REPORT 2242 B2. Test object. Summary. Appendix. Standard. Niklas Warnströmm PDU Torshamnsgatan Stockholmm. (9 appendices) See appendix

Transcription

1 RIss sued by an FCC listedd Laboratory Reg. no The test site complies with w RSS-Gen, IC file no Contact person Jörgen Wassholm Electronics jorgen.wassholm@sp.se P8534--F24 (2)) 2 ISO/IEC 725 Radio measurements on RD 2242 B2 with FCC ID T8KRY9328- and IC:287B-S9328 (9 appendices) Ericsson B Niklas Warnströmm PDU HW Torshamnsgatan Stockholmm Test object Product name: RD 2242 B2 Product number: KRY 9 328/ Summary See appendix for general information and appendix 9 for external photos. Standard FCC CFR 47 part 2 and 24 / IC RSS-33 Issue 6 Compliant ppendix 2.46 / RSS / RSS / RSS-Gen / RSS / RSS / RSS / RSS RF power output conducted RF power output radiated Occupied bandwidth Band edge Spurious emission at antenna terminals Field strength of spurious radiation Frequency stability Yes Yes Yes Yes Yes Yes Yes Note: bove RSS-33 items are givenn as cross-reference only. Measurements were performed according to NSI procedures referenced by FCCC and covered by SP s accreditation. Electronics - EMC Performed by Examined by Jörgen Wassholm nders Nordlöf Postal address SP Box 857 SE-5 5 BORÅS Sweden Office locationn Västeråsen Brinellgatan 4 SE BORÅS B Phone / Fax / Laboratories are accredited by the Swedish Board for ccreditation and Conformity ssessment (SWEDC) under the terms of o Swedish legislation. This report may not n be reproduced other than in full, except e with the prior written approval of the issuing laboratory.

2 P8534--F24 2 (2)) Table of contents Description of the test object Operation mode during measurement ts Test setups Purpose of test RF power output conducted RF power output radiatedd Occupied bandwidth Band edge Spurious emission at antenna terminals Field strength of spuriouss radiation Frequency stability External photos ppendix ppendix ppendix ppendix ppendix 2 ppendix 3 ppendix 4 ppendix 5 ppendix 6 ppendix 7 ppendix 8 ppendix 9

3 P8534--F24 () ppendix Description of the testt object Radio equipment: Hardware revision state: Tested configuration: Frequency bands: ntenna ports: RF configuration: RF power tolerance RD 2242 B2 Product number: KRY 9 328/3 FCCC ID T8KRY9328- IC 287B-S9328 IC MODEL NO: S9328 R2BB LTEE single RT TX: : MHz RX: : 85 9 MHz 2 TX/RX ports, (internally connected to integrated Omni directional antenna elements) Single carrier, multi carrier,tx-diversityy and MIMO 2x2 +2.7/ -4.3dB Nominal output power per antenna port: Single carrier: Multi carrier: x 7 dbmm ( x 5mW) 2 x 4 dbmm (2 x 25mW) ntenna type: ntenna gain: Channel bandwidths: Modulations: Nominal supply voltage: Omni directional antenna +3 dbi Singel carrier: 5 MHz, MHz, 5 MHzz and 2 MHz Multi carrier: 5 MHz, MHz, 5 MHz z and 2 MHz QPSK, 6QM and 64QM -48VDC (associated equipment)

4 P8534--F24 2 () ppendix Operation mode during measurements Measurements were performed with the test object transmitting test models as definedd in 3GPP TS 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 s when settings with different modulations, channel bandwidths, number of carrierss and RF configurations has been tested to find the worst case setting. ll measurements were performed with the test object configured for maximumm transmit power. The settings below were w used for all measurements if not otherwise noted. MIMO mode, single carrier, E-TM. MIMO mode, multi carrier, 2 carriers, E-TM. Cable configurations between RD and IRU The cables, used during tests, correspond to minimum and maximum length, according to clause 2.9 in Exhibit 2 Technical Circuit Description. The following cable configurations has been used: RDI Cable 2 m: total cable length 2 m patch cables included. RDI Cable 92 m: total cable length 922 m patch cables included. RDI Cable 2 m: total cable length 2 m patch cables included. Patch cable RDI cable Cat 6a Schneider Electric ctassi CL-MNC6 Cat 6a Schneider Electric ctassi CL-MXC6 Conducted measurements The conducted measurements were performed on RD 2242 B22 with product number KRY 9 328/. The test object was mounted in a fixture and powered by the RBS R Main Unit via the RDI LN cable. ll TX parameters were measured at port RF B with port RF terminatedd into 5 ohm. Complete measurements were made on RF B, limited measurements on RF. Radiated measurementss The test object was mounted in a fixture and powered by the RBS R Main Unit via the 2 m RDI LN cable representing worst case. In field strength of spurios radiation both RF ports were terminated into 5 ohm. For RF power outpu measurement the internal antenna was used.

5 P8534--F24 3 () ppendix Purpose of test The purpose of the tests is i to verify compliance to the performance characteristics specified in applicable items of FCC CFR 47 and Industry Canada RSS-33 and RSS-Gen. standards: NSI NSI/TI -63-C 24 CFR 47 part 2, October st, 23 CFR 47 part 24, October st, 23 3GPP TS 36..4, version.4. RSS-Gen Issue 4 RSS-33 Issue s Measurements were done according to relevant parts of the following 6

6 P8534--F24 4 () ppendix Uncertainties Measurement and test instrument uncertainties are described in i the qualityy assurance documentation SP-QD 885. The uncertainties are calculated with a coverage factor k=2 (95% level of confidence). Compliance evaluation iss based on a shared risk principle withh respect to the measurement uncertainty. Reservation The test results in this report apply only to the particular test object o as declared in the report. r Delivery of test objectt The test object was delivered Manufacturer s representative Lars Wallin, Ericsson B. Test engineers ndreas Johnson, Maulo Rivera, Tomas Isbring, Patric ugustsson and Jörgen Wassholm, SP. Test participant None.

