Test Report DFS

FCC ID: NM8PG09410

Test Report

Download: PDF
FCCID_1501176

SPORTON International Inc. No. 52, Hwa Ya 1st Rd., Kwei-Shan Hsiang, TaoYuan Hsien, Taiwan, R.O.C. Ph: 886-3-327-3456 / FAX: 886-3-327-0973 / www.sporton.com.tw FCC Dynamic Frequency Selection Test Report Applicant’s company HTC Coporation Applicant Address No. 6-3, Baoquang Rd., Xindian City, Taipei County, Taiwan FCC ID NM8PG09410 Manufacturer’s company HTC Coporation Manufacturer Address No. 6-3, Baoquang Rd., Xindian City, Taipei County, Taiwan Product Name Tablet computer Model Name PG09410 Test Standard(s) 47 CFR FCC Part 15 Subpart E § 15.407 Test Freq. Range 5250~5350 / 5470~5725 MHz Received Date Mar. 29, 2011 Final Test Date Jun. 14, 2011 Submission Type Original Equipment Operating Mode Client (without radar detection function) Statement The test result in this report refers exclusively to the presented test model / sample. Without written approval of SPORTON International Inc., the test report shall not be reproduced except in full. The measurements and test results shown in this test report were made in accordance with the procedures and found in compliance with the limit given in FCC OET Order 06-96A (2006) and 47 CFR FCC Part 15 Subpart E § 15.407. The test equipment used to perform the test is calibrated and traceable to NML/ROC. Report Format Version: 01

Report No.: FZ132945 Table of Contents 1. CERTIFICATE OF COMPLIANCE ......................................................................................................................... 1 2. SUMMARY OF THE TEST RESULT .......................................................................................................................... 2 3. GENERAL INFORMATION .................................................................................................................................. 3 3.1. Standard Requirement .......................................................................................................................................................................3 3.2. Product Specification Table................................................................................................................................................................3 3.3. Accessories.........................................................................................................................................................................................4 3.4. Table for DFS Band Carrier Frequencies .............................................................................................................................................4 4. DFS DETECTION THRESHOLDS AND RADAR TEST WAVEFORMS ............................................................................. 5 4.1. Interference Threshold values, Master or Client incorporating In-Service Monitoring.........................................................................5 4.2. DFS Response requirement values......................................................................................................................................................5 4.3. Radar Test Waveforms Minimum Step.................................................................................................................................................5 4.4. Short Pulse Radar Test Waveforms ......................................................................................................................................................6 4.5. Long Pulse Radar Test Waveform........................................................................................................................................................7 4.6. Frequency Hopping Radar Test Waveform.......................................................................................................................................10 4.7. Conducted Calibration Setup ..........................................................................................................................................................12 4.8. Radar Waveform Calibration Procedure ..........................................................................................................................................13 4.9. Calibration Deviation........................................................................................................................................................................13 4.10. Radar Waveform Calibration Result .................................................................................................................................................14 5. TEST SETUP AND TEST RESULT............................................................................................................................ 