24--2 3P8658-F27 2 (2) Table of contents Description of the test object ppendix Operation mode during measurements ppendix Test setups ppendix Purpose of test ppendix RF power output conducted ppendix 2 Occupied bandwidth ppendix 3 Band edge ppendix 4 Spurious emission at antenna terminals ppendix 5 Field strength of spurious radiation ppendix 6 Frequency stability ppendix 7 External photos ppendix 8
Date Reference 24--2 3P8658-F27 Page (8)) ppendix Description of the testt object Equipment: Tested configuration: Frequency bands: ntenna ports: Product name: RRUS E2 B29 Product number: KRC 6 48/, 4 R FCCC ID T8KRC648- IC 287B-S648 IC MODEL NO: S648 LTEE single RT TX: : 77 728 MHz RX: : N/ 2 TXX ports RF configuration: Single carrier, multi carrier and a MIMO mode 2x2 Nominal output power per antenna port: Single carrier: Multi carrier: x 46. dbm ( x 4W) 2x 43. dbm (2 x 2W) ntenna: Channel bandwidths: Modulations: Nominal supply voltage: No dedicated antenna, handled during licensing 3 MHz, 5 MHz and MHzz QPSK, 6QM and 64QM -48VDC
24--2 3P8658-F27 2 (8) ppendix Operation mode during measurements Measurements were performed with the test object transmitting test models as defined in 3GPP TS 36.4. Test model E-TM. represent QPSK modulation, test model E-TM3.2 represent 6QM modulation and test model E-TM3. represent 64QM modulation. The settings below were deemed representative for all traffic scenarios when settings with different modulations, channel bandwidths, number of carriers and RF configurations has been tested to find the worst case setting. ll measurements were performed with the test object configured for maximum transmit power. The settings below were used for all measurements if not otherwise noted. MIMO mode, single carrier: E-TM. MIMO mode, multi carrier: 2 carriers E-TM. Conducted measurements The test object was supplied with -48 VDC by an external power supply if not noted otherwise. dditional connections are documented in the setup drawings below. Complete measurements were made on RF with additional measurements on RF B to verify that the ports are identical. Radiated measurements The test object was supplied with -48 VDC by an external power supply. dditional connections are documented in the setup drawings below. Purpose of test The purpose of the tests is to verify compliance to the performance characteristics specified in applicable items of FCC CFR 47 and IC RSS-3 and IC RSS-Gen. References Measurements were done according to relevant parts of the following standards: NSI 63.4-29 NSI/TI/EI-63-C-24 3GPP TS 36.4, version.4. CFR 47 part 2, December 6 th, 23 CFR 47 part 27, December 6 th, 23 RSS-Gen Issue 3 RSS-3 Issue
24--2 3P8658-F27 3 (8) ppendix Uncertainties Measurement and test instrument uncertainties are described in the quality assurance documentation SP-QD 885. The uncertainties are calculated with a coverage factor k=2 (95% level of confidence). Compliance evaluation is based on a shared risk principle with respect to the measurement uncertainty. Reservation The test results in this report apply only to the particular test object as declared in the report. Delivery of test object The test object was delivered 23-2-6. Manufacturer s representative Mihai Simon, Ericsson B. Test engineers Tomas Isbring, Kexin Chen, Jörgen Wassholm, Tomas Lennhager, ndreas Johnson and Rolf Kühn, SP. Test participants Mihai Simon and Ove Nilsson, Ericsson B.
24--2 3P8658-F27 4 (8) ppendix Measurement equipment Calibration due SP number Test site Tesla 25-53 88 R&S FSIQ 4 24-7 53 738 R&S ESU 26 24-5 9 553 R&S FSW43 24-7 92 73 R&S FSQ 4 24-3 54 43 Control computer with - 53 899 R&S software EMC32 version 8.52. High pass filter 24-7 9 5 High pass filter 24-7 9 52 High pass filter 24-7 54 99 High pass filter 24-9 9 373 High pass filter 24-9 53 739 High pass filter 24-7 53 74 RF attenuator 24-7 54 59 RF attenuator 24-7 9 233 RF attenuator 24-7 9 69 RF attenuator 24-7 9 384 Chase Bilog ntenna CBL 6 24 53 82 EMCO Horn ntenna 35 25-9 52 75 Std.gain horn FLNN model 224-2 - 53 674 µcomp Nordic, Low Noise mplifier 24-4 9 545 Miteq Low Noise mplifier 24-9 53 285 Schwartzbeck preamplifier BBV 9742 24-4 54 85 Temperature and humidity meter, Testo 635 24-6 54 23 Temperature and humidity meter, Testo 625 24-6 54 88 Temperature Chamber - 5 3 Multimeter Fluke 87 24-8 52 9
