F mode, catalyst temperature e.g. Two Type 1 cycles (as described in Annex III of Regulation (EC) No 692/2008 or in Annex XXI to Regulation (EU) 2017/1151) e.g. Type 1 test (as described in Annex III of Regulation (EC) No 692/2008 or in Annex XXI to Regulation (EU) 2017/1151)

3. 
In order to facilitate the provision of generic diagnostic tools for multi-make repairers, vehicle manufacturers shall make available the information referred to in the points 3.1 to 3.3. through their repair information web-sites. This information shall include all diagnostic tool functions and all the links to repair information and troubleshooting instructions. The access to this information may be subject to the payment of a reasonable fee.
 3.1. 
The following information shall be required indexed against vehicle make, model and variant, or other workable definition such as VIN or vehicle and systems identification:


((a)) Any additional protocol information system necessary to enable complete diagnostics in addition to the standards prescribed in Section 4 of Annex XI, including any additional hardware or software protocol information, parameter identification, transfer functions, ‘keep alive’ requirements, or error conditions;
((b)) Details of how to obtain and interpret all fault codes not in accordance with the standards prescribed in Section 4 of Annex XI:
((c)) A list of all available live data parameters including scaling and access information;
((d)) A list of all available functional tests including device activation or control and the means to implement them;
((e)) Details of how to obtain all component and status information, time stamps, pending DTC and freeze frames;
((f)) Resetting adaptive learning parameters, variant coding and replacement component setup, and customer preferences;
((g)) ECU identification and variant coding;
((h)) Details of how to reset service lights;
((i)) Location of diagnostic connector and connector details;
((j)) Engine code identification.
 3.2. 
The following information shall be required:


((a)) A description of tests to confirm its functionality, at the component or in the harness
((b)) Test procedure including test parameters and component information
((c)) Connection details including minimum and maximum input and output and driving and loading values
((d)) Values expected under certain driving conditions including idling
((e)) Electrical values for the component in its static and dynamic states
((f)) Failure mode values for each of the above scenarios
((g)) Failure mode diagnostic sequences including fault trees and guided diagnostics elimination.
 3.3. 
The following information shall be required:


((a)) ECU and component initialisation (in the event of replacements being fitted)
((b)) Initialisation of new or replacement ECUs where relevant using pass-through (re-) programming techniques.

Appendix 6
1. Section 3 of the EC type-approval number issued according to Article 6(1) shall be composed by the number of the implementing regulatory act or the latest amending regulatory act applicable to the EC type-approval. This number shall be followed by one or more characters reflecting the different categories in accordance with Table 1.

Character Emission standard OBD standard Vehicle category and class Engine Implementation date: new types Implementation date: new vehicles Last date of registration
AA Euro 6c Euro 6-1 M, N1 class I PI, CI   31.8.2018
AB Euro 6c Euro 6-1 N1 class II PI, CI   31.8.2019
AC Euro 6c Euro 6-1 N1 class III, N2 PI, CI   31.8.2019
AD Euro 6c Euro 6-2 M, N1 class I PI, CI  1.9.2018 31.8.2019
AE Euro 6c Euro 6-2 N1 class II PI, CI  1.9.2019 31.8.2020
AF Euro 6c Euro 6-2 N1 class III, N2 PI, CI  1.9.2019 31.8.2020
AG Euro 6d-TEMP Euro 6-2 M, N1 class I PI, CI 1.9.2017 1.9.2019 31.12.2020
AH Euro 6d-TEMP Euro 6-2 N1 class II PI, CI 1.9.2018 1.9.2020 31.12.2021
AI Euro 6d-TEMP Euro 6-2 N1 class III, N2 PI, CI 1.9.2018 1.9.2020 31.12.2021
AJ Euro 6d Euro 6-2 M, N1 class I PI, CI 1.1.2020 1.1.2021 
AK Euro 6d Euro 6-2 N1 class II PI, CI 1.1.2021 1.1.2022 
AL Euro 6d Euro 6-2 N1 class III, N2 PI, CI 1.1.2021 1.1.2022 
AX n.a. n.a. All vehicles Battery full electric 1.9.2009 1.1.2011 
AY n.a. n.a. All vehicles Battery full electric 1.9.2009 1.1.2011 
AZ n.a. n.a. All vehicles using certificates according to point 2.1.1 of Annex I PI, CI 1.9.2009 1.1.2011 
Key:
‘Euro 6-1’ OBD standard = Full Euro 6 OBD requirements but with preliminary OBD threshold limits as defined in point 2.3.4 of Annex XI and partially relaxed IUPR;
‘Euro 6-2’ OBD standard = Full Euro 6 OBD requirements but with final OBD threshold limits as defined in point 2.3.3 of Annex XI;
‘Euro 6c’ emissions standard = RDE testing for monitoring only (no NTE emission limits applied), otherwise full Euro 6 emission requirements;
‘Euro 6d-TEMP’ emissions standard = RDE testing against temporary conformity factors, otherwise full Euro 6 emission requirements;"
‘Euro 6d’ emissions standard = RDE testing against final conformity factors, otherwise full Euro 6 emission requirements.

2.  2.1 
e13× 715∕2007× xxx∕2016AJ× 0017× 00
 2.2 
e19× 715∕2007× xyz∕2018AH× 0001× 00

Appendix 7

Appendix 8a
The Test Report is the report issued by the technical service responsible for conducting the tests according this regulation.
A separate Test Report shall be prepared for each interpolation family, as defined in paragraph 5.6. of Annex XXI
The following information, if applicable, is the minimum data required for the Type 1 test and Ambient Temperature Correction Test (ATCT) test.

APPLICANT 
Manufacturer 
SUBJECT Determination of a vehicle road load
Object submitted to tests
 Make : 
 Type : 
CONCLUSION The object submitted to tests complies with the requirements mentioned in the subject.
PLACE, DD/MM/YYYY

— The references to the relevant sections of Regulation (EU) No 692/2008 are highlighted in grey
— (ATCT) means only for Ambient Temperature Correction Test (ATCT) test report
— (not ATCT) means not relevant for ATCT test report
— No reference to ATCT means needed for both ‘type 1’ test report and ATCT test report

If there are several options (references), the one tested should be described in the test report

If there are not, a single reference to the information document at the start of the test report may be sufficient.

Every Technical Service is free to include some additional information


((a)) Specific to positive ignition engine
((b)) Specific to compression ignition engine

1.  1.1. 

Vehicle numbers : Prototype number and VIN
CategoryAnnex I Appendix 3 & 4 §0.4 : 
Number of seats including the driverAnnex I Appendix 3 §9.10.3 & Appendix 4 addendum §1.4 : 
BodyworkAnnex I Appendix 3 §9.1 & Appendix 4 addendum §1.6 : 
Drive wheelsAnnex I Appendix 3 §1.3.3 & Appendix 4 addendum §1.7 : 
 1.1.1. 

Powertrain architecture : internal combustion, hybrid, electric or fuel cell
 1.1.2. 
For more than one ICE, please repeat the paragraph


Make : 
TypeAnnex I Appendix 3 §3.1.1 & Appendix 4 addendum §1.10 : 
Working principleAnnex I Appendix 3 §3.2.1.1 : two/four stroke
Cylinders number and arrangementAnnex I Appendix 3 §3.2.1.2 : 
Engine capacity (cm3)Annex I Appendix 3 §3.2.1.3 & Appendix 4 addendum §1.10.1 : 
Engine idling speed (min–1)Annex I Appendix 3 §3.2.1.6 :  +–
High engine idling speed (min–1 (a)Annex I Appendix 3 §3.2.1.6.1 :  +–
nmin drive(rpm) : 
Rated engine powerAnnex I Appendix 3 §3.2.1.8 & Appendix 4 addendum §1.10.4 :  kW at  rpm
Maximum net torqueAnnex I Appendix 3 §3.2.1.10 & Appendix 4 addendum §1.11.3 :  Nm at  rpm
Engine lubricant : Manufacturer specification (If there are several references in the information document)
Cooling systemAnnex I Appendix 3 §3.2.7 : Type: air/water/oil
Insulation : material, amount, location, volume and weight
 1.1.3. 
For more than one test fuel, please repeat the paragraph


Make : 
TypeAnnex I Appendix 3 §3.2.2.1 & Appendix 4 addendum §1.10.3 : petrol E10 - Diesel B7 – LPG – NG - …
Density at 15°CAnnex IX : 
Sulphur contentsub annex 3 of annex XXI : Only for Diesel B7 and Petrol E10
Annex IX : 
Batch number : 
Willans factors (for ICE) for CO2 emission (gCO2/km) : 
 1.1.4. 
For more than one fuel feed system, please repeat the paragraph


Direct injection : yes/no or description
Vehicle fuel typeAnnex I Appendix 3 §3.2.2.4 : Monofuel / bifuel / flex fuel
Control unit
Part referenceAnnex I Appendix 3 § 3.2.4.2.9.3.1 : same as information document
Software testedAnnex I Appendix 3 § 3.2.4.2.9.3.1.1 : read via scantool, for example
Air flowmeterAnnex I Appendix 3 § 3.2.4.2.9.3.3 : 
Throttle bodyAnnex I Appendix 3 § 3.2.4.2.9.3.5 : 
Pressure sensorAnnex I Appendix 3 § 3.2.4.3.4.11 : 
Injection pumpAnnex I Appendix 3 § 3.2.4.2.3 : 
Injector(s)Annex I Appendix 3 § 3.2.4.2.6 : 
 1.1.5. 
For more than one intake system, please repeat the paragraph


Pressure chargerAnnex I Appendix 3 § 3.2.8.1 : Yes/nomake & type (1)
IntercoolerAnnex I Appendix 3 § 3.2.8.2 : yes/notype (air/air – air/water) (1)
Air filter (element) (1)Annex I Appendix 3 § 3.2.8.4.2 : make & type
Intake silencer (1)Annex I Appendix 3 § 3.2.8.4.3 : make & type
 1.1.6. 
For more than one, please repeat the paragraph


First catalytic converterAnnex I Appendix 3 §3.2.12.2.1.12.& 3.2.12.2.1.13 : make & reference (1)principle: three way / oxidising / NOx trap /Selective Catalyst Reduction
Second catalytic converter : make & reference (1)principle: three way / oxidising / NOx trap /Selective Catalyst Reduction
Particulate trapAnnex I Appendix 3 §3.2.12.2.6 : with/without/not applicablemake & reference (1)
Reference and position of oxygen sensor(s)Annex I Appendix 3 §3.2.12.2.2 : before catalyst / after catalyst
Air injectionAnnex I Appendix 3 §3.2.12.2.3 : with/without/not applicable
EGRAnnex I Appendix 3 §3.2.12.2.4 : with/without/not applicablecooled/non-cooled
Evaporative emission control systemAnnex I Appendix 3 §3.2.12.2.5 : with/without/not applicable
Reference and position of NOx sensor(s) : Before/ after
General description (1)Annex I Appendix 3 §3.2.9.2 : 
 1.1.7. 
For more than one Heat Storage System, please repeat the paragraph


Heat storage device : yes/no
Heat capacity (enthalpy stored J) : 
Time for heat release (s) : 
 1.1.8. 
For more than one Transmission, please repeat the paragraph


GearboxAnnex I Appendix 3 § 4.5.1& Appendix 4 addendum §1.13.1 : manual / automatic / continuous variation
Gear shifting procedure
Predominant mode : yes/nonormal / drive / eco/…
Best case mode for CO2 emissions and fuel consumption (if applicable) : 
Worst case mode for CO2 emissions and fuel consumption (if applicable) : 
Control unit : 
Gearbox lubricant : Manufacturer’s specification (If there are several references in the information document)
TyresAnnex I Appendix 3 §6.6 & Appendix 4 addendum §1.14
Make : 
Type : 
Dimensions front/rearAnnex I Appendix 3 §6.6.1 : 
Circumference (m) : 
Tyre pressure (kPa)Annex I Appendix 3 §6.6.3 : 

Transmission ratios (R.T.), primary ratios (R.P.) and (vehicle speed (km/h)) / (engine speed (1 000 (min – 1)) (V1 000) for each of the gearbox ratios (R.B.).

Annex I Appendix 3 §4.6 & Appendix 4 addendum §1.13.3


R.B. R.P. R.T. V1 000
1st 1/1  
2nd 1/1  
3rd 1/1  
4th 1/1  
5th 1/1  
…   
   
 1.1.9. 
For more than one Electric Machine, please repeat the paragraph


Make : 
Type : 
Peak Power : 
 1.1.10. 
For more than one Traction REESS, please repeat the paragraph


Make : 
Type : 
Capacity : 
Nominal Voltage : 
 1.1.12. 
For more than one Fuel Cell, please repeat the paragraph


Make : 
Type : 
Maximum Power : 
Nominal Voltage : 
 1.1.13. 
Can be more than one PE (propulsion converter, low voltage system or charger)


Make : 
Type : 
Power : 
 1.2.  1.2.1. 

Test mass of VH (kg) : 
 1.2.2. 

f0 (N) : 
f1 (N/(km/h)) : 
f2 (N/(km/h)2) : 
f2_TReg (N/(km/h)2) : (ATCT)
Cycle energy demand (Ws)Annex XXI §3.5.6 : 
Road load test report reference : 
 1.2.3. 

Cycle (without downscaling) : Class 1 / 2 / 3a / 3b
Ratio of rated power to mass in running order (PMR)(W/kg) : (if applicable)
Capped speed process used during measurementAnnex XXI sub-annex 1 §9 : yes/no
Maximum speed of the vehicleAnnex I appendix 3 §4.7 : 
Downscaling (if applicable) : yes/no
Downscaling factor fdsc : 
Cycle distance (m) : 
Constant speed (in the case of the shortened test procedure) : if applicable
 1.2.4. 

Gear shifting : Average gear for v ≥ 1 km/h, rounded to four places of decimal
 1.3.  1.3.1. 

Test mass of VL(kg) : 
 1.3.2. 

f0 (N) : 
f1 (N/(km/h)) : 
f2 (N/(km/h)2) : 
Cycle energy demand (Ws) : 
Δ(CD×Af)LH : 
Road load test report reference : 
 1.3.3. 

Cycle (without downscaling) : Class 1 / 2 / 3a / 3b
Ratio of rated power to mass in running order (PMR)(W/kg) : (if applicable)
Capped speed process used during measurementAnnex XXI sub-annex 1 §9 : yes/no
Maximum speed of the vehicleAnnex I appendix 3 §4.7 : 
Downscaling (if applicable) : yes/no
Downscaling factor fdsc : 
Cycle distance (m) : 
Constant speed (in the case of the shortened test procedure) : if applicable
 1.3.4. 

Gear shifting : Average gear for v ≥ 1 km/h, rounded to four places of decimal
 1.4.  1.4.1. 

Test mass of VL(kg) : 
 1.4.2. 

f0 (N) : 
f1 (N/(km/h)) : 
f2 (N/(km/h) 2) : 
Cycle energy demand (Ws) : 
Δ(CD×Af)LH : 
 1.4.3. 

Cycle (without downscaling) : Class 1 / 2 / 3a / 3b
Ratio of rated power to mass in running order (PMR)(W/kg) : (if applicable)
Capped speed process used during measurementAnnex XXI sub-annex 1 §9 : yes/no
Maximum speed of the vehicleAnnex I appendix 3 §4.7 : 
Downscaling (if applicable) : yes/no
Downscaling factor fdsc : 
Cycle distance (m) : 
Constant speed (in the case of the shortened test procedure) : if applicable
 1.4.4. 

Gear shifting : Average gear for v ≥ 1 km/h, rounded to four places of decimal

2.  2.1. 

Method of chassis dyno setting : Fixed run / iterative / alternative with its own warmup cycle
Dynamometer operation modeAnn XXI sub-ann6 §1.2.4.2.2.  yes/no
Coastdown modeAnn XXI sub-ann4 §4.2.1.8.5 : yes/no
Additional preconditioning : yes/nodescription
Deterioration factors : assigned / tested
 2.1.1. 

Date of tests : (day/month/year)
Place of the test : 
Height of the lower edge above ground of cooling fan (cm) : 
Lateral position of fan centre (if modified as request by the manufacturer) : in the vehicle centre-line/…
Distance from the front of the vehicle (cm) : 
 2.1.1.1.  2.1.1.1.1. 
For each operating modes tested the paragraphs below has to be repeated (predominant mode or best case mode and worst case, mode if applicable)


Pollutants CO(mg/km) THC (a)(mg/km) NMHC (a)(mg/km) NOx(mg/km) THC+NOx (b)(mg/km) Particulate Matter(mg/km) Particle Number(#.1011/km)
Measured values       
Regeneration factors (Ki)(2)Additive       
Regeneration factors (Ki)(2)Multiplicative       
Deterioration factors (DF) additive       
Deterioration factors (DF) multiplicative       
Final values       
Limit values       


 (2) See Ki family report(s)
 : 
Type 1/I performed for Ki determination : Annex XXI, Sub-Annex 4 or UN/ECE Regulation No 83


Same paragraph

Same paragraph
 2.1.1.1.2. 
Pollutant emission limits have to be fulfilled and the following paragraph has to be repeated for each driven test cycle.


Pollutants CO(mg/km) THC (a)(mg/km) NMHC (a)(mg/km) NOx(mg/km) THC+NOx (b)(mg/km) Particulate Matter(mg/km) Particle Number(#.1011/km)
Measured single cycle values       
Limit single cycle values       

Same paragraph

Same paragraph
 2.1.1.1.3. 

Pollutants CO(mg/km) THC (a)(mg/km) NMHC (a)(mg/km) NOx(mg/km) THC+NOx (b)(mg/km) Particulate Matter(mg/km) Particle Number(#.1011/km)
Calculated values       
 2.1.1.2.  2.1.1.2.1. 
For each operating mode tested the paragraphs below have to be repeated (predominant mode or best case mode and worst case, mode if applicable)


CO2 Emission Low Medium High Extra High Combined
Measured value MCO2,p,1 / MCO2,c,2     
RCB correction coefficient:     
MCO2,p,3 / MCO2,c,3     
Regeneration factors (Ki)Additive     
Regeneration factors (Ki)Multiplicative     
MCO2,c,4 — 
AFKi= MCO2,c,3 / MCO2,c,4 — 
MCO2,p,4 / MCO2,c,4     —
ATCT correction (FCF) 
Temporary values MCO2,p,5 / MCO2,c,5     
Declared value — — — — 
dCO21 * declared value — — — — 



Same paragraph with dCO22

Same paragraph


CO2 Emission (g/km) Low Medium High Extra High Combined
Averaging MCO2,p,6/ MCO2,c,6     
Alignment MCO2,p,7 / MCO2,c,7     
Final values MCO2,p,H / MCO2,c,H     
 2.1.1.2.2. 

CO2 Emission (g/km) Low Medium High Extra High Combined
Measured value MCO2,p,1 / MCO2,c,2     
RCB correction coefficient (5)     
MCO2,p,3 / MCO2,c,3     


CO2 Emission (g/km) Combined
ATCT (14°C) MCO2,Treg 
Type 1 (23°C) MCO2,23° 
Family correction factor (FCF) 
 2.1.1.2.3. 

CO2 Mass Emission (g/km) Combined
Calculated value MCO2,CD 
Declared value 
dCO21 

Same paragraph with dCO22

Same paragraph


CO2 Mass Emission (g/km) Combined
Averaging MCO2,CD 
Final value MCO2,CD 
 2.1.1.2.4. 

CO2 Mass Emission (g/km) Combined
Calculated value MCO2,weighted 
 2.1.1.3  2.1.1.3.1. 
For each operating modes tested the paragraphs below has to be repeated (predominant mode or best case mode and worst case, mode if applicable)


Consumption (l/100 km) Low Medium High Extra High Combined
Final values FCp,H / FCc,H     

 2.1.1.3.2. 

Fuel Consumption (l/100 km) Combined
Calculated value FCCD 

Same paragraph

Same paragraph


Fuel Consumption (l/100 km) Combined
Averaging FCCD 
Final value FCCD 
 2.1.1.3.3. 

Fuel Consumption (l/100 km) Combined
Calculated value FCweighted 
 2.1.1.3.4. 
For each operating modes tested the paragraphs below has to be repeated (predominant mode or best case mode and worst case, mode if applicable)


Consumption (kg/100 km) Low Medium High Extra High Combined
Measured values     
RCB correction coefficient     
Final values FCp/ FCc     
 2.1.1.4.  2.1.1.4.1.  2.1.1.4.1.1. 

AER (km) City Combined
Measured/Calculated values AER  
Declared value — 

Same paragraph

Same paragraph


AER (km) City Combined
Averaging AER (if applicable)  
Final values AER  
 2.1.1.4.1.2. 

EAER (km) City Combined
Final values EAER  
 2.1.1.4.1.3. 

RCDA (km) Combined
Final value RCDA 
 2.1.1.4.1.4. 

RCDC (km) Combined
Final value RCDC 
Index Number of the transition cycle 
REEC of confirmation-cycle (%) 

Same paragraph

Same paragraph
 2.1.1.4.2. 

PER (km) City Combined
Calculated values PER  
Declared value — 

Same paragraph

Same paragraph


PER (km) City Combined
Averaging PER  
Final values PER  
 2.1.1.5.  2.1.1.5.1.  2.1.1.5.1.1. 

EC (Wh/km) Low Medium High Extra High City Combined
Final values EC      
 2.1.1.5.1.2. 

ECAC,CD (Wh/km) Combined
Calculated value ECAC,CD 

Same paragraph

Same paragraph


ECAC,CD (Wh/km) Combined
Averaging ECAC,CD 
Final value 
 2.1.1.5.1.3. 

ECAC,weighted (Wh) Combined
Calculated value ECAC,weighted 

Same paragraph

Same paragraph


ECAC,weighted (Wh/km) Combined
Averaging ECAC,weighted 
Final value 
 2.1.1.5.2. 

EC (Wh/km) City Combined
Calculated values EC  
Declared value — 

Same paragraph

Same paragraph


EC (Wh/km) Low Medium High Extra High City Combined
Averaging EC      
Final values EC      
 2.1.2. 
Repeat § 2.1.1.
 2.1.3. 
Repeat § 2.1.1.
 2.1.4. 

Pollutants CO(mg/km) THC (a)(mg/km) NMHC (a)(mg/km) NOx(mg/km) THC+NOx (b)(mg/km) PM(mg/km) PN(#.1011/km)
Highest values       

 2.2. 
Included the emissions data required for roadworthiness testing


Test CO (% vol) Lambda Engine speed (min–1) Oil temperature (°C)
Idle  —  
High idle    
 2.3. 
Emission of crankcase gases into the atmosphere: none
 2.4. 

See report(s) : 
 2.5. 

See durability family report(s) : 
Type 1/I cycle for criteria emissions testing : Annex XXI, Sub-Annex 4 or UN/ECE Regulation No 83

 2.6. 

RDE family number : MSxxxx
See family report(s) : 
 2.7. 

Date of tests : (day/month/year)
Place of tests : 
Method of setting of the chassis dyno : coast down (road load reference)
Inertia mass (kg) : 
If deviation from the vehicle of type 1 : 
Tyres : 
Make : 
Type : 
Dimensions front/rear : 
Circumference (m) : 
Tyre pressure (kPa) : 


Pollutants CO(g/km) HC(g/km)
Test 1  
2  
3  
Average  
Limit  
 2.8. 

See family report(s) : 
 2.9.  2.9.1. 

See family report(s) : 
 2.9.2. 

Measured absorption value (m –1) : 
Corrected absorption value (m –1) : 
 2.10. 

See family report(s) : 
 2.11. 

Engine coolant temperature at the end of soaking time (°C)sub-ann6a §3.9.2 : 
Average soak area temperature over the 3 last hours (°C)sub-ann6a §3.9.2 : 
Difference between engine coolant end temperature and average soak area temperature of the last 3 hours ΔT_ATCT (°C)sub-ann6a §3.9.3 : 
The minimum soaking time tsoak_ATCT (s)sub-ann6a §3.9.1 : 
Location of temperature sensorsub-ann6a §3.9.5 : 

Annex of the test report (not applicable ATCT test and PEV),
 1 — 
Reference of input file: …
 2 — Co2mpas output:
 3 — NEDC test results (if applicable):

Appendix 8b
The following information, if applicable, is the minimum data required for the road load determination test.

APPLICANT 
Manufacturer 
SUBJECT Determination of a vehicle road load
Object submitted to tests
 Make : 
 Type : 
CONCLUSION The object submitted to tests complies with the requirements mentioned in the subject.
PLACE, DD/MM/YYYY
1. 

Make(s) concerned : 
Type(s) concerned : 
Commercial description : 
Maximal speed (km/h) : 
Powered axle(s) : 

2.  2.1. 
If no interpolation: the worst-case vehicle (regarding energy demand) has to be described
 2.1.1. 

Make : 
Type : 
Version : 
Cycle energy demand over a complete WLTC Class 3 cycle independent of the vehicle class : 
Deviation from production series : 
Mileage : 
 2.1.2. 

Make : 
Type : 
Version : 
Cycle energy demand over a complete WLTC Class 3 cycle independent of the vehicle class : (4 to 35% based on HR)
Deviation from production series : 
Mileage : 
 2.1.3. 

Make : 
Type : 
Version : 
Cycle energy demand over a complete WLTC : 
Deviation from production series : 
Mileage : 
 2.2.  2.2.1. 

Test mass (kg) : 
Average mass mav(kg) : (average before and after the test)
Rotational mass mr (kg) : 3% of (MRO+25kg) or measured
Weight distribution
Front : 
Rear : 
 2.2.2. 
Repeat §2.2.1. with VL data
 2.2.3. 

Test mass (kg) : 
Average mass mav(kg) : (average before and after the test)
Technically permissible maximum laden mass (≥3 000kg) : 
Estimated arithmetic average of the mass of optional equipment : 
Weight distribution
Front : 
Rear : 
 2.3.  2.3.1. 

Size designation : front/rear if different
Make : front/rear if different
Type : front/rear if different
Rolling resistance (kgf/1 000 kg
Front : 
Rear : 
Front pressure (kPa) : 
Rear pressure (kPa) : 
 2.3.2. 
Repeat §2.3.1. with VL data
 2.3.3. 
Repeat §2.3.1. with the representative vehicle data
 2.4.  2.4.1. 

Type : AA/AB/AC/AD/AE/AF BA/BB/BC/BD
Version : 
Aerodynamic devices  
Movable aerodynamic body parts : y/n and list if applicable
Installed aerodynamic options list : 
 2.4.2. 
Repeat §2.4.1. with VL data


Delta (Cd*Af)LH compared to VH : 
 2.4.3. 

Body shape description : Square box (if no representative body shape for a complete vehicle can be determined)

Repeat §2.4.1. with the representative vehicle data if applicable


Frontal area Afr : 
 2.5.  2.5.1. 

Engine code : 
Transmission type : manual, automatic, CVT
Transmission model(manufacturer's codes) : (torque rating and no of clutches → to be included in info doc)
Covered transmission models(manufacturer's codes) : 
Engine rotational speed divided by vehicle speed : 
Gear Gear ratio N/V ratio
1st 1/.. 
2nd 1.. 
3rd 1/.. 
4th 1/.. 
5th 1/.. 
6th 1/.. 
..  
..  
Electric machine(s) coupled in position N : n.a. (no electric machine or no coastdown mode)
Type and number of electric machines : construction type: asynchronous/ synchronous…
Type of coolant : air, liquid,…
 2.5.2. 
Repeat §2.5.1. with VL data
 2.6.  2.6.1. 

Dates of tests : dd/mm/yyyy


Method of the test : coastdown (Annex XXI, Sub Annex 4, §4.3.)or torque meter method (Annex XXI, Sub Annex 4, §4.4.)
Facility (name / location / track's reference) : 
Coastdown mode : y/n
Wheel alignment : Toe and camber values
Maximum reference speed (km/h)Annex XXI, Sub Annex 4, §4.2.4.1.2. : 
Anemometry : stationaryor on board: influence of anemometry (cd*A) and if it was corrected.
Number of split(s) : 
Wind : average, peaks and direction in conjunction with direction of the test track
Air pressure : 
Temperature (mean value) : 
Wind correction : y/n
Tyre pressure adjustment : y/n
Raw results : Torque method:c0=c1=c2=Coastdown method:f0f1f2
Final results  Torque method:c0=c1=c2=andf0=f1=f2=Coastdown method:f0=f1=f2=

Or


Facility (name/location/dynamometer's reference) : 
Qualification of the facilities : Report reference and date
Dynamometer
Type of dynamometer : flat belt or chassis dynamometer
Method : stabilised speeds or deceleration method
Warm up : warm-up by dyno or by driving the vehicle
Correction of the roller curve(Annex XXI, Sub Annex 4, §6.6.3.) : (for chassis dynamometer, if applicable)
Method of chassis dynamometer setting : Fixed run / iterative / alternative with its own warmup cycle
Measured aerodynamic drag coefficient multiplied by the frontal area : 
Velocity (km/h) Cd*A (m2)
… …
… …
Result : f0=f1=f2=

Or


Method of the test : coastdown (Annex XXI, Sub Annex 4, §4.3)or torque meter method (Annex XXI, Sub Annex 4, §4.4)
Facility (name/location/track's reference) : 
Coastdown mode : y/n
Wheel alignment : Toe and camber values
Maximum reference speed (km/h)Annex XXI, Sub Annex 4, §4.2.4.1.2. : 
Anemometry : stationaryor on board: influence of anemometry (cd*A) and if it was corrected.
Number of split(s) : 
Wind : average, peaks and direction in conjunction with direction of the test track
Air pressure : 
Temperature (mean value) : 
Wind correction : y/n
Tyre pressure adjustment : y/n
Raw results : Torque method:c0r=c1r=c2r=Coastdown method:f0rf1rf2r
Final results  Torque method:c0r=c1r=c2r=andf0r=f1r=f2r=Coastdown method:f0r=f1r=f2r=
 2.6.2. 
Repeat §2.6.1. with VL data

Appendix 8c

The ‘test sheet’ shall include the test data that are recorded, but not included in any test report.
The test sheet(s) shall be retained by the technical service or the manufacturer for at least 10 years.
The following information, if applicable, is the minimum data required for test sheets.

Adjustable wheel alignment parametersAnnex XXI, Sub-Annex 4, § 4.2.1.8.3. : 
The coefficients, c0, c1 and c2, : c0=
c1=
c2=
The coastdown times measured on the chassis dynamometerAnnex XXI, Sub-Annex 4, §4.4.4. : 
Vehicle speed (km/h) Coastdown time (s)
125-115 
115-105 
105-95 
95-85 
85-75 
75-65 
65-55 
55-45 
45-35 
35-25 
25-15 
15-05 
Additional weight may be placed on or in the vehicle to eliminate tyre slippageAnnex XXI, Sub-Annex 4, §7.1.1.1.1. : weight (kg)on/in the vehicle
The coastdown times after performing the vehicle coast down procedure according paragraph 4.3.1.3 of Annex XXI, Sub-Annex 4Annex XXI, Sub-Annex 4, §8.2.4.2. : 
Vehicle speed (km/h) Coastdown time (s)
125-115 
115-105 
105-95 
95-85 
85-75 
75-65 
65-55 
55-45 
45-35 
35-25 
25-15 
15-05 

Indicated concentrations (a); (b), (c), (d), and the concentration when the NOx analyser is in the NO mode so that the calibration gas does not pass through the converter

Annex XXI, Sub-Annex 5, §5.5
 : (a)=(b)=(c)=(d)=Concentration in NO mode=

Annex XXI, Sub-Annex 6, §1.2.6.4.6. and 1.2.12.6.
 : 
For manual shift transmission vehicle, MT vehicle that cannot follow the cycle trace:  
The deviations from the driving cycle :
Annex XXI, Sub-Annex 6, §1.2.6.5.1
Drive trace indices:  
The following indices shall be calculated according to SAE J2951(Revised JAN2014):  
(a) EREnergy Rating :
(b) DRDistance Rating :
(c) EEREnergy Economy Rating :
(d) ASCRAbsolute Speed Change Rating :
(e) IWRInertial Work Rating :
(f) RMSSERoot Mean Squared Speed Error :
Annex XXI, Sub-Annex 6, §1.2.8.5. and 7.  
Particulate sample filter weighing  
Filter before the test :
Filter after the test :
Reference filter :
Annex XXI, Sub-Annex 6, §1.2.10.1.2 and 1.2.14.3.1 

Annex XXI, Sub-Annex 6, §1.2.14.2.8
 : 
Regeneration factor determination  
The number of cycles D between two WLTCs where regeneration events occur :
The number of cycles over which emission measurements are made n :
The mass emissions measurement M′sij for each compound i over each cycle j :
Annex XXI, Sub-Annex 6, Appendix 1, §2.1.3. 
Regeneration factor determination  
The number of applicable test cycles d measured for complete regeneration : 
Annex XXI, Sub-Annex 6, Appendix 1, § 2.2.6. 
Regeneration factor determination  
Msi :
Mpi :
Ki :
Annex XXI, Sub-Annex 6, Appendix 1, §3.1.1
ATCT  
The air temperature and humidity of the test cell measured at the vehicle cooling fan outlet at a minimum frequency of 1 Hz. : Temperature set point = Treg
Annex XXI, Sub-Annex 6a, §3.2.1.1. Actual temperature value± 3 °C at the start of the test± 5 °C during the test
The temperature of the soak area measured continuously at a minimum frequency of 1 Hz. : Temperature set point = Treg
Annex XXI, Sub-Annex 6a, §3.2.2.1. Actual temperature value± 3 °C at the start of the test± 5 °C during the test

Annex XXI, Sub-Annex 6a, §3.6.2.
 : ≤ 10 minutes
The time between the end of the Type 1 test and the cool down procedure : ≤ 10 minutes
The measured soaking time, and shall be recorded in all relevant test sheets.Annex XXI, Sub-Annex 6a, §3.9.2. : time between the measurement of the end temperature and the end of the Type 1 test at 23 °C
ANNEX II
1.  1.1. This Annex sets out the tailpipe emissions and OBD (inclusive IUPRM) in-service conformity requirements for vehicles type approved to this Regulation.

2. 
The in-service conformity requirements shall be those specified in paragraph 9 and Appendices 3, 4 and 5 of UN/ECE Regulation No 83 with exceptions described in the following sections.
 2.1. 
The audit of in-service conformity by the approval authority shall be conducted on the basis of any relevant information that the manufacturer has, under the same procedures as those for the conformity of production defined in Article 12(1) and (2) of Directive 2007/46/EC and in points 1 and 2 of Annex X to that Directive. If information is provided to the approval authority from any approval authority or Member State surveillance testing, it shall complement the in-service monitoring reports supplied by the manufacturer.
 2.2. 
'…Vehicles of small series productions with less than 1 000 vehicles per OBD family are exempted from minimum IUPR requirements as well as the requirement to demonstrate these to the approval authority.'
 2.3. References to ‘Contracting Parties’ shall be understood as references to ‘Member States’.
 2.4. 
The vehicle shall belong to a vehicle type that is type-approved under this Regulation and covered by a certificate of conformity in accordance with Directive 2007/46/EC. It shall be registered and have been used in the Union.
 2.5. The reference in paragraph 2.2. of Appendix 3 to UN/ECE Regulation No 83 to the ‘1958 Agreement’ shall be understood as reference to Directive 2007/46/EC.
 2.6. 
The lead content and sulphur content of a fuel sample from the vehicle tank shall meet the applicable standards laid down in Directive 2009/30/EC of the European Parliament and of the Council and there shall be no evidence of mis-fuelling. Checks may be done in the tailpipe.
 2.7. Reference in paragraph 4.1. of Appendix 3 to UN/ECE Regulation No 83 to ‘emissions tests in accordance with Annex 4a’ shall be understood as being to ‘emissions tests conducted in accordance with Annex XXI to this Regulation’.
 2.8. Reference in paragraph 4.1. of Appendix 3 to UN/ECE Regulation No 83 to ‘paragraph 6.3. of Annex 4a’ shall be understood as being to ‘paragraph 1.2.6. of Sub-Annex 6 to Annex XXI to this Regulation’.
 2.9. Reference in paragraph 4.4. of Appendix 3 to UN/ECE Regulation No 83 to ‘the 1958 Agreement’ shall be understood as reference to ‘Article 13(1) or (2) of Directive 2007/46/EC’.
 2.10. In paragraph 3.2.1., paragraph 4.2. and footnotes 1 and 2 of Appendix 4 to UN/ECE Regulation No 83, the reference to the limit values given in Table 1 of paragraph 5.3.1.4. shall be understood as reference to Table 1 of Annex I to Regulation (EC) No 715/2007.

ANNEX III

[Reserved]

ANNEX IIIA
1.  1.1. 
This Annex describes the procedure to verify the Real Driving Emissions (RDE) performance of light passenger and commercial vehicles.
 1.2. 

1.2.1. ‘Accuracy’ means the deviation between a measured or calculated value and a traceable reference value.
1.2.2. ‘Analyser’ means any measurement device that is not part of the vehicle but installed to determine the concentration or the amount of gaseous or particle pollutants.
1.2.3. ‘Axis intercept’ of a linear regression (a0) means:
a0=y–−a1×x–
where:
a1is the slope of the regression linex–is the mean value of the reference parametery–is the mean value of the parameter to be verified
1.2.4. ‘Calibration’ means the process of setting the response of an analyser, flow-measuring instrument, sensor, or signal so that its output agrees with one or multiple reference signals.
1.2.5. ‘Coefficient of determination’ (r2) means:
r2=1−∑ni= 1yi− a0−a1× xi2∑ni= 1yi−y–2
where:
a0is the axis intercept of the linear regression linea1is the slope of the linear regression linexiis the measured reference valueyiis the measured value of the parameter to be verifiedy–is the mean value of the parameter to be verifiednis the number of values
1.2.6. ‘Cross-correlation coefficient’ (r) means:
r=∑n− 1i= 1xi−x–×yi−y–∑n− 1i= 1xi−x–2×∑n− 1i= 1yi−y–2
where:
xiis the measured reference valueyiis the measured value of the parameter to be verifiedx–is the mean reference valuey–is the mean value of the parameter to be verifiednis the number of values
1.2.7. ‘Delay time’ means the time from the gas flow switching (t0) until the response reaches 10 per cent (t10) of the final reading.
1.2.8. ‘Engine control unit (ECU) signals or data’ means any vehicle information and signal recorded from the vehicle network using the protocols specified in point 3.4.5.of Appendix 1.
1.2.9. ‘Engine control unit’ means the electronic unit that controls various actuators to ensure the optimal performance of the powertrain.
1.2.10. ‘Emissions’ also referred to as ‘components’, ‘pollutant components’ or ‘pollutant emissions’ means the regulated gaseous or particle constituents of the exhaust.
1.2.11. ‘Exhaust’, also referred to as exhaust gas, means the total of all gaseous and particulate components emitted at the exhaust outlet or tailpipe as the result of fuel combustion within the vehicle’s internal combustion engine.
1.2.12. ‘Exhaust emissions’ means the emissions of particles, characterized as particulate matter and particle number, and of gaseous components at the tailpipe of a vehicle.
1.2.13. ‘Full scale’ means the full range of an analyser, flow-measuring instrument or sensor as specified by the equipment manufacturer. If a sub-range of the analyser, flow-measuring instrument or sensor is used for measurements, full scale shall be understood as the maximum reading.
1.2.14. ‘Hydrocarbon response factor’ of a particular hydrocarbon species means the ratio between the reading of a FID and the concentration of the hydrocarbon species under consideration in the reference gas cylinder, expressed as ppmC1.
1.2.15. ‘Major maintenance’ means the adjustment, repair or replacement of an analyser, flow-measuring instrument or sensor that could affect the accuracy of measurements.
1.2.16. ‘Noise’ means two times the root mean square of ten standard deviations, each calculated from the zero responses measured at a constant recording frequency of at least 1.0 Hz during a period of 30 seconds.
1.2.17. ‘Non-methane hydrocarbons’ (NMHC) means the total hydrocarbons (THC) excluding methane (CH4).
1.2.18. ‘Particle number’ (PN) means as the total number of solid particles emitted from the vehicle exhaust as defined by the measurement procedure provided for by this Regulation for assessing compliance with the respective Euro 6 emission limit defined in Table 2 of Annex I to Regulation 715/2007.
1.2.19. ‘Precision’ means 2.5 times the standard deviation of 10 repetitive responses to a given traceable standard value.
1.2.20. ‘Reading’ means the numerical value displayed by an analyser, flow-measuring instrument, sensor or any other measurement devise applied in the context of vehicle emission measurements.
1.2.21. ‘Response time’ (t90) means the sum of the delay time and the rise time.
1.2.22. ‘Rise time’ means the time between the 10 per cent and 90 per cent response (t90 – t10) of the final reading.
1.2.23. ‘Root mean square’ (xrms) means the square root of the arithmetic mean of the squares of values and defined as:
xrms=1nx21+ x22+ …+ x2n
where:
xis the measured or calculated valuenis the number of values
1.2.24. ‘Sensor’ means any measurement device that is not part of the vehicle itself but installed to determine parameters other than the concentration of gaseous and particle pollutants and the exhaust mass flow.
1.2.25. ‘Span’ means the calibration of an analyser, flow-measuring instrument, or sensor so that it gives an accurate response to a standard that matches as closely as possible the maximum value expected to occur during the actual emissions test.
1.2.26. ‘Span response’ means the mean response to a span signal over a time interval of at least 30 seconds.
1.2.27. ‘Span response drift’ means the difference between the mean response to a span signal and the actual span signal that is measured at a defined time period after an analyser, flow-measuring instrument or sensor was accurately spanned.
1.2.28. ‘Slope’ of a linear regression (a1) means:
a1=∑ni= 1yi−y–×xi−x–∑ni= 1xi−x–2
where:
x–is the mean value of the reference parametery–is the mean value of the parameter to be verifiedxiis the actual value of the reference parameteryiis the actual value of the parameter to be verifiednis the number of values
1.2.29. ‘Standard error of estimate’ (SEE) means:
SEE=1xmax×∑ni= 1yi− ý2n− 2
where:
ýis the estimated value of the parameter to be verifiedyiis the actual value of the parameter to be verifiedxmaxis the maximum actual value of the reference parameternis the number of values
1.2.30. ‘Total hydrocarbons’ (THC) means the sum of all volatile compounds measurable by a flame ionization detector (FID).
1.2.31. ‘Traceable’ means the ability to relate a measurement or reading through an unbroken chain of comparisons to a known and commonly agreed standard.
1.2.32. ‘Transformation time’ means the time difference between a change of concentration or flow (t0) at the reference point and a system response of 50 per cent of the final reading (t50).
1.2.33. ‘Type of analyser’, also referred to as ‘analyser type’ means a group of analysers produced by the same manufacturer that apply an identical principle to determine the concentration of one specific gaseous component or the number of particles.
1.2.34. ‘Type of exhaust mass flow meter’ means a group of exhaust mass flow meters produced by the same manufacturer that share a similar tube inner diameter and function on an identical principle to determine the mass flow rate of the exhaust gas.
1.2.35. ‘Validation’ means the process of evaluating the correct installation and functionality of a Portable Emissions Measurement System and the correctness of exhaust mass flow rate measurements as obtained from one or multiple non-traceable exhaust mass flow meters or as calculated from sensors or ECU signals.
1.2.36. ‘Verification’ means the process of evaluating whether the measured or calculated output of an analyser, flow-measuring instrument, sensor or signal agrees with a reference signal within one or more predetermined thresholds for acceptance.
1.2.37. ‘Zero’ means the calibration of an analyser, flow-measuring instrument or sensor so that it gives an accurate response to a zero signal.
1.2.38. ‘Zero response’ means the mean response to a zero signal over a time interval of at least 30 seconds.
1.2.39. ‘Zero response drift’ means the difference between the mean response to a zero signal and the actual zero signal that is measured over a defined time period after an analyser, flow-measuring instrument or sensor has been accurately zero calibrated.
 1.3. 
Abbreviations refer generically to both the singular and the plural forms of abbreviated terms.

CH4MethaneCLDChemiLuminescence DetectorCOCarbon MonoxideCO2Carbon DioxideCVSConstant Volume SamplerDCTDual Clutch TransmissionECUEngine Control UnitEFMExhaust mass Flow MeterFIDFlame Ionisation DetectorFSfull scaleGPSGlobal Positioning SystemH2OWaterHCHydroCarbonsHCLDHeated ChemiLuminescence DetectorHEVHybrid Electric VehicleICEInternal Combustion EngineIDidentification number or codeLPGLiquid Petroleum GasMAWMoving Average Windowmaxmaximum valueN2NitrogenNDIRNon-Dispersive InfraRead analyserNDUVNon-Dispersive UltraViolet analyserNEDCNew European Driving CycleNGNatural GasNMCNon-Methane CutterNMC-FIDNon-Methane Cutter in combination with a Flame-Ionisation DetectorNMHCNon-Methane HydroCarbonsNONitrogen MonoxideNo.numberNO2Nitrogen DioxideNOXNitrogen OxidesNTENot-to-exceedO2OxygenOBDOn-Board DiagnosticsPEMSPortable Emissions Measurement SystemPHEVPlug-in Hybrid Electric VehiclePNparticle numberRDEReal Driving EmissionsRPARelative Positive AccelerationSCRSelective Catalytic ReductionSEEStandard Error of EstimateTHCTotal HydroCarbonsUN/ECEUnited Nations Economic Commission for EuropeVINVehicle Identification NumberWLTCWorldwide harmonized Light vehicles Test CycleWWH-OBDWorldWide Harmonised On-Board Diagnostics

2.  2.1 
Throughout the normal life of a vehicle type approved according to Regulation (EC) No 715/2007, its emissions determined in accordance with the requirements of this Annex and emitted at any possible RDE test performed in accordance with the requirements of this Annex, shall not be higher than the following pollutant-specific not-to-exceed (NTE) values:
NTEpollutant=CFpollutant× TFp1,…, pn× EURO-6
where EURO-6 is the applicable Euro 6 emission limit laid down in Table 2 of Annex I to Regulation (EC) No 715/2007.
 2.1.1 
The conformity factor CFpollutant for the respective pollutant is specified as follows:


Pollutant Mass of oxides of nitrogen (NOx) Number of particles (PN) Mass of carbon monoxide (CO) Mass of total hydrocarbons (THC) Combined mass of total hydrocarbons and oxides of nitrogen (THC + NOx)
CFpollutant 1 + margin with margin = 0,5 to be determined — — —

 2.1.2 
By way of exception to the provisions of point 2.1.1, during a period of 5 years and 4 months following the dates specified in Article 10(4) and (5) of Regulation (EC) 715/2007 and upon request of the manufacturer, the following temporary conformity factors may apply:


Pollutant Mass of oxides of nitrogen (NOx) Number of particles (PN) Mass of carbon monoxide (CO) Mass of total hydrocarbons (THC) Combined mass of total hydrocarbons and oxides of nitrogen (THC + NOx)
CFpollutant 2,1 to be determined — — —


The application of temporary conformity factors shall be recorded in the certificate of conformity of the vehicle.
 2.1.3 
The transfer function TF(p1, …, pn) referred to in point 2.1 is set to 1 for the entire range of parameters pi (i = 1, …, n).

If the transfer function TF(p1, …, pn) is amended, this shall be done in a manner which is not detrimental to the environmental impact and the effectiveness of the RDE test procedures. In particular the following condition shall hold:
∫TFp1,…,pn× Qp1,…,pn dp=∫Qp1,…,pn dp
Where:


— dp represents the integral over the entire space of the parameters pi(i = 1, …, n)
— Q(p1, …, pn), is the probability density of an event corresponding to the parameters pi(i= 1, …, n) in real driving The manufacturer shall confirm compliance with point 2.1 by completing the certificate set out in Appendix 9.
 2.2. The RDE tests required by this Annex at type approval and during the lifetime of a vehicle provide a presumption of conformity with the requirement set out in point 2.1. The presumed conformity may be reassessed by additional RDE tests.
 2.3. Member States shall ensure that vehicles can be tested with PEMS on public roads in accordance with the procedures under their own national law, while respecting local road traffic legislation and safety requirements.
 2.4. Manufacturers shall ensure that vehicles can be tested with PEMS by an independent party on public roads, e.g. by making available suitable adapters for exhaust pipes, granting access to ECU signals and making the necessary administrative arrangements. If the respective PEMS test is not required by this Regulation the manufacturer may charge a reasonable fee as set out in Article 7(1) of Regulation (EC) No 715/2007.

3.  3.1. The following requirements apply to PEMS tests referred to in Article 3(10), second sub-paragraph.
 3.1.0. The requirements of point 2.1 shall be fulfilled for the urban part and the complete PEMS trip. Upon the choice of the manufacturer the conditions of at least one of the two points below shall be fulfilled:

3.1.0.1. Mgas,d,t ≤ NTEpollutant and Mgas,d,u ≤ NTEpollutant with the definitions of point 2.1 of this Annex and points 6.1 and 6.3 of Appendix 5 and the setting gas = pollutant.
3.1.0.2. Mw,gas,d ≤ NTEpollutant and Mw,gas,d,u ≤ NTEpollutant with the definitions of point 2.1 of this Annex and point 3.9 of Appendix 6 and the setting gas = pollutant.
 3.1.1. For type approval, the exhaust mass flow shall be determined by measurement equipment functioning independently from the vehicle and no vehicle ECU data shall be used in this respect. Outside the type approval context, alternative methods to determine the exhaust mass flow can be used according to Appendix 2, Section 7.2.
 3.1.2. If the approval authority is not satisfied with the data quality check and validation results of a PEMS test conducted according to Appendices 1 and 4, the approval authority may consider the test to be void. In such case, the test data and the reasons for voiding the test shall be recorded by the approval authority.
 3.1.3.  3.1.3.1. A technical report prepared by the manufacturer in accordance with Appendix 8 shall be made available to the approval authority.
 3.1.3.2. 

3.1.3.2.1. By entering the vehicle type approval number and the information on type, variant and version as defined in sections 0.10 and 0.2 of the vehicle's EC certificate of conformity provided by Annex IX of Directive (EC) 2007/46, the unique identification number of a PEMS test family to which a given vehicle emission type belongs, as set out in point 5.2 of Appendix 7.
3.1.3.2.2. By entering the unique identification number of a PEMS test family:

— the full information as required by point 5.1 of Appendix 7,
— the lists described in points 5.3 and 5.4 of Appendix 7;
— the results of the PEMS tests as set out in points 6.3 of Appendix 5 and 3.9 of Appendix 6 for all vehicle emission types in the list described in point 5.4 of Appendix 7.
 3.1.3.3. Upon request, without costs and within 30 days, the manufacturer shall make available the technical report referred to in point 3.1.3.1 to any interested party.
 3.1.3.4. Upon request, the type approval authority shall make available the information listed under points 3.1.3.1 and 3.1.3.2 within 30 days of receiving the request. The type approval authority may charge a reasonable and proportionate fee, which does not discourage an inquirer with a justified interest from requesting the respective information or exceed the internal costs of the authority for making the requested information available.

4.  4.1. The RDE performance shall be demonstrated by testing vehicles on the road operated over their normal driving patterns, conditions and payloads. The RDE test shall be representative for vehicles operated on their real driving routes, with their normal load.
 4.2. The manufacturer shall demonstrate to the approval authority that the chosen vehicle, driving patterns, conditions and payloads are representative for the vehicle family. The payload and altitude requirements, as specified in points 5.1 and 5.2, shall be used ex-ante to determine whether the conditions are acceptable for RDE testing.
 4.3. The approval authority shall propose a test trip in urban, rural and motorway environments meeting the requirements of point 6. For the purpose of trip selection, the definition of urban, rural and motorway operation shall be based on a topographic map.
 4.4. If for a vehicle the collection of ECU data influences the vehicle's emissions or performance the entire PEMS test family to which the vehicle belongs as defined in Appendix 7 shall be considered as non-compliant. Such functionality shall be considered as a ‘defeat device’ as defined in Article 3(10) of Regulation (EC) 715/2007.

5.  5.1.  5.1.1. The vehicle's basic payload shall comprise the driver, a witness of the test (if applicable) and the test equipment, including the mounting and the power supply devices.
 5.1.2. For the purpose of testing some artificial payload may be added as long as the total mass of the basic and artificial payload does not exceed 90% of the sum of the ‘mass of the passengers’ and the ‘pay-mass’ defined in points 19 and 21 of Article 2 of Commission Regulation (EU) No 1230/2012.
 5.2.  5.2.1. The test shall be conducted under ambient conditions laid down in this section. The ambient conditions become ‘extended’ when at least one of the temperature and altitude conditions is extended.
 5.2.2. Moderate altitude conditions: Altitude lower or equal to 700 meters above sea level.
 5.2.3. Extended altitude conditions: Altitude higher than 700 meters above sea level and lower or equal to 1300 meters above sea level.
 5.2.4. Moderate temperature conditions: Greater than or equal to 273 K (0 °C) and lower than or equal to 303 K (30 °C)
 5.2.5. Extended temperature conditions: Greater than or equal to 266 K (– 7 °C) and lower than 273 K (0 °C) or greater than 303 K (30 °C) and lower than or equal to 308 K (35 °C)
 5.2.6. By way of derogation from the provisions of points 5.2.4 and 5.2.5 the lower temperature for moderate conditions shall be greater or equal to 276 K (3 °C) and the lower temperature for extended conditions shall be greater or equal to 271K (– 2 °C) between the start of the application of binding NTE emission limits as defined in section 2.1 and until five years after the dates given in paragraphs 4 and 5 of Article 10 of Regulation (EC) No 715/2007.
 5.3. Not applicable.
 5.4. 
The dynamic conditions encompass the effect of road grade, head wind and driving dynamics (accelerations, decelerations) and auxiliary systems upon energy consumption and emissions of the test vehicle. The verification of the normality of dynamic conditions shall be done after the test is completed, using the recorded PEMS data. This verification shall be conducted in 2 steps:


5.4.1. The overall excess or insufficiency of driving dynamics during the trip shall be checked using the methods described in Appendix 7a to this Annex.
5.4.2. If the trip results as valid following the verifications according to point 5.4.1, the methods for verifying the normality of the test conditions as laid down in Appendices 5 and 6 to this Annex must be applied. Each method includes a reference for test conditions, ranges around the reference and the minimum coverage requirements to achieve a valid test.
 5.5.  5.5.1. 
The air conditioning system or other auxiliary devices shall be operated in a way which corresponds to their possible use by a consumer at real driving on the road.
 5.5.2.  5.5.2.1. ‘Periodically regenerating systems’ shall be understood according to the definition in Article 2(6).
 5.5.2.2. If periodic regeneration occurs during a test, the test may be voided and repeated once at the request of the manufacturer.
 5.5.2.3. The manufacturer may ensure the completion of the regeneration and precondition the vehicle appropriately prior to the second test.
 5.5.2.4. If regeneration occurs during the repetition of the RDE test, pollutants emitted during the repeated test shall be included in the emissions evaluation.

6.  6.1. The shares of urban, rural and motorway driving, classified by instantaneous speed as described in points 6.3 to 6.5, shall be expressed as a percentage of the total trip distance.
 6.2. The trip sequence shall consist of urban driving followed by rural and motorway driving according to the shares specified in point 6.6. The urban, rural and motorway operation shall be run continuously. Rural operation may be interrupted by short periods of urban operation when driving through urban areas. Motorway operation may be interrupted by short periods of urban or rural operation, e.g., when passing toll stations or sections of road work. If another testing order is justified for practical reasons, the order of urban, rural and motorway operation may be altered, after obtaining approval from the approval authority.
 6.3. Urban operation is characterised by vehicle speeds lower than or equal to 60 km/h.
 6.4. Rural operation is characterised by vehicle speeds higher than 60 and lower than or equal to 90 km/h.
 6.5. Motorway operation is characterised by speeds above 90 km/h.
 6.6. The trip shall consist of approximately 34 % per cent urban, 33 % per cent rural and 33 % per cent motorway driving classified by speed as described in points 6.3 to 6.5 above. ‘Approximately’ shall mean the interval of ±10 per cent points around the stated percentages. The urban driving shall however never be less than 29% of the total trip distance.
 6.7. The vehicle velocity shall normally not exceed 145 km/h. This maximum speed may be exceeded by a tolerance of 15 km/h for not more than 3 % of the time duration of the motorway driving. Local speed limits remain in force during a PEMS test, notwithstanding other legal consequences. Violations of local speed limits per se do not invalidate the results of a PEMS test.
 6.8. The average speed (including stops) of the urban driving part of the trip should be between 15 and 40 km/h. Stop periods, defined as vehicle speed of less than 1 km/h, shall account for 6 to 30 % of the time duration of urban operation. Urban operation shall contain several stop periods of 10s or longer. If a stop period lasts more the 180 s, the emission events during the 180 s following such an excessively long stop period shall be excluded from the emissions evaluation.
 6.9. The speed range of the motorway driving shall properly cover a range between 90 and at least 110 km/h. The vehicle's velocity shall be above 100 km/h for at least 5 minutes.
 6.10. The trip duration shall be between 90 and 120 minutes.
 6.11. The start and the end point shall not differ in their elevation above sea level by more than 100 m. In addition, the proportional cumulative positive altitude gain shall be less than 1 200 m/100km) and be determined according to Appendix 7b.
 6.12. The minimum distance of each, the urban, rural and motorway operation shall be 16 km.

7.  7.1. The trip shall be selected in such a way that the testing is uninterrupted and the data continuously recorded to reach the minimum test duration defined in point 6.10.
 7.2. Electrical power shall be supplied to the PEMS by an external power supply unit and not from a source that draws its energy either directly or indirectly from the engine of the test vehicle.
 7.3. The installation of the PEMS equipment shall be done in a way to influence the vehicle emissions or performance or both to the minimum extent possible. Care should be exercised to minimize the mass of the installed equipment and potential aerodynamic modifications of the test vehicle. The vehicle payload shall be in accordance with point 5.1.
 7.4. RDE tests shall be conducted on working days as defined for the Union in Council Regulation (EEC, Euratom) No 1182/71
 7.5. RDE tests shall be conducted on paved roads and streets (e.g. off road operation is not permitted).
 7.6. Prolonged idling shall be avoided after the first ignition of the combustion engine at the beginning of the emissions test. If the engine stalls during the test, it may be restarted, but the sampling shall not be interrupted.

8.  8.1. The fuel, lubricant and reagent (if applicable) used for RDE testing shall be within the specifications issued by the manufacturer for vehicle operation by the customer.
 8.2. Samples of fuel, lubricant and reagent (if applicable) shall be taken and kept for at least 1 year.

9.  9.1. The test shall be conducted in accordance with Appendix 1 of this Annex.
 9.2. The trip shall fulfil the requirements set out in points 4 to 8.
 9.3. It shall not be permitted to combine data of different trips or to modify or remove data from a trip with exception of provisions for long stops as described in 6.8.
 9.4. After establishing the validity of a trip according to Point 9.2 emission results shall be calculated using the methods laid down in Appendices 5 and 6 of this Annex.
 9.5. If during a particular time interval the ambient conditions are extended in accordance with point 5.2, the pollutant emissions during this particular time interval, calculated according to Appendix 4, shall be divided by a value of 1,6 before being evaluated for compliance with the requirements of this Annex. This provision does not apply to carbon dioxide emissions.
 9.6. The cold start is defined in accordance with point 4 of Appendix 4 of this Annex. Until specific requirements for emissions at cold start are applied, the latter shall be recorded but excluded from the emissions evaluation.

Appendix 1
1. 
This Appendix describes the test procedure to determine exhaust emissions from light passenger and commercial vehicles using a Portable Emissions Measurement System.

2. 
≤smaller or equal#number#/m3number per cubic metre%per cent°Cdegree centigradeggrammeg/sgramme per secondhhourHzhertzKkelvinkgkilogrammekg/skilogramme per secondkmkilometrekm/hkilometre per hourkPakilopascalkPa/minkilopascal per minutellitrel/minlitre per minutemmetrem3cubic-metremgmilligramminminutepeevacuated pressure [kPa]qvsvolume flow rate of the system [l/min]ppmparts per millionppmC1parts per million carbon equivalentrpmrevolutions per minutessecondVssystem volume [l]

3.  3.1. 
The test shall be carried out with a PEMS, composed of components specified in points 3.1.1 to 3.1.5. If applicable, a connection with the vehicle ECU may be established to determine relevant engine and vehicle parameters as specified in point 3.2.
 3.1.1. Analysers to determine the concentration of pollutants in the exhaust gas.
 3.1.2. One or multiple instruments or sensors to measure or determine the exhaust mass flow.
 3.1.3. A Global Positioning System to determine the position, altitude and, speed of the vehicle.
 3.1.4. If applicable, sensors and other appliances being not part of the vehicle, e.g., to measure ambient temperature, relative humidity, air pressure, and vehicle speed.
 3.1.5. An energy source independent of the vehicle to power the PEMS.
 3.2. 
Test parameters as specified in Table 1 of this Appendix shall be measured, recorded at a constant frequency of 1.0 Hz or higher and reported according to the requirements of Appendix 8. If ECU parameters are obtained, these should be made available at a substantially higher frequency than the parameters recorded by PEMS. The PEMS analysers, flow-measuring instruments and sensors shall comply with the requirements laid down in Appendices 2 and 3 of this Annex.


Parameter Recommended unit Source
THC concentration, ppm Analyser
CH4 concentration, ppm Analyser
NMHC concentration, ppm Analyser
CO concentration, ppm Analyser
CO2 concentration ppm Analyser
NOX concentration, ppm Analyser
PN concentration #/m3 Analyser
Exhaust mass flow rate kg/s EFM, any methods described in point 7 of Appendix 2
Ambient humidity % Sensor
Ambient temperature K Sensor
Ambient pressure kPa Sensor
Vehicle speed km/h Sensor, GPS, or ECU
Vehicle latitude Degree GPS
Vehicle longitude Degree GPS
Vehicle altitude, M GPS or Sensor
Exhaust gas temperature K Sensor
Engine coolant temperature K Sensor or ECU
Engine speed rpm Sensor or ECU
Engine torque Nm Sensor or ECU
Torque at driven axle Nm Rim torque meter
Pedal position % Sensor or ECU
Engine fuel flow g/s Sensor or ECU
Engine intake air flow g/s Sensor or ECU
Fault status — ECU
Intake air flow temperature K Sensor or ECU
Regeneration status — ECU
Engine oil temperature K Sensor or ECU
Actual gear # ECU
Desired gear (e.g. gear shift indicator) # ECU
Other vehicle data unspecified ECU









 3.3. 
The preparation of the vehicle shall include a general verification of the correct technical functioning of the test vehicle.
 3.4.  3.4.1. 
The installation of the PEMS shall follow the instructions of the PEMS manufacturer and the local health and safety regulations. The PEMS should be installed as to minimize during the test electromagnetic interferences as well as exposure to shocks, vibration, dust and variability in temperature. The installation and operation of the PEMS shall be leak-tight and minimize heat loss. The installation and operation of PEMS shall not change the nature of the exhaust gas nor unduly increase the length of the tailpipe. To avoid the generation of particles, connectors shall be thermally stable at the exhaust gas temperatures expected during the test. It is recommended to avoid the use of a material which may emit volatile components to connect the vehicle exhaust outlet and the connecting tube. Elastomer connectors, if used, shall have a minimum exposure to the exhaust gas to avoid artefacts at high engine load.
 3.4.2. 
The installation and operation of the PEMS shall not unduly increase the static pressure at the exhaust outlet. If technically feasible, any extension to facilitate the sampling or connection with the exhaust mass flow meter shall have an equivalent, or larger, cross sectional area than the exhaust pipe.
 3.4.3. 
Whenever used, the exhaust mass flow meter shall be attached to the vehicle's tailpipe(s) according to the recommendations of the EFM manufacturer. The measurement range of the EFM shall match the range of the exhaust mass flow rate expected during the test. The installation of the EFM and any exhaust pipe adaptors or junctions shall not adversely affect the operation of the engine or exhaust after-treatment system. A minimum of four pipe diameters or 150 mm of straight tubing, whichever is larger, shall be placed at either side of the flow-sensing element. When testing a multi-cylinder engine with a branched exhaust manifold, it is recommended to combine the manifolds upstream of the exhaust mass flow meter and to increase the cross section of the piping appropriately as to minimize backpressure in the exhaust. If this is not feasible, exhaust flow measurements with several exhaust mass flow meters shall be considered. The wide variety of exhaust pipe configurations, dimensions and exhaust mass flow rates may require compromises, guided by good engineering judgement, when selecting and installing the EFM(s). If measurement accuracy requires, it is permissible to install an EFM with a diameter smaller than that of the exhaust outlet or the total cross-sectional area of multiple outlets, providing it does not adversely affect the operation or the exhaust after-treatment as specified in point 3.4.2.
 3.4.4. 
The GPS antenna should be mounted, e.g. at the highest possible location, as to ensure good reception of the satellite signal. The mounted GPS antenna shall interfere as little as possible with the vehicle operation.
 3.4.5. 
If desired, relevant vehicle and engine parameters listed in Table 1 can be recorded by using a data logger connected with the ECU or the vehicle network through standards, such as ISO 15031-5 or SAE J1979, OBD-II, EOBD or WWH-OBD. If applicable, manufacturers shall disclose labels to allow the identification of required parameters.
 3.4.6. 
Vehicle speed sensors, temperature sensors, coolant thermocouples or any other measurement device not part of the vehicle shall be installed to measure the parameter under consideration in a representative, reliable and accurate manner without unduly interfering with the vehicle operation and the functioning of other analysers, flow-measuring instruments, sensors and signals. Sensors and auxiliary equipment shall be powered independently of the vehicle. It is permitted to power any safety-related illumination of fixtures and installations of PEMS components outside of the vehicle’s cabin by the vehicle’s battery.
 3.5. 
Emissions sampling shall be representative and conducted at locations of well-mixed exhaust where the influence of ambient air downstream of the sampling point is minimal. If applicable, emissions shall be sampled downstream of the exhaust mass flow meter, respecting a distance of at least 150 mm to the flow sensing element. The sampling probes shall be fitted at least 200 mm or three times the inner diameter of the exhaust pipe, whichever is larger, upstream of the point at which the exhaust exits the PEMS sampling installation into the environment. If the PEMS feeds back a flow to the tail pipe, this shall occur downstream of the sampling probe in a manner that does not affect during engine operation the nature of the exhaust gas at the sampling point(s). If the length of the sampling line is changed, the system transport times shall be verified and if necessary corrected.

If the engine is equipped with an exhaust after-treatment system, the exhaust sample shall be taken downstream of the exhaust after-treatment system. When testing a vehicle with a multi-cylinder engine and branched exhaust manifold, the inlet of the sampling probe shall be located sufficiently far downstream so as to ensure that the sample is representative of the average exhaust emissions of all cylinders. In multi-cylinder engines, having distinct groups of manifolds, such as in a ‘V’ engine configuration, the manifolds shall be combined upstream of the sampling probe. If this is technically not feasible, multi-point sampling at locations of well-mixed exhaust free of ambient air shall be considered. In this case, the number and location of sampling probes shall match as far as possible those of the exhaust mass flow meters. In case of unequal exhaust flows, proportional sampling or sampling with multiple analysers shall be considered.

If particles are measured, the exhaust shall be sampled from the centre of the exhaust stream. If several probes are used for emissions sampling, the particle sampling probe shall be placed upstream of the other sampling probes.

If hydrocarbons are measured, the sampling line shall be heated to 463 ± 10 K (190 ± 10 °C). For the measurement of other gaseous components with or without cooler, the sampling line shall be kept at a minimum of 333 K (60 °C) to avoid condensation and to ensure appropriate penetration efficiencies of the various gases. For low pressure sampling systems, the temperature can be lowered corresponding to the pressure decrease provided that the sampling system ensures a penetration efficiency of 95 % for all regulated gaseous pollutants. If particles are sampled, the sampling line from the raw exhaust sample point shall be heated to a minimum of 373 K (100 °C). The residence time of the sample in the particle sampling line shall be less than 3 s until reaching first dilution or the particle counter.

4.  4.1. 
After the installation of the PEMS is completed, a leak check shall be performed at least once for each PEMS-vehicle installation as prescribed by the PEMS manufacturer or as follows. The probe shall be disconnected from the exhaust system and the end plugged. The analyser pump shall be switched on. After an initial stabilization period all flow meters shall read approximately zero in the absence of a leak. Else, the sampling lines shall be checked and the fault be corrected.

The leakage rate on the vacuum side shall not exceed 0.5 per cent of the in-use flow rate for the portion of the system being checked. The analyser flows and bypass flows may be used to estimate the in-use flow rate.

Alternatively, the system may be evacuated to a pressure of at least 20 kPa vacuum (80 kPa absolute). After an initial stabilization period the pressure increase Δp (kPa/min) in the system shall not exceed:
Δp=peVs× qvs× 0.005
Alternatively, a concentration step change at the beginning of the sampling line shall be introduced by switching from zero to span gas while maintaining the same pressure conditions as under normal system operation. If for a correctly calibrated analyser after an adequate period of time the reading is ≤ 99 per cent compared to the introduced concentration, the leakage problem shall be corrected.
 4.2. 
The PEMS shall be switched on, warmed up and stabilized according to the specifications of the PEMS manufacturer until, e.g., pressures, temperatures and flows have reached their operating set points.
 4.3. 
The sampling system, consisting of the sampling probe, sampling lines and the analysers, shall be prepared for testing by following the instruction of the PEMS manufacturer. It shall be ensured that the sampling system is clean and free of moisture condensation.
 4.4. 
If used for measuring the exhaust mass flow, the EFM shall be purged and prepared for operation in accordance with the specifications of the EFM manufacturer. This procedure shall, if applicable, remove condensation and deposits from the lines and the associated measurement ports.
 4.5. 
Zero and span calibration adjustments of the analysers shall be performed using calibration gases that meet the requirements of point 5 of Appendix 2. The calibration gases shall be chosen to match the range of pollutant concentrations expected during the RDE test. To minimize analyser drift, one should conduct the zero and span calibration of analysers at an ambient temperature that resembles, as closely as possible, the temperature experienced by the test equipment during the trip.
 4.6. 
The zero level of the analyser shall be recorded by sampling HEPA filtered ambient air. The signal shall be recorded at a constant frequency of at least 1.0 Hz over a period of 2 min and averaged; the permissible concentration value shall be determined once suitable measurement equipment becomes available.
 4.7. 
Vehicle speed shall be determined by at least one of the following methods:


((a)) a GPS; if vehicle speed is determined by a GPS, the total trip distance shall be checked against the measurements of another method according to point 7 of Appendix 4.
((b)) a sensor (e.g., optical or micro-wave sensor); if vehicle speed is determined by a sensor, the speed measurements shall comply with the requirements of point 8 of Appendix 2, or alternatively, the total trip distance determined by the sensor shall be compared with a reference distance obtained from a digital road network or topographic map. The total trip distance determined by the sensor shall deviate by no more than 4 % from the reference distance.
((c)) the ECU; if vehicle speed is determined by the ECU, the total trip distance shall be validated according to point 3 of Appendix 3 and the ECU speed signal adjusted, if necessary to fulfil the requirements of point 3.3 of Appendix 3. Alternatively, the total trip distance as determined by the ECU can be compared with a reference distance obtained from a digital road network or topographic map. The total trip distance determined by the ECU shall deviate by no more than 4 % from the reference.
 4.8. 
The correctness of connections with all sensors and, if applicable, the ECU shall be verified. If engine parameters are retrieved, it shall be ensured that the ECU reports values correctly (e.g., zero engine speed [rpm] while the combustion engine is in key-on-engine-off status). The PEMS shall function free of warning signals and error indication.

5.  5.1. 
Sampling, measurement and recording of parameters shall begin prior to the start of the engine. To facilitate time alignment, it is recommended to record the parameters that are subject to time alignment either by a single data recording device or with a synchronised time stamp. Before and directly after engine start, it shall be confirmed that all necessary parameters are recorded by the data logger.
 5.2. 
Sampling, measurement and recording of parameters shall continue throughout the on-road test of the vehicle. The engine may be stopped and started, but emissions sampling and parameter recording shall continue. Any warning signals, suggesting malfunctioning of the PEMS, shall be documented and verified. Parameter recording shall reach a data completeness of higher than 99 %. Measurement and data recording may be interrupted for less than 1 % of the total trip duration but for no more than a consecutive period of 30 s solely in the case of unintended signal loss or for the purpose of PEMS system maintenance. Interruptions may be recorded directly by the PEMS. It is not permissible to introduce interruptions in the recorded parameter via the pre-processing, exchange or post-processing of data. If conducted, auto zeroing shall be performed against a traceable zero standard similar to the one used to zero the analyser. If necessary it is strongly recommended to initiate PEMS system maintenance during periods of zero vehicle speed.
 5.3. 
The end of the test is reached when the vehicle has completed the trip and the combustion engine is switched off. Excessive idling of the engine after the completion of the trip shall be avoided. The data recording shall continue until the response time of the sampling systems has elapsed.

6.  6.1. 
The zero and span of the analysers of gaseous components shall be checked by using calibration gases identical to the ones applied under point 4.5 to evaluate the analyser's zero and response drift compared to the pre-test calibration. It is permissible to zero the analyser prior to verifying the span drift, if the zero drift was determined to be within the permissible range. The post-test drift check shall be completed as soon as possible after the test and before the PEMS, or individual analysers or sensors, are turned off or have switched into a non-operating mode. The difference between the pre-test and post-test results shall comply with the requirements specified in Table 2.


Pollutant Zero response drift Span response drift
CO2 ≤ 2 000 ppm per test ≤ 2 % of reading or ≤ 2 000 ppm per test, whichever is larger
CO ≤ 75 ppm per test ≤ 2 % of reading or ≤ 75 ppm per test, whichever is larger
NO2 ≤ 5 ppm per test ≤ 2 % of reading or ≤ 5 ppm per test, whichever is larger
NO/NOX ≤ 5 ppm per test ≤ 2 % of reading or ≤ 5 ppm per test, whichever is larger
CH4 ≤ 10 ppmC1 per test ≤ 2 % of reading or ≤ 10 ppmC1 per test, whichever is larger
THC ≤ 10 ppmC1 per test ≤ 2 % of reading or ≤10 ppmC1 per test, whichever is larger


If the difference between the pre-test and post-test results for the zero and span drift is higher than permitted, all test results shall be voided and the test repeated.
 6.2. 
The zero level of the analyser shall be recorded by sampling HEPA filtered ambient air. The signal shall be recorded over a period of 2 min and averaged; the permissible final concentration shall be defined once suitable measurement equipment becomes available. If the difference between the pre-test and post-test check is higher than permitted, all test results shall be voided and the test repeated.
 6.3. 
The calibrated range of the analysers shall account at least for 90 % of the concentration values obtained from 99 % of the measurements of the valid parts of the emissions test. It is permissible that 1 % of the total number of measurements used for evaluation exceeds the calibrated range of the analysers by up to a factor of two. If these requirements are not met, the test shall be voided.

Appendix 2
1. 
This appendix sets out the specifications and calibration of PEMS components and signals.

2. 
>larger than≥larger than or equal to%per cent≤smaller than or equal toAundiluted CO2 concentration [%]a0y-axis intercept of the linear regression linea1slope of the linear regression lineBdiluted CO2 concentration [%]Cdiluted NO concentration [ppm]canalyser response in the oxygen interference testcFS,bfull scale HC concentration in step (b) [ppmC1]cFS,dfull scale HC concentration in step (d) [ppmC1]cHC(w/NMC)HC concentration with CH4 or C2H6 flowing through the NMC [ppmC1]cHC(w/o NMC)HC concentration with CH4 or C2H6 bypassing the NMC [ppmC1]cm,bmeasured HC concentration in step (b) [ppmC1]cm,dmeasured HC concentration in step (d) [ppmC1]cref,breference HC concentration in step (b) [ppmC1]cref,dreference HC concentration in step (d) [ppmC1]°Cdegree centigradeDundiluted NO concentration [ppm]Deexpected diluted NO concentration [ppm]Eabsolute operating pressure [kPa]ECO2per cent CO2 quenchEEethane efficiencyEH2Oper cent water quenchEMmethane efficiencyEO2oxygen interferenceFwater temperature [K]Gsaturation vapour pressure [kPa]ggramgH2O/kggramme water per kilogramhhourHwater vapour concentration [%]Hmmaximum water vapour concentration [%]HzhertzKkelvinkgkilogrammekm/hkilometre per hourkPakilopascalmaxmaximum valueNOX,drymoisture-corrected mean concentration of the stabilized NOX recordingsNOX,mmean concentration of the stabilized NOX recordingsNOX,refreference mean concentration of the stabilized NOX recordingsppmparts per millionppmC1parts per million carbon equivalentsr2coefficient of determinationssecondt0time point of gas flow switching [s]t10time point of 10 % response of the final readingt50time point of 50 % response of the final readingt90time point of 90 % response of the final readingtbdto be determinedxindependent variable or reference valueχminminimum valueydependent variable or measured value

3.  3.1. 
The linearity of analysers, flow-measuring instruments, sensors and signals, shall be traceable to international or national standards. Any sensors or signals that are not directly traceable, e.g., simplified flow-measuring instruments shall be calibrated alternatively against chassis dynamometer laboratory equipment that has been calibrated against international or national standards.
 3.2. 
All analysers, flow-measuring instruments, sensors and signals shall comply with the linearity requirements given in Table 1. If air flow, fuel flow, the air-to-fuel ratio or the exhaust mass flow rate is obtained from the ECU, the calculated exhaust mass flow rate shall meet the linearity requirements specified in Table 1.


Measurement parameter/instrument χmin×a1− 1+ a0 Slopea1 Standard errorSEE Coefficient of determination r2
Fuel flow rate ≤ 1 % max 0,98 - 1,02 ≤ 2 % max ≥ 0,99
Air flow rate ≤ 1 % max 0,98 - 1,02 ≤ 2 % max ≥ 0,99
Exhaust mass flow rate ≤ 2 % max 0,97 - 1,03 ≤ 2 % max ≥ 0,99
Gas analysers ≤ 0,5 % max 0,99 - 1,01 ≤ 1 % max ≥ 0,998
Torque ≤ 1 % max 0,98-1,02 ≤ 2 % max ≥ 0,99
PN analysers tbd tbd tbd tbd



 3.3. 
The linearity requirements according to point 3.2 shall be verified:


((a)) for each analyser at least every three months or whenever a system repair or change is made that could influence the calibration;
((b)) for other relevant instruments, such as exhaust mass flow meters and traceably calibrated sensors, whenever damage is observed, as required by internal audit procedures, by the instrument manufacturer or by ISO 9000 but no longer than one year before the actual test.

The linearity requirements according to point 3.2 for sensors or ECU signals that are not directly traceable shall be performed with a traceably calibrated measurement device on the chassis dynamometer once for each PEMS setup.
 3.4.  3.4.1. 
The relevant analysers, instruments and sensors shall be brought to their normal operating condition according to the recommendations of their manufacturer. The analysers, instruments and sensors shall be operated at their specified temperatures, pressures and flows.
 3.4.2. 
The linearity shall be verified for each normal operating range by executing the following steps:


((a)) The analyser, flow-measuring instrument or sensor shall be set to zero by introducing a zero signal. For gas analysers, purified synthetic air or nitrogen shall be introduced to the analyser port via a gas path that is as direct and short as possible.
((b)) The analyser, flow-measuring instrument or sensor shall be spanned by introducing a span signal. For gas analysers, an appropriate span gas shall be introduced to the analyser port via a gas path that is as direct and short as possible.
((c)) The zero procedure of (a) shall be repeated.
((d)) The linearity shall be verified by introducing at least 10, approximately equally spaced and valid, reference values (including zero). The reference values with respect to the concentration of components, the exhaust mass flow rate or any other relevant parameter shall be chosen to match the range of values expected during the emissions test. For measurements of exhaust mass flow, reference points below 5 % of the maximum calibration value can be excluded from the linearity verification.
((e)) For gas analysers, known gas concentrations in accordance with point 5 shall be introduced to the analyser port. Sufficient time for signal stabilisation shall be given.
((f)) The values under evaluation and, if needed, the reference values shall be recorded at a constant frequency of at least 1.0 Hz over a period of 30 seconds.
((g)) The arithmetic mean values over the 30 seconds period shall be used to calculate the least squares linear regression parameters, with the best-fit equation having the form:
y=a1x+ a0
where:
yis the actual value of the measurement systema1is the slope of the regression linexis the reference valuea0is the y intercept of the regression line
The standard error of estimate (SEE) of y on x and the coefficient of determination (r2) shall be calculated for each measurement parameter and system.
((h)) The linear regression parameters shall meet the requirements specified in Table 1.
 3.4.3. 
Non-traceable flow-measuring instruments, sensors or ECU signals that cannot directly be calibrated according to traceable standards, shall be calibrated on a chassis dynamometer. The procedure shall follow as far as applicable, the requirements of Annex 4a to UN/ECE Regulation No 83. If necessary, the instrument or sensor to be calibrated shall be installed on the test vehicle and operated according to the requirements of Appendix 1. The calibration procedure shall follow whenever possible the requirements of point 3.4.2; at least 10 appropriate reference values shall be selected as to ensure that at least 90 % of the maximum value expected to occur during the RDE test is covered.

If a not directly traceable flow-measuring instrument, sensor or ECU signal for determining exhaust flow is to be calibrated, a traceably calibrated reference exhaust mass flow meter or the CVS shall be attached to the vehicle’s tailpipe. It shall be ensured that the vehicle exhaust is accurately measured by the exhaust mass flow meter according to point 3.4.3 of Appendix 1. The vehicle shall be operated by applying constant throttle at a constant gear selection and chassis dynamometer load.

4.  4.1.  4.1.1. 
The gaseous components shall be measured with analysers specified in points 1.3.1 to 1.3.5 of Appendix 3, Annex 4A to UN/ECE Regulation No 83, 07 series of amendments. If an NDUV analyser measures both NO and NO2, a NO2/NO converter is not required.
 4.1.2. 
Any analyser not meeting the design specifications of point 4.1.1 is permissible provided that it fulfils the requirements of point 4.2. The manufacturer shall ensure that the alternative analyser achieves an equivalent or higher measurement performance compared to a standard analyser over the range of pollutant concentrations and co-existing gases that can be expected from vehicles operated with permissible fuels under moderate and extended conditions of valid RDE testing as specified in points 5, 6 and 7 of this Annex. Upon request, the manufacturer of the analyser shall submit in writing supplemental information, demonstrating that the measurement performance of the alternative analyser is consistently and reliably in line with the measurement performance of standard analysers. Supplemental information shall contain:


((a)) a description of the theoretical basis and the technical components of the alternative analyser;
((b)) a demonstration of equivalency with the respective standard analyser specified in point 4.1.1 over the expected range of pollutant concentrations and ambient conditions of the type-approval test defined in Annex 4a to UN/ECE Regulation No 83, 07 series of amendments as well as a validation test as described in point 3 of Appendix 3 for a vehicle equipped with a spark-ignition and compression-ignition engine; the manufacturer of the analyser shall demonstrate the significance of equivalency within the permissible tolerances given in point 3.3 of Appendix 3.
((c)) a demonstration of equivalency with the respective standard analyser specified in point 4.1.1 with respect to the influence of atmospheric pressure on the measurement performance of the analyser; the demonstration test shall determine the response to span gas having a concentration within the analyser range to check the influence of atmospheric pressure under moderate and extended altitude conditions defined in point 5.2 of this Annex. Such a test can be performed in an altitude environmental test chamber.
((d)) a demonstration of equivalency with the respective standard analyser specified in point 4.1.1 over at least three on-road tests that fulfil the requirements of this Annex.
((e)) a demonstration that the influence of vibrations, accelerations and ambient temperature on the analyser reading does not exceed the noise requirements for analysers set out in point 4.2.4.

Approval authorities may request additional information to substantiate equivalency or refuse approval if measurements demonstrate that an alternative analyser is not equivalent to a standard analyser.
 4.2.  4.2.1. 
In addition to the linearity requirements defined for each analyser in point 3, the compliance of analyser types with the specifications laid down in points 4.2.2 to 4.2.8 shall be demonstrated by the analyser manufacturer. Analysers shall have a measuring range and response time appropriate to measure with adequate accuracy the concentrations of the exhaust gas components at the applicable emissions standard under transient and steady state conditions. The sensitivity of the analysers to shocks, vibration, aging, variability in temperature and air pressure as well as electromagnetic interferences and other impacts related to vehicle and analyser operation shall be limited as far as possible.
 4.2.2. 
The accuracy, defined as the deviation of the analyser reading from the reference value, shall not exceed 2 % of reading or 0.3 % of full scale, whichever is larger.
 4.2.3. 
The precision, defined as 2.5 times the standard deviation of 10 repetitive responses to a given calibration or span gas, shall be no greater than 1 % of the full scale concentration for a measurement range equal or above 155 ppm (or ppmC1) and 2 % of the full scale concentration for a measurement range of below 155 ppm (or ppmC1).
 4.2.4. 
The noise, defined as two times the root mean square of ten standard deviations, each calculated from the zero responses measured at a constant recording frequency of at least 1.0 Hz during a period of 30 seconds, shall not exceed 2 % of full scale. Each of the 10 measurement periods shall be interspersed with an interval of 30 seconds in which the analyser is exposed to an appropriate span gas. Before each sampling period and before each span period, sufficient time shall be given to purge the analyser and the sampling lines.
 4.2.5. 
The drift of the zero response, defined as the mean response to a zero gas during a time interval of at least 30 seconds, shall comply with the specifications given in Table 2.
 4.2.6. 
The drift of the span response, defined as the mean response to a span gas during a time interval of at least 30 seconds, shall comply with the specifications given in Table 2.


Pollutant Zero response drift Span response drift
CO2 ≤1,0 ppm over 4 h ≤2 % of reading or ≤1,0 ppm over 4 h, whichever is larger
CO ≤50 ppm over 4 h ≤2 % of reading or ≤50 ppm over 4 h, whichever is larger
NO2 ≤5 ppm over 4 h ≤2 % of reading or ≤5 ppm over 4 h, whichever is larger
NO/NOX ≤5 ppm over 4 h ≤2 % of reading or 5 ppm over 4h, whichever is larger
CH4 ≤10 ppmC1 ≤2 % of reading or ≤10 ppmC1 over 4 h, whichever is larger
THC ≤10 ppmC1 ≤2 % of reading or ≤10 ppmC1 over 4 h, whichever is larger
 4.2.7. 
The rise time, defined as the time between the 10 per cent and 90 per cent response of the final reading (t90 – t10; see point 4.4), shall not exceed 3 seconds.
 4.2.8. 
Exhaust gases may be measured wet or dry. A gas-drying device, if used, shall have a minimal effect on the composition of the measured gases. Chemical dryers are not permitted.
 4.3.  4.3.1. 
The provisions in points 4.3.2 to 4.3.5 define additional performance requirements for specific analyser types and apply only to cases, in which the analyser under consideration is used for RDE emission measurements.
 4.3.2. 
If a NOX converter is applied, for example to convert NO2 into NO for analysis with a chemiluminescence analyser, its efficiency shall be tested by following the requirements of point 2.4 of Appendix 3 of Annex 4a to UN/ECE Regulation No 83, 07 series of amendments. The efficiency of the NOX converter shall be verified no longer than one month before the emissions test.
 4.3.3.  (a) 
If hydrocarbons are measured, the FID shall be adjusted at intervals specified by the analyser manufacturer by following point 2.3.1 of Appendix 3 of Annex 4a to UN/ECE Regulation No 83, 07 series of amendments. A propane-in-air or propane-in-nitrogen span gas shall be used to optimize the response in the most common operating range.
 (b) 
If hydrocarbons are measured, the hydrocarbon response factor of the FID shall be verified by following the provisions of point 2.3.3 of Appendix 3 of Annex 4a to UN/ECE Regulation No 83, 07 series of amendments, using propane-in-air or propane-in-nitrogen as span gases and purified synthetic air or nitrogen as zero gases, respectively.
 (c) 
The oxygen interference check shall be performed when introducing a FID into service and after major maintenance intervals. A measuring range shall be chosen in which the oxygen interference check gases fall in the upper 50 per cent. The test shall be conducted with the oven temperature set as required. The specifications of the oxygen interference check gases are described in point 5.3.

The following procedure applies:


((i)) The analyser shall be set at zero;
((ii)) The analyser shall be spanned with a 0 per cent oxygen blend for positive ignition engines and a 21 per cent oxygen blend for compression ignition engines;
((iii)) The zero response shall be rechecked. If it has changed by more than 0.5 per cent of full scale, steps (i) and (ii) shall be repeated;
((iv)) The 5 per cent and 10 per cent oxygen interference check gases shall be introduced;
((v)) The zero response shall be rechecked. If it has changed by more than ±1 per cent of full scale, the test shall be repeated;
((vi)) The oxygen interference EO2 shall be calculated for each oxygen interference check gas in step (iv) as follows:
EO2=cref,d− ccref,d× 100
where the analyser response is:
c=cref,d× cFS,bcm,b×cm,bcFS,d
where:
cref,bis the reference HC concentration in step (ii) [ppmC1]cref,dis the reference HC concentration in step (iv) [ppmC1]cFS,bis the full scale HC concentration in step (ii) [ppmC1]cFS,dis the full scale HC concentration in step (iv) [ppmC1]cm,bis the measured HC concentration in step (ii) [ppmC1]cm,dis the measured HC concentration in step (iv) [ppmC1]
((vii)) The oxygen interference EO2 shall be less than ±1.5 per cent for all required oxygen interference check gases.
((viii)) If the oxygen interference EO2 is higher than ±1.5 per cent, corrective action may be taken by incrementally adjusting the air flow (above and below the manufacturer's specifications), the fuel flow and the sample flow.
((ix)) The oxygen interference check shall be repeated for each new setting.
 4.3.4. 
If hydrocarbons are analysed, a NMC can be used to remove non-methane hydrocarbons from the gas sample by oxidizing all hydrocarbons except methane. Ideally, the conversion for methane is 0 per cent and for the other hydrocarbons represented by ethane is 100 per cent. For the accurate measurement of NMHC, the two efficiencies shall be determined and used for the calculation of the NMHC emissions (see point 9.2 of Appendix 4). It is not necessary to determine the methane conversion efficiency in case the NMC-FID is calibrated according to method (b) in point 9.2 of Appendix 4 by passing the methane/air calibration gas through the NMC.
 (a) 
Methane calibration gas shall be flown through the FID with and without bypassing the NMC; the two concentrations shall be recorded. The methane efficiency shall be determined as:
 E M= 1−c HCw∕NMCc HCw∕oNMC
where:

cHC(w/NMC)is the HC concentration with CH4 flowing through the NMC [ppmC1]cHC(w/o NMC)is the HC concentration with CH4 bypassing the NMC [ppmC1]
 (b) 
Ethane calibration gas shall be flown through the FID with and without bypassing the NMC; the two concentrations shall be recorded. The ethane efficiency shall be determined as:
 E E= 1−c HCw∕NMCc HCw∕oNMC
where:

cHC(w/NMC)is the HC concentration with C2H6 flowing through the NMC [ppmC1]cHC(w/o NMC)is the HC concentration with C2H6 bypassing the NMC [ppmC1]
 4.3.5.  (a) 
Other gases than the ones being analysed can affect the analyser reading. A check for interference effects and the correct functionality of analysers shall be performed by the analyser manufacturer prior to market introduction at least once for each type of analyser or device addressed in points (b) to (f).
 (b) 
Water and CO2 can interfere with the measurements of the CO analyser. Therefore, a CO2 span gas having a concentration of 80 to 100 per cent of full scale of the maximum operating range of the CO analyser used during the test shall be bubbled through water at room temperature and the analyser response recorded. The analyser response shall not be more than 2 per cent of the mean CO concentration expected during normal on-road testing or ± 50 ppm, whichever is larger. The interference check for H2O and CO2 may be run as separate procedures. If the H2O and CO2 levels used for the interference check are higher than the maximum levels expected during the test, each observed interference value shall be scaled down by multiplying the observed interference with the ratio of the maximum expected concentration value during the test and the actual concentration value used during this check. Separate interference checks with concentrations of H2O that are lower than the maximum concentration expected during the test may be run and the observed H2O interference shall be scaled up by multiplying the observed interference with the ratio of the maximum H2O concentration value expected during the test and the actual concentration value used during this check. The sum of the two scaled interference values shall meet the tolerance specified in this point.
 (c) 
The two gases of concern for CLD and HCLD analysers are CO2 and water vapour. The quench response to these gases is proportional to the gas concentrations. A test shall determine the quench at the highest concentrations expected during the test. If the CLD and HCLD analysers use quench compensation algorithms that utilize H2O or CO2 measurement analysers or both, quench shall be evaluated with these analysers active and with the compensation algorithms applied.
 (i) 
A CO2 span gas having a concentration of 80 to 100 per cent of the maximum operating range shall be passed through the NDIR analyser; the CO2 value shall be recorded as A. The CO2 span gas shall then be diluted by approximately 50 per cent with NO span gas and passed through the NDIR and CLD or HCLD; the CO2 and NO values shall be recorded as B and C, respectively. The CO2 gas flow shall then be shut off and only the NO span gas shall be passed through the CLD or HCLD; the NO value shall be recorded as D. The per cent quench shall be calculated as:
 E CO2= 1−C× AD× A−D× B× 100
where:

Ais the undiluted CO2 concentration measured with the NDIR [%]Bis the diluted CO2 concentration measured with the NDIR [%]Cis the diluted NO concentration measured with the CLD or HCLD [ppm]Dis the undiluted NO concentration measured with the CLD or HCLD [ppm]

Alternative methods of diluting and quantifying of CO2 and NO span gas values such as dynamic mixing/blending are permitted upon approval of the approval authority.
 (ii) 
This check applies to measurements of wet gas concentrations only. The calculation of water quench shall consider dilution of the NO span gas with water vapour and the scaling of the water vapour concentration in the gas mixture to concentration levels that are expected to occur during an emissions test. A NO span gas having a concentration of 80 per cent to 100 per cent of full scale of the normal operating range shall be passed through the CLD or HCLD; the NO value shall be recorded as D. The NO span gas shall then be bubbled through water at room temperature and passed through the CLD or HCLD; the NO value shall be recorded as C. The analyser's absolute operating pressure and the water temperature shall be determined and recorded as E and F, respectively. The mixture's saturation vapour pressure that corresponds to the water temperature of the bubbler F shall be determined and recorded as G. The water vapour concentration H [%] of the gas mixture shall be calculated as:
H=GE= 100
The expected concentration of the diluted NO-water vapour span gas shall be recorded as De after being calculated as:
D e= D× 1−H100
For diesel exhaust, the maximum concentration of water vapour in the exhaust gas (in per cent) expected during the test shall be recorded as Hm after being estimated, under the assumption of a fuel H/C ratio of 1.8/1, from the maximum CO2 concentration in the exhaust gas A as follows:
 H m=0,9× A
The per cent water quench shall be calculated as:
 E H2O=D e− CD e×H mH× 100
where:

Deis the expected diluted NO concentration [ppm]Cis the measured diluted NO concentration [ppm]Hmis the maximum water vapour concentration [%]His the actual water vapour concentration [%]
 (iii) 
The combined CO2 and water quench shall not exceed 2 per cent of full scale.
 (d) 
Hydrocarbons and water can positively interfere with NDUV analysers by causing a response similar to that of NOX. The manufacturer of the NDUV analyser shall use the following procedure to verify that quench effects are limited:


((i)) The analyser and chiller shall be set up by following the operating instructions of the manufacturer; adjustments should be made as to optimise the analyser and chiller performance.
((ii)) A zero calibration and span calibration at concentration values expected during emissions testing shall be performed for the analyser.
((iii)) A NO2 calibration gas shall be selected that matches as far as possible the maximum NO2 concentration expected during emissions testing.
((iv)) The NO2 calibration gas shall overflow at the gas sampling system's probe until the NOX response of the analyser has stabilised.
((v)) The mean concentration of the stabilized NOX recordings over a period of 30 s shall be calculated and recorded as NOX,ref.
((vi)) The flow of the NO2 calibration gas shall be stopped and the sampling system saturated by overflowing with a dew point generator's output, set at a dew point of 50 °C. The dew point generator's output shall be sampled through the sampling system and chiller for at least 10 minutes until the chiller is expected to be removing a constant rate of water.
((vii)) Upon completion of (iv), the sampling system shall again be overflown by the NO2 calibration gas used to establish NOX,ref until the total NOX response has stabilized.
((viii)) The mean concentration of the stabilized NOX recordings over a period of 30 s shall be calculated and recorded as NOX,m.
((ix)) NOX,m shall be corrected to NOX,dry based upon the residual water vapour that passed through the chiller at the chiller's outlet temperature and pressure.
The calculated NOX,dry shall at least amount to 95 % of NOX,ref.
 (e) 
A sample dryer removes water, which can otherwise interfere with the NOX measurement. For dry CLD analysers, it shall be demonstrated that at the highest expected water vapour concentration Hm the sample dryer maintains the CLD humidity at ≤ 5 g water/kg dry air (or about 0.8 per cent H2O), which is 100 per cent relative humidity at 3.9 °C and 101.3 kPa or about 25 per cent relative humidity at 25 °C and 101.3 kPa. Compliance may be demonstrated by measuring the temperature at the outlet of a thermal sample dryer or by measuring the humidity at a point just upstream of the CLD. The humidity of the CLD exhaust might also be measured as long as the only flow into the CLD is the flow from the sample dryer.
 (f) 
Liquid water remaining in an improperly designed sample dryer can remove NO2 from the sample. If a sample dryer is used in combination with a NDUV analyser without an NO2/NO converter upstream, water could therefore remove NO2 from the sample prior to the NOX measurement. The sample dryer shall allow for measuring at least 95 per cent of the NO2 contained in a gas that is saturated with water vapour and consists of the maximum NO2 concentration expected to occur during emission testing.
 4.4. 
For the response time check, the settings of the analytical system shall be exactly the same as during the emissions test (i.e. pressure, flow rates, filter settings in the analysers and all other parameters influencing the response time). The response time shall be determined with gas switching directly at the inlet of the sample probe. The gas switching shall be done in less than 0.1 second. The gases used for the test shall cause a concentration change of at least 60 per cent full scale of the analyser.

The concentration trace of each single gas component shall be recorded. The delay time is defined as the time from the gas switching (t0) until the response is 10 per cent of the final reading (t10). The rise time is defined as the time between 10 per cent and 90 per cent response of the final reading (t90 – t10). The system response time (t90) consists of the delay time to the measuring detector and the rise time of the detector.

For time alignment of the analyser and exhaust flow signals, the transformation time is defined as the time from the change (t0) until the response is 50 per cent of the final reading (t50).

The system response time shall be ≤ 12 s with a rise time of ≤ 3 seconds for all components and all ranges used. When using a NMC for the measurement of NMHC, the system response time may exceed 12 seconds.

5.  5.1. 
The shelf life of calibration and span gases shall be respected. Pure and mixed calibration and span gases shall fulfil the specifications of points 3.1 and 3.2 of Appendix 3 of Annex 4A to UN/ECE Regulation No 83, 07 series of amendments. In addition, NO2 calibration gas is permissible. The concentration of the NO2 calibration gas shall be within two per cent of the declared concentration value. The amount of NO contained in the NO2 calibration gas shall not exceed 5 per cent of the NO2 content.
 5.2. 
Gas dividers, i.e., precision blending devices that dilute with purified N2 or synthetic air, can be used to obtain calibration and span gases. The accuracy of the gas divider shall be such that the concentration of the blended calibration gases is accurate to within ± 2 per cent. The verification shall be performed at between 15 and 50 per cent of full scale for each calibration incorporating a gas divider. An additional verification may be performed using another calibration gas, if the first verification has failed.

Optionally, the gas divider may be checked with an instrument which by nature is linear, e.g. using NO gas in combination with a CLD. The span value of the instrument shall be adjusted with the span gas directly connected to the instrument. The gas divider shall be checked at the settings typically used and the nominal value shall be compared with the concentration measured by the instrument. The difference shall in each point be within ±1 per cent of the nominal concentration value.
 5.3. 
Oxygen interference check gases consist of a blend of propane, oxygen and nitrogen and shall contain propane at a concentration of 350 ± 75 ppmC1. The concentration shall be determined by gravimetric methods, dynamic blending or the chromatographic analysis of total hydrocarbons plus impurities. The oxygen concentrations of the oxygen interference check gases shall meet the requirements listed in Table 3; the remainder of the oxygen interference check gas shall consist of purified nitrogen.


 Engine type
Compression ignition Positive ignition
O2 concentration 21 ± 1 % 10 ± 1 %
10 ± 1 % 5 ± 1 %
5 ± 1 % 0,5 ± 0,5 %

6. 
This sections will define future requirement for analysers for measuring particle number emissions, once their measurement becomes mandatory.

7.  7.1. 
Instruments, sensors or signals for measuring the exhaust mass flow rate shall have a measuring range and response time appropriate for the accuracy required to measure the exhaust mass flow rate under transient and steady state conditions. The sensitivity of instruments, sensors and signals to shocks, vibration, aging, variability in temperature, ambient air pressure, electromagnetic interferences and other impacts related to vehicle and instrument operation shall be on a level as to minimize additional errors.
 7.2. 
The exhaust mass flow rate shall be determined by a direct measurement method applied in either of the following instruments:


((a)) Pitot-based flow devices;
((b)) Pressure differential devices like flow nozzle (details see ISO 5167);
((c)) Ultrasonic flow meter;
((d)) Vortex flow meter.

Each individual exhaust mass flow meter shall fulfil the linearity requirements set out in point 3. Furthermore, the instrument manufacturer shall demonstrate the compliance of each type of exhaust mass flow meter with the specifications in points 7.2.3 to 7.2.9.

It is permissible to calculate the exhaust mass flow rate based on air flow and fuel flow measurements obtained from traceably calibrated sensors if these fulfil the linearity requirements of point 3, the accuracy requirements of point 8 and if the resulting exhaust mass flow rate is validated according to point 4 of Appendix 3.

In addition, other methods that determine the exhaust mass flow rate based on not directly traceable instruments and signals, such as simplified exhaust mass flow meters or ECU signals are permissible if the resulting exhaust mass flow rate fulfils the linearity requirements of point 3 and is validated according to point 4 of Appendix 3.
 7.2.1. 
The measurement performance of exhaust mass flow meters shall be verified with air or exhaust gas against a traceable standard such as, e.g. a calibrated exhaust mass flow meter or a full flow dilution tunnel.
 7.2.2. 
The compliance of exhaust mass flow meters with points 7.2.3 and 7.2.9 shall be verified no longer than one year before the actual test.
 7.2.3. 
The accuracy, defined as the deviation of the EFM reading from the reference flow value, shall not exceed ± 2 percent of the reading, 0,5 % of full scale or ± 1,0 per cent of the maximum flow at which the EFM has been calibrated, whichever is larger.
 7.2.4. 
The precision, defined as 2,5 times the standard deviation of 10 repetitive responses to a given nominal flow, approximately in the middle of the calibration range, shall not exceed 1 per cent of the maximum flow at which the EFM has been calibrated.
 7.2.5. 
The noise, defined as two times the root mean square of ten standard deviations, each calculated from the zero responses measured at a constant recording frequency of at least 1,0 Hz during a period of 30 seconds, shall not exceed 2 per cent of the maximum calibrated flow value. Each of the 10 measurement periods shall be interspersed with an interval of 30 seconds in which the EFM is exposed to the maximum calibrated flow.
 7.2.6. 
The zero response drift is defined as the mean response to zero flow during a time interval of at least 30 seconds. The zero response drift can be verified based on the reported primary signals, e.g., pressure. The drift of the primary signals over a period of 4 hours shall be less than ±2 per cent of the maximum value of the primary signal recorded at the flow at which the EFM was calibrated.
 7.2.7. 
The span response drift is defined as the mean response to a span flow during a time interval of at least 30 seconds. The span response drift can be verified based on the reported primary signals, e.g., pressure. The drift of the primary signals over a period of 4 hours shall be less than ± 2 per cent of the maximum value of the primary signal recorded at the flow at which the EFM was calibrated.
 7.2.8. 
The rise time of the exhaust flow instruments and methods should match as far as possible the rise time of the gas analysers as specified in point 4.2.7 but shall not exceed 1 second.
 7.2.9. 
The response time of exhaust mass flow meters shall be determined by applying similar parameters as those applied for the emissions test (i.e., pressure, flow rates, filter settings and all other response time influences). The response time determination shall be done with gas switching directly at the inlet of the exhaust mass flow meter. The gas flow switching shall be done as fast as possible, but highly recommended in less than 0,1 second. The gas flow rate used for the test shall cause a flow rate change of at least 60 per cent full scale of the exhaust mass flow meter. The gas flow shall be recorded. The delay time is defined as the time from the gas flow switching (t0) until the response is 10 per cent (t10) of the final reading. The rise time is defined as the time between 10 per cent and 90 per cent response (t90 – t10) of the final reading. The response time (t90) is defined as the sum of the delay time and the rise time. The exhaust mass flow meter response time (t90) shall be ≤ 3 seconds with a rise time (t90 – t10) of ≤ 1 second in accordance with point 7.2.8.

8. 
Any sensor and auxiliary equipment used to determine, e.g., temperature, atmospheric pressure, ambient humidity, vehicle speed, fuel flow or intake air flow shall not alter or unduly affect the performance of the vehicle’s engine and exhaust after-treatment system. The accuracy of sensors and auxiliary equipment shall fulfil the requirements of Table 4. Compliance with the requirements of Table 4 shall be demonstrated at intervals specified by the instrument manufacturer, as required by internal audit procedures or in accordance with ISO 9000.


Measurement parameter Accuracy
Fuel flow ± 1 % of reading
Air flow ± 2 % of reading
Vehicle speed ± 1,0 km/h absolute
Temperatures ≤600 K ± 2 K absolute
Temperatures >600 K ± 0,4 % of reading in Kelvin
Ambient pressure ± 0,2 kPa absolute
Relative humidity ± 5 % absolute
Absolute humidity ± 10 % of reading or, 1 gH2O/kg dry air, whichever is larger




Appendix 3
1. 
This appendix describes the requirements to validate under transient conditions the functionality of the installed PEMS as well as the correctness of the exhaust mass flow rate obtained from non-traceable exhaust mass flow meters or calculated from ECU signals.

2. 
%per cent#/kmnumber per kilometrea0y intercept of the regression linea1slope of the regression lineg/kmgramme per kilometreHzhertzkmkilometremmetremg/kmmilligramme per kilometrer2coefficient of determinationxactual value of the reference signalyactual value of the signal under validation

3.  3.1. 
It is recommended to validate the installed PEMS once for each PEMS-vehicle combination either before the RDE test or, alternatively, after the completion of the test.
 3.2.  3.2.1. 
The PEMS shall be installed and prepared according to the requirements of Appendix 1. The PEMS installation shall be kept unchanged in the time period between the validation and the RDE test.
 3.2.2. 
The validation test shall be conducted on a chassis dynamometer, as far as applicable, under type approval conditions by following the requirements of Annex 4a to UN/ECE Regulation No 83, 07 series of amendments or any other adequate measurement method. It is recommended to conduct the validation test with the Worldwide harmonized Light vehicles Test Cycle (WLTC) as specified in Annex 1 to UNECE Global Technical Regulation No. 15. The ambient temperature shall be within the range specified in point 5.2 of this Annex.