7 P8534--F24 5 () ppendix Measurement equipment Semi anechoic chamber, Tesla R&S ESU 26 R&S FSQ 4 R&S FSW 43 Control computer with R&S software EMC32 ver High pass filter High pass filter High pass filter High pass filter High pass filter High pass filter High pass filter High pass filter RF attenuator RF attenuator RF attenuator RF attenuator RF attenuator RF attenuator Chase Bilog ntenna CBL 6 EMCO Horn ntenna 35 µcomp Nordic, Low Noise mplifierr Flann STD Gain Horn ntenna 6-24 Flann STD Gain Horn ntenna 8-24 Flann STD Gain Horn ntenna Schwarzbeck preamplifier BBV Temperature and humidity meter, Testo 635 Temperature and humidity meter, Testo 625 Temperature Chamber Multimeter Fluke 87 Calibration Due SP number BX

8 P8534--F24 6 () ppendix Test frequencies used for conducted and radiated measurements TX test frequencies, single carrier: ERFCN Downlink Frequency [MHz] Symbolic name B B B B M 98. T T T T Comment TX bottom frequency in 5 MHz M BW configuration TX bottom frequency in MHz BW configuration. TX bottom frequency in 5 MHz BW configuration. TX bottom frequency in 2 MHz BW configuration. TX band mid frequency all BW B configurations TX top frequency in 2 MHz BW configuration. TX top frequency in 5 MHz BW configuration. TX top frequency in MHz BW configuration. TX top frequency in 5 MHz BW configuration

9 P8534--F24 7 () ppendix TX test frequencies, multi carrier: ERFCN Downlink Frequency [MHz] Symbolic name B B B B M M M M T T T T T B2im T2im B2/T2im2 Comment TX bottom frequency in 5 MHz BW configuration 2 carriers. TX bottom frequency in MHz BW configuration 2 carriers. TX bottom frequency in 5 MHz BW configuration 2 carriers. TX bottom frequency in 2 MHz BW configuration 2 carriers. TX mid frequency in 5 MHz BW configuration 2 carriers. TX mid frequency in MHz M BW configuration 2 carriers. TX mid frequency in 5 MHz M BW configuration 2 carriers. TX mid frequency in 2 MHz M BW configuration 2 carriers. TX Top frequency in 5 MHz BW configuration 2 carriers. TX Top frequency in 5 MHz BW configuration 2 carriers. TX Top frequency in MHz M BW configuration 2 carriers. TX Top frequency in 5 MHz M BW configuration 2 carriers. TX Top frequency in 2 MHz M BW configuration 2 carriers. TX bottom frequency in 5 MHz BW configuration 2 carriers. TX Top frequency in 5 MHz BW configuration 2 carriers. TX Mid frequency in 5 MHz BW configuration 2 carriers. ll RX frequencies were configured 8 MHz below the corresponding TXX frequency according the applicable duplex offset for the operating band.

10 P8534--F24 8 () ppendix Test setup conducted measurement ts Test object. RD 2242 B4, KRY 9 328/, revision R2B, s/n: C (FCC ID: T8KRY9328- and IC: 287B-S9328) with software: CXP / 4, revision R59FC ssociated equipment: 2. RBS 622: BYB 9 4/, revision R3B, s/n: TU8J DUS 4, KDU /, revision R5/ /, s/n: D6H5594 IRU 2242, KRC 6 444/, revision RC, s/ /n: C Patch panel, BGK 9 55/, revision R, s/n: - 6. GPS 2, NCD 9 4/, revision RD, s/ /n: TU8K GPS ctive ntenna, KRE 282/ Functional test equipment: 4. Switch Netgear FS726T 5. Laptop EliteBook 854w 8. ttenuator/ Terminator 5 ohm 9. SP test instrument according measurement equipment list

11 P8534--F24 9 () ppendix Test setup radiated measurements Test object. RD 2242 B4, KRY 9 328/, revision R2B, s/n: C (FCC ID: T8KRY9328- and IC: 287B-S9328) with software: CXP / 4, revision R59FC ssociated equipment: 2. RBS 622: BYB 9 4/, revision R3B, s/n: TU8J DUS 4, KDU /, revision R5/ /, s/n: D6H5594 IRU 2242, KRC 6 444/, revision RC, s/ /n: C Patch panel, BGK 9 55/, revision R, s/n: - 6. GPS 2, NCD 9 4/, revision RD, s/ /n: TU8KH GPS ctive ntenna, KRE 282/ Functional test equipment: 6. Netgear switch FS726T 7. HP Elitebook 854w 8. ttenuator/ Terminator 5 ohm

12 P8534--F24 () ppendix Interfaces: ntenna port (), hirose connector ntenna port (B), hirose connector DIF, Patch cable Cat 6a Schneider Electric ctassi CL-MNC6 Type off port: ntenna ntenna Signal RBS software: Software CXP 2 5/22 Revision R46L

13 P8534--F24 (6)) ppendix 2 RF power output measurementss according to CFR / IC RSS , conducted Temperature 22 C ± 3 C 22 C ± 3 C 2 C ± 3 C 22 C ± 3 C 22 C ± 3 C Humidity H 2 % ± 5 % 2 % ± 5 % 2 % ± 5 % 8 % ± 5 % 8 % ± 5 % Test set-up and procedure The test object was connected to a signal analyser measuring peak p and RMS output power in CDF mode. resolution bandwidth of 5 MHz was used. Measurement equipment R&S FSQ 4 RF attenuator Testo 635, temperature and humidity meter SPP number Measurement uncertainty:. db

14 P8534--F24 2 (6)) ppendix 2 Results Configuration: RDI Cable 2 m MIMO mode, single carrier Rated outputt power levell at RF connector x 7 dbm. Carrier BW [MHz] Symbolic name T T T T Port RF 6.49/ / / / 7.8 [RMS dbm/ PR db] Port RF B 7. 84/ / / / 7.79 Total power ) MIMO mode, multi carrier Rated outputt power levell at RF connector 2x 4 dbm. Carrier BW [MHz] Symbolic name B2-5 M2-5 T2-5 T2- T2-5 T2-2 Port RF 4.9/ / / / / 8. [RMS dbm/ PR db] Port RF B 5. 49/ / / / / / 8.3 Total power ) ) : Summed output powerr according to FCC KDB6629 D Multiple transmitter output v2r. Note: The PR value is the t. % Peak to verage Ratio.

15 P8534--F24 3 (6)) ppendix 2 Configuration: RDI Cable 92 m MIMO mode, single carrier Rated outputt power levell at RF connector x 7 dbm. Carrier BW [MHz] Symbolic name M T T T Port RF 5.9/ / / / 7.79 [RMS dbm/ PR db] Port RF B 7. 47/ / / / 7.86 Total power ) MIMO mode, multi carrier Rated outputt power levell at RF connector 2x 4 dbm. Carrier BW Symbolic [RMS dbm/ PR db] [MHz] name Port RF Port RF B 5 B / / M / / T / / 7.76 Total power ) ) : Summed v2r. output power according to FCC KDB6629 D Multiple transmitter output Note: The PR value is the t. % Peak to verage Ratio.