Date Reference 24--2 3P8658-F27 Page 5 (8)) ppendix Test frequencies used for conducted and radiated measurements TX test frequencies ERFCN Frequency Downlink [MHz] 9695 72.5 9725 723.5 9695 72.5 9735 724.5 9685 79.5 9725 723.5 9695 72.5 9685 79.5 97 722. 975 722.5 969 72. 973 724. 9755 726.5 9745 725.5 972 723. 9725 723.5 9755 726.5 975 72.5 9745 725.5 Symbolic name B2 3 3 B2 3 5 B2 5 3 B B B M M2 3 3 T T T T2 3 3 T2 3 5 Comment 2 carrier TX bottom constellation 3 MHz BW configuration 2 carrier TX bottom constellation 3 MHz and 5MHz BW configurationc n 2 carrier TX bottom constellation 5 MHz and 3MHz BW configurationc n TX bottom frequency inn 3 MHz BWW configuration TX bottom frequency inn 5 MHz BWW configuration TX bottom frequency inn MHz BWW configuration TX band mid frequencyy all BW configurations 2 carrier TX mid constellation 3 MHz BW configuration TX top frequency in 3 MHz BW configuration TX top frequency in 5 MHz BW configuration TX top frequency in MHz BW configuration 2 carrier TX top constellation 3 MHz BW configuration 2 carrier TX top constellation 3 MHz and 5 MHz BW configuration
Date Reference 24--2 3P8658-F27 Page 6 (8) ppendix Test setup conducted measurement ts Test object:. RRUS E2 B29, KRC 6 48/, revision R, s/n: C827525947 Software CXP 9 736/2, revision R54VB (FCC ID: T8KRC648- and IC: 287B-S648) Functional test equipment 2. SUP 66, /BFL 9 9/4, revision RE, s/n: BR88258944 DUL 2, KDU 37 533/4, revison RC, s/n: C824435943 3. Fast Ethernet switch, Netgear GSM7224, BMS 57289 4. Controlling computer SUN ULTR 27, BMS 75844 5 SP testt Instrumentation according to measurement equipment list 6. SP Test Instrumentation according to measurement equipment list 7. Terminator
Date Reference 24--2 3P8658-F27 Page 7 (8) ppendix Test setup radiated measuremen nts Test object:. RRUS E2 B29, KRC 6 48/, revision R, s/n: C827525956 Software CXP 9 736/2 revision R54VB (FCC ID: T8KRC648- and IC: 287B-S648) Functional test equipment: 2. Main Unit SUP 66, /BFL 9 9/4, revision RE, s/n: BR88237597 DUL 2, KDU 37 533/4, revision RC, s/n: C82432473 3. Switch Netgear GSM722, BMS 57299 4. Computer Sun ultra27-, BMS 758436 5. Terminator 6. RET Remote Electrical Tilt unit, KRY 2 67/2, revision RN
24--2 3P8658-F27 8 (8) ppendix Interfaces: Power: -48 VDC ntenna port (), 7/6 connector ntenna port (B), 7/6 connector Data, Optical Interface Link, single mode opto fibre Data 2, Optical Interface Link, single mode opto fibre, not in use larm, shielded multi-wire LD Ctrl, shielded multi-wire Ground wire DC Power ntenna ntenna Signal Signal Signal Signal Ground RBS software: Software CXP 2 5/2 Revision R8GT
24--2 3P8658-F27 (3) ppendix 2 RF power output measurements according to CFR 47 27.5 / IC RSS-3 4.4, conducted Date 23-2-2 24--7 24--8 Temperature 22 C ± 3 C 2 C ± 3 C 23 C ± 3 C Humidity 26 % ± 5 % 34 % ± 5 % 3 % ± 5 % Test set-up and procedure The test object was connected to a signal analyser measuring peak and RMS output power in CDF mode. resolution bandwidth of 5 MHz was used. For the MHz power averaging measurement method acc. to KDB9768, chapter 5.4. Measurement equipment SP number R&S FSQ 54 43 RF attenuator 92 282 Testo 635, temperature and humidity meter 54 23 Measurement uncertainty:. db
24--2 3P8658-F27 2 (3) ppendix 2 Results Single carrier, MIMO Rated output power level at RF connector x 46. dbm. Carrier BW [MHz] Symbolic name [RMS dbm/ PR db] Port RF Port RF B Total power ) 3 B 46.9/ 6.85 46.4/ 6.85 49.3 5 B 45.99/ 7.24 45.85/ 7.28 48.93 3 M 46.22/ 6.8 46.6/ 6.83 49.5 5 M 46.2/ 6.83 46.8/ 6.85 49.6 M 46./ 7.24 46./ 7.24 49.7 3 T 45.79/ 6.83 45.84/ 6.83 48.83 5 T 45.88/ 6.8 45.9/ 6.83 48.9 ) : Summed output power according to FCC KDB6629 DMultiple transmitter output v2r. Note: The PR value is the. % Peak to verage Ratio. MIMO mode, multicarrier Rated output power level at RF connector 2x 43. dbm. Carrier BW [MHz] Symbolic name [RMS dbm/ PR db] Port RF Port RF B Total power ) 3 and 3 B2 3 3 46.7/ 6.97 46.6/ 6.97 49.8 3 and 5 B2 3 5 46./ 7.43 45.98/ 7.5 49. 5 and 3 B2 5 3 46./ 7.43 45.98/ 7.5 49. 3 and 3 M2 3 3 46.5/ 7.7 46.3/ 7.9 49.5 3 and 3 T2 3 3 45.94/ 6.83 45.94/ 6.85 48.95 3 and 5 T2 3 5 45.98/ 6.88 45.99/ 6.88 49. ) : Summed output power according to FCC KDB6629 D Multiple transmitter output v2r. Method E), 2), a). Note: The PR value is the. % Peak to verage Ratio.
