
Article 1 
The Annex to Decision 2006/771/EC is replaced by the text in the Annex to this Decision.
Article 2 
Decision 2006/804/EC is repealed with effect from 1 January 2018.
Article 3 
Member States shall report to the Commission on the implementation of this Decision by 2 May 2018 at the latest.
Article 4 
This Decision is addressed to the Member States.
Done at Brussels, 8 August 2017.
For the Commission
Mariya GABRIEL
Member of the Commission
ANNEX

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ANNEX 
Band no Frequency band [i] Category of short-range devices [ii] Transmit power limit/field strength limit/power density limit [iii] Additional parameters (channelling and/or channel access and occupation rules) [iv] Other usage restrictions [v] Implementation deadline
1 9-59,750 kHz Inductive devices [14] 72 dΒμΑ/m at 10 metres   1 July 2014
2 9-315 kHz Active medical implant devices [1] 30 dΒμΑ/m at 10 metres Duty cycle limit [vi]: 10 % This set of usage conditions is only available to active implantable medical devices [7]. 1 July 2014
3 59,750-60,250 kHz Inductive devices [14] 42 dΒμΑ/m at 10 metres   1 July 2014
4 60,250-74,750 kHz Inductive devices [14] 72 dBμA/m at 10 metres   1 July 2014
5 74,750-75,250 kHz Inductive devices [14] 42 dBμA/m at 10 metres   1 July 2014
6 75,250-77,250 kHz Inductive devices [14] 72 dBμA/m at 10 metres   1 July 2014
7 77,250-77,750 kHz Inductive devices [14] 42 dBμA/m at 10 metres   1 July 2014
8 77,750-90 kHz Inductive devices [14] 72 dBμA/m at 10 metres   1 July 2014
9 90-119 kHz Inductive devices [14] 42 dBμA/m at 10 metres   1 July 2014
10 119-128,6 kHz Inductive devices [14] 66 dBμA/m at 10 metres   1 July 2014
11 128,6-129,6 kHz Inductive devices [14] 42 dBμA/m at 10 metres   1 July 2014
12 129,6-135 kHz Inductive devices [14] 66 dBμA/m at 10 metres   1 July 2014
13 135-140 kHz Inductive devices [14] 42 dBμA/m at 10 metres   1 July 2014
14 140-148,5 kHz Inductive devices [14] 37,7 dΒμΑ/m at 10 metres   1 July 2014
15 148,5-5 000 kHz [17] Inductive devices [14] – 15 dΒμΑ/m at 10 metres in any bandwidth of 10 kHz.Furthermore the total field strength is – 5 dΒμΑ/m at 10 m for systems operating at bandwidths larger than 10 kHz   1 July 2014
17 400-600 kHz Radio Frequency Identification (RFID) devices [12] – 8 dΒμΑ/m at 10 metres   1 July 2014
18 456,9-457,1 kHz Non-specific short-range devices [3] 7 dBμA/m at 10 m  This set of usage conditions is only available for emergency detections of buried victims and valuable items devices. 1 July 2014
19 984-7 484 kHz Transport and Traffic Telematics devices [13] 9 dΒμΑ/m at 10 m Duty cycle limit [vi]: 1 % This set of usage conditions is only available for Eurobalise transmissions in the presence of trains and using the 27 MHz band for telepowering. 1 July 2014
20 3 155-3 400 kHz Inductive devices [14] 13,5 dΒμΑ/m at 10 metres   1 July 2014
21 5 000-30 000 kHz [18] Inductive devices [14] – 20 dΒμΑ/m at 10 metres in any bandwidth of 10 kHz. Furthermore the total field strength is – 5 dΒμΑ/m at 10 m for systems operating at bandwidths larger than 10 kHz   1 July 2014
22 6 765-6 795 kHz Inductive devices [14] 42 dΒμΑ/m at 10 metres   1 July 2014
23 7 300-23 000 kHz Transport and Traffic Telematics devices [13] – 7 dΒμΑ/m at 10 m Antenna restrictions apply that provide at least equivalent performance to the techniques described in the harmonised standards adopted under Directive 2014/53/EU. This set of usage conditions is only available for Euroloop transmissions in the presence of trains and using the 27 MHz band for telepowering. 1 July 2014
24 7 400-8 800 kHz Inductive devices [14] 9 dΒμΑ/m at 10 metres   1 July 2014
25 10 200-11 000 kHz Inductive devices [14] 9 dΒμΑ/m at 10 metres   1 July 2014
27a 13 553-13 567 kHz Inductive devices [14] 42 dΒμΑ/m at 10 metres   1 July 2014
