Test Report_DFS

FCC ID: SLE-WAPC002

Test Report

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FCCID_4055980

Report No.: 1840253R-RFUSP10V00 Dynamic Frequency Selection (DFS) Test Report Product Name MOXA IEEE 802.11a/n/ac 4*4 module Model No WAPC002 FCC ID SLE-WAPC002 Applicant MOXA Inc. Address FL.4, NO. 135. LANE 235, BAOQIAO RD. XINDIAN DIST., NEW TAIPEI CITY, TAIWAN Date of Receipt Apr. 20, 2018 Issued Date Sep. 14, 2018 Report No. 1840253R-RFUSP10V00 Report Version V0.1-Draft The test results relate only to the samples tested. The test results shown in the test report are traceable to the national/international standard through the calibration report of the equipment and evaluated measurement uncertainty herein. This report must not be used to claim product endorsement by TAF or any agency of the government. The test report shall not be reproduced without the written approval of DEKRA Testing and Certification Co., Ltd. Page: 1 of 25

Report No.: 1840253R-RFUSP10V00 DFS Tes t R e p o r t Issued Date: Sep. 14, 2018 Report No.: 1840253R-RFUSP10V00 Product Name MOXA IEEE 802.11a/n/ac 4*4 module Applicant MOXA Inc. FL.4, NO. 135. LANE 235, BAOQIAO RD. XINDIAN DIST., NEW TAIPEI Address CITY, TAIWAN Manufacturer MOXA Inc. Model No. WAPC002 FCC ID. SLE-WAPC002 EUT Rated Voltage DC 3.3V EUT Test Voltage AC 120V/60Hz Trade Name MOXA Applicable Standard FCC CFR Title 47 Part 15 Subpart E 15.407 (h): 2016 KDB 905462 D02 UNII DFS Compliance Procedures v02 KDB 905462 D03 UNII Clients Without Radar Detection v01r02 FCC 14-30 Test Result Complied Documented By : ( Senior Adm. Specialist / Rita Huang ) Tested By : ( Engineer / Sam Hsu ) Approved By : ( Director/ Vincent Lin ) Page: 2 of 25

Report No.: 1840253R-RFUSP10V00 TA B L E O F C O N T E N T S Description Page 1. GENERAL INFORMATION ..................................................................................................................... 4 1.1. EUT Description ............................................................................................................................................................................ 4 1.2. Standard Requirement.................................................................................................................................................................... 7 1.3. UNII Device Description ............................................................................................................................................................... 7 1.4. Test Equipment .............................................................................................................................................................................. 9 1.5. Test Setup .................................................................................................................................................................................... 10 1.6. DFS Requirements Prior to Use of a Channel ............................................................................................................................. 10 1.7. DFS requirements during normal operation................................................................................................................................. 11 1.8. DFS Detection Thresholds ........................................................................................................................................................... 11 1.9. Radar Test Waveforms ................................................................................................................................................................. 12 1.10. Radar Waveform Calibration ....................................................................................................................................................... 17 1.11. Radar Waveform Calibration Result ............................................................................................................................................ 18 1.12. Slave Data Traffic Plot Result...................................................................................................................................................... 19 2. IN-SERVICE MONITORING FOR CHANNEL MOVE TIME AND CHANNEL CLOSING TRANSMISSION TIME AND NON-OCCUPANCY PERIOD ......................................................................20 2.1. Test Procedure ............................................................................................................................................................................. 20 2.2. Test Requirement ......................................................................................................................................................................... 20 2.3. Uncertainty .................................................................................................................................................................................. 20 2.4. Test Result of Channel Move Time and Channel Closing Transmission Time and Non-Occupancy Period ............................... 21 3. DFS TEST SETUP PHOTO...................................................................................................................... 24 Attachment 1: EUT Test Photographs Page: 3 of 25