Date Reference 24--2 3P8658-F27 Page 3 (3)) ppendix 2 MIMO mode, single carrier Measured output power per MHz. Carrier BW Symbolic [RMS dbm] [MHz] name Portt RF Port RF B 3 B 42.48 42.23 5 B 4.43 4.4 3 M 42.64 42.32 5 M 4.43 4.8 M 37.45 37.25 3 T 42.6 42.8 5 T 4.5 4.8 Total power ) [RMS dbm] 45.48 43.43 45.64 43.43 4.45 45.6 43.5 ) : Measured according to FCC KDB6629 D Multiple Transmitter Output v2r. Method E), 2), c). Measure and add log(n nt ) Remark This unit is ested without antenna. ERP/EIRP compliance is addressed a at the time of licensing, as required by the responsible FCC/IC Bureau(s). Licensee s L aree required to take into account maximum allowed antenna gain used in combination with power settings to prevent the radiated outpu power to exceed the limits. Limits CFR 47 27.5 / IC RSS-3 4.4 27.5: licensee authorized to operate in the 76-722 or 722-728 MHz bands may operate a fixed or base station at an ERP up to a total off 5 kw within its authorized, 6 MHzz spectrum block. RSS-3 4.4: The average equivalent isotropically radiated power (e.i.r.p.) limits l in SRSP-58 apply, resulting in a maximumm EIRP of 328 W/ MHzz for the scope of this report. The peak-to-average ratio PR of thee power shalll not exceed 3 db. Complies? Yes
24--2 3P8658-F27 (6) ppendix 3 Occupied bandwidth measurements according to 47 CFR 2.49 / RSS-Gen 4.6. Date 23-2-2 24--7 Temperature 22 C ± 3 C 2 C ± 3 C Humidity 26 % ± 5 % 34 % ± 5 % Test set-up and procedure The measurements were made per definition in 2.49. The output was connected to a signal analyser with the RMS detector activated. The signal analyser was connected to an external MHz reference standard during the measurements. Measurement equipment SP number R&S FSQ 54 43 RF attenuator 92 282 Testo 635, temperature and humidity meter 54 23 Measurement uncertainty: 3.7 db Results MIMO mode, single carrier Diagram BW configuration Symbolic name Tested Port Occupied BW (99%) [MHz] 3 MHz B RF 2.69 2 5 MHz B RF 4.48 3 3 MHz M RF 2.69 4 3 MHz M RF B 2.69 5 5 MHz M RF 4.48 6 5 MHz M RF B 4.48 7 MHz M RF 8.93 8 MHz M RF B 8.93 9 3 MHz T RF 2.69 5 MHz T RF 4.48
24--2 3P8658-F27 2 (6) ppendix 3 Diagram : Ref 6 dbm * RBW 3 khz VBW 3 khz * tt 3 db * SWT 2 s 24.8 dbm 72.5 MHz 6 OBW 2.69 MHz Temp [T OBW] RM * CLRWR 5 4 25.79 dbm 79.545 MHz Temp 2 [T OBW] 25.9 dbm 72.8455 MHz 3 T T2 2-2 -3-4 Center 72.5 MHz 9 khz/ Span 9 MHz Date: 2.DEC.23 2:6:56 Diagram 2: Ref 66 dbm * RBW 5 khz VBW 5 khz * tt 3 db * SWT 2 s 25.35 dbm 79.5 MHz RM * CLRWR 6 5 4 OBW 4.475 MHz Temp [T OBW] 25.9 dbm 77.2675 MHz Temp 2 [T OBW] 25.96 dbm 72.7425 MHz 3 T T2 2-2 -3 Start 72 MHz.5 MHz/ Stop 727 MHz Date: 2.DEC.23 5:54:4
24--2 3P8658-F27 3 (6) ppendix 3 Diagram 3: Ref 62 dbm * RBW 3 khz VBW 3 khz * tt 3 db * SWT 2 s 25. dbm 722.5 MHz 6 OBW 2.69 MHz Temp [T OBW] RM * CLRWR 5 4 25.94 dbm 72.545 MHz Temp 2 [T OBW] 25.87 dbm 723.8455 MHz 3 T T2 2-2 -3 Center 722.5 MHz 9 khz/ Span 9 MHz Date: 2.DEC.23 6:6:33 Diagram 4: Ref 62 dbm * RBW 3 khz VBW 3 khz * tt 3 db * SWT 2 s 24.63 dbm 722.5 MHz 6 OBW 2.6925 MHz Temp [T OBW] 25.84 dbm RM CLRWR * 5 4 72.545 MHz Temp 2 [T OBW] 25.74 dbm 723.847 MHz 3 T T2 2-2 -3 Center 722.5 MHz 9 khz/ Span 9 MHz Date: 7.JN.24 9::29
24--2 3P8658-F27 4 (6) ppendix 3 Diagram 5: Ref 66 dbm * RBW 5 khz VBW 5 khz * tt 3 db * SWT 2 s 25.37 dbm 722.5 MHz RM * CLRWR 6 5 4 OBW 4.4775 MHz Temp [T OBW] 25.77 dbm 72.2625 MHz Temp 2 [T OBW] 25.88 dbm 724.74 MHz 3 T T2 2-2 -3 Center 722.5 MHz.5 MHz/ Span 5 MHz Date: 2.DEC.23 6:3:7 Diagram 6: Ref 66 dbm * RBW 5 khz VBW 5 khz * tt 3 db * SWT 2 s 25.4 dbm 722.5 MHz RM CLRWR * 6 5 4 OBW 4.4775 MHz Temp [T OBW] 25.88 dbm 72.2625 MHz Temp 2 [T OBW] 26. dbm 724.74 MHz 3 T T2 2-2 -3 Center 722.5 MHz.5 MHz/ Span 5 MHz Date: 7.JN.24 9:27:6
24--2 3P8658-F27 5 (6) ppendix 3 Diagram 7: Ref 66 dbm * RBW khz VBW MHz * tt 3 db * SWT 2 s 26.28 dbm 722.5 MHz RM CLRWR * 6 5 4 OBW 8.93 MHz Temp [T OBW] 25.6 dbm 78.4 MHz Temp 2 [T OBW] 25.97 dbm 726.97 MHz 3 T T2 2-2 -3 Center 722.5 MHz 3 MHz/ Span 3 MHz Date: 2.DEC.23 6:36:2 Diagram 8: Ref 66 dbm * RBW khz VBW MHz * tt 3 db * SWT 2 s 26.8 dbm 722.5 MHz RM * CLRWR 6 5 4 OBW 8.93 MHz Temp [T OBW] 25.48 dbm 78.4 MHz Temp 2 [T OBW] 25.94 dbm 726.97 MHz 3 T T2 2-2 -3 Center 722.5 MHz 3 MHz/ Span 3 MHz Date: 7.JN.24 9:22:27