15 5.1. Test setup ..........................................................................................................................................................................................15 5.2. In-Service Monitoring for Channel Move Time, Channel Closing Transmission Time and Non-Occupancy Period Measurement...19 6. LIST OF MEASURING EQUIPMENTS ................................................................................................................... 25 7. TEST LOCATION.............................................................................................................................................. 26 8. TAF CERTIFICATE OF ACCREDITATION ............................................................................................................. 27 APPENDIX A. TEST PHOTOS ........................................................................................................................ A1 ~ A2 Report Format Version: 01 Page No. : i of ii FCC ID: NM8PG09410 Issued Date :Jul. 01, 2011

Report No.: FZ132945 History of This Test Report REPORT NO. VERSION DESCRIPTION ISSUED DATE FZ132945 Rev. 01 Initial issue of report Jul. 01, 2011 Report Format Version: 01 Page No. : ii of ii FCC ID: NM8PG09410 Issued Date :Jul. 01, 2011

Report No.: FZ132945 Certificate No.: CB10006151 1. CERTIFICATE OF COMPLIANCE Product Name : Tablet computer Model Name : PG09410 Applicant : HTC Coporation Test Rule Part(s) : 47 CFR FCC Part 15 Subpart E § 15.407 Sporton International as requested by the applicant to evaluate the EMC performance of the product sample received on Mar. 29, 2011 would like to declare that the tested sample has been evaluated and found to be in compliance with the tested rule parts. The data recorded as well as the test configuration specified is true and accurate for showing the sample’s EMC nature. _____________________________ Jordan Hsiao SPORTON INTERNATIONAL INC. Report Format Version: 01 Page No. : 1 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 2. SUMMARY OF THE TEST RESULT Applied Standard: OET Order 06-96A (2006) Part Appendix Description of Test Result In-Service Monitoring for Channel Move Time, Channel Closing 5.2 7.8.3 Complies Transmission Time and Non-Occupancy Period Note: Since the product is client without radar detection function, only Channel Move Time, Channel Closing Transmission Time and Non-Occupancy Period are required to be performed. Report Format Version: 01 Page No. : 2 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 3. GENERAL INFORMATION 3.1. Standard Requirement FCC 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 30 dBm. A TPC mechanism is not required for systems with an e.i.r.p. of less than 500 mW. 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. 3.2. Product Specification Table Specification Items Description Modulation OFDM (BPSK / QPSK / 16QAM / 64QAM) Operating Frequency Range 5250~5350 / 5470~5725 MHz Channel Bandwidth 20 MHz operating channel bandwidth DFS Function Client (without radar detection function Max. Con. Power (DFS band) 802.11n: Band 2: 9.13 dBm ; Band 3: 9.54 dBm 802.11a: Band 2: 9.14 dBm ; Band 3: 9.59 dBm Min. Con. Power (DFS band) 802.11n: Band 2: 3.13 dBm ; Band 3: 3.54 dBm 802.11a: Band 2: 3.14 dBm ; Band 3: 3.59 dBm Max. EIRP Power (DFS band) 802.11n: Band 2: 8.13 dBm ; Band 3: 8.54 dBm 802.11a: Band 2: 8.14 dBm ; Band 3: 8.59 dBm Min. EIRP Power (DFS band) 802.11n: Band 2: 2.13 dBm ; Band 3: 2.54 dBm 802.11a: Band 2: 2.14 dBm ; Band 3: 2.59 dBm TPC Function 5260~5320 MHz ; 5500~5700 MHz Operating Mode Client (without radar detection function) Communication Mode IP based system Power-on cycle NA (No Channel Availability Check Function) Software Version HTC Sense Version 2.1 Antenna Type PIFA Antenna with gain -1.0 dBi Report Format Version: 01 Page No. : 3 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 3.3. Accessories Specification of Accessory Brand Name HTC AC Adapter Manufacturer Delta Model Name EADP-15ZB Brand Name HTC Battery Manufacturer ATL