Report No.: 1840253R-RFUSP10V00 1. GENERAL INFORMATION 1.1. EUT Description Product Name MOXA IEEE 802.11a/n/ac 4*4 module Trade Name MOXA FCC ID. SLE-WAPC002 Model No. WAPC002 Frequency Range 802.11a/n-20MHz: 5180-5320MHz, 5500-5700MHz, 5745-5825MHz 802.11n-40MHz: 5190-5310, 5510-5670MHz, 5755-5795MHz 802.11ac-20MHz: 5720, 802.11ac-40MHz: 5710 802.11ac-80MHz: 5210-5290MHz, 5530-5690MHz, 5775MHz Number of Channels 802.11a/n-20MHz: 24; 802.11n-40MHz: 11 802.11ac-20MHz: 1, 802.11ac-40MHz: 1, 802.11ac-80MHz: 6 Channel Control Auto Data Rate 802.11a: 6 - 54Mbps 802.11n: up to 300Mbps 802.11ac-80MHz: up to 866.7MHz Type of Modulation OFDM, BPSK, QPSK, 16QAM, 64QAM, 256QAM DFS Function □ Master ■ Slave (Without Radar Detection) TPC Function ■ <500mW not required □ ≧ 500mW employ a TPC Communication Mode ■ IP Based Systems □ Frame Based System □ Other System Antenna type Panel Antenna, Dipole Antenna, Railway Antenna, Sector Antenna, Patch Antenna Page: 4 of 25

Report No.: 1840253R-RFUSP10V00 Antenna List No. Manufacturer Part No. Antenna Type Peak Gain 1 MOXA MAT-WDB-PA-NF-2-0708 Panel 8.77dBi For 5.15~5.25GHz 8.77dBi For 5.25~5.35GHz 8.5dBi For 5.47~5.725GHz 8.18dBi For 5.725~5.825GHz 2 MOXA MI05-A1-XX23037-X0 Panel 23dBi For 5GHz 3 MOXA MI05-A1-XX16020-X0 Panel 12 dBi For 5GHz 4 MOXA WI25-A1-0810012-RG316 Panel 10.5 dBi For 5GHz 5 MOXA ANT-WSB5-PNF-18 Panel 18 dBi For 5GHz 6 MOXA ANT-WDB-PNF-1518 Panel 18 dBi For 5GHz 7 MOXA ANT-WDB-ARM-02 Dipole 0.81 dBi For 5GHz 8 MOXA ANT-WSB5-ANF-12 Dipole 12 dBi For 5GHz 9 MOXA MAT-WDB-CA-RM-2-0205 Dipole 5dBi For 5.15~5.25GHz 5.7dBi For 5.25~5.35GHz 4.9dBi For 5.47~5.725GHz 5.2dBi For 5.725~5.825GHz 10 MOXA MAT-WDB-DA-RM-2-0203-1m Dipole 3.8dBi For 5.15~5.25GHz 2.72dBi For 5.25~5.35GHz 2.26dBi For 5.47~5.725GHz 2.34dBi For 5.725~5.825GHz 11 MOXA ANT-WDB-ANM-0306 Dipole 5.7dBi For 5.15~5.25GHz 5.7dBi For 5.25~5.35GHz 6.3dBi For 5.47~5.725GHz 6.3dBi For 5.725~5.825GHz 12 MOXA ANT-WDB-ARM-0202 Dipole 1.8 dBi For 5GHz 13 MOXA ANT-WDB-ANM-0502 Dipole 2 dBi For 5GHz 14 MOXA ANT-WDB-ANM-0407 Dipole 7 dBi For 5GHz 15 MOXA ANT-WDB-ANF-0609 Dipole 9 dBi For 5GHz 16 MOXA ANT-WDB-ANM-0609 Dipole 9 dBi For 5GHz 17 MOXA MHH-A11-XX110170-X0 Railway 8 dBi For 5GHz 18 MOXA WI25-A1-1215053-X0 Sector 15 dBi For 5GHz 19 MOXA TOP 200 AMR MF-05-4 Patch 8.5 dBi For 5GHz Note: 1. Each antenna has been evaluated and only the worst case (higher gain antenna) is presented in the report. 2. The antenna of EUT conforms to FCC 15.203. Page: 5 of 25

