EN Test Report

Transcription

1 EN Test Report Product Name : 1, AC1600 WLAN Telefon DSL Router Model No. : Archer VR600v; Archer VR400v Applicant : TP-Link Technologies Co., Ltd. Address : Building 24 (floors 1,3,4,5) and 28 (floors1-4) Central Science and Technology Park,Shennan Rd, Nanshan, Shenzhen,China Date of Receipt : Jan.12th, 2017 Test Date : Jan. 12th, 2017~ Mar. 01st, 2017 Issued Date : Mar. 17th, 2017 Report No. : R-RF-CE-P15V01 Report Version : V1.0 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 of the equipment and evaluated measurement uncertainty herein. This report must not be used to claim product endorsement by CNAS, TAF or any agency of the government. The test report shall not be reproduced without the written approval of DEKRA Testing and Certification (Suzhou) Co., Ltd.

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3 Description TABLE OF CONTENTS Page 1. General Information EUT Description a/n/ac Antenna List Channel List Test Channel The test modes of the EUT can support: Power Setting EUT Operational Condition Mode of Operation Tested System Details Configuration of Tested System EUT Exercise Software Technical Test Summary of Test Result Measurement Uncertainty Test Environment Centre Frequencies Test Equipment Test Setup Limit Test Procedure Test Result Occupied Channel Bandwidth Test Equipment Test Setup Limit Test Procedure Page: 3 of 134

4 4.5. Test Result RF Output Power and Power Density Test Equipment Test Setup Limit Test Procedure Test Result Transmitter Unwanted Emissions Outside the 5GHz RLAN Bands Test Equipment Test Setup Limit Test Procedure Test Result Transmitter Unwanted Emissions Within the 5GHz RLAN Bands Test Equipment Test Setup Limit Test Procedure Test Result Receiver Spurious Emissions Test Equipment Test Setup Limit Test Procedure Test Result Adaptivity (Channel Access Mechanism) Test Equipment Test Setup Limit Page: 4 of 134

5 9.4. Test Procedure Test Result Attachment Test Photograph EUT Photograph Page: 5 of 134

6 History of This Test Report REPORT NO. VERSION DESCRIPTION ISSUED DATE R-RF-CE-P15V01 V1.0 Initial Issued Report Mar. 17th, 2017 Page: 6 of 134

7 1. General Information 1.1. EUT Description Product Name 1, AC1600 WLAN Telefon DSL Router Model No. Archer VR600v; Archer VR400v EUT Voltage V~50/60Hz 0.6A Test Voltage AC 230V/50Hz Wi-Fi Transmit modes a n(20MHz) n(40MHz) ac(20MHz) ac(40MHz) ac(80MHz) Supporting Bands 5150MHz~5250MHz 5250MHz~5350MHz 5470MHz~5725MHz With TDWR Channels Without TDWR Channels Frequency Range a/n/ac (20MHz): MHz, n/ac (40MHz): MHz ac (80MHz): 5210MHz Channel Number a/n/ac (20MHz): n/ac (40MHz): ac (80MHz): 1 Type of Modulation a/n/ac: OFDM-BPSK, QPSK, 16QAM, 64QAM Data Rate a: 6/9/12/18/24/36/48/54 Mbps n: up to 450 Mbps ac: up to 1.3 Gbps Note: 1. The difference of models is for different marketing requirement. 2. Archer VR600v has two versions, and only minor circuitry for non-transmitter portions(rx Filter and Hybrid Filter) changed, which has nothing effect with RF circuit. Page: 7 of 134

8 a/n/ac Antenna List Antenna manufacturer N/A Antenna Delivery 1*TX+1*RX 2*TX+2*RX 3*TX+3*RX Antenna technology SISO Basic Sectorized antenna systems Cross-polarized antennas MIMO Unequal antenna gains, with equal transmit powers Spatial Multiplexing CDD Beam-forming Antenna Type External Dipole Internal PIFA PCB Ceramic Chip Antenna Metal plate type F antenna Cross-polarize Antenna Antenna Gain #1 3dBi Antenna Gain #2 3dBi Antenna Gain #3 3dBi Beam-forming Gain 2dBi Page: 8 of 134