27b 13 553-13 567 kHz Radio Frequency Identification (RFID) devices [12] 60 dΒμΑ/m at 10 metres The transmission mask and antenna requirements for all combined frequency segments have to provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU.  1 July 2014
27c 13 553-13 567 kHz Non-specific short-range devices [3] 42 dΒμΑ/m at 10 metres   1 July 2014
28 26 957-27 283 kHz Non-specific short-range devices [3] 10 mW effective radiated power (e.r.p.)   1 July 2014
29 26 990-27 000 kHz Non-specific short-range devices [3] 100 mW e.r.p. Duty cycle limit [vi]: 0,1 %.Model control devices may operate without duty cycle restrictions [11].  1 July 2014
30 27 040-27 050 kHz Non-specific short-range devices [3] 100 mW e.r.p. Duty cycle limit [vi]: 0,1 %.Model control devices may operate without duty cycle restrictions [11].  1 July 2014
31 27 090-27 100 kHz Non-specific short-range devices [3] 100 mW e.r.p. Duty cycle limit [vi]: 0,1 %.Model control devices may operate without duty cycle restrictions [11].  1 July 2014
32 27 140-27 150 kHz Non-specific short-range devices [3] 100 mW e.r.p. Duty cycle limit [vi]: 0,1 %.Model control devices may operate without duty cycle restrictions [11].  1 July 2014
33 27 190-27 200 kHz Non-specific short-range devices [3] 100 mW e.r.p. Duty cycle limit [vi]: 0,1 %.Model control devices may operate without duty cycle restrictions [11].  1 July 2014
34 30-37,5 MHz Active medical implant devices [1] 1 mW e.r.p. Duty cycle limit [vi]: 10 % This set of usage conditions is only available to ultra-low power medical membrane implants for blood pressure measurements within the definition of active implantable medical devices [7] in Directive 90/385/EEC. 1 July 2014
35 40,66-40,7 MHz Non-specific short-range devices [3] 10 mW e.r.p.   1 January 2018
36 87,5-108 MHz High duty cycle/continuous transmission devices [8] 50 nW e.r.p. Channel spacing up to 200 kHz. This set of usage conditions is only available to wireless audio and multimedia streaming transmitters with analogue frequency modulation (FM). 1 July 2014
37a 169,4-169,475 MHz Assistive Listening Devices (ALD) [4] 500 mW e.r.p. Channel spacing: max 50 kHz.  1 July 2014
37c 169,4-169,475 MHz Non-specific short-range devices [3] 500 mW e.r.p. Channel spacing: max 50 kHz. Duty cycle limit [vi]: 1,0 %. For metering devices [5], the duty cycle limit [vi] is 10,0 %  1 July 2014
38 169,4-169,4875 MHz Non-specific short-range devices [3] 10 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Duty cycle limit [vi]: 0,1 %.  1 July 2014
39a 169,4875-169,5875 MHz Assistive Listening Devices (ALD) [4] 500 mW e.r.p. Channel spacing: max 50 kHz.  1 July 2014
39b 169,4875-169,5875 MHz Non-specific short-range devices [3] 10 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Duty cycle limit [vi]: 0,001 %.Between 00:00h and 06:00h local time a duty cycle limit [vi] of 0,1 % may be used.  1 July 2014
40 169,5875-169,8125 MHz Non-specific short-range devices [3] 10 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Duty cycle limit [vi]: 0,1 %.  1 July 2014
82 173,965-216 MHz Assistive Listening Devices (ALD) [4] 10 mW e.r.p. On a tuning range basis [25]. Channel spacing: max 50 kHz. A threshold of 35 dBμV/m is required to ensure the protection of a DAB receiver located at 1,5 m from the ALD device, subject to DAB signal strength measurements taken around the ALD operating site. The ALD device should operate under all circumstances at least 300 kHz away from the channel edge of an occupied DAB channel.Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.  1 January 2018