Report No.: 1840253R-RFUSP10V00 802.11a/n-20MHz Center Working Frequency of Each Channel: Channel Frequency Channel Frequency Channel Frequency Channel Frequency Channel 36: 5180 MHz Channel 40: 5200 MHz Channel 44: 5220 MHz Channel 48: 5240 MHz Channel 52: 5260 MHz Channel 56: 5280 MHz Channel 60: 5300 MHz Channel 64: 5320 MHz Channel 100: 5500 MHz Channel 104: 5520 MHz Channel 108: 5540 MHz Channel 112: 5560 MHz Channel 116: 5580 MHz Channel 120: 5600 MHz Channel 124: 5620 MHz Channel 128: 5640 MHz Channel 132: 5660 MHz Channel 136: 5680 MHz Channel 140: 5700 MHz Channel 149: 5745 MHz Channel 153: 5765 MHz Channel 157: 5785 MHz Channel 161: 5805 MHz Channel 165: 5825 MHz 802.11n-40MHz Center Working Frequency of Each Channel: Channel Frequency Channel Frequency Channel Frequency Channel Frequency Channel 38: 5190 MHz Channel 46: 5230 MHz Channel 54: 5270 MHz Channel 62: 5310 MHz Channel 102: 5510 MHz Channel 110: 5550 MHz Channel 118: 5590 MHz Channel 126: 5630 MHz Channel 134: 5670 MHz Channel 151: 5755 MHz Channel 159: 5795 MHz 802.11ac-20MHz Center Working Frequency of Each Channel: Channel Frequency Channel 144: 5720 MHz 802.11ac-40MHz Center Working Frequency of Each Channel: Channel Frequency Channel 142: 5710 MHz 802.11ac-80MHz Center Working Frequency of Each Channel: Channel Frequency Channel Frequency Channel Frequency Channel Frequency Channel 42: 5210 MHz Channel 58: 5290 MHz Channel 106: 5530 MHz Channel 122: 5610 MHz Channel 138: 5690 MHz Channel 155: 5775 MHz Test Mode Mode 1: Transmit Page: 6 of 25

Report No.: 1840253R-RFUSP10V00 1.2. Standard Requirement FCC Part 15.407: U-NII devices operating in the 5.25-5.35 GHz band and the 5.47-5.725 GHz band shall employ a TPC mechanism. The U-NII device is required to have the capability to operate at least 6 dB below the mean EIRP value of 30dBm. A TPC mechanism is not required for systems with an E.I.R.P. of less than 500mW. U-NII devices operating in the 5.25-5.35 GHz and 5.47-5.725 GHz bands shall employ a DFS radar detection mechanism to detect the presence of radar systems and to avoid co-channel operation with radar systems. 1.3. UNII Device Description (1) The EUT operates in the following DFS band: 1. 5250-5350 MHz 2. 5470-5725 MHz (2) The maximum EIRP of the 5GHz equipment is 49.67dBm. Below are the available 50 ohm antenna assemblies and their corresponding gains. 0dBi gain was used to set the -63 dBm threshold level (-64dBm +1 dB) during calibration of test setup. Page: 7 of 25

