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ATIS 0700019-2015 RF Minimum Performance of WGPRS Indoor Bearer.pdf

1、 ATIS-0700019 ATIS Standard on - RF MINIMUM PERFORMANCE OF WGPRS INDOOR BEARER As a leading technology and solutions development organization, the Alliance for Telecommunications Industry Solutions (ATIS) brings together the top global ICT companies to advance the industrys most pressing business pr

2、iorities. ATIS nearly 200 member companies are currently working to address the All-IP transition, network functions virtualization, big data analytics, cloud services, device solutions, emergency services, M2M, cyber security, network evolution, quality of service, billing support, operations, and

3、much more. These priorities follow a fast-track development lifecycle from design and innovation through standards, specifications, requirements, business use cases, software toolkits, open source solutions, and interoperability testing. ATIS is accredited by the American National Standards Institut

4、e (ANSI). The organization is the North American Organizational Partner for the 3rd Generation Partnership Project (3GPP), a founding Partner of the oneM2M global initiative, a member of and major U.S. contributor to the International Telecommunication Union (ITU), as well as a member of the Inter-A

5、merican Telecommunication Commission (CITEL). For more information, visit www.atis.org. Notice of Disclaimer GPRS Radio Interface Stage 2“.1 3a 3GPP TS 43.071: “Location Services (LCS); Functional description Stage 2”.1 4 3GPP TS 45.001: “Physical layer on the radio path; General description“.1 1Thi

6、s document is available from the Third Generation Partnership Project (3GPP) at . ATIS-0700019 2 5 3GPP TS 45.004: “Modulation“.1 6 3GPP TS 45.008: “Radio subsystem link control“.1 7 3GPP TS 45.010: “Radio subsystem synchronization“.1 8 3GPP TS 51.010-1: “Mobile Station (MS) conformance specificatio

7、n Part 1: Conformance Specification“.1 9 3GPP TS 51.011: “Specification of the Subscriber Identity Module - Mobile Equipment (SIM - ME) interface“.1 10 ITU-T (formerly CCITT) Recommendation O.153: “Basic parameters for the measurement of error performance at bit rates below the primary rate“.211 ETS

8、 300 019-1-3: “Equipment Engineering (EE); Environmental conditions and environmental tests for telecommunications equipment; Part 1-3: Classification of environmental conditions Stationary use at weather protected locations“.312 ETS 300 019-1-4: “Equipment Engineering (EE); Environmental conditions

9、 and environmental tests for telecommunications equipment; Part 1-4: Classification of environmental conditions Stationary use at non-weather protected locations“.3 13 3GPP TS 44.014: Individual equipment type requirements and interworking; Special conformance testing functions”.1 14 ATIS-1000610, G

10、eneric Procedures for Supplementary Services, 1990.415 3GPP TS 43.052: “GSM Cordless Telephony System (CTS); Phase 1; Lower layers of the CTS radio interface; Stage 2“.116 3GPP TS 45.005, Radio Transmission and Reception 1.2 Abbreviations Abbreviations used in this document are listed in 3GPP TR 21.

11、905. 1.3 Acronyms 8-PSK 8-ary Phase Shift Keying ARFCN Absolute Radio-Frequency Channel Number ATIS Alliance for Telecommunications Industry Solutions BLER Block Error Rate BSS Base Station System BTS Base Transceiver Station C/I Carrier to Interference Ratio 2This document is available from the Int

12、ernational Telecommunications Union. 3This document is available from the European Committee for Electrotechnical Standardization (CENELEC). 4This document is available from the Alliance for Telecommunications Industry Solutions (ATIS) at . ATIS-0700019 3 CW Continuous Wave DMAC Digital Mobile Atten

13、uation Code DRx Discontinuous Reception DTx Discontinuous Transmission ERP Effective Radiated Power FH Frequency Hopping GMSK Gaussian Minimum Shift Keying HS High Speed MAC Mobile Attenuation Code micro-BTS microcell Base Transceiver Station MS Mobile Station NER Nominal Error Rates O-QAM Offset Qu

14、adrature Ampitude Modulation PCS 8 PSK Coding Scheme pico-BTS picocell Base Transceiver Station PL Power Level RF Radio Frequency SFH Slow Frequency Hopping VMAC Voice Mobile Attenuation Code WGPRS Wideband General Packet Radio Service WTSC Wireless Technologies and Systems Committee 2 Frequency Ban

15、ds while the change from level 7 to level 8 uses the bottom row criteria. 4.1.1.2 1900 MHz The mean ERP of the mobile station is shown in the table below. The manufacturer should recommend the net power gain or loss of the antenna system to be installed with the mobile station such that the power me

16、asured at the transmitter output terminals can be directly related to the required ERP (typical antenna systems have 2.5 dB gain with respect to a half-wave dipole and 1.5 dB cable loss). The station class indicated by the mobile station at the beginning of any call will be assumed by the system to