41 401-402 MHz Active medical implant devices [1] 25 μW e.r.p. Channel spacing: 25 kHz. Individual transmitters may combine adjacent channels for increased bandwidth up to 100 kHz. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 0,1 % may also be used. This set of usage conditions is only available for systems specifically designed for the purpose of providing non-voice digital communications between active implantable medical devices [7] and/or body-worn devices and other devices external to the human body used for transferring non-time-critical individual patient-related physiological information. 1 July 2014
42 402-405 MHz Active medical implant devices [1] 25 μW e.r.p. Channel spacing: 25 kHz. Individual transmitters may combine adjacent channels for increased bandwidth up to 300 kHz. Other techniques to access spectrum or mitigate interference, including bandwidths greater than 300 kHz, can be used provided they result at least in an equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU to ensure compatible operation with the other users and in particular with meteorological radiosondes. This set of usage conditions is only available to active implantable medical devices [7]. 1 July 2014
43 405-406 MHz Active medical implant devices [1] 25 μW e.r.p. Channel spacing: 25 kHz Individual transmitters may combine adjacent channels for increased bandwidth up to 100 kHz. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 0,1 % may also be used. This set of usage conditions is only available for systems specifically designed for the purpose of providing non-voice digital communications between active implantable medical devices [7] and/or body-worn devices and other devices external to the human body used for transferring non-time-critical individual patient-related physiological information. 1 July 2014
44a 433,05-434,04 MHz Non-specific short-range devices [3] 1 mW e.r.p. and – 13 dBm/10 kHz power density for bandwidth modulation larger than 250 kHz Voice applications are allowed with advanced mitigation techniques. Audio and video applications are excluded. 1 July 2014
44b 433,05-434,04 MHz Non-specific short-range devices [3] 10 mW e.r.p. Duty cycle limit [vi]: 10 % Analogue audio applications other than voice are excluded. Analogue video applications are excluded. 1 July 2014
45a 434,04-434,79 MHz Non-specific short-range devices [3] 1 mW e.r.p. and – 13 dBm/10 kHz power density for bandwidth modulation larger than 250 kHz Voice applications are allowed with advanced mitigation techniques. Audio and video applications are excluded. 1 July 2014
45b 434,04-434,79 MHz Non-specific short-range devices [3] 10 mW e.r.p. Duty cycle limit [vi]: 10 % Analogue audio applications other than voice are excluded. Analogue video applications are excluded. 1 July 2014
45c 434,04-434,79 MHz Non-specific short-range devices [3] 10 mW e.r.p. Duty cycle limit [vi]: 100 % subject to channel spacing up to 25 kHz. Voice applications are allowed with advanced mitigation techniques. Audio and video applications are excluded. 1 July 2014
83 446,0-446,2 MHz PMR446 [21] 500 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.  1 January 2018
46a 863-865 MHz Non-specific short-range devices [3] 25 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 0,1 % may also be used.  1 January 2018
46b 863-865 MHz High duty cycle/continuous transmission devices [8] 10 mW e.r.p.  This set of usage conditions is only available to wireless audio and multimedia streaming devices. 1 July 2014
84 863-868 MHz Wideband data transmission devices [16] 25 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.Bandwidth: ≤ 1 MHz.Duty cycle [vi]: ≤ 10 % for network access points [26]Duty cycle [vi]: ≤ 2,8 % otherwise This set of usage conditions is only available for wideband SRDs in data networks [26]. 1 January 2018
47 865-868 MHz Non-specific short-range devices [3] 25 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 1 % may also be used. Analogue audio applications other than voice are excluded. Analogue video applications are excluded. 1 July 2014