It is recommended to feed the exhaust flow extracted by the PEMS during the validation test back to the CVS. If this is not feasible, the CVS results shall be corrected for the extracted exhaust mass. If the exhaust mass flow rate is validated with an exhaust mass flow meter, it is recommended to cross-check the mass flow rate measurements with data obtained from a sensor or the ECU.
 3.2.3. 
The total distance-specific emissions [g/km] measured with laboratory equipment shall be calculated following Annex 4a to UN/ECE Regulation No 83, 07 series of amendments. The emissions as measured with the PEMS shall be calculated according to point 9 of Appendix 4, summed to give the total mass of pollutant emissions [g] and then divided by the test distance [km] as obtained from the chassis dynamometer. The total distance-specific mass of pollutants [g/km], as determined by the PEMS and the reference laboratory system, shall be evaluated against the requirements specified in point 3.3. For the validation of NOX emission measurements, humidity correction shall be applied following point 6.6.5 of Annex 4a to UN/ECE Regulation No 83, 07 series of amendments.
 3.3. 
The PEMS validation results shall fulfil the requirements given in Table 1. If any permissible tolerance is not met, corrective action shall be taken and the PEMS validation shall be repeated.


Parameter [Unit] Permissible tolerance
Distance [km] ± 250 m of the laboratory reference
THC [mg/km] ± 15 mg/km or 15 % of the laboratory reference, whichever is larger
CH4 [mg/km] ± 15 mg/km or 15 % of the laboratory reference, whichever is larger
NMHC [mg/km] ± 20 mg/km or 20 % of the laboratory reference, whichever is larger
PN [#/km] 
CO [mg/km] ± 150 mg/km or 15 % of the laboratory reference, whichever is larger
CO2 [g/km] ± 10 g/km or 10 % of the laboratory reference, whichever is larger
NOx [mg/km] ± 15 mg/km or 15 % of the laboratory reference, whichever is larger




4.  4.1. 
In addition to fulfilling the linearity requirements of point 3 of Appendix 2 under steady-state conditions, the linearity of non-traceable exhaust mass flow meters or the exhaust mass flow rate calculated from non-traceable sensors or ECU signals shall be validated under transient conditions for each test vehicle against a calibrated exhaust mass flow meter or the CVS. The validation can be executed without the installation of the PEMS but shall generally follow the requirements defined in Annex 4a to UN/ECE Regulation No 83, 07 series of amendments and the requirements pertinent to exhaust mass flow meters defined in Appendix 1.
 4.2. 
The validation shall be conducted on a chassis dynamometer under type approval conditions, as far as applicable, by following the requirements of Annex 4a to UN/ECE Regulation No 83, 07 series of amendments. The test cycle shall be the Worldwide harmonized Light vehicles Test Cycle (WLTC) as specified in Annex 1 to UNECE Global Technical Regulation No. 15. As reference, a traceably calibrated flow meter shall be used. The ambient temperature can be any within the range specified in point 5.2 of this Annex. The installation of the exhaust mass flow meter and the execution of the test shall fulfil the requirement of point 3.4.3 of Appendix 1 of this Annex.

The following calculation steps shall be taken to validate the linearity:


((a)) The signal under validation and the reference signal shall be time corrected by following, as far as applicable, the requirements of point 3 of Appendix 4.
((b)) Points below 10 % of the maximum flow value shall be excluded from the further analysis.
((c)) At a constant frequency of at least 1,0 Hz, the signal under validation and the reference signal shall be correlated using the best-fit equation having the form:
y=a1x+ a0
where:
yis the actual value of the signal under validationa1is the slope of the regression linexis the actual value of the reference signala0is the y intercept of the regression line
The standard error of estimate (SEE) of y on x and the coefficient of determination (r2) shall be calculated for each measurement parameter and system.
((d)) The linear regression parameters shall meet the requirements specified in Table 2.
 4.3. 
The linearity requirements given in Table 2 shall be fulfilled. If any permissible tolerance is not met, corrective action shall be taken and the validation shall be repeated.


Measurement parameter/system a0 Slope a1 Standard errorSEE Coefficient of determinationr2
Exhaust mass flow 0,0 ± 3,0 kg/h 1,00 ± 0,075 ≤10 % max ≥ 0,90

Appendix 4
1. 
This appendix describes the procedure to determine the instantaneous mass and particle number emissions [g/s; #/s] that shall be used for the subsequent evaluation of a RDE trip and the calculation of the final emission result as described in Appendices 5 and 6.

2. 
%per cent<smaller than#/snumber per secondαmolar hydrogen ratio (H/C)βmolar carbon ratio (C/C)γmolar sulphur ratio (S/C)δmolar nitrogen ratio (N/C)Δtt,itransformation time t of the analyser [s]Δtt,mtransformation time t of the exhaust mass flow meter [s]εmolar oxygen ratio (O/C)ρedensity of the exhaustρgasdensity of the exhaust component ‘gas’λexcess air ratioλiinstantaneous excess air ratioA/Fststoichiometric air-to-fuel ratio [kg/kg]°Cdegrees centigradecCH4concentration of methanecCOdry CO concentration [%]cCO2dry CO2 concentration [%]cdrydry concentration of a pollutant in ppm or per cent volumecgas,iinstantaneous concentration of the exhaust component ‘gas’ [ppm]cHCwwet HC concentration [ppm]cHC(w/NMC)HC concentration with CH4 or C2H6 flowing through the NMC [ppmC1]cHC(w/oNMC)HC concentration with CH4 or C2H6 bypassing the NMC [ppmC1]ci,ctime-corrected concentration of component i [ppm]ci,rconcentration of component i [ppm] in the exhaustcNMHCconcentration of non-methane hydrocarbonscwetwet concentration of a pollutant in ppm or per cent volumeEEethane efficiencyEMmethane efficiencyggrammeg/sgramme per secondHaintake air humidity [g water per kg dry air]inumber of the measurementkgkilogrammekg/hkilogramme per hourkg/skilogramme per secondkwdry-wet correction factormmetremgas,imass of the exhaust component ‘gas’ [g/s]qmaw,iinstantaneous intake air mass flow rate [kg/s]qm,ctime-corrected exhaust mass flow rate [kg/s]qmew,iinstantaneous exhaust mass flow rate [kg/s]qmf,iinstantaneous fuel mass flow rate [kg/s]qm,rraw exhaust mass flow rate [kg/s]rcross-correlation coefficientr2coefficient of determinationrhhydrocarbon response factorrpmrevolutions per minutessecondugasu value of the exhaust component ‘gas’

3. 
For the correct calculation of distance-specific emissions, the recorded traces of component concentrations, exhaust mass flow rate, vehicle speed, and other vehicle data shall be time corrected. To facilitate the time correction, data which are subject to time alignment shall be recorded either in a single data recording device or with a synchronised timestamp following point 5.1 of Appendix 1. The time correction and alignment of parameters shall be carried out by following the sequence described in points 3.1 to 3.3.
 3.1. 
The recorded traces of all component concentrations shall be time corrected by reverse shifting according to the transformation times of the respective analysers. The transformation time of analysers shall be determined according to point 4.4 of Appendix 2:
 c i,c t− Δt t,i= c i,r t
where:

ci,cis the time-corrected concentration of component i as function of time tci,ris the raw concentration of component i as function of time tΔtt,iis the transformation time t of the analyser measuring component i
 3.2. 
The exhaust mass flow rate measured with an exhaust flow meter shall be time corrected by reverse shifting according to the transformation time of the exhaust mass flow meter. The transformation time of the mass flow meter shall be determined according to point 4.4.9 of Appendix 2:
 q m,c t− Δt t,m= q m,r t
where:

qm,cis the time-corrected exhaust mass flow rate as function of time tqm,ris the raw exhaust mass flow rate as function of time tΔtt,mis the transformation time t of the exhaust mass flow meter

In case the exhaust mass flow rate is determined by ECU data or a sensor, an additional transformation time shall be considered and obtained by cross-correlation between the calculated exhaust mass flow rate and the exhaust mass flow rate measured following point 4 of Appendix 3.
 3.3. 
Other data obtained from a sensor or the ECU shall be time-aligned by cross-correlation with suitable emission data (e.g., component concentrations).
 3.3.1. 
To time align vehicle speed with the exhaust mass flow rate, it is first necessary to establish one valid speed trace. In case vehicle speed is obtained from multiple sources (e.g., the GPS, a sensor or the ECU), the speed values shall be time aligned by cross-correlation.
 3.3.2. 
Vehicle speed shall be time aligned with the exhaust mass flow rate by cross-correlation between the exhaust mass flow rate and the product of vehicle speed and positive acceleration.
 3.3.3. 
The time alignment of signals whose values change slowly and within a small value range, e.g. ambient temperature, can be omitted.

4. 
The cold start period covers the first 5 minutes after initial start of the combustion engine. If the coolant temperature can be reliably determined, the cold start period ends once the coolant has reached 343 K (70 °C) for the first time but no later than 5 min after initial engine start. Cold start emissions shall be recorded.

5. 
Any instantaneous emissions or exhaust flow measurements obtained while the combustion engine is deactivated shall be recorded. In a separate step, the recorded values shall afterward be set to zero by the data post processing. The combustion engine shall be considered as deactivated if two of the following criteria apply: the recorded engine speed is < 50 rpm; the exhaust mass flow rate is measured at < 3 kg/h; the measured exhaust mass flow rate drops to <15 % of the steady-state exhaust mass flow rate at idling.

6. 
In case well-reasoned doubts exist that a trip has been conducted above of the permissible altitude as specified in point 5.2 of this Annex and in case altitude has only been measured with a GPS, the GPS altitude data shall be checked for consistency and, if necessary, corrected. The consistency of data shall be checked by comparing the latitude, longitude and altitude data obtained from the GPS with the altitude indicated by a digital terrain model or a topographic map of suitable scale. Measurements that deviate by more than 40 m from the altitude depicted in the topographic map shall be manually corrected and marked.

7. 
The vehicle speed as determined by the GPS shall be checked for consistency by calculating and comparing the total trip distance with reference measurements obtained from either a sensor, the validated ECU or, alternatively, from a digital road network or topographic map. It is mandatory to correct GPS data for obvious errors, e.g., by applying a dead reckoning sensor, prior to the consistency check. The original and uncorrected data file shall be retained and any corrected data shall be marked. The corrected data shall not exceed an uninterrupted time period of 120 s or a total of 300 s. The total trip distance as calculated from the corrected GPS data shall deviate by no more than 4 % from the reference. If the GPS data do not meet these requirements and no other reliable speed source is available, the test results shall be voided.

8.  8.1. 
If the emissions are measured on a dry basis, the measured concentrations shall be converted to a wet basis as:

where:
 c wet= k w× c dry
cwetis the wet concentration of a pollutant in ppm or per cent volumecdryis the dry concentration of a pollutant in ppm or per cent volumekwis the dry-wet correction factor

The following equation shall be used to calculate kw:
 k w=11+ α× 0,005× c co2+ c co− k w1× 1,008
where:
 k w1=1,608× H a1000+1,608× H a
where:

Hais the intake air humidity [g water per kg dry air]cCO2is the dry CO2 concentration [%]cCOis the dry CO concentration [%]αis the molar hydrogen ratio
 8.2. 
NOx emissions shall not be corrected for ambient temperature and humidity.

9.  9.1. 
The components in the raw exhaust shall be measured with the measurement and sampling analysers described in Appendix 2. The raw concentrations of relevant components shall be measured in accordance with Appendix 1. The data shall be time corrected and aligned in accordance with point 3.
 9.2. 
For methane measurement using a NMC-FID, the calculation of NMHC depends on the calibration gas/method used for the zero/span calibration adjustment. When a FID is used for THC measurement without a NMC, it shall be calibrated with propane/air or propane/N2 in the normal manner. For the calibration of the FID in series with a NMC, the following methods are permitted:


((a)) the calibration gas consisting of propane/air bypasses the NMC;
((b)) the calibration gas consisting of methane/air passes through the NMC.

It is strongly recommended to calibrate the methane FID with methane/air through the NMC.

In method (a), the concentrations of CH4 and NMHC shall be calculated as follows:
 cCH 4=c HC w∕ oNMC× 1− EM− c HC w∕NMC EE− EM c NMHC=c HC w∕ NMC− c HC w∕ oNMC× 1− EErh× EE− EM
In method (b), the concentration of CH4 and NMHC shall be calculated as follows:
 cCH 4=c HCw∕ NMC× rh× 1− EM− c HC w∕ oNMC× 1− EE rh× EE− EM c NMHC=c HC w∕ oNMC× 1− EM− c HC w∕ NMC× rh× 1− EM EE− EM
where:

cHC(w/oNMC)is the HC concentration with CH4 or C2H6 bypassing the NMC [ppmC1]cHC(w/NMC)is the HC concentration with CH4 or C2H6 flowing through the NMC [ppmC1]rhis the hydrocarbon response factor as determined in point 4.3.3.(b) of Appendix 2EMis the methane efficiency as determined in point 4.3.4.(a) of Appendix 2EEis the ethane efficiency as determined in point 4.3.4(b) of Appendix 2

If the methane FID is calibrated through the cutter (method b), then the methane conversion efficiency as determined in point 4.3.4.(a) of Appendix 2 is zero. The density used for calculating the NMHC mass shall be equal to that of total hydrocarbons at 273,15 K and 101,325 kPa and is fuel-dependent.

10.  10.1. 
The calculation of instantaneous mass emissions according to points 11 and 12 requires determining the exhaust mass flow rate. The exhaust mass flow rate shall be determined by one of the direct measurement methods specified in point 7.2 of Appendix 2. Alternatively, it is permissible to calculate the exhaust mass flow rate as described in points 10.2 to 10.4.
 10.2. 
The instantaneous exhaust mass flow rate can be calculated from the air mass flow rate and the fuel mass flow rate as follows:
 q mew,i= q maw,i+ q mf,i
where:

qmew,iis the instantaneous exhaust mass flow rate [kg/s]qmaw,iis the instantaneous intake air mass flow rate [kg/s]qmf,iis the instantaneous fuel mass flow rate [kg/s]

If the air mass flow rate and the fuel mass flow rate or the exhaust mass flow rate are determined from ECU recording, the calculated instantaneous exhaust mass flow rate shall meet the linearity requirements specified for the exhaust mass flow rate in point 3 of Appendix 2 and the validation requirements specified in point 4.3 of Appendix 3.
 10.3. 
The instantaneous exhaust mass flow rate can be calculated from the air mass flow rate and the air-to-fuel ratio as follows:
 q mew,i= q maw,i× 1+1A∕F st× λ i
where:
 A∕F st=138,0×1+α4−ε2+ γ12,011+ 1,008× α+ 15,9994× ε+ 14,0067× δ+ 32,0675× γ λ i= 100−c CO× 10− 42− c HCw× 10− 4+α4×1−2× c CO× 10− 43,5× c CO21+c CO× 10− 43,5× c CO2−ε2−δ2× c CO2+ c CO× 10− 44,764×1+α4−ε2+ γ× c CO2+ c CO× 10− 4+ c HCw× 10− 4
where:

qmaw,iis the instantaneous intake air mass flow rate [kg/s]A/Fstis the stoichiometric air-to-fuel ratio [kg/kg]λiis the instantaneous excess air ratiocCO2is the dry CO2 concentration [%]cCOis the dry CO concentration [ppm]cHCwis the wet HC concentration [ppm]αis the molar hydrogen ratio (H/C)βis the molar carbon ratio (C/C)γis the molar sulphur ratio (S/C)δis the molar nitrogen ratio (N/C)εis the molar oxygen ratio (O/C)

Coefficients refer to a fuel Cβ Hα Oε Nδ Sγ with β = 1 for carbon based fuels. The concentration of HC emissions is typically low and may be omitted when calculating λi.

If the air mass flow rate and air-to-fuel ratio are determined from ECU recording, the calculated instantaneous exhaust mass flow rate shall meet the linearity requirements specified for the exhaust mass flow rate in point 3 of Appendix 2 and the validation requirements specified in point 4.3 of Appendix 3.
 10.4. 
The instantaneous exhaust mass flow rate can be calculated from the fuel flow and the air-to-fuel ratio (calculated with A/Fst and λi according to point 10.3) as follows:
 q mew,i= q mf,i× 1+ A∕F st× λ i
The calculated instantaneous exhaust mass flow rate shall meet the linearity requirements specified for the exhaust gas mass flow rate in point 3 of Appendix 2 and the validation requirements specified in point 4.3 of Appendix 3.

11. 
The instantaneous mass emissions [g/s] shall be determined by multiplying the instantaneous concentration of the pollutant under consideration [ppm] with the instantaneous exhaust mass flow rate [kg/s], both corrected and aligned for the transformation time, and the respective u value of Table 1. If measured on a dry basis, the dry-wet correction according to point 8.1 shall be applied to the instantaneous component concentrations before executing any further calculations. If occurring, negative instantaneous emission values shall enter all subsequent data evaluations. Parameter values shall enter the calculation of instantaneous emissions [g/s] as reported by the analyser, flow-measuring instrument, sensor or the ECU. The following equation shall be applied:

where:

 m gas,i= u gas× cgas,i× q mew,i

mgas,iis the mass of the exhaust component ‘gas’ [g/s]ugasis the ratio of the density of the exhaust component ‘gas’ and the overall density of the exhaust as listed in Table 1cgas,iis the measured concentration of the exhaust component ‘gas’ in the exhaust [ppm]qmew,iis the measured exhaust mass flow rate [kg/s]gasis the respective componentinumber of the measurement


Fuel ρe [kg/m3] Component or pollutant i
NOx CO HC CO2 O2 CH4
ρgas [kg/m3]
2,053 1,25  1,9636 1,4277 0,716
ugas,
Diesel (B7) 1,2943 0,001586 0,000966 0,000482 0,001517 0,001103 0,000553
Ethanol (ED95) 1,2768 0,001609 0,00098 0,00078 0,001539 0,001119 0,000561
CNG 1,2661 0,001621 0,000987 0,000528 0,001551 0,001128 0,000565
Propane 1,2805 0,001603 0,000976 0,000512 0,001533 0,001115 0,000559
Butane 1,2832 0,0016 0,000974 0,000505 0,00153 0,001113 0,000558
LPG 1,2811 0,001602 0,000976 0,00051 0,001533 0,001115 0,000559
Petrol (E10) 1,2931 0,001587 0,000966 0,000499 0,001518 0,001104 0,000553
Ethanol (E85) 1,2797 0,001604 0,000977 0,00073 0,001534 0,001116 0,000559







12. 
This sections will define the requirement for calculating instantaneous particle number emissions, once their measurement becomes mandatory.

13. 
The data shall be exchanged between the measurement systems and the data evaluation software by a standardised reporting file as specified in point 2 of Appendix 8. Any pre-processing of data (e.g. time correction according to point 3 or the correction of the GPS vehicle speed signal according to point 7) shall be done with the control software of the measurement systems and shall be completed before the data reporting file is generated. If data are corrected or processed prior to entering the data reporting file, the original raw data shall be kept for quality assurance and control. Rounding of intermediate values is not permitted.

Appendix 5
1. 
The Moving Averaging Window method provides an insight on the real-driving emissions (RDE) occurring during the test at a given scale. The test is divided in sub-sections (windows) and the subsequent statistical treatment aims at identifying which windows are suitable to assess the vehicle RDE performance.

The ‘normality’ of the windows is conducted by comparing their CO2 distance-specific emissions with a reference curve. The test is complete when the test includes a sufficient number of normal windows, covering different speed areas (urban, rural, motorway).

Step 1.Segmentation of the data and exclusion of cold start emissions (section 4 in Appendix 4);Step 2.Calculation of emissions by sub-sets or ‘windows’ (section 3.1);Step 3.Identification of normal windows (section 4);Step 4.Verification of trip completeness and normality (section 5);Step 5.Calculation of emissions using the normal windows (section 6).

2. 
Index (i) refers to the time step

Index (j) refers to the window

Index (k) refers to the category (t=total, u=urban, r=rural, m=motorway) or to the CO2 characteristic curve (cc)

Index ‘gas’ refers to the regulated exhaust gas components (e.g. NOx, CO, PN)

Δdifference≥larger or equal#number%per cent≤smaller or equala1, b1coefficients of the CO2 characteristic curvea2, b2coefficients of the CO2 characteristic curvedjdistance covered by window j [km]fkweighting factors for urban, rural and motorway shareshdistance of windows to the CO2 characteristic curve [%]hjdistance of window j to the CO2 characteristic curve [%]h–kseverity index for urban, rural and motorway shares and the complete tripk11, k12coefficients of the weighting functionk21, k21coefficients of the weighting functionMCO2,refreference CO2 mass [g]Mgasmass or particle number of the exhaust component ‘gas’ [g] or [#]Mgas,jmass or particle number of the exhaust component ‘gas’ in window j [g] or [#]Mgas,ddistance-specific emission for the exhaust component ‘gas’ [g/km] or [#/km]Mgas,d,jdistance-specific emission for the exhaust component ‘gas’ in window j [g/km] or [#/km]Nknumber of windows for urban, rural, and motorway sharesP1, P2, P3reference pointsttime [s]t1,jfirst second of the jth averaging window [s]t2,jlast second of the jth averaging window [s]titotal time in step i [s]ti,jtotal time in step i considering window j [s]tol1primary tolerance for the vehicle CO2 characteristic curve [%]tol2secondary tolerance for the vehicle CO2 characteristic curve [%]ttduration of a test [s]vvehicle speed [km/h]v–average speed of windows [km/h]viactual vehicle speed in time step i [km/h]v–javerage vehicle speed in window j [km/h]vP1–=19 km∕haverage speed of the Low Speed phase of the WLTP cyclevP2–=56,6 km∕haverage speed of the High Speed phase of the WLTP cyclevP3–=92,3 km∕haverage speed of the Extra High Speed phase of the WLTP cyclewweighting factor for windowswjweighting factor of window j

3.  3.1. 
The instantaneous emissions calculated according to Appendix 4 shall be integrated using a moving averaging window method, based on the reference CO2 mass. The principle of the calculation is as follows: The mass emissions are not calculated for the complete data set, but for sub-sets of the complete data set, the length of these sub-sets being determined so as to match the CO2 mass emitted by the vehicle over the reference laboratory cycle. The moving average calculations are conducted with a time increment Δt corresponding to the data sampling frequency. These sub-sets used to average the emissions data are referred to as ‘averaging windows’. The calculation described in the present point may be run from the last point (backwards) or from the first point (forward).

The following data shall not be considered for the calculation of the CO2 mass, the emissions and the distance of the averaging windows:


— The periodic verification of the instruments and/or after the zero drift verifications;
— The cold start emissions, defined according to Appendix 4, point 4.4;
— Vehicle ground speed < 1 km/h;
— Any section of the test during which the combustion engine is switched off.

The mass (or particle number) emissions Mgas,j shall be determined by integrating the instantaneous emissions in g/s (or #/s for PN) calculated as specified in Appendix 4.

Figure 1
Figure 2The duration t2,j− t1,j of the jth averaging window is determined by: MCO 2t 2,j− MCO 2t 1,j≥ MCO 2,refwhere:MCO2ti,j is the CO2 mass measured between the test start and time (t2,j) [g];MCO2,ref is the half of the CO2 mass [g] emitted by the vehicle over the Worldwide harmonized Light vehicles Test Cycle (WLTC) described in the UNECE Global Technical Regulation No. 15 - Worldwide harmonized Light vehicles Test Procedure (ECE/TRANS/180/Add.15; Type I test, including cold start);t2,j shall be selected such as: MCO 2t 2,j− Δt−MCO 2t 1,j< MCO 2,ref≤ MCO 2t 2,j− MCO 2t 1,jwhere Δt is the data sampling period.The CO2 masses are calculated in the windows by integrating the instantaneous emissions calculated as specified in Appendix 4 to this Annex. 3.2. 
The following shall be calculated for each window determined in accordance with point 3.1.,


— The distance-specific emissions Mgas,d,j for all the pollutants specified in this annex;
— The distance-specific CO2 emissions MCO2,d,j;
— The average vehicle speed v–j

4.  4.1. 
The reference dynamic conditions of the test vehicle are set out from the vehicle CO2 emissions versus average speed measured at type approval and referred to as ‘vehicle CO2 characteristic curve’.

To obtain the distance-specific CO2 emissions, the vehicle shall be tested on the chassis dynamometer by applying the vehicle road load settings as determined following the procedure prescribed in Annex 4 of the UNECE Global Technical Regulation No. 15 - Worldwide harmonized Light vehicles Test Procedure (ECE/TRANS/180/Add.15). The road loads shall not account for the mass added to the vehicle during the RDE test, e.g. the co-pilot and the PEMS equipment.
 4.2. 
The reference points P1,P2 and P3 required to define the curve shall be established as follows:
 4.2.1. 
vP1–=19 km/h (average speed of the Low Speed phase of the WLTP cycle)

MCO2,d,P1 = Vehicle CO2 emissions over the Low Speed phase of the WLTP cycle x 1,2 [g/km]
 4.2.2.  4.2.3. vP2–=56,6 km/h(average speed of the High Speed phase of the WLTP cycle)
MCO2,d,P2 = Vehicle CO2 emissions over the High Speed phase of the WLTP cycle x 1.1 [g/km]
 4.2.4.  4.2.5. 
MCO2,d,P3 = Vehicle CO2 emissions over the Extra High Speed phase of the WLTP cycle x 1,05 [g/km]
 4.3. 
Using the reference points defined in section 4.2, the characteristic curve CO2 emissions are calculated as a function of the average speed using two linear sections (P1, P2) and (P2, P3). The section (P2, P3) is limited to 145 km/h on the vehicle speed axis. The characteristic curve is defined by equations as follows:

For the section (P1,P2):
 MCO 2,d,CCv–= a 1v–+ b 1
witha1=MCO2,d,P2− MCO2,d,P1∕vP2–−vP1–andb1=MCO2,d,P1− a1vP1–

For the section (P2,P3):
 MCO 2,d,C Cv–=a 2v–+ b 2
witha2=MCO2,d,P3− MCO2,d,P2∕vP3–−vP2–andb2=MCO2,d,P2− a2vP2–

Figure 3 4.4.  4.4.1. Urban windows are characterized by average vehicle ground speeds v–j smaller than 45 km/h,
 4.4.2. Rural windows are characterized by average vehicle ground speeds v–j greater than or equal to 45 km/h and smaller than 80 km/h,
 4.4.3. Motorway windows are characterized by average vehicle ground speeds v–j greater than or equal to 80 km/h and smaller than 145 km/h

Figure 4
5.  5.1. 
The primary tolerance and the secondary tolerance of the vehicle CO2 characteristic curve are respectively tol1 = 25 % and tol2 = 50 %.
 5.2. 
The test shall be complete when it comprises at least 15 % of urban, rural and motorway windows, out of the total number of windows.
 5.3. 
The test shall be normal when at least 50 % of the urban, rural and motorway windows are within the primary tolerance defined for the characteristic curve.

If the specified minimum requirement of 50 % is not met, the upper positive tolerance tol1 may be increased by steps of 1 percentage point until the 50 % of normal windows target is reached. When using this approach, tol1 shall never exceed 30 %.

6.  6.1. 
The emissions shall be calculated as a weighted average of the windows' distance-specific emissions separately for the urban, rural and motorway categories and the complete trip.
 Mgas,d,k=∑wjMgas,d,j∑wj k= u,r,m
The weighting factor wj for each window shall be determined as such:

IfMCO2,d,CCv–j×1− tol1∕100≤MCO2,d,j≤MCO2,d,C Cv–j×1+ tol1∕100

Then wj=1

If
 MCO2,d,CCv–j× 1+ tol 1∕ 100< MCO2,d,j≤ MCO2,d,CCv–j× 1+ tol 2∕ 100
Then wj=k11hj+ k12

Withk11=1∕tol1− tol2

andk12=tol2∕tol2− tol1

If
 MCO2,d,CCv–j× 1− tol 2∕ 100≤ MCO2,d,j< MCO2,d,CCv–j× 1− tol 1∕ 100
Then wj=k21hj+ k22

withk21=1∕tol2− tol1

andk22=k12=tol2∕tol2− tol1

If
MCO2,d,j< MCO2,d,CCv–j× 1− tol 2∕ 100
or
 MCO2,d,j> MCO2,d,CCv–j× 1+ tol 2∕ 100
Then wj=0

where:
hj= 100×MCO2,d,j− MCO2,d,CCv–jMCO2,d,ccv–j Figure 5  6.2. 
The severity indices shall be calculated separately for the urban, rural and motorway categories:
h–k=1Nk∑hj k=u,r,m
and the complete trip:
h–t=ƒuh–u+ƒrh–r+ƒmh–mƒu+ƒr+ƒm
where ƒu, ƒr ƒm are equal to 0,34, 0,33 and 0,33 respectively.
 6.3. 
Using the weighted distance-specific emissions calculated under point 6.1, the distance-specific emissions in [mg/km] shall be calculated for the complete trip each gaseous pollutant in the following way:
Mgas,d,t=1000×ƒu× Mgas,d,u+ƒr× Mgas,d,r+ƒm× Mgas,d,mƒu+ƒr+ƒm
And for particle number:
MPN,d,t=ƒu× MPN,d,u+ƒr× MPN,d,r+ƒm× MPN,d,mƒu+ƒr+ƒm
Where ƒu, ƒr ƒm are respectively equal to 0,34, 0,33 and 0,33.

7.  7.1. 

MCO2,ref [g] 610
Direction for averaging window calculation Forward
Acquisition Frequency [Hz] 1

Figure 6 shows how averaging windows are defined on the basis of data recorded during an on-road test performed with PEMS. For sake of clarity, only the first 1 200 seconds of the trip are shown hereafter.

Seconds 0 up to 43 as well as seconds 81 to 86 are excluded due to operation under zero vehicle speed.

The first averaging window starts at t1,1 = 0s and ends at second t2,1 = 524s (Table 3).

Figure 6 7.2. 

CO2 Low Speed WLTC × 1,2 (P1) [g/km] 154
CO2 High Speed WLTC × 1,1 (P2) [g/km] 96
CO2 Extra-High Speed WLTC × 1,05 (P3) [g/km] 120


Reference Point  
P1 vP1–=19,0 km∕h MCO2,d,P1= 154 g∕km
P2 vP2–=56,6 km∕h MCO2,d,P2= 96 g∕km
P3 vP3–=92.3 km∕h MCO2,d,P3= 120 g∕km

The definition of the CO2 characteristic curve is as follows:

For the section (P1, P2):
MCO 2,dv–=a 1v–+ b 1
with
 a 1=96− 154∕56.6− 19.0=−5837.6=− 1.543
and b1=154−− 1,543× 19,0=154+ 29,317=183,317

For the section (P2, P3):
MCO 2,dv–=a 2v–+ b 2
with
 a2=120− 96∕92.3− 56.6=2435.7=0.672
andb2=96− 0,672× 56,6=96− 38,035=57,965

Examples of calculation for the weighting factors and the window categorisation as urban, rural or motorway are:

For window #45:
MCO2,d,45= 122,62 g∕kmv 45–=38,12 km∕h
The average speed of the window is lower than 45 km/h, therefore it is an urban window.

For the characteristic curve:
MCO 2,d,CCv 45–=a 1v45–+ b1=− 1,543× 38,12+ 183,317=124,498 g∕km
Verification of:
MCO2,d,CCvj–× 1− tol 1∕ 100≤ MCO2,d,j≤MCO2,d,CCvj–× 1+ tol 1∕ 100MCO2,d,CCv45–× 1− tol 1∕ 100≤MCO2,d,45≤MCO2,d,CCv45–× 1+ tol 1∕ 100124,498×1− 25∕100≤122,62≤124,498×1+ 25∕10093,373≤ 122,62≤ 155,622
Leads to: w45=1

For window #556:
MCO2,d,556= 72,15 g∕kmv 556–=50,12 km∕h
The average speed of the window is higher than 45 km/h but lower than 80 km/h, therefore it is a rural window.

For the characteristic curve:
MCO2,d,CCv 556–=a 1v 556–+ b 1=− 1,543× 50,12+ 183,317=105,982 g∕km
Verification of:
MCO2,d,CCvj–× 1− tol 2∕ 100≤MCO2,d,j<MCO2,d,CCvj–× 1− tol 1∕ 100MCO2,d,CCv– 556×1− tol 2∕ 100≤ MCO2,d,556<MCO2,d,CCv– 556× 1− tol 1∕ 100105,982×1− 50∕100≤72,15<105,982×1− 25∕10052,991≤ 72,15< 79,487
Leads to:
h 556= 100×MCO2,d,556− MCO2,d,CCv– 556MCO2,d,CCv– 556=100×72,15− 105,982105,982=− 31,922 w 556= k 21 h 556+ k 22= 0,04×− 31.922+ 2=0,723
withk21=1∕tol2− tol1=1∕50− 25=0,04

and k22=k12=tol2∕tol2− tol1=50∕50− 25=2


Window[#] t1,j[s] t2,j−Δt[s] t2,j[s] MCO2t2,j− Δt− MCO2t1,j<MCO2,ref[g] MCO2t2,j− MCO2t1,j≥CO2,ref[g]
     
1 0 523 524 609,06 610,22
2 1 523 524 609,06 610,22
… …  … … …
43 42 523 524 609,06 610,22
44 43 523 524 609,06 610,22
45 44 523 524 609,06 610,22
46 45 524 525 609,68 610,86
47 46 524 525 609,17 610,34
… …  … … …
100 99 563 564 609,69 612,74
… …  … … …
200 199 686 687 608,44 610,01
… …  … … …
474 473 1 024 1 025 609,84 610,6
475 474 1 029 1 030 609,8 610,49
 …  … … …
556 555 1 173 1 174 609,96 610,59
557 556 1 174 1 175 609,09 610,08
558 557 1 176 1 177 609,09 610,59
559 558 1 180 1 181 609,79 611,23
 7.3. 
In this numerical example, the trip consists of 7 036 averaging windows. Table 5 lists the number of windows classified in urban, rural and motorway according to their average vehicle speed and divided in regions with respect to their distance to the CO2 characteristic curve. The trip is complete since it comprises at least 15 % of urban, rural and motorway windows out of the total number of windows. In addition the trip is characterized as normal since at least 50 % of the urban, rural and motorway windows are within the primary tolerances defined for the characteristic curve.


Driving Conditions Numbers Percentage of windows
All Windows
Urban 1 909 1 909/7 036*100=27,1 > 15
Rural 2 011 2 011/7 036*100=28,6 > 15
Motorway 3 116 3 116/7 036*100=44,3 > 15
Total 1 909 + 2 011 + 3 116=7 036 
Normal Windows
Urban 1 514 1 514/1 909*100=79,3 > 50
Rural 1 395 1 395/2 011*100=69,4 > 50
Motorway 2 708 2 708/3 116*100=86,9 > 50
Total 1 514 + 1 395+2 708=5 617 

Appendix 6
1. 
This Appendix describes the data evaluation according to the power binning method, named in this appendix ‘evaluation by normalisation to a standardised power frequency (SPF) distribution’

2. 
aref…Reference acceleration for Pdrive, [0,45 m/s2]DWLTC…intercept of the Veline from WLTCf0, f1, f2…Driving resistance coefficients [N], [N/(km/h)], [N/(km/h)2]i…Time step for instantaneous measurements, minimum resolution 1Hzj…Wheel power class, j=1 to 9k…Time step for the 3 second moving average valueskWLTC…Slope of the Veline from WLTCmgas, i…Instantaneous mass of the exhaust component ‘gas’ at time step i, [g/s]; for PN in [#/s]mgas, 3s, k…3 second moving average mass flow of the exhaust gas component ‘gas’ in time step k given in 1 Hz resolution [g/s]; for PN in [#/s]m–gas,j…Average emission value of an exhaust gas component in the wheel power class j, [g/s]; for PN in [#/s]m–gas,U…Weighted emission value of an exhaust gas component ‘gas’ for the subsample of all seconds i with vi < 60 km/h, [g/s]; for PN in [#/s]Mw gas,d…Weighted distance-specific emissions for the exhaust gas component ‘gas’ for the entire trip, [g/km]; for PN in [#/km]Mw PN,d…Weighted distance-specific emissions for the exhaust gas component ‘PN’ for the entire trip, [#/km]Mw,gas,d,U…Weighted distance-specific emissions for the exhaust gas component ‘gas’ for the subsample of all seconds i with vi < 60 km/h, [g/km]Mw,PN,d,U…Weighted distance-specific emissions for the exhaust gas component ‘PN’ for the subsample of all seconds i with vi < 60 km/h, [#/km]p…Phase of WLTC (low, medium, high and extra-high), p=1-4Pdrag…Engine drag power in the Veline approach where fuel injection is zero, [kW]Prated…Maximum rated engine power as declared by the manufacturer, [kW]Prequired,i…Power to overcome road load and inertia of a vehicle at time step i, [kW]Pr,,i…Same as Prequired,i defined above used in longer equationsPwot(nnorm)…Full load power curve, [kW]Pc,j…Wheel power class limits for class number j, [kW] (Pc,j, lower bound represents the lower limit Pc,j, upper bound the upper limit)Pc,norm, j…Wheel power class limits for class j as normalised power value, [-]Pr, i…Power demand at the vehicles wheel hubs to overcome driving resistances in time step i [kW]Pw,3s,k…3 second moving average power demand at the vehicles wheel hubs to overcome driving resistances in in time step k in 1 Hz resolution [kW]Pdrive…Power demand at the wheel hubs for a vehicle at reference speed and acceleration [kW]Pnorm…Normalised power demand at the wheel hubs [-]ti…Total time in step i, [s]tc,j…Time share of the wheel power class j, [%]ts…Start time of the WLTC phase p, [s]te…end time of the WLTC phase p, [s]TM…Test mass of the vehicle, [kg]; to be specified per section: real test weight in PEMS test, NEDC inertia class weight or WLTP masses (TML, TMH or TMind)SPF…Standardised Power Frequency distributionvi…Actual vehicle speed in time step i, [km/h]v–j…Average vehicle speed in the wheel power class j, km/hvref…Reference velocity for Pdrive, [70 km/h]v3s,k…3 seconds moving average of the vehicle velocity in time step k, [km/h]v–U…Weighted vehicle speed in the wheel power class j, [km/h]

3. 
The power binning method uses the instantaneous emissions of the pollutants, mgas, i (g/s) calculated in accordance with Appendix 4.

The mgas, i values shall be classified in accordance with the corresponding power at the wheels and the classified average emissions per power class shall be weighted to obtain the emission values for a test with a normal power distribution according to the following points.
 3.1. 
The actual wheel power Pr,i shall be the total power to overcome air resistance, rolling resistance, road gradients, longitudinal inertia of the vehicle and rotational inertia of the wheels.

When measured and recorded, the wheel power signal shall use a torque signal meeting the linearity requirements laid down in Appendix 2, point 3.2. The reference point for measurement are the wheel hubs of the driven wheels.

As an alternative, the actual wheel power may be determined from the instantaneous CO2 emissions following the procedure laid down in point 4 of this Appendix.
 3.2. 
Three second moving averages shall be calculated from all relevant instantaneous test data to reduce influences of possibly imperfect time alignment between emission mass flow and wheel power. The moving average values shall be computed in a 1 Hz frequency:
mgas,3s,k=∑k+ 2i= kmgas,i3Pw,3s,k=∑k+ 2i= kPw,i3v3s,k=∑k+ 2i= kvi3
Where

k…time step for moving average valuesi…time step from instantaneous test data
 3.3. 
The standard power frequencies are defined for urban driving and for the total trip (see paragraph 3.4) and a separate evaluation of the emissions shall be made for the total trip and for the urban part. For the later evaluation of the urban part of the trip, the three second moving averages calculated according to paragraph 3.2 shall be allocated to urban driving conditions according to the three second moving average of the velocity signal (v3s,k) following the speed range defined in Table 1-1. The sample for the total trip evaluation shall cover all speed ranges including also the urban part.


 Urban Rural Motorway
vi [km/h] 0 to ≤ 60 > 60 to ≦ 90 > 90

 3.4.  3.4.1. The power classes and the corresponding time shares of the power classes in normal driving are defined for normalized power values to be representative for any LDV (Table 1).

Powerclass No. Pc,norm,j [-] Urban Total trip
From > to ≤ Time share, tC,j
1  – 0,1 21,9700 % 18,5611 %
2 – 0,1 0,1 28,7900 % 21,8580 %
3 0,1 1 44,0000 % 43,4582 %
4 1 1,9 4,7400 % 13,2690 %
5 1,9 2,8 0,4500 % 2,3767 %
6 2,8 3,7 0,0450 % 0,4232 %
7 3,7 4,6 0,0040 % 0,0511 %
8 4,6 5,5 0,0004 % 0,0024 %
9 5,5  0,0003 % 0,0003 %
The Pc,norm columns in Table 1 shall be de-normalised by multiplication with Pdrive, where Pdrive is the actual wheel power of the tested car in the type approval settings at the chassis dynamometer at vref and aref.
Pc,j [kW] = Pc,norm,j * Pdrive
Pdrive=vref3.6× f 0+ f 1× vref+ f 2× v2ref+ TMNEDC× aref× 0,001Where:

— j is the power class index according to Table 1
— The driving resistance coefficients f0, f1, f2 should be calculated with a least squares regression analysis from the following definition:
PCorrected∕v=f0+ f1× v+ f2× v2
with (PCorrected/v) being the road load force at vehicle velocity v for the NEDC test cycle defined in point 5.1.1.2.8 of Appendix 7 to Annex 4a of UNECE Regulation 83 - 07 series of amendments.
— TMNEDC is the inertia class of the vehicle in the type approval test, [kg]
 3.4.2. 
The maximum wheel power class to be considered is the highest class in Table 1 which includes (Prated × 0.9). The time shares of all excluded classes shall be added to the highest remaining class.

From each Pc,norm,j the corresponding Pc,j shall be calculated to define the upper and lower bounds in kW per wheel power class for the tested vehicle as shown in Figure 1.

Figure 1
An example for this de-normalisation is given below.


Parameter Value
f0 [N] 79,19
f1 [N/(km/h)] 0,73
f2 [N/(km/h)2] 0,03
TM [kg] 1,47
Prated [kW] 120 (Example 1)
Prated [kW] 75 (Example 2)

Corresponding results (see Table 2, Table 3):
Pdrive= 70 km∕h∕ 3,6× 79,19+ 0,73 N∕km∕h× 70 km∕h+ 0,03 N∕km∕h2× 70 km∕h2+ 1470 kg× 0,45 m∕s2× 0,001Pdrive= 18,25 kW

Powerclass No. Pc,j [kW] Urban Total trip
From > to ≤ Time share, tC,j [%]
1 All < – 1,825 – 1,825 21,97 % 18,5611 %
2 – 1,825 1,825 28,79 % 21,8580 %
3 1,825 18,25 44,00 % 43,4583 %
4 18,25 34,675 4,74 % 13,2690 %
5 34,675 51,1 0,45 % 2,3767 %
6 51,1 67,525 0,045 % 0,4232 %
7 67,525 83,95 0,004 % 0,0511 %
8 83,95 100,375 0,0004 % 0,0024 %
9 100,375 All > 100,375 0,00025 % 0,0003 %



Powerclass No. Pc,j [kW] Urban Total trip
From > to ≤ Time share, tC,j [%]
1 All < –1,825 – 1,825 21,97 % 18,5611 %
2 – 1,825 1,825 28,79 % 21,8580 %
3 1,825 18,25 44,00 % 43,4583 %
4 18,25 34,675 4,74 % 13,2690 %
5 34,675 51,1 0,45 % 2,3767 %
6 51,1 All > 51,1 0,04965 % 0,4770 %
7 67,525 83,95 — —
8 83,95 100,375 — —
9 100,375 All > 100,375 — —

 3.5. 
The cold start emissions, defined according to Appendix 4, point 4.4, shall be excluded from the following evaluation.

Each moving average value calculated according to point 3.2 shall be sorted into the de-normalized wheel power class into which the actual 3 second moving average wheel power Pw,3s,k fits. The de-normalised wheel power class limits have to be calculated according to point 3.3.

The classification shall be done for all three second moving averages of the entire valid trip data including also all urban trip parts. Additionally all moving averages classified to urban according to the velocity limits defined in table 1-1 shall be classified into one set of urban power classes independently of the time when the moving average appeared in the trip.

Then the average of all three second moving average values within a wheel power class shall be calculated for each wheel power class per parameter. The equations are described below and shall be applied once for the urban data set and once for the total data set.

Classification of the 3-second moving average values into power class j (j = 1 to 9):
if PC,j lower bound< Pw,3s,k≤ PC,j upper bound
then: class index for emissions and velocity = j

The number of 3-second moving average values shall be counted for each power class:
if PC,j lower bound< Pw,3s,k≤ PC,j upper bound
then: countsj = n + 1 (countsj is counting the number of 3 second moving average emission values in a power class to check later the minimum coverage demands)
 3.6. 
For a valid test the time shares of the single wheel power classes shall be in the ranges listed in Table 4.


Powerclass No. Pc,norm,j [–] Total trip Urban trip parts
From > to ≤ lower bound upper bound lower bound upper bound
Sum 1+2  0,1 15 % 60 % 5 % 60 %
3 0,1 1 35 % 50 % 28 % 50 %
4 1 1,9 7 % 25 % 0,7 % 25 %
5 1,9 2,8 1,0 % 10 % > 5 counts 5 %
6 2,8 3,7 > 5 counts 2,5 % 0 % 2 %
7 3,7 4,6 0 % 1,0 % 0 % 1 %
8 4,6 5,5 0 % 0,5 % 0 % 0,5 %
9 5,5  0 % 0,25 % 0 % 0,25 %


In addition to the requirements in Table 4, a minimum coverage of 5 counts is demanded for the total trip in each wheel power class up to the class containing 90 % of the rated power to provide a sufficient sample size.

A minimum coverage of 5 counts is required for the urban part of the trip in each wheel power class up to class No. 5. If the counts in the urban part of the trip in a wheel power class above number 5 are less than 5, the average class emission value shall be set to zero.
 3.7. 
The moving averages sorted in each wheel power class shall be averaged as follows:
m–gas,j=∑all k in classjmgas,3s,kcountsjv–j=∑all k in classjv3s,kcountsj
Where

j …wheel power class 1 to 9 according to Table 1m–gas,j…average emission value of an exhaust gas component in a wheel power class (separate value for total trip data and for the urban parts of the trip), [g/s]v–j…average velocity in a wheel power class (separate value for total trip data and for the urban parts of the trip), [km/h]k …time step for moving average values
 3.8. 
The average values of each wheel power class shall be multiplied with the time share, tC,j per class according to Table 1 and summed up to produce the weighted average value for each parameter. This value represents the weighted result for a trip with the standardised power frequencies. The weighted averages shall be computed for the urban part of the test data using the time shares for urban power distribution as well as for the total trip using the time shares for the total.

The equations are described below and shall be applied once for the urban data set and once for the total data set.
m–gas=∑9j= 1m–gas,j× tc,jv–=∑j= 19v–j× tc,j 3.9 
The time based weighted averages of the emissions in the test shall be converted into distance based emissions once for the urban data set and once for the total data set as follows:

For the total tripMw,gas,d=m–gas×3600v–For the urban part of the tripMw,gas,d,U=m–gas,U×3600v–U

For particle number the same method as for gaseous pollutants shall be applied but the unit [#/s] shall be used for m–PN and [#/km] shall be used for Mw,PN:

For the total tripMw,PN,d=m–PN×3600v–For the urban part of the tripMw,PN,d,U=m–PN×3600v–U

4. 
The power at the wheels (Pw,i) can be computed from the measured CO2 mass flow in 1 Hz. For this calculation the vehicle specific CO2 line (‘Veline’) shall be used.

The Veline shall be calculated from the vehicle type approval test in the WLTC according to the test procedure described in UNECE Global Technical Regulation No. 15 - Worldwide harmonized Light vehicles Test Procedure (ECE/TRANS/180/Add.15).

The average wheel power per WLTC phase shall be calculated in 1 Hz from the driven velocity and from the chassis dynamometer settings. For all wheel power values below the drag power shall be set to the drag power value.

Pw,i=vi3,6×f 0+ f 1× vi+ f 2× v2i+ TM× ai× 0,001

With f0, f1, f2…road load coefficients used in in the WLTP test performed with the vehicleTM…test mass of the vehicle in the WLTP test performed with the vehicle in [kg]

Pdrag=− 0,04× Prated

if Pw,i<Pdrag then Pw,i= Pdrag

The average power per WLTC phase is calculated from the 1 Hz wheel power according to:

Pw,p–=∑tej= tsPw,ite− ts

Withpphase of WLTC (low, medium, high and extra-high)tsStart time of the WLTC phase p, [s]teend time of the WLTC phase p, [s]

Then a linear regression shall be made with the CO2 mass flow from the bag values of the WLTC on the y-axis and from the average wheel power Pw,p per phase on the x-axis as illustrated in Figure 2.

The resulting Veline equation defines the CO2 mass flow as function of the wheel power:

CO 2 i=kWLTC X Pw,i+ DWLTC CO 2 in g∕h

Where

kWLTC … slope of the Veline from WLTC, [g/kWh]

DWLTC … intercept of the Veline from WLTC, [g/h]

Figure 2
The actual wheel power shall be calculated from the measured CO2 mass flow according to:

Pw,i=CO2i− DWLTCkWLTC

WithCO2 in [g/h]
PW,j in [kW]

The above equation can be used to provide PWi for the classification of the measured emissions as described in point 3 with following additional conditions in the calculation


((I)) if vi < 0,5 and if ai < 0 then P w,i = 0 v in [m/s]
((II)) if CO2i < 0,5 X DWLTC then P w,i = Pdrag

In time steps where (I) and (II) are valid, condition (II) shall be applied.

Appendix 7
1. 
Due to their particular characteristics, PEMS tests are not required to be performed for each ‘vehicle type with regard to emissions and vehicle repair and maintenance information’ as defined in Article 2(1) of this Regulation, which is called in the following ‘vehicle emission type’. Several vehicle emission types may be put together by the vehicle manufacturer to form a ‘PEMS test family’ according to the requirements of point 3, which shall be validated according to the requirements of point 4.

2. 
NNumber of vehicle emission typesNTMinimum number of vehicle emission typesPMRHhighest power-to-mass-ratio of all vehicles in the PEMS test familyPMRLlowest power-to-mass-ratio of all vehicles in the PEMS test familyV_eng_maxmaximum engine volume of all vehicles within the PEMS test family

3. 
A PEMS test family shall comprise vehicles with similar emission characteristics. Upon the choice of the manufacturer vehicle emission types may be included in a PEMS test family only if they are identical with respect to the characteristics in points 3.1. and 3.2.
 3.1.  3.1.1. The approval authority issuing the emission type approval according to Regulation (EC) No 715/2007 (‘authority’)
 3.1.2. A single vehicle manufacturer.
 3.2.  3.2.1. Propulsion type (e.g. ICE, HEV, PHEV)
 3.2.2. Type(s) of fuel(s) (e.g. petrol, diesel, LPG, NG, …). Bi- or flex-fuelled vehicles may be grouped with other vehicles, with which they have one of the fuels in common.
 3.2.3. Combustion process (e.g. two stroke, four stroke)
 3.2.4. Number of cylinders
 3.2.5. Configuration of the cylinder block (e.g. in-line, V, radial, horizontally opposed)
 3.2.6. 
The vehicle manufacturer shall specify a value V_eng_max (= maximum engine volume of all vehicles within the PEMS test family). The engine volumes of vehicles in the PEMS test family shall not deviate more than – 22 % from V_eng_max if V_eng_max ≥ 1 500 ccm and – 32 % from V_eng_max if V_eng_max < 1 500 ccm.
 3.2.7. Method of engine fuelling (e.g. indirect or direct or combined injection)
 3.2.8. Type of cooling system (e.g. air, water, oil)
 3.2.9. Method of aspiration such as naturally aspirated, pressure charged, type of pressure charger (e.g. externally driven, single or multiple turbo, variable geometries …)
 3.2.10. Types and sequence of exhaust after-treatment components (e.g. three-way catalyst, oxidation catalyst, lean NOx trap, SCR, lean NOx catalyst, particulate trap).
 3.2.11. Exhaust gas recirculation (with or without, internal/external, cooled/non-cooled, low/high pressure)
 3.3. 
An existing PEMS test family may be extended by adding new vehicle emission types to it. The extended PEMS test family and its validation must also fulfil the requirements of points 3 and 4. This may in particular require the PEMS testing of additional vehicles to validate the extended PEMS test family according to point 4.
 3.4. 
As an alternative to the provisions of points 3.1 to 3.2 the vehicle manufacturer may define a PEMS test family, which is identical to a single vehicle emission type. In this the requirement of point 4.1.2 for validating the PEMS test family shall not apply.

4.  4.1.  4.1.1. The vehicle manufacturer presents a representative vehicle of the PEMS test family to the authority. The vehicle shall be subject to a PEMS test carried out by a Technical Service to demonstrate compliance of the representative vehicle with the requirements of this Annex.
 4.1.2. The authority selects additional vehicles according to the requirements of point 4.2 of this Appendix for PEMS testing carried out by a Technical Service to demonstrate compliance of the selected vehicles with the requirements of this Annex. The technical criteria for selection of an additional vehicle according to point 4.2 of this Appendix. shall be recorded with the test results.
 4.1.3. With agreement of the authority, a PEMS test can also be driven by a different operator witnessed by a Technical Service, provided that at least the tests of the vehicles required by points 4.2.2 and 4.2.6 of this Appendix and in total at least 50 % of the PEMS tests required by this Appendix for validating the PEMS test family are driven by a Technical Service. In such case the Technical Service remains responsible for the proper execution of all PEMS tests pursuant to the requirements of this Annex.
 4.1.4. 

— the vehicles included in all PEMS test families to be validated are approved by a single authority according to the requirements of Regulation (EC) 715/2007 and this authority agrees to the use of the specific vehicle's PEMS test results for validating different PEMS test families;
— each PEMS test family to be validated includes a vehicle emission type, which comprises the specific vehicle;

For each validation the applicable responsibilities are considered to be borne by the manufacturer of the vehicles in the respective family, regardless of whether this manufacturer was involved in the PEMS test of the specific vehicle emission type.
 4.2. 
By selecting vehicles from a PEMS test family it should be ensured that the following technical characteristics relevant for pollutant emissions are covered by a PEMS test. One vehicle selected for testing can be representative for different technical characteristics. For the validation of a PEMS test family vehicles shall be selected for PEMS testing as follows:


4.2.1. For each combination of fuels (e.g. petrol-LPG, petrol-NG, petrol only), on which some vehicle of the PEMS test family can operate, at least one vehicle that can operate on this combination of fuels shall be selected for PEMS testing.
4.2.2. The manufacturer shall specify a value PMRH (= highest power-to-mass-ratio of all vehicles in the PEMS test family) and a value PMRL (= lowest power-to-mass-ratio of all vehicles in the PEMS test family). Here the ‘power-to-mass-ratio’ corresponds to the ratio of the maximum net power of the internal combustion engine as indicated in point 3.2.1.8 of Appendix 3 to Annex I of this Regulation and of the reference mass as defined in Article 3(3) of Regulation (EC) No 715/2007. At least one vehicle configuration representative for the specified PMRH and one vehicle configuration representative for the specified PMRL of a PEMS test family shall be selected for testing. If the power-to-mass ratio of a vehicle deviates by not more than 5 % from the specified value for PMRH, or PMRL, the vehicle should be considered as representative for this value.
4.2.3. At least one vehicle for each transmission type (e.g., manual, automatic, DCT) installed in vehicles of the PEMS test family shall be selected for testing.
4.2.4. At least one four-wheel drive vehicle (4x4 vehicle) shall be selected for testing if such vehicles are part of the PEMS test family.
4.2.5. For each engine volume occurring on a vehicle in the PEMS family at least one representative vehicle shall be tested.
4.2.6. At least one vehicle for each number of installed exhaust after-treatment components shall be selected for testing.
4.2.7. Notwithstanding the provisions in points 4.2.1 to 4.2.6, at least the following number of vehicle emission types of a given PEMS test family shall be selected for testing:
Number N of vehicle emission types in a PEMS test family Minimum number NT of vehicle emission types selected for PEMS testing
1 1
from 2 to 4 2
from 5 to 7 3
from 8 to 10 4
from 11 to 49 NT = 3 + 0,1 × N
more than 49 NT = 0,15 × N


5.  5.1. The vehicle manufacturer provides a full description of the PEMS test family, which includes in particular the technical criteria described in point 3.2 and submits it to the authority.
 5.2. The manufacturer attributes a unique identification number of the format MS-OEM-X-Y to the PEMS test family and communicates it to the authority. Here MS is the distinguishing number of the Member State issuing the EC type-approval, OEM is the 3 character manufacturer, X is a sequential number identifying the original PEMS test family and Y is a counter for its extensions (starting with 0 for a PEMS test family not extended yet).
 5.3. The authority and the vehicle manufacturer shall maintain a list of vehicle emission types being part of a given PEMS test family on the basis of emission type approval numbers. For each emission type all corresponding combinations of vehicle type approval numbers, types, variants and versions as defined in sections 0.10 and 0.2 of the vehicle's EC certificate of conformity shall be provided as well.
 5.4. The authority and the vehicle manufacturer shall maintain a list of vehicle emission types selected for PEMS testing in order validate a PEMS test family in accordance with point 4, which also provides the necessary information on how the selection criteria of point 4.2 are covered. This list shall also indicate whether the provisions of point 4.1.3 were applied for a particular PEMS test.

Appendix 7a
1. 
This Appendix describes the calculation procedures to verify the overall trip dynamics, to determine the overall excess or absence of dynamics during urban, rural and motorway driving.

2.  RPA 
Δdifference>larger≥larger or equal%per cent<smaller≤smaller or equalaacceleration [m/s2]aiacceleration in time step i [m/s2]apospositive acceleration greater than 0,1 m/s2 [m/s2]apos,i,kpositive acceleration greater than 0,1 m/s2 in time step i considering the urban, rural and motorway shares [m/s2]aresacceleration resolution [m/s2]didistance covered in time step i [m]di,kdistance covered in time step i considering the urban, rural and motorway shares [m]Index (i)discrete time stepIndex (j)discrete time step of positive acceleration datasetsIndex (k)refers to the respective category (t=total, u=urban, r=rural, m=motorway)Mknumber of samples for urban, rural and motorway shares with positive acceleration greater than 0,1 m/s2Nktotal number of samples for the urban, rural and motorway shares and the complete tripRPAkrelative positive acceleration for urban, rural and motorway shares [m/s2 or kWs/(kg*km)]tkduration of the urban, rural and motorway shares and the complete trip [s]T4253Hcompound data smootherνvehicle speed [km/h]νiactual vehicle speed in time step i [km/h]νi,kactual vehicle speed in time step i considering the urban, rural and motorway shares [km/h]ν× aiactual vehicle speed per acceleration in time step i [m2/s3 or W/kg]ν× aposj,kactual vehicle speed per positive acceleration greater than 0,1 m/s2 in time step j considering the urban, rural and motorway shares [m2/s3 or W/kg].ν× aposk−9595th percentile of the product of vehicle speed per positive acceleration greater than 0,1 m/s2 for urban, rural and motorway shares [m2/s3 or W/kg]ν–kaverage vehicle speed for urban, rural and motorway shares [km/h]

3.  3.1.  3.1.1. 
Dynamic parameters like acceleration, ν× apos or RPA shall be determined with a speed signal of an accuracy of 0,1 % for all speed values above 3 km/h and a sampling frequency of 1 Hz. This accuracy requirement is generally fulfilled by signals obtained from a wheel (rotational) speed sensor.

The speed trace shall be checked for faulty or implausible sections. The vehicle speed trace of such sections is characterised by steps, jumps, terraced speed traces or missing values. Short faulty sections shall be corrected, for example by data interpolation or benchmarking against a secondary speed signal. Alternatively, short trips containing faulty sections could be excluded from the subsequent data analysis. In a second step the acceleration values shall be calculated and ranked in ascending order, as to determine the acceleration resolution ares=minimum acceleration value> 0.

If ares≤ 0,01 m∕s2, the vehicle speed measurement is sufficiently accurate.

If 0,01 m∕s2< ares, data smoothing by using a T4253H Hanning filter shall be performed

The T4235 Hanning filter performs the following calculations: The smoother starts with a running median of 4, which is centred by a running median of 2. The filter then re-smoothes these values by applying a running median of 5, a running median of 3, and hanning (running weighted averages). Residuals are computed by subtracting the smoothed series from the original series. This whole process is then repeated on the computed residuals. Finally, the smoothed final speed values are computed by summing up the smoothed values obtained the first time through the process with the computed residuals.

The correct speed trace builds the basis for further calculations and binning as described in paragraph 8.1.2.
 3.1.2. 
The following calculations shall be performed over the whole time based speed trace (1 Hz resolution) from second 1 to second tt (last second).

The distance increment per data sample shall be calculated as follows:
di=vi3,6, i= 1 to Nt
where:

diis the distance covered in time step i [m]νiis the actual vehicle speed in time step i [km/h]Ntis the total number of samples

The acceleration shall be calculated as follows:
ai=vi+ 1− vi− 1∕2× 3,6, i= 1 to Nt
where:

aiis the acceleration in time step i [m/s2]. For i = 1: vi-1= 0, for i= Nt: vi+ 1= 0.

The product of vehicle speed per acceleration shall be calculated as follows:
v× ai=vi× ai∕3,6,i= 1 to Nt
where:

ν× aiis the product of the actual vehicle speed per acceleration in time step i [m2/s3 or W/kg].
 3.1.3. 
After the calculation of ai and ν× ai, the values vi, di, ai and ν× ai shall be ranked in ascending order of the vehicle speed.

All datasets with vi≤ 60 km∕h belong to the ‘urban’ speed bin, all datasets with 60 km∕h< vi≤ 90 km∕h belong to the ‘rural’ speed bin and all datasets with vi> 90 km∕h belong to the ‘motorway’ speed bin.

The number of datasets with acceleration values ai> 0,1 m∕s2 shall be bigger or equal to 150 in each speed bin.

For each speed bin the average vehicle speed v–k shall be calculated as follows:
v–k=∑ivi,k∕Nk, i= 1 to Nk, k= u,r,m
where:

Nkis the total number of samples of the urban, rural, and motorway shares.
 3.1.4. 
The 95th percentile of the v× apos values shall be calculated as follows:

The v× ai,k values in each speed bin shall be ranked in ascending order for all datasets with ai,k> 0,1 m∕s2ai,k≥ 0,1 m∕s2 and the total number of these samples Mk shall be determined.

Percentile values are then assigned to the v× aposi,k values with ai,k≥ 0,1 m∕s2 as follows:

The lowest v× apos value gets the percentile 1/Mk, the second lowest 2/Mk, the third lowest 3/Mk and the highest value Mk∕Mk= 100 %.

v× aposk−95 is the v× aposj,k value, with j∕Mk= 95 %. If j∕Mk= 95 %. cannot be met, v× aposk−95 shall be calculated by linear interpolation between consecutive samples j and j+1 with j∕Mk< 95 % and j+ 1∕Mk> 95 %.

The relative positive acceleration per speed bin shall be calculated as follows:
RPAk=∑jΔt×v× aposj,k∕∑idi,k,j= 1 to Mk, i= 1 to Nk, k= u,r,m
where:

RPAkis the relative positive acceleration for urban, rural and motorway shares in [m/s2 or kWs/(kg*km)]Δtis a time difference equal to 1 secondMkis the sample number for urban, rural and motorway shares with positive accelerationNkis the total sample number for urban, rural and motorway shares

4.  4.1.1. 
If v–k≤ 74,6 km∕h

and
v× aposk−95>0,136×v–k+ 14,44
is fulfilled, the trip is invalid.

If v–k> 74,6 km∕h and v× aposk−95>0,0742×v–k+ 18,966 is fulfilled, the trip is invalid.
 4.1.2. 
If v–k≤ 94,05 km∕h and RPAk<− 0,0016×v–k+ 0,1755 is fulfilled, the trip is invalid.

If v–k> 94,05 km∕h and RPAk<− 0,025 is fulfilled, the trip is invalid.

Appendix 7b
1. 
This Appendix describes the procedure to determine the cumulative elevation gain of a PEMS trip.

2. 
d(0)distance at the start of a trip [m]dcumulative distance travelled at the discrete way point under consideration [m]d0cumulative distance travelled until the measurement directly before the respective way point d [m]d1cumulative distance travelled until the measurement directly after the respective way point d [m]dareference way point at d(0) [m]decumulative distance travelled until the last discrete way point [m]diinstantaneous distance [m]dtottotal test distance [m]h(0)vehicle altitude after the screening and principle verification of data quality at the start of a trip [m above sea level]h(t)vehicle altitude after the screening and principle verification of data quality at point t [m above sea level]h(d)vehicle altitude at the way point d [m above sea level]h(t-1)vehicle altitude after the screening and principle verification of data quality at point t-1 [m above sea level]hcorr(0)corrected altitude directly before the respective way point d [m above sea level]hcorr(1)corrected altitude directly after the respective way point d [m above sea level]hcorr(t)corrected instantaneous vehicle altitude at data point t [m above sea level]hcorr(t-1)corrected instantaneous vehicle altitude at data point t-1 [m above sea level]hGPS,iinstantaneous vehicle altitude measured with GPS [m above sea level]hGPS(t)vehicle altitude measured with GPS at data point t [m above sea level]hint(d)interpolated altitude at the discrete way point under consideration d [m above sea level]hint,sm,1(d)smoothed and interpolated altitude, after the first smoothing run at the discrete way point under consideration d [m above sea level]hmap(t)vehicle altitude based on topographic map at data point t [m above sea level]Hzhertzkm/hkilometer per hourmmeterroadgrade,1(d)smoothed road grade at the discrete way point under consideration d after the first smoothing run [m/m]roadgrade,2(d)smoothed road grade at the discrete way point under consideration d after the second smoothing run [m/m]sintrigonometric sine functionttime passed since test start [s]t0time passed at the measurement directly located before the respective way point d [s]viinstantaneous vehicle speed [km/h]v(t)vehicle speed at a data point t [km/h]

3. 
The cumulative positive elevation gain of a RDE trip shall be determined based on three parameters: the instantaneous vehicle altitude hGPS,i [m above sea level] as measured with the GPS, the instantaneous vehicle speed vi [km/h] recorded at a frequency of 1 Hz and the corresponding time t [s] that has passed since test start.

4.  4.1. 
The cumulative positive elevation gain of a RDE trip shall be calculated as a three-step procedure, consisting of (i) the screening and principle verification of data quality, (ii) the correction of instantaneous vehicle altitude data, and (iii) the calculation of the cumulative positive elevation gain.
 4.2. 
The instantaneous vehicle speed data shall be checked for completeness. Correcting for missing data is permitted if gaps remain within the requirements specified in Point 7 of Appendix 4; else, the test results shall be voided. The instantaneous altitude data shall be checked for completeness. Data gaps shall be completed by data interpolation. The correctness of interpolated data shall be verified by a topographic map. It is recommended to correct interpolated data if the following condition applies:
hGPSt− hmapt> 40m
The altitude correction shall be applied so that:
ht= hmapt
where:

h(t)vehicle altitude after the screening and principle verification of data quality at data point t [m above sea level]hGPS(t)vehicle altitude measured with GPS at data point t [m above sea level]hmap(t)vehicle altitude based on topographic map at data point t [m above sea level]
 4.3. 
The altitude h(0) at the start of a trip at d(0) shall be obtained by GPS and verified for correctness with information from a topographic map. The deviation shall not be larger than 40 m. Any instantaneous altitude data h(t) shall be corrected if the following condition applies:
ht− ht− 1>vt∕ 3,6× sin45°
The altitude correction shall be applied so that:
hcorrt= hcorrt− 1
where:

h(t)vehicle altitude after the screening and principle verification of data quality at data point t [m above sea level]h(t-1)vehicle altitude after the screening and principle verification of data quality at data point t-1 [m above sea level]v(t)vehicle speed of data point t [km/h]hcorr(t)corrected instantaneous vehicle altitude at data point t [m above sea level]hcorr(t-1)corrected instantaneous vehicle altitude at data point t-1 [m above sea level]

Upon the completion of the correction procedure, a valid set of altitude data is established. This data set shall be used for the calculation of the cumulative positive elevation gain as described in Point 13.4.
 4.4.  4.4.1. 
The total distance dtot [m] covered by a trip shall be determined as sum of the instantaneous distances di. The instantaneous distance di shall be determined as:
di=vi3,6
Where:

diinstantaneous distance [m]viinstantaneous vehicle speed [km/h]

The cumulative elevation gain shall be calculated from data of a constant spatial resolution of 1 m starting with the first measurement at the start of a trip d(0). The discrete data points at a resolution of 1 m are referred to as way points, characterized by a specific distance value d (e.g., 0, 1, 2, 3 m…) and their corresponding altitude h(d) [m above sea level].

The altitude of each discrete way point d shall be calculated through interpolation of the instantaneous altitude hcorr(t) as:
hintd=hcorr 0+hcorr 1− hcorr 0d 1− d 0×d− d 0
Where:

hint(d)interpolated altitude at the discrete way point under consideration d [m above sea level]hcorr(0)corrected altitude directly before the respective way point d [m above sea level]hcorr(1)corrected altitude directly after the respective way point d [m above sea level]dcumulative distance traveled until the discrete way point under consideration d [m]d0cumulative distance travelled until the measurement located directly before the respective way point d [m]d1cumulative distance travelled until the measurement located directly after the respective way point d [m]
 4.4.2. 
The altitude data obtained for each discrete way point shall be smoothed by applying a two-step procedure; da and de denote the first and last data point respectively (Figure 1). The first smoothing run shall be applied as follows:
roadgrade,1d=hintd+ 200m− hintdad+ 200m for d≤ 200mroadgrade,1d=hintd+ 200m− hintd− 200md+ 200m−d− 200m for 200m< d<de− 200mroadgrade,1d=hintde− hintd− 200mde−d− 200m for d≥de− 200mhint,sm,1d=hint,sm,1d− 1m+ roadgrade,1d, d= da+ 1 to dehint,sm,1da=hintda+ roadgrade,1da
Where:

roadgrade,1(d)smoothed road grade at the discrete way point under consideration after the first smoothing run [m/m]hint(d)interpolated altitude at the discrete way point under consideration d [m above sea level]hint,sm,1(d)smoothed interpolated altitude, after the first smoothing run at the discrete way point under consideration d [m above sea level]dcumulative distance travelled at the discrete way point under consideration [m]dareference way point at a distance of zero meters [m]decumulative distance travelled until the last discrete way point [m]

The second smoothing run shall be applied as follows:
roadgrade,2d=hint,sm,1d+ 200m− hint,sm,1dad+ 200m for d≤ 200mroadgrade,2d=hint,sm,1d+ 200m− hint,sm,1d− 200md+ 200m−d− 200m for 200m< d<de− 200mroadgrade,2d=hint,sm,1de− hint,sm,1d− 200mde−d− 200m for d≥de− 200m
Where:

roadgrade,2(d)smoothed road grade at the discrete way point under consideration after the second smoothing run [m/m]hint,sm,1(d)smoothed interpolated altitude, after the first smoothing run at the discrete way point under consideration d [m above sea level]dcumulative distance travelled at the discrete way point under consideration [m]dareference way point at a distance of zero meters [m]decumulative distance travelled until the last discrete way point [m]

Figure 1 4.4.3. 
The positive cumulative elevation gain of a trip shall be calculated by integrating all positive interpolated and smoothed road grades, i.e. roadgrade,2(d). The result should be normalized by the total test distance dtot and expressed in meters of cumulative elevation gain per one hundred kilometers of distance.

5. 
Tables 1 and 2 show how to calculate the positive elevation gain on the basis of data recorded during an on-road test performed with PEMS. For the sake of brevity an extract of 800m and 160s is presented here.
 5.1. 
The screening and principle verification of data quality consists of two steps. First, the completeness of vehicle speed data is checked. No data gaps related to vehicle speed are detected in the present data sample (see Table 1). Second, the altitude data are checked for completeness; in the data sample, altitude data related to seconds 2 and 3 are missing. The gaps are filled by interpolating the GPS signal. In addition, the GPS altitude is verified by a topographic map; this verification includes the altitude h(0) at the start of the trip. Altitude data related to seconds 112 -114 are corrected on the basis of the topographic map to satisfy the following condition:
hGPSt− hmapt<− 40m
As result of the applied data verification, the data in the fifth column h(t) are obtained.
 5.2. 
As a next step, the altitude data h(t) of seconds 1 to 4, 111 to 112 and 159 to 160 are corrected assuming the altitude values of seconds 0, 110 and 158 respectively since for the altitude data in these time periods the following condition applies:
ht− ht− 1>vt∕ 3,6× sin45°
As result of the applied data correction, the data in the sixth column hcorr(t) are obtained. The effect of the applied verification and correction steps on the altitude data is depicted in Figure 2.
 5.3.  5.3.1. 
The instantaneous distance di is calculated by dividing the instantaneous vehicle speed measured in km/h by 3.6 (Column 7 in Table 1). Recalculating the altitude data to obtain a uniform spatial resolution of 1 m yields the discrete way points d (Column 1 in Table 2) and their corresponding altitude values hint(d) (Column 7 in Table 2). The altitude of each discrete way point d is calculated through interpolation of the measured instantaneous altitude hcorr as:
hint 0= 120,3+120,3− 120,30,1− 0,0× 0− 0= 120,3000hint 520= 132,5+132,6− 132,5523,6− 519,9× 520− 519,9= 132,5027 5.3.2. 
In Table 2, the first and last discrete way points are: da=0m and de=799m, respectively. The altitude data of each discrete way point is smoothed by applying a two steps procedure. The first smoothing run consists of:
roadgrade,1 0=hint200m− hint 0 0+ 200m=120,9682− 120,3000200= 0,0033
chosen to demonstrate the smoothing for d ≤ 200m
roadgrade,1 320=hint 520− hint 120 520− 120=132,5027− 121,0400= 0,0288
chosen to demonstrate the smoothing for 200m < d < (599m)
roadgrade,1 720=hint 799− hint 520 799− 520=121,2000− 132,5027279=− 0,0405
chosen to demonstrate the smoothing for d ≥ (599m)

The smoothed and interpolated altitude is calculated as:
hint,sm,1 0=hint 0+ roadgrade,1 0= 120,3+ 0,0033≈ 120,3033mhint,sm,1 799=hint,sm,1 798+ roadgrade,1 799= 121,2550− 0,0220= 121,2330m
Second smoothing run:
roadgrade,2 0=hint,sm,1 200− hint,sm,1 0 200=119,9618− 120,3033 200=− 0,0017
chosen to demonstrate the smoothing for d ≤ 200m
roadgrade,2 320=hint,sm,1 520− hint,sm,1 120 520− 120=123,6809− 120,1843 400= 0,0087
chosen to demonstrate the smoothing for 200m < d < (599)
roadgrade,2 720=hint,sm,1 799− hint,sm,1 520 799− 520=121,2330− 123,6809 279=− 0,0088
chosen to demonstrate the smoothing for d ≥ (599m)
 5.3.3. 
The positive cumulative elevation gain of a trip is calculated by integrating all positive interpolated and smoothed road grades, i.e. values in the column roadgrade,2(d) in Table 2. For the entire data set the total covered distance was dtot= 139,7 km and all positive interpolated and smoothed road grades were of 516m. Therefore the positive cumulative elevation gain reached 516*100/139,7=370m/100km.


Timet [s] v(t)[km/h] hGPS(t)[m] hmap(t)[m] h(t)[m] hcorr(t)[m] di[m] Cum. d[m]
       
0 0,00 122,7 129,0 122,7 122,7 0,0 0,0
1 0,00 122,8 129,0 122,8 122,7 0,0 0,0
2 0,00 — 129,1 123,6 122,7 0,0 0,0
3 0,00 — 129,2 124,3 122,7 0,0 0,0
4 0,00 125,1 129,0 125,1 122,7 0,0 0,0
… … … … … … … …
18 0,00 120,2 129,4 120,2 120,2 0,0 0,0
19 0,32 120,2 129,4 120,2 120,2 0,1 0,1
… … … … … … … …
37 24,31 120,9 132,7 120,9 120,9 6,8 117,9
38 28,18 121,2 133,0 121,2 121,2 7,8 125,7
… … … … … … … …
46 13,52 121,4 131,9 121,4 121,4 3,8 193,4
47 38,48 120,7 131,5 120,7 120,7 10,7 204,1
… … … … … … … …
56 42,67 119,8 125,2 119,8 119,8 11,9 308,4
57 41,70 119,7 124,8 119,7 119,7 11,6 320,0
… … … … … … … …
110 10,95 125,2 132,2 125,2 125,2 3,0 509,0
111 11,75 100,8 132,3 100,8 125,2 3,3 512,2
112 13,52 0,0 132,4 132,4 125,2 3,8 516,0
113 14,01 0,0 132,5 132,5 132,5 3,9 519,9
114 13,36 24,30 132,6 132,6 132,6 3,7 523,6
… … … … … … … 
149 39,93 123,6 129,6 123,6 123,6 11,1 719,2
150 39,61 123,4 129,5 123,4 123,4 11,0 730,2
… … … … … … … 
157 14,81 121,3 126,1 121,3 121,3 4,1 792,1
158 14,19 121,2 126,2 121,2 121,2 3,9 796,1
159 10,00 128,5 126,1 128,5 121,2 2,8 798,8
160 4,10 130,6 126,0 130,6 121,2 1,2 800,0
— denotes data gaps


d[m] t0[s] d0[m] d1[m] h0[m] h1[m] hint(d)[m] roadgrade,1(d)[m/m] hint,sm,1(d)[m] roadgrade,2(d)[m/m]
0 18 0,0 0,1 120,3 120,4 120,3 0,0035 120,3 – 0,0015
… … … … … … … … … …
120 37 117,9 125,7 120,9 121,2 121,0 – 0,0019 120,2 0,0035
… … … … … … … … … …
200 46 193,4 204,1 121,4 120,7 121,0 – 0,0040 120,0 0,0051
… … … … … … … … … …
320 56 308,4 320,0 119,8 119,7 119,7 0,0288 121,4 0,0088
… … … … … … … … … …
520 113 519,9 523,6 132,5 132,6 132,5 0,0097 123,7 0,0037
… … … … … … … … … …
720 149 719,2 730,2 123,6 123,4 123,6 – 0,0405 122,9 – 0,0086
… … … … … … … … … …
798 158 796,1 798,8 121,2 121,2 121,2 – 0,0219 121,3 – 0,0151
799 159 798,8 800,0 121,2 121,2 121,2 – 0,0220 121,3 – 0,0152

Figure 2
Figure 3

d[m] t0[s] d0[m] d1[m] h0[m] h1[m] hint(d)[m] roadgrade,1(d)[m/m] hint,sm,1(d)[m] roadgrade,2(d)[m/m]
         
0 18 0,0 0,1 120,3 120,4 120,3 0,0035 120,3 – 0,0015
… … … … … … … … … …
120 37 117,9 125,7 120,9 121,2 121,0 – 0,0019 120,2 0,0035
… … … … … … … … … …
200 46 193,4 204,1 121,4 120,7 121,0 – 0,0040 120,0 0,0051
… … … … … … … … … …
320 56 308,4 320,0 119,8 119,7 119,7 0,0288 121,4 0,0088
… … … … … … … … … …
520 113 519,9 523,6 132,5 132,6 132,5 0,0097 123,7 0,0037
… … … … … … … … … …
720 149 719,2 730,2 123,6 123,4 123,6 – 0,0405 122,9 – 0,0086
… … … … … … … … … …
798 158 796,1 798,8 121,2 121,2 121,2 – 0,0219 121,3 – 0,0151
799 159 798,8 800,0 121,2 121,2 121,2 – 0,0220 121,3 – 0,0152

Appendix 8
1. 
This Appendix describes the requirements for the data exchange between the measurement systems and the data evaluation software and the reporting and exchange of intermediate and final results after the completion of the data evaluation.

The exchange and reporting of mandatory and optional parameters shall follow the requirements of point 3.2 of Appendix 1. The data specified in the exchange and reporting files of point 3 shall be reported to ensure traceability of final results.

2. 
a1coefficient of the CO2 characteristic curveb1coefficient of the CO2 characteristic curvea2coefficient of the CO2 characteristic curveb2coefficient of the CO2 characteristic curvek11coefficient of the weighing functionk12coefficient of the weighing functionk21coefficient of the weighing functionk22coefficient of the weighing functiontol1primary tolerancetol2secondary tolerancev× aposk−9595th percentile of the product of vehicle speed and positiveacceleration greater than 0,1 m/s2 for urban, rural and motorway driving [m2/s3 or W/kg]RPAKrelative positive acceleration for urban, rural and motorway driving [m/s2 or kWs/(kg*km)]

3.  3.1. 
Emission values as well as any other relevant parameters shall be reported and exchanged as csv-formatted data file. Parameter values shall be separated by a comma, ASCII-Code #h2C. The decimal marker of numerical values shall be a point, ASCII-Code #h2E. Lines shall be terminated by carriage return, ASCII-Code #h0D. No thousands separators shall be used.
 3.2. 
Data shall be exchanged between the measurement systems and the data evaluation software by means of a standardised reporting file that contains a minimum set of mandatory and optional parameters. The data exchange file shall be structured as follows: The first 195 lines shall be reserved for a header that provides specific information about, e.g., the test conditions, the identity and calibration of the PEMS equipment (Table 1). Lines 198-200 shall contain the labels and units of parameters. Lines 201 and all consecutive data lines shall comprise the body of the data exchange file and report parameter values (Table 2). The body of the data exchange file shall contain at least as many data lines as the test duration in seconds multiplied by the recording frequency in hertz.
 3.3. 
Summary parameters of intermediate results shall be recorded and structured as indicated in Table 3. The information in Table 3 shall be obtained prior to the application of the data evaluation methods laid down in Appendices 5 and 6.

The vehicle manufacturer shall record the results of the two data evaluation methods in separate files. The results of the data evaluation with the method described in Appendix 5 shall be reported according to Tables 4, 5 and 6. The results of the data evaluation with the method described in Appendix 6 shall be reported according to Tables 7, 8 and 9. The header of the data reporting file shall be composed of three parts. The first 95 lines shall be reserved for specific information about the settings of the data evaluation method. Lines 101-195 shall report the results of the data evaluation method. Lines 201-490 shall be reserved for reporting the final emission results. Line 501 and all consecutive data lines comprise the body of the data reporting file and shall contain the detailed results of the data evaluation.

4.  4.1. 

Line Parameter Description/unit
1 TEST ID [code]
2 Test date [day.month.year]
3 Organisation supervising the test [name of the organization]
4 Test location [city, country]
5 Person supervising the test [name of the principal supervisor]
6 Vehicle driver [name of the driver]
7 Vehicle type [vehicle name]
8 Vehicle manufacturer [name]
9 Vehicle model year [year]
10 Vehicle ID [VIN code]
11 Odometer reading at test start [km]
12 Odometer reading at test end [km]
13 Vehicle category [category]
14 Type approval emissions limit [Euro X]
15 Engine type [e.g., spark ignition, compression ignition]
16 Engine rated power [kW]
17 Peak torque [Nm]
18 Engine displacement [ccm]
19 Transmission [e.g., manual, automatic]
20 Number of forward gears [#]
21 Fuel [e.g., gasoline, diesel]
22 Lubricant [product label]
23 Tire size [width/height/rim diameter]
24 Front and rear axle tire pressure [bar; bar]
25W Road load parameters from WLTP, [F0, F1, F2]
25N Road load parameters from NEDC [F0, F1, F2],
26 Type-approval test cycle [NEDC, WLTC]
27 Type-approval CO2 emissions [g/km]
28 CO2 emissions in WLTC mode Low [g/km]
29 CO2 emissions in WLTC mode Mid [g/km]
30 CO2 emissions in WLTC mode High [g/km]
31 CO2 emissions in WLTC mode Extra High [g/km]
32 Vehicle test mass [kg;%]
33 PEMS manufacturer [name]
34 PEMS type [PEMS name]
35 PEMS serial number [number]
36 PEMS power supply [e.g., battery type]
37 Gas analyser manufacturer [name]
38 Gas analyser type [type]
39 Gas analyser serial number [number]
40-50 … …
51 EFM manufacturer [name]
52 EFM sensor type [functional principle]
53 EFM serial number [number]
54 Source of exhaust mass flow rate [EFM/ECU/sensor]
55 Air pressure sensor [type, manufacturer]
56 Test date [day.month.year]
57 Start time of pre-test procedure [h:min]
58 Start time of trip [h:min]
59 Start time of post-test procedure [h:min]
60 End time of pre-test procedure [h:min]
61 End time of trip [h:min]
62 End time of post-test procedure [h:min]
63-70 … …
71 Time correction: Shift THC [s]
72 Time correction: Shift CH4 [s]
73 Time correction: Shift NMHC [s]
74 Time correction: Shift O2 [s]
75 Time correction: Shift PN [s]
76 Time correction: Shift CO [s]
77 Time correction: Shift CO2 [s]
78 Time correction: Shift NO [s]
79 Time correction: Shift NO2 [s]
80 Time correction: Shift exhaust mass flow rate [s]
81 Span reference value THC [ppm]
82 Span reference value CH4 [ppm]
83 Span reference value NMHC [ppm]
84 Span reference value O2 [%]
85 Span reference value PN [#]
86 Span reference value CO [ppm]
87 Span reference value CO2 [%]
88 Span reference value NO [ppm]
89 Span Reference Value NO2 [ppm]
90-95 … …
96 Pre-test zero response THC [ppm]
97 Pre-test zero response CH4 [ppm]
98 Pre-test zero response NMHC [ppm]
99 Pre-test zero response O2 [%]
100 Pre-test zero response PN [#]
101 Pre-test zero response CO [ppm]
102 Pre-test zero response CO2 [%]
103 Pre-test zero response NO [ppm]
104 Pre-test zero response NO2 [ppm]
105 Pre-test span response THC [ppm]
106 Pre-test span response CH4 [ppm]
107 Pre-test span response NMHC [ppm]
108 Pre-test span response O2 [%]
109 Pre-test span response PN [#]
110 Pre-test span response CO [ppm]
111 Pre-test span response CO2 [%]
112 Pre-test span response NO [ppm]
113 Pre-test span response NO2 [ppm]
114 Post-test zero response THC [ppm]
115 Post-test zero response CH4 [ppm]
116 Post-test zero response NMHC [ppm]
117 Post-test zero response O2 [%]
118 Post-test zero response PN [#]
119 Post-test zero response CO [ppm]
120 Post-test zero response CO2 [%]
121 Post-test zero response NO [ppm]
122 Post-test zero response NO2 [ppm]
123 Post-test span response THC [ppm]
124 Post-test span response CH4 [ppm]
125 Post-test span response NMHC [ppm]
126 Post-test span response O2 [%]
127 Post-test span response PN [#]
128 Post-test span response CO [ppm]
129 Post-test span response CO2 [%]
130 Post-test span response NO [ppm]
131 Post-test span response NO2 [ppm]
132 PEMS validation – results THC [mg/km;%]
133 PEMS validation – results CH4 [mg/km;%]
134 PEMS validation – results NMHC [mg/km;%]
135 PEMS validation – results PN [#/km;%]
136 PEMS validation – results CO [mg/km;%]
137 PEMS validation – results CO2 [g/km;%]
138 PEMS validation – results NOX [mg/km;%]
… … …









Line 198 199 200 201
 Time trip [s] 
 Vehicle speed Sensor [km/h] 
 Vehicle speed GPS [km/h] 
 Vehicle speed ECU [km/h] 
 Latitude GPS [deg:min:s] 
 Longitude GPS [deg:min:s] 
 Altitude GPS [m] 
 Altitude Sensor [m] 
 Ambient pressure Sensor [kPa] 
 Ambient temperature Sensor [K] 
 Ambient humidity Sensor [g/kg; %] 
 THC concentration Analyser [ppm] 
 CH4 concentration Analyser [ppm] 
 NMHC concentration Analyser [ppm] 
 CO concentration Analyser [ppm] 
 CO2 concentration Analyser [ppm] 
 NOX concentration Analyser [ppm] 
 NO concentration Analyser [ppm] 
 NO2 concentration Analyser [ppm] 
 O2 concentration Analyser [ppm] 
 PN concentration Analyser [#/m3] 
 Exhaust mass flow rate EFM [kg/s] 
 Exhaust temperature in the EFM EFM [K] 
 Exhaust mass flow rate Sensor [kg/s] 
 Exhaust mass flow rate ECU [kg/s] 
 THC mass Analyser [g/s] 
 CH4 mass Analyser [g/s] 
 NMHC mass Analyser [g/s] 
 CO mass Analyser [g/s] 
 CO2 mass Analyser [g/s] 
 NOX mass Analyser [g/s] 
 NO mass Analyser [g/s] 
 NO2 mass Analyser [g/s] 
 O2 mass Analyser [g/s] 
 PN Analyser [#/s] 
 Gas measurement active PEMS [active (1); inactive (0); error (>1)] 
 Engine speed ECU [rpm] 
 Engine torque ECU [Nm] 
 Torque at driven axle Sensor [Nm] 
 Wheel rotational speed Sensor [rad/s] 
 Fuel rate ECU [g/s] 
 Engine fuel flow ECU [g/s] 
 Engine intake air flow ECU [g/s] 
 Coolant temperature ECU [K] 
 Oil temperature ECU [K] 
 Regeneration status ECU — 
 Pedal position ECU [%] 
 Vehicle status ECU [error (1); normal (0)] 
 Per cent torque ECU [%] 
 Per cent friction torque ECU [%] 
 State of charge ECU [%] 
 … … … ,




 4.2.  4.2.1. 

Line Parameter Description/unit
1 Total trip distance [km]
2 Total trip duration [h:min:s]
3 Total stop time [min:s]
4 Trip average speed [km/h]
5 Trip maximum speed [km/h]
6 Altitude at start point of the trip [m above sea level]
7 Altitude at end point of the trip [m above sea level]
8 Cumulative elevation gain during the trip [m/100 km]
6 Average THC concentration [ppm]
7 Average CH4 concentration [ppm]
8 Average NMHC concentration [ppm]
9 Average CO concentration [ppm]
10 Average CO2 concentration [ppm]
11 Average NOX concentration [ppm]
12 Average PN concentration [#/m3]
13 Average exhaust mass flow rate [kg/s]
14 Average exhaust temperature [K]
15 Maximum exhaust temperature [K]
16 Cumulated THC mass [g]
17 Cumulated CH4 mass [g]
18 Cumulated NMHC mass [g]
19 Cumulated CO mass [g]
20 Cumulated CO2 mass [g]
21 Cumulated NOX mass [g]
22 Cumulated PN [#]
23 Total trip THC emissions [mg/km]
24 Total trip CH4 emissions [mg/km]
25 Total trip NMHC emissions [mg/km]
26 Total trip CO emissions [mg/km]
27 Total trip CO2 emissions [g/km]
28 Total trip NOX emissions [mg/km]
29 Total trip PN emissions [#/km]
30 Distance urban part [km]
31 Duration urban part [h:min:s]
32 Stop time urban part [min:s]
33 Average speed urban part [km/h]
34 Maximum speed urban part [km/h]
38 v× aposk−95, k=urban [m2/s3]
39 RPAk, k=urban [m/s2]
40 Cumulative urban elevation gain [m/100 km]
41 Average urban THC concentration [ppm]
42 Average urban CH4 concentration [ppm]
43 Average urban NMHC concentration [ppm]
44 Average urban CO concentration [ppm]
45 Average urban CO2 concentration [ppm]
46 Average urban NOX concentration [ppm]
47 Average urban PN concentration [#/m3]
48 Average urban exhaust mass flow rate [kg/s]
49 Average urban exhaust temperature [K]
50 Maximum urban exhaust temperature [K]
51 Cumulated urban THC mass [g]
52 Cumulated urban CH4 mass [g]
53 Cumulated urban NMHC mass [g]
54 Cumulated urban CO mass [g]
55 Cumulated urban CO2 mass [g]
56 Cumulated urban NOX mass [g]
57 Cumulated urban PN [#]
58 Urban THC emissions [mg/km]
59 Urban CH4 emissions [mg/km]
60 Urban NMHC emissions [mg/km]
61 Urban CO emissions [mg/km]
62 Urban CO2 emissions [g/km]
63 Urban NOX emissions [mg/km]
64 Urban PN emissions [#/km]
65 Distance rural part [km]
66 Duration rural part [h:min:s]
67 Stop time rural part [min:s]
68 Average speed rural part [km/h]
69 Maximum speed rural part [km/h]
70 v× aposk−95, k=rural [m2/s3]
71 RPAk, k=rural [m/s2]
72 Average rural THC concentration [ppm]
73 Average rural CH4 concentration [ppm]
74 Average rural NMHC concentration [ppm]
75 Average rural CO concentration [ppm]
76 Average rural CO2 concentration [ppm]
77 Average rural NOX concentration [ppm]
78 Average rural PN concentration [#/m3]
79 Average rural exhaust mass flow rate [kg/s]
80 Average rural exhaust temperature [K]
81 Maximum rural exhaust temperature [K]
82 Cumulated rural THC mass [g]
83 Cumulated rural CH4 mass [g]
84 Cumulated rural NMHC mass [g]
85 Cumulated rural CO mass [g]
86 Cumulated rural CO2 mass [g]
87 Cumulated rural NOX mass [g]
88 Cumulated rural PN [#]
89 Rural THC emissions [mg/km]
90 Rural CH4 emissions [mg/km]
91 Rural NMHC emissions [mg/km]
92 Rural CO emissions [mg/km]
93 Rural CO2 emissions [g/km]
94 Rural NOX emissions [mg/km]
95 Rural PN emissions [#/km]
96 Distance motorway part [km]
97 Duration motorway part [h:min:s]
98 Stop time motorway part [min:s]
99 Average speed motorway part [km/h]
100 Maximum speed motorway part [km/h]
101 v× aposk−95, k=motorway [m2/s3]
102 RPAk, k=motorway [m/s2]
103 Average motorway THC concentration [ppm]
104 Average motorway CH4 concentration [ppm]
105 Average motorway NMHC concentration [ppm]
106 Average motorway CO concentration [ppm]
107 Average motorway CO2 concentration [ppm]
108 Average motorway NOX concentration [ppm]
109 Average motorway PN concentration [#/m3]
110 Average motorway exhaust mass flow rate [kg/s]
111 Average motorway exhaust temperature [K]
112 Maximum motorway exhaust temperature [K]
113 Cumulated motorway THC mass [g]
114 Cumulated motorway CH4 mass [g]
115 Cumulated motorway NMHC mass [g]
116 Cumulated motorway CO mass [g]
117 Cumulated motorway CO2 mass [g]
118 Cumulated motorway NOX mass [g]
119 Cumulated motorway PN [#]
120 Motorway THC emissions [mg/km]
121 Motorway CH4 emissions [mg/km]
122 Motorway NMHC emissions [mg/km]
123 Motorway CO emissions [mg/km]
124 Motorway CO2 emissions [g/km]
125 Motorway NOX emissions [mg/km]
126 Motorway PN emissions [#/km]
… … …

 4.2.2. 

Line Parameter Unit
1 Reference CO2 mass [g]
2 Coefficient a1 of the CO2 characteristic curve 
3 Coefficient b1 of the CO2 characteristic curve 
4 Coefficient a2 of the CO2 characteristic curve 
5 Coefficient b2 of the CO2 characteristic curve 
6 Coefficient k11 of the weighing function 
7 Coefficient k21 of the weighing function 
8 Coefficient k22=k12 of the weighing function 
9 Primary tolerance tol1 [%]
10 Secondary tolerance tol2 [%]
11 Calculation software and version (e.g. EMROAD 5.8)
… … …



Line Parameter Unit
101 Number of windows 
102 Number of urban windows 
103 Number of rural windows 
104 Number of motorway windows 
105 Share of urban windows [%]
106 Share of rural windows [%]
107 Share of motorway windows [%]
108 Share of urban windows in the total number of windows higher than 15 % (1=Yes, 0=No)
109 Share of rural windows in the total number of windows higher than 15 % (1=Yes, 0=No)
110 Share of motorway windows in the total number of windows higher than 15 % (1=Yes, 0=No)
111 Number of windows within ± tol1 
112 Number of urban windows within ± tol1 
113 Number of rural windows within ± tol1 
114 Number of motorway windows within ± tol1 
115 Number of windows within ± tol2 
116 Number of urban windows within ± tol2 
117 Number of rural windows within ± tol2 
118 Number of motorway windows within ± tol2 
119 Share of urban windows within ± tol1 [%]
120 Share of rural windows within ± tol1 [%]
121 Share of motorway windows within ± tol1 [%]
122 Share of urban windows within ± tol1 greater than 50 % (1=Yes, 0=No)
123 Share of rural windows within ± tol1 greater than 50 % (1=Yes, 0=No)
124 Share of motorway windows within ± tol1 greater than 50 % (1=Yes, 0=No)
125 Average severity index of all windows [%]
126 Average severity index of urban windows [%]
127 Average severity index of rural windows [%]
128 Average severity index of motorway windows [%]
129 Weighted THC emissions of urban windows [mg/km]
130 Weighted THC emissions of rural windows [mg/km]
131 Weighted THC emissions of motorway windows [mg/km]
132 Weighted CH4 emissions of urban windows [mg/km]
133 Weighted CH4 emissions of rural windows [mg/km]
134 Weighted CH4 emissions of motorway windows [mg/km]
135 Weighted NMHC emissions of urban windows [mg/km]
136 Weighted NMHC emissions of rural windows [mg/km]
137 Weighted NMHC emissions of motorway windows [mg/km]
138 Weighted CO emissions of urban windows [mg/km]
139 Weighted CO emissions of rural windows [mg/km]
140 Weighted CO emissions of motorway windows [mg/km]
141 Weighted NOx emissions of urban windows [mg/km]
142 Weighted NOx emissions of rural windows [mg/km]
143 Weighted NOx emissions of motorway windows [mg/km]
144 Weighted NO emissions of urban windows [mg/km]
145 Weighted NO emissions of rural windows [mg/km]
146 Weighted NO emissions of motorway windows [mg/km]
147 Weighted NO2 emissions of urban windows [mg/km]
148 Weighted NO2 emissions of rural windows [mg/km]
149 Weighted NO2 emissions of motorway windows [mg/km]
150 Weighted PN emissions of urban windows [#/km]
151 Weighted PN emissions of rural windows [#/km]
152 Weighted PN emissions of motorway windows [#/km]
… … …



Line Parameter Unit
201 Total trip - THC Emissions [mg/km]
202 Total trip - CH4 Emissions [mg/km]
203 Total trip - NMHC Emissions [mg/km]
204 Total trip - CO Emissions [mg/km]
205 Total trip - NOx Emissions [mg/km]
206 Total trip - PN Emissions [#/km]
… … …



Line 498 499 500 501
 Window Start Time  [s] 
 Window End Time  [s] 
 Window Duration  [s] 
 Window Distance Source (1=GPS, 2=ECU, 3=Sensor) [km] 
 Window THC emissions  [g] 
 Window CH4 emissions  [g] 
 Window NMHC emissions  [g] 
 Window CO emissions  [g] 
 Window CO2 emissions  [g] 
 Window NOX emissions  [g] 
 Window NO emissions  [g] 
 Window NO2 emissions  [g] 
 Window O2 emissions  [g] 
 Window PN emissions  [#] 
 Window THC emissions  [mg/km] 
 Window CH4 emissions  [mg/km] 
 Window NMHC emissions  [mg/km] 
 Window CO emissions  [mg/km] 
 Window CO2 emissions  [g/km] 
 Window NOX emissions  [mg/km] 
 Window NO emissions  [mg/km] 
 Window NO2 emissions  [mg/km] 
 Window O2 emissions  [mg/km] 
 Window PN emissions  [#/km] 
 Window distance to CO2 characteristic curve hj  [%] 
 Window weighing factor wj  [—] 
 Window Average Vehicle Speed Source (1=GPS, 2=ECU, 3=Sensor) [km/h] 
 … … … ,




Line Parameter Unit
1 Torque source for the power at the wheels Sensor/ECU/‘Veline’
2 Slope of the Veline [g/kWh]
3 Intercept of the Veline [g/h]
4 Moving average duration [s]
5 Reference speed for de-normalisation of goal pattern [km/h]
6 Reference acceleration [m/s2]
7 Power demand at the wheel hub for a vehicle at reference speed and acceleration [kW]
8 Number of power classes including the 90 % of Prated —
9 Goal pattern layout (stretched/shrank)
10 Calculation software and version (e.g. CLEAR 1.8)
… … …



Line Parameter Unit
101 Power class coverage (counts > 5) (1=Yes, 0=No)
102 Power class normality (1=Yes, 0=No)
103 Total trip - Weighted average THC emissions [g/s]
104 Total trip - Weighted average CH4 emissions [g/s]
105 Total trip - Weighted average NMHC emissions [g/s]
106 Total trip - Weighted average CO emissions [g/s]
107 Total trip - Weighted average CO2 emissions [g/s]
108 Total trip - Weighted average NOX emissions [g/s]
109 Total trip - Weighted s average NO emissions [g/s]
110 Total trip - Weighted average NO2 emissions [g/s]
111 Total trip - Weighted average O2 emissions [g/s]
112 Total trip - Weighted average PN emissions [#/s]
113 Total trip - Weighted average Vehicle Speed [km/h]
114 Urban - Weighted average THC emissions [g/s]
115 Urban - Weighted average CH4 emissions [g/s]
116 Urban - Weighted average NMHC emissions [g/s]
117 Urban - Weighted average CO emissions [g/s]
118 Urban - Weighted average CO2 emissions [g/s]
119 Urban - Weighted average NOX emissions [g/s]
120 Urban - Weighted s average NO emissions g/s]
121 Urban - Weighted average NO2 emissions [g/s]
122 Urban - Weighted average O2 emissions [g/s]
123 Urban - Weighted average PN emissions [#/s]
124 Urban - Weighted average Vehicle Speed [km/h]
… … …



Line Parameter Unit
201 Total trip - THC Emissions [mg/km]
202 Total trip - CH4 Emissions [mg/km]
203 Total trip - NMHC Emissions [mg/km]
204 Total trip - CO Emissions [mg/km]
205 Total trip - NOx Emissions [mg/km]
206 Total trip - PN Emissions [#/km]
… … …



Line 498 499 500 501
 Total trip - Power class number  — 
 Total trip - Lower power class limit  [kW] 
 Total trip - Upper power class limit  [kW] 
 Total trip - Goal pattern used (distribution)  [%] 
 Total trip - Power class occurrence  — 
 Total trip - Power class coverage > 5 counts  — (1=Yes, 0=No)
 Total trip - Power class normality  — (1=Yes, 0=No)
 Total trip - Power class average THC emissions  [g/s] 
 Total trip - Power class average CH4 emissions  [g/s] 
 Total trip - Power class average NMHC emissions  [g/s] 
 Total trip - Power class average CO emissions  [g/s] 
 Total trip - Power class average CO2 emissions  [g/s] 
 Total trip - Power class average NOX emissions  [g/s] 
 Total trip - Power class average NO emissions  [g/s] 
 Total trip - Power class average NO2 emissions  [g/s] 
 Total trip - Power class average O2 emissions  [g/s] 
 Total trip - Power class average PN emissions  [#/s] 
 Total trip - Power class average Vehicle Speed Source (1=GPS, 2=ECU, 3=Sensor) [km/h] 
 Urban trip - Power class number  — 
 Urban trip - Lower power class limit  [kW] 
 Urban trip - Upper power class limit  [kW] 
 Urban trip - Goal pattern used (distribution)  [%] 
 Urban trip - Power class occurrence  — 
 Urban trip - Power class coverage > 5 counts  — (1=Yes, 0=No)
 Urban trip - Power class normality  — (1=Yes, 0=No)
 Urban trip - Power class average THC emissions  [g/s] 
 Urban trip - Power class average CH4 emissions  [g/s] 
 Urban trip - Power class average NMHC emissions  [g/s] 
 Urban trip - Power class average CO emissions  [g/s] 
 Urban trip - Power class average CO2 emissions  [g/s] 
 Urban trip - Power class average NOX emissions  [g/s] 
 Urban trip - Power class average NO emissions  [g/s] 
 Urban trip - Power class average NO2 emissions  [g/s] 
 Urban trip - Power class average O2 emissions  [g/s] 
 Urban trip - Power class average PN emissions  [#/s] 
 Urban trip - Power class average Vehicle Speed Source (1=GPS, 2=ECU, 3=Sensor) [km/h] 
 … … … ,




 4.3. 
The manufacturer shall provide the vehicle and engine description in accordance with Appendix 4 of Annex I.

Appendix 9

ANNEX IV

Appendix 1
MEASURING CARBON MONOXIDE EMISSION AT ENGINE IDLING SPEEDS  1.  1.1. This appendix describes the procedure for the type 2 test, measuring carbon monoxide emissions at engine idling speeds (normal and high).
 2.  2.1. The general requirements shall be those specified in section 5.3.2 and paragraphs 5.3.7.1 to 5.3.7.6 of UN/ECE Regulation No 83, with the exception set out in section 2.2.
 2.2. The table referred to in paragraph 5.3.7.5. of UN/ECE Regulation No 83 shall be understood as the table for the Type 2 test in section 2.1 the Addendum to Appendix 4 to Annex I to this Regulation.
 3.  3.1. The technical requirements shall be those set out in Annex 5 to UN/ECE Regulation No 83, with the exceptions set out in sections 3.2. and 3.3.
 3.2. The reference fuel specifications referred to in paragraph 2.1 of Annex 5 to UN/ECE Regulation No 83 shall be understood as referring to the appropriate reference fuel specifications in Annex IX to this Regulation.
 3.3. Reference to the Type I test in paragraph 2.2.1. of Annex 5 to UN/ECE Regulation No 83 shall be understood as referring to the Type 1 test in Annex XXI to this Regulation.

Appendix 2
1.  1.1. This Appendix describes the requirements for measuring the opacity of exhaust emissions.

2.  2.1. A symbol of the corrected absorption coefficient shall be affixed to every vehicle conforming to a vehicle type to which this test applies. The symbol shall be a rectangle surrounding a figure expressing in m–1 the corrected absorption coefficient obtained, at the time of approval, from the test under free acceleration. The test method is described in section 4.
 2.2. The symbol shall be clearly legible and indelible. It shall be fixed in a conspicuous and readily accessible place, the location of which shall be specified in the Addendum to the type-approval certificate shown in Appendix 4 to Annex I.
 2.3. Figure IV.2.1 gives an example of the symbol.

Figure IV.2.1The above symbol shows that the corrected absorption coefficient is 1,30 m–1.
3.  3.1. The specifications and tests shall be those set out in Part III, section 24, of UN/ECE Regulation No 24, with the exception to these procedures set out in section 3.2.
 3.2. The reference to Annex 2 in paragraph 24.1 of UN/ECE Regulation No 24 shall be understood as a reference to Appendix 4 to Annex I to this Regulation.

4.  4.1. The technical requirements shall be those set out in Annexes 4, 5, 7, 8, 9 and 10 to UN/ECE Regulation No 24, with the exceptions set out in sections 4.2., 4.3 and 4.4.
 4.2.  4.2.1. The references to Annex 1 in paragraph 3.1. of Annex 4 of UN/ECE Regulation No 24 shall be understood as references to Appendix 3 to Annex I to this Regulation.
 4.2.2. The reference fuel specified in paragraph 3.2 of Annex 4 of UN/ECE Regulation No 24 shall be understood as reference to the reference fuel in Annex IX to this Regulation appropriate to the emission limits against which the vehicle is being type approved.
 4.3.  4.3.1. The references to Table 2, Annex 2 in paragraph 2.2 of Annex 5 to UN/ECE Regulation No 24 shall be understood as references to the table under point 2.4.2.1 of Appendix 4 to Annex I to this Regulation.
 4.3.2. The references to paragraph 7.3 of Annex 1 in paragraph 2.3 of Annex 5 to UN/ECE Regulation No 24 shall be understood as references to Appendix 3 to Annex I to this Regulation.
 4.4.  4.4.1. The references in paragraph 7 of Annex 10 to UN/ECE Regulation No 24 to the ‘Appendix to this Annex’ and in paragraphs 7 and 8 of Annex 10 to UN/ECE Regulation No 24 to ‘Annex 1’ shall be understood as references to Appendix 3 to Annex I to this Regulation.