17、be maintained throughout that call. ATIS-0700019 7 Table 4.3 Mobile Station Nominal Power Levels Mobile Station Power Level (PL) Mobile Attenuation Code (MAC) Nominal ERP(dBW) for Mobile Station Power Class (see Note 4) II III IV 0 0000 0.0 -2 1 0001 0.0 -2 2 0010 -2 -2 3 0011 -6 -6 4 0100 -10 -10 5

18、 0101 -14 -14 6 0110 -18 -18 7 0111 -22 -22 8 1000 -284dB -284dB 9 1001 -335dB -335dB 10 1010 -386dB -386dB NOTE 1: The three least significant bits of MAC are used in the VMAC field. All four bits of MAC are used in the DMAC field. NOTE 2: The output powers shown above shall be maintained within th

19、e range of +2 dB, -4 dB of nominal value for Power Levels 0 7, and within +2 dB, -6 dB of the nominal value for Power Levels 8 10 (see Note 3). NOTE 3: The Nominal Output Power for levels 8, 9, and 10 are expressed as a range, rather than an absolute value. When the mobile station changes to one of

20、these power levels, it shall insure that it stabilizes within the range centered around the target value for that level. For example, the target value for power level 8 in the 1900 MHz operating band is -28dBW. The mobile station is considered to be within the requirement provided it stabilizes with

21、in 4dB of this target level. Once the mobile station has stabilized, the operating tolerance is applied to the specific value within the nominal range on which the mobile station stabilized. NOTE 4: The Nominal ERP values in watts for power level 0 are: Class Power Level II. +0 dBW = 1.0 W III. Rese

22、rved IV. -2 dBW = 0.6 W NOTE 5: Only Power Class IV is applicable to the Indoor. ATIS-0700019 8 Table 4.4 Relative Step Accuracy vs. Power Level on a Single Channel Mobile Station Power Class II Levels (PL) Mobile Station Power Class IV Levels (PL) Step Between Successive Power Levels (dB) 0 7 2 7 4

23、 1 - 7 10 4 2 When the mobile station changes from power level X to power level X+1, it shall satisfy the requirements for the Nominal Output Power for that level. Additionally, the mobile station shall satisfy the requirements identified for the Relative Step Accuracy going into the X+1 Power Level

24、. Thus, the mobile station shall reduce its power such that it conforms to the Nominal level, with a reduction in power at least as great as the minimum specified by the Relative Step requirement. 4.1.2 Base Station The micro-BTS maximum output power per carrier measured at the antenna connector aft

25、er all stages of combining shall be, according to its class, defined in the following table. Table 4.5 Micro-BTS Maximum Output Power per Carrier 800 MHz micro and pico-BTS 1900 MHz micro and pico-BTS TRX power class Maximum output power TRX power class Maximum output power Micro Micro M1 ( 19) - 24

26、 dBm M1 ( 27) - 32 dBm M2 ( 14) - 19 dBm M2 ( 22) - 27 dBm M3 ( 9) - 14 dBm M3 ( 17) - 22 dBm Pico Pico P1 ( 13) - 20 dBm P1 ( 16) - 23 dBm For BTS supporting 8-PSK, the manufacturer shall declare the output power capability at 8-PSK modulation. For BTS supporting Offset Quadrature Ampitude Modulati

27、on (O-QAM), the manufacturer shall declare the output power capability at O-QAM modulation. The class of a micro-BTS or a pico-BTS is defined by the highest output power capability for either modulation and the output power shall not exceed the maximum output power of the corresponding class. The to

28、lerance of the actual maximum output power of the BTS shall be 2 dB under normal conditions and 2.5 dB under extreme conditions. Settings shall be provided to allow the output power to be reduced from its maximum level in at least six steps of nominally 2 dB with an accuracy of 1 dB to allow a fine

29、adjustment of the coverage by the network operator. In addition, the actual absolute output power at each static RF power step (N) shall be 2*N dB below the absolute output power at static RF power step 0 with a tolerance of 3 dB under normal conditions and 4 dB under extreme conditions. The static

30、RF power step 0 shall be the actual output power according to the TRX power class. As an option the BSS can utilize downlink RF power control. In addition to the static RF power steps described above, the BSS may then utilize up to 15 steps of power control levels with a step size of 2 dB 1.5 dB, in

31、 addition the actual absolute output power at each power control level (N) shall be 2*N dB ATIS-0700019 9 below the absolute output power at power control level 0 with a tolerance of 3 dB under normal conditions and 4 dB under extreme conditions. The power control level 0 shall be the set output pow

32、er according to the TRX power class and the six power settings defined above. Network operators or manufacturers may also specify the BTS output power including any Tx combiner, according to their needs. 4.1.2.1 Additional Requirements for 1900 MHz Base Stations The BTS transmitter maximum rated out

33、put power per carrier, measured at the input of the transmitter combiner, shall be, according to its TRX power class, as defined in Table 4.5. The base station output power may also be specified by the manufacturer or system operator at a different reference point (e.g., after transmitter combining)

