Test Report Part 24H

FCC ID: JOYJA53

Test Report

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FCCID_4182971

Report on the RF Testing of: KYOCERA Corporation Mobile Phone, Model: JA53 FCC ID: JOYJAS53 In accordance with FCC Part 24 Subpart E Prepared for: KYOCERA Corporation Add value. Yokohama Office 2—1—1 Kagahara, Tsuzuki—ku Inspire trust. Yokohama—shi, Kanagawa, Japan Phone: +81—45—943—6253 Fax: +81—45—943—6314 COMMERCIAL—IN—CONFIDENCE Document Number: JPD—TR—19043—0 SIGNATURE JOB TITLE RESPONSIBLE FOR I1SSUE DATE Hiroaki Suzuki Deputy Manager of RF Group Approved Signatory 0 7 FEB 2019 Signatures in this approval box have checked this document in line with the requirements of TUV SUD Japan Ltd. document control rules. EXECUTIVE SUMMARY A sample(s) of this product was tested and found to be compliant with FCC Part 24 Subpart E. DISCLAIMER AND COPYRIGHT ®© \\\“\‘\'.ljl"/,, The results in this report are applicable only to the equipment tested. wl $nt//z> This report shall not be re—produced except in full without the written approval of TUV SUD N ;tf; @ M‘E‘- Japan Ltd. — Ee es TESTING "4@@ Anluks ACCREDIATION . — . . NVLAP LAB CODE 200306—0 f This test report must not be used by the client to claim product certification, approval, or endorsement by NVLAP, NIST, ILAC—MRA, or any agency of the federal government. TUV SUD Japan Ltd. Phone: +81 (0) 238 28 2881 Yonezawa Testing Center Fax: +81 (0) 238 28 2888 5—4149—7 Hachimanpara, ceud i Yonezawa—shi, Yamagata, www—tuy—sud jp 992—1128 Japan TUV SUD Japan Ltd.

Document Number: JPD-TR-19043-0 Contents 1 Summary of Test .................................................................................................................... 3 1.1 Modification history of the test report ........................................................................................ 3 1.2 Standards ................................................................................................................................ 3 1.3 Test methods ........................................................................................................................... 3 1.4 Deviation from standards.......................................................................................................... 3 1.5 List of applied test(s) of the EUT............................................................................................... 3 1.6 Test information ....................................................................................................................... 3 1.7 Test set up ............................................................................................................................... 3 1.8 Test period ............................................................................................................................... 3 2 Equipment Under Test ........................................................................................................... 4 2.1 EUT information ....................................................................................................................... 4 2.2 Modification to the EUT ............................................................................................................ 4 2.3 Variation of family model(s) ...................................................................................................... 5 2.4 Description of test mode........................................................................................................... 5 3 Configuration of Equipment .................................................................................................. 6 3.1 Equipment used ....................................................................................................................... 6 3.2 System configuration................................................................................................................ 6 4 Test Result ............................................................................................................................. 7 4.1 Equivalent Isotropic Radiated Power ........................................................................................ 7 4.2 Peak to Average Ratio ........................................................................................................... 10 4.3 Occupied Bandwidth .............................................................................................................. 13 4.4 Band Edge Spurious and Harmonic at Antenna Terminals ...................................................... 15 4.5 Radiated Emissions and Harmonic Emissions ........................................................................ 20 4.6 Frequency Stability................................................................................................................. 24 5 Measurement Uncertainty.................................................................................................... 26 6 Laboratory Information ........................................................................................................ 27 Appendix A. Test Equipment............................................................................................................... 28 TÜV SÜD Japan Ltd. Page 2 of 29

