TEST REPORT. No. I17Z60314-GTE03. for. HMD Global Oy. Smart Phone. Model Name: TA-1033 FCC ID: 2AJOTTA with. Hardware Version: EVT

Transcription

1 TEST REPORT No. I7Z634-GTE3 for HMD Global Oy Smart Phone Model Name: T-33 FCC ID: 2JOTT-33 with Hardware Version: EVT Software Version: C_3_5 Issued Date: Note : The test results in this test report relate only to the devices specified in this report. This report shall not be reproduced except in full without the written approval of CTTL. Test Laboratory: FCC Listed: No CTTL,Telecommunication Technology Labs, cademy of Telecommunication Research, MIIT No. 52, Huayuan North Road, Haidian District, Beijing, P. R. China 9. Tel:+86() , Fax:+86() cttl_terminals@catr.cn, website:

2 REPORT HISTORY Report Number Revision Description Issue Date I7Z634-GTE3 Rev. st edition I7Z634-GTE3 Rev. 2nd edition Copyright. ll rights reserved by CTTL Page 2 of 82

3 Page 3 of 82 CONTENTS. TEST LBORTORY TESTING LOCTION TESTING ENVIRONMENT PROJECT DT SIGNTURE CLIENT INFORMTION PPLICNT INFORMTION MNUFCTURER INFORMTION EQUIPMENT UNDER TEST (EUT) ND NCILLRY EQUIPMENT (E) BOUT EUT INTERNL IDENTIFICTION OF EUT USED DURING THE TEST INTERNL IDENTIFICTION OF E USED DURING THE TEST GENERL DESCRIPTION REFERENCE DOCUMENTS REFERENCE DOCUMENTS FOR TESTING LBORTORY ENVIRONMENT SUMMRY OF TEST RESULTS SUMMRY OF TEST RESULTS STTEMENTS TEST EQUIPMENTS UTILIZED... 3 NNEX : MESUREMENT RESULTS OUTPUT POWER EMISSION LIMIT FREQUENCY STBILITY OCCUPIED BNDWIDTH EMISSION BNDWIDTH BND EDGE COMPLINCE CONDUCTED SPURIOUS EMISSION PEK-TO-VERGE POWER RTIO... 8

4 Page 4 of 82. Test Laboratory.. Testing Location Company Name: CTTL,Telecommunication Technology Labs, cademy of ddress: Telecommunication Research, MIIT No. 52, Huayuan North Road, Haidian District, Beijing, P. R. China 9. Telephone: Fax: No. 5, Xueyuan Road, Haidian District, Beijing, P. R. China 9... Testing Environment Normal Temperature: 5-35 Relative Humidity: 2-75%.2. Project data Testing Start Date: Testing End Date: Signature Shen Yi (Prepared this test report) Zhong Nan (Reviewed this test report) Sun Xiang Qian Deputy Director of the laboratory (pproved this test report)

5 Page 5 of Client Information 2.. pplicant Information Company Name: HMD Global Oy ddress /Post: Karaportti 2, 26 Espoo, Finland Contact: Mikko Kahlos mikko.kahlos@hmdglobal.com Telephone: Fax: Manufacturer Information Company Name: HMD Global Oy ddress /Post: Contact: Karaportti 2, 26 Espoo, Finland Mikko Kahlos mikko.kahlos@hmdglobal.com Telephone: Fax:

6 Page 6 of Equipment Under Test (EUT) and ncillary Equipment (E) 3.. bout EUT Description Model Name FCC ID Smart Phone T-33 2JOTT-33 ntenna Integrated Output power 22.74dBm maximum EIRP measured for Band 7 Extreme vol. Limits 3.6VDC to 4.4VDC (nominal: 3.84VDC) Extreme temp. Tolerance C to +5 C Note: Components list, please refer to documents of the manufacturer; it is also included in the original test record of CTTL, Telecommunication Technology Labs, cademy of Telecommunication Research, MIIT Note: The EUT is a variant model of T-2. LL the results are coming from the initial model I7Z Internal Identification of EUT used during the test EUT ID* IMEI HW Version SW Version UT8a EVT C_3_5 UT97a EVT C_3_5 *EUT ID: is used to identify the test sample in the lab internally Internal Identification of E used during the test E ID* Description SN Note E Battery / INBUILT E2 Battery / INBUILT E3 Travel charger / / E4 Travel charger / / E5 USB cable / / E6 Headset / / E7 Travel charger / / E8 Travel charger / / E9 Travel charger / / E Travel charger / / E Model Manufacturer HE36 Capacitance 3mh Nominal voltage 3.82V SCUD(FUJIN) ELECTRONICS CO LTD E2

7 Page 7 of 82 Model HE37 Manufacturer SCUD(FUJIN) ELECTRONICS CO LTD Capacitance 3mh Nominal voltage 3.84V E3/E4 Model FC Manufacturer Salcomp Length of cable / E5 Model Manufacturer Length of cable CUBBM-F-DH FOXCONN 99cm E6 Model 5CB5422B-N-DG Manufacturer FOXCONN Length of cable / E7 Type FC Manufacturer Salcomp Length of cable / E8 Type Manufacturer Length of cable / FC2 Salcomp E9 Type FC3 Manufacturer Salcomp Length of cable / E Type FC Manufacturer Salcomp Length of cable / *E ID: is used to identify the test sample in the lab internally General Description The Equipment Under Test (EUT) is a model of Smart Phone with integrated antenna. Manual and specifications of the EUT were provided to fulfil the test.

8 Page 8 of Reference Documents 4.. Reference Documents for testing The following documents listed in this section are referred for testing. Reference Title Version FCC Part 22 PUBLIC MOBILE SERVICES --5 Edition FCC Part 27 NSI/TI3-D NSI C63.4 KDB 9768 D MISCELLNEOUS WIRELESS COMMUNICTIONS SERVICES Land Mobile FM or PM Communications Equipment Measurement and Performance Standards Methods of Measurement of Radio-Noise Emissions from Low-Voltage Electrical and Electronic Equipment in the Range of 9 khz to 4 GHz MESUREMENT GUIDNCE FOR CERTIFICTION OF LICENSED DIGITL TRNSMITTERS --5 Edition 2 24 v2r2

9 Page 9 of LBORTORY ENVIRONMENT Semi-anechoic chamber SC- (23 meters 7meters meters) did not exceed following limits along the EMC testing: Temperature Min. = 5, Max. = 35 Relative humidity Min. = 5 %, Max. = 75 % Shielding effectiveness Electrical insulation Ground system resistance Normalised site attenuation (NS) Site voltage standing-wave ratio (S VSWR ) Uniformity of field strength.4mhz - MHz, >6dB; MHz - MHz, >9dB. > 2 M < 4 < ± 4 db, 3m/m distance, from 3 to MHz Between and 6 db, from GHz to 8GHz Between and 6 db, from 8 to 3 MHz Fully-anechoic chamber FC-3 (9 meters 6.5 meters 4 meters) did not exceed following limits along the EMC testing: Temperature Min. = 5, Max. = 35 Relative humidity Min. = 5 %, Max. = 75 % Shielding effectiveness Electrical insulation Ground system resistance Site voltage standing-wave ratio (S VSWR ) Uniformity of field strength.4mhz - MHz, >6dB; MHz - MHz, >9dB. > 2 M < 4 Between and 6 db, from GHz to 8GHz Between and 6 db, from 8 to 4 MHz Shielded room did not exceed following limits along the EMC testing: Temperature Min. = 5, Max. = 35 Relative humidity Min. = 2 %, Max. = 75 % Shielding effectiveness Electrical insulation Ground system resistance.4mhz - MHz, >6dB; MHz - MHz, >9dB. > 2 M < 4