Report No.: 1840253R-RFUSP10V00 No. Manufacturer Part No. Antenna Type Peak Gain 1 MOXA MAT-WDB-PA-NF-2-0708 Panel 8.77dBi For 5.15~5.25GHz 8.77dBi For 5.25~5.35GHz 8.5dBi For 5.47~5.725GHz 8.18dBi For 5.725~5.825GHz 2 MOXA MI05-A1-XX23037-X0 Panel 23dBi For 5GHz 3 MOXA MI05-A1-XX16020-X0 Panel 12 dBi For 5GHz 4 MOXA WI25-A1-0810012-RG316 Panel 10.5 dBi For 5GHz 5 MOXA ANT-WSB5-PNF-18 Panel 18 dBi For 5GHz 6 MOXA ANT-WDB-PNF-1518 Panel 18 dBi For 5GHz 7 MOXA ANT-WDB-ARM-02 Dipole 0.81 dBi For 5GHz 8 MOXA ANT-WSB5-ANF-12 Dipole 12 dBi For 5GHz 9 MOXA MAT-WDB-CA-RM-2-0205 Dipole 5dBi For 5.15~5.25GHz 5.7dBi For 5.25~5.35GHz 4.9dBi For 5.47~5.725GHz 5.2dBi For 5.725~5.825GHz 10 MOXA MAT-WDB-DA-RM-2-0203-1m Dipole 3.8dBi For 5.15~5.25GHz 2.72dBi For 5.25~5.35GHz 2.26dBi For 5.47~5.725GHz 2.34dBi For 5.725~5.825GHz 11 MOXA ANT-WDB-ANM-0306 Dipole 5.7dBi For 5.15~5.25GHz 5.7dBi For 5.25~5.35GHz 6.3dBi For 5.47~5.725GHz 6.3dBi For 5.725~5.825GHz 12 MOXA ANT-WDB-ARM-0202 Dipole 1.8 dBi For 5GHz 13 MOXA ANT-WDB-ANM-0502 Dipole 2 dBi For 5GHz 14 MOXA ANT-WDB-ANM-0407 Dipole 7 dBi For 5GHz 15 MOXA ANT-WDB-ANF-0609 Dipole 9 dBi For 5GHz 16 MOXA ANT-WDB-ANM-0609 Dipole 9 dBi For 5GHz 17 MOXA MHH-A11-XX110170-X0 Railway 8 dBi For 5GHz 18 MOXA WI25-A1-1215053-X0 Sector 15 dBi For 5GHz 19 MOXA TOP 200 AMR MF-05-4 Patch 8.5 dBi For 5GHz (3) DFS operation description: WLAN traffic is generated by streaming the video file “TestFile.mp2” from the Master device to the Slave device in full motion video mode using the media player with the V2.61 Codec package. (4) The master device is an Access Point and FCC ID: SK6-XR320 Page: 8 of 25

Report No.: 1840253R-RFUSP10V00 1.4. Test Equipment Dynamic Frequency Selection (DFS) / CTR Instrument Manufacturer Type No. Serial No Cal. Date Spectrum Analyzer Agilent E4440A MY46185846 Nov, 29, 2017 Vector Signal Generator Agilent E4438C MY49070137 May, 2, 2018 Instrument Manufacturer Type No. Serial No Splitter/Combiner (Qty: 2) Mini-Circuits ZFRSC-123-S+ SN331000910 Notebook Pc Hp HSTNN-155C CNU8476RVZ CPQ511VT5870Q4X320MIBN Notebook Pc Compaq CNU0060M23 CN2Pa 8-WAY Power Divider JFW 50PD-647-SMA 517518 8-WAY Power Divider JFW 50PD-647-SMA RF Cable (Qty: 4) GORE C86 N/A ATT (Qty: 2) Mini-Circuits 15542 30912 ATT (Qty: 2) Mini-Circuits 15542 30909 RF Cable SUHNER SUCOFLEX 104 309180/4 RF Cable SUHNER SUCOFLEX 106 3474516 Splitter/Combiner (Qty: 2) Mini-Circuits ZFRSC-123-S+ SN331000910 Access Point XiRRUS XR300 X103502006E80 Notebook PC Dell M65 DYTKN1S Software Manufacturer Function Agilent Signal Studio for Agilent Radar Signal Generation Software Pulse Building V1.3.13.0 Agilent DFS_TEST Agilent Radar Signal Generation Software V1.0.0.73 Page: 9 of 25

Report No.: 1840253R-RFUSP10V00 1.5. Test Setup 1.6. DFS Requirements Prior to Use of a Channel Requirement Operational Mode Client Client Without With Master Radar Radar Detection Detection Non-Occupancy Period Not Yes Yes required DFS Detection Threshold Yes Not Yes required Channel Availability Check Time Yes Not Not required required Uniform Spreading Yes Not Not required required U-NII Detection Bandwidth Yes Not Yes required Page: 10 of 25