9 1.3. Channel List a/n/ac (20MHz) Working Frequency of Each Channel: Channel Frequency Channel Frequency Channel Frequency Channel Frequency MHz MHz MHz MHz n/ac (40MHz) Working Frequency of Each Channel: Channel Frequency Channel Frequency Channel Frequency Channel Frequency MHz MHz N/A N/A N/A N/A ac (80MHz) Working Frequency of Each Channel: Channel Frequency Channel Frequency Channel Frequency Channel Frequency MHz N/A N/A N/A N/A N/A N/A Page: 9 of 134

10 1.4. Test Channel Test Clause Test channels Lower sub-band (5 150 ~ MHz) Higher sub-band (5 470 ~ MHz) 5150 ~ 5250MHz 5250 ~ 5350MHz Centre frequencies C7 (see note 1) C8 (see note 1) Occupied Channel Bandwidth C7 C8 Power, power density C1 C2 C3,C4 Transmitter unwanted emissions outside the C7 (see note 1) C8 (see note 1) 5 GHz RLAN bands Transmitter unwanted emissions within the C1 C2 C3,C4 5 GHz RLAN bands Receiver spurious emissions C7 (see note 1) C8 (see note 1) Transmit Power Control n.a. (see note 2) C2 (see note 1) C3, C4 (see note 1) (TPC) Dynamic Frequency n.a. (see note 2) C5 C6 (see note 3) Selection (DFS) Adaptivity C7 C8 C1, C3: The lowest declared channel for every declared nominal channel bandwidth within this band. For the power density testing, it is sufficient to only perform this test using the lowest nominal channel bandwidth. C2, C4: The highest declared channel for every declared nominal channel bandwidth within this band. For the power density testing, it is sufficient to only perform this test using the lowest nominal channel bandwidth. Page: 10 of 134

11 C5, C6: One channel out of the declared channels for this frequency range. If more than one nominal Channel bandwidth has been declared for this sub-band, testing shall be performed using the lowest and highest nominal channel bandwidth. C7, C8: One channel out of the declared channels for this sub-band. For Occupied Channel Bandwidth, testing shall be repeated for every declared nominal channel bandwidth within this sub-band. For Adaptivity, testing shall be performed using the highest nominal channel bandwidth. NOTE 1: In case of more than one channel plan has been declared, testing of these specific requirements need only be performed using one of the declared channel plans. NOTE 2: Testing is not required for nominal channel bandwidths that fall completely within the frequency range MHz to MHz. NOTE 3: Where the declared channel plan includes channels whose nominal channel bandwidth falls completely or partly within the MHz to MHz band, the tests for the Channel Availability Check (and where implemented, for the Off-Channel CAC) shall be performed on one of these channels in addition to a channel within the band MHz to MHz or within the band MHz to MHz NOTE 4: For power and TCP items: the lowest middle and highest frequency of channel were selected to test, then others items will be referenced by highest power with every nominal channel bandwidth The test modes of the EUT can support: Test Mode Ant 1 Ant 2 Ant 3 Ant a X X X n(20MHz) X X X n(40MHz) X X X ac(20MHz) X X X ac(40MHz) X X X ac(80MHz) X X X Page: 11 of 134

12 1.6. Power Setting Test Mode Band Test Frequency Ant 1 Ant 2 Ant 3 Ant a Band n(20MHz) Band n(40MHz) Band ac(20MHz) Band ac(40MHz) Band ac(80MHz) Band a Beam-forming Band n(20MHz) Beam-forming Band n(40MHz) Beam-forming Band ac(20MHz) Beam-forming Band ac(40MHz) Beam-forming Band ac(80MHz) Beam-forming Band Page: 12 of 134

13 1.7. EUT Operational Condition EUT Voltage V~50/60Hz 0.6A Test Voltage AC 230V/50Hz Extreme Temperature T nom (25 ) T max (40 ) T min (0 ) Page: 13 of 134