34、. 4.1.2.2 Additional Requirements for 800 MHz Base Stations The BTS transmitter maximum rated output power per carrier, measured at the input of the transmitter combiner, shall be, according to its TRX power class, as defined in Table 4.5. The base station output power may also be specified by the m

35、anufacturer or system operator at a different reference point (e.g., after transmitter combining). 4.2 Output RF Spectrum The specifications contained in this section apply to both BTS and MS, in frequency hopping as well as in non frequency hopping mode, except that beyond 1800 kHz offset from the

36、carrier the BTS is not tested in frequency hopping mode. Due to the bursty nature of the signal, the output RF spectrum results from two effects: the modulation process; and the power ramping up and down (switching transients). The two effects are specified separately; the measurement method used to

37、 analyse separately those two effects is specified in 3GPP TS 51.010-1 and 51.021. It is based on the “ringing effect“ during the transients, and is a measurement in the time domain, at each point in frequency. The limits specified thereunder are based on a 5-pole synchronously tuned measurement fil

38、ter. Unless otherwise stated, for the BTS, only one transmitter is active for the tests of this section. 4.2.1 Spectrum Due to the Modulation A continuous, static sine wave signal at a level as in the table below and at a frequency (f) which is an integer multiple of 1.6 MHz. ATIS-0700019 18 With th

39、e following exceptions, called spurious response frequencies: a) 800 MHz: in band, for a maximum of six occurrences (which if grouped shall not exceed three contiguous occurrences per group); 1900 MHz: in band, for a maximum of twelve occurrences (which if grouped shall not exceed three contiguous o

40、ccurrences per group); b) Out of band, for a maximum of 24 occurrences (which if below f0and grouped shall not exceed three contiguous occurrences per group). Where the above performance shall be met when the continuous sine wave signal (f) is set to a level of 70 dBV (emf) (i.e., -43 dBm). Table 5.

41、3 Spurious Response for 800 MHz and 1900 MHz Frequency Band 800 MHz 1900 MHz MS BTS MS BTS dBV dBm dBV dBm dBV dBm dBV dBm (emf) (emf) (emf) (emf) Indoor 1.6 MHz bandwidth: 4.8 MHz |f-fo| 16 MHz, which is an integer multiple of 1.6 MHz, a GSM TDMA signal modulated in GMSK and by any 148-bit sequence

42、 (O-QAM modulated signal, 144-bit sequence, Short burst at Indoor) of the 511-bit pseudo random bit sequence, defined in ITU-T Recommendation O.153, at a level as defined in the table below. The interferer shall have one timeslot active and the frequency shall be at least 2 channels separated from a

43、ny identified spurious response. The transmitted bursts shall be synchronized to but delayed in time between 61 and 86 bit periods relative to the bursts of the wanted signal. NOTE 1: When testing this requirement, a notch filter may be necessary to ensure that the co-channel performance of the rece

44、iver is not compromised. Micro and pico-BTS MS BTS M1 M2 M3 P1 (dBm) (dBm) (dBm) (dBm) (dBm) (dBm) 800 MHz -31 -35 -34 -29 -24 -21 1900 MHz -29 -33 -33 -28 -23 -26 5.3 Intermodulation Characteristics The reference sensitivity performance as specified in table 6.1 shall be met when the following sign

45、als are simultaneously input to the receiver: A useful signal at frequency fo, 3 dB above the reference sensitivity level as specified in section 6.2; A continuous, static sine wave signal at frequency f1and a level of 70 dBV (emf) (i.e., -43 dBm): ATIS-0700019 20 For 1900 MHz MS and 1900 MHz BTS th

46、is value is relaxed to 64 dBV (emf) (i.e., -49 dBm); Any 148-bits subsequence (O-QAM modulated signal, 144-bit sequence, Short burst at Indoor) of the 511-bits pseudo-random sequence, defined in ITU-T Recommendation O.153 modulating a signal at frequency f2, and a level of 70 dBV (emf) (i.e., -43 dB

47、m): For 1900 MHz MS and 1900 MHz BTS this value is relaxed to 64 dBV (emf) (i.e., -49 dBm); Such that f0= 2f1- f2and |f2-f1| = 800 kHz (|f2-f1| = 6.4 MHz). NOTE 1: For sections 5.2 and 5.3 instead of any 148-bits subsequence of the 511-bits pseudo-random sequence, defined in ITU-T Recommendation O.1

48、53, it is also allowed to use a more random pseudo-random sequence. 5.4 Spurious Emissions The spurious emissions for a BTS receiver, measured in the conditions specified in section 4.3.1, shall be no more than: 2 nW (-57 dBm) in the frequency band 9 kHz - 1 GHz; and 20 nW (-47 dBm) in the frequency

49、 band 1 - 12.75 GHz. NOTE 1: For radiated spurious emissions for the BTS, the specifications currently only apply to the frequency band 30 MHz to 4 GHz. The specification and method of measurement outside this band are under consideration. 6 Transmitter/Receiver Performance In order to assess the error rate performance that is described in this section it is required for a mobile equipment to have a “loop back“ facility by which the equipment transmits back the same i

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