47a 865-868 MHz Radio Frequency Identification (RFID) devices [12] 2 W e.r.p.Interrogator transmissions at 2 W e.r.p. are only permitted within the four channels centred at 865,7 MHz, 866,3 MHz, 866,9 MHz and 867,5 MHz; each with a maximum bandwidth of 200 kHz.RFID interrogator devices placed on the market before the repeal date of EC Decision 2006/804/EC are “grandfathered”, i.e. they are continuously permitted to be used in line with the provisions set out in EC Decision 2006/804/EC before the repeal date. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.  1 January 2018
47b 865-868 MHz Non-specific short-range devices [3] 500 mW e.r.p.Transmissions only permitted within the bands 865,6-865,8 MHz, 866,2-866,4 MHz, 866,8-867,0 MHz and 867,4-867,6 MHz.Adaptive Power Control (APC) required. Alternatively other mitigation technique with at least an equivalent level of spectrum compatibility. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.Bandwidth: ≤ 200 kHzDuty cycle [vi]: ≤ 10 % for network access points [26]Duty cycle [vi]: ≤ 2,5 % otherwise This set of usage conditions is only available for data networks [26]. 1 January 2018
48 868-868,6 MHz Non-specific short-range devices [3] 25 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 1 % may also be used. Analogue video applications are excluded. 1 July 2014
49 868,6-868,7 MHz Low duty cycle/high reliability devices [15] 10 mW e.r.p. Channel spacing: 25 kHz The whole frequency band may also be used as a single channel for high-speed data transmission.Duty cycle limit [vi]: 1,0 % This set of usage conditions is only available to alarm systems [22]. 1 July 2014
50 868,7-869,2 MHz Non-specific short-range devices [3] 25 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 0,1 % may also be used. Analogue video applications are excluded. 1 July 2014
51 869,2-869,25 MHz Low duty cycle/high reliability devices [15] 10 mW e.r.p. Channel spacing: 25 kHz. Duty cycle limit [vi]: 0,1 % This set of usage conditions is only available to social alarm devices [6]. 1 July 2014
52 869,25-869,3 MHz Low duty cycle/high reliability devices [15] 10 mW e.r.p. Channel spacing: 25 kHz Duty cycle limit [vi]: 0,1 % This set of usage conditions is only available to alarm systems [22]. 1 July 2014
53 869,3-869,4 MHz Low duty cycle/high reliability devices [15] 10 mW e.r.p. Channel spacing: 25 kHz Duty cycle limit [vi]: 1,0 % This set of usage conditions is only available to alarm systems [22]. 1 July 2014
54 869,4-869,65 MHz Non-specific short-range devices [3] 500 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a Duty cycle limit [vi] of 10 % may also be used. Analogue video applications are excluded. 1 July 2014
55 869,65-869,7 MHz Low duty cycle/high reliability devices [15] 25 mW e.r.p. Channel spacing: 25 kHz Duty cycle limit [vi]: 10 % This set of usage conditions is only available to alarm systems [22]. 1 July 2014
56a 869,7-870 MHz Non-specific short-range devices [3] 5 mW e.r.p. Voice applications allowed with advanced mitigation techniques. Audio and video applications are excluded. 1 July 2014
56b 869,7-870 MHz Non-specific short-range devices [3] 25 mW e.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Alternatively a duty cycle limit [vi] of 1 % may also be used. Analogue audio applications other than voice are excluded. Analogue video applications are excluded. 1 July 2014
57a 2 400-2 483,5 MHz Non-specific short-range devices [3] 10 mW equivalent isotropic radiated power (e.i.r.p.)   1 July 2014
57b 2 400-2 483,5 MHz Radio determination devices [9] 25 mW e.i.r.p.   1 July 2014
57c 2 400-2 483,5 MHz Wideband data transmission devices [16] 100 mW e.i.r.p. and 100 mW/100 kHz e.i.r.p. density applies when frequency hopping modulation is used, 10 mW/MHz e.i.r.p. density applies when other types of modulation are used Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.  1 July 2014