Document Number: JPD-TR-19043-0 1 Summary of Test 1.1 Modification history of the test report Document Number Modification History Issue Date JPD-TR-19043-0 First Issue Refer to the cover page 1.2 Standards CFR47 FCC Part 24 Subpart E 1.3 Test methods KDB 971168 D01 Power Meas License Digital Systems v03r01 ANSI/TIA/EIA-603-D-2010 1.4 Deviation from standards None 1.5 List of applied test(s) of the EUT Test item Test item Condition Result Remark section 2.1046 Conducted Output Power Conducted PASS *1 Effective Radiated Power 24.232(c) Radiated PASS - Equivalent Isotropic Radiated Power 24.232(d) Peak to Average Ratio Conducted PASS - 24.238(a) Occupied Bandwidth Conducted PASS - 2.1049 24.238(a) Band Edge Spurious and Harmonic at Conducted PASS - 2.1051 Antenna Terminal 24.238(a) Radiated emissions and Radiated PASS - 2.1053 Harmonic Emissions 24.235 Frequency Stability Conducted PASS - 2.1055 *1: Refer to RF Exposure Report (Test Report_SAR) 1.6 Test information None 1.7 Test set up Table-top 1.8 Test period 26-December-2018 - 04-February-2019 TÜV SÜD Japan Ltd. Page 3 of 29

Document Number: JPD-TR-19043-0 2 Equipment Under Test 2.1 EUT information Applicant KYOCERA Corporation Yokohama Office 2-1-1 Kagahara, Tsuzuki-ku Yokohama-shi, Kanagawa, Japan Phone: +81-45-943-6253 Fax: +81-45-943-6314 Equipment Under Test (EUT) Mobile Phone Model number JA53 Serial number N/A Trade name Kyocera Number of sample(s) 1 EUT condition Pre-Production Power rating Battery: DC 3.8 V Size (W) 51.3 × (D) 17.4 × (H) 112.3 mm Environment Indoor and Outdoor use Terminal limitation -20˚C to 60˚C RF Specification Frequency of Operation Up Link GSM1900: 1850.2-1909.8 MHz Down Link GSM1900: 1930.2-1989.8 MHz Modulation type GSM1900: GMSK Emission designator GSM1900: 248KGXW Equivalent Isotropic Radiated GSM1900: 1.8197 W (32.6 dBm) Power (E.I.R.P) Antenna type Internal antenna Antenna gain GSM1900: 0.61 dBi 2.2 Modification to the EUT The table below details modifications made to the EUT during the test project. Modification State Description of Modification Modification fitted by Date of Modification Model: JA53, Serial Number: N/A 0 As supplied by the applicant Not Applicable Not Applicable TÜV SÜD Japan Ltd. Page 4 of 29

Document Number: JPD-TR-19043-0 2.3 Variation of family model(s) 2.3.1 List of family model(s) JA53 has model with camera and without camera. 2.3.2 Reason for selection of EUT Not applicable 2.4 Description of test mode The EUT had been tested under operating condition. There are three channels have been tested as following: Band Channel Frequency [MHz] 512 1850.2 GSM1900 661 1880.0 810 1909.8 The field strength of spurious emissions was measured at each position of all three axis X, Y and Z to compare the level, and the maximum noise. The worst emission was found in X-axis, Open and the worst case recorded. TÜV SÜD Japan Ltd. Page 5 of 29

Document Number: JPD-TR-19043-0 3 Configuration of Equipment Numbers assigned to equipment on the diagram in “3.2 System configuration” correspond to the list in “3.1 Equipment used”. 3.1 Equipment used No. Equipment Company Model No. Serial No. FCC ID/DoC Comment 1 Mobile Phone KYOCERA JA53 N/A JOYJA53 EUT 3.2 System configuration 1. Mobile Phone (EUT) TÜV SÜD Japan Ltd. Page 6 of 29