Report No.: 1840253R-RFUSP10V00 1.7. DFS requirements during normal operation Requirement Operational Mode Master Client Client Without Radar With Radar Detection Detection DFS Detection Threshold Yes Not required Yes Channel Closing Transmission Time Yes Yes Yes Channel Move Time Yes Yes Yes U-NII Detection Bandwidth Yes Not required Yes 1.8. DFS Detection Thresholds (1) Interference Threshold value, Master or Client incorporating In-Service Monitoring Maximum Transmit Power Value (see note)  200 milliwatt -64 dBm EIRP < 200 milliwatt and -62 dBm power spectral density < 10 dBm/MHz EIRP < 200 milliwatt that do not meet the power -64 dBm spectral density requirement Note 1: This is the level at the input of the receiver assuming a 0 dBi receive antenna. Note 2: Throughout these test procedures an additional 1 dB has been added to the amplitude of the test transmission waveforms to account for variations in measurement equipment. This will ensure that the test signal is at or above the detection threshold level to trigger a DFS response. Note3: EIRP is based on the highest antenna gain. For MIMO devices refer to KDB Publication 662911 D01. Page: 11 of 25

Report No.: 1840253R-RFUSP10V00 (2) DFS Response requirement values Parameter Value Non-Occupancy Period 30 Minutes Channel Availability Check Time 60 Seconds 10 seconds Channel Move Time See Note 1. 200 milliseconds + an aggregate of 60 Channel Closing Transmission Time milliseconds over remaining 10 second period. See Notes 1 and 2. Minimum 100% of the U-NII 99% U-NII Detection Bandwidth transmission power bandwidth. See Note 3. Note 1: Channel Move Time and the Channel Closing Transmission Time should be performed with Radar Type 0. The measurement timing begins at the end of the Radar Type 0 burst. Note 2: The Channel Closing Transmission Time is comprised of 200 milliseconds starting at the beginning of the Channel Move Time plus any additional intermittent control signals required to facilitate a Channel move (an aggregate of 60 milliseconds) during the remainder of the 10 second period. The aggregate duration of control signals will not count quiet periods in between transmissions. Note 3: During the U-NII Detection Bandwidth detection test, radar type 0 should be used. For each frequency step the minimum percentage of detection is 90 percent. Measurements are performed with no data traffic. 1.9. Radar Test Waveforms This section provides the parameters for required test waveforms, minimum percentage of successful detections, and the minimum number of trials that must be used for determining DFS conformance. Step intervals of 0.1 microsecond for Pulse Width, 1 microsecond for PRI, 1 MHz for chirp width and 1 for the number of pulses will be utilized for the random determination of specific test waveforms. Page: 12 of 25

Report No.: 1840253R-RFUSP10V00 (1) Short Pulse Radar Test Waveforms A minimum of 30 unique waveforms are required for each of the Short Pulse Radar Types 2 through 4. If more than 30 waveforms are used for Short Pulse Radar Types 2 through 4, then each additional waveform must also be unique and not repeated from the previous waveforms. If more than 30 waveforms are used for Short Pulse Radar Type 1, then each additional waveform is 905462 D02 UNII DFS Compliance Procedures v01 Page 10 generated with Test B and must also be unique and not repeated from the previous waveforms in Tests A or B. Page: 13 of 25