24--2 3P8658-F27 6 (6) ppendix 3 Diagram 9: Ref 6 dbm * RBW 3 khz VBW 3 khz * tt 3 db * SWT 2 s 24.29 dbm 726.5 MHz 6 OBW 2.69 MHz Temp [T OBW] RM * CLRWR 5 4 25.56 dbm 725.545 MHz Temp 2 [T OBW] 25.35 dbm 727.8455 MHz 3 T T2 2-2 -3-4 Center 726.5 MHz 9 khz/ Span 9 MHz Date: 7.JN.24 9:55:36 Diagram : Ref 66 dbm * RBW 5 khz VBW 5 khz * tt 3 db * SWT 2 s 25.6 dbm 725.5 MHz RM CLRWR * 6 5 4 OBW 4.48 MHz Temp [T OBW] 25.46 dbm 723.26 MHz Temp 2 [T OBW] 25.37 dbm 727.74 MHz 3 T T2 2-2 -3 Center 725.5 MHz.5 MHz/ Span 5 MHz Date: 7.JN.24 9:4:26
Date Reference 24--2 3P8658-F27 Page (3) ppendix 4 Band edge measurements according to CFR 47 27.53(f) / IC RSS-3 4.6 Date 23-2-2 24--7 24--8 Temperature 22 C ± 3 C 2 C ± 3 C 23 C ± 3 C Humidity H 26 % ± 5 % 34 % ± 5 % 3 % ± 5 % Test set-up and procedure The measurements were made per definition in 27.53(f). Thee test object was connected to a spectrum analyser with the RMS detector activated. The spectrum analyser was connected to an external MHz reference standard during the measurements. Compliance with this provision is based on the use of measurement instrumentation employing a resolution bandwidth of khz or greater. However, in the khz bands immediately outside and adjacent to a licensee's frequency block, a resolution bandwidth of at least 3 khz may be employed. Before comparing the results to the limit, 3 db [ log (2)] should be added according to method E), 3), a), (iii ) Measure and add log(n NT ) of FCCC KDB6629 D Multiple Transmitter Output v2r. Measurement equipment R&S FSQ RF attenuator Testo 635, temperature and humidity meter SPP number 54 43 92 282 54 23 Measurement uncertainty: 3.7 db
Date Reference 24--2 3P8658-F27 Page 2 (3) ppendix 4 Results MIMO mode, Single carrier Diagram BW configuration a+b 3 MHz 2 a+b 5 MHz 3 a MHz 4 a+b 3 MHz 5 a+b 3 MHz 6 a+b 5 MHz 7 a MHz MIMO mode, multi carrier Diagram BW configuration 8 a+b 3 and 3 MHz 9 a+b 5 and 3 MHz a+b 3 and 3 MHz a+b 3 and 5 MHz Limits CFR 47 27. 53(f) and RSS-3 4.6 Symbolic name B B B T T T T Symbolic name B2 3 3 B2 5 3 T2 3 3 T2 3 5 Tested Port RF RF RF RF RF B RF RF Tested Port RF RF RF RF Outside a licensee s frequency band(s) of operation the powerr of any emission shall be attenuated below the transmitter power (P) by at least 43 + log (P) db, resulting in a limit of -3 dbm. Complies? Yes
24--2 3P8658-F27 3 (3) ppendix 4 Diagram a: Ref 7 dbm * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s -39.76 dbm 76.9 MHz RM * 7 6 5 Marker 2 [T ] -39.65 dbm 77. MHz Marker 3 [T ] 24.8 dbm 72.5 MHz 4 3 3 2 D -3 dbm -2-3 -4-5 2 F2 F Start 76 MHz 9 khz/ Stop 725 MHz Date: 7.JN.24 :9:29 Diagram b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -34.7 dbm 76.9 MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 7 MHz.59 MHz/ Stop 76.9 MHz Date: 7.JN.24 :23:36
24--2 3P8658-F27 4 (3) ppendix 4 Diagram 2 a: Ref 7 dbm * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s -28.47 dbm 76.9 MHz RM * 7 6 5 Marker 2 [T ] -32.42 dbm 77. MHz Marker 3 [T ] 22.34 dbm 79.5 MHz 4 3 3 2 D -3 dbm -2-3 2-4 -5 F2 F Start 76 MHz 9 khz/ Stop 725 MHz Date: 2.DEC.23 4:54:56 Diagram 2 b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -23.94 dbm 76.9 MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 7 MHz.59 MHz/ Stop 76.9 MHz Date: 2.DEC.23 5:2:4
24--2 3P8658-F27 5 (3) ppendix 4 Diagram 3 a: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -32.35 dbm 77. MHz RM * 7 6 5 Marker 2 [T ] 26.28 dbm 722. MHz Marker 3 [T ] -33.5 dbm 728. MHz 4 3 2 2 D -3 dbm -2-3 3-4 -5 F F2 Start 7 MHz 4.3 MHz/ Stop 744 MHz Date: 2.DEC.23 6::42
24--2 3P8658-F27 6 (3) ppendix 4 Diagram 4 a: RM * * RBW 3 khz VBW 3 khz Ref 7 dbm * tt 2 db * SWT 2 s 7 6 5 24.57 dbm 726.5 MHz Marker 2 [T ] -7.2 dbm 728. MHz Marker 3 [T ] -3.53 dbm 728. MHz 4 3 2 D -3 dbm 2-2 -3 3-4 -5 F2 F Start 72 MHz 9 khz/ Stop 729 MHz Date: 2.DEC.23 :5:4 Diagram 4 b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -23.34 dbm 728. MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 728. MHz.59 MHz/ Stop 744 MHz Date: 2.DEC.23 :2:2