Document Number: JPD-TR-19043-0 4 Test Result 4.1 Equivalent Isotropic Radiated Power 4.1.1 Measurement procedure [FCC 24.232(c)] <Step 1> The EUT and support equipment are placed on a 1 meter x 1 meter surface, 0.8 meter height styrene foam table. Radiated emission measurements are performed at 3 meter distance with the broadband antenna (double ridged guide antenna). The antenna is positioned both the horizontal and vertical planes of polarization and height is varied 1 to 4 meters and stopped at height producing the maximum emission. The bandwidth of the spectrum analyzer is set to 1 MHz. The turntable is rotated by 360 degrees and stopped at azimuth of producing the maximum emission. <Step 2> The substitution antenna is replaced by the transmitter antenna (EUT). The frequency of the signal generator is adjusted to the measurement frequency. Level of the signal generator is adjusted to the level that is obtained from step 1, and record the emission level of signal generator. The spectrum analyzer is set to; a) Span = 1.5 times the OBW b) RBW = 1-5% of the expected OBW, not to exceed 1 MHz c) VBW ≥ 3 x RBW d) Number of sweep points ≥ 2 x span / RBW e) Sweep time = auto-couple f) Detector = RMS (power averaging) g) If the EUT can be configured to transmit continuously (i.e., burst duty cycle ≥ 98%), then set the trigger to free run. h) If the EUT cannot be configured to transmit continuously (i.e., burst duty cycle < 98 %), then use a sweep trigger with the level set to enable triggering only on full power bursts and configure the EUT to transmit at full power for the entire duration of each sweep. Ensure that the sweep time is less than or equal to the transmission burst duration. i) Trace average at least 100 traces in power averaging (i.e., RMS) mode. j) Compute the power by integrating the spectrum across the OBW of the signal using the instrument’s band power measurement function, with the band limits set equal to the OBW band edges. If the instrument does not have a band power function, then sum the spectrum levels (in linear power units) at intervals equal to the RBW extending across the entire OBW of the spectrum. - Test configuration TÜV SÜD Japan Ltd. Page 7 of 29

Document Number: JPD-TR-19043-0 4.1.2 Calculation method Result(EIRP) = Ant. Input - Cable loss + Antenna Gain Margin = Limit – Result (EIRP) Example: Limit @ 1880 MHz : 33.0 dBm Ant. Input = 19.3 dBm Cable loss = 1.1dB Ant. Gain = 8.3 dBi Result = 19.3 - 1.1 + 8.3 = 26.5 dBm Margin = 33.0 - 26.5 = 6.5 dB 4.1.3 Limit 2 W (33 dBm) TÜV SÜD Japan Ltd. Page 8 of 29

Document Number: JPD-TR-19043-0 4.1.4 Test data Date : 30-January-2019 Temperature : 18.2 [˚C] Humidity : 27.5 [%] Test engineer : Test place : 3m Semi-anechoic chamber Chiaki Kanno [GSM1900 - With camera] S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 1850.2 -28.9 23.0 1.1 8.4 30.3 33.0 2.7 H 1880.0 -29.2 23.5 1.1 8.4 30.7 33.0 2.3 H 1909.8 -28.4 25.4 1.2 8.4 32.6 33.0 0.4 [GSM1900 - Without camera] S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 1850.2 -28.5 23.4 1.1 8.4 30.7 33.0 2.3 H 1880.0 -28.9 23.8 1.1 8.4 31.0 33.0 2.0 H 1909.8 -28.5 25.3 1.2 8.4 32.5 33.0 0.5 TÜV SÜD Japan Ltd. Page 9 of 29

Document Number: JPD-TR-19043-0 4.2 Peak to Average Ratio 4.2.1 Measurement procedure [FCC 24.232(d)] The peak to average ratio was measured with a spectrum analyzer connected to the antenna terminal. The spectrum analyzer is set to; [GSM1900] a) Span = 5 MHz b) RBW = 1 MHz c) VBW ≥ 3 x RBW d) Detector = Peak / Average e) Sweep time = auto-couple f) Trace mode=Max hold [WCDMA Band II, LTE Band II] a) Power Stat CCDF mode 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 as follows: 1) For continuous transmissions, set to 1ms. 2) For burst transmissions, employ an external trigger that is synchronized with the EUT burst timing sequence, or use the internal burst trigger with a trigger level that allows the burst duration. e) Record the maximum PAPR level associated with a probability of 0.1%. - Test configuration Power splitter Spectrum Wireless Analyzer Attenuator Communication Coaxial cable Coaxial cable Tester EUT 4.2.2 Limit 13 dB or less TÜV SÜD Japan Ltd. Page 10 of 29

Document Number: JPD-TR-19043-0 4.2.3 Measurement result Date : 07-December-2018 Temperature : 21.8 [˚C] Humidity : 31.6 [%] Test engineer : Test place : Shielded room No.4 Taiki Watanabe Frequency Peak to Average Power Ratio Limit Band Channel [MHz] [dB] [dB] 512 1850.2 0.3 GSM1900 661 1880.0 0.05 13.0 810 1909.8 0.1 TÜV SÜD Japan Ltd. Page 11 of 29