ANNEX V
VERIFYING EMISSIONS OF CRANKCASE GASES  1.  1.1. This Annex describes the procedure for the type 3 test verifying emissions of crankcase gases as described in section 5.3.3. of UN/ECE Regulation No 83.
 2.  2.1. The general requirements for conducting the type 3 test shall be those set out in sections 1 and 2 of Annex 6 to UN/ECE Regulation No 83, with the exceptions set out in points 2.2 and 2.3 below.
 2.2. Reference to the Type I test in paragraph 2.1. of Annex 6 to UN/ECE Regulation No 83 shall be understood as referring to the Type 1 test in Annex XXI to this Regulation.
 2.3. The road load coefficients to be used shall be those for VL. If VL low does not exist the VH road load shall be used.
 3.  3.1. The technical requirements shall be those set out in section 3 to 6 of Annex 6 to UN/ECE Regulation No 83, with the exception set out in point 3.2 below.
 3.2. References to the Type I test in paragraph 3.2. of Annex 6 to UN/ECE Regulation No 83 shall be understood as referring to the Type 1 test in Annex XXI to this Regulation.

ANNEX VI
DETERMINATION OF EVAPORATIVE EMISSIONS  1.  1.1. This Annex describes the procedure for the Type 4 test, which determines the emission of hydrocarbons by evaporation from the fuel systems of vehicles with positive ignition engines.
 2.  2.1. 
The procedure includes the evaporative emissions test and two additional tests, one for the aging of the carbon canister, as described in point 5.1, and one for the permeability of the fuel storage system, as described in point 5.2.

The evaporative emissions test (Figure VI.1) is designed to determine hydrocarbon evaporative emissions as a consequence of diurnal temperatures fluctuation, hot soaks during parking, and urban driving.
 2.2 The evaporative emissions test consists of:

((a)) Test drive including an urban (Part One) and an extra-urban (Part Two) driving cycle, followed by two urban (Part One) driving cycles,
((b)) Hot soak loss determination,
((c)) Diurnal loss determination.
The mass emissions of hydrocarbons from the hot soak and the diurnal loss phases are added up together with the permeability factor to provide an overall result for the test.
 3.  3.1.  3.1.1. The vehicle shall be in good mechanical condition and have been run in and driven at least 3 000 km before the test. For the purpose of the determination of evaporative emissions, the mileage and the age of the vehicle used for certification shall be recorded. The evaporative emission control system shall be connected and have been functioning correctly over the run in period and the carbon canister(s) shall have been subject to normal use, neither undergoing abnormal purging nor abnormal loading. The carbon canister(s) aged according to the procedure set out in paragraph 5.1 shall be connected as described in Figure VI.1.
 3.2.  3.2.1. The Type 1 E10 reference fuel specified in Annex IX of this Regulation shall be used. For the purposes of this Regulation, E10 reference shall mean the Type 1 reference fuel, except for the canister aging, as set out in point 5.1.
 4.  4.1. 
The chassis dynamometer shall meet the requirements of Appendix 1 of Annex 4a to UN/ECE Regulation No 83.
 4.2. 
The evaporative emission measurement enclosure shall meet the requirements of paragraph 4.2. of Annex 7 to UN/ECE Regulation No 83.

Figure VI.13 000 km run-in period (no excessive purge/load)Use of aged of canister(s)Steam-clean of vehicle (if necessary)Reducing or removing non-fuel background emission sources (if agreed) 1. Evaporative emission control families – as in paragraph 3.2 of Annex I
 2. Exhaust emissions may be measured during Type 1 test drive but these are not used for legislative purposes. Exhaust emission legislative test remains separate.
 4.3. 
The analytical systems shall meet the requirements of paragraph 4.3. of Annex 7 to UN/ECE Regulation No 83.
 4.4. 
The temperature recording shall meet the requirements of paragraph 4.5. of Annex 7 to UN/ECE Regulation No 83.
 4.5. 
The pressure recording shall meet the requirements of paragraph 4.6. of Annex 7 to UN/ECE Regulation No 83.
 4.6. 
The fans shall meet the requirements of paragraph 4.7. of Annex 7 to UN/ECE Regulation No 83.
 4.7. 
The gases shall meet the requirements of paragraph 4.8. of Annex 7 to UN/ECE Regulation No 83.
 4.8. 
The additional equipment shall meet the requirements of paragraph 4.9. of Annex 7 to UN/ECE Regulation No 83.
 5.  5.1. 
Before performing the hot soak and diurnal losses sequences, the canister(s) must be aged according the following procedure described in Figure VI.2.

Figure VI.2 5.1.1. 
In a dedicated temperature chamber, the canister(s) is (are) cycled between temperatures from – 15 °C to 60 °C, with 30 min of stabilisation at – 15 °C and 60 °C. Each cycle shall last 210 min as in Figure 3. The temperature gradient shall be as close as possible to 1 °C/min. No forced air flow should pass through the canister(s).

The cycle is repeated 50 times consecutively. In total, this operation will last 175 hours.

Figure VI.3 5.1.2. 
After the temperature aging procedure, the canister(s) is (are) shaken along the vertical axis with the canister(s) mounted as per its orientation in the vehicle with overall Grms > 1.5m/sec2 with frequency of 30 ± 10 Hz. The test shall last 12 hours.
 5.1.3.  5.1.3.1.  5.1.3.1.1. 
The canister(s) is (are) loaded to the corresponding breakthrough. Breakthrough shall be considered as the point at which the cumulative quantity of hydrocarbons emitted is equal to 2 grams. As an alternative, the loading is deemed completed when the equivalent concentration level at the vent hole reaches 3 000 ppm.
 5.1.3.1.1.1 
Density at 15 °C


— Vapour Pressure (DVPE)
— Distillation (evaporates only)
— Hydrocarbon analysis (olefins, aromatics, benzene only)
— Oxygen content
— Ethanol content
 5.1.3.1.2. 
The canister must be purged between 5 minutes to 1 hour maximum after loading.
 5.1.3.1.3. The steps of the procedure set out in points 5.1.3.1.1. and 5.1.3.1.2. shall be repeated 50 times, followed by a measurement of the Butane Working Capacity (BWC), meant as the ability of an activated carbon canister to absorb and desorb butane from dry air under specified conditions, in 5 butane cycles, as described in point 5.1.3.1.4 below. The fuel vapour ageing will continue until 300 cycles are reached. A measurement of the BWC in 5 butane cycles, as set out in point 5.1.3.1.4, will be made after the 300 cycles.
 5.1.3.1.4. 
Then, the canister(s) shall be purged according the procedure of paragraph 5.1.3.8. of Annex 7 to UN/ECE Regulation No 83.

The canister must be purged between 5 minutes to 1 hour maximum after loading.

The operation of butane loading is repeated 5 times. The BWC is recorded after each butane loading step. The BWC50 is calculated as the average of the 5 BWC and recorded.

In total, the canister(s) will be aged with 300 fuel aging cycles + 10 butane cycles and considered to be stabilized.
 5.1.3.2. If the canister(s) is (are) provided by the Suppliers, the Manufacturers shall inform in advance the Type Approval Authorities to allow them to witness any part of the aging in the Supplier’s facilities.
 5.1.3.3. The manufacturer shall provide to the Type Approval Authorities a test report including at least the following elements:

— Type of activated carbon,
— Loading rate,
— Fuel specifications,
— BWC measurements
 5.2. 
Figure VI.4
The fuel storage system representative of a family is selected and fixed to a rig, then soaked with E10 reference fuel for 20 weeks at 40 °C +/– 2 °C. The orientation of the fuel storage system on the rig has to be similar to the original orientation on the vehicle.
 5.2.1. The tank is filled with fresh E10 reference fuel at a temperature of 18 °C ± 8 °C. The tank is filled at 40 +/– 2 % of the nominal tank capacity. Then, the rig with the fuel system is placed in a specific and secure room with a controlled temperature of 40 °C +/– 2 °C for 3 weeks.
 5.2.2. 
Within 6 to 36 hours, the last 6h at 20 °C ± 2 °C the rig with the fuel system is placed in a VT-SHED a diurnal procedure is performed over a period of 24 hours, according to the procedure described according to paragraph 5.7. of Annex 7 of UN/ECE Regulation No 83. The fuel system is vented to the outside of the VT-SHED to eliminate the possibility of the tank venting emissions being counted as permeation. The HC emissions are measured and the value is recorded as HC3W.
 5.2.3. The rig with the fuel system is placed again in a specific and secure room with a controlled temperature of 40 °C +/– 2 °C for the remaining 17 weeks.
 5.2.4. 
Within 6 to 36 hours, the last 6h at 20 oC ± 2 °C, the rig with the fuel system is placed in a VT-SHED a diurnal procedure is performed over a period of 24 hours, according to the procedure described according to paragraph 5.7. Annex 7 of UN/ECE Regulation No 83. The fuel system is vented to the outside of the VT-SHED to eliminate the possibility of the tank venting emissions being counted as permeation. The HC emissions are measured and the value is recorded as HC20W.
 5.2.5. The Permeability Factor is the difference between HC20W and HC3W in g/24h with 3 digits.
 5.2.6. If the Permeability Factor is determined by the Suppliers, the Manufacturers shall inform in advance the Type Approval Authorities to allow witness check in Supplier’s facilities.
 5.2.7 

((a)) A full description of the fuel storage system tested, including information on the type of tank tested, whether the tank is monolayer or multilayer and which types of materials are used for the tank and other parts of the fuel storage system,
((b)) the weekly mean temperatures at which the ageing was performed,
((c)) the HC measured at week 3 (HC3W),
((d)) the HC measured at week 20 (HC20W)
((e)) the resulting Permeability Factor (PF)
 5.2.8 
APF multilayer tank = 120 mg/24h
 5.2.8.1 Where the manufacturer chooses to use Assigned Permeability Factors, the manufacturer shall provide to the Type Approval Authority, a declaration in which the type of tank is clearly specified, as well as a declaration of the type of materials used.
 5.3. 
The vehicle is prepared in accordance to paragraph 5.1.1. and 5.1.2. of Annex 7 of UN/ECE Regulation No 83. At the request of the manufacturer and with the approval of the approval authority, non-fuel background emission sources may be removed or reduced before testing (e.g. baking tire or vehicle, removing washer fluid).
 5.3.1. 
The vehicle is parked for a minimum of 12 hours and a maximum of 36 hours in the soak area. The engine oil and coolant temperatures shall have reached the temperature of the area or within ±3 C of it at the end of the period.
 5.3.2. 
The fuel drain and refill is performed in accordance to the procedure of paragraph 5.1.7. of Annex 7 of UN/ECE Regulation No 83.
 5.3.3. 
Within one hour from the completing of fuel drain and refill, the vehicle is placed on the chassis dynamometer and driven through one Part One and two Part Two driving cycles of Type I according to Annex 4a to UN/ECE Regulation No 83.

Exhaust emissions are not sampled during this operation.
 5.3.4. 
Within five minutes of completing the preconditioning operation the vehicle is parked for a minimum of 12 hours and a maximum of 36 hours in the soak area. The engine oil and coolant temperatures shall have reached the temperature of the area or within ±3 C of it at the end of the period.
 5.3.5. 
The canister(s) aged according to the sequence described in paragraph 5.1 is loaded to breakthrough according to the procedure paragraph 5.1.4 of Annex 7 to UN/ECE Regulation No 83.
 5.3.6.  5.3.6.1. Within one hour from completing of canister loading, the vehicle is placed on the chassis dynamometer and driven through one Part One and one Part Two driving cycles of Type I according to Annex 4a to UN/ECE Regulation No 83. Then the engine is shut off. Exhaust emissions may be sampled during this operation but the results shall not be used for the purpose of exhaust emission type approval.
 5.3.6.2. Within two minutes of completing the Type I Test drive specified in point 5.3.6.1 the vehicle is driven a further conditioning drive consisting of two Part One test cycles (hot start) of Type I. Then the engine is shut off again. Exhaust emissions need not be sampled during this operation.
 5.3.7. 
After the Dynamometer test, hot soak evaporative emissions test is performed in accordance to paragraph 5.5 of Annex 7 to UN/ECE Regulation No 83. The hot soak losses result is calculated according to paragraph 6 of Annex 7 to UN/ECE Regulation No 83 and recorded as MHS.
 5.3.8. 
After hot soak evaporative emissions test, a soak is performed according to paragraph 5.6 of Annex 7 to UN/ECE Regulation No 83.
 5.3.9.  5.3.9.1. After the soak, a first measurement of Diurnal Losses over 24 hours is performed according to paragraph 5.7 of Annex 7 to UN/ECE Regulation No 83. Emissions are calculated according to paragraph 6 of Annex 7 to UN/ECE Regulation No 83. The obtained value is recorded as MD1.
 5.3.9.2. After the first 24 hours diurnal test, a second measurement of Diurnal Losses over 24 hours is performed according to paragraph 5.7 of Annex 7 to UN/ECE Regulation No 83. Emissions are calculated according to paragraph 6 of Annex 7 to UN/ECE Regulation No 83. The obtained value is recorded as MD2.
 5.3.10. 
The result of MHS+MD1+MD2+2PF shall be below the limit defined in Table 3 of Annex I to Regulation (EC) No 715/2007.
 5.3.11 The manufacturer shall provide to the Type Approval Authorities a test report containing at least the following elements:

((a)) description of the soak periods, including time and mean temperatures
((b)) description to aged canister used and reference to exact ageing report
((c)) mean temperature during the hot soak test
((d)) measurement during hot soak test, HSL
((e)) measurement of first diurnal, DL1st day
((f)) measurement of second diurnal, DL2nd day
((g)) final evaporative test result, calculated as "MHS+MD1+MD2+2PF"

ANNEX VII
VERIFYING THE DURABILITY OF POLLUTION CONTROL DEVICES  1.  1.1. This Annex describes the tests for verifying the durability of pollution control devices.
 2.  2.1. The general requirements for conducting the type 5 test shall be those set out in Section 5.3.6. of UN/ECE Regulation No 83 with exceptions provided in sections 2.2. and 2.3 below.
 2.2. 
Engine Category Assigned deterioration factors
CO THC NMHC NOx HC + NOx PM P
Positive-ignition 1,5 1,3 1,3 1,6 — 1,0 1,0
Compression-ignition As there are no assigned deterioration factors for compression ignition vehicles, manufacturers shall use the whole vehicle or bench ageing durability test procedures to establish deterioration factors. 2.3. The reference to the requirements of paragraphs 5.3.1 and 8.2 in paragraph 5.3.6.5 of UN/ECE Regulation No 83 shall be understood as reference to the requirements of Annex XXI and Section 4.2 of Annex I to this Regulation during the useful life of the vehicle.
 2.4. Before emission limits set out in Table 2 of Annex I to Regulation (EC) No 715/2007 are used for assessing compliance with the requirements referred to in paragraph 5.3.6.5 of UN/ECE Regulation No 83 the deterioration factors shall be calculated and applied, as described in Table A7/1 of Sub-Annex 7 and Table A8/5 of Sub-Annex 8 to Annex XXI.
 3.  3.1. The technical requirements and specifications shall be those set out in sections 1 to 7 and Appendices 1, 2 and 3 of Annex 9 to UN/ECE Regulation No 83, with the exceptions set out in sections 3.2. to 3.10.
 3.2. Reference to Annex 2 in paragraph 1.5. of Annex 9 to UN/ECE Regulation No 83 shall be understood as referring to Appendix 4 to Annex I to this Regulation.
 3.3. Reference to the emissions limits set out in Table 1 in paragraph 1.6. of Annex 9 to UN/ECE Regulation No 83 shall be understood as referring to the emissions limits set out in Table 2 of Annex I to Regulation (EC) No 715/2007.
 3.4. The references to the Type I test in paragraph 2.3.1.7 of Annex 9 of UN/ECE Regulation No 83 shall be understood as reference to the Type 1 test in Annex XXI to this Regulation.
 3.5. The references to the Type I test in paragraph 2.3.2.6 of Annex 9 of UN/ECE Regulation No 83 shall be understood as reference to the Type 1 test in Annex XXI to this Regulation.
 3.6. The references to the Type I test in paragraph 3.1 of Annex 9 of UN/ECE Regulation No 83 shall be understood as reference to the Type 1 test in Annex XXI to this Regulation.
 3.7. The reference to paragraph 5.3.1.4. in the first section of paragraph 7 of Annex 9 of UN/ECE Regulation No 83 shall be understood as reference to Table 2 of Annex I of the Regulation (EC) No 715/2007.
 3.8. The reference in paragraph 6.3.1.2 of Annex 9 to UN/ECE Regulation No 83 to the methods in Appendix 7 to Annex 4a shall be understood as being a reference to Sub-Annex 4 to Annex XXI to this Regulation.
 3.9. The reference in paragraph 6.3.1.4 of Annex 9 to UN/ECE Regulation No 83 to Annex 4a shall be understood as being a reference to Sub-Annex 4 to Annex XXI to this Regulation.
 3.10. The road load coefficients to be used shall be those for VL. If VL low does not exist the VH road load shall be used.

ANNEX VIII
VERIFYING THE AVERAGE EMISSIONS AT LOW AMBIENT TEMPERATURES  1.  1.1. This Annex describes the equipment required and the procedure for the Type 6 test in order to verify the emissions at cold temperatures.
 2.  2.1. The general requirements for the Type 6 test are those set out in section 5.3.5 of UN/ECE Regulation No 83 with the exception specified in section 2.2 below.
 2.2. The limit values referred to in paragraph 5.3.5.2 of UN/ECE Regulation No 83 relate to the limit values set out in Annex 1, Table 4, to Regulation (EC) No 715/2007.
 3.  3.1. The technical requirements and specifications are those set out in section 2 to 6 of Annex 8 to UN/ECE Regulation No 83 with the exception specified in section 3.2 below.
 3.2. The reference to paragraph 2 of Annex 10 in paragraph 3.4.1 of Annex 8 to UN/ECE Regulation No 83 shall be understood as reference to Section B of Annex IX to this Regulation.
 3.3. The road load coefficients to be used shall be those for VL. If VL low does not exist the VH road load shall be used.

ANNEX IX
A.  1. 

Parameter Unit Limits Test method
Minimum Maximum
Research octane number, RON  95,0 98,0 EN ISO 5164
Motor octane number, MON  85,0 89,0 EN ISO 5163
Density at 15 C kg/m3 743,0 756,0 EN ISO 12185
Vapour pressure (DVPE) kPa 56,0 60,0 EN 13016-1
Water content % v/v  0,05 EN 12937
Appearance at – 7 C  Clear and bright 
Distillation:    
 — evaporated at 70 C
 % v/v 34,0 46,0 EN ISO 3405
 — evaporated at 100 C
 % v/v 54,0 62,0 EN ISO 3405
 — evaporated at 150 C
 % v/v 86,0 94,0 EN ISO 3405
 — final boiling point
 °C 170 195 EN ISO 3405
Residue % v/v — 2,0 EN ISO 3405
Hydrocarbon analysis:    
 — olefins
 % v/v 6,0 13,0 EN 22854
 — aromatics
 % v/v 25,0 32,0 EN 22854
 — benzene
 % v/v — 1,00 EN 22854EN 238
 — saturates
 % v/v report EN 22854
Carbon/hydrogen ratio  report 
Carbon/oxygen ratio  report 
Induction Period minutes 480 — EN ISO 7536
Oxygen content % m/m 3,3 3,7 EN 22854
Solvent washed gum(Existent gum content) mg/100 ml — 4 EN ISO 6246
Sulphur content mg/kg — 10 EN ISO 20846EN ISO 20884
Copper corrosion 3 hrs, 50 C  — class 1 EN ISO 2160
Lead content mg/l — 5 EN 237
Phosphorus content mg/l — 1,3 ASTM D 3231
Ethanol % v/v 9,0 10,0 EN 22854








 (2) Equivalent EN/ISO methods will be adopted when issued for properties listed above.


Parameter Unit Limits Test method
Minimum Maximum
Research octane number, RON  95 — EN ISO 5164
Motor octane number, MON  85 — EN ISO 5163
Density at 15 C kg/m3 Report ISO 3675
Vapour pressure kPa 40 60 EN ISO 13016-1 (DVPE)
Sulphur content mg/kg — 10 EN ISO 20846 EN ISO 20884
Oxidation stability minutes 360  EN ISO 7536
Existent gum content (solvent washed) mg/100ml — 5 EN-ISO 6246
Appearance This shall be determined at ambient temperature or 15 C whichever is higher.  Clear and bright, visibly free of suspended or precipitated contaminants Visual inspection
Ethanol and higher alcohols % (V/V) 83 85 EN 1601EN 13132EN 14517
Higher alcohols (C3-C8) % (V/V) — 2 
Methanol % (V/V)  0,5 
Petrol % (V/V) Balance EN 228
Phosphorus mg/l 0,3 ASTM D 3231
Water content % (V/V)  0,3 ASTM E 1064
Inorganic chloride content mg/l  1 ISO 6227
pHe  6,5 9 ASTM D 6423
Copper strip corrosion (3h at 50 C) Rating Class 1  EN ISO 2160
Acidity, (as acetic acid CH3COOH) % (m/m) — 0,005 ASTM D 1613
(mg/l) — 40
Carbon/hydrogen ratio  report 
Carbon/oxygen ration  report 









Parameter Unit Fuel A Fuel B Test method
Composition:    ISO 7941
C3-content % vol 30 ± 2 85 ± 2 
C4-content % vol Balance Balance 
< C3, > C4 % vol Maximum 2 Maximum 2 
Olefins % vol Maximum 12 Maximum 15 
Evaporation residue mg/kg Maximum 50 Maximum 50 prEN 15470
Water at 0 C  Free Free prEN 15469
Total sulphur content mg/kg Maximum 10 Maximum 10 ASTM 6667
Hydrogen sulphide  None None ISO 8819
Copper strip corrosion Rating Class 1 Class 1 ISO 6251
Odour  Characteristic Characteristic 
Motor octane number  Minimum 89 Minimum 89 EN 589 Annex B



Characteristics Units Basis Limits Test method
minimum maximum
Reference fuel G20     
Composition:     
Methane % mole 100 99 100 ISO 6974
Balance % mole — — 1 ISO 6974
N2 % mole    ISO 6974
Sulphur content mg/m3 — — 10 ISO 6326-5
Wobbe Index (net) MJ/m3 48,2 47,2 49,2 
Reference fuel G25     
Composition:     
Methane % mole 86 84 88 ISO 6974
Balance % mole — — 1 ISO 6974
N2 % mole 14 12 16 ISO 6974
Sulphur content mg/m3 — — 10 ISO 6326-5
Wobbe Index (net) MJ/m3 39,4 38,2 40,6 








Characteristics Units Limits Test method
minimum maximum
Hydrogen purity % mole 98 100 ISO 14687-1
Total hydrocarbon μmol/mol 0 100 ISO 14687-1
Water μmol/mol 0  ISO 14687-1
Oxygen μmol/mol 0  ISO 14687-1
Argon μmol/mol 0  ISO 14687-1
Nitrogen μmol/mol 0  ISO 14687-1
CO μmol/mol 0 1 ISO 14687-1
Sulphur μmol/mol 0 2 ISO 14687-1
Permanent particulates    ISO 14687-1






 2. 

Parameter Unit Limits Test method
Minimum Maximum
Cetane Index  46,0  EN ISO 4264
Cetane number  52,0 56,0 EN ISO 5165
Density at 15 C kg/m3 833,0 837,0 EN ISO 12185
Distillation:    
 — 50 % point
 °C 245,0 — EN ISO 3405
 — 95 % point
 °C 345,0 360,0 EN ISO 3405
 — final boiling point
 °C — 370,0 EN ISO 3405
Flash point °C 55 — EN ISO 2719
Cloud point °C — – 10 EN 23015
Viscosity at 40 C mm2/s 2,30 3,30 EN ISO 3104
Polycyclic aromatic hydrocarbons % m/m 2,0 4,0 EN 12916
Sulphur content mg/kg — 10,0 EN ISO 20846EN ISO 20884
Copper corrosion 3 hrs, 50 C  — Class 1 EN ISO 2160
Conradson carbon residue (10 % DR) % m/m — 0,20 EN ISO 10370
Ash content % m/m — 0,010 EN ISO 6245
Total contamination mg/kg — 24 EN 12662
Water content mg/kg — 200 EN ISO 12937
Acid number mg KOH/g — 0,10 EN ISO 6618
Lubricity (HFRR wear scan diameter at 60 C) μm — 400 EN ISO 12156
Oxidation stability at 110 C h 20,0  EN 15751
FAME % v/v 6,0 7,0 EN 14078




 3. 

Characteristics Units Limits Test method
minimum maximum
Hydrogen fuel % mole 99,99 100 ISO 14687-2
Total gases μmol/mol 0 100 
Total hydrocarbon μmol/mol 0 2 ISO 14687-2
Water μmol/mol 0 5 ISO 14687-2
Oxygen μmol/mol 0 5 ISO 14687-2
Helium (He), Nitrogen (N2), Argon (Ar) μmol/mol 0 100 ISO 14687-2
CO2 μmol/mol 0 2 ISO 14687-2
CO μmol/mol 0 0,2 ISO 14687-2
Total sulphur compounds μmol/mol 0 0,004 ISO 14687-2
Formaldehyde (HCHO) μmol/mol 0 0,01 ISO 14687-2
Formic acid (HCOOH) μmol/mol 0 0,2 ISO 14687-2
Ammonia (NH3) μmol/mol 0 0,1 ISO 14687-2
Total halogenated compounds μmol/mol 0 0,05 ISO 14687-2
Particulates size μm 0 10 ISO 14687-2
Particulates concentration μg/l 0 1 ISO 14687-2



B. 

Parameter Unit Limits Test method
Minimum Maximum
Research octane number, RON  95,0 98,0 EN ISO 5164
Motor octane number, MON  85,0 89,0 EN ISO 5163
Density at 15 C kg/m3 743,0 756,0 EN ISO 12185
Vapour pressure (DVPE) kPa 56,0 95,0 EN 13016-1
Water content  max 0,05 % v/vAppearance at – 7 C: clear and bright EN 12937
Distillation:    
 — evaporated at 70 C
 % v/v 34,0 46,0 EN ISO 3405
 — evaporated at 100 C
 % v/v 54,0 62,0 EN ISO 3405
 — evaporated at 150 C
 % v/v 86,0 94,0 EN ISO 3405
 — final boiling point
 °C 170 195 EN ISO 3405
Residue % v/v — 2,0 EN ISO 3405
Hydrocarbon analysis:    
 — olefins
 % v/v 6,0 13,0 EN 22854
 — aromatics
 % v/v 25,0 32,0 EN 22854
 — benzene
 % v/v — 1,00 EN 22854EN 238
 — saturates
 % v/v report EN 22854
Carbon/hydrogen ratio  report 
Carbon/oxygen ratio  report 
Induction Period minutes 480 — EN ISO 7536
Oxygen content % m/m 3,3 3,7 EN 22854
Solvent washed gum(Existent gum content) mg/100 ml — 4 EN ISO 6246
Sulphur content mg/kg — 10 EN ISO 20846EN ISO 20884
Copper corrosion 3 hrs, 50 C  — class 1 EN ISO 2160
Lead content mg/l — 5 EN 237
Phosphorus content mg/l — 1,3 ASTM D 3231
Ethanol % v/v 9,0 10,0 EN 22854








 (2) Equivalent EN/ISO methods will be adopted when issued for properties listed above.


Parameter Unit Limits Test method
Minimum Maximum
Research octane number, RON  95 — EN ISO 5164
Motor octane number, MON  85 — EN ISO 5163
Density at 15 C kg/m3 report EN ISO 12185
Vapour pressure kPa 50 60 EN ISO 13016-1 (DVPE)
Sulphur content mg/kg — 10 EN ISO 20846EN ISO 20884
Oxidation stability minutes 360 — EN ISO 7536
Existent gum content (solvent washed) mg/100ml — 4 EN ISO 6246
Appearance shall be determined at ambient temperature or 15 C whichever is higher  Clear and bright, visibly free of suspended or precipitated contaminants Visual inspection
Ethanol and higher alcohols % (V/V) 70 80 EN 1601EN 13132EN 14517
Higher alcohols (C3 – C8) % (V/V) — 2 
Methanol  — 0,5 
Petrol % (V/V) Balance EN 228
Phosphorus mg/l 0,30 EN 15487ASTM D 3231
Water content % (V/V) — 0,3 ASTM E 1064EN 15489
Inorganic chloride content mg/l — 1 ISO 6227 — EN 15492
pHe  6,50 9 ASTM D 6423EN 15490
Copper strip corrosion (3h at 50 C) Rating Class 1  EN ISO 2160
Acidity (as acetic acid CH3COOH) % (m/m)  0,005 ASTM D1613EN 15491
mg/l  40
Carbon/hydrogen ration  report 
Carbon/oxygen ration  report 








ANNEX X

Reserved

ANNEX XI
1.  1.1. This Annex sets out the functional aspects of on-board diagnostic (OBD) systems for the control of emissions from motor vehicles.

2.  2.1. The definitions, requirements and tests for OBD systems are those specified in Sections 2 and 3 of Annex 11 to UN/ECE Regulation No 83. The exceptions to these requirements are described in the following sections.
 2.1.1. 
'For the purposes of this Annex only:'
 2.1.2. 
'A “driving cycle” consists of engine key on, a driving mode where a malfunction would be detected if present, and engine key-off'.
 2.1.3. 
' 3.2.3. Identification of deterioration or malfunctions may be also be done outside a driving cycle (e.g. after engine shutdown).
'
 2.1.4. Reference to ‘THC and NOx’ in paragraph 3.3.3.1. of Annex 11to UN/ECE Regulation No 83 shall be understood as being reference to ‘NMHC and NOx’.
 2.1.5. Reference to ‘limits’ in paragraphs 3.3.3.1. and 3.3.4.4. of Annex 11to UN/ECE Regulation No 83 shall be understood as being reference to ‘OBD threshold limits’.
 2.1.6. Reference to ‘emission limits’ in paragraph 3.3.5. of Annex 11to UN/ECE Regulation No 83 shall be understood as being reference to ‘OBD threshold limits’.
 2.1.7. Paragraphs 3.3.4.9. and 3.3.4.10. of Annex 11 of UN/ECE Regulation No 83 shall be deleted.
 2.1.8. 
' 3.3.5.1. 

((a)) A particulate trap fitted to compression ignition engines as a separate unit or integrated into a combined emission control device;
((b)) A NOx after-treatment system fitted to compression ignition engines as a separate unit or integrated into a combined emission control device;
((c)) A diesel oxidation catalyst (DOC) fitted to compression ignition engines as a separate unit or integrated into a combined emission control device.
 3.3.5.2. The devices referred to in paragraph 3.3.5.1. shall also be monitored for any failure that would result in exceeding the applicable OBD threshold limits.
'
 2.1.9. 
'The OBD system may erase a fault code and the distance travelled and freeze-frame information if the same fault is not re-registered in at least 40 engine warm-up cycles or 40 driving cycles with vehicle operation in which the criteria specified in sections 7.5.1.(a)–(c) of Annex 11, Appendix 1 are met.'
 2.1.10. 
'… the standard listed in paragraph 6.5.3.2.(a) of Annex 11, Appendix 1 of this Regulation.'
 2.1.11. 
' 3.10. Additional provisions for vehicles employing engine shut - off strategies
 3.10.1. Driving cycle
 3.10.1.1. Autonomous engine restarts commanded by the engine control system following an engine stall may be considered a new driving cycle or a continuation of the existing driving cycle.
'
 2.2. The Type V durability distance and Type V durability test mentioned in section 3.1 and 3.3.1 of Annex 11 to UN/ECE Regulation No 83 respectively shall be understood as reference to the requirements of Annex VII to this Regulation.
 2.3.  2.3.1. 
Final Euro 6 OBD threshold limits
  Reference mass(RM) (kg) Mass of carbon monoxide Mass of non-methane hydrocarbons Mass of oxides of nitrogen Mass of particulate matter Number of particles
Category Class  (CO)(mg/km) (NMHC)(mg/km) (NOx)(mg/km) (PM)(mg/km) (PN)(#/km)
 PI CI PI CI PI CI CI PI CI PI
M — All 1 900 1 750 170 290 90 140 12 12  
N1 I RM ≤ 1 305 1 900 1 750 170 290 90 140 12 12  
II 1 305 < RM ≤ 1 760 3 400 2 200 225 320 110 180 12 12  
III 1 760 < RM 4 300 2 500 270 350 120 220 12 12  
N2 — All 4 300 2 500 270 350 120 220 12 12  


Key: PI = Positive Ignition, CI = Compression Ignition. 2.3.2. 
Preliminary Euro 6 OBD threshold limits
  Reference mass(RM) (kg) Mass of carbon monoxide Mass of non-methane hydrocarbons Mass of oxides of nitrogen Mass of particulate matter
Category Class  (CO)(mg/km) (NMHC)(mg/km) (NOx)(mg/km) (PM)(mg/km)
 PI CI PI CI PI CI CI PI
M — All 1 900 1 750 170 290 150 180 25 25
N1 I RM ≤ 1 305 1 900 1 750 170 290 150 180 25 25
 II 1 305 < RM ≤ 1 760 3 400 2 200 225 320 190 220 25 25
 III 1 760 < RM 4 300 2 500 270 350 210 280 30 30
N2 — All 4 300 2 500 270 350 210 280 30 30

Key: PI = Positive Ignition, CI = Compression Ignition 2.4. The reference to the threshold limits in Section 3.3.3.1 of Annex 11 to UNECE Regulation No 83 shall be understood as reference to the threshold limits in Section 2.3 of this Annex.
 2.5. The Type I test cycle referred to in paragraph 3.3.3.2. of Annex 11 to UN/ECE Regulation No 83 shall be understood as being the same as the Type 1 cycle that was used for at least two consecutive cycles after introduction of the misfire faults according to paragraph 6.3.1.2. of Appendix 1 to Annex 11 to UN/ECE Regulation No 83.
 2.6. The reference to the particulate threshold limits provided for by paragraph 3.3.2. in section 3.3.3.7 of Annex 11 to UN/ECE Regulation No 83 shall be understood as being reference to the particulate threshold limits provided in Section 2.3 of this Annex.
 2.7. The reference to the Type I test cycle in section 2.1.3 of Appendix 1 to Annex 11 of UN/ECE Regulation No 83 shall be understood as a reference to the type 1 test according to Regulation (EC) 692/2008 or Annex XXI of this Regulation, upon the choice of the manufacturer for each individual malfunction to be demonstrated.

3.  3.1. The administrative provisions for deficiencies of OBD systems as set out in Article 6(2) shall be those specified in Section 4 of Annex 11 of UN/ECE Regulation No 83 with the following exceptions.
 3.2. Reference to OBD threshold limits in paragraph 4.2.2. of Annex 11 to UN/ECE Regulation No 83 shall be understood as being reference to the OBD threshold limits in Section 2.3 of this Annex.
 3.3. 
'The approval authority shall notify its decision in granting a deficiency request in accordance with Article 6(2).'

4.  4.1. Requirements for access to OBD information are specified in section 5 of Annex 11 to UN/ECE Regulation 83. The exceptions to these requirements are described in the following sections.
 4.2. References to Appendix 1 of Annex 2 to UN/ECE Regulation No 83 shall be understood as references to Appendix 5 to Annex I to this Regulation.
 4.3. References to section 3.2.12.2.7.6. of Annex 1 to UN/ECE Regulation No 83 shall be understood as references to 3.2.12.2.7.6 of Appendix 3 to Annex I to this Regulation.
 4.4. References to ‘contracting parties’ shall be understood as references to ‘member states’.
 4.5. References to approval granted under Regulation 83 shall be understood as references to type-approval granted under this Regulation and Regulation (EC) No 715/2007.
 4.6. UN/ECE type-approval shall be understood as EC type-approval.

Appendix 1
1.  1.1. This Appendix describes the procedure of the test according to section 2 of this Annex.

2.  2.1. The technical requirements and specifications shall be those set out in Appendix 1 to Annex 11 to UN/ECE Regulation No 83 with the exceptions and additional requirements as described in the following sections.
 2.2. The references in Appendix 1 to Annex 11 to UN/ECE Regulation No 83 to the OBD threshold limits set out in paragraph 3.3.2 to Annex 11 of UN/ECE Regulation No 83 shall be understood as references to the OBD threshold limits set out in section 2.3 of this Annex.
 2.3. The reference fuels specified in paragraph 3.2 of Appendix 1 of Annex 11 of UN/ECE Regulation No 83 shall be understood as reference to the appropriate reference fuel specifications in Annex IX to this Regulation.
 2.4. The reference to Annex 11 in paragraph 6.5.1.4 of Appendix 1 of Annex 11 of UN/ECE Regulation No 83 shall be understood as reference to Annex XI to this Regulation.
 2.5. 
'For electrical failures (short/open circuit), the emissions may exceed the limits of paragraph 3.3.2. by more than twenty per cent.'
 2.6. 
' 6.5.3. The emission control diagnostic system shall provide for standardised and unrestricted access and conform with the following ISO standards and/or SAE specification. Later versions may be used at the manufacturers' discretion.
 6.5.3.1. 

((a)) ISO 15765-4:2011 “Road vehicles – Diagnostics on Controller Area Network (CAN) – Part 4: Requirements for emissions-related systems”, dated 1 February 2011;
 6.5.3.2. 

((a)) ISO 15031-5 “Road vehicles - communication between vehicles and external test equipment for emissions-related diagnostics – Part 5: Emissions-related diagnostic services”, dated 1 April 2011 or SAE J1979 dated 23 February 2012;
((b)) ISO 15031-4 “Road vehicles – Communication between vehicle and external test equipment for emissions related diagnostics – Part 4: External test equipment”, dated 1 June 2005 or SAE J1978 dated 30 April 2002;
((c)) ISO 15031-3 “Road vehicles – Communication between vehicle and external test equipment for emissions related diagnostics Part 3: Diagnostic connector and related electrical circuits: specification and use”, dated 1 July 2004 or SAE J 1962 dated 26 July 2012;
((d)) ISO 15031-6 “Road vehicles – Communication between vehicle and external test equipment for emissions related diagnostics – Part 6: Diagnostic trouble code definitions”, dated 13 August 2010 or SAE J2012 dated 07 March 2013;
((e)) ISO 27145 “Road vehicles – Implementation of World-Wide Harmonized On-Board Diagnostics (WWH-OBD)” dated 2012-08-15 with the restriction, that only 6.5.3.1.(a) may be used as a data link;
((f)) ISO 14229:2013 “Road vehicles – Unified diagnostic services (UDS) with the restriction, that only 6.5.3.1.(a) may be used as a data link”.

The standards (e) and (f) may be used as an option instead of (a) not earlier than 1 January 2019.
 6.5.3.3. Test equipment and diagnostic tools needed to communicate with OBD systems shall meet or exceed the functional specification given in the standard listed in paragraph 6.5.3.2.(b) of this Appendix.
 6.5.3.4. 
The vehicle manufacturer shall provide to a national standardisation body the details of any emission-related diagnostic data, e.g. PID’s, OBD monitor Id’s, Test Id’s not specified in the standard listed in paragraph 6.5.3.2.(a) of this Regulation but related to this Regulation.
 6.5.3.5. 
The vehicle manufacturer shall provide to a national standardisation body the details of any emission-related diagnostic data, e.g. PID’s, OBD monitor Id’s, Test Id’s not specified in the standards listed in paragraph 6.5.3.2.(a) of this Appendix but related to this Regulation.
 6.5.3.6. The connection interface between the vehicle and the diagnostic tester shall be standardised and shall meet all the requirements of the standard listed in paragraph 6.5.3.2.(c) of this appendix. The installation position shall be subject to agreement of the administrative department such that it is readily accessible by service personnel but protected from tampering by non-qualified personnel.
 6.5.3.7. 
Entitled to such information is any person engaged in commercially servicing or repairing, road-side rescuing, inspecting or testing of vehicles or in the manufacturing or selling replacement or retro-fit components, diagnostic tools and test equipment.
'
 2.6. 
' 6.1.1. The Type I Test need not be performed for the demonstration of electrical failures (short/open circuit). The manufacturer may demonstrate these failure modes using driving conditions in which the component is used and the monitoring conditions are encountered. These conditions shall be documented in the type approval documentation.
'
 2.7. 
'At the request of the manufacturer, alternative and/or additional preconditioning methods may be used.'
 2.8. 
' 6.2.3. The use of additional preconditioning cycles or alternative preconditioning methods shall be documented in the type approval documentation.
'
 2.9. 
'Electrical disconnection of the electronic evaporative purge control device (if equipped and if active on the selected fuel type).'
 2.10. 
'The MI shall be activated at the latest before the end of this test under any of the conditions given in paragraphs 6.4.1.2. to 6.4.1.5. The MI may also be activated during preconditioning. The Technical Service may substitute those conditions with others in accordance with paragraph 6.4.1.6.'
 2.11. 
'The MI shall be activated at the latest before the end of this test under any of the conditions given in paragraphs 6.4.2.2. to 6.4.2.5. The MI may also be activated during preconditioning. The Technical Service may substitute those conditions by others in accordance with paragraph 6.4.2.5.'

3.  3.1. 
The technical requirements and specifications shall be those set out in Appendix 1 to Annex 11 to UN/ECE Regulation No 83 with the exceptions and additional requirements as described in the following sections.
 3.1.1. 
For new type approvals and new vehicles the monitor required by point 2.9 of this Annex shall have an IUPR greater or equal to 0,1 until three years after the dates specified in Article 10(4) and (5) of Regulation (EC) No 715/2007 respectively.
 3.1.2. 
The manufacturer shall demonstrate to the approval authority and, upon request, to the Commission that these statistical conditions are satisfied for all monitors required to be reported by the OBD system according to paragraph 7.6. of Appendix 1 to Annex 11 to Regulation No 83 not later than 18 months after the entry onto the market of the first vehicle type with IUPR in an OBD family and every 18 months thereafter. For this purpose, for OBD families consisting of more than 1000 registrations in the Union, that are subject to sampling within the sampling period, the process described in Annex II shall be used without prejudice to the provisions of paragraph 7.1.9. of Appendix 1 to Annex 11 to Regulation No 83.

In addition to the requirements set out in Annex II and regardless of the result of the audit described in Section 2 of Annex II, the authority granting the approval shall apply the in-service conformity check for IUPR described in Appendix 1 to Annex II in an appropriate number of randomly determined cases. ‘In an appropriate number of randomly determined cases’ means, that this measure has a dissuasive effect on non-compliance with the requirements of Section 3 of this Annex or the provision of manipulated, false or non-representative data for the audit. If no special circumstances apply and can be demonstrated by the type-approval authorities, random application of the in-service conformity check to 5 % of the type approved OBD families shall be considered as sufficient for compliance with this requirement. For this purpose, type-approval authorities may find arrangements with the manufacturer for the reduction of double testing of a given OBD family as long as these arrangements do not harm the dissuasive effect of the type-approval authority’s own in-service conformity check on non-compliance with the requirements of Section 3 of this Annex. Data collected by Member States during surveillance testing programmes may be used for in-service conformity checks. Upon request, type-approval authorities shall provide data on the audits and random in-service conformity checks performed, including the methodology used for identifying those cases, which are made subject to the random in-service conformity check, to the Commission and other type-approval authorities.
 3.1.3. Non-compliance with the requirements of paragraph 7.1.6. of Appendix 1 to Annex 11 to Regulation No 83 established by tests described in point 3.1.2 of this Appendix or paragraph 7.1.9 of Appendix 1 to Annex 11 to Regulation No 83 shall be considered as an infringement subject to the penalties set out in Article 13 of Regulation (EC) No 715/2007. This reference does not limit the application of such penalties to other infringements of other provisions of Regulation (EC) No 715/2007 or this Regulation, which do not explicitly refer to Article 13 of Regulation (EC) No 715/2007.
 3.1.4. 
' 7.6.1. 

((a)) Catalysts (each bank to be reported separately);
((b)) Oxygen/exhaust gas sensors, including secondary oxygen sensors
(each sensor to be reported separately);
((c)) Evaporative system;
((d)) EGR system;
((e)) VVT system;
((f)) Secondary air system;
((g)) Particulate filter;
((h)) NOx after-treatment system (e.g. NOx absorber, NOx reagent/catalyst system);
((i)) Boost pressure control system.
'

Paragraph 7.6.2. of Appendix 1 to Annex 11 of UN/ECE Regulation No 83 shall be replaced with the following:

' 7.6.2. For specific components or systems that have multiple monitors, which are required to be reported by this point (e.g. oxygen sensor bank 1 may have multiple monitors for sensor response or other sensor characteristics), the OBD system shall separately track numerators and denominators for each of the specific monitors and report only the corresponding numerator and denominator for the specific monitor that has the lowest numerical ratio. If two or more specific monitors have identical ratios, the corresponding numerator and denominator for the specific monitor that has the highest denominator shall be reported for the specific component.
'

A new paragraph 7.6.2.1. of Appendix 1 to Annex 11 of UN/ECE Regulation No 83 shall be inserted as follows:

' 7.6.2.1. 
“Continuously,” if used in this context means monitoring is always enabled and sampling of the signal used for monitoring occurs at a rate no less than two samples per second and the presence or the absence of the failure relevant to that monitor has to be concluded within 15 seconds.

If for control purposes, a computer input component is sampled less frequently, the signal of the component may instead be evaluated each time sampling occurs.

It is not required to activate an output component/system for the sole purpose of monitoring that output component/system.
'

Appendix 2

The essential characteristics of the vehicle family shall be those specified in Appendix 2 to Annex 11 to UN/ECE Regulation No 83.

ANNEX XII
1.  1.1. According to Article 11(1) of Regulation (EU) No 725/2011 for M1 vehicles and Article 11(1) of Regulation (EU) No 427/2014 for N1 vehicles, a manufacturer wishing to benefit from a reduction of its average specific CO2 emissions, as result of the savings achieved by one or more eco-innovations fitted in a vehicle, shall apply to an approval authority for an EC type-approval certificate of the vehicle fitted with the eco-innovation.
 1.2. The CO2 emissions savings from the vehicle fitted with an eco-innovation shall, for the purpose of type approval, be determined using the procedure and testing methodology specified in the Commission Decision approving the eco-innovation, in accordance with Article 10 of Regulation (EU) No 725/2011 for M1 vehicles, or Article 10 of Regulation (EU) No 427/2014 for N1 vehicles.
 1.3. The performance of the necessary tests for the determination of the CO2 emissions savings achieved by the eco-innovations shall be considered without prejudice to the demonstration of compliance of the eco-innovations with the technical prescriptions laid down in Directive 2007/46/EC, if applicable.
 1.4. If the innovative technology does not meet the threshold of 1g CO2/km as specified in Article 9 of Regulation (EU) No 725/2011, the type approval certificate shall be issued without reference to the eco-innovation code or the CO2 reductions achieved by the innovative technology.

2.  2.1. For the purpose of determining the CO2 emissions and fuel consumption of a vehicle submitted to multi-stage type-approval, as defined in Article 3(7) of Directive 2007/46/EC, the procedures of Annex XXI apply. Specific provisions for multi-stage type approval are set in points 2.2 to 2.7 of this annex.
 2.2. The road load shall be determined with the road load matrix family by using the parameters of a representative multi-stage vehicle which are set in paragraph 4.2.1.4 in Sub-Annex 4 of Annex XXI.
 2.3. The calculation of road load and running resistance are based on a representative vehicle of a road load matrix family as set in paragraph 5.1 of Sub-Annex 4 of Annex XXI.
 2.4. The manufacturer of the base vehicle shall test a representative multi-stage vehicle for CO2 emission and fuel consumption and make available a calculation tool to establish, on the basis of the parameters of completed vehicles, their fuel consumption and CO2 values as set in Sub-Annex 7 of Annex XXI.
 2.5. The final fuel consumption and CO2 values shall be calculated by the final-stage manufacturer on the basis of the parameters of the completed vehicle as set in paragraph 3.2.4 of Sub-Annex 7 of Annex XXI.
 2.6. The manufacturer of the completed vehicle shall include, in the certificate of conformity, the information of the completed vehicles and add the information of the base vehicles in accordance with Annex IX to Directive 2007/46/EC.
 2.7. 

((a)) the CO2 emissions measured according to the methodology set out in points 2.1 to 2.6 above;
((b)) the mass of the completed vehicle in running order;
((c)) the identification code corresponding to the type, variant and version of the base vehicle;
((d)) the type-approval number of the base vehicle, including the extension number;
((e)) the name and address of the manufacturer of the base vehicle;
((f)) the mass of the base vehicle in running order.

ANNEX XIII
1.  1.1. This Annex contains additional requirement for the type-approval as separate technical units of pollution control devices.

2.  2.1. 
Original replacement pollution control devices shall bear at least the following identifications:


((a)) the vehicle manufacturer’s name or trade mark;
((b)) the make and identifying part number of the original replacement pollution control device as recorded in the information mentioned in point 2.3.
 2.2. 
Original replacement pollution control devices shall be accompanied by the following information:


((a)) the vehicle manufacturer’s name or trade mark;
((b)) the make and identifying part number of the original replacement pollution control device as recorded in the information mentioned in point 2.3;
((c)) the vehicles for which the original replacement pollution control device is of a type covered by point 2.3 of the Addendum to Appendix 4 to Annex I, including, where applicable, a marking to identify if the original replacement pollution control device is suitable for fitting to a vehicle that is equipped with an on-board diagnostic (OBD) system;
((d)) installation instructions, where necessary.

This information shall be available in the product catalogue distributed to points of sale by the vehicle manufacturer.
 2.3. The vehicle manufacturer shall provide to the technical service and/or approval authority the necessary information in electronic format which makes the link between the relevant part numbers and the type-approval documentation.
This information shall contain the following:

((a)) make(s) and type(s) of vehicle,
((b)) make(s) and type(s) of original replacement pollution control device,
((c)) part number(s) of original replacement pollution control device,
((d)) type-approval number of the relevant vehicle type(s).

3.  3.1. Every replacement pollution control device conforming to the type approved under this Regulation as a separate technical unit shall bear an EC type-approval mark.
 3.2. 
The EC type- approval mark shall also include in the vicinity of the rectangle the ‘base approval number’ contained in section 4 of the type-approval number referred to in Annex VII to Directive 2007/46/EC, preceded by the two figures indicating the sequence number assigned to the latest major technical amendment to Regulation (EC) No 715/2007 or this Regulation on the date EC type-approval for a separate technical unit was granted. For this Regulation, the sequence number is 00.
 3.3. The EC type-approval mark shall be affixed to the replacement pollution control device in such a way as to be clearly legible and indelible. It shall, wherever possible, be visible when the replacement pollution control device is installed on the vehicle.
 3.4. Appendix 3 to this Annex gives example of the EC type- approval mark.

4.  4.1. The requirements for the type-approval of replacement pollution control devices shall be those of Section 5 of UN/ECE Regulation No 103 with the exceptions set out in sections 4.1.1 to 4.1.5.
 4.1.1. Reference to the ‘test cycle’ in Section 5 of UN/ECE Regulation No 103 shall be understood as being the same Type I / Type 1 test and Type I / Type 1 test cycle as used for the original type approval of the vehicle.
 4.1.2. The terms ‘catalytic converter’ and ‘converter’ used in section 5 of UN/ECE Regulation No 103 shall be understood to mean ‘pollution control device’
 4.1.3. The regulated pollutants referred to throughout section 5.2.3 of UN/ECE Regulation No 103 shall be replaced by all the pollutants specified in Annex 1, Table 2 of Regulation (EC) No 715/2007 for replacement pollution control devices intended to be fitted to vehicles type approved to Regulation (EC) No 715/2007.
 4.1.4. For replacement pollution control devices standards intended to be fitted to vehicles type approved to Regulation (EC) No 715/2007, the durability requirements and associated deterioration factors specified in section 5 of UN/ECE Regulation No 103, shall refer to those specified in Annex VII of this Regulation.
 4.1.5. Reference to Appendix 1 of the type-approval communication in section 5.5.3 of UN/ECE Regulation No 103 shall be understood as reference to the addendum to the EC type-approval certificate on vehicle OBD information (Appendix 5 to Annex I).
 4.2. For vehicles with positive-ignition engines, if the NMHC emissions measured during the demonstration test of a new original equipment catalytic converter, under paragraph 5.2.1 of UN/ECE Regulation No 103, are higher than the values measured during the type-approval of the vehicle, the difference shall be added to the OBD threshold limits. The OBD threshold limits are specified in point 2.3 of Annex XI of this Regulation.
 4.3. The revised OBD threshold limits will apply during the tests of OBD compatibility set out in paragraphs 5.5 to 5.5.5 of UN/ECE Regulation No 103. In particular, when the exceedance allowed in paragraph 1 of Appendix 1 to Annex 11 to UN/ECE Regulation No 83 is applied.
 4.4.  4.4.1.  4.4.1.1. The vehicle(s) indicated in Article 11(3), equipped with a replacement periodically regenerating system of the type for which approval is requested, shall be subject to the tests described in paragraph 3 of Annex 13 of UN/ECE Regulation No 83, in order to compare its performance with the same vehicle equipped with the original periodically regenerating system.
 4.4.1.2. Reference to the ‘Type I test’ and ‘Type I test cycle’ in paragraph 3. of Annex 13 of UN/ECE Regulation No 83 and the ‘test cycle’ in Section 5 of UN/ECE Regulation No 103 shall be understood as being the same Type I / Type 1 test and Type I / Type 1 test cycle as used for the original type approval of the vehicle.
 4.4.2.  4.4.2.1. The vehicle shall be fitted with a new original periodically regenerating system. The emissions performance of this system shall be determined following the test procedure set out in paragraph 3 of Annex 13 of UN/ECE Regulation No 83.
 4.4.2.1.1. Reference to the ‘Type I test’ and ‘Type I test cycle’ in paragraph 3. of Annex 13 of UN/ECE Regulation No 83 and the ‘test cycle’ in Section 5 of UN/ECE Regulation No 103 shall be understood as being the same Type I / Type 1 test and Type I / Type 1 test cycle as used for the original type approval of the vehicle.
 4.4.2.2. Upon request of the applicant for the approval of the replacement component, the approval authority shall make available on a non-discriminatory basis, the information referred to in points 3.2.12.2.1.11.1 and 3.2.12.2.6.4.1 of the information document contained in Appendix 3 to Annex I to this Regulation for each vehicle tested.
 4.4.3.  4.4.3.1. The original equipment periodically regenerating system of the test vehicle(s) shall be replaced by the replacement periodically regenerating system. The emissions performance of this system shall be determined following the test procedure set out in paragraph 3 Annex 13 of UN/ECE Regulation No 83.
 4.4.3.1.1. Reference to the ‘Type I test’ and ‘Type I test cycle’ in paragraph 3. of Annex 13 of UN/ECE Regulation No 83 and the ‘test cycle’ in Section 5 of UN/ECE Regulation No 103 shall be understood as being the same Type I / Type 1 test and Type I / Type 1 test cycle as used for the original type approval of the vehicle.
 4.4.3.2. To determine the D-factor of the replacement periodically regenerating system, any of the engine test bench methods referred to in paragraph 3 of Annex 13 of UN/ECE Regulation No 83 may be used.
 4.4.4. 
The requirements of paragraphs 5.2.3, 5.3, 5.4 and 5.5 of UN/ECE Regulation No 103 shall apply to replacement periodically regenerating systems. In these paragraphs the words ‘catalytic converter’ shall be understood to mean ‘periodically regenerating system’. In addition the exceptions made to these paragraphs in section 4.1 of this annex shall also apply to periodically regenerating systems.

5.  5.1. 

((a)) the vehicles (including year of manufacture) for which the replacement pollution control device is approved, including, where applicable, a marking to identify if the replacement pollution control device is suitable for fitting to a vehicle that is equipped with an on-board diagnostic (OBD) system;
((b)) installation instructions, where necessary.

The information shall be available in the product catalogue distributed to points of sale by the manufacturer of replacement pollution control devices.

6.  6.1. Measures to ensure the conformity of production shall be taken in accordance with the provisions laid down in Article 12 of Directive 2007/46/EC.
 6.2.  6.2.1. The checks referred to in point 2.2 of Annex X to Directive 2007/46/EC shall include compliance with the characteristics as defined under point 8 of Article 2 of this Regulation.
 6.2.2. For the application of Article 12(2) of Directive 2007/46/EC, the tests described in section 4.4.1 of this Annex and section 5.2 of UN/ECE Regulation No 103 (requirements regarding emissions) may be carried out. In this case, the holder of the approval may request, as an alternative, to use as a basis for comparison not the original equipment pollution control device, but the replacement pollution control device which was used during the type-approval tests (or another sample that has been proven to conform to the approved type). Emissions values measured with the sample under verification shall then on average not exceed by more than 15 % the mean values measured with the sample used for reference.

Appendix 1
Information document No … 
The following information, if applicable, must be supplied in triplicate and include a list of contents. Any drawings must be supplied in appropriate scale and sufficient detail on size A4 or on a folder of A4 format. Photographs, if any, must show sufficient detail.

If the systems, components or separate technical units have electronic controls, information concerning their performance must be supplied.
 0.  0.1. Make (trade name of manufacturer): …
 0.2. Type: …
 0.2.1. Commercial name(s), if available: …
 0.5. 
Name and address of authorised representative, if any: …
 0.7. In the case of components and separate technical units, location and method of affixing of the EC approval mark: …
 0.8. Address(es) of assembly plant(s): …
 1.  1.1. Make and type of the replacement pollution control device: …
 1.2. Drawings of the replacement pollution control device, identifying in particular all the characteristics referred to under point 8 of Article 2 of this Regulation: …
 1.3. Description of the vehicle type or types for which the replacement pollution control device is intended: …
 1.3.1. Number(s) and/or symbol(s) characterising the engine and vehicle type(s): …
 1.3.2. Is the replacement pollution control device intended to be compatible with OBD requirements (Yes/No)
 1.4. Description and drawings showing the position of the replacement pollution control device relative to the engine exhaust manifold(s): …

Appendix 2
MODEL EC TYPE-APPROVAL CERTIFICATE 
Communication concerning the:


— EC type-approval, …,
— extension of EC type-approval, …,
— refusal of EC type-approval, …,
— withdrawal of EC type-approval, …,

of a type of component/separate technical unit

with regard to Regulation (EC) No 715/2007, as implemented by Regulation (EU) 2017/1151.

Regulation (EC) No 715/2007 or Regulation (EU) 2017/1151 as last amended by …

EC type-approval number: …

Reason for extension: …
 SECTION I  0.1. Make (trade name of manufacturer): …
 0.2. Type: …
 0.3. Means of identification of type if marked on the component/separate technical unit: …
 0.3.1. Location of that marking: …
 0.5. Name and address of manufacturer: …
 0.7. In the case of components and separate technical units, location and method of affixing of the EC approval mark: …
 0.8. Name and address(es) of assembly plant(s): …
 0.9. Name and address of manufacturer’s representative (if any): …
 SECTION II  1. Additional information
 1.1. Make and type of the replacement pollution control device: …
 1.2. Vehicle type(s) for which the pollution control device type qualifies as replacement part: …
 1.3. Type(s) of vehicles) on which the replacement pollution control device has been tested: …
 1.3.1. Has the replacement pollution control device demonstrated compatibility with OBD requirements (yes/no): …
 2. Technical service responsible for carrying out the tests: …
 3. Date of test report: …
 4. Number of test report: …
 5. Remarks: …
 6. Place: …
 7. Date: …
 8. Signature: …

Attachments: Information package.

Appendix 3
Example of the EC type-approval marks 
The above approval mark affixed to a component of a replacement pollution control device shows that the type concerned has been approved in France (e 2), pursuant to this Regulation. The first two digits of the approval number (00) indicate that this part was approved according to this Regulation. The following four digits (1234) are those allocated by the approval authority to the replacement pollution control device as the base approval number.

ANNEX XIV
1.  1.1. This Annex lays down technical requirements for the accessibility of vehicle OBD and vehicle repair and maintenance information.

2.  2.1. 
Information on all parts of the vehicle, with which the vehicle, as identified by the vehicle identification number (VIN) and any additional criteria such as wheelbase, engine output, trim level or options, is equipped by the vehicle manufacturer and which can be replaced by spare parts offered by the vehicle manufacturer to its authorised repairers or dealers or third parties by means of reference to original equipment (OE) parts number, shall be made available in a database easily accessible to independent operators.

This database shall comprise the VIN, OE parts numbers, OE naming of the parts, validity attributes (valid-from and valid-to dates), fitting attributes and where applicable structuring characteristics.

The information on the database shall be regularly updated. The updates shall include in particular all modifications to individual vehicles after their production if this information is available to authorised dealers.
 2.2. 

((i)) data shall be exchanged ensuring confidentiality, integrity and protection against replay;
((ii)) the standard https//ssl-tls (RFC4346) shall be used;
((iii)) security certificates in accordance with ISO 20828 shall be used for mutual authentication of independent operators and manufacturers;
((iv)) the independent operator’s private key shall be protected by secure hardware.

The Forum on Access to Vehicle Information provided for by paragraph 9 of Article 13 will specify the parameters for fulfilling these requirements according to the state-of-the-art.

The independent operator shall be approved and authorised for this purpose on the basis of documents demonstrating that they pursue a legitimate business activity and have not been convicted of relevant criminal activity.
 2.3. Reprogramming of control units shall be conducted in accordance with either ISO 22900 or SAE J2534, regardless of the date of type approval. For the validation of the compatibility of the manufacturer-specific application and the vehicle communication interfaces (VCI) complying to ISO 22900 or SAE J2534, the manufacturer shall offer either a validation of independently developed VCIs or the information, and loan of any special hardware, required for a VCI manufacturer to conduct such validation himself. The conditions of Article 7(1) of Regulation (EC) No 715/2007 apply to fees for such validation or information and hardware.
 2.4. All emission-related fault codes shall be consistent with Appendix 1 to Annex XI.
 2.5. For access to any vehicle OBD and vehicle repair and maintenance information other than that relating to secure areas of the vehicle, registration requirements for use of the manufacturer’s web site by an independent operator shall require only such information as is necessary to confirm how payment for the information is to be made. For information concerning access to secure areas of the vehicle, the independent operator shall present a certificate in accordance with ISO 20828 to identify himself and the organisation to which he belongs and the manufacturer shall respond with his own certificate in accordance with ISO 20828 to confirm to the independent operator that he is accessing a legitimate site of the intended manufacturer. Both parties shall keep a log of any such transactions indicating the vehicles and changes made to them under this provision.
 2.6. In the event that vehicle OBD and vehicle repair and maintenance information available on a manufacturer’s website does not contain specific relevant information to permit the proper design and manufacture of alternative fuels retrofit systems, then any interested alternative fuels retrofit system manufacturer shall be able to access the information required in paragraphs 0, 2, and 3 of Appendix 3 to Annex Iby contacting the manufacturer directly with such a request. Contact details for that purpose shall be clearly indicated on the manufacturer’s website and the information shall be provided within 30 days. Such information need only be provided for alternative fuels retrofit systems that are subject to UN/ECE Regulation No 115 or for alternative fuels retrofit components that form part of systems subject to UN/ECE Regulation No 115, and need only be provided in response to a request that clearly specifies the exact specification of the vehicle model for which the information is required and that specifically confirms that the information is required for the development of alternative fuels retrofit systems or components subject to UN/ECE Regulation No 115.
 2.7. Manufacturers shall indicate in their repair information websites the type-approval number by model.
 2.8. Manufacturers shall establish fees for hourly, daily, monthly, annual and per-transaction access to their repair and maintenance information websites, which are reasonable and proportionate.

Appendix 1

ANNEX XV

ANNEX XVI
1. 
This Annex sets out the requirements for vehicles that rely on the use of a reagent for the after-treatment system in order to reduce emissions.

The requirements shall be those specified in Appendix 6 to UN/ECE Regulation No 83, with the following exception.

The reference to Annex 1 in paragraph 4.1. of Appendix 6 to UN/ECE Regulation No 83 shall be understood as reference to Appendix 3 to Annex I to this Regulation.

ANNEX XVII
1. 

(a) Points 3. to 3.1.1. shall be amended to read:
' 3.  3.1. Manufacturer of the propulsion energy converter(s): …
 3.1.1. Manufacturer's code (as marked on the propulsion energy converter or other means of identification): …
'
(b) Point 3.2.1.8. shall be amended to read:
' 3.2.1.8. Rated engine power (n): … kW at … min–1 (manufacturer's declared value)
'
(c) Point 3.2.2.2. shall be renumbered 3.2.2.1.1. and shall read as follows:
' 3.2.2.1.1. RON, unleaded: …
'
(d) Point 3.2.4.2.1. shall be amended to read:
' 3.2.4.2.1. System description (common rail/unit injectors/distribution pump etc.): …
'
(e) Point 3.2.4.2.3. shall be amended to read:
' 3.2.4.2.3. Injection/Delivery pump
'
(f) Point 3.2.4.2.4. shall be amended to read:
' 3.2.4.2.4. Engine speed limitation control
'
(g) Point 3.2.4.2.9.3. shall be amended to read:
' 3.2.4.2.9.3. Description of the system
'
(h) Points 3.2.4.2.9.3.6. to 3.2.4.2.9.3.8. shall be amended to read:
' 3.2.4.2.9.3.6. Make and type or working principle of water temperature sensor: …
 3.2.4.2.9.3.7. Make and type or working principle of air temperature sensor: …
 3.2.4.2.9.3.8. Make and type or working principle of air pressure sensor: …
'
(i) Point 3.2.4.3.4.3. shall be amended to read:
' 3.2.4.3.4.3. Make and type or working principle of air-flow sensor: …
'
(j) Points 3.2.4.3.4.9. to 3.2.4.3.4.11. shall be amended to read:
' 3.2.4.3.4.9. Make and type or working principle of water temperature sensor: …
 3.2.4.3.4.10. Make and type or working principle of air temperature sensor: …
 3.2.4.3.4.11. Make and type or working principle of air pressure sensor: …
'
(k) Point 3.2.4.3.5. shall be amended to read:
' 3.2.4.3.5. Injectors
'
(l) Points 3.2.12.2. to 3.2.12.2.1. shall be amended to read:
' 3.2.12.2. Pollution control devices (if not covered by another heading)
 3.2.12.2.1. Catalytic converter
'
(m) Points 3.2.12.2.1.11. to 3.2.12.2.1.11.10 shall be deleted
(n) Points 3.2.12.2.2. to 3.2.12.2.2.5. shall be deleted and replaced with the following:
' 3.2.12.2.2. Sensors
 3.2.12.2.2.1. Oxygen sensor: yes/no (1)
 3.2.12.2.2.1.1. Make: …
 3.2.12.2.2.1.2. Location: …
 3.2.12.2.2.1.3. Control range: …
 3.2.12.2.2.1.4. Type or working principle: …
 3.2.12.2.2.1.5. Identifying part number: …
'
(o) Points 3.2.12.2.4.1. to 3.2.12.2.4.2. shall be amended to read:
' 3.2.12.2.4.1. Characteristics (make, type, flow, high pressure / low pressure / combined pressure, etc.): …
 3.2.12.2.4.2. Water-cooled system (to be specified for each EGR system e.g. low pressure / high pressure / combined pressure: yes/no (1)
'
(p) Points 3.2.12.2.5. to 3.2.12.2.5.6. shall be amended to read:
' 3.2.12.2.5. Evaporative emissions control system (petrol and ethanol engines only): yes/no (1)
 3.2.12.2.5.1. Detailed description of the devices: …
 3.2.12.2.5.2. Drawing of the evaporative emissions control system: …
 3.2.12.2.5.3. Drawing of the carbon canister: …
 3.2.12.2.5.4. Mass of dry charcoal: … g
 3.2.12.2.5.5. Schematic drawing of the fuel tank with indication of capacity and material (petrol and ethanol engines only): …
 3.2.12.2.5.6. Description and schematic of the heat shield between tank and exhaust system: …
'
(q) Points 3.2.12.2.6.4. to 3.2.12.2.6.4.4. shall be deleted
(r) Points 3.2.12.2.6.5. and 3.2.12.2.6.6. shall be renumbered to read:
' 3.2.12.2.6.4. Make of particulate trap: …
 3.2.12.2.6.5. Identifying part number: …
'
(s) Points 3.2.12.2.8. shall be amended to read:
' 3.2.12.2.8. Other system: …
'
(t) New points 3.2.12.2.10. to 3.2.12.2.11.8. shall be added as follows:
' 3.2.12.2.10. Periodically regenerating system: (provide the information below for each separate unit)
 3.2.12.2.10.1. Method or system of regeneration, description and/or drawing: …
 3.2.12.2.10.2. The number of Type 1 operating cycles, or equivalent engine test bench cycles, between two cycles where regenerative phases occur under the conditions equivalent to Type 1 test (Distance “D” in Figure A6.App1/1 in Appendix 1 to Sub-Annex 6 of Annex XXI to Regulation (EU) 2017/1151 or figure A13/1 in Annex 13 to UN/ECE Regulation 83 (as applicable)): …
 3.2.12.2.10.2.1. Applicable Type 1 cycle: (indicate the applicable procedure: Annex XXI, Sub-Annex 4 or UN/ECE Regulation 83): …
 3.2.12.2.10.3. Description of method employed to determine the number of cycles between two cycles where regenerative phases occur: …
 3.2.12.2.10.4. Parameters to determine the level of loading required before regeneration occurs (i.e. temperature, pressure etc.): …
 3.2.12.2.10.5. Description of method used to load system in the test procedure described in paragraph 3.1., Annex 13 to UN/ECE Regulation 83: …
 3.2.12.2.11. Catalytic converter systems using consumable reagents (provide the information below for each separate unit) yes/no (1)
 3.2.12.2.11.1. Type and concentration of reagent needed: …
 3.2.12.2.11.2. Normal operational temperature range of reagent: …
 3.2.12.2.11.3. International standard: …
 3.2.12.2.11.4. Frequency of reagent refill: continuous/maintenance (where appropriate):
 3.2.12.2.11.5. Reagent indicator: (description and location)
 3.2.12.2.11.6. Reagent tank
 3.2.12.2.11.6.1. Capacity: …
 3.2.12.2.11.6.2. Heating system: yes/no (1)
 3.2.12.2.11.6.2.1. Description or drawing
 3.2.12.2.11.7. Reagent control unit: yes/no (1)
 3.2.12.2.11.7.1. Make: …
 3.2.12.2.11.7.2. Type: …
 3.2.12.2.11.8. Reagent injector (make, type and location): …
'
(u) Point 3.2.15.1. shall be amended to read:
' 3.2.15.1. Type-approval number according to Regulation (EC) No 661/2009 (OJ L 200, 31.7.2009, p. 1)
'
(v) Point 3.2.16.1. shall be amended to read:
' 3.2.16.1. Type-approval number according to Regulation (EC) No 661/2009 (OJ L 200, 31.7.2009, p. 1)
'
(w) Point 3.3. shall be amended to read:
' 3.3. Electric machine
'
(x) Point 3.3.2. shall be amended to read:
' 3.3.2. REESS
'
(y) Point 3.4. shall be amended to read:
' 3.4. Combinations of propulsion energy converters
'
(z) Point 3.4.4. shall be amended to read:
' 3.4.4. Description of the energy storage device: (REESS, capacitor, flywheel/generator)
'
(aa) Point 3.4.4.5. shall be amended to read:
' 3.4.4.5. Energy: … (for REESS: voltage and capacity Ah in 2 h, for capacitor: J, …)
'
(bb) Point 3.4.5. shall be amended to read:
' 3.4.5. Electric machine (describe each type of electric machine separately)
'
(cc) Point 3.5. shall be amended to read:
' 3.5. Manufacturer’s declared values for determination of CO2 emissions/fuel consumption/electric consumption/electric range and details of eco-innovations (where applicable)(o)
'
(dd) Point 4.4. shall be amended to read:
' 4.4. Clutch(es)
'
(ee) Point 4.6. shall be amended to read:
' 4.6. 
Gear Internal gearbox ratios (ratios of engine to gearbox output shaft revolutions) Final drive ratio(s) (ratio of gearbox output shaft to driven wheel revolutions) Total gear ratios
Maximum for CVT   
1   
2   
3   
…   
Minimum for CVT   '
(ff) Point 6.6. to 6.6.3. shall be replaced as follows:
' 6.6. Tyres and wheels
 6.6.1. Tyre/wheel combination(s)
 6.6.1.1. Axles
 6.6.1.1.1. Axle 1: …
 6.6.1.1.1.1. Tyre size designation
 6.6.1.1.2. Axle 2: …
 6.6.1.1.2.1. 
etc.
 6.6.2. Upper and lower limits of rolling radii
 6.6.2.1. Axle 1: …
 6.6.2.2. 
etc.
 6.6.3. Tyre pressure(s) as recommended by the vehicle manufacturer: … kPa
'
(gg) Point 9.1. shall be amended to read:
' 9.1. Type of bodywork using the codes defined in Part C of Annex II of Directive 2007/46/EC: …
'

2. 
'
ZD Euro 6c Euro 6-2 M, N1 class I PI, CI   31.8.2018
ZE Euro 6c Euro 6-2 N1 class II PI, CI   31.8.2019
ZF Euro 6c Euro 6-2 N1 class III, N2 PI, CI   31.8.2019
ZG Euro 6d-TEMP Euro 6-2 M, N1 class I PI, CI   31.8.2018
ZH Euro 6d-TEMP Euro 6-2 N1 class II PI, CI   31.8.2019
ZI Euro 6d-TEMP Euro 6-2 N1 class III, N2 PI, CI   31.8.2019
ZJ Euro 6d Euro 6-2 M, N1 class I PI, CI   31.8.2018
ZK Euro 6d Euro 6-2 N1 class II PI, CI   31.8.2019
ZL Euro 6d Euro 6-2 N1 class III, N2 PI, CI   31.8.2019
ZX n.a. n.a. All vehicles Battery full electric 1.9.2009 1.1.2011 31.8.2019
ZY n.a. n.a. All vehicles Battery full electric 1.9.2009 1.1.2011 31.8.2019
ZZ n.a. n.a. All vehicles using certificates according to point 2.1.1 of Annex I PI, CI 1.9.2009 1.1.2011 31.8.2019'

ANNEX XVIII (1) 

(a) Point 2.6.1. shall be amended to read:
' 2.6.1. 

((a)) minimum and maximum for each variant: …
((b)) mass of each version (a matrix must be provided): …
'
(b) Points 3. to 3.1.1. shall be amended to read:
' 3.  3.1. Manufacturer of the propulsion energy converter(s): …
 3.1.1. Manufacturer's code (as marked on the propulsion energy converter or other means of identification): …
'
(c) Point 3.2.1.8. shall be amended to read:
' 3.2.1.8. Rated engine power (n): … kW at … min–1 (manufacturer's declared value)
'
(d) A new point 3.2.2.1.1. shall be added as follows:
' 3.2.2.1.1. RON, unleaded: …
'
(e) Point 3.2.4.2.1. shall be amended to read:
' 3.2.4.2.1. System description (common rail/unit injectors/distribution pump etc.): …
'
(f) Point 3.2.4.2.3. shall be amended to read:
' 3.2.4.2.3. Injection/Delivery pump
'
(g) Point 3.2.4.2.4. shall be amended to read:
' 3.2.4.2.4. Engine speed limitation control
'
(h) Point 3.2.4.2.9.3. shall be amended to read:
' 3.2.4.2.9.3. Description of the system
'
(i) A new point 3.2.4.2.9.3.1.1. shall be added as follows:
' 3.2.4.2.9.3.1.1. Software version of the ECU: …
'
(j) Points 3.2.4.2.9.3.6. to 3.2.4.2.9.3.8. shall be amended to read:
' 3.2.4.2.9.3.6. Make and type or working principle of water temperature sensor: …
 3.2.4.2.9.3.7. Make and type or working principle of air temperature sensor: …
 3.2.4.2.9.3.8. Make and type or working principle of air pressure sensor: …
'
(k) A new point 3.2.4.3.4.1.1. shall be added as follows:
' 3.2.4.3.4.1.1. Software version of the ECU: …
'
(l) Point 3.2.4.3.4.3. shall be amended to read:
' 3.2.4.3.4.3. Make and type or working principle of air-flow sensor: …
'
(m) Points 3.2.4.3.4.9. to 3.2.4.3.4.11. shall be amended to read:
' 3.2.4.3.4.9. Make and type or working principle of water temperature sensor: …
 3.2.4.3.4.10. Make and type or working principle of air temperature sensor: …
 3.2.4.3.4.11. Make and type or working principle of air pressure sensor: …
'
(n) Point 3.2.4.3.5. shall be amended to read:
' 3.2.4.3.5. Injectors
'
(o) New points 3.2.4.4.2. and 3.2.4.4.3. shall be added as follows:
' 3.2.4.4.2. Make(s): ….
 3.2.4.4.3. Type(s): …
'
(p) Points 3.2.12.2. to 3.2.12.2.1. shall be amended to read:
' 3.2.12.2. Pollution control devices (if not covered by another heading)
 3.2.12.2.1. Catalytic converter
'
(q) Points 3.2.12.2.1.11. to 3.2.12.2.1.11.10 shall be deleted and replaced with the following new point:
' 3.2.12.2.1.11. Normal operating temperature range: … °C
'
(r) Points 3.2.12.2.2. to 3.2.12.2.2.5. shall be deleted and replaced with the following:
' 3.2.12.2.2. Sensors
 3.2.12.2.2.1. Oxygen sensor: yes/no (1)
 3.2.12.2.2.1.1. Make: …
 3.2.12.2.2.1.2. Location: …
 3.2.12.2.2.1.3. Control range: ….
 3.2.12.2.2.1.4. Type or working principle: …
 3.2.12.2.2.1.5. Identifying part number: …
 3.2.12.2.2.2. NOx sensor: yes/no (1)
 3.2.12.2.2.2.1. Make: …
 3.2.12.2.2.2.2. Type: …
 3.2.12.2.2.2.3. Location: …
 3.2.12.2.2.3. Particulate sensor: yes/no (1)
 3.2.12.2.2.3.1. Make: …
 3.2.12.2.2.3.2. Type: …
 3.2.12.2.2.3.3. Location: …
'
(s) Points 3.2.12.2.4.1. to 3.2.12.2.4.2. shall be amended to read:
' 3.2.12.2.4.1. Characteristics (make, type, flow, high pressure / low pressure / combined pressure, etc.): …
 3.2.12.2.4.2. Water-cooled system (to be specified for each EGR system e.g. low pressure / high pressure / combined pressure: yes/no (1)
'
(t) Points 3.2.12.2.5. to 3.2.12.2.5.6. shall be amended to read:
' 3.2.12.2.5. Evaporative emissions control system (petrol and ethanol engines only): yes/no (1)
 3.2.12.2.5.1. Detailed description of the devices: ….
 3.2.12.2.5.2. Drawing of the evaporative control system: …
 3.2.12.2.5.3. Drawing of the carbon canister: …
 3.2.12.2.5.4. Mass of dry charcoal: … g
 3.2.12.2.5.5. Schematic drawing of the fuel tank with indication of capacity and material (petrol and ethanol engines only): …
 3.2.12.2.5.6. Description and schematic of the heat shield between tank and exhaust system: …
'
(u) Points 3.2.12.2.6.4. to 3.2.12.2.6.4.4. shall be deleted
(v) Points 3.2.12.2.6.5. and 3.2.12.2.6.6. shall be renumbered to read:
' 3.2.12.2.6.4. Make of particulate trap: …
 3.2.12.2.6.5. Identifying part number: …
'
(w) Points 3.2.12.2.7. to 3.2.12.2.7.0.6. shall be amended to read:
' 3.2.12.2.7. On-board-diagnostic (OBD) system: yes/no (1): …
 3.2.12.2.7.0.1. (Euro VI only) Number of OBD engine families within the engine family
 3.2.12.2.7.0.2. (Euro VI only) List of the OBD engine families (when applicable)
 3.2.12.2.7.0.3. (Euro VI only) Number of the OBD engine family the parent engine / the engine member belongs to: …
 3.2.12.2.7.0.4. (Euro VI only) Manufacturer references of the OBD-Documentation required by Article 5(4)(c) and Article 9(4) of Regulation (EU) No 582/2011 and specified in Annex X to that Regulation for the purpose of approving the OBD system
 3.2.12.2.7.0.5. (Euro VI only) When appropriate, manufacturer reference of the Documentation for installing in a vehicle an OBD equipped engine system
 3.2.12.2.7.0.6. (Euro VI only) When appropriate, manufacturer reference of the documentation package related to the installation on the vehicle of the OBD system of an approved engine
'
(x) In point 3.2.12.2.7.6.4.1. the heading ‘Low-duty vehicles’ shall be replaced with ‘Light-duty vehicles’
(y) Points 3.2.12.2.8. shall be amended to read:
' 3.2.12.2.8. Other system: …
'
(z) New points 3.2.12.2.8.2.3. to 3.2.12.2.8.2.5. are added as follows:
' 3.2.12.2.8.2.3. Type of inducement system: no engine restart after countdown/no start after refuelling/fuel-lockout/performance restriction
 3.2.12.2.8.2.4. Description of the inducement system
 3.2.12.2.8.2.5. Equivalent to the average driving range of the vehicle with a complete tank of fuel: … km
'
(aa) A new point 3.2.12.2.8.4. shall be added as follows:
' 3.2.12.2.8.4. (Euro VI only) List of the OBD engine families (when applicable): …
'
(bb) New points 3.2.12.2.10. to 3.2.12.2.11.8. shall be added as follows:
' 3.2.12.2.10. Periodically regenerating system: (provide the information below for each separate unit)
 3.2.12.2.10.1. Method or system of regeneration, description and/or drawing: ….
 3.2.12.2.10.2. The number of Type 1 operating cycles, or equivalent engine test bench cycles, between two cycles where regenerative phases occur under the conditions equivalent to Type 1 test (Distance “D” in Figure A6.App1/1 in Appendix 1 to Sub-Annex 6 of Annex XXI to Regulation (EU) 2017/1151 or figure A13/1 in Annex 13 to UN/ECE Regulation 83 (as applicable)): …
 3.2.12.2.10.2.1. Applicable Type 1 cycle (indicate the applicable procedure: Annex XXI, Sub-Annex 4 or UN/ECE Regulation 83): …
 3.2.12.2.10.3. Description of method employed to determine the number of cycles between two cycles where regenerative phases occur: …
 3.2.12.2.10.4. Parameters to determine the level of loading required before regeneration occurs (i.e. temperature, pressure etc.): …
 3.2.12.2.10.5. Description of method used to load system in the test procedure described in paragraph 3.1., Annex 13 to UN/ECE Regulation 83: ….
 3.2.12.2.11. Catalytic converter systems using consumable reagents (provide the information below for each separate unit) yes/no (1)
 3.2.12.2.11.1. Type and concentration of reagent needed: …
 3.2.12.2.11.2. Normal operational temperature range of reagent: …
 3.2.12.2.11.3. International standard: …
 3.2.12.2.11.4. Frequency of reagent refill: continuous/maintenance (where appropriate):
 3.2.12.2.11.5. Reagent indicator (description and location): …
 3.2.12.2.11.6. Reagent tank
 3.2.12.2.11.6.1. Capacity: …
 3.2.12.2.11.6.2. Heating system: yes/no
 3.2.12.2.11.6.2.1. Description or drawing: …
 3.2.12.2.11.7. Reagent control unit: yes/no (1)
 3.2.12.2.11.7.1. Make: …
 3.2.12.2.11.7.2. Type: …
 3.2.12.2.11.8. Reagent injector (make type and location): …
'
(cc) Point 3.2.15.1. shall be amended to read:
' 3.2.15.1. Type-approval number according to Regulation (EC) No 661/2009 (OJ L 200, 31.7.2009, p. 1): …
'
(dd) Point 3.2.16.1. shall be amended to read:
' 3.2.16.1. Type-approval number according to Regulation (EC) No 661/2009 (OJ L 200, 31.7.2009, p. 1): …
'
(ee) New points 3.2.20. to 3.2.20.2.4. shall be added as follows:
' 3.2.20. Heat storage information
 3.2.20.1. Active heat storage device: yes/no
 3.2.20.1.1. Enthalpy: … (J)
 3.2.20.2. Insulation materials
 3.2.20.2.1. Insulation material: …
 3.2.20.2.2. Insulation volume: …
 3.2.20.2.3. Insulation weight: …
 3.2.20.2.4. Insulation location: …
'
(ff) Point 3.3. shall be amended to read:
' 3.3. Electric machine
'
(gg) Point 3.3.2. shall be amended to read:
' 3.3.2. REESS
'
(hh) Point 3.4. shall be amended to read:
' 3.4. Combinations of propulsion energy converters
'
(ii) Point 3.4.4. shall be amended to read:
' 3.4.4. Description of the energy storage device: (REESS, capacitor, flywheel/generator)
'
(jj) Point 3.4.4.5. shall be amended to read:
' 3.4.4.5. Energy: … (for REESS: voltage and capacity Ah in 2 h, for capacitor: J, …)
'
(kk) Point 3.4.5. shall be amended to read:
' 3.4.5. Electric machine (describe each type of electric machine separately)
'
(ll) Point 3.5. shall be amended to read:
' 3.5. Manufacturer's declared values for determination of CO2 emissions/fuel consumption/electric consumption/electric range and details of eco-innovations (where applicable)(°)
'
(mm) New points 3.5.7. to 3.5.8.3. are added as follows:
' 3.5.7. Manufacturer's declared values
 3.5.7.1. Test vehicle parameters
 3.5.7.1.1 Vehicle high
 3.5.7.1.1.1. Cycle Energy Demand: … J
 3.5.7.1.1.2. Road load coefficients
 3.5.7.1.1.2.1. f0: … N
 3.5.7.1.1.2.2. f1: …N/(km/h)
 3.5.7.1.1.2.3. f2: …N/(km/h)2
 3.5.7.1.2. Vehicle Low (if applicable)
 3.5.7.1.2.1. Cycle Energy Demand: … J
 3.5.7.1.2.2. Road load coefficients
 3.5.7.1.2.2.1. f0: … N
 3.5.7.1.2.2.2. f1: …N/(km/h)
 3.5.7.1.2.2.3. f2: …N/(km/h)2
 3.5.7.1.3. Vehicle M (if applicable)
 3.5.7.1.3.1. Cycle Energy Demand: … J
 3.5.7.1.3.2. Road load coefficients
 3.5.7.1.3.2.1. f0: … N
 3.5.7.1.3.2.2. f1: … N/(km/h)
 3.5.7.1.3.2.3. f2: … N/(km/h)2
 3.5.7.2. Combined CO2 mass emissions
 3.5.7.2.1. CO2 mass emission for ICE
 3.5.7.2.1.1. Vehicle High: … g/km
 3.5.7.2.1.2. Vehicle low (if applicable): … g/km
 3.5.7.2.2. Charge Sustaining CO2 mass emission for OVC-HEVs and NOVC-HEVs
 3.5.7.2.2.1. Vehicle high: … g/km
 3.5.7.2.2.2. Vehicle low (if applicable): … g/km
 3.5.7.2.2.3. Vehicle M (if applicable): … g/km
 3.5.7.2.3. Charge Depleting CO2 mass emission for OVC-HEVs
 3.5.7.2.3.1. Vehicle high: … g/km
 3.5.7.2.3.2. Vehicle low (if applicable): … g/km
 3.5.7.2.3.3. Vehicle M (if applicable): … g/km
 3.5.7.3. Electric range for electrified vehicles
 3.5.7.3.1. Pure Electric Range (PER) for PEVs
 3.5.7.3.1.1. Vehicle high: … km
 3.5.7.3.1.2. Vehicle low (if applicable): … km
 3.5.7.3.2. All Electric Range AER for OVC-HEVs
 3.5.7.3.2.1. Vehicle high: … km
 3.5.7.3.2.2. Vehicle low (if applicable): … km
 3.5.7.3.2.3. Vehicle M (if applicable): … km
 3.5.7.4. Charge Sustaining fuel consumption (FCCS) for FCHVs
 3.5.7.4.1. Vehicle high: … kg/100 km
 3.5.7.4.2. Vehicle low (if applicable): … kg/100 km
 3.5.7.4.3. Vehicle M (if applicable): … kg/100 km
 3.5.7.5. Electric energy consumption for electrified vehicles
 3.5.7.5.1. Combined electric energy consumption (ECWLTC) for Pure electric vehicles
 3.5.7.5.1.1. Vehicle high: … Wh/km
 3.5.7.5.1.2. Vehicle low (if applicable): … Wh/km
 3.5.7.5.2. Utility factor weighted charge-depleting electric consumption ECAC,CD (combined)
 3.5.7.5.2.1. Vehicle high: … Wh/km
 3.5.7.5.2.2. Vehicle low (if applicable): … Wh/km
 3.5.7.5.2.3. Vehicle M (if applicable): … Wh/km
 3.5.8. Vehicle fitted with an eco-innovation within the meaning of Article 12 of Regulation (EC) No 443/2009 for M1 vehicles or Article 12 of Regulation (EU) No 510/2011 for N1 vehicles: yes/no (1)
 3.5.8.1. Type/Variant/Version of the baseline vehicle as referred to in Article 5 of Regulation (EU) No 725/2011 for M1 vehicles or Article 5 of Regulation (EU) No 427/2014 for N1 vehicles (if applicable): …
 3.5.8.2. Existence of interactions between different eco-innovations: yes/no (1)
 3.5.8.3. 
Decision approving the eco-innovation (w2) Code of the eco-innovation (w3) 1. CO2 emissions of the baseline vehicle (g/km) 2. CO2 emissions of the eco-innovation vehicle (g/km) 3. CO2 emissions of the baseline vehicle under type 1 test-cycle (w4) 4. CO2 emissions of the eco-innovation vehicle under type 1 test-cycle 5. Usage factor (UF), i.e. temporal share of technology usage in normal operation conditions CO2 emissions savings ((1 – 2) – (3 – 4))*5
xxxx/201x       
       
       
Total CO2 emissions saving (g/km)(w5) '
(nn) Point 4.4. shall be amended to read:
' 4.4. Clutch(es): …
'
(oo) New points 4.5.1.1. to 4.5.1.5. shall be added as follows:
' 4.5.1.1. Predominant mode: yes/no (1)
 4.5.1.2. Best mode (if no predominant mode): …
 4.5.1.3. Worst mode (if no predominant mode): …
 4.5.1.4. Torque rating: …
 4.5.1.5. Number of clutches: …
'
(pp) Point 4.6. shall be amended to read:
' 4.6. Gear ratios

Gear Internal gearbox ratios (ratios of engine to gearbox output shaft revolutions) Final drive ratio(s) (ratio of gearbox output shaft to driven wheel revolutions) Total gear ratios
Maximum for CVT   
1   
2   
3   
…   
Minimum for CVTReverse   '
(qq) Point 6.6. to 6.6.5. shall be replaced as follows:
' 6.6. Tyres and wheels
 6.6.1. Tyre/wheel combination(s)
 6.6.1.1. Axles
 6.6.1.1.1. Axle 1: …
 6.6.1.1.1.1. Tyre size designation: …
 6.6.1.1.1.2. Load-capacity index: …
 6.6.1.1.1.3. Speed category symbol (r)
 6.6.1.1.1.4. Wheel rim size(s): …
 6.6.1.1.1.5. Wheel off-set(s): …
 6.6.1.1.2. Axle 2: …
 6.6.1.1.2.1. Tyre size designation: …
 6.6.1.1.2.2. Load-capacity index: …
 6.6.1.1.2.3. Speed category symbol: …
 6.6.1.1.2.4. Wheel rim size(s): …
 6.6.1.1.2.5. 
etc.
 6.6.1.2. Spare wheel, if any: …
 6.6.2. Upper and lower limits of rolling radii
 6.6.2.1. Axle 1: … mm
 6.6.2.2. Axle 2: … mm
 6.6.2.3. Axle 3: …mm
 6.6.2.4. 
etc.
 6.6.3. Tyre pressure(s) as recommended by the vehicle manufacturer: … kPa
 6.6.4. Chain/tyre/wheel combination on the front and/or rear axle that is suitable for the type of vehicle, as recommended by the manufacturer: …
 6.6.5. Brief description of temporary use spare unit (if any): …
'
(rr) Point 9.1. shall be amended to read:
' 9.1. Type of bodywork using the codes defined in Part C of Annex II of Directive 2007/46/EC: …
'
(ss) Point 9.9.2.1. shall be amended to read:
' 9.9.2.1. Type and description of the device: …
'
 (2) 

((a)) At the end of the two points 1.3.1 and 3.3.1 of part B of Annex II defining the criteria for ‘vehicle versions’ for M1 and N1 vehicles each, the following text should be added:
'As an alternative to the criteria (h), (i) and (j), the vehicles grouped into a version shall have all tests performed for the calculation of their CO2 emissions, electric energy consumption and fuel consumptions according to the provisions of sub-Annex 6 to Annex XXI of Regulation (EU) 2017/1151 in common.'
((b)) The following text shall be added at the end of point 3.3.1 of part B of Annex II
' (k) the existence of a unique set of innovative technologies, as specified in Article 12 of Regulation (EU) No 510/2011.
'
 (3) 

((a)) Points 3. to 3.1.1. shall be amended to read:
' 3.  3.1. Manufacturer of the propulsion energy converter(s): …
 3.1.1. Manufacturer's code (as marked on the propulsion energy converter or other means of identification): …
'
((b)) Point 3.2.1.8. shall be amended to read:
' 3.2.1.8. Rated engine power (n): … kW at … min–1 (manufacturer's declared value)
'
((c)) Points 3.2.12.2. to 3.2.12.2.1. shall be amended to read:
' 3.2.12.2. Pollution control devices (if not covered by another heading)
 3.2.12.2.1. Catalytic converter
'
((d)) Point 3.2.12.2.1.11. shall be deleted
((e)) Points 3.2.12.2.1.11.6. and 3.2.12.2.1.11.7. shall be deleted
((f)) Point 3.2.12.2.2. shall be deleted and replaced with the following new point:
' 3.2.12.2.2.1. Oxygen sensor: yes/no (1)
'
((g)) Point 3.2.12.2.5. shall be amended to read:
' 3.2.12.2.5. Evaporative emissions control system (petrol and ethanol engines only): yes/no (1)
'
((h)) Point 3.2.12.2.8. shall be amended to read:
' 3.2.12.2.8. Other system
'
((i)) New points 3.2.12.2.10. to 3.2.12.2.10.1. shall be added as follows:
' 3.2.12.2.10. Periodically regenerating system: (provide the information below for each separate unit)
 3.2.12.2.10.1. Method or system of regeneration, description and/or drawing: ….
'
((j)) A new point 3.2.12.2.11.1. shall be added as follows:
' 3.2.12.2.11.1. Type and concentration of reagent needed: …
'
((k)) Point 3.3. shall be amended to read:
' 3.3. Electric machine
'
((l)) Point 3.3.2. shall be amended to read:
' 3.3.2. REESS
'
((m)) Point 3.4. shall be amended to read:
' 3.4. Combinations of propulsion energy converters
'
((n)) Points 3.5.4 to 3.5.5.6. shall be deleted.
((o)) Point 4.6. shall be amended to read:
' 4.6. 
Gear Internal gearbox ratios (ratios of engine to gearbox output shaft revolutions) Final drive ratio(s) (ratio of gearbox output shaft to driven wheel revolutions) Total gear ratios
Maximum for CVT   
1   
2   
3   
…   
Minimum for CVTReverse   '
((p)) Point 6.6.1.shall be amended to read:
' 6.6.1. Tyre/wheel combination(s)
'
((q)) Point 9.1. shall be amended to read:
' 9.1. Type of bodywork using the codes defined in Part C of Annex II of Directive 2007/46/EC: …
'
 (4) 
 ‘ANNEX VIII 
(To be completed by the type-approval authority and attached to the vehicle EC type-approval certificate)

In each case, the information must make clear to which variant and version it is applicable. One version may not have more than one result. However, a combination of several results per version indicating the worst case is permissible. In the latter case, a note shall state that for items marked (*) only worst case results are given.
 1. 
Number of the base regulatory act and latest amending regulatory act applicable to the approval. In case of a regulatory act with two or more implementation stages, indicate also the implementation stage: ….


Variant/Version: … … …
Moving (dB(A)/E): … … …
Stationary (dB(A)/E): … … …
at (min– 1): … … …
 2.  2.1. 
Indicate the latest amending regulatory act applicable to the approval. In case the regulatory act has two or more implementation stages, indicate also the implementation stage: …

Fuel(s) … (diesel, petrol, LPG, NG, Bi-fuel: petrol/NG, LPG, NG/biomethane, Flex-fuel: petrol/ethanol…)
 2.1.1. 

Variant/Version: … … …
CO (mg/km) … … …
THC (mg/km) … … …
NMHC (mg/km) … … …
NOx (mg/km) … … …
THC + NOx (mg/km) … … …
Mass of particulate matter (PM) (mg/km) … … …
Number of particles (PN) (#/km) (1) … … …


ATCT Family Interpolation family Road Load Matrix family
… … …
… … …


ATCT Family FCF
… …
… …
 2.1.2. 
Type 2, low idle test:


Variant/Version: … … …
CO (% vol.) … … …
Engine speed (min–1) … … …
Engine oil temperature (°C) … … …

Type 2, high idle test:


Variant/Version: … … …
CO (% vol.) … … …
Lambda Value … … …
Engine speed (min–1) … … …
Engine oil temperature (°C) … … …
 2.1.3. Type 3 test (emissions of crankcase gases): …
 2.1.4. Type 4 test (evaporative emissions): … g/test
 2.1.5. Type 5 test (durability of anti-pollution control devices):

— Ageing distance covered (km)(e.g. 160 000 km): …
— Deterioration factor DF: calculated/fixed
— Values:
Variant/Version: … … …
CO … … …
THC … … …
NMHC … … …
NOx … … …
THC + NOx … … …
Mass of particulate matter (PM) … … …
Number of particles (PN) (1) … … …
 2.1.6. Type 6 test (average emissions at low ambient temperatures):

Variant/Version: … … …
CO (g/km) … … …
THC (g/km) … … …
 2.1.7. OBD: yes/no
 2.2. 
Indicate the latest amending regulatory act applicable to the approval. In case the regulatory act has two or more implementation stages, indicate also the implementation stage: …

Fuel(s) … (diesel, petrol, LPG, NG, ethanol …)
 2.2.1. 

Variant/Version: … … …
CO (mg/kWh) … … …
THC (mg/kWh) … … …
NOx (mg/kWh) … … …
NH3 (ppm) (1) … … …
PM mass (mg/kWh) … … …
PM number (#/kWh) (1) … … …
 2.2.2. 

Variant/Version: … … …
Smoke value: … m–1 … … …
 2.2.3. 

Variant/Version: … … …
CO (mg/kWh) … … …
THC (mg/kWh) … … …
NMHC (mg/kWh) (1) … … …
CH4 (mg/kWh) (1) … … …
NOx (mg/kWh) … … …
NH3 (ppm) (1) … … …
PM mass (mg/kWh) … … …
PM number (#/kWh) (1) … … …
 2.2.4. 

Variant/Version: … … …
CO (% vol.) … … …
Lambda Value (1) … … …
Engine speed (min–1) … … …
Engine oil temperature (K) … … …
 2.3. 
Indicate the latest amending regulatory act applicable to the approval. In case the regulatory act has two or more implementation stages, indicate also the implementation stage: …
 2.3.1. 

Variant/Version: … … …
Corrected value of the absorption coefficient (m–1) … … …
Normal engine idling speed … … …
Maximum engine speed … … …
Oil temperature (min./max.) … … …
 3. 
Number of the base regulatory act and the latest amending regulatory act applicable to the approval: …
 3.1. 

Variant/Version: … … …
CO2 mass emission (urban conditions) (g/km) … … …
CO2 mass emission (extra-urban conditions) (g/km) … … …
CO2 mass emission (combined) (g/km) … … …
Fuel consumption (urban conditions) (l/100 km) … … …
Fuel consumption (extra-urban conditions) (l/100 km) … … …
Fuel consumption (combined) (l/100 km) … … …





Interpolation family identifier Variant/versions
… …
… …
… …



Road Load Matrix family identifier Variant/versions
… …
… …
… …



Results: Interpolation family identifier Road Load Matrix family identifier
VH VM (if applicable) VL (if applicable) V representative
CO2 mass emission LOW phase (g/km) … … … 
CO2 mass emission MID phase (g/km) … … … 
CO2 mass emission HIGH phase (g/km) … … … 
CO2 mass emission EXTRA-HIGH phase (g/km) … … … 
CO2 mass emission (combined) (g/km) … … … 
Fuel consumption LOW phase (l/100 km m3/100 km kg/100 km) … … … 
Fuel consumption MID phase (l/100 km m3/100 km kg/100 km) … … … 
Fuel consumption HIGH phase (l/100 km m3/100 km kg/100 km) … … … 
Fuel consumption EXTRA-HIGH phase (l/100 km m3/100 km kg/100 km) … … … 
Fuel consumption (combined) (l/100 km m3/100 km kg/100 km) … … … 
f0 … … … 
f1 … … … 
f2 … … … 
RR … … … 
Delta Cd*A (for VL if applicable compared to VH) … … … 
Test Mass … … … 

Repeat for each interpolation or road load matrix family.
 3.2. 

Variant/Version: … … …
CO2 mass emission (Condition A, combined) (g/km) … … …
CO2 mass emission (Condition B, combined) (g/km) … … …
CO2 mass emission (weighted, combined) (g/km) … … …
Fuel consumption (Condition A, combined) (l/100 km) (g) … … …
Fuel consumption (Condition B, combined) (l/100 km) (g) … … …
Fuel consumption (weighted, combined) (l/100 km) (g) … … …
Electric energy consumption (Condition A, combined) (Wh/km) … … …
Electric energy consumption (Condition B, combined) (Wh/km) … … …
Electric energy consumption (weighted and combined) (Wh/km) … … …
Pure electric range (km) … … …


Interpolation family number Variant/versions
… …
… …
… …


Road Load Matrix family identifier Variant/versions
… …
… …
… …


Results: Interpolation family identifier Road Load Matrix family identifier
VH VM (if applicable) VL (if applicable) V representative
CS CO2 mass emission LOW phase (g/km) …  … 
CS CO2 mass emission MID phase (g/km) …  … 
CS CO2 mass emission HIGH phase (g/km) …  … 
CS CO2 mass emission EXTRA-HIGH phase (g/km) …  … 
CS CO2 mass emission (combined) (g/km) …  … 
CD CO2 mass emission (combined) (g/km)    
CO2 mass emission (weighted, combined) (g/km)    
CS Fuel consumption LOW phase (l/100 km) …  … 
CS Fuel consumption MID phase (l/100 km) …  … 
CS Fuel consumption HIGH phase (l/100 km) …  … 
CS Fuel consumption EXTRA-HIGH phase (l/100 km) …  … 
CS Fuel consumption (combined) (l/100 km) …  … 
CD Fuel consumption (combined) (l/100 km) …  … 
Fuel consumption (weighted, combined) (l/100 km) …  … 
ECAC,weighted …  … 
EAER (combined) …  … 
EAERcity …  … 
f0 …  … 
f1 …  … 
f2 …  … 
RR …  … 
Delta Cd*A (for VL or VM compared to VH) …  … 
Test Mass …  … 
Frontal area of the representative vehicle (m2)    

Repeat for each interpolation family.
 3.3. 

Variant/Version: … … …
Electric energy consumption (Wh/km) … … …
Range (km) … … …


Interpolation family number Variant/versions
… …
… …
… …


Road Load Matrix family identifier Variant/versions
… …
… …
… …


Results: Interpolation family identifier Matrix family identifier
VH VL V representative
Electric Consumption (Combined) (Wh/km) … … 
Pure Electric Range (Combined) (km) … … 
Pure Electric Range (City) (km) … … 
f0 … … 
f1 … … 
f2 … … 
RR … … 
Delta Cd*A (for VL compared to VH) … … 
Test Mass … … 
Frontal area of the representative vehicle (m2)   
 3.4. 

Variant/Version: … … …
Fuel consumption (kg/100 km) … … …


 Variant/Version: Variant/Version:
Fuel Consumption (Combined) (kg/100 km) … …
f0 … …
f1 … …
f2 … …
RR … …
Test Mass … 
 3.5. 
Repeat for each interpolation or road load matrix family:

Interpolation family identifier or road load matrix family [Footnote: “Type Approval Number + Interpolation Family Sequence number”]: …

VH report: …

VL report (if applicable): …

V representative: …
 4. 
According to Regulation 83 (if applicable)


 Variant/Version …
Decision approving the eco-innovation Code of the eco-innovation Type 1/I cycle (NEDC/WLTP) 1. CO2 emissions of the baseline vehicle (g/km) 2. CO2 emissions of the eco-innovation vehicle (g/km) 3. CO2 emissions of the baseline vehicle under Type 1 test-cycle 4. CO2 emissions of the eco-innovation vehicle under Type 1 test-cycle (= 3.5.1.3 of Annex I) 5. Usage factor (UF) i.e. temporal share of technology usage in normal operation conditions CO2 emissions savings ((1 – 2) – (3 – 4)) * 5
xxx/201x … … … … … … … …
… … … … … … … … …
… … … … … … … … …
 Total CO2 emissions savings on NEDC(g/km) …





According to Annex XXI of Regulation (EU) 2017/1151 (if applicable)


 Variant/Version …
Decision approving the eco-innovation Code of the eco-innovation Type 1/I cycle (NEDC/WLTP) 1. CO2 emissions of the baseline vehicle (g/km) 2. CO2 emissions of the eco-innovation vehicle (g/km) 3. CO2 emissions of the baseline vehicle under Type 1 test-cycle 4. CO2 emissions of the eco-innovation vehicle under Type 1 test-cycle 5. Usage factor (UF) i.e. temporal share of technology usage in normal operation conditions CO2 emissions savings ((1 – 2) – (3 – 4)) * 5
xxx/201x … … … … … … … …
… … … … … … … … …
… … … … … … … … …
 Total CO2 emissions savings on WLTP(g/km) 




 4.1.  (h) Eco-innovations.

 (5) 
 ‘ANNEX IX  0. 
The certificate of conformity is a statement delivered by the vehicle manufacturer to the buyer in order to assure him that the vehicle he has acquired complies with the legislation in force in the European Union at the time it was produced.

The certificate of conformity also serves the purpose to enable the competent authorities of the Member States to register vehicles without having to require the applicant to supply additional technical documentation.

For these purposes, the certificate of conformity has to include:


((a)) the Vehicle Identification Number;
((b)) the exact technical characteristics of the vehicle (i.e. it is not permitted to mention any range of value in the various entries).
 1.  1.1. 

