CERTIFICATION TEST REPORT

Transcription

1 CERTIFICATION TEST REPORT Report Number. : E4V3 Applicant : Model : FCC ID : EUT Description : Test Standard(s) : APPLE, INC. 1 INFINITE LOOP CUPERTINO, CA 95014, U.S.A. A1901 BCG-E3175A SMARTPHONE FCC 47 CFR PART 15 SUBPART E Date Of Issue: August 31, 2017 Prepared by: UL Verification Services Inc Benicia Street Fremont, CA 94538, U.S.A. TEL: (510) FAX: (510)

2 Revision History Rev. Issue Date Revisions Revised By V1 8/10/2017 Initial issue Chin Pang V2 8/17/2017 Address TCB s Questions Chin Pang V3 8/31/2017 Address TCB s Questions Chin Pang Page 2 of 780

3 TABLE OF CONTENTS 1. ATTESTATION OF TEST RESULTS TEST METHODOLOGY FACILITIES AND ACCREDITATION CALIBRATION AND UNCERTAINTY MEASURING INSTRUMENT CALIBRATION SAMPLE CALCULATION MEASUREMENT UNCERTAINTY EQUIPMENT UNDER TEST DESCRIPTION OF EUT MAXIMUM OUTPUT POWER DESCRIPTION OF AVAILABLE ANTENNAS SOFTWARE AND FIRMWARE WORST-CASE CONFIGURATION AND MODE DESCRIPTION OF TEST SETUP TEST AND MEASUREMENT EQUIPMENT ON TIME, DUTY CYCLE AND MEASUREMENT METHODS ON TIME AND DUTY CYCLE MEASUREMENT METHODS ANTENNA PORT TEST RESULTS n HT20 UAT 2 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT20 LAT 3 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT20 2TX CDD MIMO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT40 UAT 2 SISO MODE IN THE 5.2GHz BAND Page 3 of 780

4 db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT40 LAT 3 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT40 2TX CDD MIMO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT80 UAT 2 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT80 LAT 3 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT80 2TX CDD MIMO MODE IN THE 5.2GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT20 UAT 2 SISO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT20 LAT 3 SISO MODE IN THE 5.3GHz BAND db BANDWIDTH `99% BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT20 2TX CDD MIMO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT40 UAT 2 SISO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD Page 4 of 780

5 n HT40 LAT 3 SISO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT40 2TX CDD MIMO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT80 UAT 2 SISO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT80 LAT 3 SISO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT80 2TX CDD MIMO MODE IN THE 5.3GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD n HT20 UAT 2 SISO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT20 UAT 2 SISO STRADDLE CHANNEL 144 (FCC) db BANDWIDTH n HT20 LAT 3 SISO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT20 LAT 3 SISO STRADDLE CHANNEL db BANDWIDTH n HT20 2TX CDD MIMO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT20 2TX CDD MIMO STRADDLE CHANNEL db BANDWIDTH n HT40 UAT 2 SISO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH Page 5 of 780

6 AVERAGE POWER OUTPUT POWER AND PPSD ac HT40 UAT 2 SISO STRADDLE CHANNEL db BANDWIDTH n HT40 LAT 3 SISO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT40 LAT 3 SISO STRADDLE CHANNEL db BANDWIDTH n HT40 2TX CDD MIMO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD ac HT40 2TX CDD MIMO STRADDLE CHANNEL db BANDWIDTH ac HT80 UAT 2 SISO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD STRADDLE CHANNEL db BANDWIDTH ac HT80 LAT 3 SISO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD STRADDLE CHANNEL db BANDWIDTH ac HT80 2TX CDD MIMO MODE IN THE 5.6GHz BAND db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER AND PPSD STRADDLE CHANNEL db BANDWIDTH n HT20 UAT 2 SISO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY n HT20 LAT 3 SISO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH Page 6 of 780

7 AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY n HT20 2TX CDD MIMO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY n HT40 UAT 2 SISO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY n HT40 LAT 3 SISO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY n HT40 2TX CDD MIMO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY ac HT80 UAT 2 SISO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY ac HT80 LAT 3 SISO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER OUTPUT POWER POWER SPECTRAL DENSITY ac HT80 2TX CDD MIMO MODE IN THE 5.8GHz BAND db BANDWIDTH db BANDWIDTH % BANDWIDTH AVERAGE POWER Page 7 of 780