16 P8534--F24 4 (6)) ppendix 2 Configuration: RDI Cable 2 m MIMO mode, single carrier Rated outputt power levell at RF connector x 7 dbm. Carrier BW [MHz] Symbolic name M M T T Port RF 6.47/ / / / 7.8 [RMS dbm/ PR db] Port RF B 6. 82/ / / / 7.84 Total power ) MIMO mode, multi carrier Rated outputt power levell at RF connector 2x 4 dbm. Carrier BW Symbolic [RMS dbm/ PR db] [MHz] name Port RF Port RF B 5 B / / M / / T / / 7.79 Total power ) ) : Summed v2r. output power according to FCC KDB6629 D Multiple transmitter output Note: The PR value is the t. % Peak to verage Ratio.

17 P8534--F24 5 (6)) ppendix 2 Configuration: RDI Cable 2 m MIMO mode, single carrier Measured output power per MHz. Carrier BW Symbolic [RMS dbm] [MHz] name Portt RF Port RF B 5 T T T T Total power ) [RMS dbm] Configuration: RDI Cable 92 m MIMO mode, single carrier Measured output power per MHz. Carrier BW Symbolic [RMS dbm] [MHz] name Portt RF Port RF B 5 M T T T Total power ) [RMS dbm] ) : Measured according to FCC KDB6629 D Multiple Transmitter Output v2r. Method E), 2), c). Measure and add log(n nt ).

18 P8534--F24 6 (6)) ppendix 2 Configuration: RDI Cable 2 m MIMO mode, single carrier Measured output power per MHz. Carrier BW Symbolic [RMS dbm] [MHz] name Portt RF Port RF B 5 M.4.89 M T T Total power ) [RMS dbm] ) : Measured according to FCC KDB6629 D Multiple Transmitter Output v2r. Method E), 2), c). Measure and add log(n nt ). Limits The maximumm output power may not exceed 328 W/MHz (EIRP). The Peak to verage Ratioo (PR) may not exceedd 3 db. RSS-33 Base station transmitters operating in the band MHzz shall not have output power exceeding watts. When the transmitter power is measured in terms of average value, thee peak-to-average ratio(pr) of the power shall not exceed 3 db There is no EIRP limit specified for base station equipment in the RSS-33. EIRP compliance is addressed at the time of licensing, as required by the responsible IC Bureau. Licensee s are required to take t into account the antenna gain to get the maximum usable power settings to prevent p the radiated output power to exceed the EIRPP limits specified in SRSP-5 Complies? Yes

19 P8534--F24 (4)) ppendix 3 RF power output measurementss according to CFR / IC RSS , radiated Temperature 22 C ± 3 C 22 C ± 3 C Humidity H 8 % ± 5 % 2 % ± 5 % Test set-up and procedure The measurements were performed according to NSI/TI-6 3-C. The test was performed with continuous transmission. The test of radiated emission was performed in a semi anechoic chamber. The measurements were performed with both horizontal and vertical polarizations of the antenna. The antenna distance was 3. m. The fundamental was scanned with PEK-detector with the antenna height was varied between -4 m and the turntable was rotated between -36 degrees for maximum response. The carrier power was measured withh RMS- detector activatedd with a RBWW of MHz. The output power was verified with the substitution method according tonsi/ti-63-c. The antenna distance during the measurements was 3. m. Measurement equipment Measurement equipment Semi anechoic chamber R&S ESU 26 EMC 32 ver EMCO Horn ntenna 35 EMCO Horn ntenna 35 Coaxial cable R&S SMB ttenuator Testo 635 temperature and humidity meter SP number BX Measurement uncertainty: 3. db

20 P8534--F24 2 (4)) ppendix 3 The test set-up during the effective radiated outpu power measurements iss shown in the picture below, side position. The test set-up during the effective radiated outpu power measurements iss shown in the picture below, upright position.

21 P8534--F24 3 (4)) ppendix 3 Results Configuration: RDI Cable 2 m Upright position Bandwidth configuration (MHz) Symbolic namee B Symbolic name n M Vertical/Horizontal RMS power (EIRP) Vertical/Hor izontal RMS power (EIRP) dbm/ MHz 9.8/ mw/ MHz 9.5/ / dbm/ MHz 2.3/ / / / 7.5 mw/ m MHz 7./ / / / 5.6 Symbolic name T Vertical/ Horizontal RMS power (EIRP) dbm/ MHz mw/ MHz 2.3/ / Side position Bandwidth configuration (MHz) Symbolic namee B Symbolic name n M Vertical/Horizontal RMS power (EIRP) Vertical/Hor izontal RMS power (EIRP) dbm/ MHz 8.3/. - mw/ MHz 6.8/ / dbm/ MHz./ /.4 mw/ m MHz 2.6/ /. 7.2/ / 9. 6./ / 6.6 Symbolic name T Vertical/ Horizontal RMS power (EIRP) dbm/ MHz mw/ MHz.3/ /

22 P8534--F24 4 (4)) ppendix 3 Limits The maximumm output power may not exceed 328 W/MHz (EIRP). The Peak to verage Ratioo (PR) may not exceedd 3 db. RSS-33 Base station transmitters operating in the band MHzz shall not have output power exceeding watts. When the transmitter power is measured in terms of average value, thee peak-to-average ratio(pr) of the power shall not exceed 3 db There is no EIRP limit specified for base station equipment in the RSS-33. EIRP compliance is addressed at the time of licensing, as required by the responsible IC Bureau. Licensee s are required to take t into account the antenna gain to get the maximum usable power settings to prevent p the radiated output power to exceed the EIRPP limits specified in SRSP-5 Complies? Yes

23 P8534--F24 (9)) ppendix 4 Occupied bandwidth measurements according to 47 CFR C / RSS-Gen Temperature 22 C ± 3 C 22 C ± 3 C 2 C ± 3 C Humidity H 2 % ± 5 % 2 % ± 5 % 2 % ± 5 % Test set-up and procedure The measurements were made according to in FCC: KDB: 9768 D Power Meas Licens, v2r2 and IC: RSS-Gen section 6.6. The output was connected too a signal analyzer with the Peak detector activated and max hold. The signal analyser was connected to an external MHz reference standard during the measurements. Measurement equipment R&S FSQ 4 RF attenuator Testo 635, temperature and humidity meter SPP number Measurement uncertainty: 3.7 db