10 Page of SUMMRY OF TEST RESULTS 6.. Summary of test results bbreviations used in this clause: P F Verdict Column N NM Location Column /B/C/D Pass Fail Not applicable Not measured The test is performed in test location, B, C or D which are described in section. of this report LTE Band 5 Items Test Name Clause in FCC rules Section in this report Verdict Output Power 2.46(a), 22.93(a). P 2 Emission Limit 22.97, P 3 Frequency Stability , P 4 Occupied Bandwidth 2.49(h)(i).4 P 5 Emission Bandwidth 22.97(b).5 P 6 Band Edge Compliance 22.97(b).6 P 7 Conducted Spurious 22.97, Emission P LTE Band 7 Items Test Name Clause in Section in FCC rules this report Verdict Output Power 27.5(h)(2). P 2 Emission Limit 27.53(m), P 3 Frequency Stability 27.54, P 4 Occupied Bandwidth 2.49(h)(i).4 P 5 Emission Bandwidth 27.53(m).5 P 6 Band Edge 27.53(m) Compliance.6 P 7 Conducted Spurious 27.53(m), Emission P 8 Peak to verage Power Ratio 27.5(a).8 P

11 Page of 82 LTE Band 38 Items Test Name Clause in Section in FCC rules this report Verdict Output Power 27.5(h)(2). P 2 Emission Limit 27.53(m), P 3 Frequency Stability 27.54, P 4 Occupied Bandwidth 2.49(h)(i).4 P 5 Emission Bandwidth 27.53(m).5 P 6 Band Edge Compliance 27.53(m).6 P 7 Conducted Spurious 27.53(m), Emission P 8 Peak to verage Power Ratio 27.5(a).8 P

12 Page 2 of Statements The test cases listed in section 6. of this report for the EUT specified in section 3 were performed by CTTL according to the standards or reference documents in section 4. The EUT met all applicable requirements of the standards or reference documents in section 4.. This report only deals with the LTE functions among the features described in section 3.

13 Page 3 of Test Equipments Utilized NO. Description TYPE series number MNUFCTURE CL DUE DTE Calibration interval Test Receiver ESU R&S year 2 Test Receiver ESU R&S year 3 EMI ntenna ETS-Lindgren year Universal Radio Communication Tester Universal Radio Communication Tester Spectrum nalyzer CMU R&S year CMW R&S year E444 MY gilent year 7 EMI ntenna Schwarzbeck year 8 EMI ntenna VULB Schwarzbeck year 9 Signal Generator SMF 295 R&S year Climate chamber SH ESPEC year Loop ntenna HFH2-Z /7 R&S year

14 Page 4 of 82 NNEX : MESUREMENT RESULTS. OUTPUT POWER.. Summary During the process of testing, the EUT was controlled via Rhode & Schwarz Digital Radio Communication tester (CMW5) to ensure max power transmission and proper modulation. In all cases, output power is within the specified limits...2 Conducted..2. Method of Measurements The EUT was set up for the max output power with pseudo random data modulation. These measurements were done at 3 frequencies (bottom, middle and top of operational frequency range) for each bandwidth Measurement result LTE band 5 Bandwidth RB size/offset Frequency (MHz) Power(dBm) QPSK 6QM RB high RB low MHz % RB mid % RB RB high MHz RB low % RB mid

15 Page 5 of 82 5MHz MHz % RB RB high RB low 5% RB mid % RB RB high RB low 5% RB mid % RB

16 Page 6 of 82 LTE band 7 Bandwidth RB size/offset Frequency (MHz) Power(dBm) QPSK 6QM RB high RB low MHz % RB mid % RB RB high RB low MHz % RB mid % RB RB high RB low MHz % RB mid % RB MHz RB high

17 Page 7 of 82 RB low 5% RB mid % RB

18 Page 8 of 82 LTE band 38 Bandwidth RB size/offset Frequency (MHz) Power(dBm) QPSK 6QM RB high RB low MHz % RB mid % RB RB high RB low MHz % RB mid % RB RB high RB low MHz % RB mid % RB MHz RB high

19 Page 9 of 82 RB low 5% RB mid % RB

20 Page 2 of Radiated..3. Description This is the test for the maximum radiated power from the EUT. Rule Part 27.5(d) specifies Fixed, mobile, and portable (handheld) stations operating in the MHz band are limited to watt EIRP. Rule Part 27.5(h)(2) specifies Mobile stations are limited to 2. watts EIRP.. Rule Part 27.5(c) specifies Portable stations (hand-held de-vices) are limited to 3 watts ERP.. Rule Part 27.5(a)(3) specifies For mobile and portable stations transmitting in the MHz band or the MHz band, the average EIRP must not exceed 5 milliwatts within any megahertz of authorized bandwidth, except that for mobile and portable stations compliant with 3GPP LTE standards or another advanced mobile broadband protocol that avoids concentrating energy at the edge of the operating band the average EIRP must not exceed 25 milliwatts within any 5 megahertz of authorized bandwidth but may exceed 5 milliwatts within any megahertz of authorized bandwidth Method of Measurement The measurements procedures in TI3D are used.. EUT was placed on a.5 meter high non-conductive stand at a 3 meter test distance from the receive antenna. receiving antenna was placed on the antenna mast 3 meters from the EUT for emission measurements. The height of receiving antenna is.5m. The test setup refers to figure below. Detected emissions were maximized at each frequency by rotating the EUT through 36 and adjusting the receiving antenna polarization. The radiated emission measurements of all transmit frequencies in three channels (High, Middle, Low) were measured with peak detector. 2. The EUT is then put into continuously transmitting mode at its maximum power level during the test. nd the maximum value of the receiver should be recorded as (Pr). 3. The EUT shall be replaced by a substitution antenna. The test setup refers to figure below.

21 Page 2 of 82 In the chamber, a substitution antenna for the frequency band of interest is placed at the reference point of the chamber. n RF signal source for the frequency band of interest is connected to the substitution antenna with a cable that has been constructed to not interfere with the radiation pattern of the antenna. power (P Mea ) is applied to the input of the substitution antenna. djust the level of the signal generator output until the value of the receiver reaches the previously recorded (P r ). The power of signal source (P Mea ) is recorded. The test should be performed by rotating the test item and adjusting the receiving antenna polarization. 4. n amplifier should be connected to the Signal Source output port. nd the cable should be connected between the amplifier and the substitution antenna. The cable loss (P cl ), the substitution antenna Gain (G a ) and the amplifier Gain (P g ) should be recorded after test. The measurement results are obtained as described below: Power (EIRP) = P Mea - P g - P cl - G a 5. This value is EIRP since the measurement is calibrated using an antenna of known gain (unit dbi) and known input power. 6. ERP can be calculated from EIRP by subtracting the gain of the dipole, ERP = EIRP -2.5.