24--2 3P8658-F27 7 (3) ppendix 4 Diagram 5 a: Ref 7 dbm * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s 24.38 dbm 726.5 MHz RM * 7 6 5 Marker 2 [T ] -6.96 dbm 728. MHz Marker 3 [T ] -3.82 dbm 728. MHz 4 3 2 D -3 dbm 2-2 -3 3-4 -5 F2 F Start 72 MHz 9 khz/ Stop 729 MHz Date: 7.JN.24 9:32:22 Diagram 5 b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -23.4 dbm 728. MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 728. MHz.59 MHz/ Stop 744 MHz Date: 7.JN.24 9:33:36
24--2 3P8658-F27 8 (3) ppendix 4 Diagram 6 a: Ref 7 dbm * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s 22.5 dbm 725.5 MHz RM * 7 6 5 Marker 2 [T ] -3.82 dbm 728. MHz Marker 3 [T ] -26.3 dbm 728. MHz 4 3 2 D -3 dbm -2-3 2 3-4 -5 F2 F Start 72 MHz 9 khz/ Stop 729 MHz Date: 7.JN.24 9:43:25 Diagram 6 b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -22. dbm 728. MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 728. MHz.59 MHz/ Stop 744 MHz Date: 7.JN.24 9:44:5
24--2 3P8658-F27 9 (3) ppendix 4 Diagram 7 a: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -34.57 dbm 77. MHz RM * 7 6 5 Marker 2 [T ] 26.6 dbm 723. MHz Marker 3 [T ] -3.7 dbm 728. MHz 4 3 2 2 D -3 dbm -2-3 3-4 -5 F F2 Start 7 MHz 4.3 MHz/ Stop 744 MHz Date: 7.JN.24 :8:6
24--2 3P8658-F27 (3) ppendix 4 Diagram 8 a: RM * Ref 7 dbm 7 6 5 4 3 2 * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s 3-4.94 dbm 76.9 MHz Marker 2 [T ] -4.7 dbm 77. MHz Marker 3 [T ] 2.56 dbm 72.5 MHz Marker 4 [T ] 2.77 dbm 723.5 MHz 4 D -3 dbm -2-3 -4-5 2 F2 F Start 76 MHz 9 khz/ Stop 725 MHz Date: 7.JN.24 :39:23 Diagram 8 b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -35.29 dbm 76.9 MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 7 MHz.59 MHz/ Stop 76.9 MHz Date: 7.JN.24 :4:56
24--2 3P8658-F27 (3) ppendix 4 Diagram 9 a: RM * Ref 7 dbm 7 6 5 4 3 2 * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s 3-3.79 dbm 76.9 MHz Marker 2 [T ] -35.9 dbm 77. MHz Marker 3 [T ] 9.3 dbm 79.5 MHz Marker 4 [T ] 2.89 dbm 723.5 MHz 4 D -3 dbm -2-3 2-4 -5 F2 F Start 76 MHz 9 khz/ Stop 725 MHz Date: 8.JN.24 8:34:59 Diagram 9 b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -26.62 dbm 76.9 MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 7 MHz.59 MHz/ Stop 76.9 MHz Date: 8.JN.24 8:37:2
24--2 3P8658-F27 2 (3) ppendix 4 Diagram a: RM * Ref 7 dbm 7 6 5 4 3 2 * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s 2.63 dbm 723.5 MHz Marker 2 [T ] 2.59 dbm 726.5 MHz Marker 3 [T ] -9.39 dbm 728. MHz Marker 4 [T ] -33.58 dbm 728. MHz 2-2 D -3 dbm 3-3 4-4 -5 F2 F Start 72 MHz 9 khz/ Stop 729 MHz Date: 7.JN.24 2:9:4 Diagram b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -26. dbm 728. MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 728. MHz.59 MHz/ Stop 744 MHz Date: 7.JN.24 2::26
24--2 3P8658-F27 3 (3) ppendix 4 Diagram a: RM * Ref 7 dbm 7 6 5 4 3 2 * RBW 3 khz VBW 3 khz * tt 2 db * SWT 2 s 2 2.64 dbm 72.5 MHz Marker 2 [T ] 9.56 dbm 725.5 MHz Marker 3 [T ] -27.86 dbm 727.9753846 MHz Marker 4 [T ] -3.2 dbm 728. MHz D -3 dbm -2-3 3 4-4 -5 F2 F Start 72 MHz 9 khz/ Stop 729 MHz Date: 8.JN.24 9::2 Diagram b: Ref 7 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s -25.34 dbm 728. MHz 7 6 RM * 5 4 3 2 D -3 dbm -2-3 -4-5 Start 728. MHz.59 MHz/ Stop 744 MHz Date: 8.JN.24 9::33
Date Reference 24--2 3P8658-F27 Page (9) ppendix 5 Conducted spurious emission measurements according to CFR 47 27.53(f)/ IC RSS-3 4.6 Date 23-2-2 24--7 24--8 Temperature 22 C ± 3 C 2 C ± 3 C 23 C ± 3 C Humidity H 26 % ± 5 % 34 % ± 5 % 3 % ± 5 % Test set-up and procedure The measurements were made per definition in 27.53(f). Thee output was connected to a spectrum analyser with a RBW setting of MHz and RMS detector activated. The spectrum analyser was connected to an externall MHz reference standard during the measurements. Before comparing the results to the limit, 3 db [ log (2)] should be added according to method E), 3), (iii) measure and addd log(n NT T) of FCC KDB6629 K D Multiple Transmitter Output v2r. Measurement equipment R&S FSQ RF attenuator HP filter Testo 635, temperature and humidity meter SPP number 54 43 92 282 9 52 54 23 Measurement uncertainty: 3.7 db
24--2 3P8658-F27 2 (9) ppendix 5 Results MIMO mode, single carrier Diagram BW configuration / [MHz] Symbolic name Tested Port a+b 3 MHz B RF 2 a+b 5 MHz B RF 3 a+b 3 MHz M RF 4 a+b 3 MHz M RF B 5 a+b 5 MHz M RF 6 a+b MHz M RF 7 a+b MHz M RF B 8 a+b 3 MHz T RF 9 a+b 5 MHz T RF MIMO mode, 2 carrier Diagram BW configuration Symbolic name Tested Port a+b 3 and 3 MHz B2 3 3 RF a+b 3 and 5 MHz B2 3 5 RF 2 a+b 3 and 3 MHz M2 3 3 RF 3 a+b 3 and 3 MHz M2 3 3 RF B 4 a+b 3 and 3 MHz T2 3 3 RF 5 a+b 3 and 5 MHz T2 3 5 RF 6 a+b 5 and 3 MHz B2 5 3 RF