58 2 446-2 454 MHz Radio Frequency Identification (RFID) devices [12] 500 mW e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used.  1 July 2014
59 2 483,5-2 500 MHz Active medical implant devices [1] 10 mW e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Channel spacing: 1 MHz. The whole frequency band may also be used dynamically as a single channel for high-speed data transmissions. In addition, a duty cycle limit [vi] of 10 % applies. This set of usage conditions is only available to active implantable medical devices [7].Peripheral master units are for indoor use only. 1 July 2014
59a 2 483,5-2 500 MHz Medical data acquisition [20] 1 mW e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Modulation Bandwidth: ≤ 3 MHz. In addition, aduty cycle [vi]: ≤ 10 % applies. The set of usage conditions is only available for medical body area network system (MBANS) [23] for indoor use within healthcare facilities 1 January 2018
59b 2 483,5-2 500 MHz Medical data acquisition [20] 10 mW e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Modulation Bandwidth: ≤ 3 MHz. In addition, aduty cycle [vi]: ≤ 2 % applies. The set of usage conditions is only available for medical body area network system (MBANS) [23] for indoor use within the patient's home 1 January 2018
60 4 500-7 000 MHz Radio determination devices [9] 24 dBm e.i.r.p. [19] Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Tank Level Probing Radar [10]. 1 July 2014
61 5 725-5 875 MHz Non-specific short-range devices [3] 25 mW e.i.r.p.   1 July 2014
62 5 795-5 815 MHz Transport and Traffic Telematics devices [13] 2 W e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions applies only to road tolling applications. 1 January 2018
63 6 000-8 500 MHz Radio determination devices [9] 7 dBm/50 MHz peak e.i.r.p. and – 33 dBm/MHz mean e.i.r.p. Automatic power control and antenna requirements as well as equivalent techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Level Probing Radar.Established exclusion zones around radio astronomy sites must be obeyed. 1 July 2014
64 8 500-10 600 MHz Radio determination devices [9] 30 dBm e.i.r.p. [19] Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Tank Level Probing Radar [10]. 1 July 2014
65 17,1-17,3 GHz Radio determination devices [9] 26 dBm e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to ground-based systems. 1 July 2014
66 24,05-24,075 GHz Transport and Traffic Telematics devices [13] 100 mW e.i.r.p.   1 July 2014
67 24,05-26,5 GHz Radio determination devices [9] 26 dBm/50 MHz peak e.i.r.p. and – 14 dBm/MHz mean e.i.r.p. Automatic power control and antenna requirements as well as equivalent techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Level Probing Radar.Established exclusion zones around radio astronomy sites must be obeyed. 1 July 2014
68 24,05-27 GHz Radio determination devices [9] 43 dBm e.i.r.p. [19] Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Tank Level Probing Radar [10]. 1 July 2014
69a 24,075-24,15 GHz Transport and Traffic Telematics devices [13] 100 mW e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Dwell time limits and frequency modulation range apply as specified in harmonised standards. This set of usage conditions is only available to ground-based vehicle radars. 1 July 2014
69b 24,075-24,15 GHz Transport and Traffic Telematics devices [13] 0,1 mW e.i.r.p.   1 July 2014
70a 24,15-24,25 GHz Non-specific short-range devices [3] 100 mW e.i.r.p.   1 July 2014
70b 24,15-24,25 GHz Transport and Traffic Telematics devices [13] 100 mW e.i.r.p.   1 July 2014