24 P8534--F24 2 (9)) ppendix 4 Results Configuration: RDI Cable 92 m MIMO mode, single carrier Diagram BW configuration Symbolic name Tested Port Occupied BW (99%) [MHz] 5 MHz B RF R B MHz M RF R B MHz T RF R B 4.48 Configuration: RDI Cable 2 m MIMO mode, single carrier Diagram BW configuration Symbolic name Tested Port Occupied BW (99%) [MHz] 4 5 MHz B RF R B MHz M RF R B MHz T RF MHz T RF R B MHz M RF R B MHz M RF R B MHz M RF R B 7.78 Configuration: RDI Cable 2 m MIMO mode, single carrier Diagram BW configuration Symbolic name Tested Port Occupied BW (99%) [MHz] 5 MHz B RF R B MHz M RF R B MHz T RF R B 4.47

25 P8534--F24 3 (9) ppendix 4 Diagram : Ref 4 dbm 4 3 RM * 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s -5.2 dbm.9325 GHz OBW MHz Temp [T OBW] dbm.9327 GHz Temp 2 [T OBW] dbm GHz T T Center.9325 GHz.5 MHz/ Span 5 MHz : 22.JN.25 :49:49 Diagram 2: Ref 45 dbm 4 RM * 3 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.96 GHz OBW 4.48 MHz Temp [T OBW] -2.6 dbm GHz Temp 2 [T OBW] -2.9 dbm GHz T T Center.96 GHz.5 MHz/ Span 5 MHz : 22.JN.25 8:2:4

26 P8534--F24 4 (9) ppendix 4 Diagram 3: Ref 4 dbm 4 3 RM * 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.9875 GHz OBW MHz Temp [T OBW] dbm GHz Temp 2 [T OBW] -4.7 dbm GHz T T Center.9875 GHz.5 MHz/ Span 5 MHz : 22.JN.25 :32:26 Diagram 4: Ref 45 dbm 4 RM * 3 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.9325 GHz OBW MHz Temp [T OBW] -7. dbm.9327 GHz Temp 2 [T OBW] dbm GHz T T Center.9325 GHz.5 MHz/ Span 5 MHz : 2.JN.25 :2:6

27 P8534--F24 5 (9) ppendix 4 Diagram 5: Ref 45 dbm 4 RM * 3 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.96 GHz OBW MHz Temp [T OBW] dbm GHz Temp 2 [T OBW] -3.2 dbm GHz T T Center.96 GHz.5 MHz/ Span 5 MHz : 2.JN.25 8:39:44 Diagram 6: Ref 45 dbm 4 RM * 3 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.9875 GHz OBW MHz Temp [T OBW] dbm GHz Temp 2 [T OBW] dbm GHz T T Center.9875 GHz.5 MHz/ Span 5 MHz : 2.JN.25 :45:28

28 P8534--F24 6 (9) ppendix 4 Diagram 7: Ref 45 dbm 4 RM * 3 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.9875 GHz OBW MHz Temp [T OBW] -.57 dbm GHz Temp 2 [T OBW] -3.5 dbm GHz T T Center.9875 GHz.5 MHz/ Span 5 MHz : 2.JN.25 4:55:39 Diagram 8: Ref 45 dbm 4 RM * 3 2 * RBW khz VBW MHz * tt 5 db * SWT 2 s -.53 dbm.985 GHz OBW 8.9 MHz Temp [T OBW] -.6 dbm.9852 GHz Temp 2 [T OBW] dbm GHz T T Center.985 GHz 3 MHz/ Span 3 MHz : 2.JN.25 8:4:4

29 P8534--F24 7 (9) ppendix 4 Diagram 9: Ref 45 dbm 4 RM * 3 2 * RBW 2 khz VBW 2 MHz * tt 5 db * SWT 2 s.78 dbm.9825 GHz OBW MHz Temp [T OBW].6 dbm GHz Temp 2 [T OBW] -.36 dbm GHz T T Center.9825 GHz 4.5 MHz/ Span 45 MHz : 2.JN.25 2:9:44 Diagram : Ref 4 dbm 4 3 RM * 2 * RBW 2 khz VBW 2 MHz * tt 5 db * SWT 2 s.3 dbm.98 GHz OBW 7.78 MHz Temp [T OBW] -.52 dbm.978 GHz Temp 2 [T OBW] dbm GHz T T Center.98 GHz 6 MHz/ Span 6 MHz : 2.JN.25 :33:6

30 P8534--F24 8 (9) ppendix 4 Diagram : MRKER.9325 GH Hz Ref 4 dbm 4 3 RM * 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.9325 GHz OBW 4.47 MHz Temp [T OBW] dbm.9327 GHz Temp 2 [T OBW] -4.5 dbm GHz T T Center.9325 GHz.5 MHz/ Span 5 MHz : 22.JN.25 4:47:49 Diagram 2: Ref 4 dbm 4 3 RM * 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s dbm.96 GHz OBW MHz Temp [T OBW] -3. dbm GHz Temp 2 [T OBW] dbm GHz T T Center.96 GHz.5 MHz/ Span 5 MHz : 22.JN.25 4:44:57

31 P8534--F24 9 (9) ppendix 4 Diagram 3: Ref 4 dbm 4 3 RM * 2 * RBW 5 khz VBW 5 khz * tt 5 db * SWT 2 s -5.5 dbm.9875 GHz OBW 4.47 MHz Temp [T OBW] dbm GHz Temp 2 [T OBW] -6.2 dbm GHz T T Center.9875 GHz.5 MHz/ Span 5 MHz : 22.JN.25 4:39:55

32 P8534--F24 (38) ppendix 5 Band edge measurements according to CFR / IC RSS Temperature 22 C ± 3 C 22 C ± 3 C 2 C ± 3 C 22 C ± 3 C Humidity H 2 % ± 5 % 2 % ± 5 % 2 % ± 5 % 8 % ± 5 % Test set-up and procedure The measurements were made per definition in The test t object was connected to a spectrum analyser with the RMS detector activated. The spectrum analyzer was connected to an external MHz reference standard during the measurements. Beyond the st MHz off the band edges the limit was adjusted to compensate for reduced measurement bandwidthss pursuant too the FCC rules, specifying a RBW off at least % of the fundamental emission bandwidth up to MHz away from the band edges and a RBW of MHz for measurements of emissions more than MHz away from the band edges. resolution bandwidth of 2 khz was used MHz to 6 MHz away fromm the band edges, to compensate for the reduced resolutionn bandwidth the limit was adjusted byy 7 db to -2 dbm. 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 43 RF attenuator Testo 635, temperature and humidity meter SPP number Measurement uncertainty: 3.7 db