((a)) SIDE 1, which consists of a statement of compliance by the manufacturer. The same template is common to all vehicle categories.
((b)) SIDE 2, which is a technical description of the main characteristics of the vehicle. The template of side 2 is adapted to each specific vehicle category.
 1.2. The certificate of conformity shall be established in a maximum format A4 (210 × 297 mm) or a folder of maximum format A4.
 1.3. Without prejudice to the provisions in Section O(b), the values and units indicated in the second part shall be those given in the type-approval documentation of the relevant regulatory acts. In case of conformity of production checks the values shall be verified according to the methods laid down in the relevant regulatory acts. The tolerances allowed in those regulatory acts shall be taken into account.
 2.  2.1. Model A of the certificate of conformity (complete vehicle) shall cover vehicles which can be used on the road without requiring any further stage for their approval.
 2.2. 
This is the normal result of the multi-stage approval process (e.g. a bus built by a second stage manufacturer on a chassis built by a vehicle manufacturer).

The additional features added during the multi-stage process shall be described briefly.
 2.3. 
Except for tractors for semi-trailers, certificates of conformity covering chassis-cab vehicles belonging to category N shall be of Model C.

PART I MODEL A1 — SIDE 1 
The undersigned [… (Full name and position)] hereby certifies that the vehicle:
 0.1. Make (Trade name of manufacturer): …
 0.2. 

— Variant: …
— Version: …
 0.2.1. Commercial name: …
 0.4. Vehicle category: …
 0.5. Company name and address of manufacturer: …
 0.6. 
Location of the vehicle identification number: …
 0.9. Name and address of the manufacturer’s representative (if any): …
 0.10. Vehicle identification number: …

conforms in all respects to the type described in approval (… type-approval number including extension number) issued on (… date of issue) and

can be permanently registered in Member States having right/left hand traffic and using metric/imperial units for the speedometer and metric/imperial units for the odometer (if applicable).


(Place) (Date): … (Signature): …
 MODEL A2 — SIDE 1 

[Year] [Sequential number]

The undersigned [… (Full name and position)] hereby certifies that the vehicle:
 0.1. Make (Trade name of manufacturer): …
 0.2. 

— Variant: …
— Version: …
 0.2.1. Commercial name: …
 0.4. Vehicle category: …
 0.5. Company name and address of manufacturer: …
 0.6. 
Location of the vehicle identification number: …
 0.9. Name and address of the manufacturer’s representative (if any): …
 0.10. Vehicle identification number: …

conforms in all respects to the type described in approval (… type-approval number including extension number) issued on (… date of issue) and

can be permanently registered in Member States having right/left (b) hand traffic and using metric/imperial units for the speedometer and metric/imperial units for the odometer (if applicable).


(Place) (Date): … (Signature): …
 MODEL B — SIDE 1 
The undersigned [… (Full name and position)] hereby certifies that the vehicle:
 0.1. Make (Trade name of the manufacturer): …
 0.2. 

— Variant: …
— Version: …
 0.2.1. Commercial name: …
 0.2.2. 

— Type: …
— Variant: …
— Version: …

Type-approval number, extension number …
 0.4. Vehicle category: …
 0.5. Company name and address of manufacturer: …
 0.5.1. For multi-stage approved vehicles, company name and address of the manufacturer of the base/previous stage(s) vehicle…
 0.6. 
Location of the vehicle identification number: …
 0.9. Name and address of the manufacturer’s representative (if any): …
 0.10. Vehicle identification number: …


((a)) has been completed and altered as follows: … and
((b)) conforms in all respects to the type described in approval (… type-approval number including extension number) issued on (… date of issue) and
((c)) can be permanently registered in Member States having right/left hand traffic and using metric/imperial units for the speedometer and metric/imperial units for the odometer (if applicable).


(Place) (Date): … (Signature): …

Attachments: Certificate of conformity delivered at each previous stage.
 VEHICLE CATEGORY M1  1. Number of axles: … and wheels: …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 13. Mass in running order: … kg
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 18. 

18.1. Drawbar trailer: … kg
18.3. Centre-axle trailer: … kg
18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static vertical mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Class of Hybrid [electric] vehicle: OVC-HEV/NOVC-HEV/OVC-FCHV/ NOVC-FCHV
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 29. Maximum speed: … km/h
 30. 

1.. … mm
2.. … mm
3.. … mm
 35. Tyre/wheel combination/Rolling Resistance Class (if applicable): …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 38. Code for bodywork: …
 40. Colour of vehicle: …
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 42.1. Seat(s) designated for use only when the vehicle is stationary: …
 42.3. Number of wheelchair user accessible position: …
 46. 

— Stationary: … dB(A) at engine speed: … min-1
— Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: …. HC: ….. NO x: …. HC + NO x: …. Particulates: …..

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): …

Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): …Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 49. CO2 emissions/fuel consumption/electric energy consumption:
 1. 

NEDC values CO2 emissions Fuel consumption in case of emission testing according to Regulation (EC) No 692/2008
Urban conditions (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra-urban conditions (1): … g/km l/100 km or m3/100 km or kg/100 km (1)
Combined (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Weighted (1), combined … g/km … l/100 km or m3/100 km or kg/100 km
Deviation factor (if applicable) 
Verification factor (if applicable) “1” or “0”
 2. 

Electric energy consumption (weighted, combined (1))  … Wh/km
Electric range  … km
 3.  3.1. General code of the eco-innovation(s): …
 3.2. 

3.2.1. NEDC savings: …g/km (if applicable)
3.2.2. WLTP savings: …g/km (if applicable)
 4. 

WLTP values CO2 emissions Fuel consumption
Low (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Medium (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
High (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra High (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Combined: … g/km … l/100 km or m3/100 km or kg/100 km (1)
Weighted, combined (1) … g/km … l/100 km or m3/100 km or kg/100 km (1)
 5.  5.1. 

Electric energy consumption  … Wh/km
Electric range  … km
Electric range city  … km
 5.2 

Electric energy consumption (ECAC,weighted)  … Wh/km
Electric range (EAER)  … km
Electric range city (EAER city)  … km
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …

Additional tyre/wheel combinations: technical parameters (no reference to RR)
 VEHICLE CATEGORY M2  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 9. Distance between the front end of the vehicle and the centre of the coupling device: … mm
 12. Rear overhang: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 17.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. 

18.1. Drawbar trailer: … kg
18.3. Centre-axle trailer: … kg
18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Class of Hybrid [electric] vehicle: OVC-HEV/NOVC-HEV/OVC-FCHV/ NOVC-FCHV
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 30. 

1.. … mm
2.. … mm
3.. … mm etc.
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination/Rolling Resistance Class (if applicable): …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 38. Code for bodywork: …
 39. Class of vehicle: class I/Class II/Class III/Class A/Class B
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 42.1. Seat(s) designated for use only when the vehicle is stationary: …
 42.3. Number of wheelchair user accessible position: …
 43. Number of standing places: …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: …. HC: ….. NO x: …. HC + NO x: …. Particulates: …..

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): …

Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 49. CO2 emissions/fuel consumption/electric energy consumption:
 1. 

NEDC values CO2 emissions Fuel consumption in case of emission testing under NEDC according to Regulation (EC) No 692/2008
Urban conditions (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra-urban conditions (1): … g/km l/100 km or m3/100 km or kg/100 km(1)
Combined (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Weighted (1), combined … g/km … l/100 km or m3/100 km or kg/100 km
Deviation factor (if applicable) 
Verification factor (if applicable) “1” or “0”
 2. 

Electric energy consumption (weighted, combined (1))  … Wh/km
Electric range  … km
 3.  3.1. General code of the eco-innovation(s): …
 3.2. Total CO2 emissions savings due to the eco-innovation(s) (repeat for each reference fuel tested):
 3.2.1. NEDC savings: …g/km (if applicable)
 3.2.2. WLTP savings: …g/km (if applicable)
 4. 

WLTP values CO2 emissions Fuel consumption
Low (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Medium (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
High (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra High (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Combined: … g/km … l/100 km or m3/100 km or kg/100 km (1)
Weighted, combined (1) … g/km … l/100 km or m3/100 km or kg/100 km (1)
 5.  5.1. 

Electric energy consumption  … Wh/km
Electric range  … km
Electric range city  … km
 5.2 

Electric energy consumption (ECAC,weighted)  … Wh/km
Electric range (EAER)  … km
Electric range city (EAER city)  … km
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …
 VEHICLE CATEGORY M3  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 9. Distance between the front end of the vehicle and the centre of the coupling device: … mm
 12. Rear overhang: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. Technically permissible maximum towable mass in case of:
 18.1. Drawbar trailer: … kg
 18.3. Centre-axle trailer: … kg
 18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 30.1. Track of each steered axle: … mm
 30.2. Track of all other axles: … mm
 32. Position of loadable axle(s): …
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 38. Code for bodywork: …
 39. Class of vehicle: class I/Class II/Class III/Class A/Class B
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 42.1. Seat(s) designated for use only when the vehicle is stationary: …
 42.2. Number of passenger seating positions: … (lower deck) … (upper deck) (including the driver)
 42.3. Number of wheelchair user accessible position: …
 43. Number of standing places: …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …
 VEHICLE CATEGORY N1  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm.
 8. Fifth wheel lead for semi-trailer towing vehicle (maximum and minimum): … mm
 9. Distance between the front end of the vehicle and the centre of the coupling device: … mm
 11. Length of the loading area: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg
 13.2. Actual mass of the vehicle: … kg
 14. Mass of the base vehicle in running order: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 18. Technically permissible maximum towable mass in case of:
 18.1. Drawbar trailer: … kg
 18.2. Semi-trailer: … kg
 18.3. Centre-axle trailer: … kg
 18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Class of Hybrid [electric] vehicle: OVC-HEV/NOVC-HEV/OVC-FCHV/ NOVC-FCHV
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 30. 

1.. … mm
2.. … mm
3.. … mm
 35. Tyre/wheel combination/Rolling Resistance Class (if applicable): …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 38. Code for bodywork: …
 40. Colour of vehicle: …
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 49. CO2 emissions/fuel consumption/electric energy consumption:
 1. 

NEDC values CO2 emissions Fuel consumption in case of emission testing according to Regulation (EC) No 692/2008
Urban conditions (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra-urban conditions (1): … g/km l/100 km or m3/100 km or kg/100 km (1)
Combined (1): … g/km … l l/100 km or m3/100 km or kg/100 km (1)
Weighted (1), combined … g/km … l/100 km or m3/100 km or kg/100 km
Deviation factor (if applicable) 
 2. 

Electric energy consumption (weighted, combined (1))  … Wh/km
Electric range  … km
 3.  3.1. General code of the eco-innovation(s): …
 3.2. 

3.2.1. NEDC savings:…g/km (if applicable)
3.2.2. WLTP savings:…g/km (if applicable)
 4. 

WLTP values CO2 emissions Fuel consumption
Low (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Medium (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
High (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra High (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Combined: … g/km … l/100 km or m3/100 km or kg/100 km (1)
Weighted, combined (1) … g/km … l/100 km or m3/100 km or kg/100 km (1)
 5.  5.1. 

Electric energy consumption  … Wh/km
Electric range  … km
Electric range city  … km
 5.2 

Electric energy consumption (ECAC,weighted)  … Wh/km
Electric range (EAER)  … km
Electric range city (EAER city)  … km
 50. Type-approved according to the design requirements for transporting dangerous goods: yes/class(es): …/no:
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …

List of tyres: technical parameters (no reference to RR)
 VEHICLE CATEGORY N2  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 8. Fifth wheel lead for semi-trailer towing vehicle (maximum and minimum): … mm
 9. Distance between the front end of the vehicle and the centre of the coupling device: … mm
 11. Length of the loading area: … mm
 12. Rear overhang: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. Technically permissible maximum towable mass in case of:
 18.1. Drawbar trailer: … kg
 18.2. Semi-trailer: … kg
 18.3. Centre-axle trailer: … kg
 18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Class of Hybrid [electric] vehicle: OVC-HEV/NOVC-HEV/OVC-FCHV/ NOVC-FCHV
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination/Rolling Resistance Class (if applicable): …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 38. Code for bodywork: …
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 49. CO2 emissions/fuel consumption/electric energy consumption:
 1. 

NEDC values CO2 emissions Fuel consumption in case of emission testing according to Regulation (EC) No 692/2008
Urban conditions (1): … g/km … l/100 km or m3/100 km or kg/100 km (1)
Extra-urban conditions (1): … g/km l/100 km or m3/100 km or kg/100 km (1)
Combined (1): … g/km … l l/100 km or m3/100 km or kg/100 km (1)
Weighted (1), combined … g/km … l/100 km or m3/100 km or kg/100 km
Deviation factor (if applicable) 
 2. 

Electric energy consumption (weighted, combined (1))  … Wh/km
Electric range  … km
 3.  3.1. General code of the eco-innovation(s): …
 3.2. Total CO2 emissions saving due to the eco-innovation(s) (repeat for each reference fuel tested):
 3.2.1. NEDC savings:…g/km (if applicable)
 3.2.2. WLTP savings:…g/km (if applicable)
 4. 

WLTP values CO2 emissions Fuel consumption
Low (1): … g/km … l/100 km or m3/100 km or kg/100 km(1)
Medium(1): … g/km … l/100 km or m3/100 km or kg/100 km(1)
High(1): … g/km … l/100 km or m3/100 km or kg/100 km(1)
Extra High(1): … g/km … l/100 km or m3/100 km or kg/100 km(1)
Combined: … g/km … l/100 km or m3/100 km or kg/100 km(1)
Weighted, combined(1) … g/km … l/100 km or m3/100 km or kg/100 km(1)
 5.  5.1. 

Electric energy consumption  … Wh/km
Electric range  … km
Electric range city  … km
 5.2 

Electric energy consumption (ECAC,weighted)  … Wh/km
Electric range (EAER)  … km
Electric range city (EAER city)  … km
 50. Type-approved according to the design requirements for transporting dangerous goods: yes/class(es): …/no:
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …
 VEHICLE CATEGORY N3  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 8. Fifth wheel lead for semi-trailer towing vehicle (maximum and minimum): … mm
 9. Distance between the front end of the vehicle and the centre of the coupling device: … mm
 11. Length of the loading area: … mm
 12. Rear overhang: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. 

18.1. Drawbar trailer: … kg
18.2. Semi-trailer: … kg
18.3. Centre-axle trailer: … kg
18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 38. Code for bodywork: …
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 50. Type-approved according to the design requirements for transporting dangerous goods: yes/class(es): …/no:
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …
 VEHICLE CATEGORIES O1 AND O2  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 10. Distance between the centre of the coupling device and the rear end of the vehicle: … mm
 11. Length of the loading area: … mm
 12. Rear overhang: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 19. Technically permissible maximum static mass on the coupling point of a semi-trailer or centre-axle trailer: … kg
 29. Maximum speed: … km/h
 30.1. Track of each steered axle: … mm
 30.2. Track of all other axles: … mm
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 34. Axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 38. Code for bodywork: …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 50. Type-approved according to the design requirements for transporting dangerous goods: yes/class(es): …/no:
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …
 VEHICLE CATEGORIES O3 AND O4  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5. Length: … mm
 6. Width: … mm
 7. Height: … mm
 10. Distance between the centre of the coupling device and the rear end of the vehicle: … mm
 11. Length of the loading area: … mm
 12. Rear overhang: … mm
 13. Mass in running order: … kg
 13.1. 

1.. … kg
2.. … kg
3.. … kg
 13.2. Actual mass of the vehicle: … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 19. Technically permissible maximum static mass on the coupling point of a semi-trailer or centre-axle trailer: … kg
 29. Maximum speed: … km/h
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 34. Axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 38. Code for bodywork: …
 44. Approval number or approval mark of coupling device (if fitted): …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …å
 50. Type-approved according to the design requirements for transporting dangerous goods: yes/class(es): …/no:
 51. For special purpose vehicles: designation in accordance with Annex II Section 5: …
 52. Remarks: …

PART II MODEL C1 — SIDE 1 
The undersigned [… (Full name and position)] hereby certifies that the vehicle:
 0.1. Make (Trade name of manufacturer): …
 0.2. 
Variant: …

Version: …
 0.2.1. Commercial name: …
 0.2.2. 
(list the information for each stage):

Type: …

Variant: …

Version: …

Type-approval number, extension number …
 0.4. Vehicle category: …
 0.5. Company name and address of manufacturer: …
 0.5.1. For multi-stage approved vehicles, company name and address of the manufacturer of the base/previous stage(s) vehicle …
 0.6. 
Location of the vehicle identification number: …
 0.9. Name and address of the manufacturer’s representative (if any): …
 0.10. Vehicle identification number: …

conforms in all respects to the type described in approval (… type-approval number including extension number) issued on (… date of issue) and

cannot be permanently registered without further approvals.


(Place) (Date): … (Signature): …
 MODEL C2 — SIDE 1 

[Year] [Sequential number]

The undersigned [… (Full name and position)] hereby certifies that the vehicle:
 0.1. Make (Trade name of manufacturer): …
 0.2. 
Variant: …

Version: …
 0.2.1. Commercial name: …
 0.4. Vehicle category: …
 0.5. Company name and address of manufacturer: …
 0.6. 
Location of the vehicle identification number: …
 0.9. Name and address of the manufacturer’s representative (if any): …
 0.10. Vehicle identification number: …

conforms in all respects to the type described in approval (… type-approval number including extension number) issued on (… date of issue) and

cannot be permanently registered without further approvals.


(Place) (Date): … (Signature): …
 VEHICLE CATEGORY M1  1. Number of axles: … and wheels: …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 7.1. Maximum permissible height: … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 18. 

18.1. Drawbar trailer: … kg
18.3. Centre-axle trailer: … kg
18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static vertical mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 29. Maximum speed: … km/h
 30. 

1.. … mm
2.. … mm
3.. … mm
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 41. Number and configuration of doors: …
 42. Number of seating positions (including the driver): …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 49. CO2 emissions/fuel consumption/electric energy consumption:
 1. 

 CO2 emissions Fuel consumption
Urban conditions: … g/km … l/100 km/m3/100 km (1)
Extra-urban conditions: … g/km … l/100 km/m3/100 km (1)
Combined: … g/km … l/100 km/m3/100 km (1)
Weighted, combined … g/km … l/100 km
 2. 

Electric energy consumption (weighted, combined (1))  … Wh/km
Electric range  … km
 52. Remarks: …
 VEHICLE CATEGORY M2  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 7.1. Maximum permissible height: … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. Technically permissible maximum towable mass in case of:
 18.1. Drawbar trailer: … kg
 18.3. Centre-axle trailer: … kg
 18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 30. 

1.. … mm
2.. … mm
3.. … mm
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Type or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 52. Remarks: …
 VEHICLE CATEGORY M3  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 7.1. Maximum permissible height: … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. 

18.1. Drawbar trailer: … kg
18.3. Centre-axle trailer: … kg
18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 30.1. Track of each steered axle: … mm
 30.2. Track of all other axles: … mm
 32. Position of loadable axle(s): …
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Types or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates: …
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 52. Remarks: …
 VEHICLE CATEGORY N1  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 7.1. Maximum permissible height: … mm
 8. Fifth wheel lead for semi-trailer towing vehicle (maximum and minimum): … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 18. Technically permissible maximum towable mass in case of:
 18.1. Drawbar trailer: … kg
 18.2. Semi-trailer: … kg
 18.3. Centre-axle trailer: … kg
 18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 30. 

1.. … mm
2.. … mm
3.. … mm
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Types or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates:
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number):
 48.1. Smoke corrected absorption coefficient: … (m–1)
 49. CO2 emissions/fuel consumption/electric energy consumption:
 1. 

 CO2 emissions Fuel consumption
Urban conditions: … g/km … l/100 km/m3/100 km (1)
Extra-urban conditions: … g/km … l/100 km/m3/100 km (1)
Combined: … g/km … l/100 km/m3/100 km (1)
Weighted, combined … g/km … l/100 km
 2. 

Electric energy consumption (weighted, combined (1))  … Wh/km
Electric range  … km
 3.  3.1. General code of the eco-innovation(s): …
 3.2. Total CO2 emissions saving due to the eco-innovation(s) (repeat for each reference fuel tested): …
 52. Remarks: …
 VEHICLE CATEGORY N2  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 8. Fifth wheel lead for semi-trailer towing vehicle (maximum and minimum): … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. 

18.1. Drawbar trailer: … kg
18.2. Semi-trailer: … kg
18.3. Centre-axle trailer: … kg
18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Types or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates:
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 52. Remarks: …
 VEHICLE CATEGORY N3  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axles (number, position): …
 3. Powered axles (number, position, interconnection): … …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 8. Fifth wheel lead for semi-trailer towing vehicle (maximum and minimum): … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.4. Technically permissible maximum mass of the combination: … kg
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 17.4. Intended registration/in service maximum permissible mass of the combination: … kg
 18. Technically permissible maximum towable mass in case of:
 18.1. Drawbar trailer: … kg
 18.2. Semi-trailer: … kg
 18.3. Centre-axle trailer: … kg
 18.4. Unbraked trailer: … kg
 19. Technically permissible maximum static mass at the coupling point: … kg
 20. Manufacturer of the engine: …
 21. Engine code as marked on the engine: …
 22. Working principle: …
 23. Pure electric: yes/no
 23.1. Hybrid [electric] vehicle: yes/no
 24. Number and arrangement of cylinders: …
 25. Engine capacity: … cm3
 26. Fuel: Diesel/petrol/LPG/CNG-Biomethane/LNG/Ethanol/Biodiesel/Hydrogen
 26.1. Mono fuel/Bi fuel/Flex fuel/Dual-fuel
 26.2. (Dual-fuel only) Type 1A/Type 1B/Type 2A/Type 2B/Type 3B
 27. Maximum power
 27.1. Maximum net power: … kW at … min–1 (internal combustion engine)
 27.2. Maximum hourly output: … kW (electric motor)
 27.3. Maximum net power: … kW (electric motor)
 27.4. Maximum 30 minutes power: … kW (electric motor)
 28. Gearbox (type): …
 29. Maximum speed: … km/h
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 33. Drive axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 36. Trailer brake connections mechanical/electric/pneumatic/hydraulic
 37. Pressure in feed line for trailer braking system: … bar
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Types or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 46. 
Stationary: … dB(A) at engine speed: … min–1

Drive-by: … dB(A)
 47. Exhaust emission level: Euro …
 47.1. Parameters for emission testing
 47.1.1. Test mass, kg: …
 47.1.2. Frontal area, m2: …
 47.1.3. Road load coefficients
 47.1.3.0. f0, N:
 47.1.3.1. f1, N/(km/h):
 47.1.3.2. f2, N/(km/h)2
 48. Exhaust emissions:

Number of the base regulatory act and latest amending regulatory act applicable: …
 1.1. 
CO: … HC: … NOx: … HC + NOx: … Particulates: …

Smoke opacity (ELR): … (m–1)
 1.2. 
CO: … THC: … NMHC: … NOx: … THC + NOx: … NH3: … Particulates (mass): … Particles (number): …
 2.1. 
CO: … NOx: … NMHC: … THC: … CH4: … Particulates:
 2.2. 
CO: … NOx: … NMHC: … THC: … CH4: … NH3: … Particulates (mass): … Particles (number): …
 48.1. Smoke corrected absorption coefficient: … (m–1)
 52. Remarks: …
 VEHICLE CATEGORIES O1 AND O2  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: … mm
 6.1. Maximum permissible width: … mm
 7.1. Maximum permissible height: … mm
 10. Distance between the centre of the coupling device and the rear end of the vehicle: … mm
 12.1. Maximum permissible rear overhang: … mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 19.1. Technically permissible maximum static mass on the coupling point of a semi-trailer or centre-axle trailer: … kg
 29. Maximum speed: … km/h
 30.1. Track of each steered axle: … mm
 30.2. Track of all other axles: … mm
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 34. Axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Types or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 52. Remarks: …
 VEHICLE CATEGORIES O3 AND O4  1. Number of axles: … and wheels: …
 1.1. Number and position of axles with twin wheels: …
 2. Steered axle (number, position): …
 4. Wheelbase: … mm
 4.1. 

1-2: … mm
2-3: … mm
3-4: … mm
 5.1. Maximum permissible length: …mm
 6.1. Maximum permissible width: …mm
 7.1. Maximum permissible height: …mm
 10. Distance between the centre of the coupling device and the rear end of the vehicle: …mm
 12.1. Maximum permissible rear overhang: …mm
 14. Mass in running order of the incomplete vehicle: … kg
 14.1. 

1.. … kg
2.. … kg
3.. … kg etc.
 15. Minimum mass of the vehicle when completed: … kg
 15.1. 

1.. … kg
2.. … kg
3.. … kg
 16. Technically permissible maximum masses
 16.1. Technically permissible maximum laden mass: … kg
 16.2. 

1.. … kg
2.. … kg
3.. … kg etc.
 16.3. 

1.. … kg
2.. … kg
3.. … kg etc.
 17. Intended registration/in service maximum permissible masses in national/international traffic
 17.1. Intended registration/in service maximum permissible laden mass: … kg
 17.2. 

1.. … kg
2.. … kg
3.. … kg
 17.3. 

1.. … kg
2.. … kg
3.. … kg
 19.1. Technically permissible maximum static mass on the coupling point of a semi-trailer or centre-axle trailer: … kg
 29. Maximum speed: … km/h
 31. Position of lift axle(s): …
 32. Position of loadable axle(s): …
 34. Axle(s) fitted with air suspension or equivalent: yes/no
 35. Tyre/wheel combination: …
 44. Approval number or approval mark of coupling device (if fitted): …
 45. Types or classes of coupling devices which can be fitted: …
 45.1. Characteristics values: D: …/ V: …/ S: …/ U: …
 52. Remarks: …
 — —
 (p) Eco-innovations.


ANNEX XIX

Regulation (EU) No 1230/2012 is amended as follows:

1.. Article 2(5) is replaced by the following:
' “Mass of the optional equipment” means maximum mass of the combinations of optional equipment which may be fitted to the vehicle in addition to the standard equipment in accordance with the manufacturer's specifications;'

ANNEX XX
1. 
This Annex sets out requirements for measuring net engine power, net power and the maximum 30 minutes power of electric drive trains.

2.  2.1. The general specifications for conducting the tests and interpreting the results are those set out in paragraph 5 of UN/ECE Regulation No 85, with the exceptions specified in this Annex.
 2.2. 
Paragraphs 5.2.3.1., 5.2.3.2.1., 5.2.3.3.1., and 5.2.3.4. of UN/ECE Regulation No 85 shall be understood as follows:

The fuel used shall be the one available on the market. In any case of dispute, the fuel shall be the appropriate reference fuel specified in Annex IX to this Regulation.
 2.3. 
By way of derogation from paragraph 5.1 of Annex 5 to UN/ECE Regulation No 85, when a turbo-charged engine is fitted with a system which allows compensating the ambient conditions temperature and altitude, at the request of the manufacturer, the correction factors αa or αd shall be set to the value of 1.

ANNEX XXI
1. 
This Annex describes the procedure for determining the levels of emissions of gaseous compounds, particulate matter, particle number, CO2 emissions, fuel consumption, electric energy consumption and electric range from light-duty vehicles..

2. 
3.  3.1.  3.1.1. ‘Accuracy’ means the difference between a measured value and a reference value, traceable to a national standard and describes the correctness of a result. See Figure 1.
 3.1.2. ‘Calibration’ means the process of setting a measurement system's response so that its output agrees with a range of reference signals.
 3.1.3. ‘Calibration gas’ means a gas mixture used to calibrate gas analysers.
 3.1.4. ‘Double dilution method’ means the process of separating a part of the diluted exhaust flow and mixing it with an appropriate amount of dilution air prior to the particulate sampling filter.
 3.1.5. ‘Full flow exhaust dilution system’ means the continuous dilution of the total vehicle exhaust with ambient air in a controlled manner using a constant volume sampler (CVS).
 3.1.6. ‘Linearisation’ means the application of a range of concentrations or materials to establish a mathematical relationship between concentration and system response.
 3.1.7. ‘Major maintenance’ means the adjustment, repair or replacement of a component or module that could affect the accuracy of a measurement.
 3.1.8. ‘Non-methane hydrocarbons’ (NMHC) are the total hydrocarbons (THC) minus the methane (CH4) contribution.
 3.1.9. ‘Precision’ means the degree to which repeated measurements under unchanged conditions show the same results (Figure 1) and, in this Annex, always refers to one standard deviation.
 3.1.10. ‘Reference value’ means a value traceable to a national standard. See Figure 1.
 3.1.11. ‘Set point’ means the target value a control system aims to reach.
 3.1.12. ‘Span’ means to adjust an instrument so that it gives a proper response to a calibration standard that represents between 75 per cent and 100 per cent of the maximum value in the instrument range or expected range of use.
 3.1.13. ‘Total hydrocarbons’ (THC) means all volatile compounds measurable by a flame ionization detector (FID).
 3.1.14. ‘Verification’ means to evaluate whether or not a measurement system's outputs agrees with applied reference signals within one or more predetermined thresholds for acceptance.
 3.1.15. ‘Zero gas’ means a gas containing no analyte, which is used to set a zero response on an analyser.

Figure 1 3.2.  3.2.1. ‘Aerodynamic drag’ means the force opposing a vehicle’s forward motion through air.
 3.2.2. ‘Aerodynamic stagnation point’ means the point on the surface of a vehicle where wind velocity is equal to zero.
 3.2.3. ‘Anemometer blockage’ means the effect on the anemometer measurement due to the presence of the vehicle where the apparent air speed is different than the vehicle speed combined with wind speed relative to the ground.
 3.2.4. ‘Constrained analysis’ means the vehicle’s frontal area and aerodynamic drag coefficient have been independently determined and those values shall be used in the equation of motion.
 3.2.5. ‘Mass in running order’ means the mass of the vehicle, with its fuel tank(s) filled to at least 90 per cent of its or their capacity/capacities, including the mass of the driver, fuel and liquids, fitted with the standard equipment in accordance with the manufacturer’s specifications and, when they are fitted, the mass of the bodywork, the cabin, the coupling and the spare wheel(s) as well as the tools.
 3.2.6. ‘Mass of the driver’ means a mass rated at 75 kg located at the driver’s seating reference point.
 3.2.7. ‘Maximum vehicle load’ means the technically permissible maximum laden mass minus the mass in running order, 25 kg and the mass of the optional equipment as defined in paragraph 3.2.8.
 3.2.8. ‘Mass of the optional equipment’ means maximum mass of the combinations of optional equipment which may be fitted to the vehicle in addition to the standard equipment in accordance with the manufacturer's specifications.
 3.2.9. ‘Optional equipment’ means all the features not included in the standard equipment which are fitted to a vehicle under the responsibility of the manufacturer, and that can be ordered by the customer.
 3.2.10. 

((a)) Atmospheric pressure: p0 = 100 kPa;
((b)) Atmospheric temperature: T0 = 20 °C;
((c)) Dry air density: ρ0 = 1,189 kg/m3;
((d)) Wind speed: 0 m/s.
 3.2.11. ‘Reference speed’ means the vehicle speed at which road load is determined or chassis dynamometer load is verified.
 3.2.12. ‘Road load’ means the force resisting the forward motion of a vehicle as measured with the coastdown method or methods that are equivalent regarding the inclusion of frictional losses of the drivetrain.
 3.2.13. ‘Rolling resistance’ means the forces of the tyres opposing the motion of a vehicle.
 3.2.14. ‘Running resistance’ means the torque resisting the forward motion of a vehicle measured by torque meters installed at the driven wheels of a vehicle.
 3.2.15. ‘Simulated road load’ means the road load experienced by the vehicle on the chassis dynamometer which is intended to reproduce the road load measured on the road, and consists of the force applied by the chassis dynamometer and the forces resisting the vehicle while driving on the chassis dynamometer and is approximated by the three coefficients of a second order polynomial.
 3.2.16. ‘Simulated running resistance’ means the running resistance experienced by the vehicle on the chassis dynamometer which is intended to reproduce the running resistance measured on the road, and consists of the torque applied by the chassis dynamometer and the torque resisting the vehicle while driving on the chassis dynamometer and is approximated by the three coefficients of a second order polynomial.
 3.2.17. ‘Stationary anemometry’ means measurement of wind speed and direction with an anemometer at a location and height above road level alongside the test road where the most representative wind conditions will be experienced.
 3.2.18. ‘Standard equipment’ means the basic configuration of a vehicle which is equipped with all the features that are required under the regulatory acts referred to in Annex IV and Annex XI of Directive 2007/46/EC including all features that are fitted without giving rise to any further specifications on configuration or equipment level.
 3.2.19. ‘Target road load’ means the road load to be reproduced.
 3.2.20. ‘Target running resistance’ means the running resistance to be reproduced on the chassis dynamometer.
 3.2.21. Reserved
 3.2.22. ‘Wind correction’ means correction of the effect of wind on road load based on input of the stationary or on-board anemometry.
 3.2.23. ‘Technically permissible maximum laden mass’ means the maximum mass allocated to a vehicle on the basis of its construction features and its design performances.
 3.2.24. ‘Actual mass of the vehicle’ means the mass in running order plus the mass of the fitted optional equipment to an individual vehicle.
 3.2.25. ‘Test mass of the vehicle’ means the sum of the actual mass of the vehicle, 25 kg and the mass representative of the vehicle load.
 3.2.26. ‘Mass representative of the vehicle load’ means x per cent of the maximum vehicle load where x is 15 per cent for category M vehicles and 28 per cent for category N vehicles.
 3.2.27. ‘Technically permissible maximum laden mass of the combination’ (MC) means the maximum mass allocated to the combination of a motor vehicle and one or more trailers on the basis of its construction features and its design performances or the maximum mass allocated to the combination of a tractor unit and a semi-trailer.
 3.3.  3.3.1. ‘All-electric range’ (AER) means the total distance travelled by an OVC-HEV from the beginning of the charge-depleting test to the point in time during the test when the combustion engine starts to consume fuel.
 3.3.2. ‘Pure Electric range’ (PER) means the total distance travelled by a PEV from the beginning of the charge-depleting test until the break-off criterion is reached.
 3.3.3. ‘Charge-depleting actual range’ (RCDA) means the distance travelled in a series of WLTCs in charge-depleting operating condition until the rechargeable electric energy storage system (REESS) is depleted.
 3.3.4. ‘Charge-depleting cycle range’ (RCDC) means the distance from the beginning of the charge-depleting test to the end of the last cycle prior to the cycle or cycles satisfying the break-off criterion, including the transition cycle where the vehicle may have operated in both depleting and sustaining conditions.
 3.3.5. ‘Charge-depleting operating condition’ means an operating condition in which the energy stored in the REESS may fluctuate but decreases on average while the vehicle is driven until transition to charge-sustaining operation.
 3.3.6. ‘Charge-sustaining operating condition’ means an operating condition in which the energy stored in the REESS may fluctuate but, on average, is maintained at a neutral charging balance level while the vehicle is driven.
 3.3.7. ‘Utility Factors’ are ratios based on driving statistics depending on the range achieved in charge-depleting condition and are used to weigh the charge-depleting and charge-sustaining exhaust emission compounds, CO2 emissions and fuel consumption for OVC-HEVs.
 3.3.8. ‘Electric machine’ (EM) means an energy converter transforming between electrical and mechanical energy.
 3.3.9. ‘Energy converter’ means a system where the form of energy output is different from the form of energy input.
 3.3.9.1. ‘Propulsion energy converter’ means an energy converter of the powertrain which is not a peripheral device whose output energy is used directly or indirectly for the purpose of vehicle propulsion
 3.3.9.2. ‘Category of propulsion energy converter’ means (i) an internal combustion engine, or (ii) an electric machine, or (iii) a fuel cell.
 3.3.10. ‘Energy storage system’ means a system which stores energy and releases it in the same form as was input.
 3.3.10.1. ‘Propulsion energy storage system’ means an energy storage system of the powertrain which is not a peripheral device and whose output energy is used directly or indirectly for the purpose of vehicle propulsion.
 3.3.10.2. ‘Category of propulsion energy storage system’ means (i) a fuel storage system, or (ii) a rechargeable electric energy storage system, or (iii) a rechargeable mechanical energy storage system.
 3.3.10.3. ‘Form of energy’ means (i) electrical energy, or (ii) mechanical energy, or (iii) chemical energy (including fuels).
 3.3.10.4. ‘Fuel storage system’ means a propulsion energy storage system that stores chemical energy as liquid or gaseous fuel.
 3.3.11. ‘Equivalent all-electric range’ (EAER) means that portion of the total charge-depleting actual range (RCDA) attributable to the use of electricity from the REESS over the charge-depleting range test.
 3.3.12. ‘Hybrid electric vehicle’ (HEV) means a hybrid vehicle where one of the propulsion energy converters is an electric machine.
 3.3.13. ‘Hybrid vehicle’ (HV) means a vehicle equipped with a powertrain containing at least two different categories of propulsion energy converters and at least two different categories of propulsion energy storage systems.
 3.3.14. ‘Net energy change’ means the ratio of the REESS energy change divided by the cycle energy demand of the test vehicle.
 3.3.15. ‘Not off-vehicle charging hybrid electric vehicle’ (NOVC-HEV) means a hybrid electric vehicle that cannot be charged from an external source
 3.3.16. ‘Off-vehicle charging hybrid electric vehicle’ (OVC-HEV) means a hybrid electric vehicle that can be charged from an external source.
 3.3.17. ‘Pure electric vehicle’ (PEV) means a vehicle equipped with a powertrain containing exclusively electric machines as propulsion energy converters and exclusively rechargeable electric energy storage systems as propulsion energy storage systems.
 3.3.18. ‘Fuel cell’ means an energy converter transforming chemical energy (input) into electrical energy (output) or vice versa.
 3.3.19. ‘Fuel cell vehicle’ (FCV) means a vehicle equipped with a powertrain containing exclusively fuel cell(s) and electric machine(s) as propulsion energy converter(s).
 3.3.20. ‘Fuel cell hybrid vehicle’ (FCHV) means a fuel cell vehicle equipped with a powertrain containing at least one fuel storage system and at least one rechargeable electric energy storage system as propulsion energy storage systems.
 3.4.  3.4.1. ‘Powertrain’ means the total combination in a vehicle, of propulsion energy storage system(s), propulsion energy converter(s) and the drivetrain(s) providing the mechanical energy at the wheels for the purpose of vehicle propulsion, plus peripheral devices.
 3.4.2. ‘Auxiliary devices’ means energy consuming, converting, storing or supplying non-peripheral devices or systems which are installed in the vehicle for purposes other than the propulsion of the vehicle and are therefore not considered to be part of the powertrain.
 3.4.3. ‘Peripheral devices’ means energy consuming, converting, storing or supplying devices, where the energy is not primarily used for the purpose of vehicle propulsion, or other parts, systems and control units, which are essential to the operation of the powertrain.
 3.4.4. ‘Drivetrain’ means the connected elements of the powertrain for transmission of the mechanical energy between the propulsion energy converter(s) and the wheels.
 3.4.5. ‘Manual transmission’ means a transmission where gears can only be shifted by action of the driver.
 3.5.  3.5.1. ‘Criteria emissions’ means those emission compounds for which limits are set in this Regulation.
 3.5.2. Reserved
 3.5.3. Reserved
 3.5.4. Reserved
 3.5.5. Reserved
 3.5.6. ‘Cycle energy demand’ means the calculated positive energy required by the vehicle to drive the prescribed cycle.
 3.5.7. Reserved
 3.5.8. ‘Driver-selectable mode’ means a distinct driver-selectable condition which could affect emissions, or fuel and/or energy consumption.
 3.5.9. ‘Predominant mode’ for the purposes of this Annex means a single mode that is always selected when the vehicle is switched on regardless of the operating mode selected when the vehicle was previously shut down.
 3.5.10. ‘Reference conditions (with regards to calculating mass emissions)’ means the conditions upon which gas densities are based, namely 101,325 kPa and 273,15 K (0 °C).
 3.5.11. ‘Exhaust emissions’ means the emission of gaseous, solid and liquid compounds.
 3.6. 
The term ‘particle’ is conventionally used for the matter being characterised (measured) in the airborne phase (suspended matter), and the term ‘particulate’ for the deposited matter.
 3.6.1. ‘Particle number emissions’ (PN) means the total number of solid particles emitted from the vehicle exhaust quantified according to the dilution, sampling and measurement methods as specified in this Annex.
 3.6.2. ‘Particulate matter emissions’ (PM) means the mass of any particulate material from the vehicle exhaust quantified according to the dilution, sampling and measurement methods as specified in this Annex.
 3.7.  3.7.1. ‘Rated engine power’ (Prated) means maximum engine power in kW as per the requirements of Annex XX to this Regulation.
 3.7.2. ‘Maximum speed’ (vmax) means the maximum speed of a vehicle as declared by the manufacturer.
 3.8.  3.8.1. ‘Periodically regenerating system’ means an exhaust emissions control device (e.g. catalytic converter, particulate trap) that requires a periodical regeneration process in less than 4 000 km of normal vehicle operation.
 3.9.  3.9.1. ‘Active heat storage device’ means a technology that stores heat within any device of a vehicle and releases the heat to a power train component over a defined time period at engine start. It is characterised by the stored enthalpy in the system and the time for heat release to the power train components.
 3.9.2. ‘Insulation materials’ means any material in the engine compartment attached to the engine and/or the chassis with a thermal insulation effect and characterised by a maximum heat conductivity of 0,1 W/(mK).

4.  4.1. 
ACAlternating currentCFVCritical flow venturiCFOCritical flow orificeCLDChemiluminescent detectorCLAChemiluminescent analyserCVSConstant volume samplerDCDirect currentETEvaporation tubeExtra High2WLTC extra high speed phase for Class 2 vehiclesExtra High3WLTC extra high speed phase for Class 3 vehiclesFCHVFuel cell hybrid vehicleFIDFlame ionisation detectorFSDFull scale deflectionGCGas chromatographHEPAHigh efficiency particulate air (filter)HFIDHeated flame ionisation detectorHigh2WLTC high speed phase for Class 2 vehiclesHigh3-1WLTC high speed phase for Class 3 vehicles vmax < 120 with km/hHigh3-2WLTC high speed phase for Class 3 vehicles with vmax ≥ 120 km/hICEInternal combustion engineLoDLimit of detectionLoQLimit of quantificationLow1WLTC low speed phase for Class 1 vehiclesLow2WLTC low speed phase for Class 2 vehiclesLow3WLTC low speed phase for Class 3 vehiclesMedium1WLTC medium speed phase for Class 1 vehiclesMedium2WLTC medium speed phase for Class 2 vehiclesMedium3-1WLTC medium speed phase for Class 3 vehicles with vmax < 120 km/hMedium3-2WLTC medium speed phase for Class 3 vehicles with vmax ≥ 120 km/hLCLiquid chromatographyLPGLiquefied petroleum gasNDIRNon-dispersive infrared (analyser)NDUVNon-dispersive ultravioletNG/biomethaneNatural gas/biomethaneNMCNon-methane cutterNOVC-FCHVNot off-vehicle charging fuel cell hybrid vehicleNOVCNot off-vehicle chargingNOVC-HEVNot off-vehicle charging hybrid electric vehicleOVC-HEVOff-vehicle charging hybrid electric vehiclePaParticulate mass collected on the background filterPeParticulate mass collected on the sample filterPAOPoly-alpha-olefinPCFParticle pre-classifierPCRFParticle concentration reduction factorPDPPositive displacement pumpPERPure electric rangePer cent FSPer cent of full scalePMParticulate matter emissionsPNParticle number emissionsPNCParticle number counterPND1First particle number dilution devicePND2Second particle number dilution devicePTSParticle transfer systemPTTParticle transfer tubeQCL-IRInfrared quantum cascade laserRCDACharge-depleting actual rangeRCBREESS charge balanceREESSRechargeable electric energy storage systemSSVSubsonic venturiUSFMUltrasonic flow meterVPRVolatile particle removerWLTCWorldwide light-duty test cycle
 4.2. 
C1Carbon 1 equivalent hydrocarbonCH4MethaneC2H6EthaneC2H5OHEthanolC3H8PropaneCOCarbon monoxideCO2Carbon dioxideDOPDi-octylphthalateH2OWaterNH3AmmoniaNMHCNon-methane hydrocarbonsNOxOxides of nitrogenNONitric oxideNO2Nitrogen dioxideN2ONitrous oxideTHCTotal hydrocarbons

5.  5.0 Each of the vehicle families defined in paragraphs 5.6. to 5.9. shall be attributed an unique identifier of the following format:
FT-TA-WMI-yyyy-nnnn
Where:

— FT is an identifier of the family type:
— IP = Interpolation family as defined in paragraph 5.6.
— RL = Road load family as defined in paragraph 5.7.
— RM = Road load matrix family as defined in paragraph 5.8.
— PR = Periodically regenerating systems (Ki) family as defined in paragraph 5.9.
— TA is the distinguishing number of the authority responsible for the family approval as defined in section 1 of point 1 of Annex VII of Directive (EC) 2007/46
— WMI (world manufacturer identifier) is a code that identifies the manufacturer in a unique manner and is defined in ISO 3780:2009. For a single manufacturers several WMI codes may be used.
— yyyy is the year when the test for the family were concluded
— nnnn is a four digit sequence number
 5.1. The vehicle and its components liable to affect the emissions of gaseous compounds, particulate matter and particle number shall be so designed, constructed and assembled as to enable the vehicle in normal use and under normal conditions of use such as humidity, rain, snow, heat, cold, sand, dirt, vibrations, wear, etc. to comply with the provisions of this Annex during its useful life.
 5.1.1. This shall include the security of all hoses, joints and connections used within the emission control systems.
 5.2. The test vehicle shall be representative in terms of its emissions-related components and functionality of the intended production series to be covered by the approval. The manufacturer and the approval authority shall agree which vehicle test model is representative.
 5.3.  5.3.1. The types and amounts of lubricants and coolant for emissions testing shall be as specified for normal vehicle operation by the manufacturer.
 5.3.2. The type of fuel for emissions testing shall be as specified in Annex IX.
 5.3.3. All emissions controlling systems shall be in working order.
 5.3.4. The use of any defeat device is prohibited, according to the provisions of Article 5(2) of Regulation (EC) No 715/2007.
 5.3.5. The engine shall be designed to avoid crankcase emissions.
 5.3.6. The tyres used for emissions testing shall be as defined in paragraph 1.2.4.5. of Sub-Annex 6 to this Annex.
 5.4.  5.4.1. Subject to paragraph 5.4.2., the inlet orifice of the petrol or ethanol tank shall be so designed as to prevent the tank from being filled from a fuel pump delivery nozzle that has an external diameter of 23.6 mm or greater.
 5.4.2. 

((a)) The vehicle is so designed and constructed that no device designed to control the emissions shall be adversely affected by leaded petrol; and
((b)) The vehicle is conspicuously, legibly and indelibly marked with the symbol for unleaded petrol, specified in ISO 2575:2010 ‘Road vehicles – Symbols for controls, indicators and tell-tales’, in a position immediately visible to a person filling the petrol tank. Additional markings are permitted.
 5.5.  5.5.1. Any vehicle with an emission control computer shall include features to deter modification, except as authorised by the manufacturer. The manufacturer shall authorise modifications if these modifications are necessary for the diagnosis, servicing, inspection, retrofitting or repair of the vehicle. Any reprogrammable computer codes or operating parameters shall be resistant to tampering and afford a level of protection at least as good as the provisions in ISO 15031-7 (March 15, 2001). Any removable calibration memory chips shall be potted, encased in a sealed container or protected by electronic algorithms and shall not be changeable without the use of specialized tools and procedures.
 5.5.2. Computer-coded engine operating parameters shall not be changeable without the use of specialized tools and procedures (e.g. soldered or potted computer components or sealed (or soldered) enclosures).
 5.5.3. Manufacturers may seek approval from the approval authority for an exemption to one of these requirements for those vehicles that are unlikely to require protection. The criteria that the approval authority shall evaluate in considering an exemption shall include, but are not limited to, the current availability of performance chips, the high-performance capability of the vehicle and the projected sales volume of the vehicle.
 5.5.4. Manufacturers using programmable computer code systems shall deter unauthorised reprogramming. Manufacturers shall include enhanced tamper protection strategies and write-protect features requiring electronic access to an off-site computer maintained by the manufacturer, to which independent operators shall also have access using the protection afforded in paragraph 5.5.1. and Section 2.2. of Annex XIV. Methods giving an adequate level of tamper protection will be approved by the approval authority.
 5.6.  5.6.1. 
Only vehicles that are identical with respect to the following vehicle/powertrain/transmission characteristics may be part of the same interpolation family:


((a)) Type of internal combustion engine: fuel type, combustion type, engine displacement, full-load characteristics, engine technology, and charging system, and also other engine subsystems or characteristics that have a non-negligible influence on CO2 mass emission under WLTP conditions;
((b)) Operation strategy of all CO2 mass emission influencing components within the powertrain;
((c)) Transmission type (e.g. manual, automatic, CVT) and transmission model (e.g. torque rating, number of gears, number of clutches, etc.);
((d)) n/v ratios (engine rotational speed divided by vehicle speed). This requirement shall be considered fulfilled if, for all transmission ratios concerned, the difference with respect to the transmission ratios of the most commonly installed transmission type is within 8 per cent;
((e)) Number of powered axles;
((f)) ATCT family.

Vehicles may only be part of the same interpolation family if they belong to the same vehicle class as described in paragraph 2 of Sub-Annex 1.
 5.6.2. 
In addition to the requirements of paragraph 5.6.1., only OVC-HEVs and NOVC-HEVs that are identical with respect to the following characteristics may be part of the same interpolation family:


((a)) Type and number of electric machines (construction type (asynchronous/ synchronous, etc..), type of coolant (air, liquid,) and any other characteristics having a non-negligible influence on CO2 mass emission and electric energy consumption under WLTP conditions;
((b)) Type of traction REESS (model, capacity, nominal voltage, nominal power, type of coolant (air, liquid));
((c)) Type of energy converter between the electric machine and traction REESS, between the traction REESS and low voltage power supply and between the recharge-plug-in and traction REESS, and any other characteristics having a non-negligible influence on CO2 mass emission and electric energy consumption under WLTP conditions.
((d)) The difference between the number of charge-depleting cycles from the beginning of the test up to and including the transition cycle shall not be more than one.
 5.6.3. 
Only PEVs that are identical with respect to the following electric powertrain/transmission characteristics may be part of the same interpolation family:


((a)) Type and number of electric machines (construction type (asynchronous/ synchronous, etc.), type of coolant (air, liquid) and any other characteristics having a non-negligible influence on electric energy consumption and range under WLTP conditions;
((b)) Type of traction REESS (model, capacity, nominal voltage, nominal power, type of coolant (air, liquid));
((c)) Transmission type (e.g. manual, automatic, CVT) and transmission model (e.g. torque rating, number of gears, numbers of clutches, etc.);
((d)) Number of powered axles;
((e)) Type of electric converter between the electric machine and traction REESS, between the traction REESS and low voltage power supply and between the recharge-plug-in and traction REESS, and any other characteristics having a non-negligible influence on electric energy consumption and range under WLTP conditions;
((f)) Operation strategy of all components influencing the electric energy consumption within the powertrain;
((g)) n/v ratios (engine rotational speed divided by vehicle speed). This requirement shall be considered fulfilled if, for all transmission ratios concerned, the difference with respect to the transmission ratios of the most commonly installed transmission type and model is within 8 per cent.
 5.7. 
Only vehicles that are identical with respect to the following characteristics may be part of the same road load family:


((a)) Transmission type (e.g. manual, automatic, CVT) and transmission model (e.g. torque rating, number of gears, number of clutches, etc.). At the request of the manufacturer and with approval of the approval authority, a transmission with lower power losses may be included in the family;
((b)) n/v ratios (engine rotational speed divided by vehicle speed). This requirement shall be considered fulfilled if, for all transmission ratios concerned, the difference with respect to the transmission ratios of the most commonly installed transmission type is within 25 per cent;
((c)) Number of powered axles;
((d)) If at least one electric machine is coupled in the gearbox position neutral and the vehicle is not equipped with a coastdown mode (paragraph 4.2.1.8.5. of Sub-Annex 4) such that the electric machine has no influence on the road load, the criteria from paragraph 5.6.2. (a) and paragraph 5.6.3. (a) shall apply.

If there is a difference, apart from vehicle mass, rolling resistance and aerodynamics, that has a non-negligible influence on road load, that vehicle shall not be considered to be part of the family unless approved by the approval authority.
 5.8. 
The road load matrix family may be applied for vehicles designed for a technically permissible maximum laden mass ≥ 3 000 kg.

Only vehicles which are identical with respect to the following characteristics may be part of the same road load matrix family:


((a)) Transmission type (e.g. manual, automatic, CVT);
((b)) Number of powered axles.
 5.9. 
Only vehicles that are identical with respect to the following characteristics may be part of the same periodically regenerating systems family:


5.9.1. Type of internal combustion engine: fuel type, combustion type,
5.9.2. Periodically regenerating system (i.e. catalyst, particulate trap);

((a)) Construction (i.e. type of enclosure, type of precious metal, type of substrate, cell density);
((b)) Type and working principle;
((c)) Volume ±10 per cent;
((d)) Location (temperature ± 100 °C at 2nd highest reference speed);
((e)) The test mass of each vehicle in the family must be less than or equal to the test mass of the vehicle used for the Ki demonstration test plus 250 kg.

6.  6.1. 
Limit values for emissions shall be those specified in Annex I of Regulation (EC) No 715/2007.
 6.2. 
Testing shall be performed according to:


((a)) The WLTCs as described in Sub-Annex 1;
((b)) The gear selection and shift point determination as described in Sub-Annex 2;
((c)) The appropriate fuel as described in Annex IX of this Regulation;
((d)) The road load and dynamometer settings as described in Sub-Annex 4;
((e)) The test equipment as described in Sub-Annex 5;
((f)) The test procedures as described in Sub-Annexes 6 and 8;
((g)) The methods of calculation as described in Sub-Annexes 7 and 8.

Sub-Annex 1
1.  1.1. 
The cycle resulting from the requirements described in this Sub-Annex shall be referred to in other parts of the Annex as the ‘applicable cycle’.

2.  2.1. Class 1 vehicles have a power to mass in running order ratio Pmr ≤ 22 W/kg.
 2.2. Class 2 vehicles have a power to mass in running order ratio > 22 but ≤ 34 W/kg.
 2.3. Class 3 vehicles have a power to mass in running order ratio > 34 W/kg.
 2.3.1. All vehicles tested according to Sub-Annex 8 shall be considered to be Class 3 vehicles.

3.  3.1.  3.1.1. A complete cycle for Class 1 vehicles shall consist of a low phase (Low1), a medium phase (Medium1) and an additional low phase (Low1).
 3.1.2. The Low1 phase is described in Figure A1/1 and Table A1/1.
 3.1.3. The Medium1 phase is described in Figure A1/2 and Table A1/2.
 3.2.  3.2.1. A complete cycle for Class 2 vehicles shall consist of a low phase (Low2), a medium phase (Medium2), a high phase (High2) and an extra high phase (Extra High2).
 3.2.2. The Low2 phase is described in Figure A1/3 and Table A1/3.
 3.2.3. The Medium2 phase is described in Figure A1/4 and Table A1/4.
 3.2.4. The High2 phase is described in Figure A1/5 and Table A1/5.
 3.2.5. The Extra High2 phase is described in Figure A1/6 and Table A1/6.
 3.3. 
Class 3 vehicles are divided into 2 subclasses according to their maximum speed, vmax.
 3.3.1.  3.3.1.1. A complete cycle shall consist of a low phase (Low3), a medium phase (Medium3-1), a high phase (High3-1) and an extra high phase (Extra High3).
 3.3.1.2. The Low3 phase is described in Figure A1/7 and Table A1/7.
 3.3.1.3. The Medium3-1 phase is described in Figure A1/8 and Table A1/8.
 3.3.1.4. The High3-1 phase is described in Figure A1/10 and Table A1/10.
 3.3.1.5. The Extra High3 phase is described in Figure A1/12 and Table A1/12.
 3.3.2.  3.3.2.1. A complete cycle shall consist of a low phase (Low3) phase, a medium phase (Medium3-2), a high phase (High3-2) and an extra high phase (Extra High3).
 3.3.2.2. The Low3 phase is described in Figure A1/7 and Table A1/7.
 3.3.2.3. The Medium3-2 phase is described in Figure A1/9 and Table A1/9.
 3.3.2.4. The High3-2 phase is described in Figure A1/11 and Table A1/11.
 3.3.2.5. The Extra High3 phase is described in Figure A1/12 and Table A1/12.
 3.4.  3.4.1. All low speed phases last 589 seconds.
 3.4.2. All medium speed phases last 433 seconds.
 3.4.3. All high speed phases last 455 seconds.
 3.4.4. All extra high speed phases last 323 seconds.
 3.5. 
OVC-HEVs and PEVs shall be tested using the WLTC and WLTC city cycles (see Sub-Annex 8) for Class 3a and Class 3b vehicles.

The WLTC city cycle consists of the low and medium speed phases only.

4. 
Figure A1/1
Figure A1/2

Time in s Speed in km/h
0 0,0
1 0,0
2 0,0
3 0,0
4 0,0
5 0,0
6 0,0
7 0,0
8 0,0
9 0,0
10 0,0
11 0,0
12 0,2
13 3,1
14 5,7
15 8,0
16 10,1
17 12,0
18 13,8
19 15,4
20 16,7
21 17,7
22 18,3
23 18,8
24 18,9
25 18,4
26 16,9
27 14,3
28 10,8
29 7,1
30 4,0
31 0,0
32 0,0
33 0,0
34 0,0
35 1,5
36 3,8
37 5,6
38 7,5
39 9,2
40 10,8
41 12,4
42 13,8
43 15,2
44 16,3
45 17,3
46 18,0
47 18,8
48 19,5
49 20,2
50 20,9
51 21,7
52 22,4
53 23,1
54 23,7
55 24,4
56 25,1
57 25,4
58 25,2
59 23,4
60 21,8
61 19,7
62 17,3
63 14,7
64 12,0
65 9,4
66 5,6
67 3,1
68 0,0
69 0,0
70 0,0
71 0,0
72 0,0
73 0,0
74 0,0
75 0,0
76 0,0
77 0,0
78 0,0
79 0,0
80 0,0
81 0,0
82 0,0
83 0,0
84 0,0
85 0,0
86 0,0
87 0,0
88 0,0
89 0,0
90 0,0
91 0,0
92 0,0
93 0,0
94 0,0
95 0,0
96 0,0
97 0,0
98 0,0
99 0,0
100 0,0
101 0,0
102 0,0
103 0,0
104 0,0
105 0,0
106 0,0
107 0,0
108 0,7
109 1,1
110 1,9
111 2,5
112 3,5
113 4,7
114 6,1
115 7,5
116 9,4
117 11,0
118 12,9
119 14,5
120 16,4
121 18,0
122 20,0
123 21,5
124 23,5
125 25,0
126 26,8
127 28,2
128 30,0
129 31,4
130 32,5
131 33,2
132 33,4
133 33,7
134 33,9
135 34,2
136 34,4
137 34,7
138 34,9
139 35,2
140 35,4
141 35,7
142 35,9
143 36,6
144 37,5
145 38,4
146 39,3
147 40,0
148 40,6
149 41,1
150 41,4
151 41,6
152 41,8
153 41,8
154 41,9
155 41,9
156 42,0
157 42,0
158 42,2
159 42,3
160 42,6
161 43,0
162 43,3
163 43,7
164 44,0
165 44,3
166 44,5
167 44,6
168 44,6
169 44,5
170 44,4
171 44,3
172 44,2
173 44,1
174 44,0
175 43,9
176 43,8
177 43,7
178 43,6
179 43,5
180 43,4
181 43,3
182 43,1
183 42,9
184 42,7
185 42,5
186 42,3
187 42,2
188 42,2
189 42,2
190 42,3
191 42,4
192 42,5
193 42,7
194 42,9
195 43,1
196 43,2
197 43,3
198 43,4
199 43,4
200 43,2
201 42,9
202 42,6
203 42,2
204 41,9
205 41,5
206 41,0
207 40,5
208 39,9
209 39,3
210 38,7
211 38,1
212 37,5
213 36,9
214 36,3
215 35,7
216 35,1
217 34,5
218 33,9
219 33,6
220 33,5
221 33,6
222 33,9
223 34,3
224 34,7
225 35,1
226 35,5
227 35,9
228 36,4
229 36,9
230 37,4
231 37,9
232 38,3
233 38,7
234 39,1
235 39,3
236 39,5
237 39,7
238 39,9
239 40,0
240 40,1
241 40,2
242 40,3
243 40,4
244 40,5
245 40,5
246 40,4
247 40,3
248 40,2
249 40,1
250 39,7
251 38,8
252 37,4
253 35,6
254 33,4
255 31,2
256 29,1
257 27,6
258 26,6
259 26,2
260 26,3
261 26,7
262 27,5
263 28,4
264 29,4
265 30,4
266 31,2
267 31,9
268 32,5
269 33,0
270 33,4
271 33,8
272 34,1
273 34,3
274 34,3
275 33,9
276 33,3
277 32,6
278 31,8
279 30,7
280 29,6
281 28,6
282 27,8
283 27,0
284 26,4
285 25,8
286 25,3
287 24,9
288 24,5
289 24,2
290 24,0
291 23,8
292 23,6
293 23,5
294 23,4
295 23,3
296 23,3
297 23,2
298 23,1
299 23,0
300 22,8
301 22,5
302 22,1
303 21,7
304 21,1
305 20,4
306 19,5
307 18,5
308 17,6
309 16,6
310 15,7
311 14,9
312 14,3
313 14,1
314 14,0
315 13,9
316 13,8
317 13,7
318 13,6
319 13,5
320 13,4
321 13,3
322 13,2
323 13,2
324 13,2
325 13,4
326 13,5
327 13,7
328 13,8
329 14,0
330 14,1
331 14,3
332 14,4
333 14,4
334 14,4
335 14,3
336 14,3
337 14,0
338 13,0
339 11,4
340 10,2
341 8,0
342 7,0
343 6,0
344 5,5
345 5,0
346 4,5
347 4,0
348 3,5
349 3,0
350 2,5
351 2,0
352 1,5
353 1,0
354 0,5
355 0,0
356 0,0
357 0,0
358 0,0
359 0,0
360 0,0
361 2,2
362 4,5
363 6,6
364 8,6
365 10,6
366 12,5
367 14,4
368 16,3
369 17,9
370 19,1
371 19,9
372 20,3
373 20,5
374 20,7
375 21,0
376 21,6
377 22,6
378 23,7
379 24,8
380 25,7
381 26,2
382 26,4
383 26,4
384 26,4
385 26,5
386 26,6
387 26,8
388 26,9
389 27,2
390 27,5
391 28,0
392 28,8
393 29,9
394 31,0
395 31,9
396 32,5
397 32,6
398 32,4
399 32,0
400 31,3
401 30,3
402 28,0
403 27,0
404 24,0
405 22,5
406 19,0
407 17,5
408 14,0
409 12,5
410 9,0
411 7,5
412 4,0
413 2,9
414 0,0
415 0,0
416 0,0
417 0,0
418 0,0
419 0,0
420 0,0
421 0,0
422 0,0
423 0,0
424 0,0
425 0,0
426 0,0
427 0,0
428 0,0
429 0,0
430 0,0
431 0,0
432 0,0
433 0,0
434 0,0
435 0,0
436 0,0
437 0,0
438 0,0
439 0,0
440 0,0
441 0,0
442 0,0
443 0,0
444 0,0
445 0,0
446 0,0
447 0,0
448 0,0
449 0,0
450 0,0
451 0,0
452 0,0
453 0,0
454 0,0
455 0,0
456 0,0
457 0,0
458 0,0
459 0,0
460 0,0
461 0,0
462 0,0
463 0,0
464 0,0
465 0,0
466 0,0
467 0,0
468 0,0
469 0,0
470 0,0
471 0,0
472 0,0
473 0,0
474 0,0
475 0,0
476 0,0
477 0,0
478 0,0
479 0,0
480 0,0
481 1,6
482 3,1
483 4,6
484 6,1
485 7,8
486 9,5
487 11,3
488 13,2
489 15,0
490 16,8
491 18,4
492 20,1
493 21,6
494 23,1
495 24,6
496 26,0
497 27,5
498 29,0
499 30,6
500 32,1
501 33,7
502 35,3
503 36,8
504 38,1
505 39,3
506 40,4
507 41,2
508 41,9
509 42,6
510 43,3
511 44,0
512 44,6
513 45,3
514 45,5
515 45,5
516 45,2
517 44,7
518 44,2
519 43,6
520 43,1
521 42,8
522 42,7
523 42,8
524 43,3
525 43,9
526 44,6
527 45,4
528 46,3
529 47,2
530 47,8
531 48,2
532 48,5
533 48,7
534 48,9
535 49,1
536 49,1
537 49,0
538 48,8
539 48,6
540 48,5
541 48,4
542 48,3
543 48,2
544 48,1
545 47,5
546 46,7
547 45,7
548 44,6
549 42,9
550 40,8
551 38,2
552 35,3
553 31,8
554 28,7
555 25,8
556 22,9
557 20,2
558 17,3
559 15,0
560 12,3
561 10,3
562 7,8
563 6,5
564 4,4
565 3,2
566 1,2
567 0,0
568 0,0
569 0,0
570 0,0
571 0,0
572 0,0
573 0,0
574 0,0
575 0,0
576 0,0
577 0,0
578 0,0
579 0,0
580 0,0
581 0,0
582 0,0
583 0,0
584 0,0
585 0,0
586 0,0
587 0,0
588 0,0
589 0,0


Time in s Speed in km/h
590 0,0
591 0,0
592 0,0
593 0,0
594 0,0
595 0,0
596 0,0
597 0,0
598 0,0
599 0,0
600 0,6
601 1,9
602 2,7
603 5,2
604 7,0
605 9,6
606 11,4
607 14,1
608 15,8
609 18,2
610 19,7
611 21,8
612 23,2
613 24,7
614 25,8
615 26,7
616 27,2
617 27,7
618 28,1
619 28,4
620 28,7
621 29,0
622 29,2
623 29,4
624 29,4
625 29,3
626 28,9
627 28,5
628 28,1
629 27,6
630 26,9
631 26,0
632 24,6
633 22,8
634 21,0
635 19,5
636 18,6
637 18,4
638 19,0
639 20,1
640 21,5
641 23,1
642 24,9
643 26,4
644 27,9
645 29,2
646 30,4
647 31,6
648 32,8
649 34,0
650 35,1
651 36,3
652 37,4
653 38,6
654 39,6
655 40,6
656 41,6
657 42,4
658 43,0
659 43,6
660 44,0
661 44,4
662 44,8
663 45,2
664 45,6
665 46,0
666 46,5
667 47,0
668 47,5
669 48,0
670 48,6
671 49,1
672 49,7
673 50,2
674 50,8
675 51,3
676 51,8
677 52,3
678 52,9
679 53,4
680 54,0
681 54,5
682 55,1
683 55,6
684 56,2
685 56,7
686 57,3
687 57,9
688 58,4
689 58,8
690 58,9
691 58,4
692 58,1
693 57,6
694 56,9
695 56,3
696 55,7
697 55,3
698 55,0
699 54,7
700 54,5
701 54,4
702 54,3
703 54,2
704 54,1
705 53,8
706 53,5
707 53,0
708 52,6
709 52,2
710 51,9
711 51,7
712 51,7
713 51,8
714 52,0
715 52,3
716 52,6
717 52,9
718 53,1
719 53,2
720 53,3
721 53,3
722 53,4
723 53,5
724 53,7
725 54,0
726 54,4
727 54,9
728 55,6
729 56,3
730 57,1
731 57,9
732 58,8
733 59,6
734 60,3
735 60,9
736 61,3
737 61,7
738 61,8
739 61,8
740 61,6
741 61,2
742 60,8
743 60,4
744 59,9
745 59,4
746 58,9
747 58,6
748 58,2
749 57,9
750 57,7
751 57,5
752 57,2
753 57,0
754 56,8
755 56,6
756 56,6
757 56,7
758 57,1
759 57,6
760 58,2
761 59,0
762 59,8
763 60,6
764 61,4
765 62,2
766 62,9
767 63,5
768 64,2
769 64,4
770 64,4
771 64,0
772 63,5
773 62,9
774 62,4
775 62,0
776 61,6
777 61,4
778 61,2
779 61,0
780 60,7
781 60,2
782 59,6
783 58,9
784 58,1
785 57,2
786 56,3
787 55,3
788 54,4
789 53,4
790 52,4
791 51,4
792 50,4
793 49,4
794 48,5
795 47,5
796 46,5
797 45,4
798 44,3
799 43,1
800 42,0
801 40,8
802 39,7
803 38,8
804 38,1
805 37,4
806 37,1
807 36,9
808 37,0
809 37,5
810 37,8
811 38,2
812 38,6
813 39,1
814 39,6
815 40,1
816 40,7
817 41,3
818 41,9
819 42,7
820 43,4
821 44,2
822 45,0
823 45,9
824 46,8
825 47,7
826 48,7
827 49,7
828 50,6
829 51,6
830 52,5
831 53,3
832 54,1
833 54,7
834 55,3
835 55,7
836 56,1
837 56,4
838 56,7
839 57,1
840 57,5
841 58,0
842 58,7
843 59,3
844 60,0
845 60,6
846 61,3
847 61,5
848 61,5
849 61,4
850 61,2
851 60,5
852 60,0
853 59,5
854 58,9
855 58,4
856 57,9
857 57,5
858 57,1
859 56,7
860 56,4
861 56,1
862 55,8
863 55,5
864 55,3
865 55,0
866 54,7
867 54,4
868 54,2
869 54,0
870 53,9
871 53,7
872 53,6
873 53,5
874 53,4
875 53,3
876 53,2
877 53,1
878 53,0
879 53,0
880 53,0
881 53,0
882 53,0
883 53,0
884 52,8
885 52,5
886 51,9
887 51,1
888 50,2
889 49,2
890 48,2
891 47,3
892 46,4
893 45,6
894 45,0
895 44,3
896 43,8
897 43,3
898 42,8
899 42,4
900 42,0
901 41,6
902 41,1
903 40,3
904 39,5
905 38,6
906 37,7
907 36,7
908 36,2
909 36,0
910 36,2
911 37,0
912 38,0
913 39,0
914 39,7
915 40,2
916 40,7
917 41,2
918 41,7
919 42,2
920 42,7
921 43,2
922 43,6
923 44,0
924 44,2
925 44,4
926 44,5
927 44,6
928 44,7
929 44,6
930 44,5
931 44,4
932 44,2
933 44,1
934 43,7
935 43,3
936 42,8
937 42,3
938 41,6
939 40,7
940 39,8
941 38,8
942 37,8
943 36,9
944 36,1
945 35,5
946 35,0
947 34,7
948 34,4
949 34,1
950 33,9
951 33,6
952 33,3
953 33,0
954 32,7
955 32,3
956 31,9
957 31,5
958 31,0
959 30,6
960 30,2
961 29,7
962 29,1
963 28,4
964 27,6
965 26,8
966 26,0
967 25,1
968 24,2
969 23,3
970 22,4
971 21,5
972 20,6
973 19,7
974 18,8
975 17,7
976 16,4
977 14,9
978 13,2
979 11,3
980 9,4
981 7,5
982 5,6
983 3,7
984 1,9
985 1,0
986 0,0
987 0,0
988 0,0
989 0,0
990 0,0
991 0,0
992 0,0
993 0,0
994 0,0
995 0,0
996 0,0
997 0,0
998 0,0
999 0,0
1000 0,0
1001 0,0
1002 0,0
1003 0,0
1004 0,0
1005 0,0
1006 0,0
1007 0,0
1008 0,0
1009 0,0
1010 0,0
1011 0,0
1012 0,0
1013 0,0
1014 0,0
1015 0,0
1016 0,0
1017 0,0
1018 0,0
1019 0,0
1020 0,0
1021 0,0
1022 0,0

5. 
Figure A1/3
Figure A1/4
Figure A1/5
Figure A1/6

Time in s Speed in km/h
0 0,0
1 0,0
2 0,0
3 0,0
4 0,0
5 0,0
6 0,0
7 0,0
8 0,0
9 0,0
10 0,0
11 0,0
12 0,0
13 1,2
14 2,6
15 4,9
16 7,3
17 9,4
18 11,4
19 12,7
20 13,3
21 13,4
22 13,3
23 13,1
24 12,5
25 11,1
26 8,9
27 6,2
28 3,8
29 1,8
30 0,0
31 0,0
32 0,0
33 0,0
34 1,5
35 2,8
36 3,6
37 4,5
38 5,3
39 6,0
40 6,6
41 7,3
42 7,9
43 8,6
44 9,3
45 10
46 10,8
47 11,6
48 12,4
49 13,2
50 14,2
51 14,8
52 14,7
53 14,4
54 14,1
55 13,6
56 13,0
57 12,4
58 11,8
59 11,2
60 10,6
61 9,9
62 9,0
63 8,2
64 7,0
65 4,8
66 2,3
67 0,0
68 0,0
69 0,0
70 0,0
71 0,0
72 0,0
73 0,0
74 0,0
75 0,0
76 0,0
77 0,0
78 0,0
79 0,0
80 0,0
81 0,0
82 0,0
83 0,0
84 0,0
85 0,0
86 0,0
87 0,0
88 0,0
89 0,0
90 0,0
91 0,0
92 0,0
93 0,0
94 0,0
95 0,0
96 0,0
97 0,0
98 0,0
99 0,0
100 0,0
101 0,0
102 0,0
103 0,0
104 0,0
105 0,0
106 0,0
107 0,8
108 1,4
109 2,3
110 3,5
111 4,7
112 5,9
113 7,4
114 9,2
115 11,7
116 13,5
117 15,0
118 16,2
119 16,8
120 17,5
121 18,8
122 20,3
123 22,0
124 23,6
125 24,8
126 25,6
127 26,3
128 27,2
129 28,3
130 29,6
131 30,9
132 32,2
133 33,4
134 35,1
135 37,2
136 38,7
137 39,0
138 40,1
139 40,4
140 39,7
141 36,8
142 35,1
143 32,2
144 31,1
145 30,8
146 29,7
147 29,4
148 29,0
149 28,5
150 26,0
151 23,4
152 20,7
153 17,4
154 15,2
155 13,5
156 13,0
157 12,4
158 12,3
159 12,2
160 12,3
161 12,4
162 12,5
163 12,7
164 12,8
165 13,2
166 14,3
167 16,5
168 19,4
169 21,7
170 23,1
171 23,5
172 24,2
173 24,8
174 25,4
175 25,8
176 26,5
177 27,2
178 28,3
179 29,9
180 32,4
181 35,1
182 37,5
183 39,2
184 40,5
185 41,4
186 42,0
187 42,5
188 43,2
189 44,4
190 45,9
191 47,6
192 49,0
193 50,0
194 50,2
195 50,1
196 49,8
197 49,4
198 48,9
199 48,5
200 48,3
201 48,2
202 47,9
203 47,1
204 45,5
205 43,2
206 40,6
207 38,5
208 36,9
209 35,9
210 35,3
211 34,8
212 34,5
213 34,2
214 34,0
215 33,8
216 33,6
217 33,5
218 33,5
219 33,4
220 33,3
221 33,3
222 33,2
223 33,1
224 33,0
225 32,9
226 32,8
227 32,7
228 32,5
229 32,3
230 31,8
231 31,4
232 30,9
233 30,6
234 30,6
235 30,7
236 32,0
237 33,5
238 35,8
239 37,6
240 38,8
241 39,6
242 40,1
243 40,9
244 41,8
245 43,3
246 44,7
247 46,4
248 47,9
249 49,6
250 49,6
251 48,8
252 48,0
253 47,5
254 47,1
255 46,9
256 45,8
257 45,8
258 45,8
259 45,9
260 46,2
261 46,4
262 46,6
263 46,8
264 47,0
265 47,3
266 47,5
267 47,9
268 48,3
269 48,3
270 48,2
271 48,0
272 47,7
273 47,2
274 46,5
275 45,2
276 43,7
277 42,0
278 40,4
279 39,0
280 37,7
281 36,4
282 35,2
283 34,3
284 33,8
285 33,3
286 32,5
287 30,9
288 28,6
289 25,9
290 23,1
291 20,1
292 17,3
293 15,1
294 13,7
295 13,4
296 13,9
297 15,0
298 16,3
299 17,4
300 18,2
301 18,6
302 19,0
303 19,4
304 19,8
305 20,1
306 20,5
307 20,2
308 18,6
309 16,5
310 14,4
311 13,4
312 12,9
313 12,7
314 12,4
315 12,4
316 12,8
317 14,1
318 16,2
319 18,8
320 21,9
321 25,0
322 28,4
323 31,3
324 34,0
325 34,6
326 33,9
327 31,9
328 30,0
329 29,0
330 27,9
331 27,1
332 26,4
333 25,9
334 25,5
335 25,0
336 24,6
337 23,9
338 23,0
339 21,8
340 20,7
341 19,6
342 18,7
343 18,1
344 17,5
345 16,7
346 15,4
347 13,6
348 11,2
349 8,6
350 6,0
351 3,1
352 1,2
353 0,0
354 0,0
355 0,0
356 0,0
357 0,0
358 0,0
359 0,0
360 1,4
361 3,2
362 5,6
363 8,1
364 10,3
365 12,1
366 12,6
367 13,6
368 14,5
369 15,6
370 16,8
371 18,2
372 19,6
373 20,9
374 22,3
375 23,8
376 25,4
377 27,0
378 28,6
379 30,2
380 31,2
381 31,2
382 30,7
383 29,5
384 28,6
385 27,7
386 26,9
387 26,1
388 25,4
389 24,6
390 23,6
391 22,6
392 21,7
393 20,7
394 19,8
395 18,8
396 17,7
397 16,6
398 15,6
399 14,8
400 14,3
401 13,8
402 13,4
403 13,1
404 12,8
405 12,3
406 11,6
407 10,5
408 9,0
409 7,2
410 5,2
411 2,9
412 1,2
413 0,0
414 0,0
415 0,0
416 0,0
417 0,0
418 0,0
419 0,0
420 0,0
421 0,0
422 0,0
423 0,0
424 0,0
425 0,0
426 0,0
427 0,0
428 0,0
429 0,0
430 0,0
431 0,0
432 0,0
433 0,0
434 0,0
435 0,0
436 0,0
437 0,0
438 0,0
439 0,0
440 0,0
441 0,0
442 0,0
443 0,0
444 0,0
445 0,0
446 0,0
447 0,0
448 0,0
449 0,0
450 0,0
451 0,0
452 0,0
453 0,0
454 0,0
455 0,0
456 0,0
457 0,0
458 0,0
459 0,0
460 0,0
461 0,0
462 0,0
463 0,0
464 0,0
465 0,0
466 0,0
467 0,0
468 0,0
469 0,0
470 0,0
471 0,0
472 0,0
473 0,0
474 0,0
475 0,0
476 0,0
477 0,0
478 0,0
479 0,0
480 0,0
481 1,4
482 2,5
483 5,2
484 7,9
485 10,3
486 12,7
487 15,0
488 17,4
489 19,7
490 21,9
491 24,1
492 26,2
493 28,1
494 29,7
495 31,3
496 33,0
497 34,7
498 36,3
499 38,1
500 39,4
501 40,4
502 41,2
503 42,1
504 43,2
505 44,3
506 45,7
507 45,4
508 44,5
509 42,5
510 39,5
511 36,5
512 33,5
513 30,4
514 27,0
515 23,6
516 21,0
517 19,5
518 17,6
519 16,1
520 14,5
521 13,5
522 13,7
523 16,0
524 18,1
525 20,8
526 21,5
527 22,5
528 23,4
529 24,5
530 25,6
531 26,0
532 26,5
533 26,9
534 27,3
535 27,9
536 30,3
537 33,2
538 35,4
539 38,0
540 40,1
541 42,7
542 44,5
543 46,3
544 47,6
545 48,8
546 49,7
547 50,6
548 51,4
549 51,4
550 50,2
551 47,1
552 44,5
553 41,5
554 38,5
555 35,5
556 32,5
557 29,5
558 26,5
559 23,5
560 20,4
561 17,5
562 14,5
563 11,5
564 8,5
565 5,6
566 2,6
567 0,0
568 0,0
569 0,0
570 0,0
571 0,0
572 0,0
573 0,0
574 0,0
575 0,0
576 0,0
577 0,0
578 0,0
579 0,0
580 0,0
581 0,0
582 0,0
583 0,0
584 0,0
585 0,0
586 0,0
587 0,0
588 0,0
589 0,0


Time in s Speed in km/h
590 0,0
591 0,0
592 0,0
593 0,0
594 0,0
595 0,0
596 0,0
597 0,0
598 0,0
599 0,0
600 0,0
601 1,6
602 3,6
603 6,3
604 9,0
605 11,8
606 14,2
607 16,6
608 18,5
609 20,8
610 23,4
611 26,9
612 30,3
613 32,8
614 34,1
615 34,2
616 33,6
617 32,1
618 30,0
619 27,5
620 25,1
621 22,8
622 20,5
623 17,9
624 15,1
625 13,4
626 12,8
627 13,7
628 16,0
629 18,1
630 20,8
631 23,7
632 26,5
633 29,3
634 32,0
635 34,5
636 36,8
637 38,6
638 39,8
639 40,6
640 41,1
641 41,9
642 42,8
643 44,3
644 45,7
645 47,4
646 48,9
647 50,6
648 52,0
649 53,7
650 55,0
651 56,8
652 58,0
653 59,8
654 61,1
655 62,4
656 63,0
657 63,5
658 63,0
659 62,0
660 60,4
661 58,6
662 56,7
663 55,0
664 53,7
665 52,7
666 51,9
667 51,4
668 51,0
669 50,7
670 50,6
671 50,8
672 51,2
673 51,7
674 52,3
675 53,1
676 53,8
677 54,5
678 55,1
679 55,9
680 56,5
681 57,1
682 57,8
683 58,5
684 59,3
685 60,2
686 61,3
687 62,4
688 63,4
689 64,4
690 65,4
691 66,3
692 67,2
693 68,0
694 68,8
695 69,5
696 70,1
697 70,6
698 71,0
699 71,6
700 72,2
701 72,8
702 73,5
703 74,1
704 74,3
705 74,3
706 73,7
707 71,9
708 70,5
709 68,9
710 67,4
711 66,0
712 64,7
713 63,7
714 62,9
715 62,2
716 61,7
717 61,2
718 60,7
719 60,3
720 59,9
721 59,6
722 59,3
723 59,0
724 58,6
725 58,0
726 57,5
727 56,9
728 56,3
729 55,9
730 55,6
731 55,3
732 55,1
733 54,8
734 54,6
735 54,5
736 54,3
737 53,9
738 53,4
739 52,6
740 51,5
741 50,2
742 48,7
743 47,0
744 45,1
745 43,0
746 40,6
747 38,1
748 35,4
749 32,7
750 30,0
751 27,5
752 25,3
753 23,4
754 22,0
755 20,8
756 19,8
757 18,9
758 18,0
759 17,0
760 16,1
761 15,5
762 14,4
763 14,9
764 15,9
765 17,1
766 18,3
767 19,4
768 20,4
769 21,2
770 21,9
771 22,7
772 23,4
773 24,2
774 24,3
775 24,2
776 24,1
777 23,8
778 23,0
779 22,6
780 21,7
781 21,3
782 20,3
783 19,1
784 18,1
785 16,9
786 16,0
787 14,8
788 14,5
789 13,7
790 13,5
791 12,9
792 12,7
793 12,5
794 12,5
795 12,6
796 13,0
797 13,6
798 14,6
799 15,7
800 17,1
801 18,7
802 20,2
803 21,9
804 23,6
805 25,4
806 27,1
807 28,9
808 30,4
809 32,0
810 33,4
811 35,0
812 36,4
813 38,1
814 39,7
815 41,6
816 43,3
817 45,1
818 46,9
819 48,7
820 50,5
821 52,4
822 54,1
823 55,7
824 56,8
825 57,9
826 59,0
827 59,9
828 60,7
829 61,4
830 62,0
831 62,5
832 62,9
833 63,2
834 63,4
835 63,7
836 64,0
837 64,4
838 64,9
839 65,5
840 66,2
841 67,0
842 67,8
843 68,6
844 69,4
845 70,1
846 70,9
847 71,7
848 72,5
849 73,2
850 73,8
851 74,4
852 74,7
853 74,7
854 74,6
855 74,2
856 73,5
857 72,6
858 71,8
859 71,0
860 70,1
861 69,4
862 68,9
863 68,4
864 67,9
865 67,1
866 65,8
867 63,9
868 61,4
869 58,4
870 55,4
871 52,4
872 50,0
873 48,3
874 47,3
875 46,8
876 46,9
877 47,1
878 47,5
879 47,8
880 48,3
881 48,8
882 49,5
883 50,2
884 50,8
885 51,4
886 51,8
887 51,9
888 51,7
889 51,2
890 50,4
891 49,2
892 47,7
893 46,3
894 45,1
895 44,2
896 43,7
897 43,4
898 43,1
899 42,5
900 41,8
901 41,1
902 40,3
903 39,7
904 39,3
905 39,2
906 39,3
907 39,6
908 40,0
909 40,7
910 41,4
911 42,2
912 43,1
913 44,1
914 44,9
915 45,6
916 46,4
917 47,0
918 47,8
919 48,3
920 48,9
921 49,4
922 49,8
923 49,6
924 49,3
925 49,0
926 48,5
927 48,0
928 47,5
929 47,0
930 46,9
931 46,8
932 46,8
933 46,8
934 46,9
935 46,9
936 46,9
937 46,9
938 46,9
939 46,8
940 46,6
941 46,4
942 46,0
943 45,5
944 45,0
945 44,5
946 44,2
947 43,9
948 43,7
949 43,6
950 43,6
951 43,5
952 43,5
953 43,4
954 43,3
955 43,1
956 42,9
957 42,7
958 42,5
959 42,4
960 42,2
961 42,1
962 42,0
963 41,8
964 41,7
965 41,5
966 41,3
967 41,1
968 40,8
969 40,3
970 39,6
971 38,5
972 37,0
973 35,1
974 33,0
975 30,6
976 27,9
977 25,1
978 22,0
979 18,8
980 15,5
981 12,3
982 8,8
983 6,0
984 3,6
985 1,6
986 0,0
987 0,0
988 0,0
989 0,0
990 0,0
991 0,0
992 0,0
993 0,0
994 0,0
995 0,0
996 0,0
997 0,0
998 0,0
999 0,0
1000 0,0
1001 0,0
1002 0,0
1003 0,0
1004 0,0
1005 0,0
1006 0,0
1007 0,0
1008 0,0
1009 0,0
1010 0,0
1011 0,0
1012 0,0
1013 0,0
1014 0,0
1015 0,0
1016 0,0
1017 0,0
1018 0,0
1019 0,0
1020 0,0
1021 0,0
1022 0,0


Time in s Speed in km/h
1023 0,0
1024 0,0
1025 0,0
1026 0,0
1027 1,1
1028 3,0
1029 5,7
1030 8,4
1031 11,1
1032 14,0
1033 17,0
1034 20,1
1035 22,7
1036 23,6
1037 24,5
1038 24,8
1039 25,1
1040 25,3
1041 25,5
1042 25,7
1043 25,8
1044 25,9
1045 26,0
1046 26,1
1047 26,3
1048 26,5
1049 26,8
1050 27,1
1051 27,5
1052 28,0
1053 28,6
1054 29,3
1055 30,4
1056 31,8
1057 33,7
1058 35,8
1059 37,8
1060 39,5
1061 40,8
1062 41,8
1063 42,4
1064 43,0
1065 43,4
1066 44,0
1067 44,4
1068 45,0
1069 45,4
1070 46,0
1071 46,4
1072 47,0
1073 47,4
1074 48,0
1075 48,4
1076 49,0
1077 49,4
1078 50,0
1079 50,4
1080 50,8
1081 51,1
1082 51,3
1083 51,3
1084 51,3
1085 51,3
1086 51,3
1087 51,3
1088 51,3
1089 51,4
1090 51,6
1091 51,8
1092 52,1
1093 52,3
1094 52,6
1095 52,8
1096 52,9
1097 53,0
1098 53,0
1099 53,0
1100 53,1
1101 53,2
1102 53,3
1103 53,4
1104 53,5
1105 53,7
1106 55,0
1107 56,8
1108 58,8
1109 60,9
1110 63,0
1111 65,0
1112 66,9
1113 68,6
1114 70,1
1115 71,5
1116 72,8
1117 73,9
1118 74,9
1119 75,7
1120 76,4
1121 77,1
1122 77,6
1123 78,0
1124 78,2
1125 78,4
1126 78,5
1127 78,5
1128 78,6
1129 78,7
1130 78,9
1131 79,1
1132 79,4
1133 79,8
1134 80,1
1135 80,5
1136 80,8
1137 81,0
1138 81,2
1139 81,3
1140 81,2
1141 81,0
1142 80,6
1143 80,0
1144 79,1
1145 78,0
1146 76,8
1147 75,5
1148 74,1
1149 72,9
1150 71,9
1151 71,2
1152 70,9
1153 71,0
1154 71,5
1155 72,3
1156 73,2
1157 74,1
1158 74,9
1159 75,4
1160 75,5
1161 75,2
1162 74,5
1163 73,3
1164 71,7
1165 69,9
1166 67,9
1167 65,7
1168 63,5
1169 61,2
1170 59,0
1171 56,8
1172 54,7
1173 52,7
1174 50,9
1175 49,4
1176 48,1
1177 47,1
1178 46,5
1179 46,3
1180 46,5
1181 47,2
1182 48,3
1183 49,7
1184 51,3
1185 53,0
1186 54,9
1187 56,7
1188 58,6
1189 60,2
1190 61,6
1191 62,2
1192 62,5
1193 62,8
1194 62,9
1195 63,0
1196 63,0
1197 63,1
1198 63,2
1199 63,3
1200 63,5
1201 63,7
1202 63,9
1203 64,1
1204 64,3
1205 66,1
1206 67,9
1207 69,7
1208 71,4
1209 73,1
1210 74,7
1211 76,2
1212 77,5
1213 78,6
1214 79,7
1215 80,6
1216 81,5
1217 82,2
1218 83,0
1219 83,7
1220 84,4
1221 84,9
1222 85,1
1223 85,2
1224 84,9
1225 84,4
1226 83,6
1227 82,7
1228 81,5
1229 80,1
1230 78,7
1231 77,4
1232 76,2
1233 75,4
1234 74,8
1235 74,3
1236 73,8
1237 73,2
1238 72,4
1239 71,6
1240 70,8
1241 69,9
1242 67,9
1243 65,7
1244 63,5
1245 61,2
1246 59,0
1247 56,8
1248 54,7
1249 52,7
1250 50,9
1251 49,4
1252 48,1
1253 47,1
1254 46,5
1255 46,3
1256 45,1
1257 43,0
1258 40,6
1259 38,1
1260 35,4
1261 32,7
1262 30,0
1263 29,9
1264 30,0
1265 30,2
1266 30,4
1267 30,6
1268 31,6
1269 33,0
1270 33,9
1271 34,8
1272 35,7
1273 36,6
1274 37,5
1275 38,4
1276 39,3
1277 40,2
1278 40,8
1279 41,7
1280 42,4
1281 43,1
1282 43,6
1283 44,2
1284 44,8
1285 45,5
1286 46,3
1287 47,2
1288 48,1
1289 49,1
1290 50,0
1291 51,0
1292 51,9
1293 52,7
1294 53,7
1295 55,0
1296 56,8
1297 58,8
1298 60,9
1299 63,0
1300 65,0
1301 66,9
1302 68,6
1303 70,1
1304 71,0
1305 71,8
1306 72,8
1307 72,9
1308 73,0
1309 72,3
1310 71,9
1311 71,3
1312 70,9
1313 70,5
1314 70,0
1315 69,6
1316 69,2
1317 68,8
1318 68,4
1319 67,9
1320 67,5
1321 67,2
1322 66,8
1323 65,6
1324 63,3
1325 60,2
1326 56,2
1327 52,2
1328 48,4
1329 45,0
1330 41,6
1331 38,6
1332 36,4
1333 34,8
1334 34,2
1335 34,7
1336 36,3
1337 38,5
1338 41,0
1339 43,7
1340 46,5
1341 49,1
1342 51,6
1343 53,9
1344 56,0
1345 57,9
1346 59,7
1347 61,2
1348 62,5
1349 63,5
1350 64,3
1351 65,3
1352 66,3
1353 67,3
1354 68,3
1355 69,3
1356 70,3
1357 70,8
1358 70,8
1359 70,8
1360 70,9
1361 70,9
1362 70,9
1363 70,9
1364 71,0
1365 71,0
1366 71,1
1367 71,2
1368 71,3
1369 71,4
1370 71,5
1371 71,7
1372 71,8
1373 71,9
1374 71,9
1375 71,9
1376 71,9
1377 71,9
1378 71,9
1379 71,9
1380 72,0
1381 72,1
1382 72,4
1383 72,7
1384 73,1
1385 73,4
1386 73,8
1387 74,0
1388 74,1
1389 74,0
1390 73,0
1391 72,0
1392 71,0
1393 70,0
1394 69,0
1395 68,0
1396 67,7
1397 66,7
1398 66,6
1399 66,7
1400 66,8
1401 66,9
1402 66,9
1403 66,9
1404 66,9
1405 66,9
1406 66,9
1407 66,9
1408 67,0
1409 67,1
1410 67,3
1411 67,5
1412 67,8
1413 68,2
1414 68,6
1415 69,0
1416 69,3
1417 69,3
1418 69,2
1419 68,8
1420 68,2
1421 67,6
1422 67,4
1423 67,2
1424 66,9
1425 66,3
1426 65,4
1427 64,0
1428 62,4
1429 60,6
1430 58,6
1431 56,7
1432 54,8
1433 53,0
1434 51,3
1435 49,6
1436 47,8
1437 45,5
1438 42,8
1439 39,8
1440 36,5
1441 33,0
1442 29,5
1443 25,8
1444 22,1
1445 18,6
1446 15,3
1447 12,4
1448 9,6
1449 6,6
1450 3,8
1451 1,6
1452 0,0
1453 0,0
1454 0,0
1455 0,0
1456 0,0
1457 0,0
1458 0,0
1459 0,0
1460 0,0
1461 0,0
1462 0,0
1463 0,0
1464 0,0
1465 0,0
1466 0,0
1467 0,0
1468 0,0
1469 0,0
1470 0,0
1471 0,0
1472 0,0
1473 0,0
1474 0,0
1475 0,0
1476 0,0
1477 0,0


Time in s Speed in km/h
1478 0,0
1479 1,1
1480 2,3
1481 4,6
1482 6,5
1483 8,9
1484 10,9
1485 13,5
1486 15,2
1487 17,6
1488 19,3
1489 21,4
1490 23,0
1491 25,0
1492 26,5
1493 28,4
1494 29,8
1495 31,7
1496 33,7
1497 35,8
1498 38,1
1499 40,5
1500 42,2
1501 43,5
1502 44,5
1503 45,2
1504 45,8
1505 46,6
1506 47,4
1507 48,5
1508 49,7
1509 51,3
1510 52,9
1511 54,3
1512 55,6
1513 56,8
1514 57,9
1515 58,9
1516 59,7
1517 60,3
1518 60,7
1519 60,9
1520 61,0
1521 61,1
1522 61,4
1523 61,8
1524 62,5
1525 63,4
1526 64,5
1527 65,7
1528 66,9
1529 68,1
1530 69,1
1531 70,0
1532 70,9
1533 71,8
1534 72,6
1535 73,4
1536 74,0
1537 74,7
1538 75,2
1539 75,7
1540 76,4
1541 77,2
1542 78,2
1543 78,9
1544 79,9
1545 81,1
1546 82,4
1547 83,7
1548 85,4
1549 87,0
1550 88,3
1551 89,5
1552 90,5
1553 91,3
1554 92,2
1555 93,0
1556 93,8
1557 94,6
1558 95,3
1559 95,9
1560 96,6
1561 97,4
1562 98,1
1563 98,7
1564 99,5
1565 100,3
1566 101,1
1567 101,9
1568 102,8
1569 103,8
1570 105,0
1571 106,1
1572 107,4
1573 108,7
1574 109,9
1575 111,2
1576 112,3
1577 113,4
1578 114,4
1579 115,3
1580 116,1
1581 116,8
1582 117,4
1583 117,7
1584 118,2
1585 118,1
1586 117,7
1587 117,0
1588 116,1
1589 115,2
1590 114,4
1591 113,6
1592 113,0
1593 112,6
1594 112,2
1595 111,9
1596 111,6
1597 111,2
1598 110,7
1599 110,1
1600 109,3
1601 108,4
1602 107,4
1603 106,7
1604 106,3
1605 106,2
1606 106,4
1607 107,0
1608 107,5
1609 107,9
1610 108,4
1611 108,9
1612 109,5
1613 110,2
1614 110,9
1615 111,6
1616 112,2
1617 112,8
1618 113,3
1619 113,7
1620 114,1
1621 114,4
1622 114,6
1623 114,7
1624 114,7
1625 114,7
1626 114,6
1627 114,5
1628 114,5
1629 114,5
1630 114,7
1631 115,0
1632 115,6
1633 116,4
1634 117,3
1635 118,2
1636 118,8
1637 119,3
1638 119,6
1639 119,7
1640 119,5
1641 119,3
1642 119,2
1643 119,0
1644 118,8
1645 118,8
1646 118,8
1647 118,8
1648 118,8
1649 118,9
1650 119,0
1651 119,0
1652 119,1
1653 119,2
1654 119,4
1655 119,6
1656 119,9
1657 120,1
1658 120,3
1659 120,4
1660 120,5
1661 120,5
1662 120,5
1663 120,5
1664 120,4
1665 120,3
1666 120,1
1667 119,9
1668 119,6
1669 119,5
1670 119,4
1671 119,3
1672 119,3
1673 119,4
1674 119,5
1675 119,5
1676 119,6
1677 119,6
1678 119,6
1679 119,4
1680 119,3
1681 119,0
1682 118,8
1683 118,7
1684 118,8
1685 119,0
1686 119,2
1687 119,6
1688 120,0
1689 120,3
1690 120,5
1691 120,7
1692 120,9
1693 121,0
1694 121,1
1695 121,2
1696 121,3
1697 121,4
1698 121,5
1699 121,5
1700 121,5
1701 121,4
1702 121,3
1703 121,1
1704 120,9
1705 120,6
1706 120,4
1707 120,2
1708 120,1
1709 119,9
1710 119,8
1711 119,8
1712 119,9
1713 120,0
1714 120,2
1715 120,4
1716 120,8
1717 121,1
1718 121,6
1719 121,8
1720 122,1
1721 122,4
1722 122,7
1723 122,8
1724 123,1
1725 123,1
1726 122,8
1727 122,3
1728 121,3
1729 119,9
1730 118,1
1731 115,9
1732 113,5
1733 111,1
1734 108,6
1735 106,2
1736 104,0
1737 101,1
1738 98,3
1739 95,7
1740 93,5
1741 91,5
1742 90,7
1743 90,4
1744 90,2
1745 90,2
1746 90,1
1747 90,0
1748 89,8
1749 89,6
1750 89,4
1751 89,2
1752 88,9
1753 88,5
1754 88,1
1755 87,6
1756 87,1
1757 86,6
1758 86,1
1759 85,5
1760 85,0
1761 84,4
1762 83,8
1763 83,2
1764 82,6
1765 81,9
1766 81,1
1767 80,0
1768 78,7
1769 76,9
1770 74,6
1771 72,0
1772 69,0
1773 65,6
1774 62,1
1775 58,5
1776 54,7
1777 50,9
1778 47,3
1779 43,8
1780 40,4
1781 37,4
1782 34,3
1783 31,3
1784 28,3
1785 25,2
1786 22,0
1787 18,9
1788 16,1
1789 13,4
1790 11,1
1791 8,9
1792 6,9
1793 4,9
1794 2,8
1795 0,0
1796 0,0
1797 0,0
1798 0,0
1799 0,0
1800 0,0

6. 
Figure A1/7
Figure A1/8
Figure A1/9
Figure A1/10
Figure A1/11
Figure A1/12

Time in s Speed in km/h
0 0,0
1 0,0
2 0,0
3 0,0
4 0,0
5 0,0
6 0,0
7 0,0
8 0,0
9 0,0
10 0,0
11 0,0
12 0,2
13 1,7
14 5,4
15 9,9
16 13,1
17 16,9
18 21,7
19 26,0
20 27,5
21 28,1
22 28,3
23 28,8
24 29,1
25 30,8
26 31,9
27 34,1
28 36,6
29 39,1
30 41,3
31 42,5
32 43,3
33 43,9
34 44,4
35 44,5
36 44,2
37 42,7
38 39,9
39 37,0
40 34,6
41 32,3
42 29,0
43 25,1
44 22,2
45 20,9
46 20,4
47 19,5
48 18,4
49 17,8
50 17,8
51 17,4
52 15,7
53 13,1
54 12,1
55 12,0
56 12,0
57 12,0
58 12,3
59 12,6
60 14,7
61 15,3
62 15,9
63 16,2
64 17,1
65 17,8
66 18,1
67 18,4
68 20,3
69 23,2
70 26,5
71 29,8
72 32,6
73 34,4
74 35,5
75 36,4
76 37,4
77 38,5
78 39,3
79 39,5
80 39,0
81 38,5
82 37,3
83 37,0
84 36,7
85 35,9
86 35,3
87 34,6
88 34,2
89 31,9
90 27,3
91 22,0
92 17,0
93 14,2
94 12,0
95 9,1
96 5,8
97 3,6
98 2,2
99 0,0
100 0,0
101 0,0
102 0,0
103 0,0
104 0,0
105 0,0
106 0,0
107 0,0
108 0,0
109 0,0
110 0,0
111 0,0
112 0,0
113 0,0
114 0,0
115 0,0
116 0,0
117 0,0
118 0,0
119 0,0
120 0,0
121 0,0
122 0,0
123 0,0
124 0,0
125 0,0
126 0,0
127 0,0
128 0,0
129 0,0
130 0,0
131 0,0
132 0,0
133 0,0
134 0,0
135 0,0
136 0,0
137 0,0
138 0,2
139 1,9
140 6,1
141 11,7
142 16,4
143 18,9
144 19,9
145 20,8
146 22,8
147 25,4
148 27,7
149 29,2
150 29,8
151 29,4
152 27,2
153 22,6
154 17,3
155 13,3
156 12,0
157 12,6
158 14,1
159 17,2
160 20,1
161 23,4
162 25,5
163 27,6
164 29,5
165 31,1
166 32,1
167 33,2
168 35,2
169 37,2
170 38,0
171 37,4
172 35,1
173 31,0
174 27,1
175 25,3
176 25,1
177 25,9
178 27,8
179 29,2
180 29,6
181 29,5
182 29,2
183 28,3
184 26,1
185 23,6
186 21,0
187 18,9
188 17,1
189 15,7
190 14,5
191 13,7
192 12,9
193 12,5
194 12,2
195 12,0
196 12,0
197 12,0
198 12,0
199 12,5
200 13,0
201 14,0
202 15,0
203 16,5
204 19,0
205 21,2
206 23,8
207 26,9
208 29,6
209 32,0
210 35,2
211 37,5
212 39,2
213 40,5
214 41,6
215 43,1
216 45,0
217 47,1
218 49,0
219 50,6
220 51,8
221 52,7
222 53,1
223 53,5
224 53,8
225 54,2
226 54,8
227 55,3
228 55,8
229 56,2
230 56,5
231 56,5
232 56,2
233 54,9
234 52,9
235 51,0
236 49,8
237 49,2
238 48,4
239 46,9
240 44,3
241 41,5
242 39,5
243 37,0
244 34,6
245 32,3
246 29,0
247 25,1
248 22,2
249 20,9
250 20,4
251 19,5
252 18,4
253 17,8
254 17,8
255 17,4
256 15,7
257 14,5
258 15,4
259 17,9
260 20,6
261 23,2
262 25,7
263 28,7
264 32,5
265 36,1
266 39,0
267 40,8
268 42,9
269 44,4
270 45,9
271 46,0
272 45,6
273 45,3
274 43,7
275 40,8
276 38,0
277 34,4
278 30,9
279 25,5
280 21,4
281 20,2
282 22,9
283 26,6
284 30,2
285 34,1
286 37,4
287 40,7
288 44,0
289 47,3
290 49,2
291 49,8
292 49,2
293 48,1
294 47,3
295 46,8
296 46,7
297 46,8
298 47,1
299 47,3
300 47,3
301 47,1
302 46,6
303 45,8
304 44,8
305 43,3
306 41,8
307 40,8
308 40,3
309 40,1
310 39,7
311 39,2
312 38,5
313 37,4
314 36,0
315 34,4
316 33,0
317 31,7
318 30,0
319 28,0
320 26,1
321 25,6
322 24,9
323 24,9
324 24,3
325 23,9
326 23,9
327 23,6
328 23,3
329 20,5
330 17,5
331 16,9
332 16,7
333 15,9
334 15,6
335 15,0
336 14,5
337 14,3
338 14,5
339 15,4
340 17,8
341 21,1
342 24,1
343 25,0
344 25,3
345 25,5
346 26,4
347 26,6
348 27,1
349 27,7
350 28,1
351 28,2
352 28,1
353 28,0
354 27,9
355 27,9
356 28,1
357 28,2
358 28,0
359 26,9
360 25,0
361 23,2
362 21,9
363 21,1
364 20,7
365 20,7
366 20,8
367 21,2
368 22,1
369 23,5
370 24,3
371 24,5
372 23,8
373 21,3
374 17,7
375 14,4
376 11,9
377 10,2
378 8,9
379 8,0
380 7,2
381 6,1
382 4,9
383 3,7
384 2,3
385 0,9
386 0,0
387 0,0
388 0,0
389 0,0
390 0,0
391 0,0
392 0,5
393 2,1
394 4,8
395 8,3
396 12,3
397 16,6
398 20,9
399 24,2
400 25,6
401 25,6
402 24,9
403 23,3
404 21,6
405 20,2
406 18,7
407 17,0
408 15,3
409 14,2
410 13,9
411 14,0
412 14,2
413 14,5
414 14,9
415 15,9
416 17,4
417 18,7
418 19,1
419 18,8
420 17,6
421 16,6
422 16,2
423 16,4
424 17,2
425 19,1
426 22,6
427 27,4
428 31,6
429 33,4
430 33,5
431 32,8
432 31,9
433 31,3
434 31,1
435 30,6
436 29,2
437 26,7
438 23,0
439 18,2
440 12,9
441 7,7
442 3,8
443 1,3
444 0,2
445 0,0
446 0,0
447 0,0
448 0,0
449 0,0
450 0,0
451 0,0
452 0,0
453 0,0
454 0,0
455 0,0
456 0,0
457 0,0
458 0,0
459 0,0
460 0,0
461 0,0
462 0,0
463 0,0
464 0,0
465 0,0
466 0,0
467 0,0
468 0,0
469 0,0
470 0,0
471 0,0
472 0,0
473 0,0
474 0,0
475 0,0
476 0,0
477 0,0
478 0,0
479 0,0
480 0,0
481 0,0
482 0,0
483 0,0
484 0,0
485 0,0
486 0,0
487 0,0
488 0,0
489 0,0
490 0,0
491 0,0
492 0,0
493 0,0
494 0,0
495 0,0
496 0,0
497 0,0
498 0,0
499 0,0
500 0,0
501 0,0
502 0,0
503 0,0
504 0,0
505 0,0
506 0,0
507 0,0
508 0,0
509 0,0
510 0,0
511 0,0
512 0,5
513 2,5
514 6,6
515 11,8
516 16,8
517 20,5
518 21,9
519 21,9
520 21,3
521 20,3
522 19,2
523 17,8
524 15,5
525 11,9
526 7,6
527 4,0
528 2,0
529 1,0
530 0,0
531 0,0
532 0,0
533 0,2
534 1,2
535 3,2
536 5,2
537 8,2
538 13
539 18,8
540 23,1
541 24,5
542 24,5
543 24,3
544 23,6
545 22,3
546 20,1
547 18,5
548 17,2
549 16,3
550 15,4
551 14,7
552 14,3
553 13,7
554 13,3
555 13,1
556 13,1
557 13,3
558 13,8
559 14,5
560 16,5
561 17,0
562 17,0
563 17,0
564 15,4
565 10,1
566 4,8
567 0,0
568 0,0
569 0,0
570 0,0
571 0,0
572 0,0
573 0,0
574 0,0
575 0,0
576 0,0
577 0,0
578 0,0
579 0,0
580 0,0
581 0,0
582 0,0
583 0,0
584 0,0
585 0,0
586 0,0
587 0,0
588 0,0
589 0,0