Document Number: JPD-TR-19043-0 4.2.4 Trace data [GSM1900] Channel: 512 Channel: 661 Channel: 810 TÜV SÜD Japan Ltd. Page 12 of 29

Document Number: JPD-TR-19043-0 4.3 Occupied Bandwidth 4.3.1 Measurement procedure [FCC 24.238(a), 2.1049] The Occupied bandwidth was measured with a spectrum analyzer connected to the antenna terminal. The spectrum analyzer is set to; a) RBW = 1-5% of the expected OBW & VBW ≥ 3 x RBW b) Detector = Peak c) Trace mode = Max hold d) Sweep time = auto-couple - Test configuration Power splitter Spectrum Wireless Analyzer Attenuator Communication Coaxial cable Coaxial cable Tester EUT 4.3.2 Limit None 4.3.3 Measurement result Date : 07-December-2018 Temperature : 21.8 [˚C] Humidity : 36.3 [%] Test engineer : Test place : Shielded room No.4 Taiki Watanabe Frequency Test Result Band Channel [MHz] [kHz] 512 1850.2 244.9966 GSM1900 661 1880.0 242.7151 810 1909.8 247.9905 TÜV SÜD Japan Ltd. Page 13 of 29

Document Number: JPD-TR-19043-0 4.3.4 Trace data [GSM1900] Channel: 512 Channel: 661 Channel: 810 TÜV SÜD Japan Ltd. Page 14 of 29

Document Number: JPD-TR-19043-0 4.4 Band Edge Spurious and Harmonic at Antenna Terminals 4.4.1 Measurement procedure [FCC 24.238(a), 2.1051] The band edge spurious and harmonic was measured with a spectrum analyzer connected to the antenna terminal. The spectrum analyzer is set to; <Band Edge> a) Span was set large enough so as to capture all out of band emissions near the band edge b) RBW ≥ 1% of the emission bandwidth or 2% of the emission bandwidth c) VBW ≥ 3 x RBW d) Detector = RMS e) Trace mode = Max hold f) Sweep time = auto-couple g) Number of sweep point ≥ 2 x span / RBW <Spurious Emissions> a) RBW = 1MHz & VBW ≥ 3 x RBW b) Detector = Peak c) Trace mode = Max hold d) Sweep time = auto-couple e) Number of sweep point ≥ 2 x span / RBW - Test configuration Power splitter Spectrum Wireless Analyzer Attenuator Communication Coaxial cable Coaxial cable Tester EUT 4.4.2 Limit -13 dBm or less 4.4.3 Measurement result Date : 07-December-2018 Temperature : 21.8 [˚C] Humidity : 36.3 [%] Test engineer : Test place : Shielded room No.4 Taiki Watanabe Frequency Limit Band Channel Results [MHz] [dB] 512 1850.2 -13.0 See the trace data PASS GSM1900 810 1909.8 -13.0 See the trace data PASS TÜV SÜD Japan Ltd. Page 15 of 29

Document Number: JPD-TR-19043-0 4.4.4 Trace data [GSM1900] (Band Edge) Channel: 512 Channel: 810 TÜV SÜD Japan Ltd. Page 16 of 29

Document Number: JPD-TR-19043-0 (Spurious Emissions) Note: Conducted spurious test was measured in the worst case of conducted output power. Channel: 512 30MHz-5GHz 5GHz-10GHz 10GHz-15GHz 15GHz-20GHz TÜV SÜD Japan Ltd. Page 17 of 29

Document Number: JPD-TR-19043-0 Channel: 661 30MHz-5GHz 5GHz-10GHz 10GHz-15GHz 15GHz-20GHz TÜV SÜD Japan Ltd. Page 18 of 29

Document Number: JPD-TR-19043-0 Channel: 810 30MHz-5GHz 5GHz-10GHz 10GHz-15GHz 15GHz-20GHz TÜV SÜD Japan Ltd. Page 19 of 29