71 24,25-24,495 GHz Transport and Traffic Telematics devices [13] – 11 dBm e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Duty cycle limits [vi] and frequency modulation ranges apply as specified in harmonised standards. This set of usage conditions is only available to ground-based vehicle radars operating in the harmonised 24 GHz frequency range. 1 July 2014
72 24,25-24,5 GHz Transport and Traffic Telematics devices [13] 20 dBm e.i.r.p. (forward-facing radars) 16 dBm e.i.r.p. (rear-facing radars) Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Duty cycle limits [vi] and frequency modulation range apply as specified in harmonised standards. This set of usage conditions is only available to ground-based vehicle radars operating in the harmonised 24 GHz frequency range. 1 July 2014
73 24,495-24,5 GHz Transport and Traffic Telematics devices [13] – 8 dBm e.i.r.p. Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Duty cycle limits [vi] and frequency modulation range apply as specified in harmonised standards. This set of usage conditions is only available to ground-based vehicle radars operating in the harmonised 24 GHz frequency range. 1 July 2014
74a 57-64 GHz Non-specific short-range devices [3] 100 mW e.i.r.p., a maximum transmit power of 10dBm and a maximum e.i.r.p. power spectral density of 13dBm/MHz   1 July 2014
74b 57-64 GHz Radio determination devices [9] 43 dBm e.i.r.p. [19] Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Tank Level Probing Radar [10]. 1 July 2014
74c 57-64 GHz Radio determination devices [9] 35 dBm/50 MHz peak e.i.r.p. and – 2 dBm/MHz mean e.i.r.p. Automatic power control and antenna requirements as well as equivalent techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Level Probing Radar. 1 July 2014
75 57-66 GHz Wideband data transmission devices [16] 40 dBm e.i.r.p. and 13 dBm/MHz e.i.r.p. density Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. Fixed outdoor installations are excluded. 1 July 2014
76 61-61,5 GHz Non-specific short-range devices [3] 100 mW e.i.r.p.   1 July 2014
77 63-64 GHz Transport and Traffic Telematics devices [13] 40 dBm e.i.r.p.  This set of usage conditions is only available to vehicle-to-vehicle, vehicle-to-infrastructure and infrastructure-to-vehicle systems. 1 July 2014
78a 75-85 GHz Radio determination devices [9] 34dBm/50 MHz peak e.i.r.p. and – 3 dBm/MHz mean e.i.r.p. Automatic power control and antenna requirements as well as equivalent techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Level Probing Radar.Established exclusion zones around radio astronomy sites must be obeyed. 1 July 2014
78b 75-85 GHz Radio determination devices [9] 43 dBm e.i.r.p. [19] Techniques to access spectrum and mitigate interference that provide at least equivalent performance to the techniques described in harmonised standards adopted under Directive 2014/53/EU must be used. This set of usage conditions is only available to Tank Level Probing Radar [10]. 1 July 2014
79a 76-77 GHz Transport and Traffic Telematics devices [13] 55 dBm peak e.i.r.p. and 50 dBm mean e.i.r.p. and 23,5 dBm mean e.i.r.p. for pulse radars  This set of usage conditions is only available to ground-based vehicle and infrastructure systems. 1 July 2014
79b 76-77 GHz Transport and Traffic Telematics devices [13] 30 dBm peak e.i.r.p. and3 dBm/MHz average power spectral density Duty cycle limit [vi]: ≤ 56 %/s This set of usage conditions is only available to obstacle detection systems for rotorcraft use [24]. 1 January 2018
80a 122-122,25 GHz Non-specific short-range devices [3] 10 dBm e.i.r.p/250 MHz and– 48 dBm/MHz at 30° elevation   1 January 2018
80b 122,25-123 GHz Non-specific short-range devices [3] 100 mW e.i.r.p.   1 January 2018
81 244-246 GHz Non-specific short-range devices [3] 100 mW e.i.r.p.   1 July 2014
[i] Member States must allow adjacent frequency bands within this table to be used as a single frequency band provided the specific conditions of each of these adjacent frequency bands are met.