33 P8534--F24 2 (38) ppendix 5 Results Configuration: RDI Cable 92 m MIMO mode, single carrier Diagram BW configuration a-c 5 MHz 2 a-c 5 MHz MIMO mode, multi carrier Diagram BW configuration 3 a-c 5 MHz 4 a-c 5 MHz Configuration: RDI Cable 2 m MIMO mode, single carrier Diagram BW configuration 5 a-c 5 MHz 6 a-c 5 MHz 7 a-c MHz 8 a-c 5 MHz 9 a-c 2 MHz a-c 5 MHz a-c 5 MHz 2 a-c MHz 3 a-c 5 MHz 4 a-c 2 MHz MIMO mode, multi carrier Diagram BW configuration 5 a-c 5 MHz 6 a-c 5 MHz Configuration: RDI Cable 2 m MIMO mode, single carrier Diagram BW configuration 7 a-c 5 MHz 8 a-c 5 MHz Symbolic name B T Symbolic name B2-5 T2-5 Symbolic name B B B B B T T T T T Symbolic name B2-5 T2-5 Tested frequency B T Tested Port RF B RF B Tested Port RF B RF B Tested Port RF RF B RF B RF B RF B RF RF B RF B RF B RF B Tested Port RF B RF B Tested Port RF B RF B Limits CFR and RSS Outside a licensee's frequency band(s) of operation the power 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

34 P8534--F24 3 (38) ppendix 5 Diagram a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 22.JN.25 :45:2 Diagram b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 22.JN.25 :46:38

35 P8534--F24 4 (38) ppendix 5 Diagram c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 22.JN.25 :47:34

36 P8534--F24 5 (38) ppendix 5 Diagram 2 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 22.JN.25 :28:4 Diagram 2 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s -4. dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 22.JN.25 :29:6

37 P8534--F24 6 (38) ppendix 5 Diagram 2 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 22.JN.25 :29:49

38 P8534--F24 7 (38) ppendix 5 Diagram 3 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 23.JN.25 3:58:3 Diagram 3 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 23.JN.25 4::5

39 P8534--F24 8 (38) ppendix 5 Diagram 3 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 23.JN.25 4::4

40 P8534--F24 9 (38) ppendix 5 Diagram 4 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 23.JN.25 4:9:56 Diagram 4 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 23.JN.25 4::24

41 P8534--F24 (38) ppendix 5 Diagram 4 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s -4.4 dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 23.JN.25 4:3:2

42 P8534--F24 (38) ppendix 5 Diagram 5 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s -44. dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 2.JN.25 :25:33 Diagram 5 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 2.JN.25 :27:8

43 P8534--F24 2 (38) ppendix 5 Diagram 5 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 2.JN.25 :28:3

44 P8534--F24 3 (38) ppendix 5 Diagram 6 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 2.JN.25 :7:5 Diagram 6 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 2.JN.25 :6:45

45 P8534--F24 4 (38) ppendix 5 Diagram 6 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s -4.7 dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 2.JN.25 :5:4

46 P8534--F24 5 (38) ppendix 5 Diagram 7 a: Ref 5 dbm 5 * RBW khz VBW MHz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 2.JN.25 ::27 Diagram 7 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s -4.5 dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 2.JN.25 ::29

47 P8534--F24 6 (38) ppendix 5 Diagram 7 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 2.JN.25 :2:36

48 P8534--F24 7 (38) ppendix 5 Diagram 8 a: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 2.JN.25 9:58:9 Diagram 8 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s -4.7 dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 2.JN.25 9:56:28

49 P8534--F24 8 (38) ppendix 5 Diagram 8 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 2.JN.25 9:55:33

50 P8534--F24 9 (38) ppendix 5 Diagram 9 a: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 2.JN.25 9:5:26 Diagram 9 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 2.JN.25 9:52:35

51 P8534--F24 2 (38) ppendix 5 Diagram 9 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s -4.2 dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 2.JN.25 9:53:33

52 P8534--F24 2 (38) ppendix 5 Diagram a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 2.JN.25 :4:26 Diagram b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s -4.7 dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 2.JN.25 :4:35

53 P8534--F24 22 (38) ppendix 5 Diagram c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 2.JN.25 :42:35

54 P8534--F24 23 (38) ppendix 5 Diagram a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 2.JN.25 4:58:8 Diagram b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 2.JN.25 4:59:32

55 P8534--F24 24 (38) ppendix 5 Diagram c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 2.JN.25 5::57

56 P8534--F24 25 (38) ppendix 5 Diagram 2 a: Ref 5 dbm 5 * RBW khz VBW MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 2.JN.25 8:45: Diagram 2 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 2.JN.25 8:46:48

57 P8534--F24 26 (38) ppendix 5 Diagram 2 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 2.JN.25 8:47:43

58 P8534--F24 27 (38) ppendix 5 Diagram 3 a: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 2.JN.25 2::25 Diagram 3 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 2.JN.25 2:2:47

59 P8534--F24 28 (38) ppendix 5 Diagram 3 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 2.JN.25 2:3:59

60 P8534--F24 29 (38) ppendix 5 Diagram 4 a: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 2.JN.25 :28:3 Diagram 4 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s -4.4 dbm GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 2.JN.25 :29:22

61 P8534--F24 3 (38) ppendix 5 Diagram 4 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 2.JN.25 :3:4

62 P8534--F24 3 (38) ppendix 5 Diagram 5 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 23.JN.25 7:29:4 Diagram 5 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 23.JN.25 7:3:27

63 P8534--F24 32 (38) ppendix 5 Diagram 5 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s -4.4 dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 23.JN.25 7:3:2

64 P8534--F24 33 (38) ppendix 5 Diagram 6 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 23.JN.25 7:25:2 Diagram 6 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 23.JN.25 7:26:3

65 P8534--F24 34 (38) ppendix 5 Diagram 6 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 23.JN.25 7:27:2

66 P8534--F24 35 (38) ppendix 5 Diagram 7 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.93 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.93 GHz : 22.JN.25 4:5:3 Diagram 7 b: Ref 4 dbm 4 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s -4.7 dbm GHz 3 RM * D -2 dbm GHz 5 khz/ Stop.929 GHz : 22.JN.25 4:52:43

67 P8534--F24 36 (38) ppendix 5 Diagram 7 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s -46. dbm.924 GHz 4 RM * D -3 dbm GHz MHz/ Stop.924 GHz : 22.JN.25 4:53:42

68 P8534--F24 37 (38) ppendix 5 Diagram 8 a: Ref 5 dbm 5 * RBW 5 khz VBW 5 khz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -3 dbm GHz F 2 khz/ Stop.99 GHz : 22.JN.25 5:2:3 Diagram 8 b: Ref 5 dbm 5 * RBW 2 khz VBW 2 MHz * tt 2 db * SWT s dbm.99 GHz 4 RM * D -2 dbm GHz 5 khz/ Stop.996 GHz : 22.JN.25 5:3:47