14 1.8. Mode of Operation DEKRA Testing and Certification (Suzhou) Co., Ltd. has verified the construction and function in typical operation. All the test modes were carried out with the EUT setting in continuously transmitting mode with maximum duty cycle using software, except for adaptivity test which is under streaming with different modes. See the different modes shown in this test report and defined as: Test Mode Listed Mode 1: Transmit by 802.1a Mode 2: Transmit by n (20MHz) Mode 3: Transmit by n (40MHz) Mode 4: Transmit by ac (20MHz) Mode 5: Transmit by ac (40MHz) Mode 6: Transmit by ac (80MHz) Mode 7: Transmit by a with Beam-forming Mode 8: Transmit by n (20MHz) with Beam-forming Mode 9: Transmit by n (40MHz) with Beam-forming Mode 10: Transmit by ac (20MHz) with Beam-forming Mode 11: Transmit by ac (40MHz) with Beam-forming Mode 12: Transmit by ac (80MHz) with Beam-forming Mode 13: Receive by a Mode 14: Receive by n (20MHz) Mode 15: Receive by n (40MHz) Mode 16: Receive by ac (20MHz) Mode 17: Receive by ac (40MHz) Mode 18: Receive by ac (80MHz) Mode 19: Receive by a with Beam-forming Mode 20: Receive by n (20MHz) with Beam-forming Mode 21: Receive by n (40MHz) with Beam-forming Mode 22: Receive by ac (20MHz) with Beam-forming Mode 23: Receive by ac (40MHz) with Beam-forming Mode 24: Receive by ac (80MHz) with Beam-forming Mode 25: Normal Operation by ac (80MHz) Note: 1. The extreme test condition for temperature was determined by manufacturer, see Clause The conducted items are tested by EN systems. Page: 14 of 134

15 1.9. Tested System Details The types for all equipments, plus descriptions of all cables used in the tested system (including inserted cards) are: Product Manufacturer Model No. Serial No. Power Cord 1 Notebook Asus N80V 8BN0AS Non-shielded Configuration of Tested System Connection Diagram( Radiated set-up) Page: 15 of 134

16 Connection Diagram( Conducted set-up) Connection Diagram A Lan Cable Non-shielded >10m B RF Cable Non-shielded <15cm EUT Exercise Software 1 Setup the EUT and simulators as shown on above. 2 Turn on the power of equipment. 3 Run the test software [MTool]. 4 Select the transmission mode and test channel, then start test. Page: 16 of 134

17 2. Technical Test 2.1. Test Information as required by ETSI EN V1.8.1 a) The Nominal Channel Bandwidth(s): Nominal Channel Bandwidth 1: MHz Nominal Channel Bandwidth 2: MHz Nominal Channel Bandwidth 3: MHz The associated centre frequencies: For Nominal Channel Bandwidth 1: for the band MHz to MHz: Reference clause 1.3 For Nominal Channel Bandwidth 2: for the band MHz to MHz: Reference clause 1.3 For Nominal Channel Bandwidth 3: for the band MHz to MHz: Reference clause 1.3 b) For equipment that support simultaneous transmissions in one or more channels: The (maximum) number of channels used for these simultaneous transmissions: These channels are adjacent channels: Yes No In case of non-adjacent channels, whether or not these channels are in different sub-bands: Yes No In case of simultaneous transmissions, further information defining the channels used for these simultaneous transmissions may be required. c) The different transmit operating modes (see clause ) (tick all that apply): Operating mode 1: Single Antenna Equipment a) Equipment with only 1 antenna b) Equipment with diversity antennas but only 1 antenna active at any moment in time c) Smart Antenna Systems with 2 or more antennas, but operating in a (legacy) mode where only 1 antenna is used. Operating mode 2: Smart Antenna Systems - Multiple Antennas without beamforming a) Single spatial stream/standard throughput b) High Throughput (> 1 spatial stream) using Nominal Channel Bandwidth 1 c) High Throughput (> 1 spatial stream) using Nominal Channel Bandwidth 2 Operating mode 3: Smart Antenna Systems - Multiple Antennas with beamforming a) Single spatial stream/standard throughput b) High Throughput (> 1 spatial stream) using Nominal Channel Bandwidth 1 c) High Throughput (> 1 spatial stream) using Nominal Channel Bandwidth 2 d) In case of Smart Antenna Systems or multiple antenna systems: Page: 17 of 134