Time in s Speed in km/h
590 0,0
591 0,0
592 0,0
593 0,0
594 0,0
595 0,0
596 0,0
597 0,0
598 0,0
599 0,0
600 0,0
601 1,0
602 2,1
603 5,2
604 9,2
605 13,5
606 18,1
607 22,3
608 26,0
609 29,3
610 32,8
611 36,0
612 39,2
613 42,5
614 45,7
615 48,2
616 48,4
617 48,2
618 47,8
619 47,0
620 45,9
621 44,9
622 44,4
623 44,3
624 44,5
625 45,1
626 45,7
627 46,0
628 46,0
629 46,0
630 46,1
631 46,7
632 47,7
633 48,9
634 50,3
635 51,6
636 52,6
637 53,0
638 53,0
639 52,9
640 52,7
641 52,6
642 53,1
643 54,3
644 55,2
645 55,5
646 55,9
647 56,3
648 56,7
649 56,9
650 56,8
651 56,0
652 54,2
653 52,1
654 50,1
655 47,2
656 43,2
657 39,2
658 36,5
659 34,3
660 31,0
661 26,0
662 20,7
663 15,4
664 13,1
665 12,0
666 12,5
667 14,0
668 19,0
669 23,2
670 28,0
671 32,0
672 34,0
673 36,0
674 38,0
675 40,0
676 40,3
677 40,5
678 39,0
679 35,7
680 31,8
681 27,1
682 22,8
683 21,1
684 18,9
685 18,9
686 21,3
687 23,9
688 25,9
689 28,4
690 30,3
691 30,9
692 31,1
693 31,8
694 32,7
695 33,2
696 32,4
697 28,3
698 25,8
699 23,1
700 21,8
701 21,2
702 21,0
703 21,0
704 20,9
705 19,9
706 17,9
707 15,1
708 12,8
709 12,0
710 13,2
711 17,1
712 21,1
713 21,8
714 21,2
715 18,5
716 13,9
717 12,0
718 12,0
719 13,0
720 16,3
721 20,5
722 23,9
723 26,0
724 28,0
725 31,5
726 33,4
727 36,0
728 37,8
729 40,2
730 41,6
731 41,9
732 42,0
733 42,2
734 42,4
735 42,7
736 43,1
737 43,7
738 44,0
739 44,1
740 45,3
741 46,4
742 47,2
743 47,3
744 47,4
745 47,4
746 47,5
747 47,9
748 48,6
749 49,4
750 49,8
751 49,8
752 49,7
753 49,3
754 48,5
755 47,6
756 46,3
757 43,7
758 39,3
759 34,1
760 29,0
761 23,7
762 18,4
763 14,3
764 12,0
765 12,8
766 16,0
767 20,4
768 24,0
769 29,0
770 32,2
771 36,8
772 39,4
773 43,2
774 45,8
775 49,2
776 51,4
777 54,2
778 56,0
779 58,3
780 59,8
781 61,7
782 62,7
783 63,3
784 63,6
785 64,0
786 64,7
787 65,2
788 65,3
789 65,3
790 65,4
791 65,7
792 66,0
793 65,6
794 63,5
795 59,7
796 54,6
797 49,3
798 44,9
799 42,3
800 41,4
801 41,3
802 43,0
803 45,0
804 46,5
805 48,3
806 49,5
807 51,2
808 52,2
809 51,6
810 49,7
811 47,4
812 43,7
813 39,7
814 35,5
815 31,1
816 26,3
817 21,9
818 18,0
819 17,0
820 18,0
821 21,4
822 24,8
823 27,9
824 30,8
825 33,0
826 35,1
827 37,1
828 38,9
829 41,4
830 44,0
831 46,3
832 47,7
833 48,2
834 48,7
835 49,3
836 49,8
837 50,2
838 50,9
839 51,8
840 52,5
841 53,3
842 54,5
843 55,7
844 56,5
845 56,8
846 57,0
847 57,2
848 57,7
849 58,7
850 60,1
851 61,1
852 61,7
853 62,3
854 62,9
855 63,3
856 63,4
857 63,5
858 63,9
859 64,4
860 65,0
861 65,6
862 66,6
863 67,4
864 68,2
865 69,1
866 70,0
867 70,8
868 71,5
869 72,4
870 73,0
871 73,7
872 74,4
873 74,9
874 75,3
875 75,6
876 75,8
877 76,6
878 76,5
879 76,2
880 75,8
881 75,4
882 74,8
883 73,9
884 72,7
885 71,3
886 70,4
887 70,0
888 70,0
889 69,0
890 68,0
891 67,3
892 66,2
893 64,8
894 63,6
895 62,6
896 62,1
897 61,9
898 61,9
899 61,8
900 61,5
901 60,9
902 59,7
903 54,6
904 49,3
905 44,9
906 42,3
907 41,4
908 41,3
909 42,1
910 44,7
911 46,0
912 48,8
913 50,1
914 51,3
915 54,1
916 55,2
917 56,2
918 56,1
919 56,1
920 56,5
921 57,5
922 59,2
923 60,7
924 61,8
925 62,3
926 62,7
927 62,0
928 61,3
929 60,9
930 60,5
931 60,2
932 59,8
933 59,4
934 58,6
935 57,5
936 56,6
937 56,0
938 55,5
939 55,0
940 54,4
941 54,1
942 54,0
943 53,9
944 53,9
945 54,0
946 54,2
947 55,0
948 55,8
949 56,2
950 56,1
951 55,1
952 52,7
953 48,4
954 43,1
955 37,8
956 32,5
957 27,2
958 25,1
959 27,0
960 29,8
961 33,8
962 37,0
963 40,7
964 43,0
965 45,6
966 46,9
967 47,0
968 46,9
969 46,5
970 45,8
971 44,3
972 41,3
973 36,5
974 31,7
975 27,0
976 24,7
977 19,3
978 16,0
979 13,2
980 10,7
981 8,8
982 7,2
983 5,5
984 3,2
985 1,1
986 0,0
987 0,0
988 0,0
989 0,0
990 0,0
991 0,0
992 0,0
993 0,0
994 0,0
995 0,0
996 0,0
997 0,0
998 0,0
999 0,0
1000 0,0
1001 0,0
1002 0,0
1003 0,0
1004 0,0
1005 0,0
1006 0,0
1007 0,0
1008 0,0
1009 0,0
1010 0,0
1011 0,0
1012 0,0
1013 0,0
1014 0,0
1015 0,0
1016 0,0
1017 0,0
1018 0,0
1019 0,0
1020 0,0
1021 0,0
1022 0,0


Time in s Speed in km/h
590 0,0
591 0,0
592 0,0
593 0,0
594 0,0
595 0,0
596 0,0
597 0,0
598 0,0
599 0,0
600 0,0
601 1,0
602 2,1
603 4,8
604 9,1
605 14,2
606 19,8
607 25,5
608 30,5
609 34,8
610 38,8
611 42,9
612 46,4
613 48,3
614 48,7
615 48,5
616 48,4
617 48,2
618 47,8
619 47,0
620 45,9
621 44,9
622 44,4
623 44,3
624 44,5
625 45,1
626 45,7
627 46,0
628 46,0
629 46,0
630 46,1
631 46,7
632 47,7
633 48,9
634 50,3
635 51,6
636 52,6
637 53,0
638 53,0
639 52,9
640 52,7
641 52,6
642 53,1
643 54,3
644 55,2
645 55,5
646 55,9
647 56,3
648 56,7
649 56,9
650 56,8
651 56,0
652 54,2
653 52,1
654 50,1
655 47,2
656 43,2
657 39,2
658 36,5
659 34,3
660 31,0
661 26,0
662 20,7
663 15,4
664 13,1
665 12,0
666 12,5
667 14,0
668 19,0
669 23,2
670 28,0
671 32,0
672 34,0
673 36,0
674 38,0
675 40,0
676 40,3
677 40,5
678 39,0
679 35,7
680 31,8
681 27,1
682 22,8
683 21,1
684 18,9
685 18,9
686 21,3
687 23,9
688 25,9
689 28,4
690 30,3
691 30,9
692 31,1
693 31,8
694 32,7
695 33,2
696 32,4
697 28,3
698 25,8
699 23,1
700 21,8
701 21,2
702 21,0
703 21,0
704 20,9
705 19,9
706 17,9
707 15,1
708 12,8
709 12,0
710 13,2
711 17,1
712 21,1
713 21,8
714 21,2
715 18,5
716 13,9
717 12,0
718 12,0
719 13,0
720 16,0
721 18,5
722 20,6
723 22,5
724 24,0
725 26,6
726 29,9
727 34,8
728 37,8
729 40,2
730 41,6
731 41,9
732 42,0
733 42,2
734 42,4
735 42,7
736 43,1
737 43,7
738 44,0
739 44,1
740 45,3
741 46,4
742 47,2
743 47,3
744 47,4
745 47,4
746 47,5
747 47,9
748 48,6
749 49,4
750 49,8
751 49,8
752 49,7
753 49,3
754 48,5
755 47,6
756 46,3
757 43,7
758 39,3
759 34,1
760 29,0
761 23,7
762 18,4
763 14,3
764 12,0
765 12,8
766 16,0
767 19,1
768 22,4
769 25,6
770 30,1
771 35,3
772 39,9
773 44,5
774 47,5
775 50,9
776 54,1
777 56,3
778 58,1
779 59,8
780 61,1
781 62,1
782 62,8
783 63,3
784 63,6
785 64,0
786 64,7
787 65,2
788 65,3
789 65,3
790 65,4
791 65,7
792 66,0
793 65,6
794 63,5
795 59,7
796 54,6
797 49,3
798 44,9
799 42,3
800 41,4
801 41,3
802 42,1
803 44,7
804 48,4
805 51,4
806 52,7
807 53,0
808 52,5
809 51,3
810 49,7
811 47,4
812 43,7
813 39,7
814 35,5
815 31,1
816 26,3
817 21,9
818 18,0
819 17,0
820 18,0
821 21,4
822 24,8
823 27,9
824 30,8
825 33,0
826 35,1
827 37,1
828 38,9
829 41,4
830 44,0
831 46,3
832 47,7
833 48,2
834 48,7
835 49,3
836 49,8
837 50,2
838 50,9
839 51,8
840 52,5
841 53,3
842 54,5
843 55,7
844 56,5
845 56,8
846 57,0
847 57,2
848 57,7
849 58,7
850 60,1
851 61,1
852 61,7
853 62,3
854 62,9
855 63,3
856 63,4
857 63,5
858 64,5
859 65,8
860 66,8
861 67,4
862 68,8
863 71,1
864 72,3
865 72,8
866 73,4
867 74,6
868 76,0
869 76,6
870 76,5
871 76,2
872 75,8
873 75,4
874 74,8
875 73,9
876 72,7
877 71,3
878 70,4
879 70,0
880 70,0
881 69,0
882 68,0
883 68,0
884 68,0
885 68,1
886 68,4
887 68,6
888 68,7
889 68,5
890 68,1
891 67,3
892 66,2
893 64,8
894 63,6
895 62,6
896 62,1
897 61,9
898 61,9
899 61,8
900 61,5
901 60,9
902 59,7
903 54,6
904 49,3
905 44,9
906 42,3
907 41,4
908 41,3
909 42,1
910 44,7
911 48,4
912 51,4
913 52,7
914 54,0
915 57,0
916 58,1
917 59,2
918 59,0
919 59,1
920 59,5
921 60,5
922 62,3
923 63,9
924 65,1
925 64,1
926 62,7
927 62,0
928 61,3
929 60,9
930 60,5
931 60,2
932 59,8
933 59,4
934 58,6
935 57,5
936 56,6
937 56,0
938 55,5
939 55,0
940 54,4
941 54,1
942 54,0
943 53,9
944 53,9
945 54,0
946 54,2
947 55,0
948 55,8
949 56,2
950 56,1
951 55,1
952 52,7
953 48,4
954 43,1
955 37,8
956 32,5
957 27,2
958 25,1
959 26,0
960 29,3
961 34,6
962 40,4
963 45,3
964 49,0
965 51,1
966 52,1
967 52,2
968 52,1
969 51,7
970 50,9
971 49,2
972 45,9
973 40,6
974 35,3
975 30,0
976 24,7
977 19,3
978 16,0
979 13,2
980 10,7
981 8,8
982 7,2
983 5,5
984 3,2
985 1,1
986 0,0
987 0,0
988 0,0
989 0,0
990 0,0
991 0,0
992 0,0
993 0,0
994 0,0
995 0,0
996 0,0
997 0,0
998 0,0
999 0,0
1000 0,0
1001 0,0
1002 0,0
1003 0,0
1004 0,0
1005 0,0
1006 0,0
1007 0,0
1008 0,0
1009 0,0
1010 0,0
1011 0,0
1012 0,0
1013 0,0
1014 0,0
1015 0,0
1016 0,0
1017 0,0
1018 0,0
1019 0,0
1020 0,0
1021 0,0
1022 0,0


Time in s Speed in km/h
1023 0,0
1024 0,0
1025 0,0
1026 0,0
1027 0,8
1028 3,6
1029 8,6
1030 14,6
1031 20,0
1032 24,4
1033 28,2
1034 31,7
1035 35,0
1036 37,6
1037 39,7
1038 41,5
1039 43,6
1040 46,0
1041 48,4
1042 50,5
1043 51,9
1044 52,6
1045 52,8
1046 52,9
1047 53,1
1048 53,3
1049 53,1
1050 52,3
1051 50,7
1052 48,8
1053 46,5
1054 43,8
1055 40,3
1056 36,0
1057 30,7
1058 25,4
1059 21,0
1060 16,7
1061 13,4
1062 12,0
1063 12,1
1064 12,8
1065 15,6
1066 19,9
1067 23,4
1068 24,6
1069 27,0
1070 29,0
1071 32,0
1072 34,8
1073 37,7
1074 40,8
1075 43,2
1076 46,0
1077 48,0
1078 50,7
1079 52,0
1080 54,5
1081 55,9
1082 57,4
1083 58,1
1084 58,4
1085 58,8
1086 58,8
1087 58,6
1088 58,7
1089 58,8
1090 58,8
1091 58,8
1092 59,1
1093 60,1
1094 61,7
1095 63,0
1096 63,7
1097 63,9
1098 63,5
1099 62,3
1100 60,3
1101 58,9
1102 58,4
1103 58,8
1104 60,2
1105 62,3
1106 63,9
1107 64,5
1108 64,4
1109 63,5
1110 62,0
1111 61,2
1112 61,3
1113 61,7
1114 62,0
1115 64,6
1116 66,0
1117 66,2
1118 65,8
1119 64,7
1120 63,6
1121 62,9
1122 62,4
1123 61,7
1124 60,1
1125 57,3
1126 55,8
1127 50,5
1128 45,2
1129 40,1
1130 36,2
1131 32,9
1132 29,8
1133 26,6
1134 23,0
1135 19,4
1136 16,3
1137 14,6
1138 14,2
1139 14,3
1140 14,6
1141 15,1
1142 16,4
1143 19,1
1144 22,5
1145 24,4
1146 24,8
1147 22,7
1148 17,4
1149 13,8
1150 12,0
1151 12,0
1152 12,0
1153 13,9
1154 17,7
1155 22,8
1156 27,3
1157 31,2
1158 35,2
1159 39,4
1160 42,5
1161 45,4
1162 48,2
1163 50,3
1164 52,6
1165 54,5
1166 56,6
1167 58,3
1168 60,0
1169 61,5
1170 63,1
1171 64,3
1172 65,7
1173 67,1
1174 68,3
1175 69,7
1176 70,6
1177 71,6
1178 72,6
1179 73,5
1180 74,2
1181 74,9
1182 75,6
1183 76,3
1184 77,1
1185 77,9
1186 78,5
1187 79,0
1188 79,7
1189 80,3
1190 81,0
1191 81,6
1192 82,4
1193 82,9
1194 83,4
1195 83,8
1196 84,2
1197 84,7
1198 85,2
1199 85,6
1200 86,3
1201 86,8
1202 87,4
1203 88,0
1204 88,3
1205 88,7
1206 89,0
1207 89,3
1208 89,8
1209 90,2
1210 90,6
1211 91,0
1212 91,3
1213 91,6
1214 91,9
1215 92,2
1216 92,8
1217 93,1
1218 93,3
1219 93,5
1220 93,7
1221 93,9
1222 94,0
1223 94,1
1224 94,3
1225 94,4
1226 94,6
1227 94,7
1228 94,8
1229 95,0
1230 95,1
1231 95,3
1232 95,4
1233 95,6
1234 95,7
1235 95,8
1236 96,0
1237 96,1
1238 96,3
1239 96,4
1240 96,6
1241 96,8
1242 97,0
1243 97,2
1244 97,3
1245 97,4
1246 97,4
1247 97,4
1248 97,4
1249 97,3
1250 97,3
1251 97,3
1252 97,3
1253 97,2
1254 97,1
1255 97,0
1256 96,9
1257 96,7
1258 96,4
1259 96,1
1260 95,7
1261 95,5
1262 95,3
1263 95,2
1264 95,0
1265 94,9
1266 94,7
1267 94,5
1268 94,4
1269 94,4
1270 94,3
1271 94,3
1272 94,1
1273 93,9
1274 93,4
1275 92,8
1276 92,0
1277 91,3
1278 90,6
1279 90,0
1280 89,3
1281 88,7
1282 88,1
1283 87,4
1284 86,7
1285 86,0
1286 85,3
1287 84,7
1288 84,1
1289 83,5
1290 82,9
1291 82,3
1292 81,7
1293 81,1
1294 80,5
1295 79,9
1296 79,4
1297 79,1
1298 78,8
1299 78,5
1300 78,2
1301 77,9
1302 77,6
1303 77,3
1304 77,0
1305 76,7
1306 76,0
1307 76,0
1308 76,0
1309 75,9
1310 76,0
1311 76,0
1312 76,1
1313 76,3
1314 76,5
1315 76,6
1316 76,8
1317 77,1
1318 77,1
1319 77,2
1320 77,2
1321 77,6
1322 78,0
1323 78,4
1324 78,8
1325 79,2
1326 80,3
1327 80,8
1328 81,0
1329 81,0
1330 81,0
1331 81,0
1332 81,0
1333 80,9
1334 80,6
1335 80,3
1336 80,0
1337 79,9
1338 79,8
1339 79,8
1340 79,8
1341 79,9
1342 80,0
1343 80,4
1344 80,8
1345 81,2
1346 81,5
1347 81,6
1348 81,6
1349 81,4
1350 80,7
1351 79,6
1352 78,2
1353 76,8
1354 75,3
1355 73,8
1356 72,1
1357 70,2
1358 68,2
1359 66,1
1360 63,8
1361 61,6
1362 60,2
1363 59,8
1364 60,4
1365 61,8
1366 62,6
1367 62,7
1368 61,9
1369 60,0
1370 58,4
1371 57,8
1372 57,8
1373 57,8
1374 57,3
1375 56,2
1376 54,3
1377 50,8
1378 45,5
1379 40,2
1380 34,9
1381 29,6
1382 28,7
1383 29,3
1384 30,5
1385 31,7
1386 32,9
1387 35,0
1388 38,0
1389 40,5
1390 42,7
1391 45,8
1392 47,5
1393 48,9
1394 49,4
1395 49,4
1396 49,2
1397 48,7
1398 47,9
1399 46,9
1400 45,6
1401 44,2
1402 42,7
1403 40,7
1404 37,1
1405 33,9
1406 30,6
1407 28,6
1408 27,3
1409 27,2
1410 27,5
1411 27,4
1412 27,1
1413 26,7
1414 26,8
1415 28,2
1416 31,1
1417 34,8
1418 38,4
1419 40,9
1420 41,7
1421 40,9
1422 38,3
1423 35,3
1424 34,3
1425 34,6
1426 36,3
1427 39,5
1428 41,8
1429 42,5
1430 41,9
1431 40,1
1432 36,6
1433 31,3
1434 26,0
1435 20,6
1436 19,1
1437 19,7
1438 21,1
1439 22,0
1440 22,1
1441 21,4
1442 19,6
1443 18,3
1444 18,0
1445 18,3
1446 18,5
1447 17,9
1448 15,0
1449 9,9
1450 4,6
1451 1,2
1452 0,0
1453 0,0
1454 0,0
1455 0,0
1456 0,0
1457 0,0
1458 0,0
1459 0,0
1460 0,0
1461 0,0
1462 0,0
1463 0,0
1464 0,0
1465 0,0
1466 0,0
1467 0,0
1468 0,0
1469 0,0
1470 0,0
1471 0,0
1472 0,0
1473 0,0
1474 0,0
1475 0,0
1476 0,0
1477 0,0


Time in s Speed in km/h
1023 0,0
1024 0,0
1025 0,0
1026 0,0
1027 0,8
1028 3,6
1029 8,6
1030 14,6
1031 20,0
1032 24,4
1033 28,2
1034 31,7
1035 35,0
1036 37,6
1037 39,7
1038 41,5
1039 43,6
1040 46,0
1041 48,4
1042 50,5
1043 51,9
1044 52,6
1045 52,8
1046 52,9
1047 53,1
1048 53,3
1049 53,1
1050 52,3
1051 50,7
1052 48,8
1053 46,5
1054 43,8
1055 40,3
1056 36,0
1057 30,7
1058 25,4
1059 21,0
1060 16,7
1061 13,4
1062 12,0
1063 12,1
1064 12,8
1065 15,6
1066 19,9
1067 23,4
1068 24,6
1069 25,2
1070 26,4
1071 28,8
1072 31,8
1073 35,3
1074 39,5
1075 44,5
1076 49,3
1077 53,3
1078 56,4
1079 58,9
1080 61,2
1081 62,6
1082 63,0
1083 62,5
1084 60,9
1085 59,3
1086 58,6
1087 58,6
1088 58,7
1089 58,8
1090 58,8
1091 58,8
1092 59,1
1093 60,1
1094 61,7
1095 63,0
1096 63,7
1097 63,9
1098 63,5
1099 62,3
1100 60,3
1101 58,9
1102 58,4
1103 58,8
1104 60,2
1105 62,3
1106 63,9
1107 64,5
1108 64,4
1109 63,5
1110 62,0
1111 61,2
1112 61,3
1113 62,6
1114 65,3
1115 68,0
1116 69,4
1117 69,7
1118 69,3
1119 68,1
1120 66,9
1121 66,2
1122 65,7
1123 64,9
1124 63,2
1125 60,3
1126 55,8
1127 50,5
1128 45,2
1129 40,1
1130 36,2
1131 32,9
1132 29,8
1133 26,6
1134 23,0
1135 19,4
1136 16,3
1137 14,6
1138 14,2
1139 14,3
1140 14,6
1141 15,1
1142 16,4
1143 19,1
1144 22,5
1145 24,4
1146 24,8
1147 22,7
1148 17,4
1149 13,8
1150 12,0
1151 12,0
1152 12,0
1153 13,9
1154 17,7
1155 22,8
1156 27,3
1157 31,2
1158 35,2
1159 39,4
1160 42,5
1161 45,4
1162 48,2
1163 50,3
1164 52,6
1165 54,5
1166 56,6
1167 58,3
1168 60,0
1169 61,5
1170 63,1
1171 64,3
1172 65,7
1173 67,1
1174 68,3
1175 69,7
1176 70,6
1177 71,6
1178 72,6
1179 73,5
1180 74,2
1181 74,9
1182 75,6
1183 76,3
1184 77,1
1185 77,9
1186 78,5
1187 79,0
1188 79,7
1189 80,3
1190 81,0
1191 81,6
1192 82,4
1193 82,9
1194 83,4
1195 83,8
1196 84,2
1197 84,7
1198 85,2
1199 85,6
1200 86,3
1201 86,8
1202 87,4
1203 88,0
1204 88,3
1205 88,7
1206 89,0
1207 89,3
1208 89,8
1209 90,2
1210 90,6
1211 91,0
1212 91,3
1213 91,6
1214 91,9
1215 92,2
1216 92,8
1217 93,1
1218 93,3
1219 93,5
1220 93,7
1221 93,9
1222 94,0
1223 94,1
1224 94,3
1225 94,4
1226 94,6
1227 94,7
1228 94,8
1229 95,0
1230 95,1
1231 95,3
1232 95,4
1233 95,6
1234 95,7
1235 95,8
1236 96,0
1237 96,1
1238 96,3
1239 96,4
1240 96,6
1241 96,8
1242 97,0
1243 97,2
1244 97,3
1245 97,4
1246 97,4
1247 97,4
1248 97,4
1249 97,3
1250 97,3
1251 97,3
1252 97,3
1253 97,2
1254 97,1
1255 97,0
1256 96,9
1257 96,7
1258 96,4
1259 96,1
1260 95,7
1261 95,5
1262 95,3
1263 95,2
1264 95,0
1265 94,9
1266 94,7
1267 94,5
1268 94,4
1269 94,4
1270 94,3
1271 94,3
1272 94,1
1273 93,9
1274 93,4
1275 92,8
1276 92,0
1277 91,3
1278 90,6
1279 90,0
1280 89,3
1281 88,7
1282 88,1
1283 87,4
1284 86,7
1285 86,0
1286 85,3
1287 84,7
1288 84,1
1289 83,5
1290 82,9
1291 82,3
1292 81,7
1293 81,1
1294 80,5
1295 79,9
1296 79,4
1297 79,1
1298 78,8
1299 78,5
1300 78,2
1301 77,9
1302 77,6
1303 77,3
1304 77,0
1305 76,7
1306 76,0
1307 76,0
1308 76,0
1309 75,9
1310 75,9
1311 75,8
1312 75,7
1313 75,5
1314 75,2
1315 75,0
1316 74,7
1317 74,1
1318 73,7
1319 73,3
1320 73,5
1321 74,0
1322 74,9
1323 76,1
1324 77,7
1325 79,2
1326 80,3
1327 80,8
1328 81,0
1329 81,0
1330 81,0
1331 81,0
1332 81,0
1333 80,9
1334 80,6
1335 80,3
1336 80,0
1337 79,9
1338 79,8
1339 79,8
1340 79,8
1341 79,9
1342 80,0
1343 80,4
1344 80,8
1345 81,2
1346 81,5
1347 81,6
1348 81,6
1349 81,4
1350 80,7
1351 79,6
1352 78,2
1353 76,8
1354 75,3
1355 73,8
1356 72,1
1357 70,2
1358 68,2
1359 66,1
1360 63,8
1361 61,6
1362 60,2
1363 59,8
1364 60,4
1365 61,8
1366 62,6
1367 62,7
1368 61,9
1369 60,0
1370 58,4
1371 57,8
1372 57,8
1373 57,8
1374 57,3
1375 56,2
1376 54,3
1377 50,8
1378 45,5
1379 40,2
1380 34,9
1381 29,6
1382 27,3
1383 29,3
1384 32,9
1385 35,6
1386 36,7
1387 37,6
1388 39,4
1389 42,5
1390 46,5
1391 50,2
1392 52,8
1393 54,3
1394 54,9
1395 54,9
1396 54,7
1397 54,1
1398 53,2
1399 52,1
1400 50,7
1401 49,1
1402 47,4
1403 45,2
1404 41,8
1405 36,5
1406 31,2
1407 27,6
1408 26,9
1409 27,3
1410 27,5
1411 27,4
1412 27,1
1413 26,7
1414 26,8
1415 28,2
1416 31,1
1417 34,8
1418 38,4
1419 40,9
1420 41,7
1421 40,9
1422 38,3
1423 35,3
1424 34,3
1425 34,6
1426 36,3
1427 39,5
1428 41,8
1429 42,5
1430 41,9
1431 40,1
1432 36,6
1433 31,3
1434 26,0
1435 20,6
1436 19,1
1437 19,7
1438 21,1
1439 22,0
1440 22,1
1441 21,4
1442 19,6
1443 18,3
1444 18,0
1445 18,3
1446 18,5
1447 17,9
1448 15,0
1449 9,9
1450 4,6
1451 1,2
1452 0,0
1453 0,0
1454 0,0
1455 0,0
1456 0,0
1457 0,0
1458 0,0
1459 0,0
1460 0,0
1461 0,0
1462 0,0
1463 0,0
1464 0,0
1465 0,0
1466 0,0
1467 0,0
1468 0,0
1469 0,0
1470 0,0
1471 0,0
1472 0,0
1473 0,0
1474 0,0
1475 0,0
1476 0,0
1477 0,0


Time in s Speed in km/h
1478 0,0
1479 2,2
1480 4,4
1481 6,3
1482 7,9
1483 9,2
1484 10,4
1485 11,5
1486 12,9
1487 14,7
1488 17,0
1489 19,8
1490 23,1
1491 26,7
1492 30,5
1493 34,1
1494 37,5
1495 40,6
1496 43,3
1497 45,7
1498 47,7
1499 49,3
1500 50,5
1501 51,3
1502 52,1
1503 52,7
1504 53,4
1505 54,0
1506 54,5
1507 55,0
1508 55,6
1509 56,3
1510 57,2
1511 58,5
1512 60,2
1513 62,3
1514 64,7
1515 67,1
1516 69,2
1517 70,7
1518 71,9
1519 72,7
1520 73,4
1521 73,8
1522 74,1
1523 74,0
1524 73,6
1525 72,5
1526 70,8
1527 68,6
1528 66,2
1529 64,0
1530 62,2
1531 60,9
1532 60,2
1533 60,0
1534 60,4
1535 61,4
1536 63,2
1537 65,6
1538 68,4
1539 71,6
1540 74,9
1541 78,4
1542 81,8
1543 84,9
1544 87,4
1545 89,0
1546 90,0
1547 90,6
1548 91,0
1549 91,5
1550 92,0
1551 92,7
1552 93,4
1553 94,2
1554 94,9
1555 95,7
1556 96,6
1557 97,7
1558 98,9
1559 100,4
1560 102,0
1561 103,6
1562 105,2
1563 106,8
1564 108,5
1565 110,2
1566 111,9
1567 113,7
1568 115,3
1569 116,8
1570 118,2
1571 119,5
1572 120,7
1573 121,8
1574 122,6
1575 123,2
1576 123,6
1577 123,7
1578 123,6
1579 123,3
1580 123,0
1581 122,5
1582 122,1
1583 121,5
1584 120,8
1585 120,0
1586 119,1
1587 118,1
1588 117,1
1589 116,2
1590 115,5
1591 114,9
1592 114,5
1593 114,1
1594 113,9
1595 113,7
1596 113,3
1597 112,9
1598 112,2
1599 111,4
1600 110,5
1601 109,5
1602 108,5
1603 107,7
1604 107,1
1605 106,6
1606 106,4
1607 106,2
1608 106,2
1609 106,2
1610 106,4
1611 106,5
1612 106,8
1613 107,2
1614 107,8
1615 108,5
1616 109,4
1617 110,5
1618 111,7
1619 113,0
1620 114,1
1621 115,1
1622 115,9
1623 116,5
1624 116,7
1625 116,6
1626 116,2
1627 115,2
1628 113,8
1629 112,0
1630 110,1
1631 108,3
1632 107,0
1633 106,1
1634 105,8
1635 105,7
1636 105,7
1637 105,6
1638 105,3
1639 104,9
1640 104,4
1641 104,0
1642 103,8
1643 103,9
1644 104,4
1645 105,1
1646 106,1
1647 107,2
1648 108,5
1649 109,9
1650 111,3
1651 112,7
1652 113,9
1653 115,0
1654 116,0
1655 116,8
1656 117,6
1657 118,4
1658 119,2
1659 120,0
1660 120,8
1661 121,6
1662 122,3
1663 123,1
1664 123,8
1665 124,4
1666 125,0
1667 125,4
1668 125,8
1669 126,1
1670 126,4
1671 126,6
1672 126,7
1673 126,8
1674 126,9
1675 126,9
1676 126,9
1677 126,8
1678 126,6
1679 126,3
1680 126,0
1681 125,7
1682 125,6
1683 125,6
1684 125,8
1685 126,2
1686 126,6
1687 127,0
1688 127,4
1689 127,6
1690 127,8
1691 127,9
1692 128,0
1693 128,1
1694 128,2
1695 128,3
1696 128,4
1697 128,5
1698 128,6
1699 128,6
1700 128,5
1701 128,3
1702 128,1
1703 127,9
1704 127,6
1705 127,4
1706 127,2
1707 127,0
1708 126,9
1709 126,8
1710 126,7
1711 126,8
1712 126,9
1713 127,1
1714 127,4
1715 127,7
1716 128,1
1717 128,5
1718 129,0
1719 129,5
1720 130,1
1721 130,6
1722 131,0
1723 131,2
1724 131,3
1725 131,2
1726 130,7
1727 129,8
1728 128,4
1729 126,5
1730 124,1
1731 121,6
1732 119,0
1733 116,5
1734 114,1
1735 111,8
1736 109,5
1737 107,1
1738 104,8
1739 102,5
1740 100,4
1741 98,6
1742 97,2
1743 95,9
1744 94,8
1745 93,8
1746 92,8
1747 91,8
1748 91,0
1749 90,2
1750 89,6
1751 89,1
1752 88,6
1753 88,1
1754 87,6
1755 87,1
1756 86,6
1757 86,1
1758 85,5
1759 85,0
1760 84,4
1761 83,8
1762 83,2
1763 82,6
1764 82,0
1765 81,3
1766 80,4
1767 79,1
1768 77,4
1769 75,1
1770 72,3
1771 69,1
1772 65,9
1773 62,7
1774 59,7
1775 57,0
1776 54,6
1777 52,2
1778 49,7
1779 46,8
1780 43,5
1781 39,9
1782 36,4
1783 33,2
1784 30,5
1785 28,3
1786 26,3
1787 24,4
1788 22,5
1789 20,5
1790 18,2
1791 15,5
1792 12,3
1793 8,7
1794 5,2
1795 0,0
1796 0,0
1797 0,0
1798 0,0
1799 0,0
1800 0,0

7. 
In order to confirm if the correct cycle version was chosen or if the correct cycle was implemented into the test bench operation system, checksums of the vehicle speed values for cycle phases and the whole cycle are listed in Table A1/13.


Vehicle class Cycle phase Checksum of 1 Hz target vehicle speeds
Class 1 Low 11 988,4
Medium 17 162,8
Total 29 151,2
Class 2 Low 11 162,2
Medium 17 054,3
High 24 450,6
Extra High 28 869,8
Total 81 536,9
Class 3-1 Low 11 140,3
Medium 16 995,7
High 25 646,0
Extra High 29 714,9
Total 83 496,9
Class 3-2 Low 11 140,3
Medium 17 121,2
High 25 782,2
Extra High 29 714,9
Total 83 758,6

8. 
Paragraph 8. of this Sub-Annex shall not apply to OVC-HEVs, NOVC-HEVs and NOVC-FCHVs.
 8.1. 
The cycle to be driven shall depend on the test vehicle’s rated power to mass in running order ratio, W/kg, and its maximum velocity, vmax, km/h.

Driveability problems may occur for vehicles with power to mass ratios close to the borderlines between Class 1 and Class 2, Class 2 and Class 3 vehicles, or very low powered vehicles in Class 1.

Since these problems are related mainly to cycle phases with a combination of high vehicle speed and high accelerations rather than to the maximum speed of the cycle, the downscaling procedure shall be applied to improve driveability.
 8.2. This paragraph describes the method to modify the cycle profile using the downscaling procedure.
 8.2.1. 
Figure A1/14 shows a downscaled medium speed phase of the Class 1 WLTC as an example.

Figure A1/14For the Class 1 cycle, the downscaling period is the time period between second 651 and second 906. Within this time period, the acceleration for the original cycle shall be calculated using the following equation:aorigi=vi+ 1− vi3,6where:viis the vehicle speed, km/h;iis the time between second 651 and second 906.The downscaling shall be applied first in the time period between second 651 and second 848. The downscaled speed trace shall be subsequently calculated using the following equation:vdsci+ 1=vdsci+ aorigi×1− fdsc× 3,6with i = 651 to 847.For i = 651, vdsci=vorigiIn order to meet the original vehicle speed at second 907, a correction factor for the deceleration shall be calculated using the following equation:fcorr_dec=vdsc_848− 36,7vorig_848− 36,7where 36,7 km/h is the original vehicle speed at second 907.The downscaled vehicle speed between second 849 and second 906 shall be subsequently calculated using the following equation:vdsci=vdsci− 1+ aorigi− 1× fcorr_dec× 3,6for i = 849 to 906. 8.2.2. 
Since the driveability problems are exclusively related to the extra high speed phases of the Class 2 and Class 3 cycles, the downscaling is related to those paragraphs of the extra high speed phases where the driveability problems occur (see Figure A1/15).

Figure A1/15
For the Class 2 cycle, the downscaling period is the time period between second 1520 and second 1742. Within this time period, the acceleration for the original cycle shall be calculated using the following equation:
aorigi=vi+ 1− vi3,6
where:

viis the vehicle speed, km/h;iis the time between second 1520 and second 1742.

The downscaling shall be applied first to the time period between second 1520 and second 1725. Second 1725 is the time when the maximum speed of the extra high speed phase is reached. The downscaled speed trace shall be subsequently calculated using the following equation:
vdsci+ 1=vdsci+ aorigi×1− fdsc× 3,6
for i = 1520 to 1724.

For i = 1520, vdsci=vorigi

In order to meet the original vehicle speed at second 1743, a correction factor for the deceleration shall be calculated using the following equation:
fcorr_dec=vdsc_1725− 90,4vorig_1725− 90,4
90,4 km/h is the original vehicle speed at second 1743.

The downscaled vehicle speed between second 1726 and second 1742 shall be calculated using the following equation:
vdsci=vdsci− 1+ aorigi− 1× fcorr_dec× 3,6
for i = 1726 to 1742.
 8.2.3. 
Figure A1/16 shows a downscaled extra high speed phase of the Class 3 WLTC as an example.

Figure A1/16
For the Class 3 cycle, the downscaling period is the time period between second 1533 and second 1762. Within this time period, the acceleration for the original cycle shall be calculated using the following equation:
aorigi=vi+ 1− vi3,6
where:

viis the vehicle speed, km/h;iis the time between second 1533 and second 1762.

The downscaling shall be applied first in the time period between second 1533 and second 1724. Second 1724 is the time when the maximum speed of the extra high speed phase is reached. The downscaled speed trace shall be subsequently calculated using the following equation:
vdsci+ 1=vdsci+ aorigi×1− fdsc× 3,6
for i = 1533 to 1723.

For i = 1533, vdsci=vorigi

In order to meet the original vehicle speed at second 1763, a correction factor for the deceleration shall be calculated using the following equation:
fcorr_dec=vdsc_1724− 82,6vorig_1724− 82,6
82.6 km/h is the original vehicle speed at second 1763.

The downscaled vehicle speed between second 1725 and second 1762 shall be subsequently calculated using the following equation:
vdsci=vdsci− 1+ aorigi− 1× fcorr_dec× 3,6
for i = 1725 to 1762.
 8.3. 
The downscaling factor fdsc, is a function of the ratio rmax between the maximum required power of the cycle phases where the downscaling is to be applied and the rated power of the vehicle, Prated.

The maximum required power Preq,max,i (in kW) is related to a specific time i and the corresponding vehicle speed vi in the cycle trace and is calculated using the following equation:
Preq,max,i=f0× vi+f1× v2i+f2× v3i+1,03× TM× vi× ai3600
where:

f0, f1, f2are the applicable road load coefficients, N, N/(km/h), and N/(km/h)2 respectively;TMis the applicable test mass, kg;viis the speed at time i, km/h.

The cycle time i at which maximum power or power values close to maximum power is required, is: second 764 for Class 1, second 1574 for Class 2 and second 1566 for Class 3 vehicles.

The corresponding vehicle speed values, vi, and acceleration values, ai, are as follows:


 vi = 61,4 km/h, ai = 0,22 m/s2 for Class 1,
 vi = 109,9 km/h, ai = 0,36 m/s2 for Class 2,
 vi = 111,9 km/h, ai = 0,50 m/s2 for Class 3.

rmax shall be calculated using the following equation:
rmax=Preq,max,iPrated
The downscaling factor, fdsc, shall be calculated using the following equations:

if rmax<r0, then fdsc=0

and no downscaling shall be applied.

If rmax≥r0, then fdsc=a1× rmax+ b1

The calculation parameter/coefficients, r0, a1 and b1, are as follows:


 Class 1 r0 = 0,978, a1 = 0,680, b1 = – 0,665
 Class 2 r0 = 0,866, a1 = 0,606, b1 = – 0,525.
 Class 3 r0 = 0,867, a1 = 0,588 b1 = – 0,510.

The resulting fdsc is mathematically rounded to 3 places of decimal and is applied only if it exceeds 0,010.

The following data shall be included in all relevant test reports:


((a)) fdsc;
((b)) vmax;
((c)) distance driven, m.

The distance shall be calculated as the sum of vi in km/h divided by 3,6 over the whole cycle trace.
 8.4. 
For different vehicle configurations in terms of test mass and driving resistance coefficients, downscaling shall be applied individually.

If, after the application of downscaling the vehicle maximum speed is lower than the maximum speed of the cycle, the process described in paragraph 9. of this Sub-Annex shall be applied with the applicable cycle.

If the vehicle cannot follow the speed trace of the applicable cycle within the tolerance at speeds lower than its maximum speed, it shall be driven with the accelerator control fully activated during these periods. During such periods of operation, speed trace violations shall be permitted.

9.  9.1. 
This paragraph applies to vehicles that are technically able to follow the speed trace of the cycle specified in paragraph 1. of this Sub-Annex (base cycle or downscaled base cycle) at speeds lower than their maximum speed, but whose maximum speed is lower than the maximum speed of the cycle. The maximum speed of such a vehicle shall be referred to as its capped speed vcap. The maximum speed of the base cycle shall be referred to as vmax,cycle.

In such cases the base cycle shall be modified as described in paragraph 9.2. in order to achieve the same cycle distance for the capped speed cycle as for the base cycle.
 9.2.  9.2.1. 
An interim capped speed cycle shall be derived by replacing all vehicle speed samples vi where vi > vcap by vcap.
 9.2.1.1. 
dmedium=∑vi+ vi− 12× 3,6×ti− ti− 1, for i= 591 to 1022

where:

vmax,mediumis the maximum vehicle speed of the medium speed phase as listed in Table A1/2 for class 1 vehicles, in Table A1/4 for class 2 vehicles, in Table A1/8 for class 3a vehicles and in Table A1/9 for class 3b vehicles.
 9.2.1.2. 
dhigh=∑vi+ vi− 12× 3,6×ti− ti− 1, for i = 1 024 to 1 477

vmax,highis the maximum vehicle speed of the high speed phase as listed in Table A1/5 for Class 2 vehicles, in Table A1/10 for Class 3a vehicles and in Table A1/11 for Class 3b vehicles.
 9.2.1.3. 
dexhigh=∑vi+ vi− 12× 3,6×ti− ti− 1, for i = 1 479 to 1 800
 9.2.2. 
In order to compensate for a difference in distance between the base cycle and the interim capped speed cycle, corresponding time periods with vi = vcap shall be added to the interim capped speed cycle as described in the following paragraphs.
 9.2.2.1. 
If vcap < vmax,medium, the additional time period to be added to the medium speed phase of the interim capped speed cycle shall be calculated using the following equation:
Δtmedium=dbase,medium− dcap,mediumvcap× 3,6
The number of time samples nadd,medium with vi = vcap to be added to the medium speed phase of the interim capped speed cycle equals Δtmedium, mathematically rounded to the nearest integer (e.g. 1.4 shall be rounded to 1, 1.5 shall be rounded to 2).
 9.2.2.2. 
If vcap < vmax,high, the additional time period to be added to the high speed phases of the interim capped speed cycle shall be calculated using the following equation:
Δthigh=dbase,high− dcap,highvcap× 3,6
The number of time samples nadd,high with vi = vcap to be added to the high speed phase of the interim capped speed cycle equals Δthigh, mathematically rounded to the nearest integer.
 9.2.2.3. The additional time period to be added to the extra high speed phase of the interim capped speed cycle shall be calculated using the following equation:
Δtexhigh=dbase,exhigh− dcap,exhighvcap× 3,6The number of time samples nadd,exhigh with vi = vcap to be added to the extra high speed phase of the interim capped speed cycle equals Δtexhigh, mathematically rounded to the nearest integer.
 9.2.3.  9.2.3.1. 
The first part of the final capped speed cycle consists of the vehicle speed trace of the interim capped speed cycle up to the last sample in the medium speed phase where v = vcap. The time of this sample is referred to as tmedium.

Then nadd,medium samples with vi = vcap shall be added, so that the time of the last sample is (tmedium + nadd,medium).

The remaining part of the medium speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1022 + nadd,medium).
 9.2.3.2.  9.2.3.2.1. 
The first part of the final capped speed cycle consists of the vehicle speed trace of the interim capped speed cycle up to the last sample in the medium speed phase where v = vcap. The time of this sample is referred to as tmedium.

Then nadd,medium samples with vi = vcap shall be added, so that the time of the last sample is (tmedium + nadd,medium).

The remaining part of the medium speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1022 + nadd,medium).

In a next step, the first part of the high speed phase of the interim capped speed cycle up to the last sample in the high speed phase where v = vcap shall be added. The time of this sample in the interim capped speed is referred to as thigh, so that the time of this sample in the final capped speed cycle is (thigh + nadd,medium).

Then, nadd,high samples with vi = vcap shall be added, so that the time of the last sample becomes (thigh + nadd,medium + nadd,high).

The remaining part of the high speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1477 + nadd,medium + nadd,high).

In a next step, the first part of the extra high speed phase of the interim capped speed cycle up to the last sample in the extra high speed phase where v = vcap shall be added. The time of this sample in the interim capped speed is referred to as texhigh, so that the time of this sample in the final capped speed cycle is (texhigh + nadd,medium + nadd,high).

Then nadd,exhigh samples with vi = vcap shall be added, so that the time of the last sample is (texhigh + nadd,medium + nadd,high + nadd,exhigh).

The remaining part of the extra high speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1800 + nadd,medium + nadd,high+ nadd,exhigh).

The length of the final capped speed cycle is equivalent to the length of the base cycle except for differences caused by the rounding process for nadd,medium, nadd,high and nadd,exhigh.
 9.2.3.2.2. 
The first part of the final capped speed cycle consists of the vehicle speed trace of the interim capped speed cycle up to the last sample in the high speed phase where v = vcap. The time of this sample is referred to as thigh.

Then, nadd,high samples with vi = vcap shall be added, so that the time of the last sample is (thigh + nadd,high).

The remaining part of the high speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1477 + nadd,high).

In a next step, the first part of the extra high speed phase of the interim capped speed cycle up to the last sample in the extra high speed phase where v = vcap shall be added. The time of this sample in the interim capped speed is referred to as texhigh, so that the time of this sample in the final capped speed cycle is (texhigh + nadd,high).

Then nadd,exhigh samples with vi = vcap shall be added, so that the time of the last sample is (texhigh + nadd,high + nadd,exhigh).

The remaining part of the extra high speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1800 + nadd,high+ nadd,exhigh).

The length of the final capped speed cycle is equivalent to the length of the base cycle except for differences caused by the rounding process for nadd,high and nadd,exhigh.
 9.2.3.2.3. 
The first part of the final capped speed cycle consists of the vehicle speed trace of the interim capped speed cycle up to the last sample in the extra high speed phase where v = vcap. The time of this sample is referred to as texhigh.

Then, nadd,exhigh samples with vi = vcap shall be added, so that the time of the last sample is (texhigh + nadd,exhigh).

The remaining part of the extra high speed phase of the interim capped speed cycle, which is identical with the same part of the base cycle, shall then be added, so that the time of the last sample is (1800 + nadd,exhigh).

The length of the final capped speed cycle is equivalent to the length of the base cycle except for differences caused by the rounding process for nadd,exhigh.

Sub-Annex 2
1.  1.1. The shifting procedures described in this Sub-Annex shall apply to vehicles equipped with manual shift transmissions.
 1.2. The prescribed gears and shifting points are based on the balance between the power required to overcome driving resistance and acceleration, and the power provided by the engine in all possible gears at a specific cycle phase.
 1.3. The calculation to determine the gears to use shall be based on engine speeds and full load power curves versus engine speed.
 1.4. For vehicles equipped with a dual-range transmission (low and high), only the range designed for normal on-road operation shall be considered for gear use determination.
 1.5. The prescriptions for the clutch operation shall not be applied if the clutch is operated automatically without the need of an engagement or disengagement of the driver.
 1.6. This Sub-Annex shall not apply to vehicles tested according to Sub-Annex 8.

2. 
The following data are required and calculations shall be performed in order to determine the gears to be used when driving the cycle on a chassis dynamometer:


((a)) Prated, the maximum rated engine power as declared by the manufacturer, kW;
((b)) nrated, the rated engine speed at which an engine develops its maximum power. If the maximum power is developed over an engine speed range, nrated shall be the minimum of this range, min–1;
((c)) nidle, idling speed, min–1;
nidle shall be measured over a period of at least 1 minute at a sampling rate of at least 1 Hz with the engine running in warm condition, the gear lever placed in neutral, and the clutch engaged. The conditions for temperature, peripheral and auxiliary devices, etc. shall be the same as described in Sub-Annex 6 for the Type 1 test.
The value to be used in this Sub-Annex shall be the arithmetic average over the measuring period, rounded or truncated to the nearest 10 min–1;
((d)) ng, the number of forward gears;
The forward gears in the transmission range designed for normal on-road operation shall be numbered in descending order of the ratio between engine speed in min–1 and vehicle speed in km/h. Gear 1 is the gear with the highest ratio, gear ng is the gear with the lowest ratio. ng determines the number of forward gears.
((e)) ndvi, the ratio obtained by dividing the engine speed n by the vehicle speed v for each gear i, for i to ngmax, min–1/(km/h);
((f)) f0, f1, f2, road load coefficients selected for testing, N, N/(km/h), and N/(km/h)2 respectively;
((g)) nmax
nmax_95, the minimum engine speed where 95 per cent of rated power is reached, min–1;
If nmax_95 is less than 65 per cent of nrated, nmax_95 shall be set to 65 per cent of nrated.
If 65 per cent of nrated× ndv3∕ndv2<1,1×nidle+ 0,125×nrated− nidle, nmax_95 shall be set to:
1,1×nidle+ 0,125×nrated− nidle× ndv2∕ndv3
nmaxngvmax=ndvngvmax× vmax,cycle
where:
ngvmaxis defined in paragraph 2(i) of this Sub-Annex.;vmax,cycleis the maximum speed of the vehicle speed trace according to Sub-Annex 1, km/h;nmaxis the maximum of nmax_95 and nmax(ngvmax), min–1.
((h)) Pwot(n), the full load power curve over the engine speed range from nidle to nrated or nmax, or ndv(ngvmax) × vmax, whichever is higher.
ndv(ngvmax) is the ratio obtained by dividing the engine speed n by the vehicle speed v for the gear ngvmax, min–1/km/h;
The power curve shall consist of a sufficient number of data sets (n, Pwot) so that the calculation of interim points between consecutive data sets can be performed by linear interpolation. Deviation of the linear interpolation from the full load power curve according to Annex XX shall not exceed 2 per cent. The first data set shall be at nidle or lower. Data sets need not be spaced equally. The full load power at engine speeds not covered by Annex XX (e.g. nidle) shall be determined according to the method described in Annex XX.
((i)) ngvmax
ngvmax, the gear in which the maximum vehicle speed is reached and shall be determined as follows:
If vmax(ng) ≥ vmax(ng-1), then,
ngvmax = ng
otherwise, ngvmax = ng-1
where:
vmax(ng)is the vehicle speed at which the required road load power equals the available power, Pwot, in gear ng (see Figure A2/1a).vmax(ng-1)is the vehicle speed at which the required road load power equals the available power, Pwot, in the next lower gear (see Figure A2/1b).
The required road load power, kW, shall be calculated using the following equation:
Prequired=f0× vmax+ f1× v2max+ f2× v3max3600
where:
vmaxis the vehicle speed, km/h.
The available power at vehicle speed vmax in gear ng or gear ng - 1 may be determined from the full load power curve, Pwot(n), by using the following equation:
nng=ndvng× vmaxng; nng− 1=ndvng− 1× vmaxng− 1
and by reducing the power values of the full load power curve by 10 per cent.
Figure A2/1a
Figure A2/1b
((j)) Exclusion of a crawler gear
Gear 1 may be excluded at the request of the manufacturer if all of the following conditions are fulfilled:

((1)) The vehicle does not have a dual-range transmission;
((2)) The vehicle family is homologated to tow a trailer;
((3)) ndv1∕ndvngvmax×vmax× ndvngvmax∕nrated> 7;
((4)) ndv2∕ndvngvmax×vmax× ndvngvmax∕nrated> 4;
((5)) The vehicle, having a mass as defined in the equation below, shall be able to pull away from standstill within 4 seconds, on an uphill gradient of at least 12 per cent, on five separate occasions within a period of 5 minutes.
mr + 25 kg + (MC – mr – 25 kg) × 0,28 (0,15 in the case of category M vehicles).
where:
ndv(ngvmax)is the ratio obtained by dividing the engine speed n by the vehicle speed v for gear ngvmax, min–1/km/h;mris the mass in running order, kg;MCis the gross train mass (gross vehicle mass + max. trailer mass), kg.
In this case, gear 1 is not used when driving the cycle on a chassis dynamometer and the gears shall be renumbered starting with the 2nd gear as gear 1.
((k)) Definition of nmin_drive
nmin_drive is the minimum engine speed when the vehicle is in motion, min–1;
For ngear = 1, nmin_drive = nidle,
For ngear = 2,

((a)) for transitions from 1st to 2nd gear:
nmin_drive = 1,15 ×nidle,
((b)) for decelerations to standstill:
nmin_drive = nidle.
((c)) for all other driving conditions:
nmin_drive = 0,9 × nidle.
For ngear > 2, nmin_drive shall be determined by:
nmin_drive = nidle + 0,125 ×(nrated -nidle).
The final result for nmin_drive shall be rounded to the nearest integer. Example: 1 199,5 becomes 1 200, 1 199,4 becomes 1 199.
Higher values may be used if requested by the manufacturer.
((l)) TM, test mass of the vehicle, kg.

3.  3.1. 
For each second j of the cycle trace, the power required to overcome driving resistance and to accelerate shall be calculated using the following equation:
Prequired,j=f0× vj+ f1× v2j+ f2× v3j3600+kr× aj× vj× TM3600
where:

Prequired,jis the required power at second j, kW;ajis the vehicle acceleration at second j, m/s2, aj=vj+ 1− vj3,6×tj+ 1− tj;kris a factor taking the inertial resistances of the drivetrain during acceleration into account and is set to 1,03.
 3.2. 
For any vj < 1 km/h, it shall be assumed that the vehicle is standing still and the engine speed shall be set to.The gear lever shall be placed in neutral with the clutch engaged except 1 second before beginning an acceleration from standstill where first gear shall be selected with the clutch disengaged.

For each vj ≥ 1 km/h of the cycle trace and each gear i, i = 1 to ngmax, the engine speed, ni,j, shall be calculated using the following equation:
ni,j=ndvi× vj 3.3. 
The following gears may be selected for driving the speed trace at vj:


((a)) all gears i < ngvmax where nmin_drive ≤ ni,j ≤ nmax_95,
((b)) all gears i ≥ ngvmax where nmin_drive ≤ ni,j ≤ nmax(ngvmax)
((c)) gear 1, if n1,j < nmin_drive.

If aj ≤ 0 and ni,j ≤ nidle, ni,j shall be set to nidle and the clutch shall be disengaged.

If aj > 0 and ni,j ≤ (1,15 × nidle), ni,j shall be set to (1,15 × nidle) and the clutch shall be disengaged.
 3.4. 
The available power for each possible gear i and each vehicle speed value of the cycle trace, shall be calculated using the following equation:
Pavailable_i,j=Pwotni,j×1−SM+ ASM
where:

Pratedis the rated power, kW;Pwotis the power available at ni,j at full load condition from the full load power curve;SMis a safety margin accounting for the difference between the stationary full load condition power curve and the power available during transition conditions. SM is set to 10 per cent;ASMis an additional exponential power safety margin, which may be applied at the request of the manufacturer. ASM is fully effective between nidle and nstart, and approaches zero exponentially at nend as described by the following requirements:

If ni,j ≤ nstart, then ASM = ASM0;

If ni,j > nstart, then:
ASM=ASM0× expln0,005∕ASM0×nstart− n∕nstart− nend
ASM0, nstart and nend shall be defined by the manufacturer but shall fulfil the following conditions:

nstart ≥ nidle,

nend > nstart.

If aj > 0 and i = 1 or i = 2 and Pavailable_i,i < Prequired,j, ni,j shall be increased by increments of 1 min–1 until Pavailable_i,i = Prequired,j, and the clutch shall be disengaged.
 3.5. 
The possible gears to be used shall be determined by the following conditions:


((a)) The conditions of paragraph 3.3. are fulfilled, and
((b)) Pavailable_i,i ≥ Prequired,j

The initial gear to be used for each second of the cycle trace is the highest final possible gear, imax. When starting from standstill, only the first gear shall be used.

The lowest final possible gear is imin.

4. 
The initial gear selection shall be checked and modified in order to avoid too frequent gearshifts and to ensure driveability and practicality.

An acceleration phase is a time period of more than 3 seconds with a vehicle speed ≥ 1 km/h and with monotonic increase of vehicle speed. A deceleration phase is a time period of more than 3 seconds with a vehicle speed ≥ 1 km/h and with monotonic decrease of vehicle speed.

Corrections and/or modifications shall be made according to the following requirements:


((a)) If a lower gear is required at a higher vehicle speed during an acceleration phase, the higher gears before shall be corrected to the lower gear.
Example: vj < vj+1 < vj+2 < vj+3 < vj+4 < vj+5 < vj+6. The original calculated gear use is 2, 3, 3, 3, 2, 2, 3. In this case the gear use shall be corrected to 2, 2, 2, 2, 2, 2, 3.
((b)) Gears used during accelerations shall be used for a period of at least 2 seconds (e.g. a gear sequence 1, 2, 3, 3, 3, 3, 3 shall be replaced by 1, 1, 2, 2, 3, 3, 3). Gears shall not be skipped during acceleration phases.
((c)) During a deceleration phase, gears with ngear > 2 shall be used as long as the engine speed does not drop below nmin_drive.
If the duration of a gear sequence is only 1 second, it shall be replaced by gear 0 and the clutch shall be disengaged.
If the duration of a gear sequence is 2 seconds, it shall be replaced by gear 0 for the 1st second and for the 2nd second with the gear that follows after the 2 second period. The clutch shall be disengaged for the 1st second.
Example: A gear sequence 5, 4, 4, 2 shall be replaced by 5, 0, 2, 2.
((d)) The 2nd gear shall be used during a deceleration phase within a short trip of the cycle as long as the engine speed does not drop below (0.9 × nidle).
If the engine speed drops below nidle, the clutch shall be disengaged.
((e)) If the deceleration phase is the last part of a short trip shortly before a stop phase and the 2nd gear would only be used for up to two seconds, the clutch may be either disengaged or the gear lever placed in neutral and the clutch left engaged.
A downshift to first gear is not permitted during those deceleration phases.
((f)) If gear is used for a time sequence of 1 to 5 seconds and the gear prior to this sequence is lower and the gear after this sequence is the same as or lower than the gear before this sequence, the gear for the sequence shall be corrected to the gear before the sequence.
Examples:

((i)) gear sequence i – 1, i, i – 1 shall be replaced by i – 1, i – 1,i – 1;
((ii)) gear sequence i – 1, i, i, i – 1 shall be replaced by i – 1, i – 1, i – 1, i – 1;
((iii)) gear sequence i – 1, i, i,i, i – 1 shall be replaced by i – 1, i – 1,i – 1, i – 1, i – 1;
((iv)) gear sequence i – 1, i, i, i, i, i – 1 shall be replaced by i – 1, i – 1, i – 1, i – 1, i – 1,i – 1;
((v)) gear sequence i – 1, i, i, i, i, i, i – 1 shall be replaced by i – 1, i – 1, i – 1, i – 1, i – 1,i – 1, i – 1.

In all cases (i) to (v), shall be fulfilled;

5. Paragraphs 4.(a) to 4.(f) inclusive shall be applied sequentially, scanning the complete cycle trace in each case. Since modifications to paragraphs 4.(a) to 4.(f) of this Sub-Annex may create new gear use sequences, these new gear sequences shall be checked three times and modified if necessary.
In order to enable the assessment of the correctness of the calculation, the average gear for v ≥ 1 km/h, rounded to four places of decimal, shall be calculated and included in all relevant test reports.

Sub-Annex 3

Sub-Annex 4
1. 
This Sub-Annex describes the determination of the road load of a test vehicle and the transfer of that road load to a chassis dynamometer.

2.  2.1.  2.2. Reference speed points shall start at 20 km/h in incremental steps of 10 km/h and with the highest reference speed according to the following provisions:

((a)) The highest reference speed point shall be 130 km/h or the reference speed point immediately above the maximum speed of the applicable test cycle if this value is less than 130 km/h. In the case that the applicable test cycle contains less than the 4 cycle phases (Low, Medium, High and Extra High) and at the request of the manufacturer and with approval of the approval authority, the highest reference speed may be increased to the reference speed point immediately above the maximum speed of the next higher phase, but no higher than 130 km/h; in this case road load determination and chassis dynamometer setting shall be done with the same reference speed points;
((b)) If a reference speed point applicable for the cycle plus 14 km/h is more than or equal to the maximum vehicle speed vmax, this reference speed point shall be excluded from the coastdown test and from chassis dynamometer setting. The next lower reference speed point shall become the highest reference speed point for the vehicle.
 2.3. Unless otherwise specified, a cycle energy demand shall be calculated according to paragraph 5. of Sub-Annex 7 over the target speed trace of the applicable drive cycle.
 2.4. f0, f1, f2 are the road load coefficients of the road load equation F = f0 + f1 × v + f2 × v2, determined according to this Sub-Annex.
f0is the constant road load coefficient, N;f1is the first order road load coefficient,, N/(km/h);f2is the second order road load coefficient, N/(km/h)2.
Unless otherwise stated, the road load coefficients shall be calculated with a least square regression analysis over the range of the reference speed points.
 2.5.  2.5.1. 
mr is the equivalent effective mass of all the wheels and vehicle components rotating with the wheels on the road while the gearbox is placed in neutral, in kilograms (kg). mr shall be measured or calculated using an appropriate technique agreed upon by the approval authority. Alternatively, mr may be estimated to be 3 per cent of the sum of the mass in running order and 25 kg.
 2.5.2. 
Coastdown times shall be transferred to forces and vice versa by taking into account the applicable test mass plus mr. This shall apply to measurements on the road as well as on a chassis dynamometer.
 2.5.3. 
If the vehicle is tested on a 4 wheel drive dynamometer and if both axles are rotating and influencing the dynamometer measurement results, the equivalent inertia mass of the chassis dynamometer shall be set to the applicable test mass.

Otherwise, the equivalent inertia mass of the chassis dynamometer shall be set to the test mass plus either the equivalent effective mass of the wheels not influencing the measurement results or 50 per cent of mr.

3. 
The manufacturer shall be responsible for the accuracy of the road load coefficients and will ensure this for each production vehicle within the road load family. Tolerances within the road load determination, simulation and calculation methods shall not be used to underestimate the road load of production vehicles. At the request of the approval authority, the accuracy of the road load coefficients of an individual vehicle shall be demonstrated.
 3.1. 
The required overall measurement accuracy shall be as follows:


((a)) Vehicle speed: ± 0,2 km/h with a measurement frequency of at least 10 Hz;
((b)) Time accuracy, precision and resolution: min. ± 10 ms;
((c)) Wheel torque: ± 6 Nm or ± 0,5 per cent of the maximum measured total torque, whichever is greater, for the whole vehicle, with a measurement frequency of at least 10 Hz;
((d)) Wind speed: ± 0,3 m/s, with a measurement frequency of at least 1 Hz;
((e)) Wind direction: ± 3°, with a measurement frequency of at least 1 Hz;
((f)) Atmospheric temperature: ± 1 °C, with a measurement frequency of at least 0,1 Hz;
((g)) Atmospheric pressure: ± 0,3 kPa, with a measurement frequency of at least 0,1 Hz;
((h)) Vehicle mass measured on the same weigh scale before and after the test: ± 10 kg (± 20 kg for vehicles > 4 000 kg);
((i)) Tyre pressure: ± 5 kPa;
((j)) Wheel rotational frequency: ± 0,05 s-1 or 1 per cent, whichever is greater.
 3.2.  3.2.1. 
The wind velocity during a measurement shall remain within ± 2 km/h at the centre of the test section. The possible wind velocity shall be at least 140 km/h.
 3.2.2. 
The air temperature during a measurement shall remain within ± 3 °C at the centre of the test section. The air temperature distribution at the nozzle outlet shall remain within ± 3 °C.
 3.2.3. 
For an equally-spaced 3 by 3 grid over the entire nozzle outlet, the turbulence intensity, Tu, shall not exceed 1 per cent. See Figure A4/1.

Figure A4/1Tu=u′U∞where:Tuis the turbulence intensity;u′is the turbulent velocity fluctuation, m/s;U∞is the free flow velocity, m/s. 3.2.4. 
The vehicle blockage ratio εsb expressed as the quotient of the vehicle frontal area and the area of the nozzle outlet as calculated using the following equation, shall not exceed 0,35.
εsb=AfAnozzle
where:

εsbis the vehicle blockage ratio;Afis the frontal area of the vehicle, m2;Anozzleis the nozzle outlet area, m2.
 3.2.5. 
To properly determine the aerodynamic influence of the wheels, the wheels of the test vehicle shall rotate at such a speed that the resulting vehicle velocity is within a ± 3 km/h tolerance of the wind velocity.
 3.2.6. 
To simulate the fluid flow at the underbody of the test vehicle, the wind tunnel shall have a moving belt extending from the front to the rear of the vehicle. The linear speed of the moving belt shall be within ± 3 km/h of the wind velocity.
 3.2.7. 
At nine equally distributed points over the nozzle area, the root mean square deviation of both angles (Y-, Z-plane) α and β at the nozzle outlet shall not exceed 1°.
 3.2.8. 
At nine equally distributed points over the nozzle outlet area, the standard deviation of the total pressure at the nozzle outlet shall be equal to or less than 0.02.
σ ΔPtq≤0,02
where:

σis the standard deviation of the pressure ratio ΔPtq;ΔPtis the variation of total pressure between the measurement points, N/m2;qis the dynamic pressure, N/ m2.

The absolute difference of the pressure coefficient cp over a distance 3 metres ahead and 3 metres behind the centre of the balance in the empty test section and at a height of the centre of the nozzle outlet shall not deviate more than ± 0,02.
cpx=+ 3m− cpx=− 3m≤0,02
where:

cpis the pressure coefficient.
 3.2.9. 
At x = 0 (balance center point), the wind velocity shall have at least 99 per cent of the inflow velocity 30 mm above the wind tunnel floor.
δ99x= 0 m≤30 mm
where:

δ99is the distance perpendicular to the road, where 99 per cent of free stream velocity is reached (boundary layer thickness).
 3.2.10. 
The restraint system mounting shall not be in front of the vehicle. The relative blockage ratio of the vehicle frontal area due to the restraint system, εrestr, shall not exceed 0,10.
εrestr=ArestrAf
where:

εrestris the relative blockage ratio of the restraint system;Arestris the frontal area of the restraint system projected on the nozzle face, m2;Afis the frontal area of the vehicle, m2.
 3.2.11. 
The inaccuracy of the resulting force in the x-direction shall not exceed ± 5 N. The resolution of the measured force shall be within ± 3 N.
 3.2.12. 
The repeatability of the measured force shall be within ± 3 N.

4.  4.1.  4.1.1.  4.1.1.1. 
The maximum permissible wind conditions for road load determination are described in paragraphs 4.1.1.1.1. and 4.1.1.1.2.

In order to determine the applicability of the type of anemometry to be used, the arithmetic average of the wind speed shall be determined by continuous wind speed measurement, using a recognized meteorological instrument, at a location and height above the road level alongside the test road where the most representative wind conditions will be experienced.

If tests in opposite directions cannot be performed at the same part of the test track (e.g. on an oval test track with an obligatory driving direction), wind speed and direction at each part of the test track shall be measured. In this case the higher measured value determines the type of anemometry to be used and the lower value the criterion for the allowance of waiving of a wind correction.
 4.1.1.1.1. 
Stationary anemometry shall be used only when wind speeds over a period of 5 seconds averages less than 5 m/s and peak wind speeds are less than 8 m/s for less than 2 seconds. In addition, the vector component of the wind speed across the test road shall be less than 2 m/s. Any wind correction shall be calculated as given in paragraph 4.5.3. of this Sub-Annex. Wind correction may be waived when the lowest arithmetic average wind speed is 2 m/s or less.
 4.1.1.1.2. 
For testing with an on-board anemometer, a device shall be used as described in paragraph 4.3.2. of this Sub-Annex. The overall arithmetic average of the wind speed during the test activity over the test road shall be less than 7 m/s with peak wind speeds of less than 10 m/s. In addition, the vector component of the wind speed across the road shall be less than 4 m/s.
 4.1.1.2. 
The atmospheric temperature should be within the range of 5 °C up to and including 35 °C.

If the difference between the highest and the lowest measured temperature during the coastdown test is more than 5 °C, the temperature correction shall be applied separately for each run with the arithmetic average of the ambient temperature of that run.

In that case the values of the road load coefficients f0, f1 and f2 shall be determined and corrected for each individual run. The final set of f0, f1 and f2 values shall be the arithmetic average of the individually corrected coefficients f0, f1 and f2 respectively.

At its option, a manufacturer may choose to perform coastdowns between 1 °C and 5 °C.
 4.1.2. 
The road surface shall be flat, even, clean, dry and free of obstacles or wind barriers that might impede the measurement of the road load, and its texture and composition shall be representative of current urban and highway road surfaces. The longitudinal slope of the test road shall not exceed ± 1 per cent. The local slope between any points 3 metres apart shall not deviate more than ± 0,5 per cent from this longitudinal slope. If tests in opposite directions cannot be performed at the same part of the test track (e.g. on an oval test track with an obligatory driving direction), the sum of the longitudinal slopes of the parallel test track segments shall be between 0 and an upward slope of 0,1 per cent. The maximum camber of the test road shall be 1,5 per cent.
 4.2.  4.2.1. 
Each test vehicle shall conform in all its components with the production series, or, if the vehicle is different from the production vehicle, a full description shall be included in all relevant test reports.
 4.2.1.1. 
A test vehicle (vehicle H) with the combination of road load relevant characteristics (i.e. mass, aerodynamic drag and tyre rolling resistance) producing the highest cycle energy demand shall be selected from the interpolation family (see paragraph 5.6. of this Annex).

If the aerodynamic influence of the different wheel rims within one interpolation family is not known, the selection shall be based on the highest expected aerodynamic drag. As a guideline, the highest aerodynamic drag may be expected for a wheel with a) the largest width, b) the largest diameter, and c) the most open structure design (in that order of importance).

The wheel selection shall be executed without prejudice to the requirement of the highest cycle energy demand.
 4.2.1.2. 
At the request of the manufacturer, the interpolation method may be applied for individual vehicles in the interpolation family (see paragraph 1.2.3.1. of Sub-Annex 6 and paragraph 3.2.3.2. of Sub-Annex 7).

In this case, two test vehicles shall be selected from the interpolation family complying with the requirements of the interpolation method (paragraphs 1.2.3.1. and 1.2.3.2. of Sub-Annex 6).

Test vehicle H shall be the vehicle producing the higher, and preferably highest, cycle energy demand of that selection, test vehicle L the one producing the lower, and preferably lowest, cycle energy demand of that selection.

All items of optional equipment and/or body shapes that are chosen not to be considered in the interpolation method shall be fitted to both test vehicles H and L such that these items of optional equipment produce the highest combination of the cycle energy demand due to their road load relevant characteristics (i.e. mass, aerodynamic drag and tyre rolling resistance).
 4.2.1.3.  4.2.1.3.1. At the request of the manufacturer and upon fulfilling the criteria of paragraph 5.7. of this Annex, the road load values for vehicles H and L of an interpolation family shall be calculated.
 4.2.1.3.2. For the purposes of paragraph 4.2.1.3. of this Sub-Annex, vehicle H of a road load family shall be designated vehicle HR. All references to vehicle H in paragraph 4.2.1. of this Sub-Annex shall be replaced by vehicle HR and all references to an interpolation family in paragraph 4.2.1. of this Sub-Annex shall be replaced by road load family.
 4.2.1.3.3. For the purposes of paragraph 4.2.1.3. of this Sub-Annex, vehicle L of a road load family shall be designated vehicle LR. All references to vehicle L in paragraph 4.2.1. of this Sub-Annex shall be replaced by vehicle LR and all references to an interpolation family in paragraph 4.2.1. of this Sub-Annex shall be replaced by road load family.
 4.2.1.3.4. 
If more than one transmission is included in the road load family, a transmission with the highest power losses shall be used for road load determination.
 4.2.1.3.5. 
The road load of vehicles H (and L) of an interpolation family within the road load family shall be calculated according to paragraphs 3.2.3.2.2. to 3.2.3.2.2.4. inclusive of Sub-Annex 7, by:


((a)) using HR and LR of the road load family instead of H and L as inputs for the equations;
((b)) using the road load parameters (i.e. test mass, Δ(CD × Af) compared to vehicle LR, and tyre rolling resistance) of vehicle H (or L) of the interpolation family as inputs for the "individual vehicle";
((c)) repeating this calculation for each H and L vehicle of every interpolation family within the road load family.

The road load interpolation shall only be applied on those road load relevant characteristics that were identified to be different between test vehicle LR and HR. For other road load relevant characteristic(s), the value of vehicle HR shall apply.
 4.2.1.4. 
A vehicle that fulfils the criteria of paragraph 5.8. of this Annex that is:


((a)) representative of the intended series of complete vehicles to be covered by the road load matrix family in terms of estimated worst CD value and body shape, and
((b)) representative of the intended series of vehicles to be covered by the road load matrix family in terms of estimated average of the mass of optional equipment, shall be used to determine the road load.

In the case that no representative body shape for a complete vehicle can be determined, the test vehicle shall be equipped with a square box with rounded corners with radii of maximum of 25 mm and a width equal to the maximum width of the vehicles covered by the road load matrix family, and a total height of the test vehicle of 3,0 m ± 0,1 m, including the box.

The manufacturer and the approval authority shall agree which vehicle test model is representative.

The vehicle parameters test mass, tyre rolling resistance and frontal area of both a vehicle HM and LM shall be determined in such a way that vehicle HM produces the highest cycle energy demand and vehicle LM the lowest cycle energy from the road load matrix family. The manufacturer and the approval authority shall agree on the vehicle parameters for vehicle HM and LM.

The road load of all individual vehicles of the road load matrix family, including HM and LM, shall be calculated according to paragraph 5.1. of this Sub-Annex.
 4.2.1.5. 
Movable aerodynamic body parts on the test vehicles shall operate during road load determination as intended under WLTP Type 1 test conditions (test temperature, vehicle speed and acceleration range, engine load, etc.).

Every vehicle system that dynamically modifies the vehicle’s aerodynamic drag (e.g. vehicle height control) shall be considered to be a movable aerodynamic body part. Appropriate requirements shall be added if future vehicles are equipped with movable aerodynamic items of optional equipment whose influence on aerodynamic drag justifies the need for further requirements.
 4.2.1.6. 
Before and after the road load determination procedure, the selected vehicle shall be weighed, including the test driver and equipment, to determine the arithmetic average mass, mav. The mass of the vehicle shall be greater than or equal to the test mass of vehicle H or of vehicle L at the start of the road load determination procedure.
 4.2.1.7. 
The test vehicle configuration shall be included in all relevant test reports and shall be used for any subsequent coastdown testing.
 4.2.1.8.  4.2.1.8.1. 
The test vehicle shall be suitably run-in for the purpose of the subsequent test for at least 10 000 but no more than 80 000 km.
 4.2.1.8.1.1. At the request of the manufacturer, a vehicle with a minimum of 3 000 km may be used.
 4.2.1.8.2. 
The vehicle shall conform to the manufacturer’s intended production vehicle specifications regarding tyre pressures described in paragraph 4.2.2.3. of this Sub-Annex, wheel alignment described in paragraph 4.2.1.8.3. of this Sub-Annex, ground clearance, vehicle height, drivetrain and wheel bearing lubricants, and brake adjustment to avoid unrepresentative parasitic drag.
 4.2.1.8.3. 
Toe and camber shall be set to the maximum deviation from the longitudinal axis of the vehicle in the range defined by the manufacturer. If a manufacturer prescribes values for toe and camber for the vehicle, these values shall be used. At the request of the manufacturer, values with higher deviations from the longitudinal axis of the vehicle than the prescribed values may be used. The prescribed values shall be the reference for all maintenance during the lifetime of the vehicle.

Other adjustable wheel alignment parameters (such as caster) shall be set to the values recommended by the manufacturer. In the absence of recommended values, they shall be set to the arithmetic average of the range defined by the manufacturer.

Such adjustable parameters and set values shall be included in all relevant test sheets.
 4.2.1.8.4. 
During the road load determination, the engine compartment cover, luggage compartment cover, manually-operated movable panels and all windows shall be closed.
 4.2.1.8.5. 
If the determination of dynamometer settings cannot meet the criteria described in paragraphs 8.1.3. or 8.2.3. of this Sub-Annex due to non-reproducible forces, the vehicle shall be equipped with a vehicle coastdown mode. The coastdown mode shall be approved by the approval authority and the use of a coastdown mode shall be included in all relevant test reports.
 4.2.1.8.5.1. If a vehicle is equipped with a vehicle coastdown mode, it shall be engaged both during road load determination and on the chassis dynamometer.
 4.2.2.  4.2.2.1. 
The selection of tyres shall be based on paragraph 4.2.1. of this Sub-Annex with their rolling resistances measured according to Annex 6 of UN/ECE Regulation No. 11702 series of amendments.

The rolling resistance coefficients shall be aligned and categorised according to the rolling resistance classes in Regulation (EC) No 1222/2009.

The actual rolling resistance values for the tyres fitted to the test vehicles shall be used to determine the gradient of the interpolation line of the interpolation method in paragraph 3.2.3.2 of Sub-Annex 7. For individual vehicles in the interpolation family, the interpolation method shall be based on the RRC class value for the tyres fitted to an individual vehicle as provided in Table A4/1.


Energy Efficiency Class C1 class value C2 class value C3 class value
A RRC = 5,9 RRC = 4,9 RRC = 3,5
B RRC = 7,1 RRC = 6,1 RRC = 4,5
C RRC = 8,4 RRC = 7,4 RRC = 5,5
D Empty Empty RRC = 6,5
E RRC = 9,8 RRC = 8,6 RRC = 7,5
F RRC = 11,3 RRC = 9,9 RRC = 8,5
G RRC = 12,9 RRC = 11,2 Empty
 4.2.2.2. 
Tyres used for the test shall:


((a)) Not be older than 2 years after the production date;
((b)) Not be specially conditioned or treated (e.g. heated or artificially aged), with the exception of grinding in the original shape of the tread;
((c)) Be run-in on a road for at least 200 km before road load determination;
((d)) Have a constant tread depth before the test between 100 and 80 per cent of the original tread depth at any point over the full tread width of the tyre.
 4.2.2.2.1. After measurement of tread depth, driving distance shall be limited to 500 km. If 500 km are exceeded, tread depth shall be measured again.
 4.2.2.3. 
The front and rear tyres shall be inflated to the lower limit of the tyre pressure range for the respective axle for the selected tyre at the coastdown test mass, as specified by the vehicle manufacturer.
 4.2.2.3.1. 
If the difference between ambient and soak temperature is more than 5 °C, the tyre pressure shall be adjusted as follows:


((a)) The tyres shall be soaked for more than 1 hour at 10 per cent above the target pressure;
((b)) Prior to testing, the tyre pressure shall be reduced to the inflation pressure as specified in paragraph 4.2.2.3. of this Sub-Annex, adjusted for difference between the soaking environment temperature and the ambient test temperature at a rate of 0,8 kPa per 1 °C using the following equation:
Δpt=0,8×Tsoak− Tamb
where:
ΔPtis the tyre pressure adjustment added to the tyre pressure defined in paragraph 4.2.2.3. of this Sub-Annex, kPa;0,8is the pressure adjustment factor, kPa/°C;Tsoakis the tyre soaking temperature, °C;Tambis the test ambient temperature, °C.
((c)) Between the pressure adjustment and the vehicle warm-up, the tyres shall be shielded from external heat sources including sun radiation.
 4.2.3. 
Any instruments shall be installed in such a manner as to minimise their effects on the aerodynamic characteristics of the vehicle.

If the effect of the installed instrument on (CD × Af) is expected to be greater than 0,015 m2, the vehicle with and without the instrument shall be measured in a wind tunnel fulfilling the criterion in paragraph 3.2. of this Sub-Annex. The corresponding difference shall be subtracted from f2. At the request of the manufacturer, and with approval of the approval authority, the determined value may be used for similar vehicles where the influence of the equipment is expected to be the same.
 4.2.4.  4.2.4.1. 
Warming up shall be performed by driving the vehicle only.
 4.2.4.1.1. Before warm-up, the vehicle shall be decelerated with the clutch disengaged or an automatic transmission placed in neutral by moderate braking from 80 to 20 km/h within 5 to 10 seconds. After this braking, there shall be no further actuation or manual adjustment of the braking system.
At the request of the manufacturer and upon approval of the approval authority, the brakes may also be activated after the warm-up with the same deceleration as described in this paragraph and only if necessary.
 4.2.4.1.2. 
All vehicles shall be driven at 90 per cent of the maximum speed of the applicable WLTC. The vehicle may be driven at 90 per cent of the maximum speed of the next higher phase (see Table A4/2) if this phase is added to the applicable WLTC warm-up procedure as defined in paragraph 7.3.4. of this Sub-Annex. The vehicle shall be warmed up for at least 20 minutes until stable conditions are reached.


Vehicle class Applicable WLTC 90 per cent of maximum speed Next higher phase
Class1 Low1 + Medium1 58 km/h NA
Class2 Low2 + Medium2 + High2 + Extra High2 111 km/h NA
Low2 + Medium2 + High2 77 km/h Extra High (111 km/h)
Class3 Low3 + Medium3 + High3 + Extra High3 118 km/h NA
Low3 + Medium3 + High3 88 km/h Extra High (118 km/h)
 4.2.4.1.3. 
Refer to paragraph 4.3.1.4.2. of this Sub-Annex.
 4.3. 
The road load shall be determined by using either the stationary anemometry (paragraph 4.3.1. of this Sub-Annex) or the on-board anemometry (paragraph 4.3.2. of this Sub-Annex) method.
 4.3.1.  4.3.1.1. 
Reference speeds for road load determination shall be selected according to paragraph 2. of this Sub-Annex.
 4.3.1.2. 
During the test, elapsed time and vehicle speed shall be measured at a minimum frequency of 5 Hz.
 4.3.1.3.  4.3.1.3.1. Following the vehicle warm-up procedure described in paragraph 4.2.4. of this Sub-Annex and immediately prior to each test measurement, the vehicle shall be accelerated to 10 to 15 km/h above the highest reference speed and shall be driven at that speed for a maximum of 1 minute. After that, the coastdown shall be started immediately.
 4.3.1.3.2. During coastdown, the transmission shall be in neutral. Any movement of the steering wheel shall be avoided as much as possible, and the vehicle brakes shall not be operated.
 4.3.1.3.3. The test shall be repeated until the coastdown data satisfy the statistical precision requirements as specified in paragraph 4.3.1.4.2.
 4.3.1.3.4. Although it is recommended that each coastdown run be performed without interruption, split runs may be performed if data cannot be collected in a single run for all the reference speed points. For split runs, care shall be taken so that vehicle conditions remain as stable as possible at each split point.
 4.3.1.4.  4.3.1.4.1. The coastdown time corresponding to reference speed as the elapsed time from vehicle speed (vj + 5 km/h) to (vj – 5 km/h) shall be measured.
 4.3.1.4.2. 
pj=h× σjn× Δtj≤0,03

where:

Pjis the statistical precision of the measurements made at reference speed vj;nis the number of pairs of measurements;Δtjis the arithmetic average of the coastdown time at reference speed vj in seconds, given by the equation:

Δtj=n∑ni= 11Δtji

where:

Δtjiis the harmonic arithmetic average coastdown time of the ith pair of measurements at velocity vj, seconds, s, given by the equation:

Δtji=21Δtjai+1Δtjbi

where:

Δtjai and Δtjbiare the coastdown times of the ith measurement at reference speed vj, in seconds, s, in the respective directions a and b;σjis the standard deviation, expressed in seconds, s, defined by:σj=1n− 1∑i= 1nΔtji− Δtpj2his a coefficient given in Table A4/3.


Table A4/3
Coefficient h as function of n
n h h/n n h h/n
3 4,3 2,48 10 2,2 0,73
4 3,2 1,60 11 2,2 0,66
5 2,8 1,25 12 2,2 0,64
6 2,6 1,06 13 2,2 0,61
7 2,5 0,94 14 2,2 0,59
8 2,4 0,85 15 2,2 0,57
9 2,3 0,77    4.3.1.4.3. 
The maximum number of pairs that still fulfil the statistical accuracy as defined in paragraph 4.3.1.4.2. shall be evaluated and the number of rejected pairs of measurement shall not exceed 1/3 of the total number of measurement pairs.
 4.3.1.4.4. 
Fj=13,6×mav+ mr×2× ΔvΔtj

where:

Δtjis the harmonic arithmetic average of alternate coastdown time measurements at velocity vj, seconds, s, given by:Δtj=21Δtja+1Δtjb

where:

Δtja and Δtjb are the arithmetic average coastdown times in directions a and b, respectively, corresponding to reference speed vj, in seconds, s, given by the following two equations:

Δtja=1n∑i= 1nΔtjai

and:

Δtjb=1n∑i= 1nΔtjbi

where:

mavis the arithmetic average of the test vehicle masses at the beginning and end of road load determination, kg;mris the equivalent effective mass of rotating components according to paragraph 2.5.1. of this Sub-Annex;

The coefficients, f0, f1 and f2, and in the road load equation shall be calculated with a least squares regression analysis.

In the case that the tested vehicle is the representative vehicle of a road load matrix family, the coefficient f1 shall be set to zero and the coefficients f0 and f2 shall be recalculated with a least squares regression analysis.
 4.3.2. 
The vehicle shall be warmed up and stabilised according to paragraph 4.2.4. of this Sub-Annex.
 4.3.2.1. 
The on-board anemometer and instrumentation shall be calibrated by means of operation on the test vehicle where such calibration occurs during the warm-up for the test.
 4.3.2.1.1. Relative wind speed shall be measured at a minimum frequency of 1 Hz and to an accuracy of 0.3 m/s. Vehicle blockage shall be accounted for in the calibration of the anemometer.
 4.3.2.1.2. Wind direction shall be relative to the direction of the vehicle. The relative wind direction (yaw) shall be measured with a resolution of 1 degree and an accuracy of 3 degrees; the dead band of the instrument shall not exceed 10 degrees and shall be directed towards the rear of the vehicle.
 4.3.2.1.3. Before the coastdown, the anemometer shall be calibrated for wind speed and yaw offset as specified in ISO 10521-1:2006(E) Annex A.
 4.3.2.1.4. Anemometer blockage shall be corrected for in the calibration procedure as described in ISO 10521-1:2006(E) Annex A in order to minimise its effect.
 4.3.2.2. 
The test vehicle speed range shall be selected according to paragraph 2.2. of this Sub-Annex.
 4.3.2.3. 
During the procedure, elapsed time, vehicle speed, and air velocity (wind speed, direction) relative to the vehicle, shall be measured at a frequency of 5 Hz. Ambient temperature shall be synchronised and sampled at a minimum frequency of 1 Hz.
 4.3.2.4. 
The measurements shall be carried out in opposite directions until a minimum of ten consecutive runs (five in each direction) have been obtained. Should an individual run fail to satisfy the required on-board anemometry test conditions, that run and the corresponding run in the opposite direction shall be rejected. All valid pairs shall be included in the final analysis with a minimum of 5 pairs of coastdown runs. See paragraph 4.3.2.6.10. of this Sub-Annex for statistical validation criteria.

The anemometer shall be installed in a position such that the effect on the operating characteristics of the vehicle is minimised.

The anemometer shall be installed according to one of the options below:


((a)) Using a boom approximately 2 metres in front of the vehicle’s forward aerodynamic stagnation point;
((b)) On the roof of the vehicle at its centreline. If possible, the anemometer shall be mounted within 30 cm from the top of the windshield.
((c)) On the engine compartment cover of the vehicle at its centreline, mounted at the midpoint position between the vehicle front and the base of the windshield.

In all cases, the anemometer shall be mounted parallel to the road surface. In the event that positions (b) or (c) are used, the coastdown results shall be analytically adjusted for the additional aerodynamic drag induced by the anemometer. The adjustment shall be made by testing the coastdown vehicle in a wind tunnel both with and without the anemometer installed in the same position as used on the track., The calculated difference shall be the incremental aerodynamic drag coefficient CD combined with the frontal area, which shall be used to correct the coastdown results.
 4.3.2.4.1. Following the vehicle warm-up procedure described in paragraph 4.2.4. of this Sub-Annex and immediately prior to each test measurement, the vehicle shall be accelerated to 10 to 15 km/h above the highest reference speed and shall be driven at that speed for a maximum of 1 minute. After that, the coastdown shall be started immediately.
 4.3.2.4.2. During a coastdown, the transmission shall be in neutral. Any steering wheel movement shall be avoided as much as possible, and the vehicle’s brakes shall not be operated.
 4.3.2.4.3. It is recommended that each coastdown run be performed without interruption. Split runs may however be performed if data cannot be collected in a single run for all the reference speed points. For split runs, care shall be taken so that vehicle conditions remain as stable as possible at each split point.
 4.3.2.5. 
Symbols used in the on-board anemometer equations of motion are listed in Table A4/4.


Symbol Units Description
Af m2 frontal area of the vehicle
a0 … an degrees-1 Aerodynamic drag coefficients as a function of yaw angle
Am N mechanical drag coefficient
Bm N/(km/h) mechanical drag coefficient
Cm N/(km/h)2 mechanical drag coefficient
CD(Y)  aerodynamic drag coefficient at yaw angle Y
D N drag
Daero N aerodynamic drag
Df N front axle drag (including driveline)
Dgrav N gravitational drag
Dmech N mechanical drag
Dr N rear axle drag (including driveline)
Dtyre N tyre rolling resistance
(dh/ds) — sine of the slope of the track in the direction of travel (+ indicates ascending)
(dv/dt) m/s2 acceleration
g m/s2 gravitational constant
mav kg arithmetic average mass of the test vehicle before and after road load determination
ρ kg/m3 air density
t s time
T K Temperature
v km/h vehicle speed
vr km/h relative wind speed
Y degrees yaw angle of apparent wind relative to direction of vehicle travel
 4.3.2.5.1. 
The general form of the equation of motion is as follows:
− medvdt=Dmech+ Daero+ Dgrav
where:

DmechDtyre + Df + Dr;DaeroDaero=12ρCDYAfv2r;DgravDgrav=m× g×dhds

In the case that the slope of the test track is equal to or less than 0.1 per cent over its length, Dgrav may be set to zero.
 4.3.2.5.2. 
Mechanical drag consisting of separate components representing tyre Dtyre and front and rear axle frictional losses, Df and Dr, including transmission losses) shall be modelled as a three-term polynomial as a function of vehicle speed v as in the equation below:
Dmech=Am+ Bmv+ Cmv2
where:

Am, Bm, and Cm are determined in the data analysis using the least squares method. These constants reflect the combined driveline and tyre drag.

In the case that the tested vehicle is the representative vehicle of a road load matrix family, the coefficient Bm shall be set to zero and the coefficients Am and Cm shall be recalculated with a least squares regression analysis.
 4.3.2.5.3. 
The aerodynamic drag coefficient CD(Y) shall be modelled as a four-term polynomial as a function of yaw angle Y as in the equation below:
CDY=a0+ a1Y+ a2Y2+ a3Y3+ a4Y4
a0 to a4 are constant coefficients whose values are determined in the data analysis.

The aerodynamic drag shall be determined by combining the drag coefficient with the vehicle’s frontal area Af and the relative wind velocity vr:
Daero=12× ρ× Af× v2r× CDYDaero=12× ρ× Af× v2ra0+ a1Y+ a2Y2+ a3Y3+ a4Y4 4.3.2.5.4. 
Through substitution, the final form of the equation of motion becomes:
medvdt=Am+ Bmv+ Cmv2+12× ρ× Af× v2ra0+ a1Y+ a2Y2+ a3Y3+ a4Y4+m× g×dhds 4.3.2.6. 
A three-term equation shall be generated to describe the road load force as a function of velocity, F = A + Bv + Cv2, corrected to standard ambient temperature and pressure conditions, and in still air. The method for this analysis process is described in paragraphs 4.3.2.6.1. to 4.3.2.6.10. inclusive in this Sub-Annex.
 4.3.2.6.1. 
If not previously determined, calibration factors to correct for vehicle blockage shall be determined for relative wind speed and yaw angle. Vehicle speed v, relative wind velocity vr and yaw Y measurements during the warm-up phase of the test procedure shall be recorded. Paired runs in alternate directions on the test track at a constant velocity of 80 km/h shall be performed, and the arithmetic average values of v, vr and Y for each run shall be determined. Calibration factors that minimise the total errors in head and cross winds over all the run pairs, i.e. the sum of (headi – headi+1)2, etc., shall be selected where headi and headi+1 refer to wind speed and wind direction from the paired test runs in opposing directions during the vehicle warm-up/stabilization prior to testing.
 4.3.2.6.2. 
From the data collected during the coastdown runs, values for v, dhdsdvdt, vr2, and Y shall be determined by applying calibration factors obtained in paragraphs 4.3.2.1.3. and 4.3.2.1.4. of this Sub-Annex. Data filtering shall be used to adjust samples to a frequency of 1 Hz.
 4.3.2.6.3. 
Using a linear least squares regression technique, all data points shall be analysed at once to determine Am, Bm, Cm, a0, a1, a2, a3 and given Me and dhdsdvdt, v, vr, and ρ.
 4.3.2.6.4. 
A predicted force medvdt shall be calculated and compared to the observed data points. Data points with excessive deviations, e.g., over three standard deviations, shall be flagged.
 4.3.2.6.5. 
Appropriate data filtering techniques may be applied and the remaining data points shall be smoothed out.
 4.3.2.6.6. 
Data points gathered where yaw angles are greater than ± 20 degrees from the direction of vehicle travel shall be flagged. Data points gathered where relative wind is less than + 5 km/h (to avoid conditions where tailwind speed is higher than vehicle speed) shall also be flagged. Data analysis shall be restricted to vehicle speeds within the speed range selected according to paragraph 4.3.2.2. of this Sub-Annex.
 4.3.2.6.7. 
All data that has not been flagged shall be analysed using a linear least squares regression technique. Given Me and dhdsdvdt, v, vr, and ρ, Am, Bm, Cm, a0, a1, a2, a3 and a4 shall be determined.
 4.3.2.6.8. 
To better separate the vehicle aerodynamic and mechanical drag, a constrained analysis may be applied such that the vehicle’s frontal area, Af, and the drag coefficient, CD, may be fixed if they have been previously determined.
 4.3.2.6.9. 
Equations of motion shall be corrected to reference conditions as specified in paragraph 4.5. of this Sub-Annex.
 4.3.2.6.10. 
The exclusion of each single pair of coastdown runs shall change the calculated road load for each coastdown reference speed vj less than the convergence requirement, for all i and j:
ΔFivj∕Fvj≤0,03n− 1
where:

ΔFi(vj)is the difference between the calculated road load with all coastdown runs and the calculated road load with the ith pair of coastdown runs excluded, N;F(vj)is the calculated road load with all coastdown runs included, N;vjis the reference speed, km/h;nis the number of pairs of coastdown runs, all valid pairs are included.

In the case that the convergence requirement is not met, pairs shall be removed from the analysis, starting with the pair giving the highest change in calculated road load, until the convergence requirement is met, as long as a minimum of 5 valid pairs are used for the final road load determination.
 4.4. 
As an alternative to the coastdown methods, the torque meter method may also be used in which the running resistance is determined by measuring wheel torque on the driven wheels at the reference speed points for time periods of at least 5 seconds.
 4.4.1. 
Wheel torque meters shall be installed between the wheel hub and the rim of each driven wheel, measuring the required torque to keep the vehicle at a constant speed.

The torque meter shall be calibrated on a regular basis, at least once a year, traceable to national or international standards, in order to meet the required accuracy and precision.
 4.4.2.  4.4.2.1. 
Reference speed points for running resistance determination shall be selected according to paragraph 2.2. of this Sub-Annex.

The reference speeds shall be measured in descending order. At the request of the manufacturer, there may be stabilization periods between measurements but the stabilization speed shall not exceed the speed of the next reference speed.
 4.4.2.2. 
Data sets consisting of actual speed vji actual torque Cji and time over a period of at least 5 seconds shall be measured for every vj at a sampling frequency of at least 10 Hz. The data sets collected over one time period for a reference speed vj shall be referred to as one measurement.
 4.4.2.3. 
Prior to the torque meter method test measurement, a vehicle warm-up shall be performed according to paragraph 4.2.4. of this Sub-Annex.

During test measurement, steering wheel movement shall be avoided as much as possible, and the vehicle brakes shall not be operated.

The test shall be repeated until the running resistance data satisfy the measurement precision requirements as specified in paragraph 4.4.3.2. of this Sub-Annex.

Although it is recommended that each test run be performed without interruption, split runs may be performed if data cannot be collected in a single run for all the reference speed points. For split runs, care shall be taken so that vehicle conditions remain as stable as possible at each split point
 4.4.2.4. 
During a measurement at a single reference speed point, the velocity deviation from the arithmetic average velocity, vji–vjm, calculated according to paragraph 4.4.3. of this Sub-Annex, shall be within the values in Table A4/5.

Additionally, the arithmetic average velocity vjm at every reference speed point shall not deviate from the reference speed vj by more than ± 1 km/h or 2 per cent of the reference speed vj, whichever is greater.


Time period, s Velocity deviation, km/h
5 - 10 ± 0,2
10 - 15 ± 0,4
15 - 20 ± 0,6
20 - 25 ± 0,8
25 - 30 ± 1,0
≥ 30 ± 1,2
 4.4.2.5. 
Tests shall be performed under the same temperature conditions as defined in paragraph 4.1.1.2. of this Sub-Annex.
 4.4.3.  4.4.3.1. 
Arithmetic average velocity vjm, in km/h, and arithmetic average torque Cjm, in Nm, of each measurement shall be calculated from the data sets collected in paragraph 4.4.2.2. of this Sub-Annex using the following equations:
vjm=1k∑i= 1kvji
and
Cjm=1k∑i= 1kCji− Cjs
where:

vjiis the actual vehicle speed of the ith data set at reference speed point j, km/h;kis the number of data sets in a single measurement;Cjiis the actual torque of the ith data set, Nm;Cjsis the compensation term for speed drift, Nm, given by the following equation:
Cjs=mst+ mr× αjrj.
Cjs1k∑ki= 1Cji shall be no greater than 0,05 and may be disregarded if αj is not greater than ± 0,005 m/s2;

mstis the test vehicle mass at the start of the measurements and shall be measured immediately before the warm-up procedure and no earlier, kg;mris the equivalent effective mass of rotating components according to paragraph 2.5.1. of this Sub-Annex, kg;rjis the dynamic radius of the tyre determined at a reference point of 80 km/h or at the highest reference speed point of the vehicle if this speed is lower than 80 km/h, calculated according to the following equation:rj=13,6×vjm2× πn

where:

nis the rotational frequency of the driven tyre, s-1;αjis the arithmetic average acceleration, m/s2, which calculated using the following equation:
αj=13,6×k∑ki= 1tivji−∑ki= 1ti∑ki= 1vjik×∑ki= 1t2i−∑ki= 1ti2where:tiis the time at which the ith data set was sampled, s.
 4.4.3.2. 
The measurements shall be carried out in opposite directions until a minimum of three pairs of measurements at each reference speed vi have been obtained, for which Cj– satisfies the precision ρj according to the following equation:
ρj=h× sn×Cj–≤0.03
where:

nis the number pairs of measurements for Cjm;Cj–is the running resistance at the speed vj, Nm, given by the equation:C–j=1n∑ni= 1Cjmi

where:

Cjmiis the arithmetic average torque of the ith pair of measurements at speed vj, Nm, and given by:Cjmi=12×Cjmai+ Cjmbi

where:

Cjmai and Cjmbi are the arithmetic average torques of the ith measurement at speed vj determined in paragraph 4.4.3.1. of this Sub-Annex for each direction, a and b respectively, Nm;

sis the standard deviation, Nm, calculated using the following equation:s=1k− 1∑ki= 1Cjmi−Cj–2;his a coefficient as a function of n as given in Table A4/3 in paragraph 4.3.1.4.2. of this Sub-Annex.
 4.4.4. 
The arithmetic average vehicle speed and arithmetic average torque at each reference speed point shall be calculated using the following equations:
Vjm=½×vjma+ vjmbCjm=½×Cjma+ Cjmb
The following least squares regression curve of arithmetic average running resistance shall be fitted to all the data pairs (vjm, Cjm) at all reference speeds described in paragraph 4.4.2.1. of this Sub-Annex to determine the coefficients c0, c1 and c2.

The coefficients, c0, c1 and c2, and as well as the coastdown times measured on the chassis dynamometer (see paragraph 8.2.4. of this Sub-Annex) shall be included in all relevant test sheets.

In the case that the tested vehicle is the representative vehicle of a road load matrix family, the coefficient c1 shall be set to zero and the coefficients c0 and c2 shall be recalculated with a least squares regression analysis.
 4.5.  4.5.1. 
The correction factor for air resistance K2 shall be determined using the following equation:
K2=T293 K×100 kPaP
where:

Tis the arithmetic average atmospheric temperature of all individual runs, Kelvin (K);Pis the arithmetic average atmospheric pressure, kPa.
 4.5.2. 
The correction factor for rolling resistance, in Kelvin-1 (K-1), may be determined based on empirical data and approved by the approval authority for the particular vehicle and tyre test, or may be assumed to be as follows:
K0=8,6× 10− 3K− 1 4.5.3.  4.5.3.1.  4.5.3.1.1. A wind correction for the absolute wind speed alongside the test road shall be made by subtracting the difference that cannot be cancelled out by alternate runs from the constant term given in paragraph 4.3.1.4.4. of this Sub-Annex, or from c0 given in paragraph 4.4.4. of this Sub-Annex.
 4.5.3.1.2. 
w1=3,62× f2× v2w

or: w2=3,62× c2× v2w

where:

w1is the wind correction resistance for the coastdown method, N;f2is the coefficient of the aerodynamic term determined in paragraph 4.3.1.4.4. of this Sub-Annex;vwis the lower arithmetic average wind speed of opposite directions alongside the test road during the test, m/s;w2is the wind correction resistance for the torque meter method, Nm;c2is the coefficient of the aerodynamic term for the torque meter method determined in paragraph 4.4.4. of this Sub-Annex.
 4.5.3.2. 
In the case that the coastdown method is based on on-board anemometry, w1 and w2 in the equations in paragraph 4.5.3.1.2. shall be set to zero, as the wind correction is already applied according to paragraph 4.3.2. of this Sub-Annex.
 4.5.4. 
The correction factor K1 for the test mass of the test vehicle shall be determined using the following equation:
K1=f0×1−TMmav
where:

f0is a constant term, N;TMis the test mass of the test vehicle, kg;mavis the actual test mass of the test vehicle determined according to paragraph 4.3.1.4.4. of this Sub-Annex, kg.
 4.5.5.  4.5.5.1. The curve determined in paragraph 4.3.1.4.4. of this Sub-Annex shall be corrected to reference conditions as follows:
F*=f0− w1− K1+ f1v×1+ K0T− 20+ K2f2v2where:
F*is the corrected road load, N;f0is the constant term, N;f1is the coefficient of the first order term, N·(h/km);f2is the coefficient of the second order term, N·(h/km)2;K0is the correction factor for rolling resistance as defined in paragraph 4.5.2. of this Sub-Annex;K1is the test mass correction as defined in paragraph 4.5.4.of this Sub-Annex;K2is the correction factor for air resistance as defined in paragraph 4.5.1. of this Sub-Annex;Tis the arithmetic average ambient atmospheric temperature, °C;vis vehicle velocity, km/h;w1is the wind resistance correction as defined in paragraph 4.5.3. of this Sub-Annex, N.
The result of the calculation ((f0 – w1 – K1) × (1 + K0 x (T-20))) shall be used as the target road load coefficient At in the calculation of the chassis dynamometer load setting described in paragraph 8.1. of this Sub-Annex.
The result of the calculation (f1 x (1 + K0 x (T-20))) shall be used as the target road load coefficient Bt in the calculation of the chassis dynamometer load setting described in paragraph 8.1. of this Sub-Annex.
The result of the calculation (K2 x f2) shall be used as the target road load coefficient Ct in the calculation of the chassis dynamometer load setting described in paragraph 8.1. of this Sub-Annex.
 4.5.5.2. The curve determined in paragraph 4.4.4. of this Sub-Annex shall be corrected to reference conditions and measurement equipment installed according to the following procedure.
 4.5.5.2.1. C*=c0− w2− K1+ c1v×1+ K0T− 20+ K2c2v2
where:

C*is the corrected running resistance, Nm;c0is the constant term as determined in paragraph 4.4.4. of this Sub-Annex, Nm;c1is the coefficient of the first order term as determined in paragraph 4.4.4. of this Sub-Annex, Nm (h/km);c2is the coefficient of the second order term as determined in paragraph 4.4.4. of this Sub-Annex, Nm (h/km)2;K0is the correction factor for rolling resistance as defined in paragraph 4.5.2.of this Sub-Annex;K1is the test mass correction as defined in paragraph 4.5.4. of this Sub-Annex;K2is the correction factor for air resistance as defined in paragraph 4.5.1.of this Sub-Annex;vis the vehicle velocity, km/h;Tis the arithmetic average atmospheric temperature, °C;w2is the wind correction resistance as defined in paragraph 4.5.3. of this Sub-Annex.
 4.5.5.2.2. 
If the running resistance is determined according to the torque meter method, the running resistance shall be corrected for effects of the torque measurement equipment installed outside the vehicle on its aerodynamic characteristics.