8 OUTPUT POWER POWER SPECTRAL DENSITY RADIATED TEST RESULTS LIMITS AND PROCEDURE n HT20 UAT 2 SISO MODE IN THE 5.2GHz BAND n HT20 LAT 3 SISO MODE IN THE 5.2GHz BAND n HT20 2TX CDD MIMO MODE IN THE 5.2GHz BAND n HT40 UAT 2 SISO MODE IN THE 5.2GHz BAND n HT40 LAT 3 SISO MODE IN THE 5.2GHz BAND n HT40 2TX CDD MIMO MODE IN THE 5.2GHz BAND ac HT80 UAT 2 SISO MODE IN THE 5.2GHz BAND ac HT80 LAT 3 SISO MODE IN THE 5.2GHz BAND ac HT80 2TX CDD MIMO MODE IN THE 5.2GHz BAND n HT20 UAT 2 SISO MODE IN THE 5.3GHz BAND n HT20 LAT 3 SISO MODE IN THE 5.3GHz BAND n HT20 2TX CDD MIMO MODE IN THE 5.3GHz BAND n HT40 UAT 2 SISO MODE IN THE 5.3GHz BAND n HT40 LAT 3 SISO MODE IN THE 5.3GHz BAND n HT40 2TX CDD MIMO MODE IN THE 5.3GHz BAND ac HT80 UAT 2 SISO MODE IN THE 5.3GHz BAND ac HT80 LAT 3 SISO MODE IN THE 5.3GHz BAND ac HT80 2TX CDD MIMO MODE IN THE 5.3GHz BAND n HT20 UAT 2 SISO MODE IN THE 5.6GHz BAND n HT20 LAT 3 SISO MODE IN THE 5.6GHz BAND n HT20 2TX CDD MIMO MODE IN THE 5.6GHz BAND ac HT20 2TX CDD MIMO STRADDLE CHANNEL n HT40 UAT 2 SISO MODE IN THE 5.6GHz BAND n HT40 2TX CDD MIMO MODE IN THE 5.6GHz BAND ac HT40 2TX CDD MIMO STRADDLE CHANNEL ac HT80 UAT 2 SISO MODE IN THE 5.6GHz BAND ac HT80 LAT 3 SISO MODE IN THE 5.6GHz BAND ac HT80 2TX CDD MIMO MODE IN THE 5.6GHz BAND ac HT80 2TX CDD MIMO STRADDLE CHANNEL n HT20 UAT 2 SISO MODE IN THE 5.8GHz BAND n HT20 LAT 3 SISO MODE IN THE 5.8GHz BAND n HT20 2TX CDD MIMO MODE IN THE 5.8GHz BAND n HT40 UAT 2 SISO MODE IN THE 5.8GHz BAND n HT40 LAT 3 SISO MODE IN THE 5.8GHz BAND n HT40 2TX CDD MIMO MODE IN THE 5.8GHz BAND ac HT80 UAT 2 SISO MODE IN THE 5.8GHz BAND ac HT80 LAT 3 SISO MODE IN THE 5.8GHz BAND ac HT80 2TX CDD MIMO MODE IN THE 5.8GHz BAND WORST-CASE BELOW 1 GHz WORST-CASE 18 to 26 GHz WORST-CASE 26 to 40 GHz AC POWER LINE CONDUCTED EMISSIONS EUT POWERED BY AC/DC ADAPTER VIA USB CABLE EUT POWERED BY HOST PC VIA USB CABLE Page 8 of 780

9 11. DYNAMIC FREQUENCY SELECTION OVERVIEW LIMITS TEST AND MEASUREMENT SYSTEM TEST ROOM ENVIRONMENT TEST AND MEASUREMENT SOFTWARE SETUP OF EUT (CLIENT MODE) SETUP OF EUT (CLIENT-TO-CLIENT COMMUNICATIONS MODE) SETUP OF EUT (PEER TO PEER MODE) DESCRIPTION OF EUT CLIENT MODE RESULTS FOR 20 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME CLIENT MODE RESULTS FOR 40 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME CLIENT MODE RESULTS FOR 80 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME MINUTE NON-OCCUPANCY PERIOD CLIENT-TO-CLIENT COMMUNICATIONS MODE RESULTS FOR 20 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME CLIENT-TO-CLIENT COMMUNICATIONS MODE RESULTS FOR 40 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME CLIENT-TO-CLIENT COMMUNICATIONS MODE RESULTS FOR 80 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME MINUTE NON-OCCUPANCY PERIOD PEER TO PEER MODE EUT RESULTS FOR 20 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS Page 9 of 780

10 MOVE AND CLOSING TIME PEER TO PEER MODE EUT RESULTS FOR 40 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME PEER TO PEER MODE EUT RESULTS FOR 80 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME MINUTE NON-OCCUPANCY PERIOD PEER TO PEER MODE PEER SLAVE DEVICE RESULTS FOR 20 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME PEER TO PEER MODE PEER SLAVE DEVICE RESULTS FOR 40 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME PEER TO PEER MODE PEER SLAVE DEVICE RESULTS FOR 80 MHz BANDWIDTH TEST CHANNEL RADAR WAVEFORM AND TRAFFIC OVERLAPPING CHANNEL TESTS MOVE AND CLOSING TIME MINUTE NON-OCCUPANCY PERIOD SETUP PHOTOS Page 10 of 780

11 1. ATTESTATION OF TEST RESULTS COMPANY NAME: EUT DESCRIPTION: MODEL: SERIAL NUMBER: APPLE, INC. 1 INFINITE LOOP CUPERTINO, CA 95014, U.S.A. SMARTPHONE A1901 C39TX016J8QN; C39TM018J578 (DFS) DATE TESTED: MAY 16, 2017 AUGUST 07, 2017 APPLICABLE STANDARDS STANDARD CFR 47 Part 15 Subpart E TEST RESULTS Pass UL Verification Services Inc. tested the above equipment in accordance with the requirements set forth in the above standards. All indications of Pass/Fail in this report are opinions expressed by UL Verification Services Inc. based on interpretations and/or observations of test results. Measurement Uncertainties were not taken into account and are published for informational purposes only. The test results show that the equipment tested is capable of demonstrating compliance with the requirements as documented in this report. Note: The results documented in this report apply only to the tested sample, under the conditions and modes of operation as described herein. This document may not be altered or revised in any way unless done so by UL Verification Services Inc. and all revisions are duly noted in the revisions section. Any alteration of this document not carried out by UL Verification Services Inc. will constitute fraud and shall nullify the document. This report must not be used by the client to claim product certification, approval, or endorsement by NVLAP, NIST, any agency of the Federal Government, or any agency of any government. Approved & Released For UL Verification Services Inc. By: Prepared By: Chin Pang Senior Engineer Tri Pham Test Engineer Page 11 of 780