Date Reference 24--2 3P8658-F27 Page 3 (9) ppendix 5 Remark The emission at 9 khz on the plots was not generated by the test object. complementary measurement with a smaller RBW showed that it was related to t the LO feed-through. The highest fundamental frequency iss 728 MHz. The measurements were made up to 8 GHz (x728 MHz = 7.28 GHz). Limits 27.53(f) and RSS-3 4.6 Outside a licensee s frequency band(s) of operation the powerr of any emission shall be attenuated below the transmitter power (P) by at least 43 + log (P) db, resulting in a limit of -3 dbm per khz RBW. Complies? Yes
24--2 3P8658-F27 4 (9) ppendix 5 Diagram a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 42.34 dbm 72.5 MHz RM * 6 5 4 Marker 2 [T ] -27.53 dbm 966.724658455 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 2.DEC.23 5:58: Diagram b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.55 dbm 3.5949 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 2.DEC.23 2:5:8
24--2 3P8658-F27 5 (9) ppendix 5 Diagram 2 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 4.3 dbm 72.5 MHz RM * 6 5 4 Marker 2 [T ] -27.42 dbm 98.5563577 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 2.DEC.23 5:5:7 Diagram 2 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -34.5 dbm 3.59866667 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 2.DEC.23 3:2:24
24--2 3P8658-F27 6 (9) ppendix 5 Diagram 3 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 42.33 dbm 722.5 MHz RM * 6 5 4 Marker 2 [T ] -27.5 dbm 972.77588645 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 2.DEC.23 6:8:52 Diagram 3 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.8 dbm 3.592 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 2.DEC.23 6:2:3
24--2 3P8658-F27 7 (9) ppendix 5 Diagram 4 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 42.25 dbm 722.5 MHz RM * 6 5 4 Marker 2 [T ] -27.47 dbm 98.762993647 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 9:2:53 Diagram 4 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.67 dbm 3.599 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 9:4:4
24--2 3P8658-F27 8 (9) ppendix 5 Diagram 5 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 4.2 dbm 722.5 MHz RM * 6 5 4 Marker 2 [T ] -27.4 dbm 983.56425487 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 2.DEC.23 6:26:45 Diagram 5 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.78 dbm 3.59866667 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 2.DEC.23 6:23:5
24--2 3P8658-F27 9 (9) ppendix 5 Diagram 6 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 37.4 dbm 722.5 MHz RM * 6 5 4 Marker 2 [T ] -27.4 dbm 993.5898282 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 2.DEC.23 6:39:57 Diagram 6 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.7 dbm 3.5977 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 2.DEC.23 6:42:38
24--2 3P8658-F27 (9) ppendix 5 Diagram 7 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 37.6 dbm 722.5 MHz RM * 6 5 4 Marker 2 [T ] -27.5 dbm 984.6552377 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 9:9:5 Diagram 7 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.77 dbm 3.58966667 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 9:7:5
24--2 3P8658-F27 (9) ppendix 5 Diagram 8 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 4.89 dbm 726.5 MHz RM * 6 5 4 Marker 2 [T ] -27.37 dbm 992.2757545 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 9:52:46 Diagram 8 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.7 dbm 3.588366667 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 9:5:9
24--2 3P8658-F27 2 (9) ppendix 5 Diagram 9 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 39.83 dbm 725.5 MHz RM * 6 5 4 Marker 2 [T ] -27.38 dbm 998.3974532 MHz 3 2 D -3 dbm -2 2-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 9:47:2 Diagram 9 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.63 dbm 3.597 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 9:48:46