Model Name BG09100 Brand Name HTC USB Cable1 Manufacturer Foxlink Model Name DC T500 Brand Name HTC USB Cable2 Manufacturer COXOC Model Name DC T500 Brand Name AU LCD Panel Model Name B101EW05 V7 Brand Name Liteon Camera 1 Model Name 10P1BA815 Brand Name Liteon Camera 2 Model Name 10P1TF113 3.4. Table for DFS Band Carrier Frequencies For IEEE 802.11n (20MHz) bandwidth systems, use Channel 52, 56, 60, 64, 100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140. For IEEE 802.11a bandwidth systems, use Channel 52, 56, 60, 64, 100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140. Frequency Band Channel No. Frequency Channel No. Frequency 5250~5350 MHz 52 5260 MHz 60 5300 MHz Band 2 56 5280 MHz 64 5320 MHz 100 5500 MHz 124 5620 MHz 104 5520 MHz 128 5640 MHz 5470~5725 MHz 108 5540 MHz 132 5660 MHz Band 3 112 5560 MHz 136 5680 MHz 116 5580 MHz 140 5700 MHz 120 5600 MHz - - Report Format Version: 01 Page No. : 4 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4. DFS DETECTION THRESHOLDS AND RADAR TEST WAVEFORMS 4.1. Interference Threshold values, Master or Client incorporating In-Service Monitoring Maximum Transmit Power Value (see note) ≥ 200 milliwatt -64 dBm < 200 milliwatt -62 dBm 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. The radar Detection Threshold, lowest antenna gain is the parameter of Interference radar DFS detection threshold, The Interference Detection Threshold is the (-64dBm) + (0) [dBi]+ 1 dB= -63 dBm. 4.2. DFS Response requirement values Parameter Value Non-occupancy period Minimum 30 minutes Channel Availability Check Time 60 seconds Channel Move Time 10 seconds See Note 1. Channel Closing Transmission Time 200 milliseconds + an aggregate of 60 milliseconds over remaining 10 second period. See Notes 1 and 2. U-NII Detection Bandwidth Minimum 80% of the 99% power bandwidth See Note 3. Note 1: The instant that the Channel Move Time and the Channel Closing Transmission Time begins is as follows: • For the Short pulse radar Test Signals this instant is the end of the Burst. • For the Frequency Hopping radar Test Signal, this instant is the end of the last radar Burst generated. • For the Long Pulse radar Test Signal this instant is the end of the 12 second period defining the radar transmission. 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 Channel changes (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 1 is used and for each frequency step the minimum percentage of detection is 90%. Measurements are performed with no data traffic. 4.3. Radar Test Waveforms Minimum Step 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. Report Format Version: 01 Page No. : 5 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4.4. Short Pulse Radar Test Waveforms Radar Pulse Width Minimum Percentage of Minimum PRI (μsec) Number of Pulses Type (μsec) Successful Detection Trials 1 1 1428 18 60% 30 2 1-5 150-230 23-29 60% 30 3 6-10 200-500 16-18 60% 30 4 11-20 200-500 12-16 60% 30 Aggregate (Radar Types 1-4) 80% 120 A minimum of 30 unique waveforms are required for each of the short pulse radar types 2 through 4. For short pulse radar type 1, the same waveform is used a minimum of 30 times. 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. The aggregate is the average of the percentage of successful detections of short pulse radar types 1-4. FCC Radar Types (1~4) System Diagram Used R&S SMU200A (Vector SG with one ARB) or SG + ARB B11: Base-band Generator with ARB (16 M samples) and Digital Modulation B13: Base-band Main Module B106: frequency range (100 kHz to 6 GHz) For selecting the waveform parameters from within the bounds of the signal type, system were random selection using uniform distribution. Report Format Version: 01 Page No. : 6 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4.5. Long Pulse Radar Test Waveform Minimum Pulse Chirp Number Radar Number of Percentage of Minimum Width Width PRI (μsec) of Pulses Type Bursts Successful Trials (μsec) (MHz) per Burst Detection 5 50-100 5-20 1000-2000 1-3 8-20 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 a radar frequency of 5300 MHz and a 20 MHz chirped signal, the chirp starts at 5290 MHz and ends at 5310 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. Report Format Version: 01 Page No. : 7 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 (6) Bursts 2 through 8 are generated using steps 3 – 