22 Page 22 of Measurement result LTE Band 5- ERP 22.93(a) Limits: 38.45dBm (7W) LTE Band 5_.4MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization H V V LTE Band 5_3MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization H V V LTE Band 5_5MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization H V V LTE Band 5_MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization H V V

23 Page 23 of 82 LTE Band 5_.4MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization H V V LTE Band 5_3MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization H V V LTE Band 5_5MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) Correction (db) ERP(dBm) Limit(dBm) Margin(dB) Polarization V H V LTE Band 5_MHz_6QM G a ntenna Correction Frequency(MHz) P Mea(dBm) P cl(db) P g(db) ERP(dBm) Limit(dBm) Margin(dB) Polarization Gain(dB) (db) H V V

24 Page 24 of 82 LTE Band 7- EIRP 27.5(h)(2) Limits: 33 dbm (2W) LTE Band 7_5MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 7_MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 7_5MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 7_2MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H

25 Page 25 of 82 LTE Band 7_5MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 7_MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 7_5MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 7_2MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H

26 Page 26 of 82 LTE Band 38- EIRP Part 27.5(h)(2) Limits: 33dBm (2W) LTE Band 38_5MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 38_MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 38_5MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 38_2MHz_QPSK Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H

27 Page 27 of 82 LTE Band 38_5MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 38_MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 38_5MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H LTE Band 38_2MHz_6QM Frequency(MHz) P Mea(dBm) P cl(db) P g(db) G a ntenna Gain(dB) EIRP(dBm) Limit(dBm) Margin(dB) Polarization H H H NLYZER SETTINGS: RBW = VBW = 8MHz for occupied bandwdiths equal to or less than 5MHz. RBW = VBW = 2MHz for occupied bandwidths equal to or greater than MHz. Note: Expanded measurement uncertainty is U =.96 db, k = 2.

28 Page 28 of 82.2 EMISSION LIMIT.2. Measurement Method The measurements procedures in TI3D are used. This measurement is carried out in fully-anechoic chamber FC-3. The spectrum was scanned from 3 MHz to the th harmonic of the highest frequency generated within the equipment, which is the transmitted carrier. The resolution bandwidth is set MHz. The spectrum was scanned with the mobile station transmitting at carrier frequencies that pertain to low, mid and high channels of the LTE Bands 5,7,38. The procedure of radiated spurious emissions is as follows:. EUT was placed on a.5 meter high non-conductive stand at a 3 meter test distance from the receive antenna. receiving antenna was placed on the antenna mast 3 meters from the EUT for emission measurements. The height of receiving antenna is.5m. The test setup refers to figure below. Detected emissions were maximized at each frequency by rotating the EUT through 36 and adjusting the receiving antenna polarization. The radiated emission measurements of all non-harmonic and harmonics of the transmit frequency through the th harmonic were measured with peak detector. 2. The EUT is then put into continuously transmitting mode at its maximum power level during the test. nd the maximum value of the receiver should be recorded as (Pr). 3. The EUT shall be replaced by a substitution antenna. The test setup refers to figure below. In the chamber, an substitution antenna for the frequency band of interest is placed at the reference point of the chamber. n RF Signal source for the frequency band of interest is connected to the substitution antenna with a cable that has been constructed to not interfere

29 Page 29 of 82 with the radiation pattern of the antenna. power (P Mea ) is applied to the input of the substitution antenna. djust the level of the signal generator output until the value of the receiver reaches the previously recorded (P r ). The power of signal source (P Mea ) is recorded. The test should be performed by rotating the test item and adjusting the receiving antenna polarization. 4. The Path loss (P pl ) between the Signal Source with the Substitution ntenna and the Substitution ntenna Gain (G a ) should be recorded after test. n amplifier should be connected in for the test. The Path loss (P pl ) is the summation of the cable loss and the gain of the amplifier. The measurement results are obtained as described below: Power (EIRP)=P Mea + P pl + G a 5. This value is EIRP since the measurement is calibrated using an antenna of known gain (unit: dbi) and known input power. 6. ERP can be calculated from EIRP by subtracting the gain of the dipole, ERP = EIRP -2.5dB..2.2 Measurement Limit Part 22.97,Part (a), Part 27.53(g), Part 27.53(h) specify that the power of any emission outside of the authorized operating frequency ranges must be attenuated below the transmitting power (P) by a factor of at least 43 + log(p) db. The specification that emissions shall be attenuated below the transmitter power (P) by at least 43 + log (P) db, translates in the relevant power range ( to. W) to -3 dbm. t W the specified minimum attenuation becomes 43 db and relative to a 3 dbm ( W) carrier becomes a limit of -3 dbm. t. W ( dbm) the minimum attenuation is 3 db, which again yields a limit of -3 dbm. In this way a translation of the specification from relative to absolute terms is carried out. Part 27.53(a) states for mobile and portable stations operating in the MHz and MHz bands: By a factor of not less than: 43 + log (P) db on all frequencies between 235 and 232 MHz and on all frequencies between 2345 and 236 MHz that are outside the licensed band(s) of operation, not less than 55 + log (P) db on all frequencies between 232 and 2324 MHz and on all frequencies between 234 and 2345 MHz, not less than 6 + log (P) db on all frequencies between 2324 and 2328 MHz and on all frequencies between 2337 and 234 MHz, and not less than 67 + log (P) db onall frequencies between 2328 and 2337MHz; By a factor of not less than 43 + log (P) db on all frequencies between 23 and 235 MHz, 55 + log (P) db on all frequencies between 2296 and 23MHz, 6 + log (P) db on all frequencies between 2292 and 2296 MHz, 67 + log (P) db on all frequencies between 2288 and 2292 MHz, and 7 + log (P) db below 2288 MHz; By a factor of not less than 43 + log (P) db on all frequencies between 236 and 2365 MHz, and not less than 7 + log (P) db above 2365 MHz..2.3 Measurement Results Radiated emissions measurements were made only at the upper, middle, and lower carrier frequencies of the LTE Bands 5,7,38. It was decided that measurements at these three carrier frequencies would be sufficient to demonstrate compliance with emissions limits because it was seen that all the significant spurs occur well outside the band and no radiation was seen from a carrier in one block of the LTE Bands 5,7,38 into any of the other blocks. The equipment must still, however, meet emissions requirements with the carrier at all frequencies over which it is capable

30 Page 3 of 82 of operating and it is the manufacturer's responsibility to verify this.the evaluated frequency range is from 3MHz to 26GHz.

31 Page 3 of 82 LTE Band 5,.4MHz, QPSK, Channel 247 Frequency(MHz) P Mea (dbm) Path ntenna Correction Peak Limit Loss Gain (db) ERP(dBm) (dbm) Margin(dB) Polarization V H V V H H Frequency(MHz) LTE Band 5,.4MHz, QPSK, Channel 2525 P Mea (dbm) Path Loss ntenna Gain Correction (db) Peak ERP(dBm) Limit (dbm) Margin(dB) H H V H V V Polarization LTE Band 5,.4MHz, QPSK, Channel 2643 Frequency(MHz) P Mea (dbm) Path ntenna Correction Peak Limit Loss Gain (db) ERP(dBm) (dbm) Margin(dB) Polarization V V H V H H

32 Page 32 of 82 LTE Band 5,.4MHz, QPSK, Channel 247 Frequency(MHz) P Mea (dbm) Path ntenna Correction Peak Limit Loss Gain (db) ERP(dBm) (dbm) Margin(dB) Polarization H H V H V V Frequency(MHz) LTE Band 5,.4MHz, QPSK, Channel 2525 P Mea (dbm) Path Loss ntenna Gain Correction (db) Peak ERP(dBm) Limit (dbm) Margin(dB) H V V H V H Polarization LTE Band 5,.4MHz, QPSK, Channel 2643 Frequency(MHz) P Mea (dbm) Path ntenna Correction Peak Limit Loss Gain (db) ERP(dBm) (dbm) Margin(dB) Polarization V H H V V V