24--2 3P8658-F27 3 (9) ppendix 5 Diagram a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 39. dbm 72.5 MHz RM * 6 5 4 Marker 2 [T ] 39.24 dbm 723.5 MHz Marker 3 [T ] -27.45 dbm 2 987.9238565 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 :43:47 Diagram b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.72 dbm 3.596766667 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 :46:43
24--2 3P8658-F27 4 (9) ppendix 5 Diagram a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 36.82 dbm 79.5 MHz RM * 6 5 4 Marker 2 [T ] 39.32 dbm 723.5 MHz Marker 3 [T ] -27.43 dbm 2 975.278879 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 8.JN.24 8:42:2 Diagram b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.78 dbm 3.5963 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 8.JN.24 8:44:5
24--2 3P8658-F27 5 (9) ppendix 5 Diagram 2 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 38.38 dbm 72. MHz RM * 6 5 4 Marker 2 [T ] 39.24 dbm 724. MHz Marker 3 [T ] -27.39 dbm 2 983.9745325 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 :59:24 Diagram 2 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.79 dbm 3.59666667 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 :57:44
24--2 3P8658-F27 6 (9) ppendix 5 Diagram 3 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 38.29 dbm 72. MHz RM * 6 5 4 Marker 2 [T ] 39.2 dbm 724. MHz Marker 3 [T ] -27.48 dbm 2 963.9682736 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 :48:55 Diagram 3 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.85 dbm 3.593733333 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 :55:23
24--2 3P8658-F27 7 (9) ppendix 5 Diagram 4 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 39.6 dbm 723.5 MHz RM * 6 5 4 Marker 2 [T ] 38.98 dbm 726.5 MHz Marker 3 [T ] -27.43 dbm 2 98.52986897 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 7.JN.24 2:2:38 Diagram 4 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.76 dbm 3.5977 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 7.JN.24 2:4:24
24--2 3P8658-F27 8 (9) ppendix 5 Diagram 5 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 39.5 dbm 72.5 MHz RM * 6 5 4 Marker 2 [T ] 36.92 dbm 725.5 MHz Marker 3 [T ] -27.42 dbm 2 979.7632647 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 8.JN.24 9:3:25 Diagram 5 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.73 dbm 3.599 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 8.JN.24 9:5:2
24--2 3P8658-F27 9 (9) ppendix 5 Diagram 6 a: Ref 65 dbm * RBW MHz VBW MHz * tt 25 db * SWT 3 s 36.82 dbm 79.5 MHz RM * 6 5 4 Marker 2 [T ] 39.32 dbm 723.5 MHz Marker 3 [T ] -27.43 dbm 2 975.278879 MHz 3 2 D -3 dbm -2 3-3 -4-5 Start 9 khz 99.999 MHz/ Stop GHz Date: 8.JN.24 8:42:2 Diagram 6 b: Ref 2 dbm * RBW MHz VBW MHz * tt db * SWT s -33.78 dbm 3.5963 GHz 2 Offset.9 db RM * LVL -M -2-3 -4-5 -6-7 -8 Start GHz 7 MHz/ Stop 8 GHz Date: 8.JN.24 8:44:5
Date Reference 24--2 3P8658-F27 Page (4)) ppendix 6 Field strength of spurious radiation measurements according too 47 CFR 27.53 (f) / IC RSS-3 4.6 Date 23-2-2 24--7 Temperature 23 C ± 3 C 22 C ± 3 C Humidity H 35 % ± 5 % 3 % ± 5 % Test set-up and procedure The test sitess are listed att FCC, Columbia with registration number: 93866. The test site complies with RSS-Gen, Industry Canada file no. 3482-. The measurements were performed with both horizontal and vertical v polarization of the antenna. The antenna distance was 3 m in the frequency rangee 3 MHz 8 GHz. In the frequency range 3 MHz 8 GHz the measurement was performed in power with a RBW of MHz. propagation loss in free space was calculated. The usedd formula was 4 D 2log, is the propagation loss and D is the antenna distance. The measurement procedure was as the following:. The pre-measuremenin eight directions and with the antenna at three heights,. m,.5 m and 2. m. was first performed with peak detector. The EUT was measured 2. Spurious radiation on frequencies closer than 2 db to the limit in thee pre-measurement is scanned -36 degrees and thee antenna is scanned - 4 m for maximum response. The emission is then measured with the RMS detector and the RMS value is reported. Frequencies closer than db too the limit when measured with the RMS detectorr were measured with the substitution method according to the standard.