18 The number of Receive chains: The number of Transmit chains: Equal power distribution among the transmit chains: Yes No In case of beamforming, the maximum (additional) beamforming gain: db NOTE: Beamforming gain does not include the basic gain of a single antenna (assembly). e) TPC feature available: Yes No f) For equipment with TPC range: The lowest and highest power level (or lowest and highest e.i.r.p. level in case of integrated antenna equipment), intended antenna assemblies and corresponding operating frequency range for the TPC range (or for each of the TPC ranges if more than one is implemented). TPC range 1: Applicable Frequency Range: MHz to MHz and MHz to MHz (Indoor) Simultaneous transmissions in both sub-bands: Yes No MHz to MHz only (Outdoor only) Indicate whether the power levels specified are Transmitter Output Power levels or e.i.r.p. levels in case of integrated antenna equipment. Power levels are specified for: TX out e.i.r.p If more than one transmit chain is present (e.g. in the case of smart antenna systems), the power levels below represent the power settings per active transmit chain (and per sub-band in case of simultaneous transmissions). Table F.1: Power levels for TPC range 1(Clause 1.6) Sub-band (MHz) Operating Mode 1 (dbm) Operating Mode 2 (dbm) Operating Mode 3 (dbm) Lowest setting to to Highest setting to to Beamforming possible: Yes No Intended Antenna Assemblies: Table F.2: Intended Antenna Assemblies for TPC range 1 Antenna Antenna Operating Sub-band Beam Assembly Gain Mode (MHz) forming e.i.r.p. for e.i.r.p. for Plow Phigh name (dbi) gain (dbm) (dbm) Page: 18 of 134

19 (db) <Antenna 1> Mode Mode Mode <Antenna 1> Mode Mode Mode <Antenna 1> Mode Mode Mode DFS Threshold level:... dbm at the antenna connector in front of the antenna g) For equipment without a TPC range: Power Setting 1: Applicable Frequency Range: MHz to MHz and MHz to MHz (Indoor) Simultaneous transmissions in both sub-bands: Yes No MHz to MHz only (Outdoor only) Indicate whether the power levels specified are Transmitter Output Power levels or e.i.r.p. levels in case of integrated antenna equipment. Power levels are specified for: TX out e.i.r.p If more than one transmit chain is present (e.g. in the case of smart antenna systems), the power levels below represent the power settings per active transmit chain (and per sub-band in case of simultaneous transmissions). Table F.5: Maximum Transmitter Output Power for Power Setting 1 Page: 19 of 134

20 Sub-band (MHz) Operating Mode 1 (dbm) Operating Mode 2 (dbm) Operating Mode 3 (dbm) to to Beamforming possible: Yes No Intended Antenna Assemblies: Table F.6: Intended Antenna Assemblies for Power Setting 1(Clause 1.6) Antenna Assembly Antenna Gain Operating Mode Sub-band (MHz) Beam forming e.i.r.p. (dbm) name (dbi) gain (db) <Antenna 1> Mode Mode Mode <Antenna 1> Mode Mode Mode <Antenna 1> Mode Mode Mode DFS Threshold level:... dbm at the antenna connector in front of the antenna h) The DFS related operating mode(s) of the equipment: Master Slave with radar detection Slave without radar detection If the equipment has more than one operating mode, tick all that apply. Page: 20 of 134

21 i) User access restrictions (please check box below to confirm): the equipment is constructed to comply with the requirements contained in clause 4.10 in ETSI EN V j) For equipment with Off-Channel CAC functionality: The equipment has an "Off-Channel CAC" function Yes No If yes, specify the "Off-Channel CAC Time" For channels outside the MHz to MHz range:... hours If applicable, for channels (partially) within the MHz to MHz range:... hours k) The equipment can operate in ad-hoc mode: no ad-hoc operation ad-hoc operation in the frequency range MHz to MHz without DFS ad-hoc operation with DFS If more than 1 is applicable, tick all that apply. l) Operating Frequency Range(s): Range 1: MHz to MHz and MHz to MHz Range 2: MHz to MHz Range 3: MHz to MHz (ad-hoc without DFS) Range 4: other, please specify: MHz to MHz (AP) m) The extreme operating temperature and supply voltage range that apply to the equipment: -20 C to +55 C (Outdoor & Indoor usage) 0 C to +35 C (Indoor usage only) Other:... 0 C to +40 C... The supply voltages of the stand-alone radio equipment or the supply voltages of the combined (host) equipment or test jig in case of plug-in devices: Details provided are for the: stand-alone equipment combined (or host) equipment test jig Supply Voltage AC mains State AC voltage: Minimum: AC 207V Nominal:. AC 230V.. Maximum:.AC 252V.. DC State DC voltage Minimum: Nominal:... Maximum:... In case of DC, indicate the type of power source: Internal Power Supply External Power Supply or AC/DC adapter Battery Nickel Cadmium Alkaline Nickel-Metal Hydride Page: 21 of 134