The running resistance coefficient c2 shall be corrected according to the following equation:
c2corr=K2× c2×1+ΔCD× Af∕CD'× Af'
where,

Δ(CD × Af) = (CD × Af) - (CD’ × Af’)

CD’ × Af’is the product of the aerodynamic drag coefficient multiplied by the frontal area of the vehicle with the torque meter measurement equipment installed measured in a wind tunnel fulfilling the criteria of paragraph 3.2. of this Sub-Annex, m2;CD × Afis the product of the aerodynamic drag coefficient multiplied by the frontal area of the vehicle with the torque meter measurement equipment not installed measured in a wind tunnel fulfilling the criteria of paragraph 3.2. of this Sub-Annex, m2.
 4.5.5.2.3. 
The result of the calculation ((c0 – w2 – K1) × (1 + K0 x (T-20))) shall be used as the target running resistance coefficient at in the calculation of the chassis dynamometer load setting described in paragraph 8.2. of this Sub-Annex.

The result of the calculation (c1 × (1 + K0 × (T-20))) shall be used as the target running resistance coefficient bt in the calculation of the chassis dynamometer load setting described in paragraph 8.2. of this Sub-Annex.

The result of the calculation (c2corr × r) shall be used as the target running resistance coefficient ct in the calculation of the chassis dynamometer load setting described in paragraph 8.2. of this Sub-Annex.

5.  5.1. 
If the road load of the representative vehicle is determined according to a method described in paragraph 4.3. of this Sub-Annex, the road load of an individual vehicle shall be calculated according to paragraph 5.1.1. of this Sub-Annex.

If the running resistance of the representative vehicle is determined according to the method described in paragraph 4.4. of this Sub-Annex, the running resistance of an individual vehicle shall be calculated according to paragraph 5.1.2. of this Sub-Annex.
 5.1.1. For the calculation of the road load of vehicles of a road load matrix family, the vehicle parameters described in paragraph 4.2.1.4. of this Sub-Annex and the road load coefficients of the representative test vehicle determined in paragraphs 4.3. of this Sub-Annex shall be used.
 5.1.1.1. 
Fc=f0+f1× v+f2× v2

where:

Fcis the calculated road load force as a function of vehicle velocity, N;f0is the constant road load coefficient, N, defined by the equation:f0=Max0,05× f0r+ 0,95×f0r× TM/TMr+RR− RRr× 9,81× TM; 0,2× f0r+ 0,8×f0r× TM∕TMr+RR− RRr× 9,81× TMf0ris the constant road load coefficient of the representative vehicle of the road load matrix family, N;f1is the first order road load coefficient and shall be set to zero;f2is the second order road load coefficient, N·(h/km)2, defined by the equation:f2=Max0,05× f2r+ 0,95× f2r× Af∕Afr;0,2× f2r+ 0,8× f2r× Af∕Afrf2ris the second order road load coefficient of the representative vehicle of the road load matrix family, N·(h/km)2;vis the vehicle speed, km/h;TMis the actual test mass of the individual vehicle of the road load matrix family, kg;TMris the test mass of the representative vehicle of the road load matrix family, kg;Afis the frontal area of the individual vehicle of the road load matrix family, m2;Afris the frontal area of the representative vehicle of the road load matrix family, m2;RRis the tyre rolling resistance of the individual vehicle of the road load matrix family, kg/tonne;RRris the tyre rolling resistance of the representative vehicle of the road load matrix family, kg/tonne.
 5.1.2. For the calculation of the running resistance of vehicles of a road load matrix family, the vehicle parameters described in paragraph 4.2.1.4. of this Sub-Annex and the running resistance coefficients of the representative test vehicle determined in paragraphs 4.4. of this Sub-Annex shall be used.
 5.1.2.1. 
Cc=c0+ c1× v+ c2× v2

where:

Ccis the calculated running resistance as a function of vehicle velocity, Nm;c0is the constant running resistance coefficient, Nm, defined by the equation:c0=r'∕1,02× Max0,05− 1,02− c0r∕r'+ 0,95×1,02× c0r∕r'× TM∕TMr+RR− RRr× 9,81× TM;0,2× 1,02× c0r∕r'+ 0,8×1,02× c0r∕r'× TM∕TMr+RR− RRr× 9,81× TMc0ris the constant running resistance coefficient of the representative vehicle of the road load matrix family, Nm;c1is the first order running resistance and shall be set to zero;c2is the second order running resistance coefficient, Nm·(h/km)2, defined by the equation:c2=r'∕1,02× Max0,05× 1,02× c2r∕r'+ 0,95× 1,02× c2r∕r'× Af∕Afr;0,2× 1,02× c2r∕r'+ 0,8× 1,02× c2r∕r'× Af∕Afrc2ris the second order running resistance coefficient of the representative vehicle of the road load matrix family, N·(h/km)2;vis the vehicle speed, km/h;TMis the actual test mass of the individual vehicle of the road load matrix family, kg;TMris the test mass of the representative vehicle of the road load matrix family, kg;Afis the frontal area of the individual vehicle of the road load matrix family, m2,Afris the frontal area of the representative vehicle of the road load matrix family, m2;RRis the tyre rolling resistance of the individual vehicle of the road load matrix family, kg/tonne;RRris the tyre rolling resistance of the representative vehicle of the road load matrix family, kg/tonne;r’is the dynamic radius of the tyre on the chassis dynamometer obtained at 80 km/h, m;1.02is an approximate coefficient compensating for drivetrain losses.
 5.2.  5.2.1. 
For the calculation of a default road load based on vehicle parameters, several parameters such as test mass, width and height of the vehicle shall be used. The default road load Fc shall be calculated for the reference speed points.
 5.2.2. 
Fc=f0+ f1× v+ f2× v2

where:

Fcis the calculated default road load force as a function of vehicle velocity, N;f0is the constant road load coefficient, N, defined by the following equation:f0=0,140× TM;f1is the first order road load coefficient and shall be set to zero;f2is the second order road load coefficient, N·(h/km)2, defined by the following equation:f2=2,8× 10− 6× TM+0,0170× width× height;49vis vehicle velocity, km/h;TMtest mass, kg;widthvehicle width as defined in 6.2. of Standard ISO 612:1978, m;heightvehicle height as defined in 6.3. of Standard ISO 612:1978, m.

6. 
The wind tunnel method is a road load measurement method using a combination of a wind tunnel and a chassis dynamometer or of a wind tunnel and a flat belt dynamometer. The test benches may be separate facilities or integrated with one another.
 6.1.  6.1.1. 

((a)) adding the road load forces measured in a wind tunnel and those measured using a flat belt dynamometer; or
((b)) adding the road load forces measured in a wind tunnel and those measured on a chassis dynamometer.
 6.1.2. Aerodynamic drag shall be measured in the wind tunnel.
 6.1.3. Rolling resistance and drivetrain losses shall be measured using a flat belt or a chassis dynamometer, measuring the front and rear axles simultaneously.
 6.2. 
The results of the wind tunnel method shall be compared to those obtained using the coastdown method to demonstrate qualification of the facilities and included in all relevant test reports.
 6.2.1. Three vehicles shall be selected by the approval authority. The vehicles shall cover the range of vehicles (e.g. size, weight) planned to be measured with the facilities concerned.
 6.2.2. Two separate coastdown tests shall be performed with each of the three vehicles according to paragraph 4.3. of this Sub-Annex, and the resulting road load coefficients, f0, f1 and f2, shall be determined according to that paragraph and corrected according to paragraph 4.5.5. of this Sub-Annex. The coastdown test result of a test vehicle shall be the arithmetic average of the road load coefficients of its two separate coastdown tests. If more than two coastdown tests are necessary to fulfil the approval of facilities' criteria, all valid tests shall be averaged.
 6.2.3. Measurement with the wind tunnel method according to paragraphs 6.3. to 6.7. inclusive of this Sub-Annex shall be performed on the same three vehicles as selected in paragraph 6.2.1. of this Sub-Annex and in the same conditions, and the resulting road load coefficients, f0, f1 and f2, shall be determined.
If the manufacturer chooses to use one or more of the available alternative procedures within the wind tunnel method (i.e. paragraph 6.5.2.1. on preconditioning, paragraphs 6.5.2.2. and 6.5.2.3. on the procedure, and paragraph 6.5.2.3.3. on dynamometer setting), these procedures shall also be used also for the approval of the facilities.
 6.2.4. 
The facility or combination of facilities used shall be approved if both of the following two criteria are fulfilled:


((a)) The difference in cycle energy, expressed as εk, between the wind tunnel method and the coastdown method shall be within ± 0,05 for each of the three vehicles k according to the following equation:
εk=Ek,WTMEk,coastdown− 1
where:
εkis the difference in cycle energy over a complete Class 3 WLTC for vehicle k between the wind tunnel method and the coastdown method, per cent;Ek, WTMis the cycle energy over a complete Class 3 WLTC for vehicle k, calculated with the road load derived from the wind tunnel method (WTM) calculated according to paragraph 5 of Sub-Annex 7, J;Ek, coastdownis the cycle energy over a complete Class 3 WLTC for vehicle k, calculated with the road load derived from the coastdown method calculated according to paragraph 5. of Sub-Annex 7, J.; and
((b)) The arithmetic average x– of the three differences shall be within 0,02.
x–=ε1+ ε2+ ε33
The facility may be used for road load determination for a maximum of two years after the approval has been granted.

Each combination of roller chassis dynamometer or moving belt and wind tunnel shall be approved separately.
 6.3. 
Conditioning and preparation of the vehicle shall be performed according to paragraphs 4.2.1. and 4.2.2. of this Sub-Annex and applies to both the flat belt or roller chassis dynamometers and the wind tunnel measurements.

In the case that the alternative warm-up procedure described in paragraph 6.5.2.1. is applied, the target test mass adjustment, the weighing of the vehicle and the measurement shall all be performed without the driver in the vehicle.

The flat belt or the chassis dynamometer test cells shall have a temperature set point of 20 °C with a tolerance of ± 3 °C. At the request of the manufacturer, the set point may also be 23 °C with a tolerance of ± 3 °C.
 6.4.  6.4.1. 
The wind tunnel design, test methods and the corrections shall provide a value of (CD × Af) representative of the on-road (CD × Af) value and with a repeatability of 0,015 m2.

For all (CD × Af) measurements, the wind tunnel criteria listed in paragraph 3.2. of this Sub-Annex shall be met with the following modifications:


((a)) The solid blockage ratio described in paragraph 3.2.4. of this Sub-Annex shall be less than 25 per cent;
((b)) The belt surface contacting any tyre shall exceed the length of that tyre's contact area by at least 20 per cent and shall be at least as wide as that contact patch;
((c)) The standard deviation of total air pressure at the nozzle outlet described in paragraph 3.2.8. of this Sub-Annex shall be less than 1 per cent;
((d)) The restraint system blockage ratio described in paragraph 3.2.10. of this Sub-Annex shall be less than 3 per cent.
 6.4.2. 
The vehicle shall be in the condition described in paragraph 6.3. of this Sub-Annex.

The vehicle shall be placed parallel to the longitudinal centre line of the tunnel with a maximum deviation of 10 mm.

The vehicle shall be placed with a yaw angle of 0° and with a tolerance of ± 0,1°.

Aerodynamic drag shall be measured for at least for 60 seconds and at a minimum frequency of 5 Hz. Alternatively, the drag may be measured at a minimum frequency of 1 Hz and with at least 300 subsequent samples. The result shall be the arithmetic average of the drag.

In the case that the vehicle has movable aerodynamic body parts, paragraph 4.2.1.5. of this Sub-Annex shall apply. Where movable parts are velocity-dependent, every applicable position shall be measured in the wind tunnel and evidence shall be provided to the approval authority indicating the relationship between reference speed, movable part position, and the corresponding (CD × Af).
 6.5.  6.5.1.  6.5.1.1. 
The wheels shall rotate on flat belts that do not change the rolling characteristics of the wheels compared to those on the road. The measured forces in the x-direction shall include the frictional forces in the drivetrain.
 6.5.1.2. 
The dynamometer shall be equipped with a centring device aligning the vehicle within a tolerance of ± 0.5 degrees of rotation around the z-axis. The restraint system shall maintain the centred drive wheel position throughout the coastdown runs of the road load determination within the following limits:


6.5.1.2.1. Lateral position (y-axis)
The vehicle shall remain aligned in the y-direction and lateral movement shall be minimised.
6.5.1.2.2. Front and rear position (x-axis)
Without prejudice to the requirement of paragraph 6.5.1.2.1. of this Sub-Annex, both wheel axes shall be within ± 10 mm of the belt’s lateral centre lines.
6.5.1.2.3. Vertical force
The restraint system shall be designed so as to impose no vertical force on the drive wheels.
 6.5.1.3. 
Only the reaction force for turning the wheels shall be measured. No external forces shall be included in the result (e.g. force of the cooling fan air, vehicle restraints, aerodynamic reaction forces of the flat belt, dynamometer losses, etc.).

The force in the x-direction shall be measured with an accuracy of ± 5 N.
 6.5.1.4. 
The belt speed shall be controlled with an accuracy of ± 0,1 km/h.
 6.5.1.5. 
The flat belt surface shall be clean, dry and free from foreign material that might cause tyre slippage.
 6.5.1.6. 
A current of air of variable speed shall be blown towards the vehicle. The set point of the linear velocity of the air at the blower outlet shall be equal to the corresponding dynamometer speed above measurement speeds of 5 km/h. The deviation of the linear velocity of the air at the blower outlet shall remain within ± 5 km/h or ± 10 per cent of the corresponding measurement speed, whichever is greater.
 6.5.2. 
The measurement procedure may be performed according to either paragraph 6.5.2.2. or paragraph 6.5.2.3. of this Sub-Annex.
 6.5.2.1. 
The vehicle shall be conditioned on the dynamometer as described in paragraphs 4.2.4.1.1. to 4.2.4.1.3. inclusive of this Sub-Annex.

The dynamometer load setting Fd, for the preconditioning shall be:
Fd=ad+ bd× v+ cd× v2
where:

ad0bd0;cdCD× Af×ρ02×13,62

The equivalent inertia of the dynamometer shall be the test mass.

The aerodynamic drag used for the load setting shall be taken from paragraph 6.7.2. of this Sub-Annex and may be set directly as input. Otherwise, ad, bd, and cd from this paragraph shall be used.

At the request of the manufacturer, as an alternative to paragraph 4.2.4.1.2. of this Sub-Annex, the warm-up may be conducted by driving the vehicle with the flat belt.

In this case, the warm-up speed shall be 110 per cent of the maximum speed of the applicable WLTC and the duration shall exceed 1 200 seconds until the change of measured force over a period of 200 seconds is less than 5 N.
 6.5.2.2.  6.5.2.2.1. The test shall be conducted from the highest to the lowest reference speed point.
 6.5.2.2.2. Immediately after the measurement at the previous speed point, the deceleration from the current to the next applicable reference speed point shall be performed in a smooth transition of approximately 1 m/s2.
 6.5.2.2.3. The reference speed shall be stabilised for at least 4 seconds and for a maximum of 10 seconds. The measurement equipment shall ensure that the signal of the measured force is stabilised after that period.
 6.5.2.2.4. 
The steps in paragraphs 6.5.2.2.2. to 6.5.2.2.4. of this Sub-Annex inclusive shall be repeated for each reference speed.
 6.5.2.3.  6.5.2.3.1. Preconditioning and dynamometer setting shall be performed according to paragraph 6.5.2.1. of this Sub-Annex. Prior to each coastdown, the vehicle shall be driven at the highest reference speed or, in the case that the alternative warm-up procedure is used at 110 per cent of the highest reference speed, for at least 1 minute. The vehicle shall be subsequently accelerated to at least 10 km/h above the highest reference speed and the coastdown shall be started immediately.
 6.5.2.3.2. The measurement shall be performed according to paragraphs 4.3.1.3.1. to 4.3.1.4.4. inclusive of this Sub-Annex. Coasting down in opposite directions is not required and the equation used to calculate Δtji in paragraph 4.3.1.4.2. of this Sub-Annex shall not apply. The measurement shall be stopped after two decelerations if the force of both coastdowns at each reference speed point is within ± 10 N, otherwise at least three coastdowns shall be performed using the criteria set out in paragraph 4.3.1.4.2. of this Sub-Annex.
 6.5.2.3.3. 
fjDyno=fjDecel− cd× v2j

where:

fjDecelis the force determined according to the equation calculating Fj in paragraph 4.3.1.4.4. of this Sub-Annex at reference speed point j, N;cdis the dynamometer set coefficient as defined in paragraph 6.5.2.1. of this Sub-Annex, N/(km/h)2.

Alternatively, at the request of the manufacturer, cd may be set to zero during the coastdown and for calculating fjDyno.
 6.5.2.4. 
The vehicle shall be in the condition described in paragraph 4.3.1.3.2. of this Sub-Annex.

During coastdown, the transmission shall be in neutral. Any movement of the steering wheel shall be avoided as much as possible, and the vehicle brakes shall not be operated.
 6.5.3. 
The result of the flat belt dynamometer fjDyno shall be referred to as fj for the further calculations in paragraph 6.7. of this Sub-Annex.
 6.6.  6.6.1. 
In addition to the descriptions in paragraphs 1. and 2. of Sub-Annex 5, the criteria described in paragraphs 6.6.1.1. to 6.6.1.6. inclusive of this Sub-Annex shall apply.
 6.6.1.1. 
The front and rear axles shall be equipped with a single roller with a diameter of no less than 1.2 metres. The measured forces in the x-direction include the frictional forces in the drivetrain.
 6.6.1.2. 
The dynamometer shall be equipped with a centring device aligning the vehicle. The restraint system shall maintain the centred drive wheel position within the following recommended limits throughout the coastdown runs of the road load determination:


6.6.1.2.1. Vehicle position
The vehicle to be tested shall be installed on the chassis dynamometer roller as defined in paragraph 7.3.3. of this Sub-Annex.
6.6.1.2.2. Vertical force
The restraint system shall fulfil the requirements of paragraph 6.5.1.2.3. of this Sub-Annex.
 6.6.1.3. 
The accuracy of measured forces shall be as described in paragraph 6.5.1.3. of this Sub-Annex apart from the force in the x-direction that shall be measured with an accuracy as described in paragraph 2.4.1. of Sub-Annex 5.
 6.6.1.4. 
The roller speeds shall be controlled with an accuracy of ± 0,2 km/h.
 6.6.1.5. 
The roller surface shall be as described in paragraph 6.5.1.5 of this Sub-Annex.
 6.6.1.6. 
The cooling fan shall be as described in paragraph 6.5.1.6. of this Sub-Annex.
 6.6.2. 
The measurement shall be performed as described in paragraph 6.5.2. of this Sub-Annex.
 6.6.3. 
The measured forces on the chassis dynamometer shall be corrected to a reference equivalent to the road (flat surface) and the result shall be referred to as fj.
fj=fjDyno× c1×1RWheelRDyno× c2+ 1+ fjDyno×1− c1
where:

c1is the tyre rolling resistance fraction of fjDyno;c2is a chassis dynamometer specific radius correction factor;fjDynois the force calculated in paragraph 6.5.2.3.3. for each reference speed j, N;RWheelis one-half of the nominal design tyre diameter, m;RDynois the radius of the chassis dynamometer roller, m.

The manufacturer and approval authority shall agree on the factors c1 and c2 to be used, based on correlation test evidence provided by the manufacturer for the range of tyre characteristics intended to be tested on the chassis dynamometer.

As an alternative the following conservative equation may be used:
fj=fjDyno×1RWheelRDyno× 0,2+ 1 6.7.  6.7.1. 
The measured forces determined in paragraphs 6.5. and 6.6. of this Sub-Annex shall be corrected to reference conditions using the following equation:
FDj=fj− K1×1+ K0T− 293
where:

FDjis the corrected resistance measured at the flat belt or chassis dynamometer at reference speed j, N;fjis the measured force at reference speed j, N;K0is the correction factor for rolling resistance as defined in paragraph 4.5.2. of this Sub-Annex, K-1;K1is the test mass correction as defined in paragraph 4.5.4. of this Sub-Annex, N;Tis the arithmetic average temperature in the test cell during the measurement, K.
 6.7.2. 
The aerodynamic drag shall be calculated using the equation below. If the vehicle is equipped with velocity-dependent movable aerodynamic body parts, the corresponding (CD × Af) values shall be applied for the concerned reference speed points.
FAj=CD× Afj×ρ02×v2j3,62
where:

FAjis the aerodynamic drag measured in the wind tunnel at reference speed j, N;(CD × Af)jis the product of the drag coefficient and frontal area at a certain reference speed point j, where applicable, m2;ρ0is the dry air density defined in paragraph 3.2.10. of this Annex, kg/m3;vjis the reference speed j, km/h.
 6.7.3. 
The total road load as a sum of the results of paragraphs 6.7.1 and 6.7.2. of this Sub-Annex shall be calculated using the following equation:
F*j=FDj+ FAj
for all applicable reference speed points j, N;

For all calculated F*j, the coefficients f0, f1 and f2 in the road load equation shall be calculated with a least squares regression analysis and shall be used as the target coefficients in paragraph 8.1.1. of this Sub-Annex.

In the case that the vehicle(s) tested according to the wind tunnel method is (are) representative of a road load matrix family vehicle, the coefficient f1 shall be set to zero and the coefficients f0 and f2 shall be recalculated with a least squares regression analysis.

7.  7.1.  7.1.1.  7.1.1.1. 
The chassis dynamometer roller(s) shall be clean, dry and free from foreign material that might cause tyre slippage. For chassis dynamometers with multiple rollers, the dynamometer shall be run in the same coupled or uncoupled state as the subsequent Type 1 test. Chassis dynamometer speed shall be measured from the roller coupled to the power absorption unit.
 7.1.1.1.1. 
Additional weight may be placed on or in the vehicle to eliminate tyre slippage. The manufacturer shall perform the load setting on the chassis dynamometer with the additional weight. The additional weight shall be present for both load setting and the emissions and fuel consumption tests. The use of any additional weight shall be included in all relevant test sheets.
 7.1.1.2. 
The laboratory atmospheric temperature shall be at a set point of 23 °C and shall not deviate by more than ± 5 °C during the test unless otherwise required by any subsequent test.
 7.2.  7.2.1. 
The equivalent inertia mass of the chassis dynamometer shall be set according to paragraph 2.5.3. of this Sub-Annex. If the chassis dynamometer is not capable to meet the inertia setting exactly, the next higher inertia setting shall be applied with a maximum increase of 10 kg.
 7.2.2. 
The chassis dynamometer shall be warmed up in accordance with the dynamometer manufacturer’s recommendations, or as appropriate, so that the frictional losses of the dynamometer may be stabilized.
 7.3.  7.3.1. 
The tyre pressure at the soak temperature of a Type 1 test shall be set to no more than 50 per cent above the lower limit of the tyre pressure range for the selected tyre, as specified by the vehicle manufacturer (see paragraph 4.2.2.3. of this Sub-Annex), and shall be included in all relevant test reports.
 7.3.2. If the determination of dynamometer settings cannot meet the criteria described in paragraph 8.1.3. of this Sub-Annex due to non-reproducible forces, the vehicle shall be equipped with a vehicle coastdown mode. The coastdown mode shall be approved by the approval authority and the use of a coastdown mode shall be included in all relevant test reports.
 7.3.2.1. If a vehicle is equipped with a vehicle coastdown mode, it shall be engaged both during road load determination and on the chassis dynamometer.
 7.3.3. 
The tested vehicle shall be placed on the chassis dynamometer in a straight ahead position and restrained in a safe manner. In the case that a single roller chassis dynamometer is used, the centre of the tyre’s contact patch on the roller shall be within ± 25 mm or ± 2 per cent of the roller diameter, whichever is smaller, from the top of the roller.
 7.3.3.1. If the torque meter method is used, the tyre pressure shall be adjusted such that the dynamic radius is within 0.5 per cent of the dynamic radius rj calculated using the equations in paragraph 4.4.3.1. of this Sub-Annex at the 80 km/h reference speed point. The dynamic radius on the chassis dynamometer shall be calculated according to the procedure described in paragraph 4.4.3.1. of this Sub-Annex.
If this adjustment is outside the range defined in paragraph 7.3.1. of this Sub-Annex, the torque meter method shall not apply.
 7.3.4.  7.3.4.1. The vehicle shall be warmed up with the applicable WLTC. In the case that the vehicle was warmed up at 90 per cent of the maximum speed of the next higher phase during the procedure defined in paragraph 4.2.4.1.2. of this Sub-Annex, this higher phase shall be added to the applicable WLTC.

Vehicle class Applicable WLTC Adopt next higher phase Warm-up cycle
Class 1 Low1+ Medium1 NA Low1+ Medium1
Class 2 Low2 + Medium2 + High2 + Extra High2 NA Low2 + Medium2 + High2 + Extra High2
Low2 + Medium2 + High2 Yes (Extra High2)
 No Low2+ Medium2+ High2
Class 3 Low3 + Medium3 + High3 + Extra High3 Low3 + Medium3 + High3 + Extra High3 Low3 + Medium3 + High3 + Extra High3
Low3 + Medium3 + High3 Yes (Extra High3)
 No Low3 + Medium3 + High3
 7.3.4.2. If the vehicle is already warmed up, the WLTC phase applied in paragraph 7.3.4.1. of this Sub-Annex, with the highest speed, shall be driven.
 7.3.4.3.  7.3.4.3.1. At the request of the vehicle manufacturer and with approval of the approval authority, an alternative warm-up procedure may be used. The approved alternative warm-up procedure may be used for vehicles within the same road load family and shall satisfy the requirements outlined in paragraphs 7.3.4.3.2. to 7.3.4.3.5. of this Sub-Annex inclusive.
 7.3.4.3.2. At least one vehicle representing the road load family shall be selected.
 7.3.4.3.3. 
The corrected road load coefficients f0a, f1a and f2a, shall be calculated according to the following equations:

f0a=f0+ Ad_alt− Ad_WLTCf1a=f1+ Bd_alt− Bd_WLTCf2a=f2+ Cd_alt− Cd_WLTC

where:

Ad_alt, Bd_alt and Cd_altare the chassis dynamometer setting coefficients after the alternative warm-up procedure;Ad_WLTC, Bd_WLTC and Cd_WLTCare the chassis dynamometer setting coefficients after a WLTC warm-up procedure described in paragraph 7.3.4.1. of this Sub-Annex and a valid chassis dynamometer setting according to paragraph 8. of this Sub-Annex.
 7.3.4.3.4. The corrected road load coefficients f0a, f1a and f2a, shall be used only for the purpose of paragraph 7.3.4.3.3. of this Sub-Annex. For other purposes, the target road load coefficients f0, f1 and f2, shall be used as the target road load coefficients.
 7.3.4.3.5. Details of the procedure and of its equivalency shall be provided to the approval authority.

8.  8.1. 
This method is applicable when the road load coefficients f0, f1 and f2 have been determined.

In the case of a road load matrix family, this method shall be applied when the road load of the representative vehicle is determined using the coastdown method described in paragraph 4.3. of this Sub-Annex. The target road load values are the values calculated using the method described in paragraph 5.1. of this Sub-Annex.
 8.1.1. 
For a chassis dynamometer with coefficient control, the chassis dynamometer power absorption unit shall be adjusted with the arbitrary initial coefficients, Ad, Bd and Cd, of the following equation:
Fd=Ad+ Bdv+ Cdv2
where:

Fdis the chassis dynamometer setting load, N;vis the speed of the chassis dynamometer roller, km/h.

The following are recommended coefficients to be used for the initial load setting:


((a)) Ad = 0, 5 × At, Bd = 0, 2 × Bt, Cd = Ct
for single-axis chassis dynamometers, or
Ad = 0, 1 × At, Bd = 0, 2 × Bt, Cd = Ct
for dual-axis chassis dynamometers, where, and are the target road load coefficients;
((b)) empirical values, such as those used for the setting for a similar type of vehicle.

For a chassis dynamometer of polygonal control, adequate load values at each reference speed shall be set to the chassis dynamometer power absorption unit.
 8.1.2. 
The coastdown test on the chassis dynamometer shall be performed with the procedure given in paragraph 8.1.3.4.1. or in paragraph 8.1.3.4.2. of this Sub-Annex and shall start no later than 120 seconds after completion of the warm-up procedure. Consecutive coastdown runs shall be started immediately. At the request of the manufacturer and with approval of the approval authority, the time between the warm-up procedure and coastdowns using the iterative method may be extended to ensure a proper vehicle setting for the coastdown. The manufacturer shall provide the approval authority with evidence for requiring additional time and evidence that the chassis dynamometer load setting parameters (e.g. coolant and/or oil temperature, force on a dynamometer) are not affected.
 8.1.3.  8.1.3.1. The target road load value shall be calculated using the target road load coefficient, At, Bt and Ct, for each reference speed, vj:
Ftj=At+ Btvj+ Ctv2jwhere:
At, Bt and Ctare the target road load parameters f0, f1 and f2 respectively;Ftjis the target road load at reference speed vj, N;vjis the jth reference speed, km/h.
 8.1.3.2. The measured road load shall be calculated using the following equation:
Fmj=13,6×TM+ mr×2× ΔvΔtjwhere:
Fmjis the measured road load for each reference speed vj, N;TMis the test mass of the vehicle, kg;mris the equivalent effective mass of rotating components according to paragraph 2.5.1. of this Sub-Annex, kg;Δtjis the coastdown time corresponding to speed vj, s.
 8.1.3.3. The simulated road load on the chassis dynamometer shall be calculated according to the method as specified in paragraph 4.3.1.4. of this Sub-Annex, with the exception of measuring in opposite directions, and with applicable corrections according to paragraph 4.5. of this Sub-Annex, resulting in a simulated road load curve:
Fs=As+ Bs× v+ Cs× v2The simulated road load for each reference speed vj shall be determined using the following equation, using the calculated As, Bs and Cs:
Fsj=As+ Bs× vj+ Cs× v2j 8.1.3.4. For dynamometer load setting, two different methods may be used. If the vehicle is accelerated by the dynamometer, the methods described in paragraph 8.1.3.4.1. of this Sub-Annex shall be used. If the vehicle is accelerated under its own power, the methods in paragraphs 8.1.3.4.1. or 8.1.3.4.2. of this Sub-Annex shall be used. The minimum acceleration multiplied by speed shall be 6 m2/sec3. Vehicles which are unable to achieve 6 m2/s3 shall be driven with the acceleration control fully applied.
 8.1.3.4.1.  8.1.3.4.1.1. The dynamometer software shall perform four coastdowns in total: From the first coastdown, the dynamometer setting coefficients for the second run according to paragraph 8.1.4. of this Sub-Annex shall be calculated. Following the first coastdown, the software shall perform three additional coastdowns with either the fixed dynamometer setting coefficients determined after the first coastdown or the adjusted dynamometer setting coefficients according to paragraph 8.1.4. of this Sub-Annex.
 8.1.3.4.1.2. 
A=At−∑4n= 2Asn− Adn3

B=Bt−∑4n= 2Bsn− Bdn3

C=Ct−∑4n= 2Csn− Cdn3

where:

At, Bt and Ctare the target road load parameters f0, f1 and f2 respectively;Asn, Bsn and Csnare the simulated road load coefficients of the nth run;Adn, Bdn and Cdnare the dynamometer setting coefficients of the nth run;nis the index number of coastdowns including the first stabilisation run.
 8.1.3.4.2. 
The calculated forces in the specified speed ranges shall either be within a tolerance of ± 10 N after a least squares regression of the forces for two consecutive coastdowns, or additional coastdowns shall be performed after adjusting the chassis dynamometer load setting according to paragraph 8.1.4. of this Sub-Annex until the tolerance is satisfied.
 8.1.4. 
The chassis dynamometer setting load shall be adjusted according to the following equations:
F*dj=Fdj− Fj=Fdj− Fsj+ Ftj=Ad+ Bdvj+ Cdv2j−As+ Bsvj+ Csv2j+At+ Btvj+ Ctv2j=Ad+ At− As+Bd+ Bt− Bsvj+Cd+ Ct− Csv2j
Therefore:
A*d=Ad+ At− AsB*d=Bd+ Bt− BsC*d=Cd+ Ct− Cs
where:

Fdjis the initial chassis dynamometer setting load, N;F*djis the adjusted chassis dynamometer setting load, N;Fjis the adjustment road load equal to (Fsj - Ftj), N;Fsjis the simulated road load at reference speed vj, N;Ftjis the target road load at reference speed vj, N;A*d, B*d and C*dare the new chassis dynamometer setting coefficients.
 8.2. 
This method is applicable when the running resistance is determined using the torque meter method described in paragraph 4.4. of this Sub-Annex.

In the case of a road load matrix family, this method shall be applied when the running resistance of the representative vehicle is determined using the torque meter method as specified in paragraph 4.4. of this Sub-Annex. The target road load values are the values calculated using the method specified in paragraph 5.1. of this Sub-Annex.
 8.2.1. 
For a chassis dynamometer of coefficient control, the chassis dynamometer power absorption unit shall be adjusted with the arbitrary initial coefficients, Ad, Bd and Cd, of the following equation:
Fd=Ad+ Bdv+ Cdv2
where:

Fdis the chassis dynamometer setting load, N;vis the speed of the chassis dynamometer roller, km/h.

The following coefficients are recommended for the initial load setting:


((a)) Ad=0,5×atr′, Bd=0,2×btr′, Cd=ctr′
for single-axis chassis dynamometers, or
Ad=0,1×atr′, Bd=0,2×btr′, Cd=ctr′
for dual-axis chassis dynamometers, where:
at, bt and ct are are the target running resistance coefficients; and
r′ is the dynamic radius of the tyre on the chassis dynamometer obtained at 80 km/h, m.; or
((b)) Empirical values, such as those used for the setting for a similar type of vehicle.

For a chassis dynamometer of polygonal control, adequate load values at each reference speed shall be set for the chassis dynamometer power absorption unit.
 8.2.2. 
The torque measurement test on the chassis dynamometer shall be performed with the procedure defined in paragraph 4.4.2. of this Sub-Annex. The torque meter(s) shall be identical to the one(s) used in the preceding road test.
 8.2.3.  8.2.3.1. The target running resistance (torque) curve shall be determined using the equation in paragraph 4.5.5.2.1. of this Sub-Annex and may be written as follows:
C*t=at+ bt× vj+ ct× v2j 8.2.3.2. The simulated running resistance (torque) curve on the chassis dynamometer shall be calculated according to the method described and the measurement precision specified in paragraph 4.4.3. of this Sub-Annex, and the running resistance (torque) curve determination as described in paragraph 4.4.4. of this Sub-Annex with applicable corrections according to paragraph 4.5. of this Sub-Annex, all with the exception of measuring in opposite directions, resulting in a simulated running resistance curve:
C*s=C0s+ C1s× vj+ C2s× v2jThe simulated running resistance (torque) shall be within a tolerance of ± 10 N×r’ from the target running resistance at every speed reference point where r’ is the dynamic radius of the tyre in metres on the chassis dynamometer obtained at 80 km/h.
If the tolerance at any reference speed does not satisfy the criterion of the method described in this paragraph, the procedure specified in paragraph 8.2.3.3. of this Sub-Annex shall be used to adjust the chassis dynamometer load setting.
 8.2.3.3. 
The chassis dynamometer load setting shall be adjusted using the following equation:
F*dj=Fdj−Fejr′=Fdj−Fsjr′+Ftjr′=Ad+ Bdvj+ Cdv2j−as+ bsvj+ csv2jr′+at+ btvj+ ctv2jr′=Ad+at− asr′+Bd+bt− btr′vj+Cd+ct− csr′v2j
therefore:
A*d=Ad+at− asr′B*d=Bd+bt− bsr′C*d=Cd+ct− csr′
where:

F*djis the new chassis dynamometer setting load, N;(Fsj - Ftj), Nm;Fejis the adjustment road load equal to (Fsj-Ftj), Nm;Fsjis the simulated road load at reference speed vj, Nm;Ftjis the target road load at reference speed vj, Nm;A*d, B*d and C*dare the new chassis dynamometer setting coefficients;r’is the dynamic radius of the tyre on the chassis dynamometer obtained at 80 km/h, m.

Paragraphs 8.2.2. and 8.2.3. of this Sub-Annex shall be repeated.
 8.2.3.4. The mass of the driven axle(s), tyre specifications and chassis dynamometer load setting shall be included in all relevant test reports when the requirement of paragraph 8.2.3.2. of this Sub-Annex is fulfilled.
 8.2.4.  8.2.4.1. If the vehicle does not coast down in a repeatable manner and a coastdown mode according to paragraph 4.2.1.8.5. of this Sub-Annex is not feasible, the coefficients f0, f1 and f2 in the road load equation shall be calculated using the equations in paragraph 8.2.4.1.1. of this Sub-Annex. In any other case, the procedure described in paragraphs 8.2.4.2. to 8.2.4.4. inclusive of this Sub-Annex shall be performed.
 8.2.4.1.1. 
f1=c1r× 1,02f2=c2r× 1,02

where:

c0, c1, c2are the running resistance coefficients determined in paragraph 4.4.4. of this Sub-Annex, Nm, Nm/(km/h), Nm/(km/h)2;ris the dynamic tyre radius of the vehicle with which the running resistance was determined, m.1,02is an approximate coefficient compensating for drivetrain losses.
 8.2.4.1.2. 

((a)) determination of downscaling, paragraph 8. of Sub-Annex 1;
((b)) determination of gearshift points, Sub-Annex 2;
((c)) interpolation of CO2 and fuel consumption, paragraph 3.2.3 of Sub-Annex 7;
((d)) calculation of results of electrified vehicles, paragraph 4. in Sub-Annex 8.
 8.2.4.2. Once the chassis dynamometer has been set within the specified tolerances, a vehicle coastdown procedure shall be performed on the chassis dynamometer as outlined in paragraph 4.3.1.3. of this Sub-Annex. The coastdown times shall be included in all relevant test sheets.
 8.2.4.3. 
Fj=13,6×TM+ mr×ΔvΔtj

where:

Fjis the road load at reference speed vj, N;TMis the test mass of the vehicle, kg;mris the equivalent effective mass of rotating components according to paragraph 2.5.1. of this Sub-Annex, kg;Δv= 10 km/hΔtjis the coastdown time corresponding to speed vj, s.
 8.2.4.4. The coefficients f0, f1 and f2 in the road load equation shall be calculated with a least squares regression analysis over the reference speed range.

Sub-Annex 5
1.  1.1.  1.1.1. A variable speed current of air shall be blown towards the vehicle. The set point of the linear velocity of the air at the blower outlet shall be equal to the corresponding roller speed above roller speeds of 5 km/h. The deviation of the linear velocity of the air at the blower outlet shall remain within ± 5 km/h or ± 10 per cent of the corresponding roller speed, whichever is greater.
 1.1.2. 

((a)) For fans with rectangular outlets, are located at the centre of each rectangle dividing the whole of the fan outlet into 9 areas (dividing both horizontal and vertical sides of the fan outlet into 3 equal parts). The centre area shall not be measured (as shown in Figure A5/1);
Figure A5/1
((b)) For fans with circular outlets, the outlet shall be divided into 8 equal sectors by vertical, horizontal and 45° lines. The measurement points shall lie on the radial centre line of each sector (22,5°) at two–thirds of the outlet radius (as shown in Figure A5/2).
Figure A5/2

These measurements shall be made with no vehicle or other obstruction in front of the fan. The device used to measure the linear velocity of the air shall be located between 0 and 20 cm from the air outlet.
 1.1.3. 

((a)) An area of at least 0,3 m2; and
((b)) A width/diameter of at least 0,8 metre.
 1.1.4. 

((a)) Height of the lower edge above ground: approximately 20 cm;
((b)) Distance from the front of the vehicle: approximately 30 cm.
 1.1.5. The height and lateral position of the cooling fan may be modified at the request of the manufacturer and, if considered appropriate, by the approval authority.
 1.1.6. In the cases described in paragraph 1.1.5. of this Sub-Annex, the position of the cooling fan (height and distance) shall be included in all relevant test reports and shall be used for any subsequent testing.

2.  2.1.  2.1.1. The dynamometer shall be capable of simulating road load with three road load coefficients that can be adjusted to shape the load curve.
 2.1.2. The chassis dynamometer may have one or two rollers. In the case that twin-roller chassis dynamometers are used, the rollers shall be permanently coupled or the front roller shall drive, directly or indirectly, any inertial masses and the power absorption device.
 2.2. 
The following specific requirements relate to the dynamometer manufacturer's specifications.
 2.2.1. The roller run-out shall be less than 0,25 mm at all measured locations.
 2.2.2. The roller diameter shall be within ± 1,0 mm of the specified nominal value at all measurement locations.
 2.2.3. The dynamometer shall have a time measurement system for use in determining acceleration rates and for measuring vehicle/dynamometer coastdown times. This time measurement system shall have an accuracy of at least ± 0,001 per cent. This shall be verified upon initial installation.
 2.2.4. The dynamometer shall have a speed measurement system with an accuracy of at least ± 0,080 km/h. This shall be verified upon initial installation.
 2.2.5. The dynamometer shall have a response time (90 per cent response to a tractive effort step change) of less than 100 ms with instantaneous accelerations that are at least 3 m/s2. This shall be verified upon initial installation and after major maintenance.
 2.2.6. The base inertia of the dynamometer shall be stated by the dynamometer manufacturer and shall be confirmed to within ± 0,5 per cent for each measured base inertia and ± 0,2 per cent relative to any arithmetic average value by dynamic derivation from trials at constant acceleration, deceleration and force.
 2.2.7. Roller speed shall be measured at a frequency of not less than 1 Hz.
 2.3.  2.3.1. The 4WD control system shall be designed such that the following requirements are fulfilled when tested with a vehicle driven over the WLTC.
 2.3.1.1. Road load simulation shall be applied such that operation in 4WD mode reproduces the same proportioning of forces as would be encountered when driving the vehicle on a smooth, dry, level road surface.
 2.3.1.2. Upon initial installation and after major maintenance, the requirements of paragraph 2.3.1.2.1. of this Sub-Annex and either paragraph 2.3.1.2.2. or 2.3.1.2.3. of this Sub-Annex shall be satisfied. The speed difference between the front and rear rollers is assessed by applying a 1 second moving average filter to roller speed data acquired at a minimum frequency of 20 Hz.
 2.3.1.2.1. The difference in distance covered by the front and rear rollers shall be less than 0,2 per cent of the distance driven over the WLTC. The absolute number shall be integrated for the calculation of the total difference in distance over the WLTC.
 2.3.1.2.2. The difference in distance covered by the front and rear rollers shall be less than 0,1 m in any 200 ms time period.
 2.3.1.2.3. The speed difference of all roller speeds shall be within +/– 0,16 km/h.
 2.4.  2.4.1. 
The accuracy and linearity of the force transducer shall be at least ± 10 N for all measured increments. This shall be verified upon initial installation, after major maintenance and within 370 days before testing.
 2.4.2. 
The dynamometer's parasitic losses shall be measured and updated if any measured value differs from the current loss curve by more than 9,0 N. This shall be verified upon initial installation, after major maintenance and within 35 days before testing.
 2.4.3. 
The dynamometer performance shall be verified by performing an unloaded coastdown test upon initial installation, after major maintenance, and within 7 days before testing. The arithmetic average coastdown force error shall be less than 10 N or 2 per cent, whichever is greater, at each reference speed point.

3.  3.1.  3.1.1.  3.1.1.1. A full flow exhaust dilution system shall be used. The total vehicle exhaust shall be continuously diluted with ambient air under controlled conditions using a constant volume sampler. A critical flow venturi (CFV) or multiple critical flow venturis arranged in parallel, a positive displacement pump (PDP), a subsonic venturi (SSV), or an ultrasonic flow meter (UFM) may be used. The total volume of the mixture of exhaust and dilution air shall be measured and a continuously proportional sample of the volume shall be collected for analysis. The quantities of exhaust gas compounds shall be determined from the sample concentrations, corrected for their respective content of the dilution air and the totalised flow over the test period.
 3.1.1.2. The exhaust dilution system shall consist of a connecting tube, a mixing device and dilution tunnel, dilution air conditioning, a suction device and a flow measurement device. Sampling probes shall be fitted in the dilution tunnel as specified in paragraphs 4.1., 4.2. and 4.3. of this Sub-Annex.
 3.1.1.3. The mixing device referred to in paragraph 3.1.1.2. of this Sub-Annex shall be a vessel such as that illustrated in Figure A5/3 in which vehicle exhaust gases and the dilution air are combined so as to produce a homogeneous mixture at the sampling position.
 3.2.  3.2.1. The vehicle exhaust gases shall be diluted with a sufficient amount of ambient air to prevent any water condensation in the sampling and measuring system at all conditions that may occur during a test.
 3.2.2. The mixture of air and exhaust gases shall be homogeneous at the point where the sampling probes are located (paragraph 3.3.3. of this Sub-Annex). The sampling probes shall extract representative samples of the diluted exhaust gas.
 3.2.3. The system shall enable the total volume of the diluted exhaust gases to be measured.
 3.2.4. The sampling system shall be gas-tight. The design of the variable dilution sampling system and the materials used in its construction shall be such that the concentration of any compound in the diluted exhaust gases is not affected. If any component in the system (heat exchanger, cyclone separator, suction device, etc.) changes the concentration of any of the exhaust gas compounds and the systematic error cannot be corrected, sampling for that compound shall be carried out upstream from that component.
 3.2.5. All parts of the dilution system in contact with raw or diluted exhaust gas shall be designed to minimise deposition or alteration of the particulate or particles. All parts shall be made of electrically conductive materials that do not react with exhaust gas components, and shall be electrically grounded to prevent electrostatic effects.
 3.2.6. If the vehicle being tested is equipped with an exhaust pipe comprising several branches, the connecting tubes shall be connected as near as possible to the vehicle without adversely affecting their operation.
 3.3.  3.3.1.  3.3.1.1. 
For multiple tailpipe configurations where all the tailpipes are combined, the start of the connecting tube shall be taken at the last joint of where all the tailpipes are combined. In this case, the tube between the exit of the tailpipe and the start of the connecting tube may or may not be insulated or heated.
 3.3.1.2. The connecting tube between the vehicle and dilution system shall be designed so as to minimize heat loss.
 3.3.1.3. 

((a)) Be less than 3.6 metres long, or less than 6.1 metres long if heat-insulated. Its internal diameter shall not exceed 105 mm; the insulating materials shall have a thickness of at least 25 mm and thermal conductivity shall not exceed 0,1 W/m–1K–1 at 400 °C. Optionally, the tube may be heated to a temperature above the dew point. This may be assumed to be achieved if the tube is heated to 70 °C;
((b)) Not cause the static pressure at the exhaust outlets on the vehicle being tested to differ by more than ± 0,75 kPa at 50 km/h, or more than ± 1,25 kPa for the duration of the test from the static pressures recorded when nothing is connected to the vehicle exhaust pipes. The pressure shall be measured in the exhaust outlet or in an extension having the same diameter and as near as possible to the end of the tailpipe. Sampling systems capable of maintaining the static pressure to within ± 0,25 kPa may be used if a written request from a manufacturer to the approval authority substantiates the need for the closer tolerance;
((c)) No component of the connecting tube shall be of a material that might affect the gaseous or solid composition of the exhaust gas. To avoid generation of any particles from elastomer connectors, elastomers employed shall be as thermally stable as possible and have minimum exposure to the exhaust gas. It is recommended not to use elastomer connectors to bridge the connection between the vehicle exhaust and the connecting tube.
 3.3.2.  3.3.2.1. The dilution air used for the primary dilution of the exhaust in the CVS tunnel shall pass through a medium capable of reducing particles of the most penetrating particle size in the filter material by ≤ 99,95 per cent, or through a filter of at least class H13 of EN 1822:2009. This represents the specification of High Efficiency Particulate Air (HEPA) filters. The dilution air may optionally be charcoal-scrubbed before being passed to the HEPA filter. It is recommended that an additional coarse particle filter be situated before the HEPA filter and after the charcoal scrubber, if used.
 3.3.2.2. At the vehicle manufacturer's request, the dilution air may be sampled according to good engineering practice to determine the tunnel contribution to background particulate and particle levels, which can be subsequently subtracted from the values measured in the diluted exhaust. See paragraph 1.2.1.3. of Sub-Annex 6.
 3.3.3.  3.3.3.1. Provision shall be made for the vehicle exhaust gases and the dilution air to be mixed. A mixing device may be used.
 3.3.3.2. The homogeneity of the mixture in any cross-section at the location of the sampling probe shall not vary by more than ± 2 per cent from the arithmetic average of the values obtained for at least five points located at equal intervals on the diameter of the gas stream.
 3.3.3.3. 

((a)) Consists of a straight tube of electrically-conductive material that is grounded;
((b)) Causes turbulent flow (Reynolds number ≥ 4 000) and be of sufficient length to cause complete mixing of the exhaust and dilution air;
((c)) Is at least 200 mm in diameter;
((d)) May be insulated and/or heated.
 3.3.4.  3.3.4.1. 

((a)) Twice as high as the maximum flow of exhaust gas produced by accelerations of the driving cycle; or
((b)) Sufficient to ensure that the CO2 concentration in the dilute exhaust sample bag is less than 3 per cent by volume for petrol and diesel, less than 2.2 per cent by volume for LPG and less than 1.5 per cent by volume for NG/biomethane.
 3.3.4.2. 

((a)) Reducing water content in the dilution air (dilution air dehumidification);
((b)) Heating of the CVS dilution air and of all components up to the diluted exhaust flow measurement device and, optionally, the bag sampling system including the sample bags and also the system for the measurement of the bag concentrations.

In such cases, the selection of the CVS flow rate for the test shall be justified by showing that condensation of water cannot occur at any point within the CVS, bag sampling or analytical system.
 3.3.5.  3.3.5.1. The method of measuring total dilute exhaust volume incorporated in the constant volume sampler shall be such that measurement is accurate to ± 2 per cent under all operating conditions. If the device cannot compensate for variations in the temperature of the mixture of exhaust gases and dilution air at the measuring point, a heat exchanger shall be used to maintain the temperature to within ± 6 °C of the specified operating temperature for a PDP CVS, ± 11 °C for a CFV CVS, ± 6 °C for a UFM CVS, and ± 11 °C for an SSV CVS.
 3.3.5.2. If necessary, some form of protection for the volume measuring device may be used e.g. a cyclone separator, bulk stream filter, etc.
 3.3.5.3. A temperature sensor shall be installed immediately before the volume measuring device. This temperature sensor shall have an accuracy and a precision of ± 1 °C and a response time of 0,1 seconds at 62 per cent of a given temperature variation (value measured in silicone oil).
 3.3.5.4. Measurement of the pressure difference from atmospheric pressure shall be taken upstream from and, if necessary, downstream from the volume measuring device.
 3.3.5.5. The pressure measurements shall have a precision and an accuracy of ± 0,4 kPa during the test. See Table A5/5.
 3.3.6. 
Figure A5/3 is a schematic drawing of exhaust dilution systems that meet the requirements of this Sub-Annex.

The following components are recommended:


((a)) A dilution air filter, which may be pre-heated if necessary. This filter shall consist of the following filters in sequence: an optional activated charcoal filter (inlet side), and a HEPA filter (outlet side). It is recommended that an additional coarse particle filter be situated before the HEPA filter and after the charcoal filter, if used. The purpose of the charcoal filter is to reduce and stabilize the hydrocarbon concentrations of ambient emissions in the dilution air;
((b)) A connecting tube by which vehicle exhaust is admitted into a dilution tunnel;
((c)) An optional heat exchanger as described in paragraph 3.3.5.1. of this Sub-Annex;
((d)) A mixing device in which exhaust gas and dilution air are mixed homogeneously, and which may be located close to the vehicle so that the length of the connecting tube is minimized;
((e)) A dilution tunnel from which particulate and particles are sampled;
((f)) Some form of protection for the measurement system may be used e.g. a cyclone separator, bulk stream filter, etc.;
((g)) A suction device of sufficient capacity to handle the total volume of diluted exhaust gas.

Exact conformity with these figures is not essential. Additional components such as instruments, valves, solenoids and switches may be used to provide additional information and co-ordinate the functions of the component system.

Figure A5/3 3.3.6.1.  3.3.6.1.1. A positive displacement pump (PDP) full flow exhaust dilution system satisfies the requirements of this Sub-Annex by metering the flow of gas through the pump at constant temperature and pressure. The total volume is measured by counting the revolutions made by the calibrated positive displacement pump. The proportional sample is achieved by sampling with pump, flow meter and flow control valve at a constant flow rate.
 3.3.6.2.  3.3.6.2.1. The use of a CFV for the full flow exhaust dilution system is based on the principles of flow mechanics for critical flow. The variable mixture flow rate of dilution and exhaust gas is maintained at sonic velocity that is directly proportional to the square root of the gas temperature. Flow is continually monitored, computed and integrated throughout the test.
 3.3.6.2.2. The use of an additional critical flow sampling venturi ensures the proportionality of the gas samples taken from the dilution tunnel. As both pressure and temperature are equal at the two venturi inlets, the volume of the gas flow diverted for sampling is proportional to the total volume of diluted exhaust gas mixture produced, and thus the requirements of this Sub-Annex are fulfilled.
 3.3.6.2.3. A measuring CFV tube shall measure the flow volume of the diluted exhaust gas.
 3.3.6.3.  3.3.6.3.1. The use of an SSV (Figure A5/4) for a full flow exhaust dilution system is based on the principles of flow mechanics. The variable mixture flow rate of dilution and exhaust gas is maintained at a subsonic velocity that is calculated from the physical dimensions of the subsonic venturi and measurement of the absolute temperature (T) and pressure (P) at the venturi inlet and the pressure in the throat of the venturi. Flow is continually monitored, computed and integrated throughout the test.
 3.3.6.3.2. An SSV shall measure the flow volume of the diluted exhaust gas.

Figure A5/4 3.3.6.4.  3.3.6.4.1. A UFM measures the velocity of the diluted exhaust gas in the CVS piping using the principle of ultrasonic flow detection by means of a pair, or multiple pairs, of ultrasonic transmitters/receivers mounted within the pipe as in Figure A5/5. The velocity of the flowing gas is determined by the difference in the time required for the ultrasonic signal to travel from transmitter to receiver in the upstream direction and the downstream direction. The gas velocity is converted to standard volumetric flow using a calibration factor for the tube diameter with real time corrections for the diluted exhaust temperature and absolute pressure.
 3.3.6.4.2. 

((a)) A suction device fitted with speed control, flow valve or other method for setting the CVS flow rate and also for maintaining constant volumetric flow at standard conditions;
((b)) A UFM;
((c)) Temperature and pressure measurement devices, T and P, required for flow correction;
((d)) An optional heat exchanger for controlling the temperature of the diluted exhaust to the UFM. If installed, the heat exchanger shall be capable of controlling the temperature of the diluted exhaust to that specified in paragraph 3.3.5.1. of this Sub-Annex. Throughout the test, the temperature of the air/exhaust gas mixture measured at a point immediately upstream of the suction device shall be within ± 6 °C of the arithmetic average operating temperature during the test.

Figure A5/5 3.3.6.4.3. 

((a)) The velocity of the diluted exhaust gas shall provide a Reynolds number higher than 4 000 in order to maintain a consistent turbulent flow before the ultrasonic flow meter;
((b)) An ultrasonic flow meter shall be installed in a pipe of constant diameter with a length of 10 times the internal diameter upstream and 5 times the diameter downstream;
((c)) A temperature sensor (T) for the diluted exhaust shall be installed immediately before the ultrasonic flow meter. This sensor shall have an accuracy and a precision of ± 1 °C and a response time of 0,1 seconds at 62 per cent of a given temperature variation (value measured in silicone oil);
((d)) The absolute pressure (P) of the diluted exhaust shall be measured immediately before the ultrasonic flow meter to within ± 0,3 kPa;
((e)) If a heat exchanger is not installed upstream of the ultrasonic flow meter, the flow rate of the diluted exhaust, corrected to standard conditions, shall be maintained at a constant level during the test. This may be achieved by control of the suction device, flow valve or other method.
 3.4.  3.4.1.  3.4.1.1. The CVS system shall be calibrated by using an accurate flow meter and a restricting device and at the intervals listed in Table A5/4. The flow through the system shall be measured at various pressure readings and the control parameters of the system measured and related to the flows. The flow metering device (e.g. calibrated venturi, laminar flow element (LFE), calibrated turbine meter) shall be dynamic and suitable for the high flow rate encountered in constant volume sampler testing. The device shall be of certified accuracy traceable to an approved national or international standard.
 3.4.1.2. The following paragraphs describe methods for calibrating PDP, CFV, SSV and UFM units using a laminar flow meter, which gives the required accuracy, along with a statistical check on the calibration validity.
 3.4.2.  3.4.2.1. The following calibration procedure outlines the equipment, the test configuration and the various parameters that are measured to establish the flow rate of the CVS pump. All the parameters related to the pump are simultaneously measured with the parameters related to the flow meter that is connected in series with the pump. The calculated flow rate (given in m3/min at pump inlet for the measured absolute pressure and temperature) shall be subsequently plotted versus a correlation function that includes the relevant pump parameters. The linear equation that relates the pump flow and the correlation function shall be subsequently determined. In the case that a CVS has a multiple speed drive, a calibration for each range used shall be performed.
 3.4.2.2. 

3.4.2.2.1. The pump pressures shall be measured at tappings on the pump rather than at the external piping on the pump inlet and outlet. Pressure taps that are mounted at the top centre and bottom centre of the pump drive head plate are exposed to the actual pump cavity pressures, and therefore reflect the absolute pressure differentials.
3.4.2.2.2. Temperature stability shall be maintained during the calibration. The laminar flow meter is sensitive to inlet temperature oscillations that cause data points to be scattered. Gradual changes of ± 1 °C in temperature are acceptable as long as they occur over a period of several minutes.
3.4.2.2.3. All connections between the flow meter and the CVS pump shall be free of leakage.
 3.4.2.3. During an exhaust emissions test, the measured pump parameters shall be used to calculate the flow rate from the calibration equation.
 3.4.2.4. 

 Barometric pressure (corrected), Pb ± 0,03 kPa
 Ambient temperature, T ± 0,2 K
 Air temperature at LFE, ETI ± 0,15 K
 Pressure depression upstream of LFE, EPI ± 0,01 kPa
 Pressure drop across the LFE matrix, EDP ± 0,0015 kPa
 Air temperature at CVS pump inlet, PTI ± 0,2 K
 Air temperature at CVS pump outlet, PTO ± 0,2 K
 Pressure depression at CVS pump inlet, PPI ± 0,22 kPa
 Pressure head at CVS pump outlet, PPO ± 0,22 kPa
 Pump revolutions during test period, n ± 1 min–1
 Elapsed time for period (minimum 250 s), t ± 0,1 s

Figure A5/6 3.4.2.5. After the system has been connected as shown in Figure A5/6., the variable restrictor shall be set in the wide-open position and the CVS pump shall run for 20 minutes before starting the calibration.
 3.4.2.5.1. The restrictor valve shall be reset to a more restricted condition in increments of pump inlet depression (about 1 kPa) that will yield a minimum of six data points for the total calibration. The system shall be allowed to stabilize for 3 minutes before the data acquisition is repeated.
 3.4.2.5.2. The air flow rate Qs at each test point shall be calculated in standard m3/min from the flow meter data using the manufacturer's prescribed method.
 3.4.2.5.3. 
V0=Qsn×Tp273,15 K×101,325 kPaPp

where:

V0is the pump flow rate at Tp and Pp, m3/rev;Qsis the air flow at 101,325 kPa and 273,15 K (0 °C), m3/min;Tpis the pump inlet temperature, Kelvin (K);Ppis the absolute pump inlet pressure, kPa;nis the pump speed, min–1.
 3.4.2.5.4. 
x0=1nΔPpPe

where:

x0is the correlation function;ΔPpis the pressure differential from pump inlet to pump outlet, kPa;Peabsolute outlet pressure (PPO + Pb), kPa.

A linear least squares fit shall be performed to generate the calibration equations having the following form:

V0=D0− M× x0

n=A− B× ΔPp

where B and M are the slopes, and A and D0 are the intercepts of the lines.
 3.4.2.6. A CVS system having multiple speeds shall be calibrated at each speed used. The calibration curves generated for the ranges shall be approximately parallel and the intercept values, D0 shall increase as the pump flow range decreases.
 3.4.2.7. The calculated values from the equation shall be within 0.5 per cent of the measured value of V0. Values of M will vary from one pump to another. A calibration shall be performed at initial installation and after major maintenance.
 3.4.3.  3.4.3.1. 
Qs=KvPT

where:

Qsis the flow, m3/min;Kvis the calibration coefficient;Pis the absolute pressure, kPa;Tis the absolute temperature, Kelvin (K).

Gas flow is a function of inlet pressure and temperature.

The calibration procedure described in paragraph 3.4.3.2. to 3.4.3.3.3.4. inclusive of this Sub-Annex establishes the value of the calibration coefficient at measured values of pressure, temperature and air flow.
 3.4.3.2. 

 Barometric pressure (corrected), Pb ± 0,03 kPa,
 LFE air temperature, flow meter, ETI ± 0,15 K,
 Pressure depression upstream of LFE, EPI ± 0,01 kPa,
 Pressure drop across LFE matrix, EDP ± 0,0015 kPa,
 Air flow, Qs± 0,5 per cent,
 CFV inlet depression, PPI ± 0,02 kPa,
 Temperature at venturi inlet, Tv ± 0,2 K.
 3.4.3.3. The equipment shall be set up as shown in Figure A5/7 and checked for leaks. Any leaks between the flow-measuring device and the critical flow venturi will seriously affect the accuracy of the calibration and shall therefore be prevented.

Figure A5/7 3.4.3.3.1. The variable-flow restrictor shall be set to the open position, the suction device shall be started and the system stabilized. Data from all instruments shall be collected.
 3.4.3.3.2. The flow restrictor shall be varied and at least eight readings across the critical flow range of the venturi shall be made.
 3.4.3.3.3. The data recorded during the calibration shall be used in the following calculation:
 3.4.3.3.3.1. 
Values of the calibration coefficient shall be calculated for each test point:

Kv=QsTvPv

where:

Qsis the flow rate, m3/min at 273,15 K (0 °C) and 101,325, kPa;Tvis the temperature at the venturi inlet, Kelvin (K);Pvis the absolute pressure at the venturi inlet, kPa.
 3.4.3.3.3.2. Kv shall be plotted as a function of venturi inlet pressure Pv. For sonic flow Kv will have a relatively constant value. As pressure decreases (vacuum increases), the venturi becomes unchoked and Kv decreases. These values of Kv shall not be used for further calculations.
 3.4.3.3.3.3. For a minimum of eight points in the critical region, an arithmetic average Kv and the standard deviation shall be calculated.
 3.4.3.3.3.4. If the standard deviation exceeds 0,3 per cent of the arithmetic average Kv, corrective action shall be taken.
 3.4.4.  3.4.4.1. Calibration of the SSV is based upon the flow equation for a subsonic venturi. Gas flow is a function of inlet pressure and temperature, and the pressure drop between the SSV inlet and throat.
 3.4.4.2.  3.4.4.2.1. 
Cd=QSSVd2V× pp×1T×r1,426p− r1,718p×11− r4D× r1,426p

where:

Qssvis the airflow rate at standard conditions (101,325 kPa, 273,15 K (0 °C)), m3/s;Tis the temperature at the venturi inlet, Kelvin (K);dVis the diameter of the SSV throat, m;rpis the ratio of the SSV throat pressure to inlet absolute static pressure, 1−Δppp;rDis the ratio of the SSV throat diameter, dV, to the inlet pipe inner diameter D;Cdis the discharge coefficient of the SSV;Ppis the absolute pressure at venturi inlet, kPa.

To determine the range of subsonic flow, Cd shall be plotted as a function of Reynolds number Re at the SSV throat. The Reynolds number at the SSV throat shall be calculated using the following equation:

Re=A1×QSSVdV× μ

where:

μ=b× T1.5S+ T

A1is 25.55152 in SI, 1m3minsmmm;Qssvis the airflow rate at standard conditions (101,325 kPa, 273,15 K (0 °C)), m3/s;dvis the diameter of the SSV throat, m;μis the absolute or dynamic viscosity of the gas, kg/ms;bis 1,458 × 106 (empirical constant), kg/ms K0.5;Sis 110,4 (empirical constant), Kelvin (K).
 3.4.4.2.2. Because QSSV is an input to the Re equation, the calculations shall be started with an initial guess for QSSV or Cd of the calibration venturi, and repeated until QSSV converges. The convergence method shall be accurate to at least 0.1 per cent.
 3.4.4.2.3. For a minimum of sixteen points in the region of subsonic flow, the calculated values of Cd from the resulting calibration curve fit equation shall be within ± 0,5 per cent of the measured Cd for each calibration point.
 3.4.5.  3.4.5.1. The UFM shall be calibrated against a suitable reference flow meter.
 3.4.5.2. The UFM shall be calibrated in the CVS configuration that will be used in the test cell (diluted exhaust piping, suction device) and checked for leaks. See Figure A5/8.
 3.4.5.3. A heater shall be installed to condition the calibration flow in the event that the UFM system does not include a heat exchanger.
 3.4.5.4. For each CVS flow setting that will be used, the calibration shall be performed at temperatures from room temperature to the maximum that will be experienced during vehicle testing.
 3.4.5.5. The manufacturer's recommended procedure shall be followed for calibrating the electronic portions (temperature (T) and pressure (P) sensors) of the UFM.
 3.4.5.6. Measurements for flow calibration of the ultrasonic flow meter are required and the following data (in the case that a laminar flow element is used) shall be found within the limits of precision given:

 Barometric pressure (corrected), Pb ± 0,03 kPa,
 LFE air temperature, flow meter, ETI ± 0,15 K,
 Pressure depression upstream of LFE, EPI ± 0,01 kPa,
 Pressure drop across (EDP) LFE matrix ± 0,0015 kPa,
 Air flow, Qs ± 0,5 per cent,
 UFM inlet depression, Pact ± 0,02 kPa,
 Temperature at UFM inlet, Tact ± 0,2 K.
 3.4.5.7.  3.4.5.7.1. The equipment shall be set up as shown in Figure A5/8 and checked for leaks. Any leaks between the flow-measuring device and the UFM will seriously affect the accuracy of the calibration.

Figure A5/8 3.4.5.7.2. The suction device shall be started. Its speed and/or the position of the flow valve shall be adjusted to provide the set flow for the validation and the system stabilised. Data from all instruments shall be collected.
 3.4.5.7.3. For UFM systems without a heat exchanger, the heater shall be operated to increase the temperature of the calibration air, allowed to stabilise and data from all the instruments recorded. The temperature shall be increased in reasonable steps until the maximum expected diluted exhaust temperature expected during the emissions test is reached.
 3.4.5.7.4. The heater shall be subsequently turned off and the suction device speed and/or flow valve shall be adjusted to the next flow setting that will be used for vehicle emissions testing after which the calibration sequence shall be repeated.
 3.4.5.8. The data recorded during the calibration shall be used in the following calculations. The air flow rate Qs at each test point shall be calculated from the flow meter data using the manufacturer's prescribed method.
Kv=QreferenceQswhere:
Qsis the air flow rate at standard conditions (101,325 kPa, 273,15 K (0 °C)), m3/s;Qreferenceis the air flow rate of the calibration flow meter at standard conditions (101,325 kPa, 273,15 K (0 °C)), m3/s;Kvis the calibration coefficient.
For UFM systems without a heat exchanger, Kv shall be plotted as a function of Tact.
The maximum variation in Kv shall not exceed 0,3 per cent of the arithmetic average Kv value of all the measurements taken at the different temperatures.
 3.5.  3.5.1.  3.5.1.1. The total accuracy of the CVS sampling system and analytical system shall be determined by introducing a known mass of an emissions gas compound into the system whilst it is being operated under normal test conditions and subsequently analysing and calculating the emission gas compounds according to the equations of Sub-Annex 7. The CFO method described in paragraph 3.5.1.1.1. of this Sub-Annex and the gravimetric method described in paragraph 3.5.1.1.2. of this Sub-Annex are both known to give sufficient accuracy.
The maximum permissible deviation between the quantity of gas introduced and the quantity of gas measured is 2 per cent.
 3.5.1.1.1. 
The CFO method meters a constant flow of pure gas (CO, CO2, or C3H8) using a critical flow orifice device.
 3.5.1.1.1.1. A known mass of pure carbon monoxide, carbon dioxide or propane gas shall be introduced into the CVS system through the calibrated critical orifice. If the inlet pressure is high enough, the flow rate q which is restricted by means of the critical flow orifice, is independent of orifice outlet pressure (critical flow). The CVS system shall be operated as in a normal exhaust emissions test and enough time shall be allowed for subsequent analysis. The gas collected in the sample bag shall be analysed by the usual equipment (paragraph 4.1. of this Sub-Annex) and the results compared to the concentration of the known gas samples If deviations exceed 2 per cent, the cause of the malfunction shall be determined and corrected.
 3.5.1.1.2. 
The gravimetric method weighs a quantity of pure gas (CO, CO2, or C3H8).
 3.5.1.1.2.1. The weight of a small cylinder filled with either pure carbon monoxide, carbon dioxide or propane shall be determined with a precision of ± 0,01 g. The CVS system shall operate under normal exhaust emissions test conditions while the pure gas is injected into the system for a time sufficient for subsequent analysis. The quantity of pure gas involved shall be determined by means of differential weighing. The gas accumulated in the bag shall be analysed by means of the equipment normally used for exhaust gas analysis as described in paragraph 4.1. of this Sub-Annex). The results shall be subsequently compared to the concentration figures computed previously. If deviations exceed 2 per cent, the cause of the malfunction shall be determined and corrected.

4.  4.1.  4.1.1.  4.1.1.1. A continuously proportional sample of the diluted exhaust gases and the dilution air shall be collected for analysis.
 4.1.1.2. The mass of gaseous emissions shall be determined from the proportional sample concentrations and the total volume measured during the test. Sample concentrations shall be corrected to take into account the respective compound concentrations in dilution air.
 4.1.2.  4.1.2.1. The sample of diluted exhaust gases shall be taken upstream from the suction device.
 4.1.2.1.1. With the exception of paragraph 4.1.3.1. (hydrocarbon sampling system), paragraph 4.2. (PM measurement equipment) and paragraph 4.3. (PN measurement equipment) of this Sub-Annex, the dilute exhaust gas sample may be taken downstream of the conditioning devices (if any).
 4.1.2.2. The bag sampling flow rate shall be set to provide sufficient volumes of dilution air and diluted exhaust in the CVS bags to allow concentration measurement and shall not exceed 0,3 per cent of the flow rate of the dilute exhaust gases, unless the diluted exhaust bag fill volume is added to the integrated CVS volume.
 4.1.2.3. A sample of the dilution air shall be taken near the dilution air inlet (after the filter if one is fitted).
 4.1.2.4. The dilution air sample shall not be contaminated by exhaust gases from the mixing area.
 4.1.2.5. The sampling rate for the dilution air shall be comparable to that used for the dilute exhaust gases.
 4.1.2.6. The materials used for the sampling operations shall be such as not to change the concentration of the emissions compounds.
 4.1.2.7. Filters may be used in order to extract the solid particles from the sample.
 4.1.2.8. Any valve used to direct the exhaust gases shall be of a quick-adjustment, quick-acting type.
 4.1.2.9. Quick-fastening, gas-tight connections may be used between three-way valves and the sample bags, the connections sealing themselves automatically on the bag side. Other systems may be used for conveying the samples to the analyser (e.g. three-way stop valves).
 4.1.2.10.  4.1.2.10.1. The gas samples shall be collected in sample bags of sufficient capacity so as not to impede the sample flow.
 4.1.2.10.2. The bag material shall be such as to affect neither the measurements themselves nor the chemical composition of the gas samples by more than ± 2 per cent after 30 minutes (e.g., laminated polyethylene/polyamide films, or fluorinated polyhydrocarbons).
 4.1.3.  4.1.3.1.  4.1.3.1.1. The hydrocarbon sampling system shall consist of a heated sampling probe, line, filter and pump. The sample shall be taken upstream of the heat exchanger (if fitted). The sampling probe shall be installed at the same distance from the exhaust gas inlet as the particulate sampling probe and in such a way that neither interferes with samples taken by the other. It shall have a minimum internal diameter of 4 mm.
 4.1.3.1.2. All heated parts shall be maintained at a temperature of 190 °C ± 10 °C by the heating system.
 4.1.3.1.3. The arithmetic average concentration of the measured hydrocarbons shall be determined by integration of the second-by-second data divided by the phase or test duration.
 4.1.3.1.4. The heated sampling line shall be fitted with a heated filter FH having a 99 per cent efficiency for particles ≥ 0,3 μm to extract any solid particles from the continuous flow of gas required for analysis.
 4.1.3.1.5. The sampling system delay time (from the probe to the analyser inlet) shall be no more than 4 seconds.
 4.1.3.1.6. The HFID shall be used with a constant mass flow (heat exchanger) system to ensure a representative sample, unless compensation for varying CVS volume flow is made.
 4.1.3.2.  4.1.3.2.1. A continuous sample flow of diluted exhaust gas shall be supplied to the analyser.
 4.1.3.2.2. The arithmetic average concentration of the NO or NO2 shall be determined by integration of the second-by-second data divided by the phase or test duration.
 4.1.3.2.3. The continuous NO or NO2 measurement shall be used with a constant flow (heat exchanger) system to ensure a representative sample, unless compensation for varying CVS volume flow is made.
 4.1.4.  4.1.4.1.  4.1.4.1.1. The analysers shall have a measuring range compatible with the accuracy required to measure the concentrations of the exhaust gas sample compounds.
 4.1.4.1.2. If not defined otherwise, measurement errors shall not exceed ± 2 per cent (intrinsic error of analyser) disregarding the reference value for the calibration gases.
 4.1.4.1.3. The ambient air sample shall be measured on the same analyser with the same range.
 4.1.4.1.4. No gas drying device shall be used before the analysers unless it is shown to have no effect on the content of the compound in the gas stream.
 4.1.4.2.  4.1.4.2.1. The analysers shall be of the non-dispersive infrared (NDIR) absorption type.
 4.1.4.3.  4.1.4.3.1. The analyser shall be of the flame ionization (FID) type calibrated with propane gas expressed in equivalent carbon atoms (C1).
 4.1.4.4.  4.1.4.4.1. The analyser shall be of the heated flame ionization type with detector, valves, pipework, etc., heated to 190 °C ± 10 °C. It shall be calibrated with propane gas expressed equivalent to carbon atoms (C1).
 4.1.4.5.  4.1.4.5.1. The analyser shall be either a gas chromatograph combined with a flame ionization detector (FID), or a flame ionization detector (FID) combined with a non-methane cutter (NMC-FID), calibrated with methane or propane gas expressed equivalent to carbon atoms (C1).
 4.1.4.6.  4.1.4.6.1. The analysers shall be of chemiluminescent (CLA) or non-dispersive ultra-violet resonance absorption (NDUV) types.
 4.1.5.  4.1.5.1. Figure A5/9 is a schematic drawing of the gaseous emissions sampling system.

Figure A5/9 4.1.5.2. Examples of system components are as listed below.
 4.1.5.2.1. Two sampling probes for continuous sampling of the dilution air and of the diluted exhaust gas/air mixture.
 4.1.5.2.2. A filter to extract solid particles from the flows of gas collected for analysis.
 4.1.5.2.3. Pumps and flow controller to ensure constant uniform flow of diluted exhaust gas and dilution air samples taken during the course of the test from sampling probes and flow of the gas samples shall be such that, at the end of each test, the quantity of the samples is sufficient for analysis.
 4.1.5.2.4. Quick-acting valves to divert a constant flow of gas samples into the sample bags or to the outside vent.
 4.1.5.2.5. Gas-tight, quick-lock coupling elements between the quick-acting valves and the sample bags. The coupling shall close automatically on the sampling bag side. As an alternative, other methods of transporting the samples to the analyser may be used (three-way stopcocks, for instance).
 4.1.5.2.6. Bags for collecting samples of the diluted exhaust gas and of the dilution air during the test.
 4.1.5.2.7. A sampling critical flow venturi to take proportional samples of the diluted exhaust gas (CFV-CVS only).
 4.1.5.3. Additional components required for hydrocarbon sampling using a heated flame ionization detector (HFID) as shown in Figure A5/10.
 4.1.5.3.1. Heated sample probe in the dilution tunnel located in the same vertical plane as the particulate and particle sample probes.
 4.1.5.3.2. Heated filter located after the sampling point and before the HFID.
 4.1.5.3.3. Heated selection valves between the zero/calibration gas supplies and the HFID.
 4.1.5.3.4. Means of integrating and recording instantaneous hydrocarbon concentrations.
 4.1.5.3.5. Heated sampling lines and heated components from the heated probe to the HFID.

Figure A5/10 4.2.  4.2.1.  4.2.1.1.  4.2.1.1.1. The particulate sampling unit shall consist of a sampling probe (PSP), located in the dilution tunnel, a particle transfer tube (PTT), a filter holder(s) (FH), pump(s), flow rate regulators and measuring units. See Figures A5/11, A5/12 and A5/13.
 4.2.1.1.2. A particle size pre-classifier (PCF), (e.g. cyclone or impactor) may be used. In such case, it is recommended that it be employed upstream of the filter holder.

Figure A5/11 4.2.1.2.  4.2.1.2.1. The sampling probe for the test gas flow for particulate shall be arranged within the dilution tunnel so that a representative sample gas flow can be taken from the homogeneous air/exhaust mixture and shall be upstream of a heat exchanger (if any).
 4.2.1.2.2. The particulate sample flow rate shall be proportional to the total mass flow of diluted exhaust gas in the dilution tunnel to within a tolerance of ± 5 per cent of the particulate sample flow rate. The verification of the proportionality of the particulate sampling shall be made during the commissioning of the system and as required by the approval authority.
 4.2.1.2.3. 
In the event that the 52 °C limit is exceeded during a test where periodic regeneration event does not occur, the CVS flow rate shall be increased or double dilution shall be applied (assuming that the CVS flow rate is already sufficient so as not to cause condensation within the CVS, sample bags or analytical system).
 4.2.1.2.4. The particulate sample shall be collected on a single filter mounted within a holder in the sampled dilute exhaust gas flow.
 4.2.1.2.5. All parts of the dilution system and the sampling system from the exhaust pipe up to the filter holder that are in contact with raw and diluted exhaust gas shall be designed to minimise deposition or alteration of the particulate. All parts shall be made of electrically conductive materials that do not react with exhaust gas components, and shall be electrically grounded to prevent electrostatic effects.
 4.2.1.2.6. If it is not possible to compensate for variations in the flow rate, provision shall be made for a heat exchanger and a temperature control device as specified in paragraphs 3.3.5.1. or 3.3.6.4.2. of this Sub-Annex, so as to ensure that the flow rate in the system is constant and the sampling rate accordingly proportional.
 4.2.1.2.7. Temperatures required for the measurement of PM shall be measured with an accuracy of ± 1 °C and a response time (t10 – t90) of 15 seconds or less.
 4.2.1.2.8. 
The accuracy specified above of the sample flow from the CVS tunnel is also applicable where double dilution is used. Consequently, the measurement and control of the secondary dilution air flow and diluted exhaust flow rates through the filter shall be of a higher accuracy.
 4.2.1.2.9. 

((a)) Diluted exhaust temperature at the particulate sampling filter;
((b)) Sampling flow rate;
((c)) Secondary dilution air flow rate (if secondary dilution is used);
((d)) Secondary dilution air temperature (if secondary dilution is used).
 4.2.1.2.10. 
The accuracy of the flow meters used for the measurement and control of the double diluted exhaust passing through the particulate sampling filters and for the measurement/control of secondary dilution air shall be sufficient so that the differential volume Vep shall meet the accuracy and proportional sampling requirements specified for single dilution.

The requirement that no condensation of the exhaust gas occur in the CVS dilution tunnel, diluted exhaust flow rate measurement system, CVS bag collection or analysis systems shall also apply in the case that double dilution systems are used.
 4.2.1.2.11. Each flow meter used in a particulate sampling and double dilution system shall be subjected to a linearity verification as required by the instrument manufacturer.

Figure A5/12
Figure A5/13 4.2.1.3.  4.2.1.3.1.  4.2.1.3.1.1. The sample probe shall deliver the particle size classification performance specified in paragraph 4.2.1.3.1.4. of this Sub-Annex. It is recommended that this performance be achieved by the use of a sharp-edged, open-ended probe facing directly into the direction of flow plus a pre-classifier (cyclone impactor, etc.). An appropriate sample probe, such as that indicated in Figure A5/11, may alternatively be used provided it achieves the pre-classification performance specified in paragraph 4.2.1.3.1.4. of this Sub-Annex.
 4.2.1.3.1.2. 
If more than one simultaneous sample is drawn from a single sample probe, the flow drawn from that probe shall be split into identical sub-flows to avoid sampling artefacts.

If multiple probes are used, each probe shall be sharp-edged, open-ended and facing directly into the direction of flow. Probes shall be equally spaced around the central longitudinal axis of the dilution tunnel, with a spacing between probes of at least 5 cm.
 4.2.1.3.1.3. The distance from the sampling tip to the filter mount shall be at least five probe diameters, but shall not exceed 2 000 mm.
 4.2.1.3.1.4. The pre-classifier (e.g. cyclone, impactor, etc.) shall be located upstream of the filter holder assembly. The pre-classifier 50 per cent cut point particle diameter shall be between 2,5 μm and 10 μm at the volumetric flow rate selected for sampling PM. The pre-classifier shall allow at least 99 per cent of the mass concentration of 1 μm particles entering the pre-classifier to pass through the exit of the pre-classifier at the volumetric flow rate selected for sampling PM.
 4.2.1.3.2.  4.2.1.3.2.1. Any bends in the PTT shall be smooth and have the largest possible radii.
 4.2.1.3.3.  4.2.1.3.3.1. 

4.2.1.3.3.1.1. Secondary dilution air shall be filtered through a medium capable of reducing particles in the most penetrating particle size of the filter material by ≥ 99,95 per cent, or through a HEPA filter of at least class H13 of EN 1822:2009. The dilution air may optionally be charcoal-scrubbed before being passed to the HEPA filter. It is recommended that an additional coarse particle filter be situated before the HEPA filter and after the charcoal scrubber, if used.
4.2.1.3.3.1.2. The secondary dilution air should be injected into the PTT as close to the outlet of the diluted exhaust from the dilution tunnel as possible.
4.2.1.3.3.1.3. The residence time from the point of secondary diluted air injection to the filter face shall be at least 0.25 seconds, but no longer than 5 seconds.
4.2.1.3.3.1.4. If the double diluted sample is returned to the CVS, the location of the sample return shall be selected so that it does not interfere with the extraction of other samples from the CVS.
 4.2.1.3.4.  4.2.1.3.4.1. The sample gas flow measurement unit shall consist of pumps, gas flow regulators and flow measuring units.
 4.2.1.3.4.2. 

((a)) When the sampling flow meter has real time monitoring and flow control operating at a frequency of 1 Hz or faster;
((b)) During regeneration tests on vehicles equipped with periodically regenerating after-treatment devices.

Should the volume of flow change unacceptably as a result of excessive filter loading, the test shall be invalidated. When it is repeated, the flow rate shall be decreased.
 4.2.1.3.5.  4.2.1.3.5.1. A valve shall be located downstream of the filter in the direction of flow. The valve shall open and close within 1 second of the start and end of test.
 4.2.1.3.5.2. For a given test, the gas filter face velocity shall be set to an initial value within the range 20 cm/s to 105 cm/s and shall be set at the start of the test so that 105 cm/s will not be exceeded when the dilution system is being operated with sampling flow proportional to CVS flow rate.
 4.2.1.3.5.3. 
All filter types shall have a 0,3 μm DOP (di-octylphthalate) or PAO (poly-alpha-olefin) CS 68649-12-7 or CS 68037-01-4 collection efficiency of at least 99 per cent at a gas filter face velocity of 5,33 cm/s measured according to one of the following standards:


((a)) U.S.A. Department of Defense Test Method Standard, MIL-STD-282 method 102.8: DOP-Smoke Penetration of Aerosol-Filter Element;
((b)) U.S.A. Department of Defense Test Method Standard, MIL-STD-282 method 502.1.1: DOP-Smoke Penetration of Gas-Mask Canisters;
((c)) Institute of Environmental Sciences and Technology, IEST-RP-CC021: Testing HEPA and ULPA Filter Media.
 4.2.1.3.5.4. The filter holder assembly shall be of a design that provides an even flow distribution across the filter stain area. The filter shall be round and have a stain area of at least 1 075 mm2.
 4.2.2.  4.2.2.1. 

((a)) The temperature of the weighing chamber (or room) in which the particulate sampling filters are conditioned and weighed shall be maintained to within 22 °C ± 2 °C (22 °C ± 1 °C if possible) during all filter conditioning and weighing.
((b)) Humidity shall be maintained at a dew point of less than 10.5 °C and a relative humidity of 45 per cent ± 8 per cent.
((c)) Limited deviations from weighing chamber (or room) temperature and humidity specifications shall be permitted provided their total duration does not exceed 30 minutes in any one filter conditioning period.
((d)) The levels of ambient contaminants in the weighing chamber (or room) environment that would settle on the particulate sampling filters during their stabilisation shall be minimised.
((e)) During the weighing operation no deviations from the specified conditions are permitted.
 4.2.2.2. 
The analytical balance used to determine the filter weight shall meet the linearity verification criteria of Table A5/1 applying a linear regression. This implies a precision of at least 2 μg and a resolution of at least 1 μg (1 digit = 1 μg). At least 4 equally-spaced reference weights shall be tested. The zero value shall be within ± 1 μg.


Table A5/1
Analytical balance verification criteria
Measurement system Intercept a0 Slope a1 Standard error SEE Coefficient of determination r2
Particulate Balance ≤ 1 μg 0,99 – 1,01 ≤ 1per cent max ≥ 0,998 4.2.2.3. 
The effects of static electricity shall be nullified. This may be achieved by grounding the balance through placement upon an antistatic mat and neutralization of the particulate sampling filters prior to weighing using a polonium neutraliser or a device of similar effect. Alternatively, nullification of static effects may be achieved through equalization of the static charge.
 4.2.2.4. 
The sample and reference filter weights shall be corrected for their buoyancy in air. The buoyancy correction is a function of sampling filter density, air density and the density of the balance calibration weight, and does not account for the buoyancy of the particulate matter itself.

If the density of the filter material is not known, the following densities shall be used:


((a)) PTFE coated glass fibre filter: 2 300 kg/m3;
((b)) PTFE membrane filter: 2 144 kg/m3;
((c)) PTFE membrane filter with polymethylpentene support ring: 920 kg/m3.

For stainless steel calibration weights, a density of 8 000 kg/m3 shall be used. If the material of the calibration weight is different, its density shall be known and be used. International Recommendation OIML R 111-1 Edition 2004(E) (or equivalent) from International Organization of Legal Metrology on calibration weights should be followed.

The following equation shall be used:

mf=muncorr×1−ρaρw1−ρaρf

where:

Pefis the corrected particulate sample mass, mg;Peuncorris the uncorrected particulate sample mass, mg;ρais the density of the air, kg/m3;ρwis the density of balance calibration weight, kg/m3;ρfis the density of the particulate sampling filter, kg/m3.

The density of the air ρa shall be calculated using the following equation:

ρa=pb× MmixR× Ta

pbis the total atmospheric pressure, kPa;Tais the air temperature in the balance environment, Kelvin (K);Mmixis the molar mass of air in a balanced environment, 28,836 g mol–1;Ris the molar gas constant, 8,3144 J mol–1 K–1.
 4.3.  4.3.1.  4.3.1.1.  4.3.1.1.1. The particle sampling system shall consist of a probe or sampling point extracting a sample from a homogenously mixed flow in a dilution system, a volatile particle remover (VPR) upstream of a particle number counter (PNC) and suitable transfer tubing. See Figure A5/14.
 4.3.1.1.2. 
A sample probe acting as an appropriate size-classification device, such as that shown in Figure A5/11, is an acceptable alternative to the use of a PCF.
 4.3.1.2.  4.3.1.2.1. The particle sampling point shall be located within a dilution system. In the case that a double dilution system is used, the particle sampling point shall be located within the primary dilution system.
 4.3.1.2.1.1. 

((a)) The sampling probe shall be installed at least 10 tunnel diameters downstream of the exhaust gas inlet, facing upstream into the tunnel gas flow with its axis at the tip parallel to that of the dilution tunnel;
((b)) The sampling probe shall be upstream of any conditioning device (e.g. heat exchanger);
((c)) The sampling probe shall be positioned within the dilution tunnel so that the sample is taken from a homogeneous diluent/exhaust mixture.
 4.3.1.2.1.2. 

((a)) In the case that a full flow exhaust dilution system, is used it shall have a flow Reynolds number, Re, lower than 1 700;
((b)) In the case that a double dilution system is used, it shall have a flow Reynolds number Re lower than 1 700 in the PTT i.e. downstream of the sampling probe or point;
((c)) Shall have a residence time ≤ 3 seconds.
 4.3.1.2.1.3. Any other sampling configuration for the PTS for which equivalent particle penetration at 30 nm can be demonstrated shall be considered acceptable.
 4.3.1.2.1.4. 

((a)) An internal diameter ≥ 4 mm;
((b)) A sample gas flow residence time of ≤ 0,8 seconds.
 4.3.1.2.1.5. Any other sampling configuration for the OT for which equivalent particle penetration at 30 nm can be demonstrated shall be considered acceptable.
 4.3.1.2.2. The VPR shall include devices for sample dilution and for volatile particle removal.
 4.3.1.2.3. All parts of the dilution system and the sampling system from the exhaust pipe up to the PNC, which are in contact with raw and diluted exhaust gas, shall be designed to minimize deposition of the particles. All parts shall be made of electrically conductive materials that do not react with exhaust gas components, and shall be electrically grounded to prevent electrostatic effects.
 4.3.1.2.4. The particle sampling system shall incorporate good aerosol sampling practice that includes the avoidance of sharp bends and abrupt changes in cross-section, the use of smooth internal surfaces and the minimization of the length of the sampling line. Gradual changes in the cross-section are permitted.
 4.3.1.3.  4.3.1.3.1. The particle sample shall not pass through a pump before passing through the PNC.
 4.3.1.3.2. A sample pre-classifier is recommended.
 4.3.1.3.3. 

((a)) Be capable of diluting the sample in one or more stages to achieve a particle number concentration below the upper threshold of the single particle count mode of the PNC and a gas temperature below 35 °C at the inlet to the PNC;
((b)) Include an initial heated dilution stage that outputs a sample at a temperature of ≥ 150 °C and ≤ 350 °C ± 10 °C, and dilutes by a factor of at least 10;
((c)) Control heated stages to constant nominal operating temperatures, within the range ≥ 150 °C and ≤ 400 °C ± 10 °C;
((d)) Provide an indication of whether or not heated stages are at their correct operating temperatures;
((e)) Be designed to achieve a solid particle penetration efficiency of at least 70 per cent for particles of 100 nm electrical mobility diameter;
((f)) Achieve a particle concentration reduction factor fr(di) for particles of 30 nm and 50 nm electrical mobility diameters that is no more than 30 per cent and 20 per cent respectively higher, and no more than 5 per cent lower than that for particles of 100 nm electrical mobility diameter for the VPR as a whole;
The particle concentration reduction factor at each particle size fr(di) shall be calculated using the following equation:
frdi=NindiNoutdi
where:
Nin(di)is the upstream particle number concentration for particles of diameter di;Nout(di)is the downstream particle number concentration for particles of diameter di;diis the particle electrical mobility diameter (30, 50 or 100 nm).
Nin(di) and Nout(di) shall be corrected to the same conditions.
The arithmetic average particle concentration reduction factor at a given dilution setting fr– shall be calculated using the following equation:
fr–=fr30 nm+ fr50 nm+ fr100 nm3
It is recommended that the VPR is calibrated and validated as a complete unit;
((g)) Be designed according to good engineering practice to ensure particle concentration reduction factors are stable across a test;
((h)) Also achieve > 99,0 per cent vaporization of 30 nm tetracontane (CH3(CH2)38CH3) particles, with an inlet concentration of ≥ 10 000 per cm3, by means of heating and reduction of partial pressures of the tetracontane.
 4.3.1.3.4. 

((a)) Operate under full flow operating conditions;
((b)) Have a counting accuracy of ± 10 per cent across the range 1 per cm3 to the upper threshold of the single particle count mode of the PNC against a suitable traceable standard. At concentrations below 100 per cm3, measurements averaged over extended sampling periods may be required to demonstrate the accuracy of the PNC with a high degree of statistical confidence;
((c)) Have a resolution of at least 0.1 particles per cm3 at concentrations below 100 per cm3;
((d)) Have a linear response to particle number concentrations over the full measurement range in single particle count mode;
((e)) Have a data reporting frequency equal to or greater than a frequency of 0,5 Hz;
((f)) Have a t90 response time over the measured concentration range of less than 5 seconds;
((g)) Incorporate a coincidence correction function up to a maximum 10 per cent correction, and may make use of an internal calibration factor as determined in paragraph 5.7.1.3.of this Sub-Annex but shall not make use of any other algorithm to correct for or define the counting efficiency;
((h)) Have counting efficiencies at the different particle sizes as specified in Table A5/2.


Table A5/2
PNC counting efficiency
Particle size electrical mobility diameter (nm) PNC counting efficiency (per cent)
23 ± 1 50 ± 12
41 ± 1 > 90 4.3.1.3.5. If the PNC makes use of a working liquid, it shall be replaced at the frequency specified by the instrument manufacturer.
 4.3.1.3.6. Where not held at a known constant level at the point at which PNC flow rate is controlled, the pressure and/or temperature at the PNC inlet shall be measured for the purposes of correcting particle number concentration measurements to standard conditions.
 4.3.1.3.7. The sum of the residence time of the PTS, VPR and OT plus the t90 response time of the PNC shall be no greater than 20 seconds.
 4.3.1.4. 
The following paragraph contains the recommended practice for measurement of PN. However, systems meeting the performance specifications in paragraphs 4.3.1.2. and 4.3.1.3. of this Sub-Annex are acceptable.

Figure A5/14 4.3.1.4.1.  4.3.1.4.1.1. The particle sampling system shall consist of a sampling probe tip or particle sampling point in the dilution system, a PTT, a PCF, and a VPR, upstream of the PNC unit.
 4.3.1.4.1.2. The VPR shall include devices for sample dilution (particle number diluters: PND1 and PND2) and particle evaporation (evaporation tube, ET).
 4.3.1.4.1.3. The sampling probe or sampling point for the test gas flow shall be arranged within the dilution tunnel so that a representative sample gas flow is taken from a homogeneous diluent/exhaust mixture.

5.  5.1. 

Instrument checks Interval Criterion
Gas analyser linearization (calibration) Every 6 months ± 2 per cent of reading
Mid span Every 6 months ± 2 per cent
CO NDIR:CO2/H2O interference Monthly – 1 to 3 ppm
NOx converter check Monthly > 95 per cent
CH4 cutter check Yearly 98 per cent of ethane
FID CH4 response Yearly See paragraph 5.4.3. of this Sub-Annex
FID air/fuel flow At major maintenance According to instrument manufacturer.
Laser infrared spectrometers (modulated high resolution narrow band infrared analysers): interference check Yearly or at major maintenance According to instrument manufacturer.
QCL Yearly or at major maintenance According to instrument manufacturer.
GC methods See paragraph 7.2. of this Sub-Annex See paragraph 7.2. of this Sub-Annex
LC methods Yearly or at major maintenance According to instrument manufacturer.
Photoacoustics Yearly or at major maintenance According to instrument manufacturer.
Microgram balance linearity Yearly or at major maintenance See paragraph 4.2.2.2. of this Sub-Annex
PNC (particle number counter) See paragraph 5.7.1.1. of this Sub-Annex See paragraph 5.7.1.3. of this Sub-Annex
VPR (volatile particle remover) See paragraph 5.7.2.1. of this Sub-Annex See paragraph 5.7.2. of this Sub-Annex


CVS Interval Criterion
CVS flow After overhaul ± 2 per cent
Dilution flow Yearly ± 2 per cent
Temperature sensor Yearly ± 1 °C
Pressure sensor Yearly ± 0,4 kPa
Injection check Weekly ± 2 per cent


Climate Interval Criterion
Temperature Yearly ± 1 °C
Moisture dew Yearly ± 5 per cent RH
Ambient pressure Yearly ± 0,4 kPa
Cooling fan After overhaul According to paragraph 1.1.1. of this Sub-Annex
 5.2.  5.2.1. Each analyser shall be calibrated as specified by the instrument manufacturer or at least as often as specified in Table A5/3.
 5.2.2. 

5.2.2.1. The analyser linearization curve shall be established by at least five calibration points spaced as uniformly as possible. The nominal concentration of the calibration gas of the highest concentration shall be not less than 80 per cent of the full scale.
5.2.2.2. The calibration gas concentration required may be obtained by means of a gas divider, diluting with purified N2 or with purified synthetic air.
5.2.2.3. The linearization curve shall be calculated by the least squares method. If the resulting polynomial degree is greater than 3, the number of calibration points shall be at least equal to this polynomial degree plus 2.
5.2.2.4. The linearization curve shall not differ by more than ± 2 per cent from the nominal value of each calibration gas.
5.2.2.5. From the trace of the linearization curve and the linearization points it is possible to verify that the calibration has been carried out correctly. The different characteristic parameters of the analyser shall be indicated, particularly:

((a)) Analyser and gas component;
((b)) Range;
((c)) Date of linearisation.
5.2.2.6. If the approval authority is satisfied that alternative technologies (e.g. computer, electronically controlled range switch, etc.) give equivalent accuracy, these alternatives may be used.
 5.3.  5.3.1.  5.3.1.1. The calibration shall be checked by use of a zero gas and by use of a calibration gas according to paragraph 1.2.14.2.3. of Sub-Annex 6,
 5.3.1.2. After testing, zero gas and the same calibration gas shall be used for re-checking according to paragraph 1.2.14.2.4. of Sub-Annex 6.
 5.4.  5.4.1. 
The FID shall be adjusted as specified by the instrument manufacturer. Propane in air shall be used on the most common operating range.
 5.4.2.  5.4.2.1. The analyser shall be calibrated using propane in air and purified synthetic air.
 5.4.2.2. A calibration curve as described in paragraph 5.2.2. of this Sub-Annex shall be established.
 5.4.3.  5.4.3.1. 
The concentration of the test gas shall be at a level to give a response of approximately 80 per cent of full-scale deflection for the operating range. The concentration shall be known to an accuracy of ± 2 per cent in reference to a gravimetric standard expressed in volume. In addition, the gas cylinder shall be preconditioned for 24 hours at a temperature between 20 and 30 °C.
 5.4.3.2. 
Propylene and purified air: 0,90<Rf<1,10

Toluene and purified air: 0,90<Rf<1,10

These are relative to an Rf of 1,00 for propane and purified air.
 5.5.  5.5.1. 

5.5.1.1. The analyser shall be calibrated in the most common operating range following the manufacturer's specifications using zero and calibration gas (the NO content of which shall amount to approximately 80 per cent of the operating range and the NO2 concentration of the gas mixture shall be less than 5 per cent of the NO concentration). The NOx analyser shall be in the NO mode so that the calibration gas does not pass through the converter. The indicated concentration shall be included in all relevant test sheets.
5.5.1.2. Via a T-fitting, oxygen or synthetic air shall be added continuously to the calibration gas flow until the concentration indicated is approximately 10 per cent less than the indicated calibration concentration given in paragraph 5.5.1.1. of this Sub-Annex. The indicated concentration (c) shall be included in all relevant test sheets. The ozonator shall be kept deactivated throughout this process.
5.5.1.3. The ozonator shall now be activated to generate enough ozone to bring the NO concentration down to 20 per cent (minimum 10 per cent) of the calibration concentration given in paragraph 5.5.1.1. of this Sub-Annex. The indicated concentration (d) shall be included all relevant test sheets.
5.5.1.4. The NOx analyser shall be subsequently switched to the NOx mode, whereby the gas mixture (consisting of NO, NO2, O2 and N2) now passes through the converter. The indicated concentration (a) shall be included in all relevant test sheets.
5.5.1.5. The ozonator shall now be deactivated. The mixture of gases described in paragraph 5.5.1.2. of this Sub-Annex shall pass through the converter into the detector. The indicated concentration (b) shall be included in all relevant test sheets.
Figure A5/15
5.5.1.6. With the ozonator deactivated, the flow of oxygen or synthetic air shall be shut off. The NO2 reading of the analyser shall then be no more than 5 per cent above the figure given in paragraph 5.5.1.1. of this Sub-Annex.
5.5.1.7. The per cent efficiency of the NOx converter shall be calculated using the concentrations a, b, c and d determined in paragraphs 5.5.1.2. to 5.5.1.5. of this Sub-Annex inclusive using the following equation:
Efficiency=1+a− bc− d× 100

5.5.1.7.1. The efficiency of the converter shall not be less than 95 per cent. The efficiency of the converter shall be tested in the frequency defined in Table A5/3.
 5.6.  5.6.1. The calibration of the microgram balance used for particulate sampling filter weighing shall be traceable to a national or international standard. The balance shall comply with the linearity requirements given in paragraph 4.2.2.2. of this Sub-Annex. The linearity verification shall be performed at least every 12 months or whenever a system repair or change is made that could influence the calibration.
 5.7. 
Examples of calibration/validation methods are available at:

http://www.unece.org/trans/main/wp29/wp29wgs/wp29grpe/pmpFCP.html
 5.7.1.  5.7.1.1. The approval authority shall ensure the existence of a calibration certificate for the PNC demonstrating compliance with a traceable standard within a 13-month period prior to the emissions test. Between calibrations either the counting efficiency of the PNC shall be monitored for deterioration or the PNC wick shall be routinely changed every 6 months. See Figures A5/16 and A5/17. PNC counting efficiency may be monitored against a reference PNC or against at least two other measurement PNCs. If the PNC reports particle number concentrations within ± 10 per cent of the arithmetic average of the concentrations from the reference PNC, or a group of two or more PNCs, the PNC shall subsequently be considered stable, otherwise maintenance of the PNC is required. Where the PNC is monitored against two or more other measurement PNCs, it is permitted to use a reference vehicle running sequentially in different test cells each with its own PNC.

Figure A5/16
Figure A5/17 5.7.1.2. The PNC shall also be recalibrated and a new calibration certificate issued following any major maintenance.
 5.7.1.3. 

((a)) A calibrated aerosol electrometer when simultaneously sampling electrostatically classified calibration particles; or
((b)) A second PNC that has been directly calibrated by the method described above.
 5.7.1.3.1. In paragraph 5.7.1.3. (a) of this Sub-Annex, calibration shall be undertaken using at least six standard concentrations spaced as uniformly as possible across the PNC’s measurement range.
 5.7.1.3.2. In paragraph 5.7.1.3. (b) of this Sub-Annex, calibration shall be undertaken using at least six standard concentrations across the PNC’s measurement range. At least 3 points shall be at concentrations below 1,000 per cm3, the remaining concentrations shall be linearly spaced between 1,000 per cm3 and the maximum of the PNC’s range in single particle count mode.
 5.7.1.3.3. In paragraphs 5.7.1.3.(a) and 5.7.1.3.(b) of this Sub-Annex, the selected points shall include a nominal zero concentration point produced by attaching HEPA filters of at least class H13 of EN 1822:2008, or equivalent performance, to the inlet of each instrument. With no calibration factor applied to the PNC under calibration, measured concentrations shall be within ± 10 per cent of the standard concentration for each concentration, with the exception of the zero point, otherwise the PNC under calibration shall be rejected. The gradient from a linear least squares regression of the two data sets shall be calculated and recorded. A calibration factor equal to the reciprocal of the gradient shall be applied to the PNC under calibration. Linearity of response is calculated as the square of the Pearson product moment correlation coefficient (r) of the two data sets and shall be equal to or greater than 0.97. In calculating both the gradient and r2, the linear regression shall be forced through the origin (zero concentration on both instruments).
 5.7.1.4. Calibration shall also include a check, according to the requirements of paragraph 4.3.1.3.4.(h) of this Sub-Annex, on the PNC’s detection efficiency with particles of 23 nm electrical mobility diameter. A check of the counting efficiency with 41 nm particles is not required.
 5.7.2.  5.7.2.1. 
It is recommended that the VPR is calibrated and validated as a complete unit.

The VPR shall be characterised for particle concentration reduction factor with solid particles of 30, 50 and 100 nm electrical mobility diameter. Particle concentration reduction factors fr(d) for particles of 30 nm and 50 nm electrical mobility diameters shall be no more than 30 per cent and 20 per cent higher respectively, and no more than 5 per cent lower than that for particles of 100 nm electrical mobility diameter. For the purposes of validation, the arithmetic average of the particle concentration reduction factor shall be within ± 10 per cent of the arithmetic average particle concentration reduction factor fr– determined during the primary calibration of the VPR.
 5.7.2.2. 
The particle concentration reduction factor for each monodisperse particle size, fr (di), shall be calculated using the following equation:

frdi=NindiNoutdi

where:

Nin(di)is the upstream particle number concentration for particles of diameter di;Nout(di)is the downstream particle number concentration for particles of diameter di;diis the particle electrical mobility diameter (30, 50 or 100 nm).

Nin(di) and Nout(di) shall be corrected to the same conditions.

The arithmetic average particle concentration reduction factor fr– at a given dilution setting shall be calculated using the following equation:

fr–=fr30nm+ fr50nm+ fr100nm3

Where a polydisperse 50 nm aerosol is used for validation, the arithmetic average particle concentration reduction factor fv– at the dilution setting used for validation shall be calculated using the following equation:

fv–=NinNout

where:

Ninis the upstream particle number concentration;Noutis the downstream particle number concentration.
 5.7.2.3. The VPR shall demonstrate greater than 99.0 per cent removal of tetracontane (CH3(CH2)38CH3) particles of at least 30 nm electrical mobility diameter with an inlet concentration ≥ 10 000 per cm3 when operated at its minimum dilution setting and manufacturers recommended operating temperature.
 5.7.3.  5.7.3.1. On a monthly basis, the flow into the PNC shall have a measured value within 5 per cent of the PNC nominal flow rate when checked with a calibrated flow meter.
 5.8. 
In the case that a gas divider is used to perform the calibrations as defined in paragraph 5.2. of this Sub-Annex, the accuracy of the mixing device shall be such that the concentrations of the diluted calibration gases may be determined to within ± 2 per cent. A calibration curve shall be verified by a mid-span check as described in paragraph 5.3. of this Sub-Annex. A calibration gas with a concentration below 50 per cent of the analyser range shall be within 2 per cent of its certified concentration.

6.  6.1.  6.1.1. All values in ppm mean V-ppm (vpm)
 6.1.2. 