12 2. TEST METHODOLOGY FCC: The tests documented in this report were performed in accordance with FCC CFR 47 Part 2, FCC CFR 47 Part 15, FCC 14-30, FCC KDB D01 v02r01, FCC KDB D02 v02/d03 v01r02/d04 v01/d06 v02/ D07v02, FCC KDB D02 v01r04, FCC KDB D03 v01, ANSI C FACILITIES AND ACCREDITATION The test sites and measurement facilities used to collect data are located at and Benicia Street, Fremont, California, USA. Line conducted emissions are measured only at the address. The following table identifies which facilities were utilized for radiated emission measurements documented in this report. Specific facilities are also identified in the test results sections Benicia Street Benicia Street Chamber A (IC:2324B-1) Chamber D (IC: ) Chamber B (IC:2324B-2) Chamber E (IC: ) Chamber C (IC:2324B-3) Chamber F (IC: ) Chamber G (IC: ) Chamber H (IC: ) The above test sites and facilities are covered under FCC Test Firm Registration # UL Verification Services Inc. is accredited by NVLAP, Laboratory Code The full scope of accreditation can be viewed at Page 12 of 780

13 4. CALIBRATION AND UNCERTAINTY 4.1. MEASURING INSTRUMENT CALIBRATION The measuring equipment utilized to perform the tests documented in this report has been calibrated in accordance with the manufacturer's recommendations, and is traceable to recognized national standards SAMPLE CALCULATION Where relevant, the following sample calculation is provided: Field Strength (dbuv/m) = Measured Voltage (dbuv) + Antenna Factor (db/m) + Cable Loss (db) Preamp Gain (db) 36.5 dbuv db/m db 26.9 db = 28.9 dbuv/m 4.3. MEASUREMENT UNCERTAINTY Where relevant, the following measurement uncertainty levels have been estimated for tests performed on the apparatus: Where relevant, the following measurement uncertainty levels have been estimated for tests performed on the apparatus: Parameter Worst Case Conducted Disturbance, 9KHz to 0.15 MHz Worst Case Conducted Disturbance, 0.15 to 30 MHz Worst Case Radiated Disturbance, 9KHz to 30 MHz Worst Case Radiated Disturbance, 30 to 1000 MHz Worst Case Radiated Disturbance, 1000 to MHz Worst Case Radiated Disturbance, to MHz Worst Case Radiated Disturbance, to MHz Uncertainty 3.84 db 3.65 db 3.15 db 5.36 db 4.32 db 4.45 db 5.24 db Occupied Channel Bandwidth ±0.39 % Time ±0.02 % Uncertainty figures are valid to a confidence level of 95%. Page 13 of 780

14 5. EQUIPMENT UNDER TEST 5.1. DESCRIPTION OF EUT The Equipment Under Test is a mobile phone with GSM, GPRS, EGPRS, UMTS, LTE and TD-SCDMA technologies. It also supports IEEE a/b/g/n/ac, Bluetooth, GPS and NFC. The device has a built-in inductive charging receiver which is not user accessible. The rechargeable battery is not user accessible MAXIMUM OUTPUT POWER The transmitter has a maximum conducted output power as follows: NOTE: Covered modes are test reduction modes. The output powers on the covered modes are equal to or less than the mode referenced and use the same modulation. 5.2GHz Band Frequency Range Mode Output Power Output Power (MHz) (dbm) (mw) a n HT20 SISO n VHT20 1TX n HT20 CDD 2TX n HT20 STBC/SDM 2TX, ac VHT20 STBC/SDM 2TX Covered by n HT20 SISO Covered by n HT20 SISO Covered by n HT20 2TX CDD n HT40 SISO n VHT40 1TX n HT40 CDD 2TX n HT40 STBC/SDM 2TX, ac VHT40 STBC/SDM 2TX ac VHT80 SISO ac VHT80 CDD 2TX ac VHT80 STBC/SDM 2TX Covered by n HT20 SISO Covered by n HT40 2TX CDD Covered by ac VHT80 2TX CDD Page 14 of 780

15 5.3GHz Band Frequency Range Mode Output Power Output Power (MHz) (dbm) (mw) a Covered by n HT20 SISO n HT20 SISO n VHT20 1TX n HT20 CDD 2TX n HT20 STBC/SDM 2TX, ac VHT20 STBC/SDM 2TX Covered by n HT20 SISO Covered by n HT20 2TX CDD n HT40 SISO n VHT40 1TX Covered by n HT40 SISO n HT40 CDD 2TX n HT40 STBC/SDM 2TX, ac VHT40 STBC/SDM 2TX Covered by n HT40 2TX CDD ac VHT80 SISO ac VHT80 CDD 2TX ac VHT80 STBC/SDM 2TX Covered by ac HT80 2TX CDD Page 15 of 780

16 5.6GHz Band Frequency Range Mode Output Power Output Power (MHz) (dbm) (mw) a Covered by n HT20 SISO n HT20 SISO n VHT20 1TX ac VHT20 SISO (based on UNII-2C band output power) n HT20 CDD 2TX n HT20 STBC/SDM 2TX, ac VHT20 STBC/SDM 2TX ac VHT20 CDD 2TX (based on UNII-2C band output power) ac VHT20 STBC SISO/2TX (based on UNII-2C band output power) Covered by n HT20 SISO Covered by n HT20 CDD 2TX Covered by n HT20 2TX CDD n HT40 SISO n HT40 1TX Covered by n HT40 SISO ac VHT40 SISO (based on UNII-2C band output power) n HT40 CDD 2TX n HT40 STBC/SDM 2TX, ac VHT40 STBC/SDM 2TX Covered by n HT40 CDD 2TX ac VHT40 CDD 2TX (based on UNII-2C band output power) ac VHT40 STBC/SDM 2TX Covered by ac VHT40 CDD 2TX ac VHT80 SISO ac VHT80 SISO (based on UNII-2C band output power) ac VHT80 CDD 2TX ac VHT80 STBC/SDM 2TX ac VHT80 CDD 2TX (based on UNII-2C band output power) ac VHT80 STBC/SDM 2TX Covered by ac VHT80 CDD 2TX Covered by ac VHT80 CDD 2TX Page 16 of 780