Report No.: 1840253R-RFUSP10V00 (2) Long Pulse Radar Test Signal Minimum Pulse Chirp Percentage Radar Pulses Per PRI Minimum Bursts Width Width of Waveform Burst (usec) Trials (usec) (MHz) Successful Detection 5 8-20 1-3 50-100 5-20 1000-2000 80% 30 The parameters for this waveform are randomly chosen. Thirty unique waveforms are required for the long pulse radar test signal. If more than 30 waveforms are used for the long pulse radar test signal, then each additional waveform must also be unique and not repeated from the previous waveforms. Each waveform is defined as follows: 1) The transmission period for the Long Pulse Radar test signal is 12 seconds. 2) There are a total of 8 to 20 Bursts in the 12 second period, with the number of Bursts being randomly chosen. This number is Burst_Count. 3) Each Burst consists of 1 to 3 pulses, with the number of pulses being randomly chosen. Each Burst within the 12 second sequence may have a different number of pulses. 4) The pulse width is between 50 and 100 microseconds, with the pulse width being randomly chosen. Each pulse within a Burst will have the same pulse width. Pulses in different Bursts may have different pulse widths. 5) Each pulse has a linear FM chirp between 5 and 20 MHz, with the chirp width being randomly chosen. Each pulse within a Burst will have the same chirp width. Pulses in different Bursts may have different chirp widths. The chirp is centered on the pulse. For example, with radar frequency of 5310 MHz and a 20 MHz chirped signal, the chirp starts at 5300 MHz and ends at 5320 MHz. 6) If more than one pulse is present in a Burst, the time between the pulses will be between 1000 and 2000 microseconds, with the time being randomly chosen. If three pulses are present in a Burst, the time between the first and second pulses is chosen independently of the time between the second and third pulses. 7) The 12 second transmission period is divided into even intervals. The number of intervals is equal to Burst_Count. Each interval is of length (12,000,000 / Burst_Count) microseconds. Each interval contains one Burst. The start time for the Burst, relative to the beginning of the interval, is between 1 and [(12,000,000 / Burst_Count) – (Total Burst Length) + (One Random PRI Interval)] microseconds, with the start time being randomly chosen. The step interval for the start time is 1 microsecond. The start time for each Burst is chosen independently. A representative example of a Long Pulse radar test waveform: 1) The total test signal length is 12 seconds. 2) 8 Bursts are randomly generated for the Burst_Count. 3) Burst 1 has 2 randomly generated pulses. 4) The pulse width (for both pulses) is randomly selected to be 75 microseconds. 5) The PRI is randomly selected to be at 1213 microseconds. 6) Bursts 2 through 8 are generated using steps 3 – 5. Page: 14 of 25

Report No.: 1840253R-RFUSP10V00 7) Each Burst is contained in even intervals of 1,500,000 microseconds. The starting location for Pulse 1, Burst 1 is randomly generated (1 to 1,500,000 minus the total Burst 1 length + 1 random PRI interval) at the 325,001 microsecond step. Bursts 2 through 8 randomly fall in successive 1,500,000 microsecond intervals (i.e. Burst 2 falls in the 1,500,001 – 3,000,000 microsecond range). Graphical Representation of a Long Pulse radar Test Waveform Page: 15 of 25

Report No.: 1840253R-RFUSP10V00 (3) Frequency Hopping Radar Test Signal Radar Pulse PRI Hopping Pulses Per Hopping Minimum Minimum Waveform Width (  sec ) Sequence Hop Rate (kHz) Percentage Trials (  sec ) Length of (msec) Successful Detection 6 1 333 300 9 0.333 70% 30 For the Frequency Hopping Radar Type, the same Burst parameters are used for each waveform. The hopping sequence is different for each waveform and a 100-length segment is selected1 from the hopping sequence defined by the following algorithm: The first frequency in a hopping sequence is selected randomly from the group of 475 integer frequencies from 5250 – 5724 MHz. Next, the frequency that was just chosen is removed from the group and a frequency is randomly selected from the remaining 474 frequencies in the group. This process continues until all 475 frequencies are chosen for the set. For selection of a random frequency, the frequencies remaining within the group are always treated as equally likely. Page: 16 of 25

Report No.: 1840253R-RFUSP10V00 1.10. Radar Waveform Calibration The following equipment setup was used to calibrate the conducted radar waveform. A spectrum analyzer was used to establish the test signal level for each radar type. During this process there were replace 50ohm terminal from master and client device and no transmissions by either the master or client device. The spectrum analyzer was switched to the zero span (time domain) at the frequency of the radar waveform generator. Peak detection was utilized. The spectrum analyzer resolution bandwidth (RBW) and video bandwidth (VBW) were set to 3MHz and 3 MHz. The signal generator amplitude was set so that the power level measured at the spectrum analyzer was -64dBm due to the interference threshold level is not required. Conducted Calibration Setup 50 Ohm Load Att. 10 dB 50 Ohm Load Splitter/ Splitter/ Combiner Combiner Agilent Hp E4407B Att. 10 dB Vector Signal Spectrum Analyzer Generator Page: 17 of 25