22 Lithium-Ion Lead acid (Vehicle regulated) Other... n) The test sequence/test software used (see also ETSI EN (V1.8.1), clause 5.1.2): o) Type of Equipment: Stand-alone Combined Equipment (Equipment where the radio part is fully integrated within another type of equipment) Plug-in radio device (Equipment intended for a variety of host systems) Other... p) Adaptivity (Channel Access Mechanism): Frame Based Equipment Load Based Equipment Option A Load Based Equipment Option B Specify which protocol has been implemented: IEEE Other:... q) The CCA time implemented by the equipment: 750 s. In case of Load Based Equipment implementing Option B (see clause ) the value q: Page: 22 of 134

23 2.2. Summary of Test Result No deviations from the test standards Deviations from the test standards as below description: Rule: ETSI EN V 1.8.1( ) Rule Chapter Worst data Test Result 4.2 Carrier Frequencies Mode: Carrier Wave Pass 4.3 Nominal Channel Bandwidth and Mode 12 Pass Occupied Channel Bandwidth 4.4 RF Output Power and Power Density Mode 11 Pass Transmitter Unwanted Emissions Outside Mode 8 Pass the 5GHz RLAN Bands Transmitter Unwanted Emissions Within Mode 5 Pass the 5GHz RLAN Bands 4.6 Receiver Spurious Emissions Mode 23 Pass 4.7 Dynamic Frequency Selection (DFS) N/A N/A 4.8 Adaptivity (Channel Access Mechanism) Mode 25 Pass 4.9 User Access Restrictions N/A N/A 4.10 Geo-location capability N/A N/A Page: 23 of 134

24 2.3. Measurement Uncertainty Where relevant, the following measurement uncertainty levels have been estimated for tests performed on the apparatus: Parameter Uncertainty Radio Frequency 1 x 10-5 RF Power Conducted 1.5dB RF Power Radiated 6dB Spurious Emissions, Conducted 3dB Spurious Emissions, Radiated 6dB Humidity 5% Temperature 1 Time 10% 2.4. Test Environment Items Required (IEC 68-1) Actual Temperature ( C) Humidity (%RH) Barometric pressure (mbar) Page: 24 of 134

25 3. Centre Frequencies 3.1. Test Equipment Centre Frequencies /TR-8 Instrument Manufacturer Type No. Serial No. Cali. Due Date Spectrum Analyzer Agilent N9010A MY DC Power Supply IDRC CD PR Programmable Temperature & Humidity Gaoyu TH-1P-B WIT Chamber Temperature/Humidity Meter Zhichen ZC1-2 TR8-TH Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards Test Setup For Conducted Measurement Page: 25 of 134

26 3.3. Limit Centre Frequencies The actual centre frequency for any given channel declared by the manufacturer shall be maintained within the range f c 20ppm Test Procedure Test Method References Rule Chapter Description ETSI EN V Centre frequencies Equipment operating without modulation 1, This test method requires that the UUT can be operated in an unmodulated test mode. 2, The UUT shall be connected to a suitable frequency measuring device (e.g. a frequency counter or a spectrum analyser) and operated in an unmodulated mode. 3,The result shall be recorded. Equipment operating with modulation 1,This method is an alternative to the above method in case the UUT cannot be operated in an un-modulated mode. 2, The UUT shall be connected to spectrum analyser. 3, Max Hold shall be selected and the centre frequency adjusted to that of the UUT. 4, The peak value of the power envelope shall be measured and noted. The span shall be reduced and the marker moved in a positive frequency increment until the upper, (relative to the centre frequency), -10 dbc point is reached. This value shall be noted as f1. 5, The marker shall then be moved in a negative frequency increment until the lower, (relative to the centre frequency), -10 dbc point is reached. This value shall be noted as f2. 6, The centre frequency is calculated as (f1 + f2) / 2. Radiated measurement 1,The test set up as described in annex B shall be used with a spectrum analyser of sufficient accuracy attached to the test antenna (see clause 5.2). 2, The test procedure is as described under clause Page: 26 of 134