Document Number: JPD-TR-19043-0 4.5 Radiated Emissions and Harmonic Emissions 4.5.1 Measurement procedure [FCC 24.238(a), 2.1053] <Step 1> The EUT and support equipment are placed on a 1 meter x 1 meter surface, 0.8 meter height styrene foam table. Radiated emission measurements are performed at 3 meter distance with the broadband antenna (Biconical antenna, Log periodic antenna and double ridged guide antenna). The antenna is positioned both the horizontal and vertical planes of polarization and height is varied 1 to 4 meters and stopped at height producing the maximum emission. The bandwidth of the spectrum analyzer is set to 1 MHz. The turntable is rotated by 360 degrees and stopped at azimuth of producing the maximum emission. The frequency is investigated up to 20 GHz. <Step 2> The substitution antenna is replaced by the transmitter antenna (EUT). The frequency of the signal generator is adjusted to the measurement frequency. Level of the signal generator is adjusted to the level that is obtained from step 1, and record the emission level of signal generator. The spectrum analyzer is set to; a) RBW = 100 kHz for below 1 GHz and 1 MHz for above 1 GHz / VBW ≥ 3 x RBW b) Detector = Peak c) Trace mode = Max hold d) Sweep time = auto-couple - Test configuration TÜV SÜD Japan Ltd. Page 20 of 29

Document Number: JPD-TR-19043-0 4.5.2 Calculation method Result = Ant. Input - Cable loss + Antenna Gain Margin = Limit – Result (EIRP) Example: Limit @ 3700.4 MHz : -13.0 dBm Ant. Input = -55.6 dBm Cable loss = 1.6 dB Ant. Gain = 9.2 dBi Result = -55.6 - 1.6 + 9.2 = -49.3 dBm Margin = -13.0 - (-49.3) = 36.3 dB 4.5.3 Limit -13 dBm or less 4.5.4 Test data Date : 26-December-2018 Temperature : 20.0 [˚C] Humidity : 26.8 [%] Test engineer : Test place : 3m Semi-anechoic chamber Taiki Watanabe Date : 10 January,2019 Temperature : 21.1 [˚C] Humidity : 27.3 [%] Test engineer : Test place : 3m Semi-anechoic chamber Taiki Watanabe Date : 11-January-2019 Temperature : 20.1 [˚C] Humidity : 26.4 [%] Test engineer : Test place : 3m Semi-anechoic chamber Taiki Watanabe Date : 30-January-2019 Temperature : 18.2 [˚C] Humidity : 27.5 [%] Test engineer : Test place : 3m Semi-anechoic chamber Chiaki Kanno TÜV SÜD Japan Ltd. Page 21 of 29

Document Number: JPD-TR-19043-0 [GSM1900 - With camera] Channel: 512 S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 3700.4 -56.7 -60.6 1.6 9.5 -52.7 -13.0 39.7 V 3700.4 -56.9 -61.9 1.6 9.5 -54.0 -13.0 41.0 H 5551.0 -50.8 -43.0 2.0 13.3 -31.7 -13.0 18.7 V 5551.0 -52.1 -42.6 2.0 13.3 -31.3 -13.0 18.3 V 7401.0 -57.7 -48.0 2.3 13.4 -36.9 -13.0 23.9 H 12950.0 -56.4 -43.0 3.1 15.5 -30.7 -13.0 17.7 V 12950.0 -56.0 -41.0 3.1 15.5 -28.7 -13.0 15.7 H 14800.0 -55.5 -40.0 3.3 14.3 -29.0 -13.0 16.0 V 14800.0 -51.7 -32.3 3.3 14.3 -21.3 -13.0 8.3 Channel: 661 S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 3760.0 -56.0 -54.1 1.6 9.4 -46.3 -13.0 33.3 V 3760.0 -56.7 -54.0 1.6 9.4 -46.2 -13.0 33.2 V 5640.0 -56.8 -49.5 2.0 13.5 -38.0 -13.0 25.0 V 7520.0 -56.1 -45.6 2.4 13.6 -34.3 -13.0 21.3 V 9400.0 -61.1 -49.1 2.6 14.2 -37.5 -13.0 24.5 V 13160.0 -55.6 -40.5 3.2 15.3 -28.4 -13.0 15.4 H 15040.0 -54.9 -41.3 3.4 15.7 -29.0 -13.0 16.0 V 15040.0 -51.3 -32.6 3.4 15.7 -20.3 -13.0 7.3 Channel: 810 S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 3819.6 -57.2 -54.1 1.7 9.3 -46.4 -13.0 33.4 V 3819.6 -56.5 -54.3 1.7 9.3 -46.6 -13.0 33.6 V 7639.0 -57.8 -47.0 2.4 13.8 -35.5 -13.0 22.5 V 9549.0 -58.6 -46.0 2.7 14.4 -34.3 -13.0 21.3 H 11460.0 -59.2 -45.4 2.9 14.9 -33.4 -13.0 20.4 V 11460.0 -59.7 -43.0 2.9 14.9 -31.0 -13.0 18.0 H 13370.0 -56.1 -44.4 3.2 14.9 -32.7 -13.0 19.7 V 13370.0 -54.5 -40.4 3.2 14.9 -28.7 -13.0 15.7 TÜV SÜD Japan Ltd. Page 22 of 29