17 5.8GHz Band Frequency Range Mode Output Power Output Power (MHz) (dbm) (mw) a Covered by n HT20 SISO n HT20 SISO n VHT20 1TX Covered by n HT20 SISO n HT20 CDD 2TX n HT20 STBC/SDM 2TX, ac VHT20 STBC/SDM 2TX Covered by n HT20 CDD 2TX n HT40 SISO n VHT40 1TX n HT40 CDD 2TX n HT40 STBC/SDM 2TX, ac VHT40 STBC/SDM 2TX ac VHT80 SISO ac VHT80 CDD 2TX ac VHT80 STBC/SDM 2TX Covered by n HT40 SISO Covered by n HT40 CDD 2TX Covered by ac VHT80 CDD 2TX 5.3. DESCRIPTION OF AVAILABLE ANTENNAS Frequency Band Antenna Gain (dbi) (GHz) UAT 2 LAT SOFTWARE AND FIRMWARE The firmware installed in the EUT during testing was version Page 17 of 780

18 5.5. WORST-CASE CONFIGURATION AND MODE For radiated harmonics spurious below 1GHz, 1-18GHz L/M/H channels, 18-40GHz, and power line conducted emissions were performed with the EUT set at the CDD mode among the CDD/STBC/SDM modes with power setting equal or higher than SISO modes as worst-case scenario. Radiated band edge, harmonic, and spurious emissions from 1GHz to 18GHz were performed with the EUT was set to transmit at highest power on Low/Middle/High channels. Radiated emissions below 30MHz, below 1GHz, above 18GHz and power line conducted emissions were performed with the EUT transmits at the channel with the highest output power as worst-case scenario. For SISO modes, there are two transmission antennas. The antenna used in any given time can be either UAT 2 or LAT 3. Both antenna ports have the same power; output power and PSD measurement for SISO modes on both antennas are reported. For MIMO modes, both UAT 2 and LAT 3 used at the same time. The fundamental of the EUT was investigated in three orthogonal orientations X (Flatbed), Y (Landscape), Z (Portrait), on both UAT 2 and LAT 3 antennas. In addition, the EUT was also investigated with and without AC/DC charger, headphones & laptop, It was determined that (see table below) was worst-case orientation for both antennas without AC/DC charger, headphones, or laptop; therefore, all final radiated testing was performed with EUT only in (see table below) orientation for 1-18GHz and 18 40GHz. And for MHz EUT was tested with AC/DC charger. All radiated harmonic 1-18GHz emissions on SISO mode, straddle channels are covered by 2TX MIMO mode with power setting equal or higher than SISO among the CDD/STBC/SDM modes. Frequency Band Mode Antenna Port Worst-case Orientation (GHz) UAT 2 Y-Landscape 1TX SISO LAT 3 Y-Landscape 2TX MIMO UAT 2 + LAT 3 Y-Landscape Worst-case data rates as provided by the client were: a mode: 6 Mbps n HT20 mode: MCS n HT40 mode: MCS ac VHT20 mode: MCS ac VHT40 mode: MCS ac VHT80 mode: MCS ac VHT20 and VHT40 mode are different from nHT20 and HT40 only in control messages and have the same power settings. Page 18 of 780

19 There are two vendors of the WiFi/Bluetooth radio modules: variant 1 and variant 2. The Wi- Fi/Bluetooth radio modules have the same mechanical outline (e.g., the same package dimension and pin-out layout), use the same on-board antenna matching circuit, have an identical antenna structure, and are built and tested to conform to the same specifications and to operate within the same tolerances. Baseline testing was performed on the two variants to determine the worst case on all conducted power and radiated emissions. For simultaneous transmission of multiple channels from the same antenna LAT 3 in the 2.4GHz BT/BLEand 5GHz bands, tests were conducted for various configurations having the highest power. No noticeable new emission was found. Page 19 of 780

20 5.6. DESCRIPTION OF TEST SETUP SUPPORT EQUIPMENT Support Equipment List Description Manufacturer Model Serial Number FCC ID Laptop AC/DC adapter Apple A1344 T1580 NA Laptop Apple A1278 C02HJ0A7DTY4 NA DC power supply Lambda GEN SCPV56329 NA I/O CABLES (CONDUCTED TEST) Cable No Port # of identical ports I/O Cable List Connector Cable Type Type Cable Length (m) Remarks 1 Antenna 1 SMA Shielded 1 N/A 2 USB 1 USB Shielded 1 Laptop to EUT 3 AC 1 AC Un-shielded 3 N/A 4 Aligator clip 1 minigrabber Un-Shielded 1 DC power supply to EUT I/O CABLES (RADIATED ABOVE 1 GHZ) Cable No NA Port # of identical ports I/O Cable List Connector Cable Type Type Cable Length (m) Remarks I/O CABLES (AC POWER CONDUCTED TEST AND BELOW 1 GHZ) Cable No Port # of identical ports I/O Cable List Connector Cable Type Type Cable Length (m) Remarks 1 AC 1 AC Un-shielded 3 N/A I/O CABLES (AC LINE CONDUCTED: LAPTOP CONFIGUARTION) Cable No Port # of identical ports I/O Cable List Connector Cable Type Type Cable Length (m) Remarks 1 AC 1 AC Un-shielded 3 N/A 2 USB 1 USB Shielded 1 N/A Page 20 of 780

21 TEST SETUP The EUT was tested connected to a host Laptop via USB cable adapter and SMA cable connected to antenna port. Test software exercised the EUT. SETUP DIAGRAM Page 21 of 780

22 TEST SETUP- RADIATED-ABOVE 1 GHZ The EUT was powered by battery. Test software exercised the EUT. SETUP DIAGRAM Page 22 of 780