6.1.2.1. Nitrogen:
Purity: ≤ 1 ppm C1, ≤ 1 ppm CO, ≤ 400 ppm CO2, ≤ 0,1 ppm NO, < 0,1 ppm NO2, < 0,1 ppm N2O, < 0,1 ppm NH3;
6.1.2.2. Synthetic air:
Purity: ≤ 1 ppm C1, ≤ 1 ppm CO, ≤ 400 ppm CO2, ≤ 0,1 ppm NO; oxygen content between 18 and 21 per cent volume;
6.1.2.3. Oxygen:
Purity: > 99,5 per cent vol. O2;
6.1.2.4. Hydrogen (and mixture containing helium or nitrogen):
Purity: ≤ 1 ppm C1, ≤ 400 ppm CO2; hydrogen content between 39 and 41 per cent volume;
6.1.2.5. Carbon monoxide:
Minimum purity 99,5 per cent;
6.1.2.6. Propane:
Minimum purity 99,5 per cent.
 6.2.  6.2.1. 
Mixtures of gases having the following compositions shall be available with bulk gas specifications according to paragraphs 6.1.2.1. or 6.1.2.2. of this Sub-Annex:


((a)) C3H8 in synthetic air (see paragraph 6.1.2.2. of this Sub-Annex);
((b)) CO in nitrogen;
((c)) CO2 in nitrogen;
((d)) CH4 in synthetic air;
((e)) NO in nitrogen (the amount of NO2 contained in this calibration gas shall not exceed 5 per cent of the NO content);

Sub-Annex 6
1.  1.1  1.1.1. The Type 1 test is used to verify the emissions of gaseous compounds, particulate matter, particle number, CO2 mass emission, fuel consumption, electric energy consumption and electric ranges over the applicable WLTP test cycle.
 1.1.1.1. The tests shall be carried out according to the method described in paragraph 1.2. of this Sub-Annex or paragraph 3. of Sub-Annex 8 for pure electric, hybrid electric and compressed hydrogen fuel cell hybrid vehicles. Exhaust gases, particulate matter and particles shall be sampled and analysed by the prescribed methods.
 1.1.2. The number of tests shall be determined according to the flowchart in Figure A6/1. The limit value is the maximum allowed value for the respective criteria pollutant as specified in Annex I of Regulation (EC) No 715/2007.
 1.1.2.1. The flowchart in Figure A6/1 shall be applicable only to the whole applicable WLTP test cycle and not to single phases.
 1.1.2.2. The test results shall be the values after the REESS energy change-based, Ki and ATCT corrections are applied.
 1.1.2.3.  1.1.2.3.1. If during any of the tests a criteria emissions limit is exceeded, the vehicle shall be rejected.
 1.1.2.3.2. Depending on the vehicle type, the manufacturer shall declare as applicable the total cycle value of the CO2 mass emission, the electric energy consumption, fuel consumption for NOVC-FCHV as well as PER and AER according to Table A6/1.
 1.1.2.3.3. The declared value of the electric energy consumption for OVC-HEVs under charge-depleting operating condition shall not be determined according to Figure A6/1. It shall be taken as the type approval value if the declared CO2 value is accepted as the approval value. If that is not the case, the measured value of electric energy consumption shall be taken as the type approval value.
 1.1.2.3.4. If after the first test all criteria in row 1 of the applicable Table A6/2 are fulfilled, all values declared by the manufacturer shall be accepted as the type approval value. If any one of the criteria in row 1 of the applicable Table A6/2 is not fulfilled, a second test shall be performed with the same vehicle.
 1.1.2.3.5. After the second test, the arithmetic average results of the two tests shall be calculated. If all criteria in row 2 of the applicable Table A6/2 are fulfilled by these arithmetic average results, all values declared by the manufacturer shall be accepted as the type approval value. If any one of the criteria in row 2 of the applicable Table A6/2 is not fulfilled, a third test shall be performed with the same vehicle.
 1.1.2.3.6. After the third test, the arithmetic average results of the three tests shall be calculated. For all parameters which fulfil the corresponding criterion in row 3 of the applicable Table A6/2, the declared value shall be taken as the type approval value. For any parameter which does not fulfil the corresponding criterion in row 3 of the applicable Table A6/2, the arithmetic average result shall be taken as the type approval value.
 1.1.2.3.7. In the case that any one of the criterion of the applicable Table A6/2 is not fulfilled after the first or second test, at the request of the manufacturer and with the approval of the approval authority, the values may be re-declared as higher values for emissions or consumption, or as lower values for electric ranges, in order to reduce the required number of tests for type approval.
 1.1.2.3.8. dCO21, dCO22 and dCO23 determination.
 1.1.2.3.8.1. Without prejudice to the requirement of paragraph 1.1.2.3.8.2., the following values for dCO21, dCO22 and dCO23 shall be used in relation to the criteria for the number of tests in Table A6/2:

dCO21 = 0,990

dCO22 = 0,995

dCO23 = 1,000
 1.1.2.3.8.2. If the charge depleting Type 1 test for OVC-HEVs consists of two or more applicable WLTP test cycles and the dCO2x value is below 1,0, the dCO2x value shall be replaced by 1,0.
 1.1.2.3.9. 

Table A6/1
Applicable rules for a manufacturer’s declared values (total cycle values)
Vehicle type MCO2(g/km) FC(kg/100 km) Electric energy consumption(Wh/km) All electric range / Pure Electric Range(km)
Vehicles tested according to Sub-Annex 6 (ICE) MCO2 Paragraph 3. of Sub-Annex 7 — — —
NOVC-FCHV — FCCS Paragraph 4.2.1.2.1. of Annex 8 — —
NOVC-HEV MCO2,CS Paragraph 4.1.1. of Sub-Annex 8 — — —
OVC-HEV CD MCO2,CD Paragraph 4.1.2. of Sub-Annex 8 — ECAC,CD Paragraph 4.3.1. of Sub-Annex 8 AER Paragraph 4.4.1.1. of Sub-Annex 8
CS MCO2,CS Paragraph 4.1.1. of Sub-Annex 8 — — —
PEV — — ECWLTC Paragraph 4.3.4.2. of Sub-Annex 8 PERWLTC Paragraph 4.4.2. of Sub-Annex 8



Figure A6/1



For ICE vehicles, NOVC-HEVs and OVC-HEVs charge-sustaining Type 1 test.

 Test Judgement parameter Criteria emission MCO2
Row 1 First test First test results ≤ Regulation limit × 0,9 ≤ Declared value × dCO21
Row 2 Second test Arithmetic average of the first and second test results ≤ Regulation limit × 1,0 ≤ Declared value × dCO22
Row 3 Third test Arithmetic average of three test results ≤ Regulation limit × 1,0 ≤ Declared value × dCO23


For OVC-HEVs charge-depleting Type 1 test.

 Test Judgement parameter Criteria emissions MCO2,CD AER
Row 1 First test First test results ≤ Regulation limit × 0,9 ≤ Declared value × dCO21 ≥ Declared value × 1,0
Row 2 Second test Arithmetic average of the first and second test results ≤ Regulation limit × 1,0 ≤ Declared value × dCO22 ≥ Declared value × 1,0
Row 3 Third test Arithmetic average of three test results ≤ Regulation limit × 1,0 ≤ Declared value × dCO23 ≥ Declared value × 1,0


For PEVs

 Test Judgement parameter Electric energy consumption PER
Row 1 First test First test results ≤ Declared value × 1,0 ≥ Declared value × 1,0
Row 2 Second test Arithmetic average of the first and second test results ≤ Declared value × 1,0 ≥ Declared value × 1,0
Row 3 Third test Arithmetic average of three test results ≤ Declared value × 1,0 ≥ Declared value × 1,0
For NOVC-FCHVs

 Test Judgement parameter FCCS
Row 1 First test First test results ≤ Declared value × 1,0
Row 2 Second test Arithmetic average of the first and second test results ≤ Declared value × 1,0
Row 3 Third test Arithmetic average of three test results ≤ Declared value × 1,0 1.1.2.4.  1.1.2.4.1.  1.1.2.4.1.1. After the total cycle declared value of the CO2 mass emission is accepted, the arithmetic average of the phase-specific values of the test results in g/km shall be multiplied by the adjustment factor CO2_AF to compensate for the difference between the declared value and the test results. This corrected value shall be the type approval value for CO2.
CO2_AF=Declared valuePhase combined value
where:
Phase combined value=CO2aveL× DL+ CO2aveM× DM+ CO2aveH× DH+ CO2aveexH× DexHDL+ DM+ DH+ DexH
where:

CO2aveLis the arithmetic average CO2 mass emission result for the L phase test result(s), g/km;CO2aveMis the arithmetic average CO2 mass emission result for the M phase test result(s), g/km;CO2aveHis the arithmetic average CO2 mass emission result for the H phase test result(s), g/km;CO2aveexHis the arithmetic average CO2 mass emission result for the exH phase test result(s), g/km;DLis theoretical distance of phase L, km;DMis theoretical distance of phase M, km;DHis theoretical distance of phase H, km;DexHis theoretical distance of phase exH, km.
 1.1.2.4.1.2. If the total cycle declared value of the CO2 mass emission is not accepted, the type approval phase-specific CO2 mass emission value shall be calculated by taking the arithmetic average of the all test results for the respective phase.
 1.1.2.4.2.  1.1.2.4.2.1. The fuel consumption value shall be calculated by the phase-specific CO2 mass emission using the equations in paragraph 1.1.2.4.1. of this Sub-Annex and the arithmetic average of the emissions.
 1.1.2.4.3.  1.1.2.4.3.1. The phase-specific electric energy consumption and the phase-specific electric ranges are calculated by taking the arithmetic average of the phase specific values of the test result(s), without an adjustment factor.
 1.2.  1.2.1.  1.2.1.1. The Type 1 test shall consist of prescribed sequences of dynamometer preparation, fuelling, soaking, and operating conditions.
 1.2.1.2. The Type 1 test shall consist of vehicle operation on a chassis dynamometer on the applicable WLTC for the interpolation family. A proportional part of the diluted exhaust emissions shall be collected continuously for subsequent analysis using a constant volume sampler.
 1.2.1.3. Background concentrations shall be measured for all compounds for which dilute mass emissions measurements are conducted. For exhaust emissions testing, this requires sampling and analysis of the dilution air.
 1.2.1.3.1.  1.2.1.3.1.1. Where the manufacturer requests subtraction of either dilution air or dilution tunnel background particulate mass from emissions measurements, these background levels shall be determined according to the procedures listed in paragraphs 1.2.1.3.1.1.1. to 1.2.1.3.1.1.3. inclusive of this Sub-Annex.
 1.2.1.3.1.1.1. The maximum permissible background correction shall be a mass on the filter equivalent to 1 mg/km at the flow rate of the test.
 1.2.1.3.1.1.2. If the background exceeds this level, the default figure of 1 mg/km shall be subtracted.
 1.2.1.3.1.1.3. Where subtraction of the background contribution gives a negative result, the background level shall be considered to be zero.
 1.2.1.3.1.2. Dilution air background particulate mass level shall be determined by passing filtered dilution air through the particulate background filter. This shall be drawn from a point immediately downstream of the dilution air filters. Background levels in g/m3 shall be determined as a rolling arithmetic average of at least 14 measurements with at least one measurement per week.
 1.2.1.3.1.3. Dilution tunnel background particulate mass level shall be determined by passing filtered dilution air through the particulate background filter. This shall be drawn from the same point as the particulate matter sample. Where secondary dilution is used for the test, the secondary dilution system shall be active for the purposes of background measurement. One measurement may be performed on the day of test, either prior to or after the test.
 1.2.1.3.2.  1.2.1.3.2.1. Where a manufacturer requests a background correction, these background levels shall be determined as follows:
 1.2.1.3.2.1.1. The background value may be either calculated or measured. The maximum permissible background correction shall be related to the maximum allowable leak rate of the particle number measurement system (0,5 particles per cm3) scaled from the particle concentration reduction factor, PCRF, and the CVS flow rate used in the actual test;
 1.2.1.3.2.1.2. Either the approval authority or the manufacturer may request that actual background measurements are used instead of calculated ones.
 1.2.1.3.2.1.3. Where subtraction of the background contribution gives a negative result, the PN result shall be considered to be zero.
 1.2.1.3.2.2. Dilution air background particle number level shall be determined by sampling filtered dilution air. This shall be drawn from a point immediately downstream of the dilution air filters into the PN measurement system. Background levels in particles per cm3 shall be determined as a rolling arithmetic average of least 14 measurements with at least one measurement per week.
 1.2.1.3.2.3. Dilution tunnel background particle number level shall be determined by sampling filtered dilution air. This shall be drawn from the same point as the PN sample. Where secondary dilution is used for the test the secondary dilution system shall be active for the purposes of background measurement. One measurement may be performed on the day of test, either prior to or after the test using the actual PCRF and the CVS flow rate utilised during the test.
 1.2.2.  1.2.2.1.  1.2.2.1.1. 

((a)) Test cell ambient air;
((b)) Dilution and sampling system temperatures as required for emissions measurement systems defined in Sub-Annex 5.
 1.2.2.1.2. Atmospheric pressure shall be measurable with a resolution of ± 0,1 kPa.
 1.2.2.1.3. Specific humidity H shall be measurable with a resolution of ± 1 g H2O/kg dry air.
 1.2.2.2.  1.2.2.2.1.  1.2.2.2.1.1. The test cell shall have a temperature set point of 23 °C. The tolerance of the actual value shall be within ± 5 °C. The air temperature and humidity shall be measured at the test cell’s cooling fan outlet at a minimum frequency of 1 Hz. For the temperature at the start of the test, see paragraph 1.2.8.1. in Sub-Annex 6.
 1.2.2.2.1.2. 
5,5≤ H≤ 12,2 g H2O∕kg dry air
 1.2.2.2.1.3. Humidity shall be measured continuously at a minimum frequency of 1 Hz.
 1.2.2.2.2. 
The soak area shall have a temperature set point of 23 °C and the tolerance of the actual value shall be within ± 3 °C on a 5 minute running arithmetic average and shall not show a systematic deviation from the set point. The temperature shall be measured continuously at a minimum frequency of 1 Hz.
 1.2.3.  1.2.3.1. 
The test vehicle shall conform in all its components with the production series, or, if the vehicle is different from the production series, a full description shall be included in all relevant test reports. In selecting the test vehicle, the manufacturer and approval authority shall agree which vehicle model is representative for the interpolation family.

For the measurement of emissions, the road load as determined with test vehicle H shall be applied. In the case of a road load matrix family, for the measurement of emissions, the road load as calculated for vehicle HM according to paragraph 5.1. of Sub-Annex 4 shall be applied.

If at the request of the manufacturer the interpolation method is used (see paragraph 3.2.3.2. of Sub-Annex 7), an additional measurement of emissions shall be performed with the road load as determined with test vehicle L. Tests on vehicles H and L should be performed with the same test vehicle and shall be tested with the shortest final transmission ratio within the interpolation family. In the case of a road load matrix family, an additional measurement of emissions shall be performed with the road load as calculated for vehicle LM according to paragraph 5.1. of Sub-Annex 4.
 1.2.3.2. 
The interpolation method shall only be used if the difference in CO2 between test vehicles L and H is between a minimum of 5 and a maximum of 30 g/km or 20 per cent of the CO2 emissions from vehicle H, whichever value is the lower.

At the request of the manufacturer and with approval of the approval authority, the interpolation line may be extrapolated to a maximum of 3 g/km above the CO2 emission of vehicle H and/or below the CO2 emission of vehicle L. This extension is valid only within the absolute boundaries of the interpolation range specified above.

This paragraph is not applicable for the difference in CO2 between vehicles HM and LM of a road load matrix family.
 1.2.3.3. 
The vehicle shall be presented in good technical condition. It shall have been run-in and driven between 3 000 and 15 000 km before the test. The engine, transmission and vehicle shall be run-in in accordance with the manufacturer’s recommendations.
 1.2.4.  1.2.4.1. Dynamometer settings and verification shall be performed according to Sub-Annex 4.
 1.2.4.2.  1.2.4.2.1. Auxiliary devices shall be switched off or deactivated during dynamometer operation unless their operation is required.
 1.2.4.2.2. 
The manufacturer shall provide the approval authority a list of the deactivated devices and justification for the deactivation. The dynamometer operation mode shall be approved by the approval authority and the use of a dynamometer operation mode shall be included in all relevant test reports.
 1.2.4.2.3. The dynamometer operation mode shall not activate, modulate, delay or deactivate the operation of any part that affects the emissions and fuel consumption under the test conditions. Any device that affects the operation on a chassis dynamometer shall be set to ensure a proper operation.
 1.2.4.2.4. If the test vehicle is tested in a two-wheel drive (2WD) mode, the test vehicle shall be tested on a single-axis chassis dynamometer which fulfils the requirements according to paragraph 2. of Sub-Annex 5. At the request of the manufacturer and with the approval of the approval authority, the vehicle may be tested on a dual-axis chassis dynamometer.
 1.2.4.2.5. 
At the request of the manufacturer and with the approval of the approval authority, the vehicle may be tested on a single-axis chassis dynamometer if the following conditions are met:


((a)) the test vehicle is converted to permanent 2WD operation in all test modes;
((b)) the manufacturer provides evidence to the approval authority that the CO2, fuel consumption and/or electrical energy consumption of the converted vehicle is the same or higher as for the non-converted vehicle being tested on a dual-axis chassis dynamometer.
 1.2.4.3. The vehicle’s exhaust system shall not exhibit any leak likely to reduce the quantity of gas collected.
 1.2.4.4. The settings of the powertrain and vehicle controls shall be those prescribed by the manufacturer for series production.
 1.2.4.5. Tyres shall be of a type specified as original equipment by the vehicle manufacturer. Tyre pressure may be increased by up to 50 per cent above the pressure specified in paragraph 4.2.2.3. of Sub-Annex 4. The same tyre pressure shall be used for the setting of the dynamometer and for all subsequent testing. The tyre pressure used shall be included in all relevant test reports.
 1.2.4.6.  1.2.4.6.1. The appropriate reference fuel as defined in Annex IX shall be used for testing.
 1.2.4.7.  1.2.4.7.1. The vehicle shall be approximately horizontal during the test so as to avoid any abnormal distribution of the fuel.
 1.2.4.7.2. If necessary, the manufacturer shall provide additional fittings and adapters, as required to accommodate a fuel drain at the lowest point possible in the tank(s) as installed on the vehicle, and to provide for exhaust sample collection.
 1.2.4.7.3. For PM sampling during a test when the regenerating device is in a stabilized loading condition (i.e. the vehicle is not undergoing a regeneration), it is recommended that the vehicle has completed > 1/3 of the mileage between scheduled regenerations or that the periodically regenerating device has undergone equivalent loading off the vehicle.
 1.2.5.  1.2.5.1. Preliminary testing cycles may be carried out if requested by the manufacturer to follow the speed trace within the prescribed limits.
 1.2.6.  1.2.6.1. The fuel tank (or fuel tanks) shall be filled with the specified test fuel. If the existing fuel in the fuel tank (or fuel tanks) does not meet the specifications contained in paragraph 1.2.4.6. of this Sub-Annex, the existing fuel shall be drained prior to the fuel fill. The evaporative emission control system shall neither be abnormally purged nor abnormally loaded.
 1.2.6.2. 
Before the preconditioning test cycle, the REESSs shall be fully charged. At the request of the manufacturer, charging may be omitted before preconditioning. The REESSs shall not be charged again before official testing.
 1.2.6.3. The test vehicle shall be moved to the test cell and the operations listed in paragraphs 1.2.6.3.1. to 1.2.6.3.9. inclusive shall be performed.
 1.2.6.3.1. The test vehicle shall be placed, either by being driven or pushed, on a dynamometer and operated through the applicable WLTCs. The vehicle need not be cold, and may be used to set the dynamometer load.
 1.2.6.3.2. The dynamometer load shall be set according to paragraphs 7. and 8. of Sub-Annex 4.
 1.2.6.3.3. During preconditioning, the test cell temperature shall be the same as defined for the Type 1 test (paragraph 1.2.2.2.1. of this Sub-Annex).
 1.2.6.3.4. The drive-wheel tyre pressure shall be set in accordance with paragraph 1.2.4.5. of this Sub-Annex.
 1.2.6.3.5. Between the tests on the first gaseous reference fuel and the second gaseous reference fuel, for vehicles with positive ignition engines fuelled with LPG or NG/biomethane or so equipped that they can be fuelled with either petrol or LPG or NG/biomethane, the vehicle shall be preconditioned again before the test on the second reference fuel.
 1.2.6.3.6. 
The dynamometer shall be set according to Sub-Annex 4.
 1.2.6.3.7. At the request of the manufacturer or approval authority, additional WLTCs may be performed in order to bring the vehicle and its control systems to a stabilized condition.
 1.2.6.3.8. The extent of such additional preconditioning shall be included in all relevant test reports.
 1.2.6.3.9. In a test facility in which there may be possible contamination of a low particulate emitting vehicle test with residue from a previous test on a high particulate emitting vehicle, it is recommended, for the purpose of sampling equipment preconditioning, that a 120 km/h steady state drive cycle of 20 minutes duration be driven by a low particulate emitting vehicle. Longer and/or higher speed running is permissible for sampling equipment preconditioning if required. Dilution tunnel background measurements shall be taken after the tunnel preconditioning, and prior to any subsequent vehicle testing.
 1.2.6.4. The powertrain start procedure shall be initiated by means of the devices provided for this purpose according to the manufacturer's instructions.
A non-vehicle initiated switching of mode of operation during the test shall not be permitted unless otherwise specified.
 1.2.6.4.1. If the initiation of the powertrain start procedure is not successful, e.g. the engine does not start as anticipated or the vehicle displays a start error, the test is void, preconditioning tests shall be repeated and a new test shall be driven.
 1.2.6.4.2. The cycle starts on initiation of the powertrain start procedure.
 1.2.6.4.3. In the cases where LPG or NG/biomethane is used as a fuel, it is permissible that the engine is started on petrol and switched automatically to LPG or NG/biomethane after a predetermined period of time that cannot be changed by the driver.
 1.2.6.4.4. During stationary/idling vehicle phases, the brakes shall be applied with appropriate force to prevent the drive wheels from turning.
 1.2.6.4.5. During the test, speed shall be measured against time or collected by the data acquisition system at a frequency of not less than 1 Hz so that the actual driven speed can be assessed.
 1.2.6.4.6. The distance actually driven by the vehicle shall be included in all relevant test sheets for each WLTC phase.
 1.2.6.5.  1.2.6.5.1. 
The gear shift prescriptions specified in Sub-Annex 2 shall be followed. Vehicles tested according to Sub-Annex 8 shall be driven according to paragraph 1.5. of that Sub-Annex.

Vehicles that cannot attain the acceleration and maximum speed values required in the applicable WLTC shall be operated with the accelerator control fully activated until they once again reach the required speed trace. Speed trace violations under these circumstances shall not void a test. Deviations from the driving cycle shall be included in all relevant test sheets.
 1.2.6.5.1.1. The tolerances given in paragraph 1.2.6.6. of this Sub-Annex shall apply.
 1.2.6.5.1.2. The gear change shall be started and completed within ± 1,0 second of the prescribed gear shift point.
 1.2.6.5.1.3. The clutch shall be depressed within ± 1,0 second of the prescribed clutch operating point.
 1.2.6.5.2.  1.2.6.5.2.1. Vehicles equipped with automatic shift transmissions shall be tested in the predominant mode. The accelerator control shall be used in such a way as to accurately follow the speed trace.
 1.2.6.5.2.2. Vehicles equipped with automatic shift transmissions with driver-selectable modes shall fulfill the limits of criteria emissions in all automatic shift modes used for forward driving. The manufacturer shall give appropriate evidence to the approval authority. On the basis of technical evidence provided by the manufacturer and with the agreement of the approval authority, the dedicated driver-selectable modes for very special limited purposes shall not be considered (e.g. maintenance mode, crawler mode).
 1.2.6.5.2.3. The manufacturer shall give evidence to the approval authority of the existence of a mode that fulfils the requirements of paragraph 3.5.9. of this Annex. With the agreement of the approval authority, the predominant mode may be used as the only mode for the determination of criteria emissions, CO2 emissions, and fuel consumption. Notwithstanding the existence of a predominant mode, the criteria emission limits shall be fulfilled in all considered automatic shift modes used for forward driving as described in paragraph 1.2.6.5.2.2. of this Sub-Annex.
 1.2.6.5.2.4. If the vehicle has no predominant mode or the requested predominant mode is not agreed by the approval authority as a predominant mode, the vehicle shall be tested in the best case mode and worst case mode for criteria emissions, CO2 emissions, and fuel consumption. Best and worst case modes shall be identified by the evidence provided on the CO2 emissions and fuel consumption in all modes. CO2 emissions and fuel consumption shall be the arithmetic average of the test results in both modes. Test results for both modes shall be included in all relevant test reports. Notwithstanding the usage of the best and worst case modes for testing, the criteria emission limits shall be fulfilled in all automatic shift modes in consideration used for forward driving as described in paragraph 1.2.6.5.2.2. of this Sub-Annex.
 1.2.6.5.2.5. 
After initial engagement, the selector shall not be operated at any time during the test. Initial engagement shall be done 1 second before beginning the first acceleration.
 1.2.6.5.2.6. Vehicles with an automatic transmission with a manual mode shall be tested according paragraph 1.2.6.5.2. of this Sub-Annex.
 1.2.6.6. 
The following tolerances shall be permitted between the actual vehicle speed and the prescribed speed of the applicable test cycles. The tolerances shall not be shown to the driver:


((a)) Upper limit: 2,0 km/h higher than the highest point of the trace within ± 1,0 second of the given point in time;
((b)) Lower limit: 2,0 km/h lower than the lowest point of the trace within ± 1,0 second of the given time.

See Figure A6/2.

Speed tolerances greater than those prescribed shall be accepted provided the tolerances are never exceeded for more than 1 second on any one occasion.

There shall be no more than ten such deviations per test.

Figure A6/2 1.2.6.7.  1.2.6.7.1. The vehicle shall be operated with the appropriate accelerator control movement necessary to accurately follow the speed trace.
 1.2.6.7.2. The vehicle shall be operated smoothly, following representative shift points, speeds and procedures.
 1.2.6.7.3. For manual transmissions, the accelerator controller shall be released during each shift and the shift shall be accomplished in minimum time.
 1.2.6.7.4. If the vehicle cannot follow the speed trace, it shall be operated at maximum available power until the vehicle speed reaches the respective target speed again.
 1.2.6.8.  1.2.6.8.1. During decelerations of the cycle, the driver shall deactivate the accelerator control but shall not manually disengage the clutch until the point specified in paragraph 4.(c) of Sub-Annex 2.
 1.2.6.8.1.1. If the vehicle decelerates faster than prescribed by the speed trace, the accelerator control shall be operated such that the vehicle accurately follows the speed trace.
 1.2.6.8.1.2. If the vehicle decelerates too slowly to follow the intended deceleration, the brakes shall be applied such that it is possible to accurately follow the speed trace.
 1.2.6.9.  1.2.6.9.1. If the engine stops unexpectedly, the preconditioning or Type 1 test shall be declared void.
 1.2.6.10. After completion of the cycle, the engine shall be switched off. The vehicle shall not be restarted until the beginning of the test for which the vehicle has been preconditioned.
 1.2.7.  1.2.7.1. After preconditioning and before testing, the test vehicle shall be kept in an area with ambient conditions as specified in paragraph 1.2.2.2.2. of this Sub-Annex.
 1.2.7.2. The vehicle shall be soaked for a minimum of 6 hours and a maximum of 36 hours with the engine compartment cover opened or closed. If not excluded by specific provisions for a particular vehicle, cooling may be accomplished by forced cooling down to the set point temperature. If cooling is accelerated by fans, the fans shall be placed so that the maximum cooling of the drive train, engine and exhaust after-treatment system is achieved in a homogeneous manner.
 1.2.8.  1.2.8.1. The test cell temperature at the start of the test shall be 23 °C ± 3 °C measured at minimum frequency of 1 Hz. The engine oil temperature and coolant temperature, if any, shall be within ± 2 °C of the set point of 23 °C.
 1.2.8.2. The test vehicle shall be pushed onto a dynamometer.
 1.2.8.2.1. The drive wheels of the vehicle shall be placed on the dynamometer without starting the engine.
 1.2.8.2.2. The drive-wheel tyre pressures shall be set in accordance with the provisions of paragraph 1.2.4.5. of this Sub-Annex.
 1.2.8.2.3. The engine compartment cover shall be closed.
 1.2.8.2.4. An exhaust connecting tube shall be attached to the vehicle tailpipe(s) immediately before starting the engine.
 1.2.8.3.  1.2.8.3.1. The powertrain start procedure shall be initiated by means of the devices provided for this purpose according to the manufacturer's instructions.
 1.2.8.3.2. The vehicle shall be driven as described in paragraphs 1.2.6.4. to 1.2.6.10. inclusive of this Sub-Annex over the applicable WLTC, as described in Sub-Annex 1.
 1.2.8.4. RCB data shall be measured for each phase of the WLTC as defined in Appendix 2 to this Sub-Annex.
 1.2.8.5. Actual vehicle speed shall be sampled with a measurement frequency of 10 Hz and the drive trace indices described in paragraph 7. of Sub-Annex 7 shall be calculated and documented.
 1.2.9. 
Gaseous samples shall be collected in bags and the compounds analysed at the end of the test or a test phase, or the compounds may be analysed continuously and integrated over the cycle.
 1.2.9.1. The following steps shall be taken prior to each test.
 1.2.9.1.1. The purged, evacuated sample bags shall be connected to the dilute exhaust and dilution air sample collection systems.
 1.2.9.1.2. Measuring instruments shall be started according to the instrument manufacturers’ instructions.
 1.2.9.1.3. The CVS heat exchanger (if installed) shall be pre-heated or pre-cooled to within its operating test temperature tolerance as specified in paragraph 3.3.5.1. of Sub-Annex 5.
 1.2.9.1.4. Components such as sample lines, filters, chillers and pumps shall be heated or cooled as required until stabilised operating temperatures are reached.
 1.2.9.1.5. CVS flow rates shall be set according to paragraph 3.3.4. of Sub-Annex 5, and sample flow rates shall be set to the appropriate levels.
 1.2.9.1.6. Any electronic integrating device shall be zeroed and may be re-zeroed before the start of any cycle phase.
 1.2.9.1.7. For all continuous gas analysers, the appropriate ranges shall be selected. These may be switched during a test only if switching is performed by changing the calibration over which the digital resolution of the instrument is applied. The gains of an analyser’s analogue operational amplifiers may not be switched during a test.
 1.2.9.1.8. All continuous gas analysers shall be zeroed and calibrated using gases fulfilling the requirements of paragraph 6. of Sub-Annex 5.
 1.2.10.  1.2.10.1. The steps described in paragraphs 1.2.10.1.1. to 1.2.10.1.2.3. inclusive of this Sub-Annex shall be taken prior to each test.
 1.2.10.1.1.  1.2.10.1.1.1. A single particulate sample filter without back-up shall be employed for the complete applicable WLTC. In order to accommodate regional cycle variations, a single filter may be employed for the first three phases and a separate filter for the fourth phase.
 1.2.10.1.2.  1.2.10.1.2.1. 
At the end of the stabilization period, the filter shall be weighed and its weight shall be included in all relevant test sheets. The filter shall subsequently be stored in a closed petri dish or sealed filter holder until needed for testing. The filter shall be used within 8 hours of its removal from the weighing chamber (or room).

The filter shall be returned to the stabilization room within 1 hour after the test and shall be conditioned for at least 1 hour before weighing.
 1.2.10.1.2.2. The particulate sample filter shall be carefully installed into the filter holder. The filter shall be handled only with forceps or tongs. Rough or abrasive filter handling will result in erroneous weight determination. The filter holder assembly shall be placed in a sample line through which there is no flow.
 1.2.10.1.2.3. It is recommended that the microbalance be checked at the start of each weighing session, within 24 hours of the sample weighing, by weighing one reference item of approximately 100 mg. This item shall be weighed three times and the arithmetic average result included in all relevant test sheets. If the arithmetic average result of the weighings is ± 5 μg of the result from the previous weighing session, the weighing session and balance are considered valid.
 1.2.11.  1.2.11.1. The steps described in paragraphs 1.2.11.1.1. to 1.2.11.1.2. inclusive of this Sub-Annex shall be taken prior to each test:
 1.2.11.1.1. The particle specific dilution system and measurement equipment shall be started and made ready for sampling;
 1.2.11.1.2. The correct function of the PNC and VPR elements of the particle sampling system shall be confirmed according to the procedures listed in paragraphs 1.2.11.1.2.1. to 1.2.11.1.2.4. inclusive of this Sub-Annex.
 1.2.11.1.2.1. A leak check, using a filter of appropriate performance attached to the inlet of the entire PN measurement system, VPR and PNC, shall report a measured concentration of less than 0.5 particles per cm3.
 1.2.11.1.2.2. Each day, a zero check on the PNC, using a filter of appropriate performance at the PNC inlet, shall report a concentration of ≤ 0,2 particles per cm3. Upon removal of the filter, the PNC shall show an increase in measured concentration to at least 100 particles per cm3 when sampling ambient air and a return to ≤ 0.2 particles per cm3 on replacement of the filter.
 1.2.11.1.2.3. It shall be confirmed that the measurement system indicates that the evaporation tube, where featured in the system, has reached its correct operating temperature.
 1.2.11.1.2.4. It shall be confirmed that the measurement system indicates that the diluter PND1 has reached its correct operating temperature.
 1.2.12.  1.2.12.1. The dilution system, sample pumps and data collection system shall be started.
 1.2.12.2. The PM and PN sampling systems shall be started.
 1.2.12.3. Particle number shall be measured continuously. The arithmetic average concentration shall be determined by integrating the analyser signals over each phase.
 1.2.12.4. Sampling shall begin before or at the initiation of the powertrain start procedure and end on conclusion of the cycle.
 1.2.12.5.  1.2.12.5.1.  1.2.12.5.1.1. Sampling from the diluted exhaust and dilution air shall be switched from one pair of sample bags to subsequent bag pairs, if necessary, at the end of each phase of the applicable WLTC to be driven.
 1.2.12.5.2.  1.2.12.5.2.1. The requirements of paragraph 1.2.10.1.1.1. of this Sub-Annex shall apply.
 1.2.12.6. Dynamometer distance shall be included in all relevant test sheets for each phase.
 1.2.13.  1.2.13.1. The engine shall be turned off immediately after the end of the last part of the test.
 1.2.13.2. The constant volume sampler, CVS, or other suction device shall be turned off, or the exhaust tube from the tailpipe or tailpipes of the vehicle shall be disconnected.
 1.2.13.3. The vehicle may be removed from the dynamometer.
 1.2.14.  1.2.14.1.  1.2.14.1.1. Zero and calibration gas reading of the analysers used for continuous diluted measurement shall be checked. The test shall be considered acceptable if the difference between the pre-test and post-test results is less than 2 per cent of the calibration gas value.
 1.2.14.2.  1.2.14.2.1. 
The gas reactivity time for compounds in the bag shall be taken into consideration.
 1.2.14.2.2. As soon as practical prior to analysis, the analyser range to be used for each compound shall be set to zero with the appropriate zero gas.
 1.2.14.2.3. The calibration curves of the analysers shall be set by means of calibration gases of nominal concentrations of 70 to 100 per cent of the range.
 1.2.14.2.4. The zero settings of the analysers shall be subsequently rechecked: if any reading differs by more than 2 per cent of the range from that set in paragraph 1.2.14.2.2. of this Sub-Annex, the procedure shall be repeated for that analyser.
 1.2.14.2.5. The samples shall be subsequently analysed.
 1.2.14.2.6. After the analysis, zero and calibration points shall be rechecked using the same gases. The test shall be considered acceptable if the difference is less than 2 per cent of the calibration gas value.
 1.2.14.2.7. The flow rates and pressures of the various gases through analysers shall be the same as those used during calibration of the analysers.
 1.2.14.2.8. The content of each of the compounds measured shall be included in all relevant test sheets after stabilization of the measuring device.
 1.2.14.2.9. The mass and number of all emissions, where applicable, shall be calculated according to Sub-Annex 7.
 1.2.14.2.10. 

((a)) Before and after each bag pair analysis; or
((b)) Before and after the complete test.

In case (b), calibrations and checks shall be performed on all analysers for all ranges used during the test.

In both cases, (a) and (b), the same analyser range shall be used for the corresponding ambient air and exhaust bags.
 1.2.14.3.  1.2.14.3.1. The particulate sample filter shall be returned to the weighing chamber (or room) no later than 1 hour after completion of the test. It shall be conditioned in a petri dish, which is protected against dust contamination and allows air exchange, for at least 1 hour, and weighed. The gross weight of the filter shall be included in all relevant test sheets.
 1.2.14.3.2. At least two unused reference filters shall be weighed within 8 hours of, but preferably at the same time as, the sample filter weighings. Reference filters shall be of the same size and material as the sample filter.
 1.2.14.3.3. If the specific weight of any reference filter changes by more than ± 5 μg between sample filter weighings, the sample filter and reference filters shall be reconditioned in the weighing chamber (or room) and reweighed.
 1.2.14.3.4. The comparison of reference filter weighings shall be made between the specific weights and the rolling arithmetic average of that reference filter's specific weights. The rolling arithmetic average shall be calculated from the specific weights collected in the period after the reference filters were placed in the weighing chamber (or room). The averaging period shall be at least one day but not more than 15 days.
 1.2.14.3.5. Multiple reconditionings and reweighings of the sample and reference filters are permitted until a period of 80 hours has elapsed following the measurement of gases from the emissions test. If, prior to or at the 80 hour point, more than half the number of reference filters meet the ± 5 μg criterion, the sample filter weighing may be considered valid. If, at the 80 hour point, two reference filters are employed and one filter fails the ± 5 μg criterion, the sample filter weighing may be considered valid under the condition that the sum of the absolute differences between specific and rolling means from the two reference filters shall be less than or equal to 10 μg.
 1.2.14.3.6. In the case that less than half of the reference filters meet the ± 5 μg criterion, the sample filter shall be discarded, and the emissions test repeated. All reference filters shall be discarded and replaced within 48 hours. In all other cases, reference filters shall be replaced at least every 30 days and in such a manner that no sample filter is weighed without comparison to a reference filter that has been present in the weighing chamber (or room) for at least one day.
 1.2.14.3.7. If the weighing chamber (or room) stability criteria outlined in paragraph 4.2.2.1. of Sub-Annex 5 are not met, but the reference filter weighings meet the above criteria, the vehicle manufacturer has the option of accepting the sample filter weights or voiding the tests, repairing the weighing chamber (or room) control system and re-running the test.

Sub-Annex 6 1.  1.1. 
Upon request of the manufacturer and with approval of the approval authority, a manufacturer may develop an alternative procedure to demonstrate its equivalency, including filter temperature, loading quantity and distance driven. This may be done on an engine bench or on a chassis dynamometer.

Alternatively to carrying out the test procedures defined in this Appendix, a fixed Ki value of 1,05 may be used for CO2 and fuel consumption.
 1.2. During cycles where regeneration occurs, emission standards need not apply. If a periodic regeneration occurs at least once per Type 1 test and has already occurred at least once during vehicle preparation, it does not require a special test procedure. In this case, this Appendix does not apply.
 1.3. The provisions of this Appendix shall apply for the purposes of PM measurements only and not PN measurements.
 1.4. At the request of the manufacturer, and with approval of the approval authority, the test procedure specific to periodically regenerating systems will not apply to a regenerative device if the manufacturer provides data demonstrating that, during cycles where regeneration occurs, emissions remain below the emissions limits for the relevant vehicle category.
 1.5. At the request of the manufacturer and with the agreement of the approval authority the Extra High phase may be excluded for determining the regenerative factor K_i for Class 2 and Class 3 vehicles.
 2. 
The test vehicle shall be capable of inhibiting or permitting the regeneration process provided that this operation has no effect on original engine calibrations. Prevention of regeneration is only permitted during loading of the regeneration system and during the preconditioning cycles. It is not permitted during the measurement of emissions during the regeneration phase. The emission test shall be carried out with the unchanged, original equipment manufacturer's (OEM) control unit. At the request of the manufacturer and with approval of the approval authority, an ‘engineering control unit’ which has no effect on original engine calibrations may be used during Ki determination.
 2.1.  2.1.1. The arithmetic average emissions between regeneration events and during loading of the regenerative device shall be determined from the arithmetic mean of several approximately equidistant (if more than two) Type 1 tests. As an alternative, the manufacturer may provide data to show that the emissions remain constant (± 15 per cent) on WLTCs between regeneration events. In this case, the emissions measured during the Type 1 test may be used. In any other case, emissions measurements for at least two Type 1 cycles shall be completed: one immediately after regeneration (before new loading) and one as close as possible prior to a regeneration phase. All emissions measurements shall be carried out according to this Sub-Annex and all calculations shall be carried out according to paragraph 3. of this Appendix.
 2.1.2. The loading process and determination shall be made during the Type 1 driving cycle on a chassis dynamometer or on an engine test bench using an equivalent test cycle. These cycles may be run continuously (i.e. without the need to switch the engine off between cycles). After any number of completed cycles, the vehicle may be removed from the chassis dynamometer and the test continued at a later time.
 2.1.3. The number of cycles D between two WLTCs where regeneration events occur, the number of cycles over which emission measurements are made n and mass emissions measurement M′sij for each compound i over each cycle j shall be included in all relevant test sheets.
 2.2.  2.2.1. Preparation of the vehicle, if required, for the emissions test during a regeneration phase, may be completed using the preconditioning cycles in paragraph 1.2.6. of this Sub-Annex or equivalent engine test bench cycles, depending on the loading procedure chosen in paragraph 2.1.2. of this Sub-Annex.
 2.2.2. The test and vehicle conditions for the Type 1 test described in this Annex apply before the first valid emission test is carried out.
 2.2.3. 

2.2.3.1. A ‘dummy’ regenerating system or partial system may be fitted for the preconditioning cycles.
2.2.3.2. Any other method agreed between the manufacturer and the approval authority.
 2.2.4. A cold start exhaust emissions test including a regeneration process shall be performed according to the applicable WLTC.
 2.2.5. If the regeneration process requires more than one WLTC, each WLTC shall be completed. Use of a single particulate sample filter for multiple cycles required to complete regeneration is permissible.
 2.2.5.1. If more than one WLTC is required, subsequent WLTC(s) shall be driven immediately, without switching the engine off, until complete regeneration has been achieved. In the case that the number of gaseous emission bags required for the multiple cycles would exceed the number of bags available, the time necessary to set up a new test shall be as short as possible. The engine shall not be switched off during this period.
 2.2.6. The emission values during regeneration Mri for each compound i shall be calculated according to paragraph 3. in this Appendix. The number of applicable test cycles d measured for complete regeneration shall be included in all relevant test sheets.
 3.  3.1. Msi=∑nj= 1M′sijn for n≥ 1Mri=∑dj= 1M′rijd for d≥ 1Mpi=Msi× D+ Mri× dD+ d
where for each compound i considered:

M′sijare the mass emissions of compound i over test cycle j without regeneration, g/km;M′rijare the mass emissions of compound i over test cycle j during regeneration, g/km (if , the first WLTC test shall be run cold and subsequent cycles hot);Msiare the mean mass emissions of compound i without regeneration, g/km;Mriare the mean mass emissions of compound i during regeneration, g/km;Mpiare the mean mass emissions of compound i, g/km;nis the number of test cycles, between cycles where regenerative events occur, during which emissions measurements on Type 1 WLTCs are made, ≥ 1;dis the number of complete applicable test cycles required for regeneration;Dis the number of complete applicable test cycles between two cycles where regeneration events occur.

The calculation of Mpi is shown graphically in Figure A6. App1/1.

Figure A6.App1/1 3.1.1. 
The manufacturer may elect to determine for each compound independently either additive offsets or multiplicative factors.

Ki factor: Ki=MpiMsi

Ki offset: Ki=Mpi− Msi

Msi, Mpi and Ki results, and the manufacturer’s choice of type of factor shall be recorded. The Ki result shall be included in all relevant test reports. Msi, Mpi and Ki results shall be included in all relevant test sheets.

Ki may be determined following the completion of a single regeneration sequence comprising measurements before, during and after regeneration events as shown in Figure A6. App1/1.
 3.2. 
The following shall be calculated for (a) one Type 1 operation cycle for criteria emissions and (b) for each individual phase for CO2 emissions and fuel consumption.
Msik=∑nkj= 1M′sik,jnk for nj≥ 1Mrik=∑dkj= 1M′rik,jdk for d≥ 1Msi=∑xk= 1Msik× Dk∑xk= 1DkMri=∑xk= 1Mrik× dk∑xk= 1dkMpi=Msi×∑xk= 1Dk+ Mri×∑xk= 1dk∑xk= 1Dk+ dkMpi=∑xk= 1Msik× Dk+ Mrik× dk∑xk= 1Dk+ dk
Ki factor: Ki=MpiMsi

Ki offset: Ki=Mpi− Msi

where:

Msiare the mean mass emissions of all events k of compound i without regeneration, g/km;Mriare the mean mass emissions of all events k of compound i during regeneration, g/km;Mpiare the mean mass emission of all events k of compound i, g/km;Msikare the mean mass emissions of event k of compound i without regeneration, g/km;Mrikare the mean mass emissions of event k of compound i during regeneration, g/km;M′sik,jare the mass emissions of event k of compound i in g/km without regeneration measured at point j where 1 ≤ j ≤ nk, g/km;M′rik,jare the mass emissions of event k of compound i during regeneration (when j > 1, the first Type 1 test is run cold, and subsequent cycles are hot) measured at test cycle j where 1 ≤ j ≤ dk, g/km;nkare the number of complete test cycles of event k, between two cycles where regenerative phases occur, during which emissions measurements (Type 1 WLTCs or equivalent engine test bench cycles) are made, ≥ 2;dkis the number of complete applicable test cycles of event k required for complete regeneration;Dkis the number of complete applicable test cycles of event k between two cycles where regenerative phases occur;xis the number of complete regeneration events.

The calculation of Mpi is shown graphically in Figure A6.App1/2.

Figure A6.App1/2
The calculation of Ki for multiple periodic regenerating systems is only possible after a certain number of regeneration events for each system.

After performing the complete procedure (A to B, see Figure A6.App1/2), the original starting condition A should be reached again.

Sub-Annex 6 1. 
In the case that NOVC-HEVs and OVC-HEVs are tested, Appendices 2 and 3 of Sub-Annex 8 shall apply.

This Appendix defines the specific provisions regarding the correction of test results for CO2 mass emission as a function of the energy balance ΔEREESS for all REESSs.

The corrected values for CO2 mass emission shall correspond to a zero energy balance (ΔEREESS = 0), and shall be calculated using a correction coefficient determined as defined below.
 2.  2.1. 
REESS depletion shall be defined as negative current.
 2.1.1. The REESS current(s) shall be measured during the tests using a clamp-on or closed type current transducer. The current measurement system shall fulfil the requirements specified in Table A8/1. The current transducer(s) shall be capable of handling the peak currents at engine starts and temperature conditions at the point of measurement.
 2.1.2. 
In case of shielded wires, appropriate methods shall be applied in accordance with the approval authority.

In order to easily measure REESS current using external measuring equipment, manufacturers should preferably integrate appropriate, safe and accessible connection points in the vehicle. If this is not feasible, the manufacturer shall support the approval authority by providing the means to connect a current transducer to the REESS cables in the manner described above.
 2.1.3. The measured current shall be integrated over time at a minimum frequency of 20 Hz, yielding the measured value of Q, expressed in ampere-hours Ah. The measured current shall be integrated over time, yielding the measured value of Q, expressed in ampere-hours Ah. The integration may be done in the current measurement system.
 2.2.  2.2.1. 

((a)) Integrated charging balance value since last ignition run in Ah;
((b)) Integrated on-board data charging balance value calculated at a minimum sample frequency of 5 Hz;
((c)) The charging balance value via an OBD connector as described in SAE J1962.
 2.2.2. 
The manufacturer may create a REESS monitoring vehicle family to prove that the vehicle on-board REESS charging and discharging data are correct. The accuracy of the data shall be demonstrated on a representative vehicle.

The following family criteria shall be valid:


((a)) Identical combustion processes (i.e. positive ignition, compression→ignition, two-stroke, four-stroke);
((b)) Identical charge and/or recuperation strategy (software REESS data module);
((c)) On-board data availability;
((d)) Identical charging balance measured by REESS data module;
((e)) Identical on-board charging balance simulation.
 3.  3.1. Measurement of the REESS current shall start at the same time as the test starts and shall end immediately after the vehicle has driven the complete driving cycle.
 3.2. The electricity balance Q measured in the electric power supply system, shall be used as a measure of the difference in the REESS energy content at the end of the cycle compared to the beginning of the cycle. The electricity balance shall be determined for the total WLTC for the applicable vehicle class.
 3.3. Separate values of Qphase shall be logged over the cycle phases required to be driven for the applicable vehicle class.
 3.4. Correction of CO2 mass emission over the whole cycle as a function of the correction criterion c.
 3.4.1. 
The correction criterion c is the ratio between the absolute value of the electric energy change ΔEREESS,j and the fuel energy and shall be calculated using the following equations:
c=ΔEREESS,jEfuel
where:

cis the correction criterion;ΔEREESS,jis the electric energy change of all REESSs over period j determined according to paragraph 4.1. of this Appendix, Wh;jis, in this paragraph, the whole applicable WLTP test cycle;Efuelis the fuel energy according to the following equation:Efuel=10× HV× FCnb× d

where:

Efuelis the energy content of the consumed fuel over the applicable WLTP test cycle, Wh;HVis the heating value according to Table A6.App2/1, kWh/l;FCnbis the non-balanced fuel consumption of the Type 1 test, not corrected for the energy balance, determined according to paragraph 6. of Sub-Annex 7, l/100 km;dis the distance driven over the corresponding applicable WLTP test cycle, km;10conversion factor to Wh.
 3.4.2. The correction shall be applied if ΔEREESS is negative (corresponding to REESS discharging) and the correction criterion c calculated according to paragraph 3.4.1. of this Sub-Annex is greater than the applicable tolerance according to Table A6.App2/2.
 3.4.3. The correction shall be omitted and uncorrected values shall be used if the correction criterion c calculated according to paragraph 3.4.1. of this Sub-Annex is less than the applicable tolerance according to Table A6.App2/2.
 3.4.4. The correction may be omitted and uncorrected values may be used if:

((a)) ΔEREESS is positive (corresponding to REESS charging) and the correction criterion c calculated according to paragraph 3.4.1. of this Sub-Annex is greater than the applicable tolerance according to Table A6.App2/2;
((b)) the manufacturer can prove to the approval authority by measurement that there is no relation between ΔEREESS and CO2 mass emission and ΔEREESS and fuel consumption respectively.

Fuel Petrol Diesel
Content Ethanol/Biodiesel, per cent E10 E85 B7
Heat value(kWh/l) 8,64 6,41 9,79

Cycle low + medium low + medium + high low + medium + high + extra high
Correction criterion c 0,015 0,01 0,005
 4.  4.1. 
ΔEREESS,j=∑i= 1n ΔEREESS,j,i

where:

ΔEREESS,j,iis the electric energy change of REESS i during the considered period j, Wh;

and:

ΔEREESS,j,i=13600× UREESS×∫t0tend Itj,i dt

where:

UREESSis the nominal REESS voltage determined according to DIN EN 60050-482, V;I(t)j,iis the electric current of REESS i during the considered period j determined according to paragraph 2. of this Appendix, A;t0is the time at the beginning of the considered period j, s;tendis the time at the end of the considered period j, s.iis the index number of the considered REESS;nis the total amount of REESS;jis the index number for the considered period, where a period shall be any applicable cycle phase, combination of cycle phases and the applicable total cycle;13600is the conversion factor from Ws to Wh.
 4.2. For correction of CO2 mass emission, g/km, combustion process-specific Willans factors from Table A6.App2/3 shall be used.
 4.3. The correction shall be performed and applied for the total cycle and for each of its cycle phases separately, and shall be included in all relevant test reports.
 4.4. 
ηalternator=0,67 for electric power supply system REESS alternators
 4.5. 
ΔMCO2,j=0,0036× ΔEREESS,j×1ηalternator× Willansfactor×1dj

where:

ΔMCO2,jis the resulting CO2 mass emission difference of period j, g/km;ΔEREESS,jis the REESS energy change of the considered period j calculated according to paragraph 4.1. of this Appendix, Wh;djis the driven distance of the considered period j, km;jis the index number for the considered period, where a period shall be any applicable cycle phase, combination of cycle phases and the applicable total cycle;0,0036is the conversion factor from Wh to MJ;ηalternatoris the efficiency of the alternator according to paragraph 4.4. of this Appendix;Willansfactoris the combustion process specific Willans factor as defined in Table A6.App2/3, gCO2/MJ;
 4.5.1. 
MCO2,p,3=MCO2,p,1− ΔMCO2,j

MCO2,c,3=MCO2,c,2− ΔMCO2,j

where:

ΔMCO2,jis the result from paragraph 4.5. of this Sub-Annex for a period j, g/km.
 4.6. 

Table A6.App2/3
Willans factors
 Naturally aspirated Pressure-charged
Positive ignition Petrol (E10) l/MJ 0,0756 0,0803
 gCO2/MJ 174 184
CNG (G20) m3/MJ 0,0719 0,0764
gCO2/MJ 129 137
LPG l/MJ 0,0950 0,101
gCO2/MJ 155 164
E85 l/MJ 0,102 0,108
gCO2/MJ 169 179
Compression ignition Diesel (B7) l/MJ 0,0611 0,0611
gCO2/MJ 161 161
Sub-Annex 6a
1. 
This Sub-Annex describes the supplemental Ambient Temperature Correction Test (ATCT) procedure to determine the CO2 emissions under representative regional temperature conditions.
 1.1. The CO2 emissions of ICE vehicles, NOVC-HEVs and the charge sustaining value of OVC-HEVs shall be corrected according to the requirements of this Sub14-Annex. No correction is required for the CO2 value of the charge depleting test. No correction is required for an Electric Range.

2.  2.1. 

((a)) Powertrain architecture (i.e. internal combustion, hybrid, fuel cell, or electric);
((b)) Combustion process (i.e. two stroke or four stroke);
((c)) Number and arrangement of cylinders;
((d)) Method of engine combustion (i.e. indirect or direct injection);
((e)) Type of cooling system (i.e. air, water, or oil);
((f)) Method of aspiration (i.e. naturally aspirated, or charged);
((g)) Fuel for which the engine is designed (i.e. petrol, diesel, NG, LPG, etc.);
((h)) Catalytic converter (i.e. three-way catalyst, lean NOx trap, SCR, lean NOx catalyst or other(s));
((i)) Whether or not a particulate trap is installed; and
((j)) Exhaust gas recirculation (with or without, cooled or non-cooled).
In addition the vehicles shall be similar with respect to the following characteristics:
((k)) The vehicles shall have a variation in engine cylinder capacity of no more than 30 % of the vehicle with the lowest capacity; and
((l)) Engine compartment insulation shall be of a similar type regarding material, amount and location of the insulation. Manufacturers shall provide evidence (e.g. by CAD drawings) to the approval authority that the volume and weight of the installed insulation material is within a tolerance of 10 % to the ATCT measured reference vehicle.
 2.1.1. 

((i)) the heat capacity, defined by the enthalpy stored in the system, is within a range of 0 to 10 % above the enthalpy of the test vehicle; and
((ii)) the OEM can provide evidence to the technical service that the time for heat release at engine start within a family is within a range of 0 to 10 % below the time for the heat release of the test vehicle.
 2.1.2. Only vehicles that meet the criteria according to paragraph 3.9.4. of this Sub-Annex shall be considered to be part of the same ATCT Family.

3. 
The Type 1 test specified in Sub-Annex 6 shall be carried out with the exception of the requirements specified in paragraphs 3.1. to 3.9. inclusive of this ATCT Sub-Annex 6a.
 3.1.  3.1.1. The temperature (Treg) at which the vehicle should be soaked and tested for the ATCT shall be 14 °C.
 3.1.2. The minimum soaking time (tsoak_ATCT) for the ATCT shall be 9 hours.
 3.2.  3.2.1.  3.2.1.1. The test cell shall have a temperature set point equal to Treg. The actual temperature value shall be within ± 3 °C at the start of the test and within ± 5 °C during the test. The air temperature and humidity shall be measured at the cooling fan outlet at a minimum frequency of 1 Hz.
 3.2.1.2. 
3,0≤ H≤ 8,1 g H2O∕kg dry air
 3.2.1.3. The air temperature and humidity shall be measured at the outlet of the vehicle cooling fan at a rate of 1 Hz.
 3.2.2.  3.2.2.1. The soak area shall have a temperature set point equal to Treg and the actual temperature value shall be within ± 3 °C on a 5 minute running arithmetic average and shall not show a systematic deviation from the set point. The temperature shall be measured continuously at a minimum frequency of 1 Hz.
 3.2.2.2. 
The sensor shall be at least 10 cm away from the wall of the soak area and shall be shielded against direct air flow.

The air-flow conditions within the soak room in the vicinity of the vehicle shall represent a natural convection flow representative for the dimension of the room (no forced convection).
 3.3.  3.3.1. The vehicle to be tested shall be representative for the family for which the ATCT data are determined (as described in paragraph 2.3. of this Sub-Annex).
 3.3.2. From the ATCT Family, the Interpolation Family with the lowest engine capacity shall be selected (see paragraph 2 of this Sub-Annex), and the test vehicle shall be in the ‘vehicle H’ configuration of this family.
 3.3.3. Where applicable, the vehicle with the lowest enthalpy of the active heat storage device and the slowest heat release for the active heat storage device from the ATCT Family shall be selected.
 3.3.4. The test vehicle shall meet the requirements detailed in paragraph 1.2.3. of Sub-Annex 6.
 3.4.  3.4.1. 
To take account of the difference in air density at 14 °C when compared to the air density at 20 °C, the chassis dynamometer shall be set as specified in paragraphs 7. and 8. of Sub-Annex 4 with the exception that f2_TReg from the following equation shall be used as the target coefficient Ct.

f2_TReg=f2×Tref+ 273∕Treg+ 273

where:

f2is the second order road load coefficient, at reference conditions, N/(km/h)2;Trefis the road load reference temperature as specified in paragraph 3.2.10. of this Annex, C;Tregis the regional temperature, as defined in paragraph 3.1.1., C.

In the case that a valid chassis dynamometer setting of the 23 °C test is available, the second order chassis dynamometer coefficient of, Cd, shall be adapted according to the following equation:

Cd_Treg=Cd+f2_TReg− f2
 3.5.  3.5.1. The vehicle shall be preconditioned as described in paragraph 1.2.6. of Sub-Annex 6. At the request of the manufacturer preconditioning may be undertaken at Treg.
 3.6.  3.6.1. After preconditioning and before testing, vehicles shall be kept in a soak area with the ambient conditions described in paragraph 3.2.2. of this Sub-Annex.
 3.6.2. The transfer from the preconditioning to the soak area shall be undertaken as quickly as possible, within a maximum of 10 minutes.
 3.6.3. The vehicle shall then be kept in the soak area such that the time from the end of the preconditioning test to the beginning of the ATCT test is equal to tsoak_ATCT with a tolerance of an additional 15 minutes. At the request of the manufacturer, and upon approval of the approval authority, tsoak_ATCT can be extended by up to 120 minutes. In this case, the extended time shall be used for the cool down specified in paragraph 3.9. of this Sub-Annex.
 3.6.4. The soak shall be performed without using a cooling fan and with all body parts positioned as intended under normal parking operation. The time between the end of the preconditioning and the start of the ATCT test shall be recorded.
 3.6.5. The transfer from the soak area to the test cell shall be undertaken as quickly as possible. The vehicle shall not be exposed to a temperature different from Treg for longer than 10 minutes.
 3.6.6. In the case that this test vehicle serves as the reference vehicle for an ATCT Family, an additional soak at 23 °C, as specified in paragraph 3.9., shall be undertaken.
 3.7.  3.7.1. The test cycle shall be the applicable WLTC specified in Sub-Annex 1 for that class of vehicle.
 3.7.2. The procedures for undertaking the emissions test as specified in Sub-Annex 6 shall be followed, with the exception that the ambient conditions for the test cell shall be those as described in paragraph 3.2.1. of this Sub-Annex.
 3.8.  3.8.1. 
FCF=MCO2,Treg∕MCO2,23°

where

MCO2,23°are the CO2 mass emission over the complete WLTC cycle of the Type 1 test at 23 °C of vehicle H, after Step 3 of Table A7/1 of Sub-Annex 7, but without any further corrections, g/km;MCO2,Tregare the CO2 mass emission over the complete WLTC cycle of the test at regional temperature after Step 3 of Table A7/1 of Sub-Annex 7, but without any further corrections, g/km.

The FCF shall be included in all relevant test reports.
 3.8.2. 
MCO2,c,5=MCO2,c,4× FCF

MCO2,p,5=MCO2,p,4× FCF

where:

MCO2,c,4and MCO2,p,4 are the CO2 mass emissions over the complete WLTC, c, and the cycle phases, p, resulting from the previous calculation step, g/km;MCO2,c,5and MCO2,p,5 are the CO2 mass emissions over the complete WLTC, c, and the cycle phases, p, including the ATCT correction, and shall be used for any further corrections or any further calculations, g/km;
 3.9.  3.9.1. For the test vehicle serving as a reference vehicle for the ATCT Family and all vehicles H of the interpolation families within the ATCT Family, the end temperature of the engine coolant shall be measured after driving the respective Type 1 test at 23 °C and after soaking at 23 °C for the duration of tsoak_ATCT, with a tolerance of an additional 15 minutes.
 3.9.1.1. In the case that tsoak_ATCT was extended in the respective ATCT test, the same soaking time shall be used, with a tolerance of an additional 15 minutes.
 3.9.2. The cool down procedure shall be undertaken as soon as possible after the end of the Type 1 test, with a maximum delay of 10 minutes. The measured soaking time is the time between the measurement of the end temperature and the end of the Type 1 test at 23 °C, and shall be included in all relevant test sheets.
 3.9.3. The average soak area temperature of the last 3 hours of the soak process has to be subtracted from the measured end temperature of the engine coolant at the end of the soaking time specified in paragraph 3.9.1. This is referred to as ΔT_ATCT.
 3.9.4. Unless the resulting ΔT_ATCT is within the range of – 2 °C to + 4 °C from the reference vehicle, this Interpolation Family shall not be considered to be a member of the same ATCT Family.
 3.9.5. For all vehicles within an ATCT Family the coolant shall be measured at the same location in the cooling system. That location shall be as close as possible to the engine so that the coolant temperature is as representative as possible to the engine temperature.
 3.9.6. The measurement of the temperature of the soak areas shall be as specified in paragraph 3.2.2.2. of this Sub-Annex.

Sub-Annex 7
1.  1.1. Calculations related specifically to hybrid, pure electric and compressed hydrogen fuel cell vehicles are described in Sub-Annex 8.
A stepwise prescription of result calculations is described in paragraph 4. of Sub-Annex 8.
 1.2. The calculations described in this Sub-Annex shall be used for vehicles using combustion engines.
 1.3.  1.3.1. Intermediate steps in the calculations shall not be rounded.
 1.3.2. The final criteria emission results shall be rounded in one step to the number of places to the right of the decimal point indicated by the applicable emission standard plus one additional significant figure.
 1.3.3. The NOx correction factor, KH, shall be rounded to two decimal places.
 1.3.4. The dilution factor, DF, shall be rounded to two decimal places.
 1.3.5. For information not related to standards, good engineering judgement shall be used.
 1.3.6. Rounding of CO2 and fuel consumption results is described in paragraph 1.4. of this Sub-Annex.
 1.4. 
The results shall be calculated in the order described in Table A7/1. All applicable results in the column ‘Output’ shall be recorded. The column ‘Process’ describes the paragraphs to be used for calculation or contains additional calculations.

For the purpose of this table, the following nomenclature within the equations and results is used:

ccomplete applicable cycle;pevery applicable cycle phase;ievery applicable criteria emission component, without CO2;CO2CO2 emission.


Source Input Process Output Step no.
Annex 6 Raw test results Mass emissionsSub-Annex 7, paragraphs 3. to 3.2.2. inclusive Mi,p,1, g/km;MCO2,p,1, g/km. 1
Output step 1 Mi,p,1, g/km;MCO2,p,1, g/km. Calculation of combined cycle values:Mi,c,2=∑pMi,p,1× dp∑pdpMCO2,c,2=∑pMCO2,p,1× dp∑pdpwhere:
 Mi/CO2,c,2 are the emission results over the total cycle;
 dp are the driven distances of the cycle phases, p. Mi,c,2, g/km;MCO2,c,2, g/km. 2
Output step 1 and 2 MCO2,p,1, g/km;MCO2,c,2, g/km. RCB correctionSub-Annex 6, Appendix 2 MCO2,p,3, g/km;MCO2,c,3, g/km. 3
Output step 2 and 3 Mi,c,2, g/km;MCO2,c,3, g/km. Emissions test procedure for all vehicles equipped with periodically regenerating systems, Ki.Sub-Annex 6, Appendix 1.Mi,c,4=Ki× Mi,c,2orMi,c,4=Ki× Mi,c,2andMCO2,c,4=KCO2× MCO2,c,3orMCO2,c,4=KCO2× MCO2,c,3Additive offset or multiplicative factor to be used according to Ki determination.If Ki is not applicable:Mi,c,4=Mi,c,2MCO2,c,4=MCO2,c,3 Mi,c,4, g/km;MCO2,c,4, g/km. 4a
Output step 3 and 4a MCO2,p,3, g/km;MCO2,c,3, g/km;MCO2,c,4, g/km. If Ki is applicable, align CO2 phase values to the combined cycle value:MCO2,p,4=MCO2,p,3× AFKifor every cycle phase p;where:AFKi=MCO2,c,4MCO2,c,3If Ki is not applicable:MCO2,p,4=MCO2,p,3 MCO2,p,4, g/km. 4b
Output step 4 Mi,c,4, g/km;MCO2,c,4, g/km;MCO2,p,4, g/km. ATCT correction according to paragraph 3.8.2. of Sub-Annex 6a.Deterioration factors calculated according to Annex VII and applied to the criteria emissions values. Mi,c,5, g/km;MCO2,c,5, g/km;MCO2,p,5, g/km. 5‘result of a single test’
Output step 5 For every test:Mi,c,5, g/km;MCO2,c,5, g/km;MCO2,p,5, g/km. Averaging of tests and declared value.Sub-Annex 6, paragraphs 1.1.2. to 1.1.2.3. inclusive Mi,c,6, g/km;MCO2,c,6, g/km;MCO2,p,6, g/km.MCO2,c,declared, g/km. 6
Output step 6 MCO2,c,6, g/km;MCO2,p,6, g/km.MCO2,c,declared, g/km. Alignment of phase values.Sub-Annex 6, paragraph 1.1.2.4.and:MCO2,c,7=MCO2,c,declared MCO2,c,7, g/km;MCO2,p,7, g/km. 7
Output steps 6 and 7 Mi,c,6, g/km;MCO2,c,7, g/km;MCO2,p,7, g/km. Calculation of fuel consumption.Sub-Annex 7, paragraph 6.The calculation of fuel consumption shall be performed for the applicable cycle and its phases separately. For that purpose:
((a)) the applicable phase or cycle CO2 values shall be used;
((b)) the criteria emission over the complete cycle shall be used.and:Mi,c,8=Mi,c,6MCO2,c,8=MCO2,c,7MCO2,p,8=MCO2,p,7 FCc,8, l/100 km;FCp,8, l/100 km;Mi,c,8, g/km;MCO2,c,8, g/km;MCO2,p,8, g/km. 8‘result of a Type 1 test for a test vehicle’
Step 8 For each of the test vehicles H and L:Mi,c,8, g/km;MCO2,c,8, g/km;MCO2,p,8, g/km;FCc,8, l/100 km;FCp,8, l/100 km. If a test vehicle L was tested in addition to a test vehicle H, the resulting criteria emission value shall be the highest of the two values and referred to as Mi,c.In the case of the combined THC+NOx emissions, the highest value of the sum referring to either the VH or VL is to be used.Otherwise, if no vehicle L was tested, Mi,c=Mi,c,8For CO2 and FC, the values derived in step 8 shall be used, and CO2 values shall be rounded to two decimal places, and FC values shall be rounded to three decimal places. Mi,c, g/km;MCO2,c,H, g/km;MCO2,p,H, g/km;FCc,H, l/100 km;FCp,H, l/100 km;and if a vehicle L was tested:MCO2,c,L, g/km;MCO2,p,L, g/km;FCc,L, l/100 km;FCp,L, l/100 km. 9‘interpolation family result’Final criteria emission result
Step 9 MCO2,c,H, g/km;MCO2,p,H, g/km;FCc,H, 1/100 km;FCp,H, 1/100 km;and if a vehicle L was tested:MCO2,c,L, g/km;MCO2,p,L, g/km;FCc,L, 1/100 km;FCp,L, 1/100 km. Fuel consumption and CO2 calculations for individual vehicles in an CO2 interpolation family.Sub-Annex 7, paragraph 3.2.3.CO2 emissions must be expressed in grams per kilometre (g/km) rounded to the nearest whole number;FC values shall be rounded to one decimal place, expressed in (1/100 km). MCO2,c,ind g/km;MCO2,p,ind, g/km;FCc,ind 1/100 km;FCp,ind, 1/100 km. 10‘result of an individual vehicle’Final CO2 and FC result

2.  2.1.  2.1.1. The volumetric flow shall be measured continuously. The total volume shall be measured for the duration of the test.
 2.2.  2.2.1. The volume shall be calculated using the following equation:
V=V0× Nwhere:
Vis the volume of the diluted gas, in litres per test (prior to correction);V0is the volume of gas delivered by the positive displacement pump in testing conditions, litres per pump revolution;Nis the number of revolutions per test.
 2.2.1.1. 
The diluted exhaust gas volume, V, shall be corrected to standard conditions according to the following equation:
Vmix=V× K1×PB− P1Tp
where:
K1=273,15K101,325kPa=2,6961
PBis the test room barometric pressure, kPa;P1is the vacuum at the inlet of the positive displacement pump relative to the ambient barometric pressure, kPa;Tpis the arithmetic average temperature of the diluted exhaust gas entering the positive displacement pump during the test, Kelvin (K).

3.  3.1.  3.1.1. Assuming no compressibility effects, all gases involved in the engine's intake, combustion and exhaust processes may be considered to be ideal according to Avogadro’s hypothesis.
 3.1.2. The mass, M of gaseous compounds emitted by the vehicle during the test shall be determined by the product of the volumetric concentration of the gas in question and the volume of the diluted exhaust gas with due regard for the following densities under the reference conditions of 273,15 K (0 °C) and 101,325 kPa:

Carbon monoxide (CO)ρ=1,25 g/lCarbon dioxide (CO2)ρ=1,964 g/l

Hydrocarbons:

for petrol (E10) (C1H1,93 O0,033)ρ=0,646 g/lfor diesel (B7) (C1H1,86O0,007)ρ=0,625 g/lfor LPG (C1H2,525)ρ=0,649 g/lfor NG/biomethane (CH4)ρ=0,716 g/lfor ethanol (E85) (C1H2,74O0,385)ρ=0,934 g/lNitrogen oxides (NOx)ρ=2,05 g/l

The density for NMHC mass calculations shall be equal to that of total hydrocarbons at 273,15 K (0 °C) and 101,325 kPa, and is fuel-dependent. The density for propane mass calculations (see paragraph 3.5. in Sub-Annex 5) is 1,967 g/l at standard conditions.

If a fuel type is not listed in this paragraph, the density of that fuel shall be calculated using the equation given in paragraph 3.1.3. of this Sub-Annex.
 3.1.3. The general equation for the calculation of total hydrocarbon density for each reference fuel with an mean composition of CXHYOZ is as follows:

ρTHC=MWC+HC× MWH+OC× MWOVM

where:

ρTHCis the density of total hydrocarbons and non-methane hydrocarbons, g/l;MWCis the molar mass of carbon (12,011 g/mol);MWHis the molar mass of hydrogen (1,008 g/mol);MWOis the molar mass of oxygen (15,999 g/mol);VMis the molar volume of an ideal gas at 273,15 K (0°C) and 101,325 kPa (22,413 l/mol);H/Cis the hydrogen to carbon ratio for a specific fuel CXHYOZ;O/Cis the oxygen to carbon ratio for a specific fuel CXHYOZ.
 3.2.  3.2.1. Mass emissions of gaseous compounds per cycle phase shall be calculated using the following equations:
Mi,phase=Vmix,phase× ρi× KHphase× Ci,phase× 10− 6dphasewhere:
Miis the mass emission of compound i per test or phase, g/km;Vmixis the volume of the diluted exhaust gas per test or phase expressed in litres per test/phase and corrected to standard conditions (273,15 K (0 °C) and 101,325 kPa);ρiis the density of compound i in grams per litre at standard temperature and pressure (273,15 K (0 °C) and 101,325 kPa);KHis a humidity correction factor applicable only to the mass emissions of oxides of nitrogen, NO2 and NOx, per test or phase;Ciis the concentration of compound i per test or phase in the diluted exhaust gas expressed in ppm and corrected by the amount of compound i contained in the dilution air;dis the distance driven over the applicable WLTC, km;nis the number of phases of the applicable WLTC.
 3.2.1.1. The concentration of a gaseous compound in the diluted exhaust gas shall be corrected by the amount of the gaseous compound in the dilution air using the following equation:
Ci=Ce− Cd×1−1DFwhere:
Ciis the concentration of gaseous compound i in the diluted exhaust gas corrected by the amount of gaseous compound i contained in the dilution air, ppm;Ceis the measured concentration of gaseous compound i in the diluted exhaust gas, ppm;Cdis the concentration of gaseous compound i in the dilution air, ppm;DFis the dilution factor.
 3.2.1.1.1. The dilution factor DF shall be calculated using the equation for the concerned fuel:
DF=13.4CCO2+CHC+ CCO× 10− 4for petrol (E10)DF=13.5CCO2+CHC+ CCO× 10− 4for diesel (B7)DF=11.9CCO2+CHC+ CCO× 10− 4for LPGDF=9.5CCO2+CHC+ CCO× 10− 4for NG/biomethaneDF=12.5CCO2+CHC+ CCO× 10− 4for ethanol (E85)DF=35.03CH2O− CH2O− DA+ CH2× 10− 4for hydrogen
With respect to the equation for hydrogen:
CH2Ois the concentration of H2O in the diluted exhaust gas contained in the sample bag, per cent volume;CH2O-DAis the concentration of H2O in the dilution air, per cent volume;CH2is the concentration of H2 in the diluted exhaust gas contained in the sample bag, ppm.
If a fuel type is not listed in this paragraph, the DF for that fuel shall be calculated using the equations in paragraph 3.2.1.1.2. of this Sub-Annex.
If the manufacturer uses a DF that covers several phases, it shall calculate a DF using the mean concentration of gaseous compounds for the phases concerned.
The mean concentration of a gaseous compound shall be calculated using the following equation:
C–i=∑nphase= 1Ci,phase× Vmix,phase∑nphase= 1 Vmix,phasewhere:
Ciis mean concentration of a gaseous compound;Ci,phaseis the concentration of each phase;Vmix,phaseis the Vmix of the corresponding phase;
 3.2.1.1.2. The general equation for calculating the dilution factor DF for each reference fuel with an arithmetic average composition of CxHyOz is as follows:
DF=XCCO2+CHC+ CCO× 10− 4where:
X=100×xx+y2+ 3,76x+y4−z2CCO2is the concentration of CO2 in the diluted exhaust gas contained in the sample bag, per cent volume;CHCis the concentration of HC in the diluted exhaust gas contained in the sample bag, ppm carbon equivalent;CCOis the concentration of CO in the diluted exhaust gas contained in the sample bag, ppm.
 3.2.1.1.3.  3.2.1.1.3.1. For methane measurement using a GC-FID, NMHC shall be calculated using the following equation:
CNMHC=CTHC−RfCH4× CCH4where:
CNMHCis the corrected concentration of NMHC in the diluted exhaust gas, ppm carbon equivalent;CTHCis the concentration of THC in the diluted exhaust gas, ppm carbon equivalent and corrected by the amount of THC contained in the dilution air;CCH4is the concentration of CCH4 in the diluted exhaust gas, ppm carbon equivalent and corrected by the amount of CH4 contained in the dilution air;RfCH4is the FID response factor to methane as defined in paragraph 5.4.3.2. of Sub-Annex 5.
 3.2.1.1.3.2. For methane measurement using an NMC-FID, the calculation of NMHC depends on the calibration gas/method used for the zero/calibration adjustment.
The FID used for the THC measurement (without NMC) shall be calibrated with propane/air in the normal manner.
For the calibration of the FID in series with an NMC, the following methods are permitted:

((a)) The calibration gas consisting of propane/air bypasses the NMC;
((b)) The calibration gas consisting of methane/air passes through the NMC.
It is highly recommended to calibrate the methane FID with methane/air through the NMC.
In case (a), the concentration of CH4 and NMHC shall be calculated using the following equations:
CCH4=CHC(w/NMC)− CHC(w/oNMC)×1− EErh×EE− EMCNMHC=CHC(w/oNMC)×1− EM− CHC(w/NMC)EE− EMIf rh < 1,05, it may be omitted from the equation above for CCH4.
In case (b), the concentration of CH4 and NMHC shall be calculated using the following equations:
CCH4=CHC(w/NMC)× rh×1− EM− CHC(w/oNMC)×1− EErh×EE− EMCNMHC=CHC(w/oNMC)×1− EM− CHC(w/NMC)× rh×1− EMEE− EMwhere:
CHC(w/NMC)is the HC concentration with sample gas flowing through the NMC, ppm C;CHC(w/oNMC)is the HC concentration with sample gas bypassing the NMC, ppm C;rhis the methane response factor as determined per paragraph 5.4.3.2. of Sub-Annex 5;EMis the methane efficiency as determined per paragraph 3.2.1.1.3.3.1. of this Sub-Annex;EEis the ethane efficiency as determined per paragraph 3.2.1.1.3.3.2. of this Sub-Annex.
If rh < 1,05, it may be omitted in the equations for case (b) above for CCH4 and CNMHC.
 3.2.1.1.3.3. 
The NMC is used for the removal of the non-methane hydrocarbons from the sample gas by oxidizing all hydrocarbons except methane. Ideally, the conversion for methane is 0 per cent, and for the other hydrocarbons represented by ethane is 100 per cent. For the accurate measurement of NMHC, the two efficiencies shall be determined and used for the calculation of the NMHC emission.
 3.2.1.1.3.3.1. 
The methane/air calibration gas shall be flowed to the FID through the NMC and bypassing the NMC and the two concentrations recorded. The efficiency shall be determined using the following equation:
EM=1−CHC(w/NMC)CHC(w/oNMC)
where:

CHC(w/NMC)is the HC concentration with CH4 flowing through the NMC, ppm C;CHC(w/oNMC)is the HC concentration with CH4 bypassing the NMC, ppm C.
 3.2.1.1.3.3.2. 
The ethane/air calibration gas shall be flowed to the FID through the NMC and bypassing the NMC and the two concentrations recorded. The efficiency shall be determined using the following equation:
EE=1−CHC(w/NMC)CHC(w/oNMC)
where:

CHC(w/NMC)is the HC concentration with C2H6 flowing through the NMC, ppm C;CHC(w/oNMC)is the HC concentration with C2H6 bypassing the NMC, ppm C.

If the ethane conversion efficiency of the NMC is 0,98 or above, EE shall be set to 1 for any subsequent calculation.
 3.2.1.1.3.4. If the methane FID is calibrated through the cutter, EM shall be 0.
The equation to calculate CH4 in paragraph 3.2.1.1.3.2. (case (b)) in this Sub-Annex becomes:
CCH4=CHC(w/NMC)The equation to calculate CNMHC in paragraph 3.2.1.1.3.2. (case (b)) in this Sub-Annex becomes:
CNMHC=CHC(w/oNMC)− CHC(w/NMC)× rhThe density used for NMHC mass calculations shall be equal to that of total hydrocarbons at 273,15 K (0 °C) and 101,325 kPa and is fuel-dependent.
 3.2.1.1.4. 
The following calculation method shall only be applied for CVS systems that are not equipped with a heat exchanger or for CVS systems with a heat exchanger that do not comply with paragraph 3.3.5.1. of Sub-Annex 5.

When the CVS flow rate, qvcvs, over the test varies by more than ± 3 per cent of the arithmetic average flow rate, a flow-weighted arithmetic average shall be used for all continuous diluted measurements including PN:
Ce=∑ni= 1 qvcvs(i)× Δt× C(i)V
where:

Ceis the flow-weighted arithmetic average concentration;qvcvs(i)is the CVS flow rate at time t= i× Δt, m3/min;C(i)is the concentration at time t= i× Δt, ppm;Δtsampling interval, s;Vtotal CVS volume, m3.
 3.2.1.2. 
In order to correct the influence of humidity on the results of oxides of nitrogen, the following calculations apply:
KH=11− 0,0329×H− 10,71
where:
H=6,211× Ra× PdPB− Pd× Ra× 10− 2
and:

His the specific humidity, grams of water vapour per kilogram dry air;Rais the relative humidity of the ambient air, per cent;Pdis the saturation vapour pressure at ambient temperature, kPa;PBis the atmospheric pressure in the room, kPa.

The KH factor shall be calculated for each phase of the test cycle.

The ambient temperature and relative humidity shall be defined as the arithmetic average of the continuously measured values during each phase.
 3.2.2.  3.2.2.1. 
Ce=∫t1t2CHC dtt2− t1

where:

∫t1t2CHCdtis the integral of the recording of the heated FID over the test (t1 to t2);Ceis the concentration of HC measured in the diluted exhaust in ppm of Ci and is substituted for CHC in all relevant equations.
 3.2.2.1.1. Dilution air concentration of HC shall be determined from the dilution air bags. Correction shall be carried out according to paragraph 3.2.1.1. of this Sub-Annex.
 3.2.3.  3.2.3.1. 
The CO2 value, as calculated in paragraph 3.2.1. of this Sub-Annex and fuel consumption, as calculated according to paragraph 6. of this Sub-Annex, shall be attributed to all individual vehicles in the interpolation family and the interpolation method shall not be applicable.
 3.2.3.2. 
The CO2 emissions and the fuel consumption for each individual vehicle in the interpolation family may be calculated according to the interpolation method outlined in paragraphs 3.2.3.2.1. to 3.2.3.2.5. inclusive of this Sub-Annex.
 3.2.3.2.1. 
The mass of CO2 emissions, MCO2− L, and MCO2− H and its phases p, MCO2− L,p and MCO2− H,p, of test vehicles L and H, used for the following calculations, shall be taken from step 9 of Table A7/1.

Fuel consumption values are also taken from step 9 of Table A7/1 and are referred to as FCL,p and FCH,p.
 3.2.3.2.2.  3.2.3.2.2.1. 
The test masses of vehicles H and L shall be used as input for the interpolation method.

TMind, in kg, shall be the individual test mass of the vehicle according to paragraph 3.2.25. of this Annex.

If the same test mass is used for test vehicles L and H, the value of TMind shall be set to the mass of test vehicle H for the interpolation method.
 3.2.3.2.2.2. 
The actual rolling resistance values for the selected tyres on test vehicle L, RRL, and test vehicle H, RRH, shall be used as input for the interpolation method. See paragraph 4.2.2.1. of Sub-Annex 4.

If the tyres on the front and rear axles of vehicle L or H have different rolling resistance values, the weighted mean of the rolling resistances shall be calculated using the following equation:
RRx=RRx,FA× mpx,FA+ RRx,RA×1− mpx,FA
where:

RRx,FAis the rolling resistance of the front axle tyres, kg/tonne;RRx,RAis the rolling resistance of the rear axle tyres, kg/tonne;mpx,FAis the proportion of the vehicle mass on the front axle of vehicle H;xrepresents vehicle L, H or an individual vehicle.

For the tyres fitted to an individual vehicle, the value of the rolling resistance RRind shall be set to the class value of the applicable tyre rolling resistance class, according to Table A4/1 of Sub-Annex 4.

If the tyres have different rolling resistance class values on the front and the rear axle, the weighted mean shall be used, calculated with the equation in this paragraph.

If the same tyres were fitted to test vehicles L and H, the value of RRind for the interpolation method shall be set to RRH.
 3.2.3.2.2.3. 
The aerodynamic drag shall be measured for each of the drag-influencing items of optional equipment and body shapes in a wind tunnel fulfilling the requirements of paragraph 3.2. of Sub-Annex 4 verified by the approval authority.

At the request of the manufacturer and with approval of the approval authority, an alternative method (e.g. simulation, wind tunnel not fulfilling the criterion in Sub-Annex 4) may be used to determine Δ(CD×Af) if the following criteria are fulfilled:


((a)) The alternative determination method shall fulfil an accuracy for Δ(CD×Af) of ± 0,015 m2 and additionally, in the case that simulation is used, the Computational Fluid Dynamics method should be validated in detail, so that the actual air flow patterns around the body, including magnitudes of flow velocities, forces, or pressures, are shown to match the validation test results;
((b)) The alternative method shall be used only for those aerodynamic-influencing parts (e.g. wheels, body shapes, cooling system) for which equivalency was demonstrated;
((c)) Evidence of equivalency shall be shown in advance to the approval authority for each road load family in the case that a mathematical method is used or every four years in the case that a measurement method is used, and in any case shall be based on wind tunnel measurements fulfilling the criteria of this Annex;
((d)) If the Δ(CD × Af) of an option is more than double than that with the option for which the evidence was given, aerodynamic drag shall not be determined with the alternative method; and
((e)) In the case that a simulation model is changed, a revalidation shall be necessary. Δ(CD×Af)LH is the difference in the product of the aerodynamic drag coefficient times frontal area of test vehicle H compared to test vehicle L and shall be included in all relevant test reports, m2.
Δ(CD×Af)ind is the difference in the product of the aerodynamic drag coefficient times frontal area between an individual vehicle and test vehicle L due to options and body shapes on the vehicle that differ from those of test vehicle L, m2;
These differences in aerodynamic drag, Δ(CD×Af), shall be determined with an accuracy of 0,015 m2.

Δ(CD×Af)ind may be calculated according to the following equation maintaining the accuracy of 0,015 m2 also for the sum of items of optional equipment and body shapes:
ΔCD× Afind=∑i= 1nΔCD× Afi
where:

CDis the aerodynamic drag coefficient;Afis the frontal area of the vehicle, m2;nis the number of items of optional equipment on the vehicle that are different between an individual vehicle and test vehicle L.ΔCD× Afiis the difference in the product of the aerodynamic drag coefficient times frontal area due to an individual feature, i, on the vehicle and is positive for an item of optional equipment that adds aerodynamic drag with respect to test vehicle L and vice versa, m2;

The sum of all ΔCD× Afi differences between test vehicles L and H shall correspond to the total difference between test vehicles L and H, and shall be referred to as Δ(CD×Af)LH.

The increase or decrease of the product of the aerodynamic drag coefficient times frontal area expressed as Δ(CD×Af) for all of the items of optional equipment and body shapes in the interpolation family that:


((a)) has an influence on the aerodynamic drag of the vehicle; and
((b)) is to be included in the interpolation,

shall be included in all relevant test reports.

The aerodynamic drag of vehicle H shall be applied to the whole interpolation family and Δ(CD×Af)LH shall be set to zero, if:


((a)) the wind tunnel facility is not able to accurately determine Δ(CD×Af); or
((b)) there are no drag influencing items of optional equipment between the test vehicles H and L that are to be included in the interpolation method.
 3.2.3.2.2.4. 
The road load coefficients f0, f1 and f2 (as defined in Sub-Annex 4) for test vehicles H and L are referred to as f0,H, f1,H and f2,H, and f0,L, f1,H and f2,H respectively. An adjusted road load curve for the test vehicle L is defined as follows:
FLv=f*0,L+ f1,L× v+ f*2,L× v2
Applying the least squares regression method in the range of the reference speed points, adjusted road load coefficients f*0,L and f*2,L shall be determined for FLv with the linear coefficient f*1,L set to f1,H. The road load coefficients f0,ind, f1,ind and f2,ind for an individual vehicle in the interpolation family shall be calculated using the following equations:
f0,ind=f0,H− Δf0×TMH× RRH− TMind× RRindTMH× RRH− TML× RRL
or, if TMH× RRH− TML× RRL=0, the equation for f0,ind below shall apply:
f0,ind=f0,H− Δf0f1,ind=f1,Hf2,ind=f2,H− Δf2ΔCd× AfLH−ΔCd× AfindΔCd× AfLH
or, if ΔCd× AfLH=0, the equation for F2,ind below shall apply:
f2,ind=f2,H− Δf2
where:
Δf0=f0,H− f*0,LΔf2=f2,H− f*2,L
In the case of a road load matrix family, the road load coefficients f0, f1 and f2 for an individual vehicle shall be calculated according to the equations in paragraph 5.1.1. of Sub-Annex 4.
 3.2.3.2.3. 
The cycle energy demand of the applicable WLTC, Ek, and the energy demand for all applicable cycle phases Ek,p, shall be calculated according to the procedure in paragraph 5. of this Sub-Annex, for the following sets, k, of road load coefficients and masses:

k=1f0=f*0,L, f1= f1,H, f2= f*2,L, m= TML
(test vehicle L)k=2f0=f0,H, f1= f1,H, f2= f2,H, m= TMH
(test vehicle H)k=3f0=f0,ind, f1= f1,H, f2= f2,ind, m= TMind
(an individual vehicle in the interpolation family)
 3.2.3.2.4. 
For each cycle phase p of the applicable cycle the mass of CO2 emissions g/km, for an individual vehicle shall be calculated using the following equation:
MCO2− ind,p=MCO2− L,p+E3,p− E1,pE2,p− E1,p×MCO2− H,p− MCO2− L,p
The mass of CO2 emissions, g/km, over the complete cycle for an individual vehicle shall be calculated using the following equation:
MCO2− ind=MCO2− L+E3− E1E2− E1×MCO2− H− MCO2− L
The terms E1,p, E2,p and E3,p and E1, E2 and E3 respectively are defined in paragraph 3.2.3.2.3. of this Sub-Annex.
 3.2.3.2.5. 
For each cycle phase p of the applicable cycle, the fuel consumption, l/100 km, for an individual vehicle shall be calculated using the following equation:

FCind,p=FCL,p+E3,p− E1,pE2,p− E1,p×FCH,p− FCL,p

The fuel consumption, 1/100 km, of the complete cycle for an individual vehicle shall be calculated using the following equation:
FCind=FCL+E3− E1E2− E1×FCH− FCL
The terms E1,p, E2,p and E3,p, and E1, E2 and E3 respectively are defined in paragraph 3.2.3.2.3. of this Sub-Annex.
 3.2.4. 
The CO2 emissions and the fuel consumption for each individual vehicle in the road load matrix family shall be calculated according to the interpolation method outlined in paragraphs 3.2.3.2.3. to 3.2.3.2.5. inclusive of this Sub-Annex. Where applicable, references to vehicle L and/or H shall be replaced by references to vehicle LM and/or HM respectively.
 3.2.4.1. 
The mass of CO2 emissions MCO2 of vehicles LM and HM shall be determined according to the calculations in paragraph 3.2.1. of this Sub-Annex for the individual cycle phases p of the applicable WLTC and are referred to as MCO2–LM,p and MCO2–HM,p respectively. Fuel consumption for individual cycle phases of the applicable WLTC shall be determined according to paragraph 6. of this Sub-Annex and are referred to as FCLM,p and FCHM,p respectively.
 3.2.4.1.1. 
The road load force shall be calculated according to the procedure described in paragraph 5.1. of Sub-Annex 4.
 3.2.4.1.1.1. 
The test masses of vehicles HM and LM selected according to paragraph 4.2.1.4. of Sub-Annex 4 shall be used as input.

TMind, in kg, shall be the test mass of the individual vehicle according to the definition of test mass in paragraph 3.2.25. of this Annex.

If the same test mass is used for vehicles LM and HM, the value of TMind shall be set to the mass of vehicle HM for the road load matrix family method.
 3.2.4.1.1.2. 
The rolling resistance values for vehicle LM, RRLM, and vehicle HM, RRHM, selected under paragraph 4.2.1.4. of Sub-Annex 4 shall be used as input.

If the tyres on the front and rear axles of vehicle LM or HM have different rolling resistance values, the weighted mean of the rolling resistances shall be calculated using the following equation:
RRx=RRx,FA× mpx,FA+ RRx,RA×1− mpx,FA
where:

RRx,FAis the rolling resistance of the front axle tyres, kg/tonne;RRx,RAis the rolling resistance of the rear axle tyres, kg/tonne;mpx,FAis the proportion of the vehicle mass on the front axle;xrepresents vehicle L, H or an individual vehicle.

For the tyres fitted to an individual vehicle, the value of the rolling resistance RRind shall be set to the class value of the applicable tyre rolling resistance class according to Table A4/1of Sub-Annex 4.

If the tyres on the front and the rear axles have different rolling resistance class values, the weighted mean shall be used, calculated with the equation in this paragraph.

If the same rolling resistance is used for vehicles LM and HM, the value of RRind shall be set to RRHM for the road load matrix family method.
 3.2.4.1.1.3. 
The frontal area for vehicle LM, AfLM, and vehicle HM, AfHM, selected under paragraph 4.2.1.4. of Sub-Annex 4 shall be used as input.

Af,ind, m2, shall be the frontal area of the individual vehicle.

If the same frontal area is used for vehicles LM and HM, the value of Af,ind shall be set to the frontal area of vehicle HM for the road load matrix family method.
 3.3.  3.3.1. 
PM shall be calculated using the following two equations:
PM=Vmix+ Vep× PeVep× d
where exhaust gases are vented outside tunnel;

and:
PM=Vmix× PeVep× d
where exhaust gases are returned to the tunnel;

where:

Vmixis the volume of diluted exhaust gases (see paragraph 2. of this Sub-Annex), under standard conditions;Vepis the volume of diluted exhaust gas flowing through the particulate sampling filter under standard conditions;Peis the mass of particulate matter collected by one or more sample filters, mg;dis the distance driven corresponding to the test cycle, km.
 3.3.1.1. 
PM=PeVep−PaVap×1−1DF×Vmix+ Vepd

in the case that the exhaust gases are vented outside the tunnel;

and:

PM=PeVep−PaVap×1−1DF×Vmixd

in the case that the exhaust gases are returned to the tunnel;

where:

Vapis the volume of tunnel air flowing through the background particulate filter under standard conditions;Pais the particulate mass from the dilution air, or the dilution tunnel background air, as determined by the one of the methods described in paragraph 1.2.1.3.1. of Sub-Annex 6;DFis the dilution factor determined in paragraph 3.2.1.1.1. of this Sub-Annex.

Where application of a background correction results in a negative result, it shall be considered to be zero mg/km.
 3.3.2. Vep=Vset− Vssd
where:

Vepis the volume of diluted exhaust gas flowing through the particulate sample filter under standard conditions;Vsetis the volume of the double diluted exhaust gas passing through the particulate sampling filters under standard conditions;Vssdis the volume of the secondary dilution air under standard conditions.

Where the secondary diluted sample gas for PM measurement is not returned to the tunnel, the CVS volume shall be calculated as in single dilution, i.e.:
Vmix=Vmix indicated+ Vep
where:

Vmix indicatedis the measured volume of diluted exhaust gas in the dilution system following extraction of the particulate sample under standard conditions.

4.  4.1. 
PN=V× k×Cs–×fr–− Cb×frb–× 103d

where:

PNis the particle number emission, particles per kilometre;Vis the volume of the diluted exhaust gas in litres per test (after primary dilution only in the case of double dilution) and corrected to standard conditions (273,15 K (0 °C) and 101,325 kPa);kis a calibration factor to correct the PNC measurements to the level of the reference instrument where this is not applied internally within the PNC. Where the calibration factor is applied internally within the PNC, the calibration factor shall be 1;Cs–is the corrected particle number concentration from the diluted exhaust gas expressed as the arithmetic average number of particles per cubic centimetre from the emissions test including the full duration of the drive cycle. If the volumetric mean concentration results C– from the PNC are not measured at standard conditions (273,15 K (0 °C) and 101,325 kPa), the concentrations shall be corrected to those conditions Cs–;Cbis either the dilution air or the dilution tunnel background particle number concentration, as permitted by the approval authority, in particles per cubic centimetre, corrected for coincidence and to standard conditions (273,15 K (0 °C) and 101,325 kPa);fr–is the mean particle concentration reduction factor of the VPR at the dilution setting used for the test;frb–is the mean particle concentration reduction factor of the VPR at the dilution setting used for the background measurement;dis the distance driven corresponding to the applicable test cycle, km.

C– shall be calculated from the following equation:

C–=∑ni= 1Cin

where:

Ciis a discrete measurement of particle number concentration in the diluted gas exhaust from the PNC; particles per cm3 and corrected for coincidence;nis the total number of discrete particle number concentration measurements made during the applicable test cycle and shall be calculated using the following equation:

n=t× f

where:

tis the time duration of the applicable test cycle, s;fis the data logging frequency of the particle counter, Hz.

5. 
Unless otherwise specified, the calculation shall be based on the target speed trace given in discrete time sample points.

For the calculation, each time sample point shall be interpreted as a time period. Unless otherwise specified, the duration Δt of these periods shall be 1 second.

The total energy demand E for the whole cycle or a specific cycle phase shall be calculated by summing Ei over the corresponding cycle time between tstart and tend according to the following equation:

E=∑tstarttend Ei

where:

Ei=Fi× di if Fi> 0

Ei=0 if Fi≤ 0

and:

tstartis the time at which the applicable test cycle or phase starts, s;tendis the time at which the applicable test cycle or phase ends, s;Eiis the energy demand during time period (i-1) to (i), Ws;Fiis the driving force during time period (i-1) to (i), N;diis the distance travelled during time period (i-1) to (i), m.

Fi=f0+ f1×vi+ vi− 12+ f2×vi+ vi− 124+1.03× TM× ai

where:

Fiis the driving force during time period (i-1) to (i), N;viis the target speed at time ti, km/h;TMis the test mass, kg;aiis the acceleration during time period (i-1) to (i), m/s2;

f0, f1, f2 are the road load coefficients for the test vehicle under consideration (TML, TMH or TMind) in N, N/km/h and in N/(km/h)2 respectively.

di=vi+ vi− 12× 3,6×ti− ti− 1

where:

diis the distance travelled in time period (i-1) to (i), m;viis the target speed at time ti, km/h;tiis time, s.

ai=vi− vi− 13,6×ti− ti− 1

where:

aiis the acceleration during time period (i-1) to (i), m/s2;viis the target speed at time ti, km/h;tiis time, s.

6.  6.1. The fuel characteristics required for the calculation of fuel consumption values shall be taken from Annex IX.
 6.2. The fuel consumption values shall be calculated from the emissions of hydrocarbons, carbon monoxide, and carbon dioxide using the results of step 6 for criteria emissions and step 7 for CO2 of Table A7/1.
 6.2.1. The general equation in paragraph 6.12. using H/C and O/C ratios shall be used for the calculation of fuel consumption.
 6.2.2. For all equations in paragraph 6. of this Sub-Annex:
FCis the fuel consumption of a specific fuel, 1/100 km (or m3 per 100 km in the case of natural gas or kg/100 km in the case of hydrogen);H/Cis the hydrogen to carbon ratio of a specific fuel CXHYOZ;O/Cis the oxygen to carbon ratio of a specific fuel CXHYOZ;MWCis the molar mass of carbon (12,011 g/mol);MWHis the molar mass of hydrogen (1,008 g/mol);MWOis the molar mass of oxygen (15,999 g/mol);ρfuelis the test fuel density, kg/l. For gaseous fuels, fuel density at 15 °C;HCare the emissions of hydrocarbon, g/km;COare the emissions of carbon monoxide, g/km;CO2are the emissions of carbon dioxide, g/km;H2Oare the emissions of water, g/km;H2are the emissions of hydrogen, g/km;p1is the gas pressure in the fuel tank before the applicable test cycle, Pa;p2is the gas pressure in the fuel tank after the applicable test cycle, Pa;T1is the gas temperature in the fuel tank before the applicable test cycle, K;T2is the gas temperature in the fuel tank after the applicable test cycle, K;Z1is the compressibility factor of the gaseous fuel at p1 and T1;Z2is the compressibility factor of the gaseous fuel at p2 and T2;Vis the interior volume of the gaseous fuel tank, m3;dis the theoretical length of the applicable phase or cycle, km.
 6.3. Reserved
 6.4. Reserved
 6.5. FC=0,1206ρfuel×0,829× HC+0,429× CO+0,273× CO2 6.6. FCnorm=0,12120,538×0,825× HC+0,429× CO+0,273× CO2 6.6.1. If the composition of the fuel used for the test differs from the composition that is assumed for the calculation of the normalised consumption, on the manufacturer's request a correction factor cf may be applied, using the following equation:
FCnorm=0,12120,538× cf×0,825× HC+0,429× CO+0,273× CO2The correction factor, cf, which may be applied, is determined using the following equation:
cf=0,825+ 0,0693× nactualwhere:
nactual is the actual H/C ratio of the fuel used.
 6.7. FCnorm=0,13360,654×0,749× HC+0,429× CO+0,273× CO2 6.8.  6.9.  6.10. FC=0,1165ρfuel×0,858× HC+0,429× CO+0,273× CO2 6.11. FC=0,1743ρfuel×0,574× HC+0,429× CO+0,273× CO2 6.12. Fuel consumption for any test fuel may be calculated using the following equation:
FC=MWC+HC× MWH+OC× MWOMWC× ρfuel× 10×MWCMWC+HC× MWH+OC× MWO× HC+MWCMWCO× CO+MWCMWCO2× CO2 6.13. Fuel consumption for a vehicle with a positive ignition engine fuelled by hydrogen:
FC=0,024×Vd×1Z1×p1T1−1Z2×p2T2With approval of the approval authority and for vehicles fuelled either with gaseous or liquid hydrogen, the manufacturer may choose to calculate fuel consumption using either the equation for FC below or a method using a standard protocol such as SAE J2572.
FC=0,1×0,1119× H2O+ H2The compressibility factor, Z, shall be obtained from the following table:

  T (K)         
  5 100 200 300 400 500 600 700 800 900
p (bar) 33 0,859 1,051 1,885 2,648 3,365 4,051 4,712 5,352 5,973 6,576
 53 0,965 0,922 1,416 1,891 2,338 2,765 3,174 3,57 3,954 4,329
 73 0,989 0,991 1,278 1,604 1,923 2,229 2,525 2,810 3,088 3,358
 93 0,997 1,042 1,233 1,470 1,711 1,947 2,177 2,400 2,617 2,829
 113 1,000 1,066 1,213 1,395 1,586 1,776 1,963 2,146 2,324 2,498
 133 1,002 1,076 1,199 1,347 1,504 1,662 1,819 1,973 2,124 2,271
 153 1,003 1,079 1,187 1,312 1,445 1,580 1,715 1,848 1,979 2,107
 173 1,003 1,079 1,176 1,285 1,401 1,518 1,636 1,753 1,868 1,981
 193 1,003 1,077 1,165 1,263 1,365 1,469 1,574 1,678 1,781 1,882
 213 1,003 1,071 1,147 1,228 1,311 1,396 1,482 1,567 1,652 1,735
 233 1,004 1,071 1,148 1,228 1,312 1,397 1,482 1,568 1,652 1,736
 248 1,003 1,069 1,141 1,217 1,296 1,375 1,455 1,535 1,614 1,693
 263 1,003 1,066 1,136 1,207 1,281 1,356 1,431 1,506 1,581 1,655
 278 1,003 1,064 1,130 1,198 1,268 1,339 1,409 1,480 1,551 1,621
 293 1,003 1,062 1,125 1,190 1,256 1,323 1,390 1,457 1,524 1,590
 308 1,003 1,060 1,120 1,182 1,245 1,308 1,372 1,436 1,499 1,562
 323 1,003 1,057 1,116 1,175 1,235 1,295 1,356 1,417 1,477 1,537
 338 1,003 1,055 1,111 1,168 1,225 1,283 1,341 1,399 1,457 1,514
 353 1,003 1,054 1,107 1,162 1,217 1,272 1,327 1,383 1,438 1,493
In the case that the required input values for p and T are not indicated in the table, the compressibility factor shall be obtained by linear interpolation between the compressibility factors indicated in the table, choosing the ones that are the closest to the sought value.

7.  7.1. 
The prescribed speed between time points in Tables A1/1 to A1/12 shall be determined by a linear interpolation method at a frequency of 10 Hz.

In the case that the accelerator control is fully activated, the prescribed speed shall be used instead of the actual vehicle speed for drive trace index calculations during such periods of operation.
 7.2. 
The following indices shall be calculated according to SAE J2951(Revised JAN2014):

(a) EREnergy Rating(b) DRDistance Rating(c) EEREnergy Economy Rating(d) ASCRAbsolute Speed Change Rating(e) IWRInertial Work Rating(f) RMSSERoot Mean Squared Speed Error

Sub-Annex 8
1. 
In the case of testing NOVC-HEVs, OVC-HEVs and NOVC-FCHVs, Appendix 2 and Appendix 3 to this Sub-Annex shall replace Appendix 2 to Sub-Annex6.

Unless stated otherwise, all requirements in this Sub-Annex shall apply to vehicles with and without driver-selectable modes. Unless explicitly stated otherwise in this Sub-Annex, all of the requirements and procedures specified in Sub-Annex 6 shall continue to apply for NOVC-HEVs, OVC-HEVs, NOVC-FCHVs and PEVs.
 1.1. 
Parameters, units and accuracy of measurements shall be as shown in Table A8/1.


Parameter Units Accuracy Resolution
Electrical energy Wh ± 1 per cent 0,001 kWh
Electrical current A ± 0,3 per cent FSD or± 1 per cent of reading 0,1 A
Electric voltage V ± 0,3 per cent FSD or± 1 per cent of reading 0,1 V




 1.2. 
Parameters, units and accuracy of measurements shall be the same as those required for conventional combustion engine-powered vehicles.
 1.3. 
Units and their precision for the communication of the final results shall follow the indications given in Table A8/2. For the purpose of calculation in paragraph 4. of this Sub-Annex, the unrounded values shall apply.


Parameter Units Communication of final test result
PER(p), PERcity, AER(p), AERcity, EAER(p), EAERcity, RCDA, RCDC km Rounded to nearest whole number
FCCS(,p), FCCD, FCweighted for HEVs l/100 km Rounded to the first place of decimal
FCCS(,p) for FCHVs kg/100 km Rounded to the second place of decimal
MCO2,CS(,p), MCO2,CD, MCO2,weighted g/km Rounded to the nearest whole number
EC(p), ECcity, ECAC,CD, ECAC,weighted Wh/km Rounded to the nearest whole number
EAC kWh Rounded to the first place of decimal


 1.4. 
All OVC-HEVs, NOVC-HEVs, PEVs and NOVC-FCHVs shall be classified as Class 3 vehicles. The applicable test cycle for the Type 1 test procedure shall be determined according to paragraph 1.4.2. of this Sub-Annex based on the corresponding reference test cycle as described in paragraph 1.4.1. of this Sub-Annex.
 1.4.1.  1.4.1.1. The reference test cycle for Class 3 vehicles is specified in paragraph 3.3. of Sub-Annex 1.
 1.4.1.2. For PEVs, the downscaling procedure, according to paragraphs 8.2.3. and 8.3. of Sub-Annex 1, may be applied on the test cycles according to paragraph 3.3. of Sub-Annex 1 by replacing the rated power with peak power. In such a case, the downscaled cycle is the reference test cycle.
 1.4.2.  1.4.2.1. 
The reference test cycle according to paragraph 1.4.1. of this Sub-Annex shall be the applicable WLTP test cycle (WLTC) for the Type 1 test procedure.

In the case that paragraph 9. of Sub-Annex 1 is applied based on the reference test cycle as described in paragraph 1.4.1. of this Sub-Annex, this modified test cycle shall be the applicable WLTP test cycle (WLTC) for the Type 1 test procedure.
 1.4.2.2. 
The WLTP city test cycle (WLTCcity) for Class 3 vehicles is specified in paragraph 3.5. of Sub-Annex 1.
 1.5. 
The vehicles shall be driven according to the manufacturer’s instructions, as incorporated in the manufacturer's handbook of production vehicles, and as indicated by a technical gear shift instrument.