33 Page 33 of 82 LTE Band 7, 5 MHz, QPSK, Channel 2775 Peak Frequency(M Path ntenn Limit Margin(dB Polarizatio P Mea (dbm) EIRP(dBm Hz) Loss a Gain (dbm) ) n ) H H H V H H LTE Band 7, 5 MHz, QPSK, Channel 2 Peak Frequency(M Path ntenn Limit Margin(dB Polarizatio P Mea (dbm) EIRP(dBm Hz) Loss a Gain (dbm) ) n ) H H V H H H LTE Band 7, 5 MHz, QPSK, Channel 2425 Peak Frequency(M Path ntenn Limit Margin(dB Polarizatio P Mea (dbm) EIRP(dBm Hz) Loss a Gain (dbm) ) n ) V H V H H V

34 Page 34 of 82 LTE Band 7, 5 MHz, 6QM, Channel 2775 Frequency( Path ntenna P Mea (dbm) MHz) Loss Gain Peak EIRP(dBm ) Limit Margin(dB Polarization (dbm) ) V H V H H V LTE Band 7, 5 MHz, 6QM, Channel 2 Frequency( Path ntenn P Mea (dbm) MHz) Loss a Gain Peak EIRP(dBm ) Limit Margin(dB Polarizatio (dbm) ) n V H V V V H LTE Band 7, 5 MHz, 6QM, Channel 2425 Frequency( Path ntenn P Mea (dbm) MHz) Loss a Gain Peak EIRP(dBm ) Limit Margin(dB Polarizatio (dbm) ) n H H V H V V

35 Page 35 of 82 LTE Band 38, 5MHz, QPSK, Channel Frequency(MHz) P Mea (dbm) Path Loss ntenna Gain Peak EIRP(dBm) Limit (dbm) Margin(dB) Polarization H H V V H V LTE Band 38, 5MHz, QPSK, Channel 38 Frequency(MHz) P Mea (dbm) Path Loss ntenna Gain Peak EIRP(dBm) Limit (dbm) Margin(dB) Polarization H V V V V H LTE Band 38, 5MHz, QPSK, Channel Frequency(MHz) P Mea (dbm) Path Loss ntenna Gain Peak EIRP(dBm) Limit (dbm) Margin(dB) Polarization H V H V H H

36 Page 36 of 82 LTE Band 38, 5MHz, 6QM, Channel Frequency(MHz) P Mea (dbm) Path Loss ntenna Gain Peak EIRP(dBm) Limit (dbm) Margin(dB) Polarization H H V H H H LTE Band 38, 5MHz, 6QM, Channel 38 Frequency(MHz) P Mea (dbm) Path Loss ntenna Gain Peak EIRP(dBm) Limit (dbm) Margin(dB) Polarization H V V V H H LTE Band 38, 5MHz, 6QM, Channel Frequency(MHz) P Mea (dbm) Path Loss ntenna Gain Peak EIRP(dBm) Limit (dbm) Margin(dB) Polarization H H H H H H Note: The maximum value of expanded measurement uncertainty for this test item is U = 4.2 db, k = 2.

37 Page 37 of 82.3 FREQUENCY STBILITY.3. Method of Measurement In order to measure the carrier frequency under the condition of FC lock, it is necessary to make measurements with the EUT in a call mode. This is accomplished with the use of R&S CMW5 DIGITL RDIO COMMUNICTION TESTER.. Measure the carrier frequency at room temperature. 2. Subject the EUT to overnight soak at. 3. With the EUT, powered via nominal voltage, connected to the CMW5 and in a simulated call on middle channel for LTE band 5/7/38, measure the carrier frequency. These measurements should be made within 2 minutes of Powering up the EUT, to prevent significant self-warming. 4. Repeat the above measurements at increments from to +5. llow at least.5 hours at each temperature, unpowered, before making measurements. 5. Re-measure carrier frequency at room temperature with nominal voltage. Vary supply voltage from minimum voltage to maximum voltage, in.volt increments re-measuring carrier frequency at each voltage. Pause at nominal voltage for.5 hours unpowered, to allow any self-heating to stabilize, before continuing. 6. Subject the EUT to overnight soak at With the EUT, powered via nominal voltage, connected to the CMW5 and in a simulated call on the centre channel, measure the carrier frequency. These measurements should be made within 2 minutes of Powering up the EUT, to prevent significant self-warming. 8. Repeat the above measurements at increments from +5 to. llow at least.5 hours at each temperature, unpowered, before making measurements. 9. t all temperature levels hold the temperature to +/-.5 during the measurement procedure..3.2 Measurement Limit ccording to the JTC standard the frequency stability of the carrier shall be accurate to within. ppm of the received frequency from the base station. The frequency stability shall be sufficient to ensure that the fundamental emission stays within the authorized frequency block. s this transceiver is considered "Hand carried, battery powered equipment" Section 2.55(d) (2) applies. This requires that the lower voltage for frequency stability testing be specified by the manufacturer. This transceiver is specified to operate with an input voltage of between 3.6VDC and 4.4VDC, with a nominal voltage of 3.84VDC. Operation above or below these voltage limits is prohibited by transceiver software in order to prevent improper operation as well as to protect components from overstress. These voltages represent a tolerance from -5.4% to.8%. For the purposes of measuring frequency stability these voltage limits are to be used.

38 Page 38 of Measurement results LTE Band 5,.4MHz bandwidth (worst case of all bandwidths) Frequency Error vs Voltage Voltage (V) Frequency error (Hz) Frequency error (ppm) QPSK 6QM QPSK 6QM Frequency Error vs Temperature Temperature ( ) Frequency error (Hz) Frequency error (ppm) QPSK 6QM QPSK 6QM LTE Band 7, MHz bandwidth (worst case of all bandwidths) Frequency Error vs Voltage Voltage (V) Frequency error (Hz) Frequency error (ppm) QPSK 6QM QPSK 6QM Frequency Error vs Temperature Temperature ( ) Frequency error (Hz) Frequency error (ppm) QPSK 6QM QPSK 6QM

39 Page 39 of 82 LTE Band 38, 5MHz bandwidth (worst case of all bandwidths) Frequency Error vs Voltage Voltage (V) Frequency error (Hz) Frequency error (ppm) QPSK 6QM QPSK 6QM Frequency Error vs Temperature Temperature ( ) Frequency error (Hz) Frequency error (ppm) QPSK 6QM QPSK 6QM Expanded measurement uncertainty for this test item is Hz, k = 2.