23 TEST SETUP- BELOW 1GHZ & AC LINE CONDUCTED TESTS The EUT was powered by AC/DC adapter. Test software exercised the EUT. SETUP DIAGRAM Page 23 of 780

24 TEST SETUP- AC LINE CONDUCTED TEST (LAPTOP CONFIGURATION) The EUT was tested connected to a host Laptop via USB cable. Test software exercised the EUT. SETUP DIAGRAM Page 24 of 780

25 6. TEST AND MEASUREMENT EQUIPMENT TEST EQUIPMENT LIST Description Manufacturer Model Asset Cal Due Antenna, Horn 1-18GHz ETS Lindgren 3117 T863 6/9/2018 Amplifier, 1 to 18GHz Miteq AFS S-42 T741 11/29/2017 Antenna, Horn 1-18GHz ETS Lindgren 3117 T344 4/20/2018 *Antenna, Broadband Hybrid, 30MHz to 2000MHz Sunol Sciences JB3 T900 5/03/2017 Amplifier, 1 to 18GHz, 35dB Amplical AMP1G18-35 T1569 9/15/2017 *Amplifier, 10KHz to 1GHz, 32dB Sonoma 310N T285 6/20/2017 Spectrum Analyzer, PXA 3Hz to 44GHz Keysight N9030A T /2/2017 *Antenna Horn, 18 to 26GHz ARA MWH-1826 T447 6/16/2017 *Amplifier, 1 to 26.5GHz 23.5dB gain Minimum Keysight 8449B T402 7/5/2017 Spectrum Analyzer, 40GHz Agilent 8564E T106 9/7/2017 *Antenna, Horn 26.5GHz to 40GHz ARA MWH-2640/B T446 5/25/2017 *Amplifier, 26.5GHz to 40GHz Miteq NSP 4000 SP2 T88 4/29/2017 Horn Antenna, 40GHz ARA MWH-2640/B /19/2017 *Pre-Amp 18-26GHz Agilent Technology 8449B T404 7/5/2017 Power Meter, P-series single channel Keysight N1912A T1245 1/05/2018 Power Sensor Keysight N1921A T1224 1/31/2018 AC Line Conducted EMI Test Receiver 9Khz-7GHz Rohde & Schwarz ESCI7 T /06/2018 *LISN for Conducted Emissions CISPR-16 Power Cable, Line Conducted Emissions Fischer 50/ T /08/2017 UL PG1 T861 9/1/2017 UL AUTOMATION SOFTWARE Radiated Software UL UL EMC Ver 9.5, April 26, 2016 Conducted Software UL UL EMC Ver 5.4, October 13, 2016 AC Line Conducted Software UL UL EMC Ver 9.5, May 26, 2015 The following test and measurement equipment was utilized for the tests documented in this report: NOTE: *testing is completed before equipment calibration expiration date. Page 25 of 780

26 7. ON TIME, DUTY CYCLE AND MEASUREMENT METHODS LIMITS 7.1. ON TIME AND DUTY CYCLE None; for reporting purposes only. PROCEDURE KDB Zero-Span Spectrum Analyzer Method. RESULTS Mode ON Time Period Duty Cycle Duty Duty Cycle 1/B B x Cycle Correction Factor Minimum VBW (msec) (msec) (linear) (%) (db) (khz) n HT20 1TX % n HT20 CDD 2TX % n HT40 1TX % n HT40 CDD 2TX % ac VHT80 1TX % ac VHT80 CDD 2TX % Page 26 of 780

27 DUTY CYCLE PLOTS DUTY CYCLE n HT20 1TX MODE DUTY CYCLE n HT20 CDD MODE Page 27 of 780

28 DUTY CYCLE n HT40 1TX MODE DUTY CYCLE n HT40 CDD MODE Page 28 of 780

29 DUTY CYCLE n HT80 1TX MODE DUTY CYCLE n HT80 CDD MODE Page 29 of 780

30 7.2. MEASUREMENT METHODS 6 db Emission BW: KDB D02 v01r04, Section C. 26 db Emission BW: KDB D02 v01r04, Section C. 99% Occupied BW: KDB D02 v01r04, Section D. Conducted Output Power: KDB D02 v01r04, Section E.3.b (Method PM-G). Power Spectral Density: KDB D02 v01r04, Section F (Method SA-2). Unwanted emissions in restricted bands: KDB D02 v01r04, Sections G.3, G.4, G.5, and G.6. Unwanted emissions in non-restricted bands: KDB D02 v01r04, Sections G.3, G.4, and G.5. Conducted line emissions: C63.10, Clause 6.2 Page 30 of 780

31 8. ANTENNA PORT TEST RESULTS LIMITS n HT20 UAT 2 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH None; for reporting purposes only. RESULTS 26 db BW Channel Frequency UAT 2 (MHz) Low Mid High Page 31 of 780

32 26dB, CH LOW 26dB, CH MID Page 32 of 780

33 26dB, CH HIGH Page 33 of 780

34 LIMITS % BANDWIDTH None; for reporting purposes only. RESULTS 99% BW Channel Frequency UAT 2 (MHz) Low Mid High Page 34 of 780

35 OBW, CH LOW OBW, CH MID Page 35 of 780

36 OBW, CH HIGH Page 36 of 780

37 AVERAGE POWER ID: Date: 7/25/17 LIMITS None; for reporting purposes only. TEST PROCEDURE Measurements perform using a wideband gated RF power meter. RESULTS Power UAT Channel Frequency 2 (dbm) Low Mid High Page 37 of 780