69 P8534--F24 38 (38) ppendix 5 Diagram 8 c: Ref 5 dbm 5 * RBW MHz VBW MHz * tt 2 db * SWT s dbm.996 GHz 4 RM * D -3 dbm GHz MHz/ Stop 2.6 GHz : 22.JN.25 5:4:38

70 P8534--F24 (52) ppendix 6 Conducted spurious emission measurements according to CFR / IC RSS Temperature 22 C ± 3 C 22 C ± 3 C 2 C ± 3 C 22 C ± 3 C 22 C ± 3 C Humidity H 2 % ± 5 % 2 % ± 5 % 2 % ± 5 % 8 % ± 5 % 8 % ± 5 % Test set-up and procedure The measurements were made per definition in The 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 4 RF attenuator HP filter Testo 635, temperature and humidity meter SPP number BX Measurement uncertainty: 3.7 db

71 P8534--F24 2 (52) ppendix 6 Results Configuration: RDI Cable 92 m MIMO mode, single carrier Diagram BW configuration / [MHz] Symbolic name Tested Port a+b+c+d 5 MHz B RF B 2 a+b+c+d 5 MHz M RF B 3 a+b+c+d 5 MHz T RF B MIMO mode, multi carrier Diagram BW configuration Symbolic name Tested Port 4 a+b+c+d+ +e 5 MHz B2/T2im22 RF B

72 P8534--F24 3 (52) ppendix 6 Configuration: RDI Cable 2 m MIMO mode, single carrier Diagram BW configuration / [MHz] Symbolic name Tested Port 5 a+b+c+d+ +e 5 MHz B RF B 6 a+b+c+d+ +e 5 MHz M RF B 7 a+b+c+d+ +e 5 MHz T RF 8 a+b+c+d+ +e 5 MHz T RF B 9 a+b+c+d+ +e MHz T RF B a+b+c+d+e 5 MHz T RF B a+b+c+d+e 2 MHz T RF B MIMO mode, multi carrier Diagram BW configuration Symbolic name Tested Port 2 a+b+c+d+e 5 MHz B2im RF B 3 a+b+c+d+e 5 MHz T2im RF B 4 a+b+c+d+e 5 MHz B2/T2im22 RF B 5 a+b+c+d+e 2 MHz T2-2 RF B 6 a 5 MHz T2-5 RF B 7 a MHz T2- RF B Configuration: RDI Cable 2 m MIMO mode, single carrier Diagram BW configuration / [MHz] Symbolic name Tested Port 8 a+b+c+ +d 5 MHz M RF B MIMO mode, multi carrier Diagram BW configuration Symbolic name Tested Port 9 a+b+c+d+e 5 MHz B2/T2im22 RF B

73 P8534--F24 4 (52) ppendix 6 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.99 GHz. The measurements were made up to 2 GHz (x.99 GHz = 9.9 GHz). Limits and RSS Outside a licensee's frequency band(s) of operation the power 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

74 P8534--F24 5 (52) ppendix 6 Diagram a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 2 [T ] dbm GHz dbm.9325 GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 22.JN.25 :43:26 Diagram b: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 22.JN.25 8:43:25

75 P8534--F24 6 (52) ppendix 6 Diagram c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 22.JN.25 8:44:24 Diagram d: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 22.JN.25 8:42:2

76 P8534--F24 7 (52) ppendix 6 Diagram 2 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 2 [T ] dbm GHz dbm.96 GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 22.JN.25 8:22:56 Diagram 2 b: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 22.JN.25 8:27:2

77 P8534--F24 8 (52) ppendix 6 Diagram 2 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 22.JN.25 8:29:8 Diagram 2 d: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 22.JN.25 8:39:5

78 P8534--F24 9 (52) ppendix 6 Diagram 3 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 2 [T ] dbm GHz dbm.9875 GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 22.JN.25 :27:2 Diagram 3 b: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 22.JN.25 8:47:35

79 P8534--F24 (52) ppendix 6 Diagram 3 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 22.JN.25 8:45:24 Diagram 3 d: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 22.JN.25 8:46:3

80 P8534--F24 (52) ppendix 6 Diagram 4 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s 8.89 dbm.9496 GHz RM * Marker 2 [T ] 9.78 dbm.974 GHz Marker 3 [T ] dbm GHz D -3 dbm khz MHz/ Stop 3 GHz : 26.JN.25 9:35:7 Diagram 4 b: Ref 4 dbm 4 3 RM * 2 * RBW MHz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz Marker 2 [T ] 8.88 dbm.9496 GHz Marker 3 [T ] 9.85 dbm.974 GHz Marker 4 [T ] dbm.99 GHz - D -3 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 26.JN.25 9:38:9

81 P8534--F24 2 (52) ppendix 6 Diagram 4 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 26.JN.25 9:39:5 Diagram 4 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 26.JN.25 9:4:7

82 P8534--F24 3 (52) ppendix 6 Diagram 4 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 26.JN.25 9:42:6

83 P8534--F24 4 (52) ppendix 6 Diagram 5 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s 8.27 dbm.9325 GHz 5 4 Marker 2 [T ] dbm GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 8:58:27 Diagram 5 b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] -2.4 dbm.9325 GHz Marker 3 [T ] dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 2.JN.25 8:55:47

84 P8534--F24 5 (52) ppendix 6 Diagram 5 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 :9:26 Diagram 5 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 :2:43

85 P8534--F24 6 (52) ppendix 6 Diagram 5 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 :2:53

86 P8534--F24 7 (52) ppendix 6 Diagram 6 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s dbm GHz 5 4 Marker 2 [T ]. dbm.96 GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 8:49:36 Diagram 6 b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ].5 dbm.96 GHz Marker 3 [T ] dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 2.JN.25 8:5:34

87 P8534--F24 8 (52) ppendix 6 Diagram 6 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 :26:26 Diagram 6 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 :25:9

88 P8534--F24 9 (52) ppendix 6 Diagram 6 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 :23:43

89 P8534--F24 2 (52) ppendix 6 Diagram 7 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 2 [T ] dbm GHz dbm.9875 GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 :36: Diagram 7 b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] -.63 dbm.9875 GHz Marker 3 [T ] -4. dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 2.JN.25 :37:45

90 P8534--F24 2 (52) ppendix 6 Diagram 7 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 :29:23 Diagram 7 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 :3:33