Document Number: JPD-TR-19043-0 [GSM1900 - Without camera] Channel: 512 S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 3700.4 -56.1 -60.0 1.6 9.5 -52.1 -13.0 39.1 V 3700.4 -55.3 -60.3 1.6 9.5 -52.4 -13.0 39.4 H 14800.0 -54.0 -35.5 3.3 14.3 -24.5 -13.0 11.5 V 14800.0 -54.5 -35.8 3.3 14.3 -24.8 -13.0 11.8 Channel: 661 S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 3760.0 -55.5 -53.6 1.6 9.4 -45.8 -13.0 32.8 V 3760.0 -56.0 -53.3 1.6 9.4 -45.5 -13.0 32.5 H 9400.0 -61.0 -52.3 2.6 14.2 -40.7 -13.0 27.7 V 9400.0 -58.1 -46.1 2.6 14.2 -34.5 -13.0 21.5 H 11280.0 -60.6 -47.0 2.9 15.1 -34.9 -13.0 21.9 H 15040.0 -55.2 -41.6 3.4 15.7 -29.3 -13.0 16.3 V 15040.0 -56.1 -37.4 3.4 15.7 -25.1 -13.0 12.1 Channel: 810 S.A Frequency Ant. Input Cable loss Ant.Gain Result Limit Margin H/V Reading [MHz] [dBm] [dB] [dBi] [dBm] [dBm] [dB] [dBm] H 3819.6 -56.1 -53.0 1.7 9.3 -45.3 -13.0 32.3 V 3819.6 -55.7 -53.5 1.7 9.3 -45.8 -13.0 32.8 V 13370.0 -54.3 -40.2 3.2 14.9 -28.5 -13.0 15.5 TÜV SÜD Japan Ltd. Page 23 of 29

Document Number: JPD-TR-19043-0 4.6 Frequency Stability 4.6.1 Measurement procedure [FCC 24.235, 2.1055] The EUT was placed of an inside of an constant temperature chamber as the temperature in the chamber was varied between -30˚C and +50˚C. The temperature was incremented by 10˚C intervals and the unit was allowed to stabilize at each measurement. The frequency drift was measured with the normal Temperature and voltage tolerance and it is presented as the ppm unit. - Test configuration Power splitter Spectrum Wireless Analyzer Attenuator Communication Coaxial cable Coaxial cable Tester EUT Constant Temperature Chamber 4.6.2 Limit ±2.5 ppm TÜV SÜD Japan Ltd. Page 24 of 29