[ii] As defined in Article 2(3)
[iii] Member States must allow the usage of spectrum up to the transmit power, field strength or power density given in this table. In accordance with Article 3(3), they may impose less restrictive conditions, i.e. allow the use of spectrum with higher transmit power, field strength or power density, provided that this does not reduce or compromise the appropriate coexistence between short-range devices in bands harmonised by this Decision.
[iv] Member States may only impose these “additional parameters (channelling and/or channel access and occupation rules)”, and shall not add other parameters or spectrum access and mitigation requirements. Less restrictive conditions within the meaning of Article 3(3), mean that Member States may completely omit the “additional parameters (channelling and/or channel access and occupation rules)” in a given cell or allow higher values, provided that the appropriate sharing environment in the harmonised band is not compromised.
[v] Member States may only impose these “other usage restrictions” and shall not add additional usage restrictions. As less restrictive conditions may be introduced within the meaning of Article 3(3), Member States may omit one or all of these restrictions, provided that the appropriate sharing environment in the harmonised band is not compromised.
[vi] “Duty cycle” is defined as the ratio, expressed as a percentage, of Σ(Ton)/(Tobs) where Ton is the “on” time of a single transmitter device and Tobs is the observation period. Ton is measured in an observation frequency band (Fobs). Unless otherwise specified in this technical annex, Tobs is a continuous one hour period and Fobs is the applicable frequency band in this technical annex. Less restrictive conditions within the meaning of Article 3(3), mean that Member States may allow a higher value for “duty cycle”.
[1] The active medical implant device category covers the radio part of active implantable medical devices that are intended to be totally or partially introduced, surgically or medically, into the human body or that of an animal, and where applicable their peripherals.
[3] The non-specific short-range device category covers all kinds of radio devices, regardless of the application or the purpose, which fulfil the technical conditions as specified for a given frequency band. Typical uses include telemetry, telecommand, alarms, data transmissions in general and other applications.
[4] The assistive listening device (ALD) category covers radio communications systems that allow persons suffering from hearing disability to increase their listening capability. Typical system installations include one or more radio transmitters and one or more radio receivers.
[5] The metering device category covers radio devices that are part of bidirectional radio communications systems which allow remote monitoring, measuring and transmission of data in smart grid infrastructures, such as electricity, gas and water.
[6] “Social alarm devices” are radio communications systems that allow reliable communication for a person in distress in a confined area to initiate a call for assistance. Typical uses of social alarm are to assist elderly or disabled people.
[7] “Active implantable medical devices” as defined in Council Directive 90/385/EEC of 20 June 1990 on the approximation of the laws of the Member States relating to active implantable medical devices (OJ L 189, 20.7.1990, p. 17).
[8] The high duty cycle/continuous transmission device category covers radio devices that rely on low latency and high duty cycle transmissions. Typical uses are for personal wireless audio and multimedia streaming systems used for combined audio/video transmissions and audio/video sync signals, mobile phones, automotive or home entertainment system, wireless microphones, cordless loudspeakers, cordless headphones, radio devices carried on a person, assistive listening devices, in-ear monitoring, wireless microphones for use at concerts or other stage productions, and low power analogue FM transmitters (band 36).
[9] The radio determination device category covers radio devices that are used for determining the position, velocity and/or other characteristics of an object, or for obtaining information relating to these parameters. Radiodetermination equipment typically conducts measurements to obtain such characteristics. Any kind of point-to-point or point-to-multipoint radio communications is outside of this definition.
[10] “Tank Level Probing Radar” (TLPR) is a specific type of radiodetermination application, which is used for tank level measurements and is installed in metallic or reinforced concrete tanks, or similar structures made of material with comparable attenuation characteristics. The purpose of the tank is to contain a substance.