91 P8534--F24 22 (52) ppendix 6 Diagram 7 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 :3:59

92 P8534--F24 23 (52) ppendix 6 Diagram 8 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s.42 dbm.9875 GHz 5 4 Marker 2 [T ] dbm GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 9::38 Diagram 8 b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ]. dbm.9875 GHz Marker 3 [T ] dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 2.JN.25 5:8:2

93 P8534--F24 24 (52) ppendix 6 Diagram 8 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s -5.7 dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 5:7:49 Diagram 8 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 5:9:

94 P8534--F24 25 (52) ppendix 6 Diagram 8 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 5::2

95 P8534--F24 26 (52) ppendix 6 Diagram 9 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s.3 dbm.985 GHz 5 4 Marker 2 [T ] dbm GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 9:43:5 Diagram 9 b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] -.5 dbm.985 GHz Marker 3 [T ] dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 2.JN.25 9:23:9

96 P8534--F24 27 (52) ppendix 6 Diagram 9 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 9:25:29 Diagram 9 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 9:27:6

97 P8534--F24 28 (52) ppendix 6 Diagram 9 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 9:3:49

98 P8534--F24 29 (52) ppendix 6 Diagram a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s 8.54 dbm.9825 GHz 5 4 Marker 2 [T ] dbm GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 9:46:3 Diagram b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] -.8 dbm.9825 GHz Marker 3 [T ] dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 2.JN.25 9:46:4

99 P8534--F24 3 (52) ppendix 6 Diagram c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 9:36:8 Diagram d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 9:34:27

100 P8534--F24 3 (52) ppendix 6 Diagram e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 9:33:2

101 P8534--F24 32 (52) ppendix 6 Diagram a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s 7.47 dbm.98 GHz 5 4 Marker 2 [T ] dbm GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 2.JN.25 9:48:2 Diagram b: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] dbm.98 GHz Marker 3 [T ] dbm.99 GHz D -23 dbm F F2.9 GHz 2 MHz/ Stop 2.2 GHz : 2.JN.25 9:49:9

102 P8534--F24 33 (52) ppendix 6 Diagram c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 2.JN.25 9:38:2 Diagram d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 2.JN.25 9:39:7

103 P8534--F24 34 (52) ppendix 6 Diagram e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 2.JN.25 9:4:33

104 P8534--F24 35 (52) ppendix 6 Diagram 2 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 3 [T ] dbm GHz RM * dbm.9375 GHz Marker 2 [T ] 7.73 dbm.9462 GHz D -3 dbm khz MHz/ Stop 3 GHz : 23.JN.25 7:4:2 Diagram 2 b: Ref 4 dbm 4 3 RM * 2 * RBW MHz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz Marker 2 [T ] 6.7 dbm.9375 GHz Marker 3 [T ] 7.76 dbm.9462 GHz Marker 4 [T ] dbm.99 GHz - D -3 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 23.JN.25 7:38:7

105 P8534--F24 36 (52) ppendix 6 Diagram 2 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s -5.6 dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 23.JN.25 7:42:5 Diagram 2 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 23.JN.25 7:48:

106 P8534--F24 37 (52) ppendix 6 Diagram 2 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 23.JN.25 7:48:58

107 P8534--F24 38 (52) ppendix 6 Diagram 3 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 3 [T ] dbm GHz RM * dbm.9738 GHz Marker 2 [T ].3 dbm.9825 GHz D -3 dbm khz MHz/ Stop 3 GHz : 23.JN.25 7:57:44 Diagram 3 b: Ref 4 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] 9.54 dbm.9738 GHz Marker 3 [T ].22 dbm.9825 GHz Marker 4 [T ] dbm.99 GHz - D -3 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 23.JN.25 7:56:8

108 P8534--F24 39 (52) ppendix 6 Diagram 3 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 23.JN.25 7:53:5 Diagram 3 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 23.JN.25 7:5:57

109 P8534--F24 4 (52) ppendix 6 Diagram 3 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 23.JN.25 7:5:5

110 P8534--F24 4 (52) ppendix 6 Diagram 4 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s 8.9 dbm.9496 GHz RM * Marker 2 [T ] 9.87 dbm.974 GHz Marker 3 [T ] dbm.9288 GHz D -3 dbm khz MHz/ Stop 3 GHz : 23.JN.25 8:7:5 Diagram 4 b: Ref 4 dbm 4 3 RM * 2 * RBW MHz VBW MHz * tt 2 db * SWT 2 s 2 3 Marker 4 [T ] dbm.99 GHz dbm.93 GHz Marker 2 [T ] 8.3 dbm.9496 GHz Marker 3 [T ] 9.96 dbm.974 GHz - D -3 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 23.JN.25 8:2:58

111 P8534--F24 42 (52) ppendix 6 Diagram 4 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s -5.9 dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 23.JN.25 8:33:49 Diagram 4 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 23.JN.25 8:34:56

112 P8534--F24 43 (52) ppendix 6 Diagram 4 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 23.JN.25 8:35:56

113 P8534--F24 44 (52) ppendix 6 Diagram 5 a: Ref 5 dbm * tt 2 db * RBW MHz VBW MHz * SWT 2 s Marker [T ].72 dbm.96 GHz RM * Marker 2 [T ] 4.37 dbm.98 GHz Marker 3 [T ] dbm GHz D -3 dbm khz MHz/ Stop 3 GHz : 23.JN.25 9:3:2 Diagram 5 b: MRKER.93 GHz Ref 4 dbm 4 3 RM * 2 - * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz Marker 2 [T ] dbm.96 GHz Marker 3 [T ] -7.3 dbm.98 GHz Marker 4 [T ] dbm.99 GHz -2-3 D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 23.JN.25 8:53:6

114 P8534--F24 45 (52) ppendix 6 Diagram 5 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 23.JN.25 8:49:56 Diagram 5 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s -43. dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 23.JN.25 8:49:

115 P8534--F24 46 (52) ppendix 6 Diagram 5 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 23.JN.25 8:47:36

116 P8534--F24 47 (52) ppendix 6 Diagram 6a: Ref 4 dbm * tt * RBW khz VBW MHz 2 db * SWT 2 s dbm..93 GHz RM * Marker 2 [T ] dbm GHz Marker 3 [T ] dbm GHz Marker 4 [T ] dbm..99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 23.JN.25 :43:46 Diagram 7 a: Ref 4 dbm * RBW khz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz RM * Marker 2 [T ] dbm.975 GHz Marker 3 [T ] dbm.985 GHz Marker 4 [T ] dbm.99 GHz D -23 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 23.JN.25 :47:56