5. (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). Report Format Version: 01 Page No. : 8 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 FCC Radar Types (5) System Diagram Used R&S SMU200A (Vector SG with two ARB) Path A / Path B Two B11: Base-band Generator with ARB (16 M samples) and Digital Modulation B13: Base-band Main Module B106: frequency range (100 kHz to 6 GHz) For selecting the waveform parameters from within the bounds of the signal type, system was random selection using uniform distribution. Report Format Version: 01 Page No. : 9 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4.6. Frequency Hopping Radar Test Waveform Minimum Pulse Hopping Radar PRI Pulses Hopping Percentage of Minimum Width Sequence Length Type (μsec) per Hop Rate (kHz) Successful Trials (μsec) (msec) Detection 6 1 333 9 0.333 300 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 selected 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. Report Format Version: 01 Page No. : 10 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 FCC Radar Types (6) System Diagram Used R&S SMU200A (Vector SG with one ARB) B11: Base-band Generator with ARB (16 M samples) and Digital Modulation B13: Base-band Main Module B106: frequency range (100 kHz to 6 GHz) For selecting the waveform parameters from within the bounds of the signal type, system were random selection using uniform distribution. Report Format Version: 01 Page No. : 11 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4.7. Conducted Calibration Setup Report Format Version: 01 Page No. : 12 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4.8. Radar Waveform Calibration Procedure The Interference Radar Detection Threshold Level is (-64dBm) + (0) [dBi]+ 1 dB= -63 dBm that had been taken into account the output power range and antenna gain. The above equipment setup was used to calibrate the conducted Radar Waveform. A vector signal generator was utilized to establish the test signal level for each radar type. During this process there were replace 50ohm terminal form 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 used. The spectrum analyzer resolution bandwidth (RBW) and video bandwidth (VBW) were set to at least 3 MHz. The vector signal generator amplitude was set so that the power level measured at the spectrum analyzer was (-64dBm) + (0) [dBi]+ 1 dB= -63 dBm. Capture the spectrum analyzer plots on short pulse radar types, long pulse radar type and hopping radar waveform. 4.9. Calibration Deviation There is no deviation with the original standard. Report Format Version: 01 Page No. : 13 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 4.10. Radar Waveform Calibration Result Radar #1 DFS detection threshold level and the burst of pulses on the Channel frequency Report Format Version: 01 Page No. : 14 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5. TEST SETUP AND TEST RESULT 5.1. Test setup 5.1.1. Test Setup Diagram Following is the test setup for generate the radar waveforms and used to monitor UNII device. Report Format Version: 01 Page No. : 15 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 EUT (Slave) Data Traffic Plot (20 MHz) Master Data Traffic Plot (20MHz) Report Format Version: 01 Page No. : 16 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 Without Data Traffic Plot (Noise Plot) (20MHz) Report Format Version: 01 Page No. : 17 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5.1.2. Supporting Units Support Units Brand Model No. Serial No. FCC ID Software Version Notebook DELL PP25L NB-O E2K4965AGNM Win XP SP2 Wireless AP Metalink Mtw_RGPlus_5.0_VB_001 N/A VT6-237VB-4B 02.03.05.35 5.1.3. Test Setup Operation System testing was performed with the designated MPEG test file that streams full motion video from the Access Point to the Client in full motion video mode using the media player with the V2.61 Codec package.. This file is used by IP and Frame based systems for loading the test channel during the In-service compliance testing of the U-NII device. The waveform parameters from within the bounds of the signal type are selected randomly using uniform distribution. A spectrum analyzer is used as a monitor to verify that the EUT has vacated the Channel within the (Channel Closing Transmission Time and Channel Move Time, and does not transmit on a Channel during the Non-Occupancy Period after the detection and Channel move. It is also used to monitor EUT transmissions