[11] “Model control devices” are a specific kind of telecommand and telemetry radio equipment that is used to remotely control the movement of models (principally miniature representations of vehicles) in the air, on land or over or under the water surface.
[12] The radio frequency identification (RFID) device category covers tag/interrogator based radio communications systems, consisting of radio devices (tags) attached to animate or inanimate items and of transmitter/receiver units (interrogators) which activate the tags and receive data back. Typical uses include the tracking and identification of items, such as for electronic article surveillance (EAS), and collecting and transmitting data relating to the items to which tags are attached, which may be either battery-less, battery assisted or battery powered. The responses from a tag are validated by its interrogator and passed to its host system.
[13] The transport and traffic telematics device category covers radio devices that are used in the fields of transport (road, rail, water or air, depending on the relevant technical restrictions), traffic management, navigation, mobility management and in intelligent transport systems (ITS). Typical applications are used for interfaces between different modes of transport, communication between vehicles (e.g. car to car), between vehicles and fixed locations (e.g. car to infrastructure) as well as communication from and to users.
[14] The inductive device category covers radio devices that use magnetic fields with inductive loop systems for near field communications. Typical uses include devices for car immobilisation, animal identification, alarm systems, cable detection, waste management, personal identification, wireless voice links, access control, proximity sensors, anti-theft systems, including RF anti-theft induction systems, data transfer to hand-held devices, automatic article identification, wireless control systems and automatic road tolling.
[15] The low duty cycle/high reliability device category covers radio devices that rely on low overall spectrum utilisation and low duty cycle spectrum access rules to ensure highly reliable spectrum access and transmissions in shared bands. Typical uses include alarm systems that use radio communication for indicating an alert condition at a distant location and social alarms systems that allow reliable communication for a person in distress.
[16] The wideband data transmission device category covers radio devices that use wideband modulation techniques to access the spectrum. Typical uses include wireless access systems such as radio local area networks (WAS/RLANs) or wideband SRDs in data networks.
[17] In band 20 higher field strengths and additional usage restrictions apply for inductive applications.
[18] In bands 22, 24, 25, 27a, and 28 higher field strengths and additional usage restrictions apply for inductive applications.
[19] The power limit applies inside a closed tank and corresponds to a spectral density of – 41,3 dBm/MHz e.i.r.p. outside a 500 litre test tank.
[20] The medical data acquisition category covers the transmission of non-voice data to and from non-implantable medical devices for the purpose of monitoring, diagnosing and treating patients in healthcare facilities or patient's home.
[21] PMR446 equipment is hand portable (no base station or repeater use) and uses integral antennas only in order to maximise sharing and minimise interference. PMR 446 equipment operates in short range peer-to-peer mode and shall be used neither as a part of infrastructure network nor as a repeater;
[22] An alarm system is a device which uses radio communication support for indicating an alert to a system or a person, as a main functionnality, at a distant location when a problem or a specific situation occurs. Radio alarms include social alarms and alarms for security and safety.
[23] Medical Body Area Network Systems (MBANSs), used for medical data acquisition, are intended to be used in healthcare facilities and patients' homes. They are low power radio systems used for the transmission of non-voice data to and from medical devices for the purposes of monitoring, diagnosing and treating patients as prescribed by duly authorised healthcare professionals and are defined in the context of medical applications only;
[24] Member States can specify exclusion zones or equivalent measures in which the obstacle detection application for rotorcraft use shall not be used for the protection of the radioastronomy service or other national use. Rotorcraft is defined as EASA CS-27 and CS-29 (resp. JAR-27 and JAR-29 for former certifications);
[25] Devices shall implement the whole frequency range on a tuning range basis.
[26] A network access point in a data network is a fixed terrestrial short range device that acts as a connection point for the other short range devices in the data network to service platforms located outside of that data network. The term data network refers to several short range devices, including the network access point, as network components and to the wireless connections between them.'