117 P8534--F24 48 (52) ppendix 6 Diagram 8 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 2 [T ] dbm GHz dbm.96 GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 22.JN.25 5::38 Diagram 8 b: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 22.JN.25 5:4:2

118 P8534--F24 49 (52) ppendix 6 Diagram 8 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 22.JN.25 5:5:33 Diagram 8 d: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 22.JN.25 5:6:5

119 P8534--F24 5 (52) ppendix 6 Diagram 9 a: Ref 5 dbm * RBW MHz VBW MHz * tt 2 db * SWT 2 s Marker 2 [T ] 8.73 dbm.974 GHz 5 4 Marker 3 [T ] dbm GHz RM * D -3 dbm khz MHz/ Stop 3 GHz : 26.JN.25 9:57:5 Diagram 9 b: Ref 4 dbm 4 3 RM * 2 * RBW MHz VBW MHz * tt 2 db * SWT 2 s dbm.93 GHz Marker 2 [T ] 8.57 dbm.9496 GHz Marker 3 [T ] 8.7 dbm.974 GHz Marker 4 [T ] dbm.99 GHz - D -3 dbm F F2 Center.96 GHz 2 MHz/ Span 2 MHz : 26.JN.25 9:55:24

120 P8534--F24 5 (52) ppendix 6 Diagram 9 c: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm GHz Offset.5 db RM * - -M LVL GHz 7 MHz/ Stop GHz : 26.JN.25 9:53:4 Diagram 9 d: Ref 5 dbm * RBW MHz VBW MHz * tt db * SWT 7 s dbm 3.55 GHz Offset.7 db RM * - -M LVL GHz 6 MHz/ Stop 6 GHz : 26.JN.25 9:5:8

121 P8534--F24 52 (52) ppendix 6 Diagram 9 e: Ref dbm * RBW MHz VBW MHz * tt db * SWT 6 s dbm GHz Offset.7 db RM * - -M LVL GHz 4 MHz/ Stop 2 GHz : 26.JN.25 9:49:5

122 P8534--F24 (5)) ppendix 7 Field strength of spurious radiation measurements according too CFR / IC RSS Temperature 23 C ± 3 C 22 C ± 3 C 22 C ± 3 C Humidity H 24 % ± 5 % 27 % ± 5 % 8 % ± 5 % Test set-up and procedure The test sitess are listed att FCC, Columbia with registration number: The test site complies with RSS-Gen, Industry Canada file no 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 and m in the frequency range 8 2 GHz. In the frequency range 3 MHz 2 GHz the measurement was w performedd 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 NSI/TI-63-C.

123 P8534--F24 2 (5)) ppendix 7 The test set-up during the spurious radiation measurements is shown in thee picture below: Measurement equipment Measurement equipment Semi anechoic chamber R&S ESU 26 EMC32 ver Chase Bilog ntenna CBL 6 EMCO Horn ntenna 35 Flann STD Gain Horn ntenna 6-24 Flann STD Gain Horn ntenna 8-24 Flann STD Gain Horn ntenna µcomp Nordic, Low Noise mplifierr Schwarzbeck BBV9742, Low Noise mplifier HP Filter 3-8 GHz Temperature and humidity meter, Testo 625 SP number n

124 P8534--F24 3 (5)) ppendix 7 Tested configurations Configuration: RDI Cable 2 m Symbolic name B M T T2-5 2 Bandwidth (MHz) 5 5,,5 and Results, representing worst case, T2-5 2 : Diagram a-d Spurious emission level (dbm)( Frequency (MHz) 3-2 Vertical ll emission > 2 dbb below limit Horizontal ll emission > 2 db below limit Measurement uncertainty: 3.2 db up to 8 GHz, 3. db above 8 GHz Limits CFR and RSS Outside a licensee's frequency band(s) of operation the power 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

125 P8534--F24 4 (5)) ppendix 7 Diagram a: - FCC P2-2 Level in dbm Frequency in MHz Diagram b: - FCC P2-2 Level in dbm Frequency in MHz Note: The emission at 97. and MHz are the carrier frequencies s and shall be ignored in the context.

126 P8534--F24 5 (5)) ppendix 7 Diagram c: - FCC P2-2 Level in dbm G 5G G 8G Frequency in Hz Diagram d: - FCCC P2-2 Level in dbm ,2 8,4 8,6 8,8 9 9,2 9,4 9,6 9,8 2 Frequency in GHz

127 P8534--F24 (3)) ppendix 8 Frequency stability measuremen nts according to CFR / IC RSS to Test set-up and procedure Temperature (test equipment) 2-22 C ± 3 C Humidity H (testt equipment) % ± 5 % The measurement was made per 3GPP TS 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 using a resolution bandwidthh of % of the emission bandwidth, a reference point at the unwanted emission level which w 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 was selected, and the frequency at these points was recorded as fl and fh respectively. Measurement equipment Rohde & Schwarz signal analyzer FSQ 4 RF attenuator Testo 635, Temperature and humidityy meter Temperature cabinet SP number

128 P8534--F24 2 (3)) ppendix 8 Results Nominal transmitter frequency was 96. MHz (M) with a bandwidth of 5 MHz. Rated output power level at connector RF (maximum): 7 dbm. Configuration: RDI Cable 2 m Test conditions Supply voltage Temp. DC (V) ( C) Maximum freq. error (Hz)) Measurement uncertainty Frequency error (Hz) Not possible to activate transmitter 4 < ± x - -7

129 P8534--F24 3 (3)) ppendix 8 Configuration: RDI Cable 2 m Test conditions Frequency margin to t band edge at -6dBm Supply voltage DC [V] Temp [ C]. Carrier Bandwidth [MHz]] Test frequency Symbolic name Bottom fl Offset to lower [MHz] band edge (93 MHz) [khz] Test frequency Symbolicc name Top fh [MHz] Offset to upper band edge (99 MHz) [khz] The frequency error results clearly shows that the frequency stability is goodd enough to ensure that the transmitted carrierr stay within the operating band. Remark It was deemed sufficient to test a limited combination of TX frequencies, channel bandwidths configurations with one test model (modulation), as all combinations share a common internal reference to derive the TX frequency from. Limits The frequency stability shall be sufficient to ensure that the fundamental emission stays within the authorized frequency block. RSS Frequency stability: s The carrier frequency shall not depart from the reference frequency in excess of ±. ppm ( ± 96 Hz) for base stations when tested to the temperature and supply voltage variations specified in RSS-Gen. Complies? Yes

130 P8534--F24 () ppendix 9 External photos Top side Bottom B side Side Label