Document Number: JPD-TR-19043-0 4.6.3 Measurement result Date : 04-February-2019 Temperature : 20.2 [˚C] Humidity : 41.4 [%] Test engineer : Test place : Shielded room No.4 Kazunori Saito [GSM1900] Channel: 661 Limit: ±0.00025% = ±2.5 ppm Power Supply Temperature Measurements Frequency Frequency Tolerance Limit Result [V] [ºC] [Hz] [ppm] [ppm] 25(Ref.) 1,879,999,964 0.00000 ±2.5 Pass 50 1,879,999,986 0.01187 ±2.5 Pass 40 1,880,000,014 0.02633 ±2.5 Pass 30 1,880,000,013 0.02597 ±2.5 Pass 20 1,880,000,014 0.02677 ±2.5 Pass 3.80 10 1,880,000,013 0.02586 ±2.5 Pass 0 1,880,000,011 0.02523 ±2.5 Pass -10 1,880,000,020 0.02962 ±2.5 Pass -20 1,880,000,040 0.04019 ±2.5 Pass -30 1,880,000,037 0.03905 ±2.5 Pass 3.42 25 1,880,000,015 0.02727 ±2.5 Pass 4.18 25 1,880,000,013 0.02617 ±2.5 Pass Calculation; Frequency Tolerance (ppm) = Measurements Frequency (Hz) – Reference Frequency (Hz) / Reference Frequency (Hz) x 1000000 TÜV SÜD Japan Ltd. Page 25 of 29

Document Number: JPD-TR-19043-0 5 Measurement Uncertainty Expanded uncertainties stated are calculated with a coverage Factor k=2. Please note that these results are not taken into account when measurement uncertainty considerations contained in ETSI TR 100 028-0011 determining compliance or non-compliance with test result. Test item Measurement uncertainty Conducted emission, AMN (9 kHz – 150 kHz) ±3.8 dB Conducted emission, AMN (150 kHz – 30 MHz) ±3.3 dB Radiated emission (9 kHz – 30 MHz) ±3.0 dB Radiated emission (30 MHz – 1000 MHz) ±4.7 dB Radiated emission (1 GHz – 6 GHz) ±4.9 dB Radiated emission (6 GHz – 18 GHz) ±5.2 dB Radiated emission (18 GHz – 40 GHz) ±5.8 dB TÜV SÜD Japan Ltd. Page 26 of 29

Document Number: JPD-TR-19043-0 6 Laboratory Information Testing was performed and the report was issued at: TÜV SÜD Japan Ltd. Yonezawa Testing Center Address: 5-4149-7 Hachimanpara, Yonezawa-shi, Yamagata, 992-1128 Japan Phone: +81-238-28-2881 Fax: +81-238-28-2888 Accreditation and Registration NVLAP LAB CODE: 200306-0 VLAC Accreditation No.: VLAC-013 BSMI Laboratory Code: SL2-IN-E-6018, SL2-A1-E-6018 Innovation, Science and Economic Development Canada Site number Facility Expiration date 4224A-4 3 m Semi-anechoic chamber 27-November-2020 4224A-5 10 m Semi-anechoic chamber No. 1 27-November-2020 4224A-6 10 m Semi-anechoic chamber No. 2 14-December-2019 VCCI Council Registration number Expiration date A-0166 03-July-2019 TÜV SÜD Japan Ltd. Page 27 of 29