40 Page 4 of 82.4 OCCUPIED BNDWIDTH.4. Occupied Bandwidth Results Occupied bandwidth measurements are only provided for selected frequencies in order to reduce the amount of submitted data. Data were taken at the extreme and mid frequencies of the US Cellular/PCS frequency bands. The table below lists the measured 99% BW. Spectrum analyzer plots are included on the following pages. The measurement method is from KDB : a) The spectrum analyzer center frequency is set to the nominal EUT channel center frequency. The frequency span for the spectrum analyzer shall be set wide enough to capture all modulation products including the emission skirts (i.e., two to five times the OBW). b) The nominal IF filter bandwidth (3 db RBW) shall be in the range of to 5 % of the anticipated OBW, and the VBW shall be at least 3 times the RBW. c) Set the reference level of the instrument as required to keep the signal from exceeding the maximum input mixer level for linear operation. In general, the peak of the spectral envelope must be at least log (OBW / RBW) below the reference level. d) Set the detection mode to peak, and the trace mode to max hold. e) Use the 99 % power bandwidth function of the spectrum analyzer and report the measured bandwidth. LTE band 5,.4MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 5,.4MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW khz SWT 4 ms 4.2 dbm MHz 3 OBW MHz Temp [T OBW] dbm MHz PK T Temp 2 [T OBW] 7.68 dbm MHz - Center MHz 5 khz/ Span 5 MHz Date:.PR.27 6:7:6

41 Page 4 of 82 LTE band 5,.4MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW khz SWT 4 ms 3.7 dbm MHz 3 OBW MHz Temp [T OBW] PK 2 T 4.89 dbm MHz Temp 2 [T OBW] 8.5 dbm MHz - Center MHz 5 khz/ Span 5 MHz Date:.PR.27 6:7:3

42 Page 42 of 82 LTE band 5, 3MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 5, 3MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 3 khz * VBW khz SWT 3 ms 2.82 dbm MHz 3 OBW MHz Temp [T OBW] PK 2 T 7.8 dbm MHz Temp 2 [T OBW] 8.86 dbm MHz - Center MHz MHz/ Span MHz Date:.PR.27 6:2:58 LTE band 5, 3MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 3 khz * VBW khz SWT 3 ms.2 dbm MHz 3 OBW MHz Temp [T OBW] PK 2 T 5.77 dbm MHz Temp 2 [T OBW] 7.59 dbm MHz - Center MHz MHz/ Span MHz Date:.PR.27 6:3:3

43 Page 43 of 82 LTE band 5, 5MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 5, 5MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms 2.2 dbm MHz 3 OBW MHz Temp [T OBW] PK 2 T 6.5 dbm MHz Temp 2 [T OBW] 7. dbm MHz - Center MHz.5 MHz/ Span 5 MHz Date:.PR.27 6:8:4 LTE band 5, 5MHz Bandwidth,6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms.37 dbm MHz 3 OBW MHz Temp [T OBW] dbm MHz PK T Temp 2 [T OBW] 6.33 dbm MHz - Center MHz.5 MHz/ Span 5 MHz Date:.PR.27 6:8:56

44 Page 44 of 82 LTE band 5, MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 5, MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms 2.32 dbm MHz 3 OBW MHz Temp [T OBW] PK 2 T 7.96 dbm MHz Temp 2 [T OBW] 7.24 dbm MHz - Center MHz 3 MHz/ Span 3 MHz Date:.PR.27 6:24:23 LTE band 5, MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms.57 dbm MHz 3 OBW MHz Temp [T OBW] PK 2 T 6.92 dbm MHz Temp 2 [T OBW] 6.8 dbm MHz - Center MHz 3 MHz/ Span 3 MHz Date:.PR.27 6:24:38

45 Page 45 of 82 LTE band 7, 5MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 7, 5MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms.43 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 5.84 dbm GHz Temp 2 [T OBW] 6.9 dbm GHz - Center GHz.5 MHz/ Span 5 MHz Date: 7.PR.27 8:9:4 LTE band 7, 5MHz Bandwidth,6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms.44 dbm GHz 3 OBW MHz Temp [T OBW] dbm GHz PK T Temp 2 [T OBW] 4.47 dbm GHz - Center GHz.5 MHz/ Span 5 MHz Date: 7.PR.27 8:9:9

46 Page 46 of 82 LTE band 7, MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 7, MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms.6 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 7.27 dbm GHz Temp 2 [T OBW] 6.3 dbm GHz - Center GHz 3 MHz/ Span 3 MHz Date: 7.PR.27 8:4:47 LTE band 7, MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms.95 dbm GHz 3 OBW MHz Temp [T OBW] dbm GHz PK T Temp 2 [T OBW] 5.26 dbm GHz - Center GHz 3 MHz/ Span 3 MHz Date: 7.PR.27 8:5:2

47 Page 47 of 82 LTE band 7, 5MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 7, 5MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 3.48 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 8.52 dbm GHz Temp 2 [T OBW] 8.3 dbm GHz - Center GHz 4.5 MHz/ Span 45 MHz Date: 7.PR.27 8:2:35 LTE band 7, 5MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 2.56 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 7.75 dbm GHz Temp 2 [T OBW] 7.6 dbm GHz - Center GHz 4.5 MHz/ Span 45 MHz Date: 7.PR.27 8:2:5

48 Page 48 of 82 LTE band 7, 2MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 7, 2MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 2.27 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 7.25 dbm GHz Temp 2 [T OBW] 8.4 dbm GHz - Center GHz 6 MHz/ Span 6 MHz Date: 7.PR.27 8:26:28 LTE band 7, 2MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms.79 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 5.79 dbm GHz Temp 2 [T OBW] 6.9 dbm GHz - Center GHz 6 MHz/ Span 6 MHz Date: 7.PR.27 8:26:43

49 Page 49 of 82 LTE band 38, 5MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 38, 5MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms 2.5 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 8.23 dbm GHz Temp 2 [T OBW].57 dbm GHz - Center GHz.5 MHz/ Span 5 MHz Date:.PR.27 3:47:35 LTE band 38, 5MHz Bandwidth,6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms 2.35 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 9.5 dbm GHz Temp 2 [T OBW] 7.64 dbm GHz - Center GHz.5 MHz/ Span 5 MHz Date:.PR.27 3:47:48

50 Page 5 of 82 LTE band 38, MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 38, MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms.46 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 5.6 dbm GHz Temp 2 [T OBW] 6.32 dbm GHz - Center GHz 3 MHz/ Span 3 MHz Date:.PR.27 4:5:8 LTE band 38, MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms.72 dbm GHz 3 OBW MHz Temp [T OBW] dbm GHz PK T Temp 2 [T OBW] 5.5 dbm GHz - Center GHz 3 MHz/ Span 3 MHz Date:.PR.27 4:5:23

51 Page 5 of 82 LTE band 38, 5MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 38, 5MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 3.5 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 5.7 dbm GHz Temp 2 [T OBW] 7.3 dbm GHz - Center GHz 4.5 MHz/ Span 45 MHz Date:.PR.27 4::56 LTE band 38, 5MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 2. dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 4.39 dbm GHz Temp 2 [T OBW] 5.7 dbm GHz - Center GHz 4.5 MHz/ Span 45 MHz Date:.PR.27 4::

52 Page 52 of 82 LTE band 38, 2MHz (99%) Frequency(MHz) Occupied Bandwidth (99%)( khz) QPSK 6QM LTE band 38, 2MHz Bandwidth, QPSK (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms.6 dbm GHz 3 OBW MHz Temp [T OBW] PK 2 T 7.77 dbm GHz Temp 2 [T OBW] 6.44 dbm GHz - Center GHz 6 MHz/ Span 6 MHz Date:.PR.27 4:9:9 LTE band38, 2MHz Bandwidth, 6QM (99% BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms.46 dbm GHz 3 OBW MHz Temp [T OBW] dbm GHz PK T Temp 2 [T OBW] 5. dbm GHz - Center GHz 6 MHz/ Span 6 MHz Date:.PR.27 4:9:34

53 Page 53 of 82.5 EMISSION BNDWIDTH.5.Emission Bandwidth Results The emission bandwidth is defined as the width of the signal between two points, one below the carrier center frequency and one above the carrier center frequency, outside of which all emissions are attenuated at least 26 db below the transmitter power. Table below lists the measured -26dBc BW. Spectrum analyzer plots are included on the following pages. LTE band 5,.4MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 5,.4MHz Bandwidth, QPSK (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW khz SWT 4 ms 3.46 dbm MHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -4.6 dbm MHz Temp 2 [T ndb] -2.5 dbm MHz - T Center MHz 5 khz/ Span 5 MHz Date:.PR.27 6:8:24