38 LIMITS FCC (a) (1) OUTPUT POWER AND PPSD (i) For an outdoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. The maximum e.i.r.p. at any elevation angle above 30 degrees as measured from the horizon must not exceed 125 mw (21 dbm). (ii) For an indoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. (iii) For fixed point-to-point access points operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W. Fixed point-topoint U-NII devices may employ antennas with directional gain up to 23 dbi without any corresponding reduction in the maximum conducted output power or maximum power spectral density. For fixed point-to-point transmitters that employ a directional antenna gain greater than 23 dbi, a 1 db reduction in maximum conducted output power and maximum power spectral density is required for each 1 db of antenna gain in excess of 23 dbi. Fixed, point-to-point operations exclude the use of point-to-multipoint systems, omnidirectional applications, and multiple collocated transmitters transmitting the same information. The operator of the U-NII device, or if the equipment is professionally installed, the installer, is responsible for ensuring that systems employing high gain directional antennas are used exclusively for fixed, point-to-point operations. (iv) For mobile and portable client devices in the GHz band, the maximum conducted output power over the frequency band of operation shall not exceed 250 mw provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 11 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. TEST PROCEDURE Measurements perform using a wideband gated RF power meter provided that the gate parameters are adjusted such that the power is measured only when the EUT is transmitting at its maximum power control level. Since the measurement is made only during the ON time of the transmitter, no duty cycle correction factor is required. DIRECTIONAL ANTENNA GAIN There is only one transmitter output therefore the directional gain is equal to the antenna gain. Page 38 of 780

39 RESULTS Antenna Gain and Limits Channel Frequency Directional Directional Power PSD Gain Gain Limit Limit for Power for PSD (MHz) (dbi) (dbi) (dbm) (dbm/1mhz) Low Mid High Duty Cycle CF (db) 0.00 Included in Calculations of Corr'd PSD Output Power Results Channel Frequency UAT 2 Total Power Power Meas Corr'd Limit Margin Power Power (MHz) (dbm) (dbm) (dbm) (db) Low Mid High PSD Results Channel Frequency UAT 2 Total PSD PSD Meas Corr'd Limit Margin PSD PSD (MHz) (dbm/1mhz) (dbm/1mhz) (dbm/1mhz) (db) Low Mid High Page 39 of 780

40 , CH LOW, CH MID Page 40 of 780

41 , CH HIGH Page 41 of 780

42 LIMITS n HT20 LAT 3 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH None; for reporting purposes only. RESULTS 26 db BW Channel Frequency LAT 3 (MHz) Low Mid High Page 42 of 780

43 26dB, CH LOW 26dB, CH MID Page 43 of 780

44 26dB, CH HIGH Page 44 of 780

45 LIMITS % BANDWIDTH None; for reporting purposes only. RESULTS 99% BW Channel Frequency LAT 3 (MHz) Low Mid High Page 45 of 780

46 OBW, CH LOW OBW, CH MID Page 46 of 780

47 OBW, CH HIGH Page 47 of 780

48 AVERAGE POWER ID: Date: 7/25/17 LIMITS None; for reporting purposes only. TEST PROCEDURE Measurements perform using a wideband gated RF power meter. RESULTS Power LAT Channel Frequency 3 (dbm) Low Mid High Page 48 of 780

49 LIMITS FCC (a) (1) OUTPUT POWER AND PPSD (i) For an outdoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. The maximum e.i.r.p. at any elevation angle above 30 degrees as measured from the horizon must not exceed 125 mw (21 dbm). (ii) For an indoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. (iii) For fixed point-to-point access points operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W. Fixed point-topoint U-NII devices may employ antennas with directional gain up to 23 dbi without any corresponding reduction in the maximum conducted output power or maximum power spectral density. For fixed point-to-point transmitters that employ a directional antenna gain greater than 23 dbi, a 1 db reduction in maximum conducted output power and maximum power spectral density is required for each 1 db of antenna gain in excess of 23 dbi. Fixed, point-to-point operations exclude the use of point-to-multipoint systems, omnidirectional applications, and multiple collocated transmitters transmitting the same information. The operator of the U-NII device, or if the equipment is professionally installed, the installer, is responsible for ensuring that systems employing high gain directional antennas are used exclusively for fixed, point-to-point operations. (iv) For mobile and portable client devices in the GHz band, the maximum conducted output power over the frequency band of operation shall not exceed 250 mw provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 11 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. TEST PROCEDURE Measurements perform using a wideband gated RF power meter provided that the gate parameters are adjusted such that the power is measured only when the EUT is transmitting at its maximum power control level. Since the measurement is made only during the ON time of the transmitter, no duty cycle correction factor is required. DIRECTIONAL ANTENNA GAIN There is only one transmitter output therefore the directional gain is equal to the antenna gain. Page 49 of 780

50 RESULTS Antenna Gain and Limits Channel Frequency Directional Directional Power PSD Gain Gain Limit Limit for Power for PSD (MHz) (dbi) (dbi) (dbm) (dbm/1mhz) Low Mid High Duty Cycle CF (db) 0.00 Included in Calculations of Corr'd PSD Output Power Results Channel Frequency LAT 3 Total Power Power Meas Corr'd Limit Margin Power Power (MHz) (dbm) (dbm) (dbm) (db) Low Mid High PSD Results Channel Frequency LAT 3 Total PSD PSD Meas Corr'd Limit Margin PSD PSD (MHz) (dbm/1mhz) (dbm/1mhz) (dbm/1mhz) (db) Low Mid High Page 50 of 780

51 , CH LOW, CH MID Page 51 of 780

52 , CH HIGH Page 52 of 780

53 LIMITS n HT20 2TX CDD MIMO MODE IN THE 5.2GHz BAND db BANDWIDTH None; for reporting purposes only. RESULTS Channel Frequency 26 db BW UAT 2 (MHz) 26 db BW LAT 3 (MHz) Low Mid High Page 53 of 780