24--2 3P8658-F27 2 (4) ppendix 6 The test set-up during the spurious radiation measurements is shown in the picture below: Measurement equipment Measurement equipment SP number Semi anechoic chamber 53 88 R&S ESU 26 9 553 EMC 32 ver. 8.52. 53 899 Chase Bilog ntenna CBL 6 52 82 EMCO Horn ntenna 35 52 75 Flann STD Gain Horn ntenna 224-2 53 674 High pass filter 9 373 Miteq, Low Noise mplifier 53 285 Temperature and humidity meter, Testo 625 54 88
Date Reference 24--2 3P8658-F27 Page 3 (4)) ppendix 6 Tested configurations Symbolic name B2 3 3 B2 3 5 B M M2 3 3 T T2 3 3 T2 3 5 BW configuration Multi carrier: 3 and 3 MHz Multi carrier: 3 and 5 MHz 3, 5 and MHz 3, 5 and MHz Multi carrier: 3 and 3 MHz 3, 5 and MHz Multi carrier: 3 and 3 MHz Multi carrier: 3 and 5 MHz Results, representing worst case M, BW: 3 MHz Diagram a-b Spurious emission level (dbm)( Frequency (MHz) 3-8 Vertical ll emission > 2 dbb below limit Horizontal ll emission > 2 db below limit Measurement uncertainty: 3.2 db up to 8 GHz. Limits 27.53(f) and RSS-3 4.6 Outside a licensee s frequency band(s) of operation the powerr of any emission shall be attenuated below the transmitter power (P) by at least 43 + log (P) db, resulting in a limit of -3 dbm per MHz RBW. Complies? Yes
24--2 3P8658-F27 4 (4) ppendix 6 Diagram a: FCC P2-2 Level in dbm -3-4 -5-6 -7-8 3M 5 6 8 M 2 3 4 5 8 G Frequency in Hz Note: The emission at 722.5 MHz is the carrier frequency and shall be ignored in the context. Diagram b: FCC P2-2 Level in dbm -3-4 -5-6 -7-8 G 2G 3G 4G 5G 6 7 8G Frequency in Hz
Date Reference 24--2 3P8658-F27 Page (2)) ppendix 7 Frequency stability measuremen nts according to CFR 47 27.54 / IC RSS 3 4.3 Date 24--9 to 24--3 Test set-up and procedure Temperature (test equipment) 22-23 C ± 3 C Humidity H (testt equipment) 26-36 % ± 5 % The measurement was made per 3GPP TS 36.4. The outputt was connected to a spectrum analyser. The spectrum analyser was connected to an external MHz reference standard during the measurements. The measurement was also made per IC RSS 3 4.3. Using a resolution bandwidth off % of the occupied bandwidth, a reference point at the unwanted emission level which complies with the attenuation of 43 + log p (watts) (i.e. -3dBm) (for MIMO -6dBm) at the band edge of the lowest and highest channel wass selected, and the frequency at these e points was recorded r as fl and fh respectively. Measurement equipment R&S FSQ RF attenuator Testo 635, Temperature and humidityy meter Temperature cabinet SP number 54 43 92 282 54 23 53 36 Results Nominal transmitter frequency was 722.5 MHz (M) with a bandwidth of 5 MHz. Rated output power level at connector RF (maximum): 46. dbm (4 W) ) Test conditions Supply voltage Temp. DC (V) ( C)) -48. +2-55.2-4.8-48. -48. -48. -48. -48. -48. -48. -48. +2 +2 +3 +4 +5 + Maximumm freq. error (Hz) Measurement uncertainty -2-3 Frequency error (Hz) - -2 - -2-2 -2 +2 - -2-3 -2 3 < ± x -7 Measurements according to t 3GPP TS 36.4.
Date Reference 24--2 3P8658-F27 Page 2 (2)) ppendix 7 Rated output power level at connector RF (maximum): 46. dbm d (4 W) Test conditions Supply voltage DC (V) Temp ( C). Carrier Bandwidth (MHz) -48. +2 3-48. +2 5-48. +2 Frequency margin too band edge at -6dBm Test frequency Symbolic name Test frequency Symbolicc name Bottom Top fll (MHz) Offset to lower band edge (>76 MHz) (khz) fh (MHz) Offset to upper band edge (<728 MHz) (khz) 79. 77.5 77.266 3 5 266 727.99658 727.95577 727.7532 3.42 44.23 246.88 Measurements according to t IC RSS 3 4.3. The frequency error results clearly shows that the frequency stability is goodd enough to ensure that the transmitted carrierr stay within the operating band. Limits Limit according to 3GPP TS 36.4: The frequency error shalll be within ±.5 PPM ± 2 Hz (±48.25Hz). 27.54: The frequency stability shall be sufficient to ensure that the fundamental emissions stay within the authorized bands of operation. RSS-3 4.3 Frequency: The frequency stability shall be sufficient to ensure that the emission bandwidth stays within the operating frequency block when tested to the temperature and supply voltage variations specified in RSS-Gen. Complies? Yes
24--2 3P8658-F27 (2) ppendix 8 External photos Front side Rear side Top side Bottom side,
24--2 3P8658-F27 2 (2) ppendix 8 ID-label