54 Page 54 of 82 LTE band 5,.4MHz Bandwidth, 6QM (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW khz SWT 4 ms 2.88 dbm MHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm MHz Temp 2 [T ndb] dbm MHz - T Center MHz 5 khz/ Span 5 MHz Date:.PR.27 6:8:4

55 Page 55 of 82 LTE band 5, 3MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 5, 3MHz Bandwidth, QPSK (-26dBc BW) * RBW 3 khz * VBW khz 2.76 dbm Ref 3 dbm * tt 25 db SWT 3 ms MHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -3.3 dbm MHz Temp 2 [T ndb] dbm MHz - T Center MHz MHz/ Span MHz Date:.PR.27 6:4:6 LTE band 5, 3MHz Bandwidth, 6QM (-26dBc BW) * RBW 3 khz * VBW khz.89 dbm Ref 3 dbm * tt 25 db SWT 3 ms MHz 3 ndb [T] 26. db BW MHz 2 Temp [T ndb] dbm PK MHz Temp 2 [T ndb] -4.9 dbm MHz - T Center MHz MHz/ Span MHz Date:.PR.27 6:4:23

56 Page 56 of 82 LTE band 5, 5MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 5, 5MHz Bandwidth, QPSK (-26dBc BW) * RBW 5 khz * VBW 2 khz.48 dbm Ref 3 dbm * tt 25 db SWT ms MHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm MHz Temp 2 [T ndb] dbm MHz - T Center MHz.5 MHz/ Span 5 MHz Date:.PR.27 6:9:49 LTE band 5, 5MHz Bandwidth,6QM (-26dBc BW) * RBW 5 khz * VBW 2 khz.67 dbm Ref 3 dbm * tt 25 db SWT ms MHz 3 ndb [T] 26. db BW MHz 2 Temp [T ndb] dbm PK MHz Temp 2 [T ndb] dbm MHz - T Center MHz.5 MHz/ Span 5 MHz Date:.PR.27 6:2:6

57 Page 57 of 82 LTE band 5, MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 5, MHz Bandwidth, QPSK (-26dBc BW) * RBW khz * VBW 3 khz.83 dbm Ref 3 dbm * tt 25 db SWT 5 ms MHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm MHz Temp 2 [T ndb] -3.5 dbm MHz - T Center MHz 3 MHz/ Span 3 MHz Date:.PR.27 6:25:32 LTE band 5, MHz Bandwidth, 6QM (-26dBc BW) * RBW khz * VBW 3 khz.65 dbm Ref 3 dbm * tt 25 db SWT 5 ms MHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm MHz Temp 2 [T ndb] dbm MHz - T Center MHz 3 MHz/ Span 3 MHz Date:.PR.27 6:25:49

58 Page 58 of 82 LTE band 7, 5MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 7, 5MHz Bandwidth, QPSK (-26dBc BW) * RBW 5 khz * VBW 2 khz.22 dbm Ref 3 dbm * tt 25 db SWT ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz.5 MHz/ Span 5 MHz Date: 7.PR.27 8::2 LTE band 7, 5MHz Bandwidth,6QM (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms.47 dbm GHz 3 ndb [T] 26. db BW MHz 2 Temp [T ndb] -6.7 dbm PK GHz Temp 2 [T ndb] -6.6 dbm GHz - T Center GHz.5 MHz/ Span 5 MHz Date: 7.PR.27 8::29

59 Page 59 of 82 LTE band 7, MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 7, MHz Bandwidth, QPSK (-26dBc BW) * RBW khz * VBW 3 khz.57 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -3.8 dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz 3 MHz/ Span 3 MHz Date: 7.PR.27 8:5:55 LTE band 7, MHz Bandwidth, 6QM (-26dBc BW) Ref 3 dbm * tt 25 db * RBW khz * VBW 3 khz SWT 5 ms.87 dbm GHz 3 ndb [T] 26. db BW MHz 2 Temp [T ndb] -5.2 dbm PK GHz Temp 2 [T ndb] dbm GHz - T Center GHz 3 MHz/ Span 3 MHz Date: 7.PR.27 8:6:2

60 Page 6 of 82 LTE band 7, 5MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 7, 5MHz Bandwidth, QPSK (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 3.42 dbm GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -.58 dbm GHz Temp 2 [T ndb] -.87 dbm GHz - T Center GHz 4.5 MHz/ Span 45 MHz Date: 7.PR.27 8:2:43 LTE band 7, 5MHz Bandwidth, 6QM (-26dBc BW) * RBW 2 khz * VBW MHz 2.32 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -4. dbm GHz Temp 2 [T ndb] -4.4 dbm GHz - T Center GHz 4.5 MHz/ Span 45 MHz Date: 7.PR.27 8:22:

61 Page 6 of 82 LTE band 7, 2MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 7, 2MHz Bandwidth, QPSK (-26dBc BW) * RBW 2 khz * VBW MHz 2.22 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -4.3 dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz 6 MHz/ Span 6 MHz Date: 7.PR.27 8:27:36 LTE band 7, 2MHz Bandwidth, 6QM (-26dBc BW) * RBW 2 khz * VBW MHz 2.43 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm GHz Temp 2 [T ndb] -3.5 dbm GHz - T Center GHz 6 MHz/ Span 6 MHz Date: 7.PR.27 8:27:53

62 Page 62 of 82 LTE band 38, 5MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc) ( khz) QPSK 6QM LTE band 38, 5MHz Bandwidth, QPSK (-26dBc BW) * RBW 5 khz * VBW 2 khz 3.8 dbm Ref 3 dbm * tt 25 db SWT ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz.5 MHz/ Span 5 MHz Date:.PR.27 3:48:4 LTE band 38, 5MHz Bandwidth,6QM (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms 2.69 dbm GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz.5 MHz/ Span 5 MHz Date:.PR.27 3:48:56

63 Page 63 of 82 LTE band 38, MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 38, MHz Bandwidth, QPSK (-26dBc BW) * RBW khz * VBW 3 khz.9 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -6.7 dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz 3 MHz/ Span 3 MHz Date:.PR.27 4:6:6 LTE band 38, MHz Bandwidth, 6QM (-26dBc BW) * RBW khz * VBW 3 khz.55 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz 2 Temp [T ndb] -7.7 dbm PK GHz Temp 2 [T ndb] dbm GHz - T Center GHz 3 MHz/ Span 3 MHz Date:.PR.27 4:6:33

64 Page 64 of 82 LTE band 38, 5MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 38, 5MHz Bandwidth, QPSK (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 3.4 dbm GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] -3.8 dbm GHz Temp 2 [T ndb] -2.4 dbm GHz - T Center GHz 4.5 MHz/ Span 45 MHz Date:.PR.27 4:2:4 LTE band 38, 5MHz Bandwidth, 6QM (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms 2.4 dbm GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz 4.5 MHz/ Span 45 MHz Date:.PR.27 4:2:2