Document Number: JPD-TR-19043-0 Appendix A. Test Equipment Antenna port conducted test Equipment Company Model No. Serial No. Cal. Due Cal. Date Spectrum analyzer Agilent Technologies E4440A US44302655 31-Jul-2019 02-Jul-2018 Attenuator Weinschel 56-10 J4180 31-Jul-2019 12-Jul-2018 Microwave cable HUBER+SUHNER SUCOFLEX 104 199119/4 31-Mar-2019 01-Mar-2018 Microwave cable HUBER+SUHNER SUCOFELX102/2m 31648 31-Mar-2019 01-Mar-2018 Power divider ANRITSU K240B 020205 31-Jul-2019 12-Jul-2018 Wideband Radio Frequency Tester ROHDE&SCHWARZ CMW500 126079 31-Oct-2019 12-Oct-2018 Temperature and humidity chamber ESPEC PL1KP 14007261 31-Dec-2019 07-Dec-2018 Radiated emission Equipment Company Model No. Serial No. Cal. Due Cal. Date EMI Receiver ROHDE&SCHWARZ ESCI 100765 30-Sep-2019 20-Sep-2018 Spectrum analyzer Agilent Technologies E4447A MY46180188 30-Apr-2019 12-Apr-2018 Spectrum analyzer Agilent Technologies E4440A US40420937 31-Oct-2019 12-Oct-2018 Preamplifier SONOMA 310 372170 30-Sep-2019 20-Sep-2018 Biconical antenna Schwarzbeck VHA9103/BBA9106 VHA91032155 31-Aug-2019 06-Aug-2018 Log periodic antenna Schwarzbeck UHALP9108A 0560 31-Aug-2019 06-Aug-2018 Attenuator TAMAGAWA.ELEC CFA-01/6dB N/A(S465) 31-May-2019 16-May-2018 Attenuator TAMAGAWA.ELEC CFA-10/3dB N/A(S503) 31-Jul-2019 11-Jul-2018 31-Jan-2019 18-Jan-2018 Preamplifier TSJ MLA-100M18-B02-40 1929118 31-Jan-2020 17-Jan-2019 31-Jan-2019 18-Jan-2018 Attenuator AEROFLEX 26A-10 081217-08 31-Jan-2020 17-Jan-2019 Double ridged guide antenna ETS LINDGREN 3117 00052315 31-Mar-2019 14-Mar-2018 Attenuator Agilent Technologies 8491B MY39268633 31-Mar-2019 14-Mar-2018 Double ridged guide antenna A.H.Systems Inc. SAS-574 469 31-Aug-2019 24-Aug-2018 Preamplifier TSJ MLA-1840-B03-35 1240332 31-Aug-2019 24-Aug-2018 High Pass Filter Wainwright WHKX2.8/18G-6SS 1 31-Jul-2019 12-Jul-2018 Band rejection filter Micro-Tronics BRC50720 014 31-Dec-2019 20-Dec-2018 Signal generator ROHDE&SCHWARZ SMB100A 177525 31-Jul-2019 31-Jul-2018 RF power amplifier R&K CGA020M602-2633R B40240 31-May-2019 17-May-2018 Microwave cable HUBER+SUHNER SUCOFELX102/2m 31648 31-Mar-2019 01-Mar-2018 Dipole antenna Schwarzbeck VHAP 1020 31-Aug-2019 03-Aug-2018 Dipole antenna Schwarzbeck UHAP 994 31-Aug-2019 03-Aug-2018 Double ridged guide antenna EMCO 3115 00058532 31-Jan-2019 18-Jan-2018 Double ridged guide antenna EMCO 3115 4328 31-May-2019 08-May-2018 Double ridged guide antenna ETS LINDGREN 3117 00218815 31-Dec-2019 27-Dec-2018 Wideband Radio Frequency Tester ROHDE&SCHWARZ CMW500 126079 31-Oct-2019 12-Oct-2018 31-Jan-2019 18-Jan-2018 SUCOFLEX104/9m MY30037/4 31-Jan-2020 16-Jan-2019 31-Jan-2019 18-Jan-2018 SUCOFLEX104/1m my24610/4 31-Jan-2020 16-Jan-2019 31-Jan-2019 18-Jan-2018 SUCOFLEX104/8m SN MY30031/4 31-Jan-2020 16-Jan-2019 Microwave cable HUBER+SUHNER 31-Jan-2019 18-Jan-2018 SUCOFLEX104 MY32976/4 31-Jan-2020 16-Jan-2019 31-Jan-2019 19-Jan-2018 SUCOFLEX104/1.5m MY19309/4 31-Jan-2020 16-Jan-2019 31-Jan-2019 19-Jan-2018 SUCOFLEX104/7m 41625/6 31-Jan-2020 16-Jan-2019 TÜV SÜD Japan Ltd. Test Report Rev. FCC-24E3.0 Page 28 of 29

Document Number: JPD-TR-19043-0 PC DELL DIMENSION E521 75465BX N/A N/A Software TOYO Corporation EP5/RE-AJ 0611193/V5.6.0 N/A N/A Absorber RIKEN PFP30 N/A N/A N/A 3m Semi an-echoic Chamber TOKIN N/A N/A(9002-NSA) 31-May-2019 21-May-2018 3m Semi an-echoic Chamber TOKIN N/A N/A(9002-SVSWR) 31-May-2019 22-May-2018 *: The calibrations of the above equipment are traceable to NIST or equivalent standards of the reference organizations. TÜV SÜD Japan Ltd. Test Report Rev. FCC-24E3.0 Page 29 of 29


Document Created: 2019-03-24 08:10:39
Document Modified: 2019-03-24 08:10:39
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