54 UAT 2 26dB, CH LOW LAT 3 26dB, CH LOW Page 54 of 780

55 UAT 2 26dB, CH MID LAT 3 26dB, CH MID Page 55 of 780

56 UAT 2 26dB, CH HIGH LAT 3 26dB, CH HIGH Page 56 of 780

57 LIMITS % BANDWIDTH None; for reporting purposes only. RESULTS Channel Frequency 99% BW UAT 2 (MHz) 99% BW LAT 3 (MHz) Low Mid High Page 57 of 780

58 UAT 2 OBW, CH LOW LAT 3 OBW, CH LOW Page 58 of 780

59 UAT 2 OBW, CH MID LAT 3 OBW, CH MID Page 59 of 780

60 UAT 2 OBW, CH HIGH LAT 3 OBW, CH HIGH Page 60 of 780

61 AVERAGE POWER ID: Date: 7/25/17 LIMITS None; for reporting purposes only. TEST PROCEDURE Measurements perform using a wideband gated RF power meter. RESULTS Average Power Results Channel Frequency UAT 2 LAT 3 Total Power Power Power (MHz) (dbm) (dbm) (dbm) Low Mid High Page 61 of 780

62 LIMITS FCC (a) (1) OUTPUT POWER AND PPSD (i) For an outdoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. The maximum e.i.r.p. at any elevation angle above 30 degrees as measured from the horizon must not exceed 125 mw (21 dbm). (ii) For an indoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. (iii) For fixed point-to-point access points operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W. Fixed point-topoint U-NII devices may employ antennas with directional gain up to 23 dbi without any corresponding reduction in the maximum conducted output power or maximum power spectral density. For fixed point-to-point transmitters that employ a directional antenna gain greater than 23 dbi, a 1 db reduction in maximum conducted output power and maximum power spectral density is required for each 1 db of antenna gain in excess of 23 dbi. Fixed, point-to-point operations exclude the use of point-to-multipoint systems, omnidirectional applications, and multiple collocated transmitters transmitting the same information. The operator of the U-NII device, or if the equipment is professionally installed, the installer, is responsible for ensuring that systems employing high gain directional antennas are used exclusively for fixed, point-to-point operations. (iv) For mobile and portable client devices in the GHz band, the maximum conducted output power over the frequency band of operation shall not exceed 250 mw provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 11 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. TEST PROCEDURE Measurements perform using a wideband gated RF power meter provided that the gate parameters are adjusted such that the power is measured only when the EUT is transmitting at its maximum power control level. Since the measurement is made only during the ON time of the transmitter, no duty cycle correction factor is required. Page 62 of 780

63 DIRECTIONAL ANTENNA GAIN For Power used uncorrelated gain: The TX chains are uncorrelated and the antenna gain is unequal among the chains. The directional gain is: UAT 2 LAT 3 Uncorrelated Chains Antenna Antenna Directional Gain Gain Gain (dbi) (dbi) (dbi) For PSD used correlated gain: The TX chains are correlated and the antenna gain is unequal among the chains. The directional gain is: UAT 2 LAT 3 Correlated Chains Antenna Antenna Directional Gain Gain Gain (dbi) (dbi) (dbi) Page 63 of 780

64 RESULTS Antenna Gain and Limits Channel Frequency Directional Directional Power PSD Gain Gain Limit Limit for Power for PSD (MHz) (dbi) (dbi) (dbm) (dbm/1mhz) Low Mid High Duty Cycle CF (db) 0.00 Included in Calculations of Corr'd PSD Output Power Results Channel Frequency UAT 2 LAT 3 Total Power Power Meas Meas Corr'd Limit Margin Power Power Power (MHz) (dbm) (dbm) (dbm) (dbm) (db) Low Mid High PSD Results Channel Frequency UAT 2 LAT 3 Total PSD PSD Meas Meas Corr'd Limit Margin PSD PSD PSD (MHz) (dbm/1mhz) (dbm/1mhz) (dbm/1mhz) (dbm/1mhz) (db) Low Mid High Page 64 of 780

65 UAT 2, CH LOW LAT 3, CH LOW Page 65 of 780

66 UAT 2, CH MID LAT 3, CH MID Page 66 of 780

67 UAT 2, CH HIGH LAT 3, CH HIGH Page 67 of 780

68 LIMITS n HT40 UAT 2 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH None; for reporting purposes only. RESULTS 26 db BW Channel Frequency UAT 2 (MHz) Low High Page 68 of 780

69 26dB, CH LOW 26dB, CH HIGH Page 69 of 780

70 LIMITS % BANDWIDTH None; for reporting purposes only. RESULTS 99% BW Channel Frequency UAT 2 (MHz) Low High Page 70 of 780

71 OBW, CH LOW OBW, CH HIGH Page 71 of 780

72 AVERAGE POWER ID: Date: 7/25/17 LIMITS None; for reporting purposes only. TEST PROCEDURE Measurements perform using a wideband gated RF power meter. RESULTS Power UAT Channel Frequency 2 (dbm) Low High Page 72 of 780

73 LIMITS FCC (a) (1) OUTPUT POWER AND PPSD (i) For an outdoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. The maximum e.i.r.p. at any elevation angle above 30 degrees as measured from the horizon must not exceed 125 mw (21 dbm). (ii) For an indoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. (iii) For fixed point-to-point access points operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W. Fixed point-topoint U-NII devices may employ antennas with directional gain up to 23 dbi without any corresponding reduction in the maximum conducted output power or maximum power spectral density. For fixed point-to-point transmitters that employ a directional antenna gain greater than 23 dbi, a 1 db reduction in maximum conducted output power and maximum power spectral density is required for each 1 db of antenna gain in excess of 23 dbi. Fixed, point-to-point operations exclude the use of point-to-multipoint systems, omnidirectional applications, and multiple collocated transmitters transmitting the same information. The operator of the U-NII device, or if the equipment is professionally installed, the installer, is responsible for ensuring that systems employing high gain directional antennas are used exclusively for fixed, point-to-point operations. (iv) For mobile and portable client devices in the GHz band, the maximum conducted output power over the frequency band of operation shall not exceed 250 mw provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 11 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. TEST PROCEDURE Measurements perform using a wideband gated RF power meter provided that the gate parameters are adjusted such that the power is measured only when the EUT is transmitting at its maximum power control level. Since the measurement is made only during the ON time of the transmitter, no duty cycle correction factor is required. DIRECTIONAL ANTENNA GAIN There is only one transmitter output therefore the directional gain is equal to the antenna gain. Page 73 of 780