65 Page 65 of 82 LTE band 38, 2MHz (-26dBc) Frequency(MHz) Occupied Bandwidth (-26dBc)( khz) QPSK 6QM LTE band 38, 2MHz Bandwidth, QPSK (-26dBc BW) * RBW 2 khz * VBW MHz.82 dbm Ref 3 dbm * tt 25 db SWT 5 ms GHz 3 ndb [T] 26. db BW MHz PK 2 Temp [T ndb] dbm GHz Temp 2 [T ndb] dbm GHz - T Center GHz 6 MHz/ Span 6 MHz Date:.PR.27 4:2:27 LTE band38, 2MHz Bandwidth, 6QM (-26dBc BW) Ref 3 dbm * tt 25 db * RBW 2 khz * VBW MHz SWT 5 ms.75 dbm GHz 3 ndb [T] 26. db BW MHz 2 Temp [T ndb] dbm PK GHz Temp 2 [T ndb] dbm GHz - T Center GHz 6 MHz/ Span 6 MHz Date:.PR.27 4:2:44

66 Page 66 of 82.6 BND EDGE COMPLINCE.6. Measurement limit Part27.53(h) states that on any frequency outside frequency band of the US Cellular/PCS spectrum, the power of any emission shall be attenuated below the transmitter power (P, in Watts) by at least 43+Log (P) db. For all power levels +3 dbm to dbm, this becomes a constant specification limit of -3 dbm. ccording to KDB , a relaxation of the reference bandwidth is often provided for measurements within a specified frequency range at the edge of the authorized frequency block/band. This is often implemented by permitting the use of a narrower RBW (typically limited to a minimum RBW of % of the OBW) for measuring the out-of-band emissions without a requirement to integrate the result over the full reference bandwidth. Part 27.53(m) states that for mobile digital stations, the attenuation factor shall be not less than 4 + log (P) db on all frequencies between the channel edge and 5 megahertz from the channel edge, 43 + log (P) db on all frequencies between 5 megahertz and X megahertz from the channel edge, and 55 + log (P) db on all frequencies more than X megahertz from the channel edge, where X is the greater of 6 megahertz or the actual emission bandwidth as defined in paragraph (m)(6) of this section. In addition, the attenuation factor shall not be less that 43 + log (P) db on all frequencies between MHz and 2496 MHz and 55 + log (P) db at or below MHz. Mobile Satellite Service licensees operating on frequencies below 2495 MHz may also submit a documented interference complaint against BRS licensees operating on channel BRS Channel on the same terms and conditions as adjacent channel BRS or EBS licensees. Part 27.53(a) states for mobile and portable stations operating in the MHz and MHz bands: By a factor of not less than: 43 + log (P) db on all frequencies between 235 and 232 MHz and on all frequencies between 2345 and 236 MHz that are outside the licensed band(s) of operation, not less than 55 + log (P) db on all frequencies between 232 and 2324 MHz and on all frequencies between 234 and 2345 MHz, not less than 6 + log (P) db on all frequencies between 2324 and 2328 MHz and on all frequencies between 2337 and 234 MHz, and not less than 67 + log (P) db onall frequencies between 2328 and 2337MHz; By a factor of not less than 43 + log (P) db on all frequencies between 23 and 235 MHz, 55 + log (P) db on all frequencies between 2296 and 23MHz, 6 + log (P) db on all frequencies between 2292 and 2296 MHz, 67 + log (P) db on all frequencies between 2288 and 2292 MHz, and 7 + log (P) db below 2288 MHz; By a factor of not less than 43 + log (P) db on all frequencies between 236 and 2365 MHz, and not less than 7 + log (P) db above 2365 MHz. Part 27.53(c) states for operations in the MHz band and the MHz band, the power of any emission outside the licensee's frequency band(s) of operation shall be attenuated below the transmitter power (P) within the licensed band(s) of operation, measured in watts, in accordance with the following:() On any frequency outside the MHz band, the power of any emission shall be attenuated outside the band below the transmitter power (P) by at least 43 + log (P) db;(2) On any frequency outside the MHz band, the power of any emission shall be attenuated outside the band below the transmitter power (P) by at least 43 + log (P)

67 Page 67 of 82 db;(4) On all frequencies between MHz and MHz, by a factor not less than 65 + log (P) db in a 6.25 khz band segment, for mobile and portable stations

68 Page 68 of Measurement result Only worst case result is given below LTE band 5 OBW: RB-low_offset Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT 2 ms 5.55 dbm MHz 3 OBW khz Temp [T OBW] dbm MHz PK Temp 2 [T OBW] -.4 dbm MHz T - Center MHz 5 khz/ Span 5 MHz Date:.PR.27 7:2: LOW BND EDGE BLOCK-RB-low_offset Ref 2 dbm * tt 2 db * RBW 3 khz * VBW khz SWT 56 ms dbm MHz 2 RM * Center 824 MHz 5 khz/ Span 5 MHz Date:.PR.27 7:2:54

69 Page 69 of 82 OBW: RB-high_offset Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT ms 4.92 dbm MHz 3 OBW khz Temp [T OBW] 2.96 dbm MHz PK Temp 2 [T OBW].3 dbm T MHz - Center MHz 25 khz/ Span 2.5 MHz Date:.PR.27 6:59:53 HIGH BND EDGE BLOCK-RB-high_offset Ref 2 dbm * tt 2 db * RBW 3 khz * VBW khz SWT 56 ms dbm MHz 2 RM * Center 849 MHz 5 khz/ Span 5 MHz Date:.PR.27 7::36

70 Page 7 of 82 LOW BND EDGE BLOCK-MHz-%RB Ref 2 dbm * tt 2 db * RBW khz * VBW 3 khz SWT 2.5 ms dbm MHz 2 RM * Center 824 MHz 5 khz/ Span 5 MHz Date:.PR.27 7::8 HIGH BND EDGE BLOCK-MHz-%RB Ref 2 dbm * tt 2 db * RBW khz * VBW 3 khz SWT 2.5 ms dbm MHz 2 RM * Center 849 MHz 5 khz/ Span 5 MHz Date:.PR.27 7::3

71 Page 7 of 82 LTE band 7 OBW: RB-low_offset Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT.2 s 4. dbm GHz 3 OBW khz Temp [T OBW] dbm GHz PK Temp 2 [T OBW] -.9 dbm T GHz - Center 2.5 GHz 3 MHz/ Span 3 MHz Date: 2.PR.27 :27:39 LOW BND EDGE BLOCK-RB-low_offset Ref 2 dbm * tt 2 db * RBW 5 khz * VBW 2 khz SWT 96 ms dbm 2.5 GHz 2 RM * - 7_2-8 Center 2.5 GHz 2.4 MHz/ Span 24 MHz Date: 2.PR.27 :28:23

72 Page 72 of 82 OBW: RB-high_offset Ref 3 dbm * tt 25 db * RBW 5 khz * VBW 2 khz SWT.2 s 5.37 dbm GHz PK 3 2 OBW khz Temp [T OBW] -.28 dbm GHz Temp 2 [T OBW] 6.3 dbm GHz - T Center 2.56 GHz 3 MHz/ Span 3 MHz Date: 2.PR.27 9:56:7 HIGH BND EDGE BLOCK-RB-high_offset Ref 2 dbm * tt 2 db * RBW 5 khz * VBW 2 khz SWT 96 ms dbm GHz 2 RM * - 7_2-8 Center 2.57 GHz 2.4 MHz/ Span 24 MHz Date: 2.PR.27 9:56:5

73 Page 73 of 82 LOW BND EDGE BLOCKMHz-%RB Ref 2 dbm * tt 2 db * RBW 2 khz * VBW MHz SWT 2.5 ms.96 dbm GHz 2 RM * - 7_2-8 Center 2.5 GHz 2.4 MHz/ Span 24 MHz Date: 2.PR.27 9:37: HIGH BND EDGE BLOCKMHz-%RB Ref 2 dbm * tt 2 db * RBW 2 khz * VBW MHz SWT 2.5 ms dbm GHz 2 RM * - 7_2-8 Center 2.57 GHz 2.4 MHz/ Span 24 MHz Date: 2.PR.27 9:37:57