during the Channel Availability Check Time. Report Format Version: 01 Page No. : 18 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5.2. In-Service Monitoring for Channel Move Time, Channel Closing Transmission Time and Non-Occupancy Period Measurement 5.2.1. Limit The EUT has In-Service Monitoring function to continuously monitor the radar signals, If radar is detected, must leave the channel (Shutdown). The Channel Move Time to cease all transmissions on the current Channel upon detection of a Radar Waveform above the DFS Detection Threshold within 10 sec. The total duration of Channel Closing Transmission Time is 260ms, consisting of data signals and the aggregate of control signals, by a U-NII device during the Channel Move Time. The Non-Occupancy Period time is 30 minute during which a Channel will not be utilized after a Radar Waveform is detected on that Channel. 5.2.2. Test Procedures 1. When a radar Burst with a level equal to the DFS Detection Threshold + 1dB is generated on the Operating Channel of the U-NII device. A U-NII device operating as a Client Device will associate with the Master at Channel. Stream the MPEG test file from the Master Device to the Client 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 Detection Threshold + 1dB. 2. Observe the transmissions of the EUT at the end of the radar Burst on the Operating Channel. Measure and record the transmissions from the EUT during the observation time (Channel Move Time). One 10 second plot been reported for the Short Pulse Radar Types 1-4 and one for the Long Pulse Radar Type test in a 22 second plot. The plot for the Short Pulse Radar Types start at the end of the radar burst. The Channel Move Time will be calculated based on the plot of the Short Pulse Radar Type. The Long Pulse Radar Type plot show the device ceased transmissions within the 10 second window after detection has occurred. The plot for the Long Pulse Radar Type should start at the beginning of the 12 second waveform. 3. Measurement of the aggregate duration of the Channel Closing Transmission Time method. With the spectrum analyzer set to zero span tuned to the center frequency of the EUT operating channel at the radar simulated frequency, peak detection, and max hold, the dwell time per bin is given by: Dwell (2ms)= S (1 sec) / B (500) ; where Dwell is the dwell time per spectrum analyzer sampling bin, S is the sweep time and B is the number of spectrum analyzer sampling bins. An upper bound of the aggregate duration of the intermittent control signals of Channel Closing Transmission Time is calculated by: C (6 ms)= N (3) X Dwell (2 ms); where C is the Closing Time, N is the number of spectrum analyzer sampling bins (intermittent control signals) showing a U-NII transmission and Dwell is the dwell time per bin. 4. Measure the EUT for more than 30 minutes following the channel close/move time to verify that the EUT does not resume any transmissions on this Channel. Report Format Version: 01 Page No. : 19 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5.2.3. Test Deviation There is no deviation with the original standard. 5.2.4. Result of Channel Move Time, Channel Closing Transmission Time and Non-Occupancy Period Test Result Parameter Limit Type 1 Test Channel (MHz) 5500 MHz - Channel Move Time (ms) 504 < 10s Intermittent Control Signals (ms) (Note) 6 < 60ms Non-Occupancy Period (min.) ≧30 ≧ 30 min Note: 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 seconds period. The aggregate duration of control signals will not count quiet periods in between transmissions. Report Format Version: 01 Page No. : 20 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5.2.5. Channel Move Time Plot Radar #1 Channel Move Time Radar Slave Signal Report Format Version: 01 Page No. : 21 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5.2.6. Channel Closing Transmission Time Plot Radar #1 Channel Closing Transmission Time is comprised of 200 ms starting at the beginning of the Channel Move Time plus 60ms additional intermittent control signals RBW 3 MHz Marker 3 [T1 ] * VBW 3 MHz -47.41 dBm Ref -16.6 dBm * Att 0 dB SWT 1 s 482.000000 ms Offset -6.6 dB Marker 1 [T1 ] 1 -20 Radar -23.87 dBm A 0.000000 s -30 Marker 2 [T1 ] 1 AP -80.71 dBm TRG CLRWR 200.000000 ms LVL -40 3 -50 -60 Slave Signal -70 3DB 2 -80 -90 -100 -110 T1 Center 5.5 GHz 100 ms/ Date: 14.JUN.2011 06:28:25 Dwell is the dwell time