74 RESULTS Antenna Gain and Limits Channel Frequency Directional Directional Power PSD Gain Gain Limit Limit for Power for PSD (MHz) (dbi) (dbi) (dbm) (dbm/1mhz) Low High Duty Cycle CF (db) 0.10 Included in Calculations of Corr'PSD Output Power Results Channel Frequency UAT 2 Total Power Power Meas Corr'd Limit Margin Power Power (MHz) (dbm) (dbm) (dbm) (db) Low High PSD Results Channel Frequency UAT 2 Total PSD PSD Meas Corr'd Limit Margin PSD PSD (MHz) (dbm/1mhz) (dbm/1mhz) (dbm/1mhz) (db) Low High Page 74 of 780

75 , CH LOW, CH HIGH Page 75 of 780

76 LIMITS n HT40 LAT 3 SISO MODE IN THE 5.2GHz BAND db BANDWIDTH None; for reporting purposes only. RESULTS 26 db BW Channel Frequency LAT 3 (MHz) Low High Page 76 of 780

77 26dB, CH LOW 26dB, CH HIGH Page 77 of 780

78 LIMITS % BANDWIDTH None; for reporting purposes only. RESULTS 99% BW Channel Frequency LAT 3 (MHz) Low High Page 78 of 780

79 OBW, CH LOW OBW, CH HIGH Page 79 of 780

80 AVERAGE POWER ID: Date: 7/25/17 LIMITS None; for reporting purposes only. TEST PROCEDURE Measurements perform using a wideband gated RF power meter. RESULTS Power LAT Channel Frequency 3 (dbm) Low High Page 80 of 780

81 LIMITS FCC (a) (1) OUTPUT POWER AND PPSD (i) For an outdoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. The maximum e.i.r.p. at any elevation angle above 30 degrees as measured from the horizon must not exceed 125 mw (21 dbm). (ii) For an indoor access point operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 17 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. (iii) For fixed point-to-point access points operating in the band GHz, the maximum conducted output power over the frequency band of operation shall not exceed 1 W. Fixed point-topoint U-NII devices may employ antennas with directional gain up to 23 dbi without any corresponding reduction in the maximum conducted output power or maximum power spectral density. For fixed point-to-point transmitters that employ a directional antenna gain greater than 23 dbi, a 1 db reduction in maximum conducted output power and maximum power spectral density is required for each 1 db of antenna gain in excess of 23 dbi. Fixed, point-to-point operations exclude the use of point-to-multipoint systems, omnidirectional applications, and multiple collocated transmitters transmitting the same information. The operator of the U-NII device, or if the equipment is professionally installed, the installer, is responsible for ensuring that systems employing high gain directional antennas are used exclusively for fixed, point-to-point operations. (iv) For mobile and portable client devices in the GHz band, the maximum conducted output power over the frequency band of operation shall not exceed 250 mw provided the maximum antenna gain does not exceed 6 dbi. In addition, the maximum power spectral density shall not exceed 11 dbm in any 1 megahertz band. If transmitting antennas of directional gain greater than 6 dbi are used, both the maximum conducted output power and the maximum power spectral density shall be reduced by the amount in db that the directional gain of the antenna exceeds 6 dbi. TEST PROCEDURE Measurements perform using a wideband gated RF power meter provided that the gate parameters are adjusted such that the power is measured only when the EUT is transmitting at its maximum power control level. Since the measurement is made only during the ON time of the transmitter, no duty cycle correction factor is required. DIRECTIONAL ANTENNA GAIN There is only one transmitter output therefore the directional gain is equal to the antenna gain. Page 81 of 780

82 RESULTS Antenna Gain and Limits Channel Frequency Directional Directional Power PSD Gain Gain Limit Limit for Power for PSD (MHz) (dbi) (dbi) (dbm) (dbm/1mhz) Low High Duty Cycle CF (db) 0.10 Included in Calculations of Corr'PSD Output Power Results Channel Frequency LAT 3 Total Power Power Meas Corr'd Limit Margin Power Power (MHz) (dbm) (dbm) (dbm) (db) Low High PSD Results Channel Frequency LAT 3 Total PSD PSD Meas Corr'd Limit Margin PSD PSD (MHz) (dbm/1mhz) (dbm/1mhz) (dbm/1mhz) (db) Low High Page 82 of 780

83 , CH LOW, CH HIGH Page 83 of 780

84 LIMITS n HT40 2TX CDD MIMO MODE IN THE 5.2GHz BAND db BANDWIDTH None; for reporting purposes only. RESULTS Channel Frequency 26 db BW UAT 2 (MHz) 26 db BW LAT 3 (MHz) Low High Page 84 of 780

85 UAT 2 26dB, CH LOW LAT 3 26dB, CH LOW Page 85 of 780

86 UAT 2 26dB, CH HIGH LAT 3 26dB, CH HIGH Page 86 of 780

87 LIMITS % BANDWIDTH None; for reporting purposes only. RESULTS Channel Frequency 99% BW UAT 2 (MHz) 99% BW LAT 3 (MHz) Low High Page 87 of 780

88 UAT 2 OBW, CH LOW LAT 3 OBW, CH LOW Page 88 of 780