74 Page 74 of 82 LTE band 38 OBW: RB-low_offset * RBW 5 khz VBW 2 khz dbm Ref 2 dbm tt 25 db SWT 96 ms GHz 2 OBW khz Temp [T OBW] -4.6 dbm GHz PK T Temp 2 [T OBW] dbm GHz Center 2.57 GHz 2.4 MHz/ Span 24 MHz Date: 3.PR.27 :5:3 LOW BND EDGE BLOCK-RB-low_offset * RBW 3 khz VBW khz. dbm Ref 2 dbm tt 45 db SWT 2.7 s GHz 2 PK Center 2.57 GHz 2.4 MHz/ Span 24 MHz Date: 3.PR.27 :5:46

75 Page 75 of 82 OBW: RB-high_offset * RBW 5 khz VBW 2 khz 4.39 dbm Ref 2 dbm tt 25 db SWT 8 ms GHz PK 2 OBW khz - Temp [T OBW] dbm GHz Temp 2 [T OBW] -.94 dbm T GHz -8 Center GHz 2 MHz/ Span 2 MHz Date: 3.PR.27 :4:6 HIGH BND EDGE BLOCK-RB-high_offset * RBW 3 khz VBW khz dbm Ref 2 dbm tt 45 db SWT 2.7 s GHz 2 PK Center 2.62 GHz 2.4 MHz/ Span 24 MHz Date: 3.PR.27 :43:44

76 Page 76 of 82 LOW BND EDGE BLOCKMHz-%RB Ref dbm tt 35 db * RBW 2 khz VBW 5 khz SWT 2.5 ms dbm GHz PK Center 2.57 GHz 2.4 MHz/ Span 24 MHz Date: 3.PR.27 :47:25 HIGH BND EDGE BLOCKMHz-%RB Ref dbm tt 35 db * RBW 2 khz VBW 5 khz SWT 2.5 ms dbm GHz PK Center 2.62 GHz 2.4 MHz/ Span 24 MHz Date: 3.PR.27 :45:38

77 Page 77 of 82.7 CONDUCTED SPURIOUS EMISSION.7. Measurement Method The following steps outline the procedure used to measure the conducted emissions from the EUT.. Determine frequency range for measurements: From CFR 2.57 the spectrum should be investigated from the lowest radio frequency generated in the equipment up to at least the th harmonic of the carrier frequency. For the mobile station equipment tested, this equates to a frequency range of 3 MHz to 9 GHz, data taken from MHz to 25 GHz. 2. Determine EUT transmit frequencies: below outlines the band edge frequencies pertinent to conducted emissions testing. 3. The number of sweep points of spectrum analyzer is set to 3 which is greater than span/rbw Measurement Limit Part 27.53(h) specifies that the power of any emission outside of the authorized operating frequency ranges must be attenuated below the transmitting power (P) by a factor of at least 43 + log(p) db. The specification that emissions shall be attenuated below the transmitter power (P) by at least 43 + log (P) db, translates in the relevant power range ( to. W) to -3 dbm. t W the specified minimum attenuation becomes 43 db and relative to a 3 dbm ( W) carrier becomes a limit of -3 dbm. t. W ( dbm) the minimum attenuation is 3 db, which again yields a limit of -3 dbm. In this way a translation of the specification from relative to absolute terms is carried out. Part 27.53(m)(4) specifies for mobile digital stations, the attenuation factor shall be not less than 4 + log (P) db on all frequencies between the channel edge and 5 megahertz from the channel edge, 43 + log (P) db on all frequencies between 5 megahertz and X megahertz from the channel edge, and 55 + log (P) db on all frequencies more than X megahertz from the channel edge, where X is the greater of 6 megahertz or the actual emission bandwidth as defined in paragraph (m)(6) of this section. In addition, the attenuation factor shall not be less that 43 + log (P) db on all frequencies between MHz and 2496 MHz and 55 + log (P) db at or below MHz. Mobile Satellite Service licensees operating on frequencies below 2495 MHz may also submit a documented interference complaint against BRS licensees operating on channel BRS Channel on the same terms and conditions as adjacent channel BRS or EBS licensees. Part 27.53(a) states for mobile and portable stations operating in the MHz and MHz bands: By a factor of not less than: 43 + log (P) db on all frequencies between 235 and 232 MHz and on all frequencies between 2345 and 236 MHz that are outside the licensed band(s) of operation, not less than 55 + log (P) db on all frequencies between 232 and 2324 MHz and on all frequencies between 234 and 2345 MHz, not less than 6 + log (P) db on all frequencies between 2324 and 2328 MHz and on all frequencies between 2337 and 234 MHz, and not less than 67 + log (P) db onall frequencies between 2328 and 2337MHz; By a factor of not less than 43 + log (P) db on all frequencies between 23 and 235 MHz, 55 + log (P) db on all frequencies between 2296 and 23MHz, 6 + log (P) db on all

78 Page 78 of 82 frequencies between 2292 and 2296 MHz, 67 + log (P) db on all frequencies between 2288 and 2292 MHz, and 7 + log (P) db below 2288 MHz; By a factor of not less than 43 + log (P) db on all frequencies between 236 and 2365 MHz, and not less than 7 + log (P) db above 2365 MHz.

79 Page 79 of Measurement result Only worst case result is given below LTE band 5: 3MHz GHz Spurious emission limit 3dBm. Ref 5 dbm tt 3 db * RBW MHz * VBW 3 MHz SWT 25 ms dbm MHz PK Start 3 MHz 997 MHz/ Stop GHz Date:.PR.27 7:4:38 LTE band 7: 3MHz 26GHz Spurious emission limit 25dBm. Ref -2 dbm tt 5 db * RBW MHz * VBW 3 MHz SWT 5 ms dbm GHz -25DBM PK Start 3 MHz GHz/ Stop 26 GHz Date: 2.PR.27 :35:43

80 Page 8 of 82 LTE band 38: 3MHz 26GHz Spurious emission limit 25dBm. Ref -5 dbm tt db * RBW MHz VBW 3 MHz SWT 55 ms 9.59 dbm GHz 38- PK Start 3 MHz GHz/ Stop 26.5 GHz Date: 3.PR.27 :58:3

81 Page 8 of 82.8 PEK-TO-VERGE POWER RTIO Reference FCC: CFR Part 27.5(a) The peak-to-average power ratio (PPR) of the transmitter output power must not exceed 3 db. The PPR measurements should be made using either an instrument with complementary cumulative distribution function (CCDF) capabilities to determine that PPR will not exceed 3 db for more than. percent of the time or other Commission approved procedure. The measurement must be performed using a signal corresponding to the highest PPR expected during periods of continuous transmission. ccording to KDB : a)refer to instrument s analyzer instruction manual for details on how to use the power statistics/ccdf function; b) Set resolution/measurement bandwidth signal s occupied bandwidth; c) Set the number of counts to a value that stabilizes the measured CCDF curve; d) Set the measurement interval to ms e)record the maximum PPR level associated with a probability of.%.8. Measurement limit not exceed 3 db.8.2 Measurement results LTE band 7, 2MHz Frequency(MHz) 25. PPR(dB) QPSK 6QM LTE band 38, 5MHz Frequency(MHz) PPR(dB) QPSK 6QM

82 Page 82 of 82 ***END OF REPORT***