per spectrum analyzer sampling bin. S is the sweep time B is the number of spectrum analyzer sampling bins C is the intermittent control signals of Channel Closing Transmission Time N is the number of spectrum analyzer sampling bins (intermittent control signals) showing a U-NII transmission Dwell (2 ms)= S (1 sec) / B (500) C (6 ms) = N (3) X Dwell (2 ms) Report Format Version: 01 Page No. : 22 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 5.2.7. Non-Occupancy Period Plot Non-Occupancy Period During the 30 minutes observation time, UUT did not make any transmissions on a channel after a radar signal was detected on that channel by either the Channel Availability Check or the In-Service Monitoring. Report Format Version: 01 Page No. : 23 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 Non-associated test Master was off. During the 30 minutes observation time, The UUT did not make any transmissions in the DFS band after UUT power up. Report Format Version: 01 Page No. : 24 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 6. LIST OF MEASURING EQUIPMENTS Calibration Instrument Manufacturer Model No. Serial No. Characteristics Remark Date Conducted Spectrum analyzer R&S FSP30 100023 9KHz~30GHz Mar. 15, 2011 (TH01-CB) Conducted Spectrum analyzer R&S FSV30 101026 9KHz~30GHz Jul. 23, 2010 (TH01-CB) Temp. and Humidity Conducted Ten Billion TTH-D3SP TBN-931011 -30~100 degree May 21, 2011 Chamber (TH01-CB) Thermo-Hygro Conducted N/A HC 520 #1 15~70 degree Nov. 02, 2010 Meter (TH01-CB) Conducted Signal Generator R&S SMR40 100302 10MHz-40GHz Nov. 19, 2010 (TH01-CB) Conducted RF Power Divider HP 11636A 00306 2GHz ~ 18GHz N/A (TH01-CB) Conducted RF Power Splitter Anaren 44100 1839 2GHz ~ 18GHz N/A (TH01-CB) Conducted RF Power Splitter Anaren 42100 17930 2GHz ~ 18GHz N/A (TH01-CB) Conducted Signal generator R&S SMU200A 102782 10MHz-40GHz Mar. 09, 2011 (TH01-CB) Conducted Horn Antenna COM-POWER AH-118 071187 1GHz – 18GHz Mar. 18, 2011 (TH01-CB) Radiation Horn Antenna COM-POWER AH-118 071042 1GHz – 18GHz Oct. 14, 2010 (05CH01-CB) Conducted RF Cable-high Woken High Cable-7 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted RF Cable-high Woken High Cable-8 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted RF Cable-high Woken High Cable-9 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted RF Cable-high Woken High Cable-10 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted RF Cable-high Woken High Cable-11 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted RF Cable-high Woken High Cable-12 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted RF Cable-high Woken High Cable-13 - 1 GHz – 26.5 GHz Nov. 17, 2010 (TH01-CB) Conducted Power Sensor Anritsu MA2411B 0917223 300MHz~40GHz Sep. 13, 2010 (TH01-CB) Conducted Power Meter Anritsu ML2495A 1035008 300MHz~40GHz Sep. 08, 2010 (TH01-CB) Note: Calibration Interval of instruments listed above is one year. * Calibration Interval of instruments listed above is two year. NCR means Non-Calibration required. Report Format Version: 01 Page No. : 25 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 7. TEST LOCATION SHIJR ADD : 6Fl., No. 106, Sec. 1, Shintai 5th Rd., Shijr City, Taipei, Taiwan 221, R.O.C. TEL : 886-2-2696-2468 FAX : 886-2-2696-2255 HWA YA ADD : No. 52, Hwa Ya 1st Rd., Kwei-Shan Hsiang, Tao Yuan Hsien, Taiwan, R.O.C. TEL : 886-3-327-3456 FAX : 886-3-318-0055 LINKOU ADD : No. 30-2, Dingfu Tsuen, Linkou Shiang, Taipei, Taiwan 244, R.O.C TEL : 886-2-2601-1640 FAX : 886-2-2601-1695 DUNGHU ADD : No. 3, Lane 238, Kangle St., Neihu Chiu, Taipei, Taiwan 114, R.O.C. TEL : 886-2-2631-4739 FAX : 886-2-2631-9740 JUNGHE ADD : 7Fl., No. 758, Jungjeng Rd., Junghe City, Taipei, Taiwan 235, R.O.C. TEL : 886-2-8227-2020 FAX : 886-2-8227-2626 NEIHU ADD : 4Fl., No. 339, Hsin Hu 2nd Rd., Taipei 114, Taiwan, R.O.C. TEL : 886-2-2794-8886 FAX : 886-2-2794-9777 JHUBEI ADD : No.8, Lane 724, Bo-ai St., Jhubei City, HsinChu County 302, Taiwan, R.O.C. TEL : 886-3-656-9065 FAX : 886-3-656-9085 Report Format Version: 01 Page No. : 26 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011

Report No.: FZ132945 8. TAF CERTIFICATE OF ACCREDITATION Report Format Version: 01 Page No. : 27 of 27 FCC ID: NM8PG09410 Issued Date : Jul. 01, 2011


Document Created: 2011-07-08 16:33:00
Document Modified: 2011-07-08 16:33:00
© 2024 FCC.report
This site is not affiliated with or endorsed by the FCC