Report No.: 1840253R-RFUSP10V00 1.11. Radar Waveform Calibration Result Radar Type 0 Calibration Plot (5530MHz) Page: 18 of 25

Report No.: 1840253R-RFUSP10V00 1.12. Slave Data Traffic Plot Result Plot of Slave Traffic at 5530MHz Page: 19 of 25

Report No.: 1840253R-RFUSP10V00 2. In-Service Monitoring for Channel Move Time and Channel Closing Transmission Time and Non-Occupancy Period 2.1. Test Procedure These tests define how the following DFS parameters are verified during In-Service Monitoring; Channel Closing Transmission Time, Channel Move Time, and Non-Occupancy Period.. The steps below define the procedure to determine the above mentioned parameters when a radar Burst with a level equal to the DFS Detection Threshold + 1dB (-63dBm) is generated on the Operating Channel of the U-NII device. A U-NII device operating as a Master Device will associate with the UUT (Client) at 5300 MHz and 5500MHz. Stream the MPEG test file from the Client (TX) Device to the Master (RX) Device on the selected Channel for the entire period of the test. At time T0 the Radar Waveform generator sends a Burst of pulses for each of the radar types at -63dBm. Observe the transmissions of the UUT at the end of the radar Burst on the Operating Channel for duration greater than 10 seconds. Measure and record the transmissions from the UUT during the observation time (Channel Move Time). Compare the Channel Move Time and Channel Closing Transmission Time results to the limits defined in the DFS Response requirement values table. Measure the UUT for more than 30 minutes following the channel close/move time to verify that the UUT does not resume any transmissions on this Channel. 2.2. Test Requirement Parameter Value Channel Move Time 10 Seconds Channel Closing Transmission 200 milliseconds + an aggregate of 60 Time milliseconds over remaining 10 seconds period Non-Occupancy Period Minimum 30 minutes 2.3. Uncertainty ± 1ms. Page: 20 of 25

Report No.: 1840253R-RFUSP10V00 2.4. Test Result of Channel Move Time and Channel Closing Transmission Time and Non-Occupancy Period Product : MOXA IEEE 802.11a/n/ac 4*4 module Test Item : Channel Move Time Test Radar Type : Type 0 Test Mode : Mode 1: Transmit Channel Move Time for Radar Test Type 0 at 5530MHz Test Result Limit Test Item (Sec) (Sec) Channel Move Time 0 10 The results showed that after radar signal injected the channel move time was less than 10 seconds. Page: 21 of 25

Report No.: 1840253R-RFUSP10V00 Product : MOXA IEEE 802.11a/n/ac 4*4 module Test Item : Channel Closing Transmission Time Test Radar Type : Type 0 Test Mode : Mode 1: Transmit Channel Closing Transmission Time for Radar Test Type 0 at 5530 MHz Test Result Limit Test Item (ms) (ms) Channel Closing Transmission 0 200 milliseconds + approx. 60 milliseconds over remaining 10 seconds period *Note: The test result is “bin number X time per bin (600 ms / 8000)” The results showed that after radar signal injected the channel transmission closing time less than 200 milliseconds and an aggregate of no more than 60 milliseconds. Page: 22 of 25

Report No.: 1840253R-RFUSP10V00 Product : MOXA IEEE 802.11a/n/ac 4*4 module Test Item Non-Occupancy Period Radar Type : Type 0 Test Mode : Mode 1: Transmit Non-Occupancy Period at 5530 MHz Test Result Limit Test Item (Minutes) (Minutes) Non-Occupancy Period 60 >30 No EUT transmissions were observed on the test channel during 30 minutes observation time. Page: 23 of 25


Document Created: 2018-10-24 16:54:10
Document Modified: 2018-10-24 16:54:10
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