2.  2.1. 

((a)) Without prejudice to the requirements of paragraph 1.2.3.3. of Sub-Annex 6, the vehicles tested according to this Sub-Annex shall have been run-in at least 300 km with those REESSs installed;
((b)) In the case that the REESSs are operated above the normal operating temperature range, the operator shall follow the procedure recommended by the vehicle manufacturer in order to keep the temperature of the REESS in its normal operating range. The manufacturer shall provide evidence that the thermal management system of the REESS is neither disabled nor reduced.
 2.2. For NOVC-FCHVs without prejudice to the requirements of paragraph 1.2.3.3. of Sub-Annex 6, the vehicles tested to this Sub-Annex shall have been run-in at least 300 km with their fuel cell system installed.

3.  3.1.  3.1.1. 

3.1.1.1. Vehicles shall be tested according to the applicable test cycles described in paragraph 1.4.2. of this Sub-Annex.
3.1.1.2. If the vehicle cannot follow the applicable test cycle within the speed trace tolerances according to paragraph 1.2.6.6. of Sub-Annex 6, the accelerator control shall, unless stated otherwise, be fully activated until the required speed trace is reached again.
3.1.1.3. The powertrain start procedure shall be initiated by means of the devices provided for this purpose according to the manufacturer's instructions.
3.1.1.4. For OVC-HEVs, NOVC-HEVs and PEVs, exhaust emissions sampling and measurement of electric energy consumption shall begin for each applicable test cycle before or at the initiation of the vehicle start procedure and end at the conclusion of each applicable test cycle.
3.1.1.5. For OVC-HEVs and NOVC-HEVs, gaseous emission compounds, shall be analysed for each individual test phase It is permitted to omit the phase analysis for phases where no combustion engine operates.
3.1.1.6. Particle number shall be analysed for each individual phase and particulate matter emission shall be analysed for each applicable test cycle.
 3.1.2. Forced cooling as described in paragraph 1.2.7.2. of Sub-Annex 6 shall apply only for the charge-sustaining Type 1 test for OVC-HEVs according to paragraph 3.2. of this Sub-Annex and for testing NOVC-HEVs according to paragraph 3.3. of this Sub-Annex.
 3.2.  3.2.1. Vehicles shall be tested under charge-depleting operating condition (CD condition), and charge-sustaining operating condition (CS condition).
 3.2.2. Vehicles may be tested according to four possible test sequences:

3.2.2.1. Option 1: charge-depleting Type 1 test with no subsequent charge-sustaining Type 1 test.
3.2.2.2. Option 2: charge-sustaining Type 1 test with no subsequent charge-depleting Type 1 test.
3.2.2.3. Option 3: charge-depleting Type 1 test with a subsequent charge-sustaining Type 1 test.
3.2.2.4. Option 4: charge-sustaining Type 1 test with a subsequent charge-depleting Type 1 test.

Figure A8/1 3.2.3. The driver-selectable mode shall be set as described in the following test sequences (Option 1 to Option 4).
 3.2.4. 
The test sequence according to Option 1, described in paragraphs 3.2.4.1. to 3.2.4.7. inclusive of this Sub-Annex, as well as the corresponding REESS state of charge profile, are shown in Figure A8.App1/1 in Appendix 1 to this Sub-Annex.
 3.2.4.1. 
The vehicle shall be prepared according to the procedures in paragraph 2.2. of Appendix 4 to this Sub-Annex.
 3.2.4.2.  3.2.4.2.1. The test shall be carried out with a fully charged REESS according to the charging requirements as described in paragraph 2.2.3. of Appendix 4 to this Sub-Annex and with the vehicle operated in charge-depleting operating condition as defined in paragraph 3.3.5. of this Annex.
 3.2.4.2.2. 
For vehicles equipped with a driver-selectable mode, the mode for the charge-depleting Type 1 test shall be selected according to paragraph 2. of Appendix 6 to this Sub-Annex.
 3.2.4.3.  3.2.4.3.1. The charge-depleting Type 1 test procedure shall consist of a number of consecutive cycles, each followed by a soak period of no more than 30 minutes until charge-sustaining operating condition is achieved.
 3.2.4.3.2. 
Restarting after soak, the vehicle shall be operated in the driver-selectable mode according to paragraph 3.2.4.2.2. of this Sub-Annex.
 3.2.4.3.3. In deviation from paragraph 5.3.1. of Sub-Annex 5 and without prejudice to paragraph 5.3.1.2. of Sub-Annex 5, analysers may be calibrated and zero- checked before and after the charge-depleting Type 1 test.
 3.2.4.4. 
The end of the charge-depleting Type 1 test is considered to have been reached when the break-off criterion according to paragraph 3.2.4.5. of this Sub-Annex is reached for the first time. The number of applicable WLTP test cycles up to and including the one where the break-off criterion was reached for the first time is set to n+1.

The applicable WLTP test cycle n is defined as the transition cycle.

The applicable WLTP test cycle n+1 is defined to be the confirmation cycle.

For vehicles without a charge-sustaining capability over the complete applicable WLTP test cycle, the end of the charge-depleting Type 1 test is reached by an indication on a standard on-board instrument panel to stop the vehicle, or when the vehicle deviates from the prescribed driving tolerance for 4 consecutive seconds or more. The accelerator control shall be deactivated and the vehicle shall be braked to standstill within 60 seconds.
 3.2.4.5.  3.2.4.5.1. Whether the break-off criterion has been reached for each driven applicable WLTP test cycle shall be evaluated.
 3.2.4.5.2. 
REECi=ΔEREESS,iEcycle×13600

where:

REECiis the relative electric energy change of the applicable test cycle considered i of the charge-depleting Type 1 test;ΔEREESS,iis the change of electric energy of all REESSs for the considered charge-depleting Type 1 test cycle i calculated according to paragraph 4.3. of this Sub-Annex, Wh;Ecycleis the cycle energy demand of the considered applicable WLTP test cycle calculated according to paragraph 5. of Sub-Annex 7, Ws;iis the index number for the considered applicable WLTP test cycle;13600is a conversion factor to Wh for the cycle energy demand.
 3.2.4.6.  3.2.4.6.1. 
The REESS is fully charged when the end-of-charge criterion, as defined in paragraph 2.2.3.2. of Appendix 4 to this Sub-Annex, is reached.
 3.2.4.6.2. The electric energy measurement equipment, placed between the vehicle charger and the mains, shall measure the recharged electric energy EAC delivered from the mains, as well as its duration. Electric energy measurement may be stopped when the end-of-charge criterion, as defined in paragraph 2.2.3.2. of Appendix 4 to this Sub-Annex, is reached.
 3.2.4.7. Each individual applicable WLTP test cycle within the charge-depleting Type 1 test shall fulfil the applicable criteria emission limits according to paragraph 1.1.2. of Sub-Annex 6.
 3.2.5. 
The test sequence according to Option 2, as described in paragraphs 3.2.5.1. to 3.2.5.3.3. inclusive of this Sub-Annex, as well as the corresponding REESS state of charge profile, are shown in Figure A8.App1/2 in Appendix 1 to this Sub-Annex.
 3.2.5.1. 
The vehicle shall be prepared according to the procedures in paragraph 2.1. of Appendix 4 to this Sub-Annex.
 3.2.5.2.  3.2.5.2.1. Tests shall be carried out with the vehicle operated in charge-sustaining operating condition as defined in paragraph 3.3.6.of this Annex.
 3.2.5.2.2. 
For vehicles equipped with a driver-selectable mode, the mode for the charge-sustaining Type 1 test shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.2.5.3.  3.2.5.3.1. Vehicles shall be tested according to the Type 1 test procedures described in Sub-Annex 6.
 3.2.5.3.2. If required, CO2 mass emission shall be corrected according to Appendix 2 to this Sub-Annex.
 3.2.5.3.3. The test according to paragraph 3.2.5.3.1. of this Sub-Annex shall fulfil the applicable criteria emission limits according to paragraph 1.1.2. of Sub-Annex 6.
 3.2.6. 
The test sequence according to Option 3, as described in paragraphs 3.2.6.1. to 3.2.6.3. inclusive of this Sub-Annex, as well as the corresponding REESS state of charge profile, are shown in Figure A8.App1/3 in Appendix 1 to this Sub-Annex.
 3.2.6.1. For the charge-depleting Type 1 test, the procedure described in paragraphs 3.2.4.1. to 3.2.4.5. inclusive as well as paragraph 3.2.4.7. of this Sub-Annex shall be followed.
 3.2.6.2. Subsequently, the procedure for the charge-sustaining Type 1 test described in paragraphs 3.2.5.1. to 3.2.5.3. inclusive of this Sub-Annex shall be followed. Paragraphs 2.1.1. to 2.1.2. inclusive of Appendix 4to this Sub-Annex shall not apply.
 3.2.6.3.  3.2.6.3.1. 
The REESS is fully charged when the end-of-charge criterion as defined in paragraph 2.2.3.2. of Appendix 4 to this Sub-Annex is reached.
 3.2.6.3.2. The energy measurement equipment, placed between the vehicle charger and the mains, shall measure the recharged electric energy EAC delivered from the mains, as well as its duration. Electric energy measurement may be stopped when the end-of-charge criterion as defined in paragraph 2.2.3.2. of Appendix 4 to this Sub-Annex is reached.
 3.2.7. 
The test sequence according to Option 4, described in paragraphs 3.2.7.1. to 3.2.7.2. inclusive of this Sub-Annex, as well as the corresponding REESS state of charge profile, are shown in Figure A8.App1/4 of Appendix 1 to this Sub-Annex.
 3.2.7.1. For the charge-sustaining Type 1 test, the procedure described in paragraphs 3.2.5.1. to 3.2.5.3. inclusive of this Sub-Annex, as well as paragraph 3.2.6.3.1. of this Sub-Annex shall be followed.
 3.2.7.2. Subsequently, the procedure for the charge-depleting Type 1 test described in paragraphs 3.2.4.2. to 3.2.4.7. inclusive of this Sub-Annex shall be followed.
 3.3. 
The test sequence described in paragraphs 3.3.1. to 3.3.3. inclusive of this Sub-Annex, as well as the corresponding REESS state of charge profile, are shown in Figure A8.App1/5 of Appendix 1 to this Sub-Annex.
 3.3.1.  3.3.1.1. 
In addition to the requirements of paragraph 1.2.6., the level of the state of charge of the traction REESS for the charge-sustaining test may be set according to the manufacturer’s recommendation before preconditioning in order to achieve a test under charge-sustaining operating condition.
 3.3.1.2. Vehicles shall be soaked according to paragraph 1.2.7. of Sub-Annex 6.
 3.3.2.  3.3.2.1. Vehicles shall be tested under charge-sustaining operating condition as defined in paragraph 3.3.6. of this Annex.
 3.3.2.2. 
For vehicles equipped with a driver-selectable mode, the mode for the charge-sustaining Type 1 test shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.3.3.  3.3.3.1. Vehicles shall be tested according to the Type 1 test procedure described in Sub-Annex 6.
 3.3.3.2. If required, the CO2 mass emission shall be corrected according to Appendix 2 to this Sub-Annex.
 3.3.3.3. The charge-sustaining Type 1 test shall fulfil the applicable exhaust emission limits according to paragraph 1.1.2. of Sub-Annex 6.
 3.4.  3.4.1. 
The test procedure to determine the pure electric range and electric energy consumption shall be selected according to the estimated pure electric range (PER) of the test vehicle from Table A8/3. In the case that the interpolation approach is applied, the applicable test procedure shall be selected according to the PER of vehicle H within the specific interpolation family.


Applicable test cycle The estimated PER is… Applicable test procedure
Test cycle according to paragraph 1.4.2.1. including the Extra High phase …less than the length of 3 applicable WLTP test cycles. Consecutive cycle Type 1 test procedure (according to paragraph 3.4.4.1. of this Sub-Annex)
…is equal to or greater than the length of 3 applicable WLTP test cycles. Shortened Type 1 test procedure (according to paragraph 3.4.4.2. of this Sub-Annex)
Test cycle according to paragraph 1.4.2.1. excluding the Extra High phase …is less than the length of 4 applicable WLTP test cycles. Consecutive cycle Type 1 test procedure (according to paragraph 3.4.4.1. of this Sub-Annex)
…is equal to or greater than the length of 4 applicable WLTP test cycles. Shortened Type 1 test procedure (according to paragraph 3.4.4.2. of this Sub-Annex)
City cycle according to paragraph 1.4.2.2. …not available over the applicable WLTP test cycle. Consecutive cycle Type 1 test procedure (according to paragraph 3.4.4.1. of this Sub-Annex)

The manufacturer shall give evidence to the approval authority concerning the estimated pure electric range (PER) prior to the test. In the case that the interpolation approach is applied, the applicable test procedure shall be determined based on the estimated PER of vehicle H of the interpolation family. The PER determined by the applied test procedure shall confirm that the correct test procedure was applied.

The test sequence for the consecutive cycle Type 1 test procedure, as described in paragraphs 3.4.2., 3.4.3. and 3.4.4.1. of this Sub-Annex, as well as the corresponding REESS state of charge profile, are shown in Figure A8.App1/6 of Appendix 1 to this Sub-Annex.

The test sequence for the shortened Type 1 test procedure, as described in paragraphs 3.4.2., 3.4.3. and 3.4.4.2., as well as the corresponding REESS state of charge profile are shown in Figure A8.App1/7 in Appendix 1 to this Sub-Annex.
 3.4.2. 
The vehicle shall be prepared according to the procedures in paragraph 3. of Appendix 4 to this Sub-Annex.
 3.4.3. 
For vehicles equipped with a driver-selectable mode, the mode for the test shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.4.4.  3.4.4.1.  3.4.4.1.1. 
The test shall be performed by driving consecutive applicable test cycles until the break-off criterion according to paragraph 3.4.4.1.3. of this Sub-Annex is reached.

Breaks for the driver and/or operator are permitted only between test cycles and with a maximum total break time defined in Table A8/4. During the break, the powertrain shall be switched off.
 3.4.4.1.2. 
From the beginning of the test until the break-off criterion is reached, the electric current of all REESSs shall be measured according to Appendix 3 to this Sub-Annex and the electric voltage shall be determined according to Appendix 3 to this Sub-Annex.
 3.4.4.1.3. 
The break-off criterion is reached when the vehicle exceeds the prescribed speed trace tolerance as specified in paragraph 1.2.6.6. of Sub-Annex 6 for 4 consecutive seconds or more. The accelerator control shall be deactivated. The vehicle shall be braked to standstill within 60 seconds.
 3.4.4.2.  3.4.4.2.1. 
The shortened Type 1 test procedure consists of two dynamic segments (DS1 and DS2) combined with two constant speed segments (CSSM and CSSE) as shown in Figure A8/2.

Figure A8/2
The dynamic segments DS1 and DS2 are used to determine the energy consumption for the applicable WLTP test cycle.

The constant speed segments CSSM and CSSE are intended to reduce test duration by depleting the REESS more rapidly than the consecutive cycle Type 1 test procedure.
 3.4.4.2.1.1. 
Each dynamic segment DS1 and DS2 consists of an applicable WLTP test cycle according to paragraph 1.4.2.1. followed by an applicable WLTP city test cycle according to paragraph 1.4.2.2.
 3.4.4.2.1.2. 
The constant speeds during segments CSSM and CSSE shall be identical. If the interpolation approach is applied, the same constant speed shall be applied within the interpolation family.
 (a) 
The minimum speed of the constant speed segments shall be 100 km/h. At the request of manufacturer and with approval of the approval authority, a higher constant speed in the constant speed segments may be selected.

The acceleration to the constant speed level shall be smooth and accomplished within 1 minute after completion of the dynamic segments and, in the case of a break according to Table A8/4, after initiating the powertrain start procedure.

If the maximum speed of the vehicle is lower than the required minimum speed for the constant speed segments according to the speed specification of this paragraph, the required speed in the constant speed segments shall be equal to the maximum speed of the vehicle.
 (b) 
The length of the constant speed segment CSSE shall be determined based on the percentage of the usable REESS energy UBESTP according to paragraph 4.4.2.1. of this Sub-Annex. The remaining energy in the traction REESS after dynamic speed segment DS2 shall be equal to or less than 10 per cent of UBESTP. The manufacturer shall provide evidence to the approval authority after the test that this requirement is fulfilled.

The length of the constant speed segment CSSM may be calculated using the following equation:

dCSSM=PERest− dDS1− dDS2− dCSSE

where:

PERestis the estimated pure electric range of the considered PEV, km;dDS1is the length of dynamic speed segment 1, km;dDS2is the length of dynamic speed segment 2, km;dCSSEis the length of constant speed segment CSSE, km.
 3.4.4.2.1.3. 
Breaks for the driver and/or operator are permitted only in the constant speed segments as prescribed in Table A8/4.


Distance driven (km) Maximum total break (min)
Up to 100 10
Up to 150 20
Up to 200 30
Up to 300 60
More than 300 Shall be based on the manufacturer’s recommendation
Note: During a break, the powertrain shall be switched off.
 3.4.4.2.2. 
From the beginning of the test until the break-off criterion is reached, the electric current of all REESSs and the electric voltage of all REESSs shall be determined according to Appendix 3 to this Sub-Annex.
 3.4.4.2.3. 
The break-off criterion is reached when the vehicle exceeds the prescribed driving tolerance as specified in paragraph 1.2.6.6. of Sub-Annex 6 for 4 consecutive seconds or more in the second constant speed segment CSSE. The accelerator control shall be deactivated. The vehicle shall be braked to a standstill within 60 seconds.
 3.4.4.3.  3.4.4.3.1. 
The REESS is fully charged when the end-of-charge criterion, as defined in paragraph 2.2.3.2. of Appendix 4 to this Sub-Annex, is reached.
 3.4.4.3.2. The energy measurement equipment, placed between the vehicle charger and the mains, shall measure the recharged electric energy EAC delivered from the mains as well as its duration. Electric energy measurement may be stopped when the end-of-charge criterion, as defined in paragraph 2.2.3.2. of Appendix 4 to this Sub-Annex, is reached.
 3.5. 
The test sequence, described in paragraphs 3.5.1. to 3.5.3. inclusive of this Sub-Annex, as well as the corresponding REESS state of charge profile, is shown in Figure A8.App1/5 in Appendix 1 to this Sub-Annex.
 3.5.1. 
Vehicles shall be conditioned and soaked according to paragraph 3.3.1. of this Sub-Annex.
 3.5.2.  3.5.2.1. Vehicles shall be tested under charge-sustaining operating conditions as defined in paragraph 3.3.6. of this Annex.
 3.5.2.2. 
For vehicles equipped with a driver-selectable mode, the mode for the charge-sustaining Type 1 test shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.5.3.  3.5.3.1. Vehicles shall be tested according to the Type 1 test procedure described in Sub-Annex 6 and fuel consumption calculated according to Appendix 7 to this Sub-Annex.
 3.5.3.2. If required, fuel consumption shall be corrected according to Appendix 2 to this Sub-Annex.

4.  4.1.  4.1.1. 
The charge-sustaining particulate matter emission PMCS shall be calculated according to paragraph 3.3. of Sub-Annex 7.

The charge-sustaining particle number emission PNCS shall be calculated according to paragraph 4. of Sub-Annex 7.
 4.1.1.1. 
The results shall be calculated in the order described in Table A8/5. All applicable results in the column ‘Output’ shall be recorded. The column ‘Process’ describes the paragraphs to be used for calculation or contains additional calculations.

For the purpose of this table, the following nomenclature within the equations and results is used:

ccomplete applicable test cycle;pevery applicable cycle phase;iapplicable criteria emission component (except CO2);CScharge-sustainingCO2CO2 mass emission.


Table A8/5
Calculation of final charge-sustaining gaseous emission values
Source Input Process Output Step no.
Sub-Annex 6 Raw test results Charge-sustaining mass emissionsSub-Annex 7, paragraphs 3. to 3.2.2. inclusive Mi,CS,p,1, g/km;MCO2,CS,p,1, g/km. 1
Output from step no. 1 of this Table. Mi,CS,p,1, g/km;MCO2,CS,p,1, g/km. Calculation of combined charge-sustaining cycle values:Mi,CS,c,2=∑pMi,CS,p,1× dp∑pdpMCO2,CS,c,2=∑pMCO2,CS,p,1∑pdpwhere:Mi,CS,c,2 is the charge-sustaining mass emission result over the total cycle;MCO2,CS,c,2 is the charge-sustaining CO2 mass emission result over the total cycle;dp are the driven distances of the cycle phases p. Mi,CS,c,2, g/km;MCO2,CS,c,2, g/km. 2
Output from step no. 1 and 2 of this Table. MCO2,CS,p,1, g/km;MCO2,CS,c,2, g/km. REESS electric energy change correctionSub-Annex 8, paragraph 4.1.1.2. to 4.1.1.5. inclusive MCO2,CS,p,3, g/km;MCO2,CS,c,3, g/km. 3
Output from step no. 2 and 3 of this Table. Mi,CS,c,2, g/kmMCO2,CS,c,3, g/km. Charge-sustaining mass emission correction for all vehicles equipped with periodically regenerating systems Ki according to Sub-Annex 6, Appendix 1.Mi,CS,c,4=Ki× Mi,CS,c,2orMi,CS,c,4=Ki+ Mi,CS,c,2andMCO2,CS,c,4=KCO2,Ki× MCO2,CS,c,3orMCO2,CS,c,4=KCO2,Ki+ MCO2,CS,c,3Additive offset or multiplicative factor to be used according to Ki determination.If Ki is not applicable:Mi,CS,c,4=Mi,CS,c,2MCO2,CS,c,4=MCO2,CS,c,3 Mi,CS,c,4, g/km.MCO2,CS,c,4, g/km. 4a
Output from step no. 3 and 4a of this Table. MCO2,CS,p,3, g/km;MCO2,CS,c,3, g/km;MCO2,CS,c,4, g/km. If Ki is applicable, align CO2 phase values to combined cycle value:MCO2,CS,p,4=MCO2,CS,p,3× AFKifor every cycle phase p;where:AFKi=MCO2,c,4MCO2,c,3If Ki is not applicable:MCO2,CS,p,4=MCO2,CS,p,3 MCO2,CS,p,4, g/km. 4b
Output from step no. 4 of this Table. Mi,CS,c,4, g/km;MCO2,CS,p,4, g/km;MCO2,CS,c,4, g/km; ATCT correction according to paragraph 3.8.2. of Sub-Annex 6a.Deterioration factors calculated and applied according to Annex VII Mi,CS,c,5, g/km;MCO2,CS,c,5, g/km;MCO2,CS,p,5, g/km. 5‘result of a single test’
Output from step no. 5 of this Table. For every test:Mi,CS,c,5, g/km;MCO2,CS,c,5, g/km;MCO2,CS,p,5, g/km Averaging of tests and declared value according to paragraph 1.1.2. to 1.1.2.3. inclusive of Sub-Annex 6. Mi,CS,c,6, g/km;MCO2,CS,c,6, g/km;MCO2,CS,p,6, g/km;MCO2,CS,c,declared, g/km. 6‘MiCS results of a Type 1 test for a test vehicle’
Output from step no. 6 of this Table. MCO2,CS,c,6, g/km;MCO2,CS,p,6, g/km;MCO2,CS,c,declared, g/km. Alignment of phase values.Sub-Annex 6, paragraph 1.1.2.4.And:MCO2,CS,c,7=MCO2,CS,c,declared MCO2,CS,c,7, g/km;MCO2,CS,p,7, g/km; 7‘MCO2,CS results of a Type 1 test for a test vehicle’
Output from step no. 6 and 7 of this Table. For each of the test vehicles H and L:Mi,CS,c,6, g/km;MCO2,CS,c,7, g/km;MCO2,CS,p,7, g/km; If in addition to a test vehicle H a test vehicle L was also tested, the resulting criteria emission value shall be the highest of the two values and referred to as Mi,CS,cIn the case of the combined THC+NOx emissions, the highest value of the sum referring to either the VH or VL is to be used.Otherwise, if no vehicle L was tested, Mi,CS,c=Mi,CS,c,6For CO2 the values derived in step 7 of this Table shall be used.CO2 values shall be rounded to two decimal places. Mi,CS,c, g/km;MCO2,CS,c,H, g/km;MCO2,CS,p,H, g/km;and if a vehicle L was tested:MCO2,CS,c,L, g/km;MCO2,CS,p,L, g/km; 8‘inter-polation family result’final criteria emission result
Output from step no. 8 of this Table. MCO2,CS,c,H, g/km;MCO2,CS,p,H, g/km;and if a vehicle L was tested:MCO2,CS,c,L, g/km;MCO2,CS,p,L, g/km; CO2 mass emission calculation according to paragraph 4.5.4.1. of this Sub-Annex for individual vehicles in an interpolation family.CO2 values shall be rounded according to Table A8/2. MCO2,CS,c,ind, g/km;MCO2,CS,p,ind, g/km; 9‘result of an individual vehicle’final CO2 result 4.1.1.2. 
MCO2,CS=MCO2,CS,nb

where:

MCO2,CSis the charge-sustaining CO2 mass emission of the charge-sustaining Type 1 test according to Table A8/5, step no. 3, g/km;MCO2,CS,nbis the non-balanced charge-sustaining CO2 mass emission of the charge-sustaining Type 1 test, not corrected for the energy balance, determined according to Table A8/5, step no. 2, g/km.
 4.1.1.3. 
MCO2,CS=MCO2,CS,nb− KCO2× ECDC,CS

where:

MCO2,CSis the charge-sustaining CO2 mass emission of the charge-sustaining Type 1 test according to Table A8/5, step no. 2, g/km;MCO2,CS,nbis the non-balanced CO2 mass emission of the charge-sustaining Type 1 test, not corrected for the energy balance, determined according to Table A8/5, step no. 2, g/km;ECDC,CSis the electric energy consumption of the charge-sustaining Type 1 test according to paragraph 4.3. of this Sub-Annex, Wh/km;KCO2is the CO2 mass emission correction coefficient according to paragraph 2.3.2. of Appendix 2 to this Sub-Annex, (g/km)/(Wh/km).
 4.1.1.4. 
MCO2,CS,p=MCO2,CS,nb,p− KCO2× ECDC,CS,p

where:

MCO2,CS,pis the charge-sustaining CO2 mass emission of phase p of the charge-sustaining Type 1 test according to Table A8/5, step no. 2, g/km;MCO2,CS,nb,pis the non-balanced CO2 mass emission of phase p of the charge-sustaining Type 1 test, not corrected for the energy balance, determined according to Table A8/5, step no. 2, g/km;ECDC,CS,pis the electric energy consumption of phase p of the charge-sustaining Type 1 test according to paragraph 4.3. of this Sub-Annex, Wh/km;KCO2is the CO2 mass emission correction coefficient according to paragraph 2.3.2. of Appendix 2 to this Sub-Annex, (g/km)/(Wh/km).
 4.1.1.5. 
MCO2,CS,p=MCO2,CS,nb,p− KCO2,p× ECDC,CS,p

where:

MCO2,CS,pis the charge-sustaining CO2 mass emission of phase p of the charge-sustaining Type 1 test according to Table A8/5, step no. 3, g/km;MCO2,CS,nb,pis the non-balanced CO2 mass emission of phase p of the charge-sustaining Type 1 test, not corrected for the energy balance, determined according to Table A8/5, step no. 2, g/km;ECDC,CS,pis the electric energy consumption of phase p of the charge-sustaining Type 1 test, determined according to paragraph 4.3. of this Sub-Annex, Wh/km;KCO2,pis the CO2 mass emission correction coefficient according to paragraph 2.3.2.2. of Appendix 2 to this Sub-Annex, (g/km)/(Wh/km);pis the index of the individual phase within the applicable WLTP test cycle.
 4.1.2. 
The utility factor-weighted charge-depleting CO2 mass emission MCO2,CD shall be calculated using the following equation:
MCO2,CD=∑kj= 1UFj× MCO2,CD,j∑kj= 1UFj
where:

MCO2,CDis the utility factor-weighted charge-depleting CO2 mass emission, g/km;MCO2,CD,jis the CO2 mass emission determined according to paragraph 3.2.1. of Sub-Annex 7 of phase j of the charge-depleting Type 1 test, g/km;UFjis the utility factor of phase j according to Appendix 5 of this Sub-Annex;jis the index number of the phase considered;kis the number of phases driven up to the end of the transition cycle according to paragraph 3.2.4.4. of this Sub-Annex.

In the case that the interpolation approach is applied, k shall be the number of phases driven up to the end of the transition cycle of vehicle L nveh_L.

If the transition cycle number driven by vehicle H, nvehH, and, if applicable, an individual vehicle within the vehicle interpolation family, nvehind, is lower than the transition cycle number driven by vehicle L, nveh_L, the confirmation cycle of vehicle H and, if applicable, an individual vehicle shall be included in the calculation. The CO2 mass emission of each phase of the confirmation cycle shall then be corrected to an electric energy consumption of zero ECDC,CD,j = 0 by using the CO2 correction coefficient according to Appendix 2 of this Sub-Annex.
 4.1.3. Utility factor-weighted mass emissions of gaseous compounds, particulate matter emission and particle number emission for OVC-HEVs.
 4.1.3.1. 
Mi,weighted=∑j= 1kUFj× Mi,CD,j+1−∑j= 1kUFj× Mi,CS

where:

Mi,weightedis the utility factor-weighted mass emission compound i, g/km;iis the index of the considered gaseous emission compound;UFjis the utility factor of phase j according to Appendix 5 of this Sub-Annex;Mi,CD,jis the mass emission of the gaseous emission compound i determined according to paragraph 3.2.1. of Sub-Annex 7 of phase j of the charge-depleting Type 1 test, g/km;Mi,CSis the charge-sustaining mass emission of gaseous emission compound i for the charge-sustaining Type 1 test according to Table A8/5, step no. 7, g/km;jis the index number of the phase considered;kis the number of phases driven until the end of the transition cycle according to paragraph 3.2.4.4. of this Sub-Annex.

In the case that the interpolation approach is applied, k shall be the number of phases driven up to the end of the transition cycle of vehicle L nveh_L.

If the transition cycle number driven by vehicle H, nvehH, and, if applicable, an individual vehicle within the vehicle interpolation family, nvehind, is lower than the transition cycle number driven by vehicle L, nveh_L, the confirmation cycle of vehicle H and, if applicable, an individual vehicle shall be included in the calculation. The CO2 mass emission of each phase of the confirmation cycle shall then be corrected to an electric energy consumption of zero ECDC,CD,j=0 by using the CO2 correction coefficient according to Appendix 2 of this Sub-Annex.
 4.1.3.2. 
PNweighted=∑j= 1kUFj× PNCD,j+1−∑j= 1kUFj× PNCS

where:

PNweightedis the utility factor-weighted particle number emission, particles per kilometre;UFjis the utility factor of phase j according to Appendix 5 of this Sub-Annex;PNCD,jis the particle number emission during phase j determined according to paragraph 4. of Sub-Annex 7 for the charge-depleting Type 1 test, particles per kilometre;PNCSis the particle number emission determined according to paragraph 4.1.1. of this Sub-Annex for the charge-sustaining Type 1 test, particles per kilometre;jis the index number of the phase considered;kis the number of phases driven until the end of transition cycle n according to paragraph 3.2.4.4. of this Sub-Annex.
 4.1.3.3. 
PMweighted=∑c= 1ncUFc× PMCD,c+1−∑c= 1ncUFc× PMCS

where:

PMweightedis the utility factor-weighted particulate matter emission, mg/km;UFcis the utility factor of cycle c according to Appendix 5 of this Sub-Annex;PMCD,cis the charge-depleting particulate matter emission during cycle c determined according to paragraph 3.3. of Sub-Annex 7 for the charge-depleting Type 1 test, mg/km;PMCSis the particulate matter emission of the charge-sustaining Type 1 test according to paragraph 4.1.1. of this Sub-Annex, mg/km;cis the index number of the cycle considered;ncis the number of applicable WLTP test cycles driven until the end of the transition cycle n according to paragraph 3.2.4.4. of this Sub-Annex.
 4.2.  4.2.1.  4.2.1.1. 

Source Input Process Output Step no.
Output from step no. 6 and 7 of Table A8/5 of this Sub-Annex. Mi,CS,c,6, g/km;MCO2,CS,c,7, g/km;MCO2,CS,p,7, g/km; Calculation of fuel consumption according to paragraph 6. of Sub-Annex 7.The calculation of fuel consumption shall be performed separately for the applicable cycle and its phases.For that purpose:
((a)) the applicable phase or cycle CO2 values shall be used;
((b)) the criteria emission over the complete cycle shall be used. FCCS,c,1, l/100 km;FCCS,p,1, l/100 km; 1‘FCCS results of a Type 1 test for a test vehicle’
Step no. 1 of this Table. For each of the test vehicles H and L:FCCS,c,1, l/100 km;FCCS,p,1, l/100 km; For FC the values derived in step no. 1 of this Table shall be used.FC values shall be rounded to three decimal places. FCCS,c,H, l/100 km;FCCS,p,H, l/100 km;and if a vehicle L was tested:FCCS,c,L, l/100 km;FCCS,p,L, l/100 km; 2‘interpolation family result’final criteria emission result
Step no. 2 of this Table. FCCS,c,H, l/100 km;FCCS,p,H, l/100 km;and if a vehicle L was tested:FCCS,c,L, l/100 km;FCCS,p,L, l/100 km; Fuel consumption calculation according to paragraph 4.5.5.1. of this Sub-Annex for individual vehicles in an interpolation family.FC values shall be rounded according to Table A8/2. FCCS,c,ind, l/100 km;FCCS,p,ind, l/100 km; 3‘result of an individual vehicle’final FC result
 4.2.1.2.  4.2.1.2.1. 
The results shall be calculated in the order described in the Tables A8/7. All applicable results in the column ‘Output’ shall be recorded. The column ‘Process’ describes the paragraphs to be used for calculation or contains additional calculations.

For the purpose of this table, the following nomenclature within the equations and results is used:

ccomplete applicable test cycle;pevery applicable cycle phase;CScharge-sustaining


Source Input Process Output Step no.
Appendix 7 of this Sub-Annex. Non-balanced charge-sustaining fuel consumptionFCCS,nb,kg/100 km Charge-sustaining fuel consumption according to paragraph 2.2.6. of Appendix 7. to this Sub-Annex FCCS,c,1, kg/100 km; 1
Output from step no. 1 of this Table. FCCS,c,1, kg/100 km; REESS electric energy change correctionSub-Annex 8, paragraphs 4.2.1.2.2. to 4.2.1.2.3. inclusive of this Sub-Annex FCCS,c,2, kg/100 km; 2
Output from step no. 2 of this Table. FCCS,c,2, kg/100 km; ATCT correction according to paragraph 3.8.2. of Sub-Annex 6a.Deterioration factors calculated according to Annex VII. FCCS,c,3, kg/100 km; 3‘result of a single test’
Output from step no. 3 of this Table. For every test:FCCS,c,3, kg/100 km; Averaging of tests and declared value according to paragraphs 1.1.2. to 1.1.2.3. inclusive of Sub-Annex 6. FCCS,c,4, kg/100 km; 4
Output from step no. 4 of this Table. FCCS,c,4, kg/100 km;FCCS,c,declared, kg/100 km Alignment of phase values.Sub-Annex 6, paragraph 1.1.2.4.And:FCCS,c5=FCCS,c,declared FCCS,c,5, kg/100 km; 5‘FCCSresults of a Type 1 test for a test vehicle’
 4.2.1.2.2. In the case that the correction according to paragraph 1.1.4. of Appendix 2 to this Sub-Annex was not applied, the following charge-sustaining fuel consumption shall be used:
FCCS=FCCS,nbwhere:
FCCSis the charge-sustaining fuel consumption of the charge-sustaining Type 1 test according to Table A8/7, step no. 2, kg/100 km;FCCS,nbis the non-balanced charge-sustaining fuel consumption of the charge-sustaining Type 1 test, not corrected for the energy balance, according to Table A8/7, step no. 1, kg/100 km.
 4.2.1.2.3. If the correction of the fuel consumption is required according to paragraph 1.1.3. of Appendix 2 to this Sub-Annex or in the case that the correction according to paragraph 1.1.4. of Appendix 2 to this Sub-Annex was applied, the fuel consumption correction coefficient shall be determined according to paragraph 2. of Appendix 2 to this Sub-Annex. The corrected charge-sustaining fuel consumption shall be determined using the following equation:
FCCS=FCCS,nb− Kfuel,FCHV× ECDC,CSwhere:
FCCSis the charge-sustaining fuel consumption of the charge-sustaining Type 1 test according to Table A8/7, step no. 2, kg/100 km;FCCS,nbis the non-balanced fuel consumption of the charge-sustaining Type 1 test, not corrected for the energy balance, according to Table A8/7, step no. 1, kg/100 km;ECDC,CSis the electric energy consumption of the charge-sustaining Type 1 test according to paragraph 4.3. of this Sub-Annex, Wh/km;Kfuel,FCHVis the fuel consumption correction coefficient according to paragraph 2.3.1. of Appendix 2 to this Sub-Annex, (kg/100 km)/(Wh/km).
 4.2.2. 
The utility factor-weighted charge-depleting fuel consumption FCCD shall be calculated using the following equation:
FCCD=∑kj= 1UFj× FCCD,j∑kj= 1UFj
where:

FCCDis the utility factor weighted charge-depleting fuel consumption, l/100 km;FCCD,jis the fuel consumption for phase j of the charge-depleting Type 1 test, determined according to paragraph 6. of Sub-Annex 7, l/100 km;UFjis the utility factor of phase j according to Appendix 5 of this Sub-Annex;jis the index number of the phase considered;kis the number of phases driven up to the end of the transition cycle according to paragraph 3.2.4.4 of this Sub-Annex.

In the case that the interpolation approach is applied, k shall be the number of phases driven up to the end of the transition cycle of vehicle L nveh_L.

If the transition cycle number driven by vehicle H, nvehH, and, if applicable, an individual vehicle within the vehicle interpolation family, nvehind, is lower than the transition cycle number driven by vehicle L nveh_L the confirmation cycle of vehicle H and, if applicable, an individual vehicle shall be included in the calculation. The fuel consumption of each phase of the confirmation cycle shall then be corrected to an electric energy consumption of zero, ECDC,CD,j=0, by using the fuel consumption correction coefficient according to Appendix 2 of this Sub-Annex.
 4.2.3. 
The utility factor-weighted fuel consumption from the charge-depleting and charge-sustaining Type 1 test shall be calculated using the following equation:
FCweighted=∑j= 1kUFj× FCCD,j+1−∑j= 1kUFj× FCCS
where:

FCweightedis the utility factor-weighted fuel consumption, l/100 km;UFjis the utility factor of phase j according to Appendix 5 of this Sub-Annex;FCCD,jis the fuel consumption of phase j of the charge-depleting Type 1 test, determined according to paragraph 6. of Sub-Annex 7, l/100 km;FCCSis the fuel consumption determined according to Table A8/6, step no. 1, l/100 km;jis the index number of the phase considered;kis the number of phases driven up to the end of the transition cycle according to paragraph 3.2.4.4. of this Sub-Annex.

In the case that the interpolation approach is applied, k shall be the number of phases driven up to the end of the transition cycle of vehicle L nveh_L.

If the transition cycle number driven by vehicle H, nvehH, and, if applicable, an individual vehicle within the vehicle interpolation family, nvehind, is lower than the transition cycle number driven by vehicle L, nveh_L, the confirmation cycle of vehicle H and, if applicable, an individual vehicle shall be included in the calculation. The fuel consumption of each phase of the confirmation cycle shall then be corrected to an electric energy consumption of zero ECDC,CD,j=0 by using the fuel consumption correction coefficient according to Appendix 2 of this Sub-Annex.
 4.3. 
For the determination of the electric energy consumption based on the current and voltage determined according to Appendix 3 of this Sub-Annex, the following equations shall be used:
ECDC,j=ΔEREESS,jdj
where:

ECDC,jis the electric energy consumption over the considered period j based on the REESS depletion, Wh/km;ΔEREESS,jis the electric energy change of all REESSs during the considered period j, Wh;djis the distance driven in the considered period j, km;

and
ΔEREESS,j=∑j= 1nΔEREESS,j,i
where:

ΔEREESS,j,iis the electric energy change of REESS i during the considered period j, Wh;

and
ΔEREESS,j,i=13600×∫t0tendUtREESS,j,i× Itj,i dt
where:

U(t)REESS,j,iis the voltage of REESS i during the considered period j determined according to Appendix 3 to this Sub-Annex, V;t0is the time at the beginning of the considered period j, s;tendis the time at the end of the considered period j, s;I(t)j,iis the electric current of REESS i during the considered period j determined according to Appendix 3 to this Sub-Annex, A;iis the index number of the considered REESS;nis the total number of REESS;jis the index for the considered period, where a period can be any combination of phases or cycles;13600is the conversion factor from Ws to Wh.
 4.3.1. 
The utility factor-weighted charge-depleting electric energy consumption based on the recharged electric energy from the mains shall be calculated using the following equation:
ECAC,CD=∑kj= 1UFj× ECAC,CD,j∑kj= 1UFj
where:

ECAC,CDis the utility factor-weighted charge-depleting electric energy consumption based on the recharged electric energy from the mains, Wh/km;UFjis the utility factor of phase j according to Appendix 5 to this Sub-Annex;ECAC,CD,jis the electric energy consumption based on the recharged electric energy from the mains of phase j, Wh/km;

and
ECAC,CD,j=ECCD,CD,j×EAC∑kj= 1ΔEREESS,j
where:

ECDC,CD,jis the electric energy consumption based on the REESS depletion of phase j of the charge-depleting Test 1 according to paragraph 4.3. of this Sub-Annex, Wh/km;EACis the recharged electric energy from the mains determined according to paragraph 3.2.4.6. of this Sub-Annex, Wh;ΔEREESS,jis the electric energy change of all REESSs of phase j according to paragraph 4.3. of this Sub-Annex, Wh;jis the index number of the phase considered;kis the number of phases driven up to the end of the transition cycle of vehicle L ,nveh_L, according to paragraph 3.2.4.4. of this Sub-Annex.
 4.3.2. 
The utility factor-weighted electric energy consumption based on the recharged electric energy from the mains shall be calculated using the following equation:
ECAC,weighted=∑j= 1kUFj× ECAC,CD,j
where:

ECAC,weightedis the utility factor-weighted electric energy consumption based on the recharged electric energy from the mains, Wh/km;UFjis the utility factor of phase j according to Appendix 5 of this Sub-Annex;ECAC,CD,jis the electric energy consumption based on the recharged electric energy from the mains of phase j according to paragraph 4.3.1. of this Sub-Annex, Wh/km;jis the index number of the phase considered;kis the number of phases driven up to the end of the transition cycle of vehicle L nveh_L according to paragraph 3.2.4.4. of this Sub-Annex.
 4.3.3.  4.3.3.1. 
The electric energy consumption based on the recharged electric energy from the mains and the equivalent all-electric range shall be calculated using the following equation:
EC=EACEAER
where:

ECis the electric energy consumption of the applicable WLTP test cycle based on the recharged electric energy from the mains and the equivalent all-electric range, Wh/km;EACis the recharged electric energy from the mains according to paragraph 3.2.4.6. of this Sub-Annex, Wh;EAERis the equivalent all-electric range according to paragraph 4.4.4.1. of this Sub-Annex, km.
 4.3.3.2. 
The phase-specific electric energy consumption based on the recharged electric energy from the mains and the phase-specific equivalent all-electric range shall be calculated using the following equation:
ECp=EACEAERp
where:

ECPis the phase-specific electric energy consumption based on the recharged electric energy from the mains and the equivalent all-electric range, Wh/km;EACis the recharged electric energy from the mains according to paragraph 3.2.4.6. of this Sub-Annex, Wh;EAERPis the phase-specific equivalent all-electric range according to paragraph 4.4.4.2. of this Sub-Annex, km.
 4.3.4.  4.3.4.1. The electric energy consumption determined in this paragraph shall be calculated only if the vehicle was able to follow the applicable test cycle within the speed trace tolerances according to paragraph 1.2.6.6. of Sub-Annex 6 during the entire considered period.
 4.3.4.2. 
The electric energy consumption of the applicable WLTP test cycle based on the recharged electric energy from the mains and the pure electric range shall be calculated using the following equation:
ECWLTC=EACPERWLTC
where:

ECWLTCis the electric energy consumption of the applicable WLTP test cycle based on the recharged electric energy from the mains and the pure electric range for the applicable WLTP test cycle, Wh/km;EACis the recharged electric energy from the mains according to paragraph 3.4.4.3. of this Sub-Annex, Wh;PERWLTCis the pure electric range for the applicable WLTP test cycle as calculated according to paragraph 4.4.2.1.1. or paragraph 4.4.2.2.1. of this Sub-Annex, depending on the PEV test procedure that must be used, km.
 4.3.4.3. 
The electric energy consumption of the applicable WLTP city test cycle based on the recharged electric energy from the mains and the pure electric range for the applicable WLTP city test cycle shall be calculated using the following equation:
ECcity=EACPERcity
where:

ECcityis the electric energy consumption of the applicable WLTP city test cycle based on the recharged electric energy from the mains and the pure electric range for the applicable WLTP city test cycle, Wh/km;EACis the recharged electric energy from the mains according to paragraph 3.4.4.3. of this Sub-Annex, Wh;PERcityis the pure electric range for the applicable WLTP city test cycle as calculated according to paragraph 4.4.2.1.2. or paragraph 4.4.2.2.2. of this Sub-Annex, depending on the PEV test procedure that must be used, km.
 4.3.4.4. 
The electric energy consumption of each individual phase based on the recharged electric energy from the mains and the phase-specific pure electric range shall be calculated using the following equation:
ECp=EACPERp
where:

ECpis the electric energy consumption of each individual phase p based on the recharged electric energy from the mains and the phase-specific pure electric range, Wh/kmEACis the recharged electric energy from the mains according to paragraph 3.4.4.3. of this Sub-Annex, Wh;PERpis the phase-specific pure electric range as calculated according to paragraph 4.4.2.1.3. or paragraph 4.4.2.2.3. of this Sub-Annex, depending on the PEV test procedure used, km.
 4.4.  4.4.1.  4.4.1.1. 
The all-electric range AER for OVC-HEVs shall be determined from the charge-depleting Type 1 test described in paragraph 3.2.4.3. of this Sub-Annex as part of the Option 1 test sequence and is referenced in paragraph 3.2.6.1. of this Sub-Annex as part of the Option 3 test sequence by driving the applicable WLTP test cycle according to paragraph 1.4.2.1. of this Sub-Annex. The AER is defined as the distance driven from the beginning of the charge-depleting Type 1 test to the point in time where the combustion engine starts consuming fuel.
 4.4.1.2.  4.4.1.2.1. The all-electric range city AERcity for OVC-HEVs shall be determined from the charge-depleting Type 1 test described in paragraph 3.2.4.3. of this Sub-Annex as part of the Option 1 test sequence and is referenced in paragraph 3.2.6.1. of this Sub-Annex as part of the Option 3 test sequence by driving the applicable WLTP city test cycle according to paragraph 1.4.2.2. of this Sub-Annex. The AERcity is defined as the distance driven from the beginning of the charge-depleting Type 1 test to the point in time where the combustion engine starts consuming fuel.
 4.4.1.2.2. 
AERcity=UBEcityECDC,city

where:

UBEcityis the usable REESS energy determined from the beginning of the charge-depleting Type 1 test described in paragraph 3.2.4.3. of this Sub-Annex by driving applicable WLTP test cycles until the point in time where the combustion engine starts consuming fuel, Wh;ECDC,cityis the weighted electric energy consumption of the pure electrically driven applicable WLTP city test cycles of the charge-depleting Type 1 test described in paragraph 3.2.4.3. of this Sub-Annex by driving applicable WLTP test cycle(s), Wh/km;

and

UBEcity=∑j= 1kΔEREESS,j

where:

ΔEREESS,jis the electric energy change of all REESSs during phase j, Wh;jis the index number of the phase considered;Kis the number of the phases driven from the beginning of the test up to and excluding the phase where the combustion engine starts consuming fuel;

and

ECDC,city=∑j= 1ncity,peECDC,city,j× Kcity,j

where:

ECDC,city,jis the electric energy consumption for the jth pure electrically driven WLTP city test cycle of the charge-depleting Type 1 test according to paragraph 3.2.4.3. of this Sub-Annex by driving applicable WLTP test cycles, Wh/km;Kcity,jis the weighting factor for the jth pure electrically driven applicable WLTP city test cycle of the charge-depleting Type 1 test according to paragraph 3.2.4.3. of this Sub-Annex by driving applicable WLTP test cycles;jis the index number of the pure electrically driven applicable WLTP city test cycle considered;ncity,peis the number of pure electrically driven applicable WLTP city test cycles;

and

Kcity,1=ΔEREESS,city,1UBEcity

where:

ΔEREESS,city,1 is the electric energy change of all REESSs during the first applicable WLTP city test cycle of the charge-depleting Type 1 test, Wh;

and

Kcity,j=1− Kcity,1ncity,pe− 1 for j= 2 to ncity,pe×
 4.4.2. 
The ranges determined in this paragraph shall only be calculated if the vehicle was able to follow the applicable WLTP test cycle within the speed trace tolerances according to paragraph 1.2.6.6. of Sub-Annex 6 during the entire considered period.
 4.4.2.1.  4.4.2.1.1. 
PERWLTC=UBESTPECDC,WLTC

where:

UBESTPis the usable REESS energy determined from the beginning of the shortened Type 1 test procedure until the break-off criterion as defined in paragraph 3.4.4.2.3. of this Sub-Annex is reached, Wh;ECDC,WLTCis the weighted electric energy consumption for the applicable WLTP test cycle of DS1 and DS2 of the shortened Type 1 test procedure Type 1 test, Wh/km;

and

UBESTP=ΔEREESS,DS1+ ΔEREESS,DS2+ ΔEREESS,CSSM+ ΔEREESS,CCSE

where:

ΔEREESS,DS1is the electric energy change of all REESSs during DS1 of the shortened Type 1 test procedure, Wh;ΔEREESS,DS2is the electric energy change of all REESSs during DS2 of the shortened Type 1 test procedure, Wh;ΔEREESS,CSSMis the electric energy change of all REESSs during CSSM of the shortened Type 1 test procedure, Wh;ΔEREESS,CSSEis the electric energy change of all REESSs during CSSE of the shortened Type 1 test procedure, Wh;

and

ECDC,WLTC=∑j= 12ECDC,WLTC,j× KWLTC,j

where:

ECDC,WLTC,jis the electric energy consumption for the applicable WLTP test cycle DSj of the shortened Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;kWLTC,jis the weighting factor for the applicable WLTP test cycle of DSj of the shortened Type 1 test procedure;

and

KWLTC,1=ΔEREESS,WLTC,1UBESTP and KWLTC,2= 1− KWLTC,1

where:

KWLTC,jis the weighting factor for the applicable WLTP test cycle of DSj of the shortened Type 1 test procedure;ΔEREESS,WLTC,1is the electric energy change of all REESSs during the applicable WLTP test cycle from DS1 of the shortened Type 1 test procedure, Wh;
 4.4.2.1.2. 
PERcity=UBESTPECDC,city

where:

UBESTPis the usable REESS energy according to paragraph 4.4.2.1.1. of this Sub-Annex, Wh;ECDC,cityis the weighted electric energy consumption for the applicable WLTP city test cycle of DS1 and DS2 of the shortened Type 1 test procedure, Wh/km;

and

ECDC,city=∑j= 14 ECDC,city,j× Kcity,j

where:

ECDC,city,jis the electric energy consumption for the applicable WLTP city test cycle where the first applicable WLTP city test cycle of DS1 is indicated as j = 1, the second applicable WLTP city test cycle of DS1 is indicated as j = 2, the first applicable WLTP city test cycle of DS2 is indicated as j = 3 and the second applicable WLTP city test cycle of DS2 is indicated as j = 4 of the shortened Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;Kcity,jis the weighting factor for the applicable WLTP city test cycle where the first applicable WLTP city test cycle of DS1 is indicated as j = 1, the second applicable WLTP city test cycle of DS1 is indicated as j = 2, the first applicable WLTP city test cycle of DS2 is indicated as j = 3 and the second applicable WLTP city test cycle of DS2 is indicated as j = 4,

and

Kcity,1=ΔEREESS,city,1UBESTPand Kcity,j=1− Kcity,13 for j= 2 ... 4

where:

ΔEREESS,city,1is the energy change of all REESSs during the first applicable WLTP city test cycle of DS1 of the shortened Type 1 test procedure, Wh;
 4.4.2.1.3. 
PERp=UBESTPECDC,p

where:

UBEUBEis the usable REESS energy according to paragraph 4.4.2.1.1. of this Sub-Annex, Wh;ECDC,pis the weighted electric energy consumption for each individual phase of DS1 and DS2 of the shortened Type 1 test procedure, Wh/km;

In the case that phase p = low and phase p = medium, the following equations shall be used:

ECDC,p=∑j= 14 ECDC,p,j× Kp,j

where:

ECDC,p,jis the electric energy consumption for phase p where the first phase p of DS1 is indicated as j = 1, the second phase p of DS1 is indicated as j = 2, the first phase p of DS2 is indicated as j = 3 and the second phase p of DS2 is indicated as j = 4 of the shortened Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;Kp,jis the weighting factor for phase p where the first phase p of DS1 is indicated as j = 1, the second phase p of DS1 is indicated as j = 2, the first phase p of DS2 is indicated as j = 3, and the second phase p of DS2 is indicated as j = 4 of the shortened Type 1 test procedure;

and

Kp,1=ΔEREESS,p,1UBESTPand Kp,j=1− Kp,13 for j= 2 ... 4

where:

ΔEREESS,p,1is the energy change of all REESSs during the first phase p of DS1 of the shortened Type 1 test procedure, Wh.

In the case that phase p = high and phase p = extraHigh, the following equations shall be used:

ECDC,p=∑j= 12 ECDC,p,j× Kp,j

where:

ECDC,p,jis the electric energy consumption for phase p of DSj of the shortened Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;kp,jis the weighting factor for phase p of DSj of the shortened Type 1 test procedure

and

Kp,1=ΔEREESS,p,1UBESTP and Kp,2= 1− Kp,1

where:

ΔEREESS,p,1is the electric energy change of all REESSs during the first phase p of DS1 of the shortened Type 1 test procedure, Wh.
 4.4.2.2.  4.4.2.2.1. 
PERWLTC=UBECCPECDC,WLTC

where:

UBECCPis the usable REESS energy determined from the beginning of the consecutive cycle Type 1 test procedure until the break-off criterion according to paragraph 3.4.4.1.3. of this Sub-Annex is reached, Wh;ECDC,WLTCis the electric energy consumption for the applicable WLTP test cycle determined from completely driven applicable WLTP test cycles of the consecutive cycle Type 1 test procedure, Wh/km;

and

UBECCP=∑kj= 1 ΔEREESS,j

where:

ΔEREESS,jis the electric energy change of all REESSs during phase j of the consecutive cycle Type 1 test procedure, Wh;jis the index number of the phase considered;kis the number of phases driven from the beginning up to and including the phase where the break-off criterion is reached;

and

ECDC,WLTC=∑nWLTCj= 1 ECDC,WLTC,j× KWLTC,j

where:

ECDC,WLTC,jis the electric energy consumption for the applicable WLTP test cycle j of the consecutive cycle Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;KWLTC,jis the weighting factor for the applicable WLTP test cycle j of the consecutive cycle Type 1 test procedure;jis the index number of the applicable WLTP test cycle;nWLTCis the whole number of complete applicable WLTP test cycles driven;

and

KWLTC,1=ΔEREESS,WLTC,1UBECCP and KWLTC,j=1− KWLTC,1nWLTC− 1 for j=2 … nWLTC

where:

ΔEREESS,WLTC,1is the electric energy change of all REESSs during the first applicable WLTP test cycle of the consecutive Type 1 test cycle procedure, Wh.
 4.4.2.2.2. 
PERcity=UBECCPECDC,city

where:

UBECCPis the usable REESS energy according to paragraph 4.4.2.2.1. of this Sub-Annex, Wh;ECDC,cityis the electric energy consumption for the applicable WLTP city test cycle determined from completely driven applicable WLTP city test cycles of the consecutive cycle Type 1 test procedure, Wh/km;

and

ECDC,city=∑n cityj= 1ECDC,city,j×Kcity,j

where:

ECDC,city,jis the electric energy consumption for the applicable WLTP city test cycle j of the consecutive cycle Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;Kcity,jis the weighting factor for the applicable WLTP city test cycle j of the consecutive cycle Type 1 test procedure;jis the index number of the applicable WLTP city test cycle;ncityis the whole number of complete applicable WLTP city test cycles driven;

and

Kcity,1=ΔEREESS,city,1UBECCP and Kcity,j=1− Kcity,1ncity− 1 for j=2 … ncity

where:

ΔEREESS,city,1is the electric energy change of all REESSs during the first applicable WLTP city test cycle of the consecutive cycle Type 1 test procedure, Wh.
 4.4.2.2.3. 
PERp=UBECCPECDC,p

where:

UBECCPis the usable REESS energy according to paragraph 4.4.2.2.1. of this Sub-Annex, Wh;ECDC,pis the electric energy consumption for the considered phase p determined from completely driven phases p of the consecutive cycle Type 1 test procedure, Wh/km;

and

ECDC,p=∑j= 1n pECDC,p,j× Kp,j

where:

ECDC,p,jis the jth electric energy consumption for the considered phase p of the consecutive cycle Type 1 test procedure according to paragraph 4.3. of this Sub-Annex, Wh/km;kp,jis the jth weighting factor for the considered phase p of the consecutive cycle Type 1 test procedure;jis the index number of the considered phase p;npis the whole number of complete WLTC phases p driven;

and

Kp,1=ΔEREESS,p,1UBECCP and Kp,j=1− Kp,1np− 1 for j=2 … np

where:

ΔEREESS,p,1is the electric energy change of all REESSs during the first driven phase p during the consecutive cycle Type 1 test procedure, Wh.
 4.4.3. 
The charge-depleting cycle range RCDC shall be determined from the charge-depleting Type 1 test described in paragraph 3.2.4.3. of this Sub-Annex as part of the Option 1 test sequence and is referenced in paragraph 3.2.6.1. of this Sub-Annex as part of the Option 3 test sequence. The RCDC is the distance driven from the beginning of the charge-depleting Type 1 test to the end of the transition cycle according to paragraph 3.2.4.4 of this Sub-Annex.
 4.4.4.  4.4.4.1. 
The cycle-specific equivalent all-electric range shall be calculated using the following equation:

EAER=MCO2,CS− MCO2,CD,avgMCO2,CS×RCDC

where:

EAERis the cycle-specific equivalent all-electric range, km;MCO2,CSis the charge-sustaining CO2 mass emission according to Table A8/5, step no. 7, g/km;MCO2,CD,avgis the arithmetic average charge-depleting CO2 mass emission according to the equation below, g/km;RCDCis the charge-depleting cycle range according to paragraph 4.4.2. of this Sub-Annex, km;

and

MCO2,CD,avg=∑kj= 1MCO2,CD,j× dj∑kj= 1 dj

where:

MCO2,CD,avgis the arithmetic average charge-depleting CO2 mass emission, g/km;MCO2,CD,jis the CO2 mass emission determined according to paragraph 3.2.1. of Sub-Annex 7 of phase j of the charge-depleting Type 1 test, g/km;djis the distance driven in phase j of the charge-depleting Type 1 test, km;jis the index number of the considered phase;kis the number of phases driven up to the end of the transition cycle n according to paragraph 3.2.4.4 of this Sub-Annex.
 4.4.4.2. 
The phase-specific equivalent all-electric range shall be calculated using the following equation:

EAERp=MCO2,CSp− MCO2,CD,avg,pMCO2,CS,p×∑kj= 1ΔEREESS,jECDC,CD,p

where:

EAERpis the phase-specific equivalent all-electric range for the considered phase p, km;MCO2,CS,pis the phase-specific CO2 mass emission from the charge-sustaining Type 1 test for the considered phase p according to Table A8/5, step no. 7, g/km;ΔEREESS,jare the electric energy changes of all REESSs during the considered phase j, Wh;ECDC,CD,pis the electric energy consumption over the considered phase p based on the REESS depletion, Wh/km;jis the index number of the considered phase;kis the number of phases driven up to the end of the transition cycle n according to paragraph 3.2.4.4 of this Sub-Annex;

and

MCO2,CD,avg,p=∑n cc= 1MCO2,CD,p,c× dp,c∑n cc= 1 dp,c

where:

MCO2,CD,avg,pis the arithmetic average charge-depleting CO2 mass emission for the considered phase p, g/km;MCO2,CD,p,cis the CO2 mass emission determined according to paragraph 3.2.1. of Sub-Annex 7 of phase p in cycle c of the charge-depleting Type 1 test, g/km;dp,cis the distance driven in the considered phase p of cycle c of the charge-depleting Type 1 test, km;cis the index number of the considered applicable WLTP test cycle;pis the index of the individual phase within the applicable WLTP test cycle;ncis the number of applicable WLTP test cycles driven up to the end of the transition cycle n according to paragraph 3.2.4.4. of this Sub-Annex;

and

E CDC,CD,P=∑ncc= 1 ECDC,CD,P,C× dp,c∑ncc= 1 dp,c

where:

ECDC,CD,Pis the electric energy consumption of the considered phase p based on the REESS depletion of the charge-depleting Type 1 test, Wh/km;ECDC,CD,P,Cis the electric energy consumption of the considered phase p of cycle c based on the REESS depletion of the charge-depleting Type 1 test according to paragraph 4.3. of this Sub-Annex, Wh/km;dp,cis the distance driven in the considered phase p of cycle c of the charge-depleting Type 1 test, km;cis the index number of the considered applicable WLTP test cycle;pis the index of the individual phase within the applicable WLTP test cycle;ncis the number of applicable WLTP test cycles driven up to the end of the transition cycle n according to paragraph 3.2.4.4. of this Sub-Annex.

The considered phase values shall be the low-phase, mid-phase, high-phase, extra high-phase, and the city driving cycle.
 4.4.5. 
The actual charge-depleting range shall be calculated using the following equation:

RCDA=∑c= 1n− 1 dc+MCO2,CS− MCO2,n,cycleMCO2,CS− MCO2,CD,avg,n− 1× dn

where:

RCDAis the actual charge-depleting range, km;MCO2,CSis the charge-sustaining CO2 mass emission according to Table A8/5, step no. 7, g/km;MCO2,n,cycleis the CO2 mass emission of the applicable WLTP test cycle n of the charge-depleting Type 1 test, g/km;MCO2,CD,avg,n–1is the arithmetic average CO2 mass emission of the charge-depleting Type 1 test from the beginning up to and including the applicable WLTP test cycle (n-1), g/km;dcis the distance driven in the applicable WLTP test cycle c of the charge-depleting Type 1 test, km;dnis the distance driven in the applicable WLTP test cycle n of the charge-depleting Type 1 test, km;cis the index number of the considered applicable WLTP test cycle;nis the number of applicable WLTP test cycles driven including the transition cycle according to paragraph 3.2.4.4. of this Sub-Annex;

and

MCO2,CD,avg,n− 1=∑n− 1c= 1MCO2,CD,c× dc∑n− 1c= 1 dc

where:

MCO2,CD,avg,n–1is the arithmetic average CO2 mass emission of the charge-depleting Type 1 test from the beginning up to and including the applicable WLTP test cycle (n-1), g/km;MCO2,CD,cis the CO2 mass emission determined according to paragraph 3.2.1. of Sub-Annex 7 of the applicable WLTP test cycle c of the charge-depleting Type 1 test, g/km;dcis the distance driven in the applicable WLTP test cycle c of the charge-depleting Type 1 test, km;cis the index number of the considered applicable WLTP test cycle;nis the number of applicable WLTP test cycles driven including the transition cycle according to paragraph 3.2.4.4 of this Sub-Annex;
 4.5.  4.5.1. 
The interpolation method shall only be used if the difference in charge-sustaining CO2 mass emission, MCO2,CS, according to Table A8/5, step no. 8 between test vehicles L and H is between a minimum of 5 g/km and a maximum of 20 g/km or 20 per cent of the charge-sustaining CO2 mass emission, MCO2,CS, according to Table A8/5, step no. 8 for vehicle H, whichever value is smaller.

At the request of the manufacturer and with approval of the approval authority, the interpolation of individual vehicle values within a family may be extended if the maximum extrapolation is not more than 3 g/km above the charge-sustaining CO2 mass emission of vehicle H and/or is not more than 3 g/km below the charge-sustaining CO2 mass emission of vehicle L. This extension is valid only within the absolute boundaries of the interpolation range specified in this paragraph.

The maximum absolute boundary of 20 g/km charge-sustaining CO2 mass emission difference between vehicle L and vehicle H or 20 per cent of the charge-sustaining CO2 mass emission for vehicle H, whichever is smaller, may be extended by 10 g/km if a vehicle M is tested. Vehicle M is a vehicle within the interpolation family with a cycle energy demand within ± 10 per cent of the arithmetic average of vehicles L and H.

The linearity of charge-sustaining CO2 mass emission for vehicle M shall be verified against the linear interpolated charge-sustaining CO2 mass emission between vehicle L and H.

The linearity criterion for vehicle M shall be considered fulfilled if the difference between the charge-sustaining CO2 mass emission of vehicle M derived from the measurement and the interpolated charge-sustaining CO2 mass emission between vehicle L and H is below 1 g/km. If this difference is greater, the linearity criterion shall be considered to be fulfilled if this difference is 3 g/km or 3 per cent of the interpolated charge-sustaining CO2 mass emission for vehicle M, whichever is smaller.

If the linearity criterion is fulfilled, the interpolation between vehicle L and H shall be applicable for all individual vehicles within the interpolation family.

If the linearity criterion is not fulfilled, the interpolation family shall be split into two sub-families for vehicles with a cycle energy demand between vehicles L and M, and vehicles with a cycle energy demand between vehicles M and H.

For vehicles with a cycle energy demand between that of vehicles L and M, each parameter of vehicle H that is necessary for the interpolation of individual OVC-HEV and NOVC-HEV values, shall be substituted by the corresponding parameter of vehicle M.

For vehicles with a cycle energy demand between that of vehicles M and H, each parameter of vehicle L that is necessary for the interpolation of individual cycle values shall be substituted by the corresponding parameter of vehicle M.
 4.5.2. 
The energy demand Ek,p and distance driven dc,p per period p applicable for individual vehicles in the interpolation family shall be calculated according to the procedure in paragraph 5. of Sub-Annex 7, for the sets k of road load coefficients and masses according to paragraph 3.2.3.2.3. of Sub-Annex 7.
 4.5.3. 
The interpolation coefficient Kind,p per period shall be calculated for each considered period p using the following equation:

Kind,p=E3,p− E1,pE2,p− E1,p

where:

Kind,pis the interpolation coefficient for the considered individual vehicle for period p;E1,pis the energy demand for the considered period for vehicle L according to paragraph 5. of Sub-Annex 7, Ws;E2,pis the energy demand for the considered period for vehicle H according to paragraph 5. of Sub-Annex 7, Ws;3,pis the energy demand for the considered period for the individual vehicle according to paragraph 5. of Sub-Annex 7, Ws;pis the index of the individual period within the applicable test cycle.

In the case that the considered period p is the applicable WLTP test cycle, Kind,p is named Kind.
 4.5.4.  4.5.4.1. 
The charge-sustaining CO2 mass emission for an individual vehicle shall be calculated using the following equation:

MCO2–ind,CS,p=MCO2–L,CS,p+ Kind,d×MCO2–H,CS,p− MCO2–L,CS,p

where:

MCO2–ind,CS,pis the charge-sustaining CO2 mass emission for an individual vehicle of the considered period p according to Table A8/5, step no. 9, g/km;MCO2–L,CS,pis the charge-sustaining CO2 mass emission for vehicle L of the considered period p according to Table A8/5, step no. 8, g/km;MCO2–H,CS,pis the charge-sustaining CO2 mass emission for vehicle H of the considered period p according to Table A8/5, step no. 8, g/km;Kind,dis the interpolation coefficient for the considered individual vehicle for period p;pis the index of the individual period within the applicable WLTP test cycle.

The considered periods shall be the low-phase, mid-phase, high-phase, extra high-phase and the applicable WLTP test cycle.
 4.5.4.2. 
The utility factor-weighted charge-depleting CO2 mass emission for an individual vehicle shall be calculated using the following equation:

MCO2–ind,CD=MCO2–L,CD+ Kind×MCO2–H,CD− MCO2–L,CD

where:

MCO2–ind,CDis the utility factor-weighted charge-depleting CO2 mass emission for an individual vehicle, g/km;MCO2–L,CDis the utility factor-weighted charge-depleting CO2 mass emission for vehicle L, g/km;MCO2–H,CDis the utility factor-weighted charge-depleting CO2 mass emission for vehicle H, g/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 4.5.4.3. 
The utility factor-weighted CO2 mass emission for an individual vehicle shall be calculated using the following equation:
MCO2–ind,weighted=MCO2–L,weighted+ Kind×MCO2–H,weighted− MCO2–L,weighted
where:

MCO2–ind,weightedis the utility factor-weighted CO2 mass emission for an individual vehicle, g/km;MCO2–L,weightedis the utility factor-weighted CO2 mass emission for vehicle L, g/km;MCO2–H,weightedis the utility factor-weighted CO2 mass emission for vehicle H, g/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 4.5.5.  4.5.5.1. 
The charge-sustaining fuel consumption for an individual vehicle shall be calculated using the following equation:
FCind,CS,p=FCL,CS,p+ Kind,p×FCH,CS,p− FCL,CS,p
where:

FCind,CS,pis the charge-sustaining fuel consumption for an individual vehicle of the considered period p according to Table A8/6, step no. 3, l/100 km;FCL,CS,pis the charge-sustaining fuel consumption for vehicle L of the considered period p according to Table A8/6, step no. 2, l/100 km;FCH,CS,pis the charge-sustaining fuel consumption for vehicle H of the considered period p according to Table A8/6, step no. 2, l/100 km;Kind,pis the interpolation coefficient for the considered individual vehicle for period p;pis the index of the individual period within the applicable WLTP test cycle.

The considered periods shall be the low-phase, mid-phase, high-phase, extra high-phase, and the applicable WLTP test cycle.
 4.5.5.2. 
The utility factor-weighted charge-depleting fuel consumption for an individual vehicle shall be calculated using the following equation:
FCind,CD=FCL,CD+ Kind×FCH,CD− FCL,CD
where:

FCind,CDis the utility factor-weighted charge-depleting fuel consumption for an individual vehicle, l/100 km;FCL,CDis the utility factor-weighted charge-depleting fuel consumption for vehicle L, l/100 km;FCH,CDis the utility factor-weighted charge-depleting fuel consumption for vehicle H, l/100 km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 4.5.5.3. 
The utility factor-weighted fuel consumption for an individual vehicle shall be calculated using the following equation:
FCind,weighted=FCL,weighted+ Kind×FCH,weighted− FCL,weighted
where:

FCind,weightedis the utility factor-weighted fuel consumption for an individual vehicle, l/100 km;FCL,weightedis the utility factor-weighted fuel consumption for vehicle L, l/100 km;FCH,weightedis the utility factor-weighted fuel consumption for vehicle H, l/100 km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 4.5.6  4.5.6.1. 
The utility factor-weighted charge-depleting electric energy consumption based on the recharged electric energy from for an individual vehicle shall be calculated using the following equation:
ECAC–ind,CD=ECAC–L,CD+ Kind×ECAC–H,CD− ECAC–L,CD
where:

ECAC–ind,CDis the utility factor-weighted charge-depleting electric energy consumption based on the recharged electric energy from the mains for an individual vehicle, Wh/km;ECAC–L,CDis the utility factor-weighted charge-depleting electric energy consumption based on the recharged electric energy from the mains for vehicle L, Wh/km;ECAC–H,CDis the utility factor-weighted charge-depleting electric energy consumption based on the recharged electric energy from the mains for vehicle H, Wh/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle
 4.5.6.2. 
The utility factor-weighted electric energy consumption based on the recharged electric energy from the mains for an individual vehicle shall be calculated using the following equation:

ECAC–ind,weighted=ECAC–L,weighted+ Kind×ECAC–H,weighted− ECAC–L,weighted

where:

ECAC–ind,weightedis the utility factor weighted electric energy consumption based on the recharged electric energy from the mains for an individual vehicle, Wh/km;ECAC–L,weightedis the utility factor weighted electric energy consumption based on the recharged electric energy from the mains for vehicle L, Wh/km;ECAC–H,weightedis the utility factor weighted electric energy consumption based on the recharged electric energy from the mains for vehicle H, Wh/km;Kindis the interpolation coefficient for the considered individual vehicle for the applicable WLTP test cycle.
 4.5.6.3. 
The electric energy consumption for an individual vehicle according to paragraph 4.3.3. of this Sub-Annex in the case of OVC-HEVs and according to paragraph 4.3.4. of this Sub-Annex in the case of PEVs shall be calculated using the following equation:
ECind,p=ECL,p+ Kind,p×ECH,p− ECL,p
where:

ECind,pis the electric energy consumption for an individual vehicle for the considered period p, Wh/km;ECL,pis the electric energy consumption for vehicle L for the considered period p, Wh/km;ECH,pis the electric energy consumption for vehicle H for the considered period p, Wh/km;Kind,pis the interpolation coefficient for the considered individual vehicle for period p;pis the index of the individual period within the applicable test cycle.

The considered periods shall be the low-phase, mid-phase, high-phase, extra high-phase, the applicable WLTP city test cycle and the applicable WLTP test cycle.
 4.5.7  4.5.7.1. 
If the following criterion
AERLRCDA,L−AERHRCDA,H≤0, 1
where:

AERLis the all-electric range of vehicle L for the applicable WLTP test cycle, km;AERHis the all-electric range of vehicle H for the applicable WLTP test cycle, km;RCDA,Lis the actual charge-depleting range of vehicle L, km;RCDA,His the actual charge-depleting range of vehicle H, km;

is fulfilled, the all-electric range for an individual vehicle shall be calculated using the following equation:
AERind,p=AERL,p+ Kind,p×AERH,p− AERL,p
where:

AERind,pis the all-electric range for an individual vehicle for the considered period p, km;AERL,pis the all-electric range for vehicle L for the considered period p, km;AERH,pis the all-electric range for vehicle H for the considered period p, kmKind,pis the interpolation coefficient for the considered individual vehicle for period p;pis the index of the individual period within the applicable test cycle.

The considered periods shall be the applicable WLTP city test cycle and the applicable WLTP test cycle.

If the criterion defined in this paragraph is not fulfilled, the AER determined for vehicle H is applicable to all vehicles within the interpolation family.
 4.5.7.2. 
The pure electric range for an individual vehicle shall be calculated using the following equation:
PERind,p=PERL,p+ Kind,p×PERH,p− PERL,p
where:

PERind,pis the pure electric range for an individual vehicle for the considered period p, km;PERL,pis the pure electric range for vehicle L for the considered period p, km;PERH,pis the pure electric range for vehicle H for the considered period p, km;Kind,pis the interpolation coefficient for the considered individual vehicle for period p;pis the index of the individual period within the applicable test cycle.

The considered periods shall be the low-phase, mid-phase, high-phase, extra high-phase, applicable WLTP city test cycle and the applicable WLTP test cycle.
 4.5.7.3. 
The equivalent all-electric range for an individual vehicle shall be calculated using the following equation:
EAERind,p=EAERL,p+ Kind,p×EAERH,p− EAERL,p
where:

EAERind,pis the equivalent all-electric range for an individual vehicle for the considered period p, km;EAERL,pis the equivalent all-electric range for vehicle L for the considered period p, km;EAERH,pis the equivalent all-electric range for vehicle H for the considered period p, km;Kind,pis the interpolation coefficient for the considered individual vehicle for period p;pis the index of the individual period within the applicable test cycle.

The considered periods shall be the low-phase, mid-phase, high-phase, extra high-phase, applicable WLTP city test cycle and the applicable WLTP test cycle.

Sub-Annex 8 1.  1.1. 
Charge-depleting type 1 test with no subsequent charge-sustaining Type 1 test (A8.App1/1)

Figure A8.App1/1 1.2. 
Charge-sustaining Type 1 test with no subsequent charge-depleting Type 1 test (A8.App1/2)

Figure A8.App1/2 1.3. 
Charge-depleting Type 1 test with subsequent charge-sustaining Type 1 test (A8.App1/3)

Figure A8.App1/3 1.4. 
Charge-sustaining Type 1 test with subsequent charge-depleting Type 1 test

Figure A8.App1/4 2. 
Charge-sustaining Type 1 test

Figure A8.App1/5 3.  3.1. 
Figure A8.App1/6 3.2. 
Figure A8.App1/7
Sub-Annex 8
This Appendix describes the procedure to correct the charge-sustaining Type 1 test CO2 mass emission for NOVC-HEVs and OVC-HEVs, and the fuel consumption for NOVC-FCHVs as a function of the electric energy change of all REESSs.
 1.  1.1.  1.1.1. The phase-specific fuel consumption for NOVC-FCHVs, and the CO2 mass emission for NOVC-HEVs and OVC-HEVs shall be corrected.
 1.1.2. In the case that a correction of fuel consumption for NOVC-FCHVs or a correction of CO2 mass emission for NOVC-HEVs and OVC-HEVs measured over the whole cycle according to paragraph 1.1.3. or paragraph 1.1.4. of this Appendix is applied, paragraph 4.3. of this Sub-Annex shall be used to calculate the charge-sustaining REESS energy change ΔEREESS,CS of the charge-sustaining Type 1 test. The considered period j used in paragraph 4.3. of this Sub-Annex is defined by the charge-sustaining Type 1 test.
 1.1.3. The correction shall be applied if ΔEREESS,CS is negative which corresponds to REESS discharging and the correction criterion c calculated in paragraph 1.2. is greater than the applicable tolerance according to Table A8.App2/1.
 1.1.4. 

((a)) ΔEREESS,CS is positive which corresponds to REESS charging and the correction criterion c calculated in paragraph 1.2. is greater than the applicable tolerance according to Table A8.App2/1;
((b)) the correction criterion c calculated in paragraph 1.2. is smaller than the applicable tolerance according to Table A8.App2/1;
((c)) the manufacturer can prove to the approval authority by measurement that there is no relation between ΔEREESS,CS and charge-sustaining CO2 mass emission and ΔEREESS,CS and fuel consumption respectively.
 1.2. The correction criterion c is the ratio between the absolute value of the REESS electric energy change ΔEREESS,CS and the fuel energy and shall be calculated as follows:
c=ΔEREESS,CSEfuel,CSwhere:
ΔEREESS,CSis the charge-sustaining REESS energy change according to paragraph 1.1.2. of this Appendix, Wh;Efuel,CSis the charge-sustaining energy content of the consumed fuel according to paragraph 1.2.1. in the case of NOVC-HEVs and OVC-HEVs, according to paragraph 1.2.2. in the case of NOVC-FCHVs, Wh.
 1.2.1. 
The charge-sustaining energy content of the consumed fuel for NOVC-HEVs and OVC-HEVs shall be calculated using the following equation:
Efuel,CS=10× HV× FCCS,nb× dCS
where:

Efuel,CSis the charge-sustaining energy content of the consumed fuel of the applicable WLTP test cycle of the charge-sustaining Type 1 test, Wh;HVis the heating value according to Table A6.App2/1, kWh/l;FCCS,nbis the non-balanced charge-sustaining fuel consumption of the charge-sustaining Type 1 test, not corrected for the energy balance, determined according to paragraph 6. of Sub-Annex 7, using the gaseous emission compound values according to Table A8/5, step no. 2, l/100 km;dCSis the distance driven over the corresponding applicable WLTP test cycle, km;10conversion factor to Wh.
 1.2.2. 
The charge-sustaining energy content of the consumed fuel for NOVC-FCHVs shall be calculated using the following equation:
Efuel,CS=10,36× 121× FCCS,nb× dCS
Efuel,CSis the charge-sustaining energy content of the consumed fuel of the applicable WLTP test cycle of the charge-sustaining Type 1 test, Wh;121is the lower heating value of hydrogen, MJ/kg;FCCS,nbis the non-balanced charge-sustaining fuel consumption of the charge-sustaining Type 1 test, not corrected for the energy balance, determined according to Table A8/7, step no.1, kg/100 km;dCSis the distance driven over the corresponding applicable WLTP test cycle, km;10,36conversion factor to Wh.


Applicable Type 1 test cycle Low + Medium Low + Medium + High Low + Medium + High + Extra High
Correction criterion ratio c 0,015 0,01 0,005
 2.  2.1. The CO2 mass emission correction coefficient KCO2, the fuel consumption correction coefficients Kfuel,FCHV, as well as, if required by the manufacturer, the phase-specific correction coefficients KCO2,p and Kfuel,FCHV,p shall be developed based on the applicable charge-sustaining Type 1 test cycles.
In the case that vehicle H was tested for the development of the correction coefficient for CO2 mass emission for NOVC-HEVs and OVC-HEVs, the coefficient may be applied within the interpolation family.
 2.2. The correction coefficients shall be determined from a set of charge-sustaining Type 1 tests according to paragraph 3. of this Appendix. The number of tests performed by the manufacturer shall be equal to or greater than five.
The manufacturer may request to set the state of charge of the REESS prior to the test according to the manufacturer’s recommendation and as described in paragraph 3. of this Appendix. This practice shall only be used for the purpose of achieving a charge-sustaining Type 1 test with opposite sign of the ΔEREESS,CS and with approval of the approval authority.
The set of measurements shall fulfil the following criteria:

((a)) The set shall contain at least one test with ΔEREESS,CS ≤ 0 and at least one test with ΔEREESS,CS > 0. ΔEREESS,CS,n is the sum of electric energy changes of all REESSs of test n calculated according to paragraph 4.3. of this Sub-Annex.
((b)) The difference in MCO2,CS between the test with the highest negative electric energy change and the test with the highest positive electric energy change shall be greater than or equal to 5 g/km. This criterion shall not be applied for the determination of Kfuel,FCHV.
In the case of the determination of KCO2, the required number of tests may be reduced to three tests if all of the following criteria are fulfilled in addition to (a) and (b):
((c)) the difference in MCO2,CS between any two adjacent measurements, related to the electric energy change during the test, shall be less than or equal to 10 g/km.
((d)) in addition to (b), the test with the highest negative electric energy change and the test with the highest positive electric energy change shall not be within the region that is defined by:
− 0,01≤ΔEREESSEfuel≤+ 0,01,
where:
Efuelis the energy content of the consumed fuel calculated according to paragraph 1.2. of this Appendix, Wh.
((e)) the difference in MCO2,CS between the test with the highest negative electric energy change and the mid-point, and the difference in MCO2,CS between mid-point and the test with the highest positive electric energy change shall be similar and preferably be within the range defined by (d).
The correction coefficients determined by the manufacturer shall be reviewed and approved by the approval authority prior to its application.
If the set of at least five tests does not fulfil criterion (a) or criterion (b) or both, the manufacturer shall provide evidence to the approval authority as to why the vehicle is not capable of meeting either or both criteria. If the approval authority is not satisfied with the evidence, it may require additional tests to be performed. If the criteria after additional tests are still not fulfilled, the approval authority will determine a conservative correction coefficient, based on the measurements.
 2.3.  2.3.1. 
For NOVC-FCHVs, the fuel consumption correction coefficient Kfuel,FCHV, determined by driving a set of charge-sustaining Type 1 tests, is defined using the following equation:
Kfuel,FCHV=∑nCSn= 1ECDC,CS,n− ECDC,CS,avg×FCCS,nb,n− FCCS,nb,avg∑nCSn= 1ECDC,CS,n− ECDC,CS,avg2
where:

Kfuel,FCHVis the fuel consumption correction coefficient, (kg/100 km)/(Wh/km);ECDC,CS,nis the charge-sustaining electric energy consumption of test n based on the REESS depletion according to the equation below, Wh/kmECDC,CS,avgis the mean charge-sustaining electric energy consumption of ncs tests based on the REESS depletion according to the equation below, Wh/km;FCCS,nb,nis the charge-sustaining fuel consumption of test n, not corrected for the energy balance, according to Table A8/7, step no. 1, kg/100 km;FCCS,nb,avgis the arithmetic average of the charge-sustaining fuel consumption of ncs tests based on the fuel consumption, not corrected for the energy balance, according to the equation below, kg/100 km;nis the index number of the considered test;ncsis the total number of tests;

and:
ECDC,CS,avg=1ncs×∑n= 1ncs ECDC,CS,n
and:
FCCS,nb,avg=1ncs×∑n= 1ncs FCCS,nb,n
and:
ECDC,CS,n=ΔEREESS,CS,ndCS,n
where:

ΔEREESS,CS,nis the charge-sustaining REESS electric energy change of test n according to paragraph 1.1.2. of this Appendix, Wh;dCS,nis the distance driven over the corresponding charge-sustaining Type 1 test n, km.

The fuel consumption correction coefficient shall be rounded to four significant figures. The statistical significance of the fuel consumption correction coefficient shall be evaluated by the approval authority.
 2.3.1.1. It is permitted to apply the fuel consumption correction coefficient that was developed from tests over the whole applicable WLTP test cycle for the correction of each individual phase.
 2.3.1.2. Without prejudice to the requirements of paragraph 2.2. of this Appendix, at the manufacturer’s request and upon approval of the approval authority, separate fuel consumption correction coefficients Kfuel,FCHV,p for each individual phase may be developed. In this case, the same criteria as described in paragraph 2.2. of this Appendix shall be fulfilled in each individual phase and the procedure described in paragraph 2.3.1. of this Appendix shall be applied for each individual phase to determine each phase specific correction coefficient.
 2.3.2. 
For OVC-HEVs and NOVC-HEVs, the CO2 mass emission correction coefficient KCO2, determined by driving a set of charge-sustaining Type 1 tests, is defined by the following equation:
KCO2=∑nCSn= 1ECDC,CS,n− ECDC,CS,avg×MCO2,CS,nb,n− MCO2,CS,nb,avg∑nCSn= 1ECDC,CS,n− ECDC,CS,avg2
where:

KCO2is the CO2 mass emission correction coefficient, (g/km)/(Wh/km);ECDC,CS,nis the charge-sustaining electric energy consumption of test n based on the REESS depletion according to paragraph 2.3.1. of this Appendix, Wh/km;ECDC,CS,avgis the arithmetic average of the charge-sustaining electric energy consumption of ncs tests based on the REESS depletion according to paragraph 2.3.1. of this Appendix, Wh/km;MCO2,CS,nb,nis the charge-sustaining CO2 mass emission of test n, not corrected for the energy balance, calculated according Table A8/5, step no. 2, g/km;MCO2,CS,nb,avgis the arithmetic average of the charge-sustaining CO2 mass emission of ncs tests based on the CO2 mass emission, not corrected for the energy balance, according to the equation below, g/km;nis the index number of the considered test;ncsis the total number of tests;

and:
MCO2,CS,nb,avg=1ncs×∑n= 1ncs MCO2,CS,nb,n
The CO2 mass emission correction coefficient shall be rounded to four significant figures. The statistical significance of the CO2 mass emission correction coefficient shall be evaluated by the approval authority.
 2.3.2.1. It is permitted to apply the CO2 mass emission correction coefficient developed from tests over the whole applicable WLTP test cycle for the correction of each individual phase.
 2.3.2.2. Without prejudice to the requirements of paragraph 2.2. of this Appendix, at the request of the manufacturer upon approval of the approval authority, separate CO2 mass emission correction coefficients KCO2,p for each individual phase may be developed. In this case, the same criteria as described in paragraph 2.2. of this Appendix shall be fulfilled in each individual phase and the procedure described in paragraph 2.3.2. of this Appendix shall be applied for each individual phase to determine phase-specific correction coefficients.
 3.  3.1. 
For OVC-HEVs, one of the following test sequences according to Figure A8.App2/1 shall be used to measure all values that are necessary for the determination of the correction coefficients according to paragraph 2. of this Appendix.

Figure A8.App2/1 3.1.1.  3.1.1.1. 
Preconditioning and soaking shall be conducted according to paragraph 2.1. of Appendix 4. to this Sub-Annex.
 3.1.1.2. 
Prior to the test procedure according to paragraph 3.1.1.3. the manufacturer may adjust the REESS. The manufacturer shall provide evidence that the requirements for the beginning of the test according to paragraph 3.1.1.3. are fulfilled.
 3.1.1.3.  3.1.1.3.1. The driver-selectable mode for the applicable WLTP test cycle shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.1.1.3.2. For testing, the applicable WLTP test cycle according to paragraph 1.4.2. of this Sub-Annex shall be driven.
 3.1.1.3.3. Unless stated otherwise in this Appendix, the vehicle shall be tested according to the Type 1 test procedure described in Sub-Annex 6.
 3.1.1.3.4. To obtain a set of applicable WLTP test cycles required for the determination of the correction coefficients, the test may be followed by a number of consecutive sequences required according to paragraph 2.2 of this Appendix consisting of paragraph 3.1.1.1. to paragraph 3.1.1.3. inclusive of this Appendix.
 3.1.2.  3.1.2.1. 
The test vehicle shall be preconditioned according to paragraph 2.1.1. or paragraph 2.1.2. of Appendix 4 to this Sub-Annex.
 3.1.2.2. 
After preconditioning, soaking according to paragraph 2.1.3. of Appendix 4 to this Sub-Annex shall be omitted and a break, during which the REESS is permitted to be adjusted, shall be set to a maximum duration of 60 minutes. A similar break shall be applied in advance of each test. Immediately after the end of this break, the requirements of paragraph 3.1.2.3. of this Appendix shall be applied.

Upon request of the manufacturer, an additional warm-up procedure may be conducted in advance of the REESS adjustment to ensure similar starting conditions for the correction coefficient determination. If the manufacturer requests this additional warm-up procedure, the identical warm-up procedure shall be applied repeatedly within the test sequence.
 3.1.2.3.  3.1.2.3.1. The driver-selectable mode for the applicable WLTP test cycle shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.1.2.3.2. For testing, the applicable WLTP test cycle according to paragraph 1.4.2. of this Sub-Annex shall be driven.
 3.1.2.3.3. Unless stated otherwise in this Appendix, the vehicle shall be tested according to the Type 1 test procedure described in Sub-Annex 6.
 3.1.2.3.4. To obtain a set of applicable WLTP test cycles that are required for the determination of the correction coefficients, the test may be followed by a number of consecutive sequences required according to paragraph 2.2. of this Appendix consisting of paragraphs 3.1.2.2. and 3.1.2.3. of this Appendix.
 3.2. 
For NOVC-HEVs and NOVC-FCHVs, one of the following test sequences according to Figure A8.App2/2 shall be used to measure all values that are necessary for the determination of the correction coefficients according to paragraph 2. of this Appendix.

Figure A8.App2/2 3.2.1.  3.2.1.1. 
The test vehicle shall be preconditioned and soaked according to paragraph 3.3.1. of this Sub-Annex.
 3.2.1.2. 
Prior to the test procedure, according to paragraph 3.2.1.3., the manufacturer may adjust the REESS. The manufacturer shall provide evidence that the requirements for the beginning of the test according to paragraph 3.2.1.3. are fulfilled.
 3.2.1.3.  3.2.1.3.1. The driver-selectable mode shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.2.1.3.2. For testing, the applicable WLTP test cycle according to paragraph 1.4.2. of this Sub-Annex shall be driven.
 3.2.1.3.3. Unless stated otherwise in this Appendix, the vehicle shall be tested according to the charge-sustaining Type 1 test procedure described in Sub-Annex 6.
 3.2.1.3.4. To obtain a set of applicable WLTP test cycles that are required for the determination of the correction coefficients, the test can be followed by a number of consecutive sequences required according to paragraph 2.2. of this Appendix consisting of paragraph 3.2.1.1. to paragraph 3.2.1.3. inclusive of this Appendix.
 3.2.2.  3.2.2.1. 
The test vehicle shall be preconditioned according to paragraph 3.3.1.1. of this Sub-Annex.
 3.2.2.2. 
After preconditioning, the soaking according to paragraph 3.3.1.2. of this Sub-Annex shall be omitted and a break, during which the REESS is permitted to be adjusted, shall be set to a maximum duration of 60 minutes. A similar break shall be applied in advance of each test. Immediately after the end of this break, the requirements of paragraph 3.2.2.3. of this Appendix shall be applied.

Upon request of the manufacturer, an additional warm-up procedure may be conducted in advance of the REESS adjustment to ensure similar starting conditions for the correction coefficient determination. If the manufacturer requests this additional warm-up procedure, the identical warm-up procedure shall be applied repeatedly within the test sequence.
 3.2.2.3.  3.2.2.3.1. The driver-selectable mode for the applicable WLTP test cycle shall be selected according to paragraph 3. of Appendix 6 to this Sub-Annex.
 3.2.2.3.2. For testing, the applicable WLTP test cycle according to paragraph 1.4.2. of this Sub-Annex shall be driven.
 3.2.2.3.3. Unless stated otherwise in this Appendix, the vehicle shall be tested according to the Type 1 test procedure described in Sub-Annex 6.
 3.2.2.3.4. To get a set of applicable WLTP test cycles that are required for the determination of the correction coefficients, the test can be followed by a number of consecutive sequences required according to paragraph 2.2. of this Appendix consisting of paragraphs 3.2.2.2. and 3.2.2.3. of this Appendix.

Sub-Annex 8 1.  1.1. This Appendix defines the method and required instrumentation to determine the REESS current and the REESS voltage of NOVC-HEVs, OVC-HEVs, PEVs and NOVC-FCHVs.
 1.2. Measurement of REESS current and REESS voltage shall start at the same time as the test starts and shall end immediately after the vehicle has finished the test.
 1.3. The REESS current and the REESS voltage of each phase shall be determined.
 1.4. 

((a)) the Type 1 test according to paragraph 3 of this Sub-Annex,
((b)) the procedure to determine the correction coefficients according to Appendix 2 of this Sub-Annex (where applicable),
((c)) the ATCT as specified in Sub-Annex 6a

shall be provided to the approval authority.
 2. 
REESS depletion is considered as a negative current.
 2.1.  2.1.1. The REESS current(s) shall be measured during the tests using a clamp-on or closed type current transducer. The current measurement system shall fulfil the requirements specified in Table A8/1 of this Sub-Annex. The current transducer(s) shall be capable of handling the peak currents at engine starts and temperature conditions at the point of measurement.
 2.1.2. 
In case of shielded wires, appropriate methods shall be applied in accordance with the approval authority.

In order to easily measure the REESS current using external measuring equipment, the manufacturer should provide appropriate, safe and accessible connection points in the vehicle. If that is not feasible, the manufacturer is obliged to support the approval authority in connecting a current transducer to one of the cables directly connected to the REESS in the manner described above in this paragraph.
 2.1.3. The current transducer output shall be sampled with a minimum frequency of 20 Hz. The measured current shall be integrated over time, yielding the measured value of Q, expressed in ampere-hours Ah. The integration may be done in the current measurement system.
 2.2. 
As an alternative to paragraph 2.1. of this Appendix, the manufacturer may use the on-board current measurement data. The accuracy of these data shall be demonstrated to the approval authority.
 3.  3.1. 
During the tests described in paragraph 3. of this Sub-Annex, the REESS voltage shall be measured with the equipment and accuracy requirements specified in paragraph 1.1. of this Sub-Annex. To measure the REESS voltage using external measuring equipment, the manufacturers shall support the approval authority by providing REESS voltage measurement points.
 3.2. 
For NOVC-HEVs, NOVC-FCHVs and OVC-HEVs, instead of using the measured REESS voltage according to paragraph 3.1. of this Appendix, the nominal voltage of the REESS determined according to DIN EN 60050-482 may be used.
 3.3. 
As an alternative to paragraph 3.1. and 3.2. of this Appendix, the manufacturer may use the on-board voltage measurement data. The accuracy of these data shall be demonstrated to the approval authority.

Sub-Annex 8 1. This Appendix describes the test procedure for REESS and combustion engine preconditioning in preparation for:

((a)) Electric range, charge-depleting and charge-sustaining measurements when testing OVC-HEVs; and
((b)) Electric range measurements as well as electric energy consumption measurements when testing PEVs.
 2.  2.1.  2.1.1. For preconditioning the combustion engine, the vehicle shall be driven over at least one applicable WLTP test cycle. During each driven preconditioning cycle, the charging balance of the REESS shall be determined. The preconditioning shall be stopped at the end of the applicable WLTP test cycle during which the break-off criterion is fulfilled according to paragraph 3.2.4.5. of this Sub-Annex.
 2.1.2. 
In such a case, a preconditioning procedure, such as that applicable to conventional vehicles as described in paragraph 1.2.6. of Sub-Annex 6, shall be applied.
 2.1.3. Soaking of the vehicle shall be performed according to paragraph 1.2.7. of Sub-Annex 6.
 2.2.  2.2.1. OVC-HEVs shall be driven over at least one applicable WLTP test cycle. During each driven preconditioning cycle, the charging balance of the REESS shall be determined. The preconditioning shall be stopped at the end of the applicable WLTP test cycle during which the break-off criterion is fulfilled according to paragraph 3.2.4.5. of this Sub-Annex.
 2.2.2. Soaking of the vehicle shall be performed according to paragraph 1.2.7. of Sub-Annex 6. Forced cooling down shall not be applied to vehicles preconditioned for the Type 1 test. During soak, the REESS shall be charged using the normal charging procedure as defined in paragraph 2.2.3. of this Appendix.
 2.2.3.  2.2.3.1. The REESS shall be charged at an ambient temperature as specified in paragraph 1.2.2.2.2. of Sub-Annex 6 either with:

((a)) The on-board charger if fitted; or
((b)) An external charger recommended by the manufacturer using the charging pattern prescribed for normal charging.
The procedures in this paragraph exclude all types of special charges that could be automatically or manually initiated, e.g. equalization charges or servicing charges. The manufacturer shall declare that, during the test, a special charge procedure has not occurred.
 2.2.3.2. 
The end-of-charge criterion is reached when the on-board or external instruments indicate that the REESS is fully charged.
 3.  3.1. 
Initial charging of the REESS consists of discharging the REESS and applying a normal charge.
 3.1.1. 
The discharge procedure shall be performed according to the manufacturer’s recommendation. The manufacturer shall guarantee that the REESS is as fully depleted as is possible by the discharge procedure.
 3.1.2. 
The REESS shall be charged according to paragraph 2.2.3.1. of this Appendix.

Sub-Annex 8 1. 
The database used to calculate the Utility Factors in paragraph 2. was predominantly based on the use characteristics (e.g. utilization, daily driven distance, shares of different vehicle classes) of conventional vehicles. It will be necessary to re-evaluate UF and charging frequencies by a customer study once a significant number of OVC-HEV vehicles are in use in the European market.
 2. 
UFidi=1− exp−∑j= 1kCj×didnj−∑l= 1i− 1UFl

Where:

UFiUtility factor for phase i.diDistance driven to the end of phase i in km.Cjjth coefficient (see Table A8.App5/1).dnNormalized distance (see Table A8.App5/1).kAmount of terms and coefficients in the exponent (see Table A8.App5/1).iNumber of considered phase.jNumber of considered term/coefficient.∑l= 1i− 1UFlSum of calculated utility factors up to phase (i-1).

The curve that is based on the following parameters in Table A8.App5/1 is valid from 0 km to the normalized distance dn where the UF converges to 1.0 (as can be seen in Figure A8/App5/1).


Table A8.App5/1
Parameter to be used in Equation y
C1 26,25
C2 -38,94
C3 -631,05
C4 5 964,83
C5 -25 094,6
C6 60 380,21
C7 -87 517,16
C8 75 513,77
C9 -35 748,77
C10 7 154,94
dn[km] 800
k 10
The curve shown below in Figure A8/App5/1 is provided for illustrative purposes only. It does not form part of the regulatory text.

Figure A8.App5/1
Sub-Annex 8 1.  1.1. The manufacturer shall select the driver-selectable mode for the Type 1 test procedure according to paragraph 2. to paragraph 4. inclusive of this Appendix which enables the vehicle to follow the considered test cycle within the speed trace tolerances according to paragraph 1.2.6.6. of Sub-Annex 6.
 1.2. 

((a)) the availability of a predominant mode under the considered conditions;
((b)) the maximum speed of the considered vehicle;
and if required:
((c)) the best and worst case mode identified by the evidence on the fuel consumption and, if applicable, on the CO2 mass emission in all modes (see Sub-Annex 6, paragraph 1.2.6.5.2.4.);
((d)) the highest electric energy consuming mode;
((e)) the cycle energy demand (according to paragraph 5. of Sub-Annex 7, where the target speed is replaced by the actual speed).
 1.3. Dedicated driver-selectable modes, such as ‘mountain mode’ or ‘maintenance mode’ which are not intended for normal daily operation but only for special limited purposes, shall not be considered.
 2. 
For vehicles equipped with a driver-selectable mode, the mode for the charge-depleting Type 1 test shall be selected according to the following conditions.

The flow chart in Figure A8.App6/1 illustrates the mode selection according to paragraph 2. of this Appendix.
 2.1. If there is a predominant mode that enables the vehicle to follow the reference test cycle under charge-depleting operating condition, this mode shall be selected.
 2.2. 

((a)) If there is only one mode which allows the vehicle to follow the reference test cycle under charge-depleting operating conditions, this mode shall be selected;
((b)) If several modes are capable of following the reference test cycle under charge-depleting operating conditions, the most electric energy consuming mode of those shall be selected.
 2.3. 

((a)) If there is a predominant mode which allows the vehicle to follow the modified reference test cycle under charge-depleting operating conditions, this mode shall be selected.
((b)) If there is no predominant mode but other modes which allow the vehicle to follow the modified reference test cycle under charge-depleting operating condition, the mode with the highest electric energy consumption shall be selected.
((c)) If there is no mode which allows the vehicle to follow the modified reference test cycle under charge-depleting operating condition, the mode or modes with the highest cycle energy demand shall be identified and the mode with the highest electric energy consumption shall be selected.

Figure A8.App6/1 3. 
For vehicles equipped with a driver-selectable mode, the mode for the charge-sustaining Type 1 test shall be selected according to the following conditions.

The flow chart in Figure A8.App6/2 illustrates the mode selection according to paragraph 3. of this Appendix.
 3.1. If there is a predominant mode that enables the vehicle to follow the reference test cycle under charge-sustaining operating condition, this mode shall be selected.
 3.2. 

((a)) If there is only one mode which allows the vehicle to follow the reference test cycle under charge-sustaining operating conditions, this mode shall be selected;
((b)) If several modes are capable of following the reference test cycle under charge-sustaining operating conditions, it shall be at the option of the manufacturer either to select the worst case mode or to select both best case mode and worst case mode and average the test results arithmetically.
 3.3. 

((a)) If there is a predominant mode which allows the vehicle to follow the modified reference test cycle under charge-sustaining operating condition, this mode shall be selected.
((b)) If there is no predominant mode but other modes which allow the vehicle to follow the modified reference test cycle under charge-sustaining operating condition, the worst case mode of these modes shall be selected.
((c)) If there is no mode which allows the vehicle to follow the modified reference test cycle under charge-sustaining operating condition, the mode or modes with the highest cycle energy demand shall be identified and the worst case mode shall be selected.

Figure A8.App6/2 4. 
For vehicles equipped with a driver-selectable mode, the mode for the test shall be selected according to the following conditions.

The flow chart in Figure A8.App 6/3 illustrates the mode selection according to paragraph 3. of this Appendix.
 4.1. If there is a predominant mode that enables the vehicle to follow the reference test cycle, this mode shall be selected.
 4.2. 

((a)) If there is only one mode which allows the vehicle to follow the reference test cycle, this mode shall be selected.
((b)) If several modes are capable of following the reference test cycle, the most electric energy consuming mode of those shall be selected.
 4.3. 

((a)) If there is a predominant mode which allows the vehicle to follow the modified reference test cycle, this mode shall be selected;
((b)) If there is no predominant mode but other modes which allow the vehicle to follow the modified reference test cycle, the mode with the highest electric energy consumption shall be selected;
((c)) If there is no mode which allows the vehicle to follow the modified reference test cycle, the mode or modes with the highest cycle energy demand shall be identified and the mode with the highest electric energy consumption shall be selected.

Figure A8.App6/3
Sub-Annex 8 1.  1.1. 
At the request of the manufacturer and with approval of the approval authority, fuel consumption may be measured using either the pressure method or the flow method. In this case, the manufacturer shall provide technical evidence that the method yields equivalent results. The pressure and flow methods are described in ISO23828.
 2. 
Fuel consumption shall be calculated by measuring the mass of the fuel tank before and after the test.
 2.1.  2.1.1. An example of the instrumentation is shown in Figure A8.App7/1. One or more off-vehicle tanks shall be used to measure the fuel consumption. The off-vehicle tank(s) shall be connected to the vehicle fuel line between the original fuel tank and the fuel cell system.
 2.1.2. For preconditioning, the originally installed tank or an external source of hydrogen may be used.
 2.1.3. The refuelling pressure shall be adjusted to the manufacturer’s recommended value.
 2.1.4. Difference of the gas supply pressures in lines shall be minimized when the lines are switched.
In the case that influence of pressure difference is expected, the manufacturer and approval authority shall agree whether correction is necessary or not.
 2.1.5.  2.1.5.1. 

Table A8.App7/1
Analytical balance verification criteria
Measurement Resolution (readability) Precision (repeatability)
Precision balance 0,1 g maximum 0,02 maximum
 2.1.5.2. 

Table A8.App7/2
Instrument calibration intervals
Instrument checks Interval
Precision (Repeatability) Yearly and at major maintenance 2.1.5.3. 
Figure A8.App7/1
where:


1 is the external fuel supply for preconditioning
2 is the pressure regulator
3 is the original tank
4 is the fuel cell system
5 is the precision balance
6 is/are off-vehicle tank(s) for fuel consumption measurement
 2.2.  2.2.1. The mass of the off-vehicle tank shall be measured before the test.
 2.2.2. The off-vehicle tank shall be connected to the vehicle fuel line as shown in Figure A8.App7/1.
 2.2.3. The test shall be conducted by fuelling from the off-vehicle tank.
 2.2.4. The off-vehicle tank shall be removed from the line.
 2.2.5. The mass of the tank after the test shall be measured.
 2.2.6. 
FCCS,nb=g1− g2d× 100

where:

FCCS,nbis the non-balanced charge-sustaining fuel consumption measured during the test, kg/100km;g1is the mass of the tank at the start of the test, kg;g2is the mass of the tank at the end of the test, kg;dis the distance driven during the test, km.

FCCS,nb,p

Sub-Annex 9
1. 
Upon request of the manufacturer, other measurement methods may be approved by the approval authority if they yield equivalent results in accordance with paragraph 1.1. of this Sub-Annex. The equivalence of the candidate method shall be demonstrated to the approval authority.
 1.1. 
A candidate method shall be considered equivalent if the accuracy and the precision is equal to or better than the reference method.
 1.2. 
The determination of method equivalency shall be based on a correlation study between the candidate and the reference methods. The methods to be used for correlation testing shall be subject to approval by the approval authority.

The basic principle for the determination of accuracy and precision of candidate and reference methods shall follow the guidelines in ISO 5725 Part 6 Annex 8 ‘Comparison of alternative Measurement Methods’.
 1.3. 
Reserved