27 3.5. Test Result Product : 1, AC1600 WLAN Telefon DSL Router : Centre Frequencies : TR-8 Test Mode : Mode 1: Transmit by 802.1a Test Conditions Measured Carrier Frequency F Limit Frequency (MHz) (ppm) (ppm) (MHz) Tnom (25 ) Vnom (AC 230V) Tmax (40 ) Vmax (AC 253V) Tmax (40 ) Vmin (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: The channel should be referenced by clause 1.4 Note 2: The worst data as below: Page: 27 of 134

28 Frequency(MHz) Page: 28 of 134

29 4. Occupied Channel Bandwidth 4.1. Test Equipment Occupied Channel Bandwidth/ TR-8 Instrument Manufacturer Type No. Serial No. Cal. Due Date Spectrum Analyzer Agilent N9010A MY Temperature/Humidity Meter Zhichen ZC1-2 TR8-TH Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards Test Setup For Conducted Measurement 4.3. Limit Occupied Channel Bandwidth The Nominal Channel Bandwidth shall be at least 5 MHz at all times. The Occupied Channel Bandwidth shall be between 80 % and 100 % of the declared Nominal Channel Bandwidth. In case of smart antenna systems (devices with multiple transmit chains) each of the transmit chains shall meet this requirement. NOTE: During an established communication, a device is allowed to operate temporarily in a mode where its Occupied Channel Bandwidth may be reduced to as low as 80 % of its Nominal Channel Bandwidth with a minimum of 4 MHz. Page: 29 of 134

30 4.4. Test Procedure Test Method References Rule Chapter Description ETSI EN V Occupied Channel Bandwidth Step 1 Connect the UUT to the spectrum analyser and use the following settings: 1) Centre Frequency: The centre frequency of the channel under test 2) Resolution Bandwidth: 100 khz 3) Video Bandwidth: 300 khz 4) Frequency Span: 2 Nominal Bandwidth (e.g. 40 MHz for a 20 MHz channel) 5) Sweep time: > 1 s; for larger Nominal Bandwidths, the sweep time may be increased until a value where the sweep time has no impact on the RMS value of the signal 6) Detector Mode: RMS 7) Trace Mode: Max Hold Step 2 Wait for the trace to stabilize. Step 3 1) Make sure that the power envelope is sufficiently above the noise floor of the analyser to avoid the noise signals left and right from the power envelope being taken into account by this measurement. 2) Use the 99 % bandwidth function of the spectrum analyser to measure the Occupied Channel Bandwidth of the UUT. This value shall be recorded. 3) The measurement described in step 1 to step 3 above shall be repeated in case of simultaneous transmissions in non-adjacent channels. Radiated measurement The test set up as described in annex B and the applicable measurement procedures described in annex C shall be used. The test procedure is as described under clause Page: 30 of 134

31 4.5. Test Result Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 1: Transmit by a Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 36(5180MHz) Page: 31 of 134

32 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 2: Transmit by n(20MHz) Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 36(5180MHz) Page: 32 of 134

33 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 3: Transmit by n(40MHz) Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 38(5190MHz) Page: 33 of 134

34 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 4: Transmit by ac(20MHz) Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 36(5180MHz) Page: 34 of 134

35 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 5: Transmit by ac(40MHz) Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 38(5190MHz) Page: 35 of 134

36 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 6: Transmit by ac(80MHz) Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 42(5210MHz) Page: 36 of 134

37 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 7: Transmit by a with Beam-forming Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 36(5180MHz) Page: 37 of 134

38 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 8: Transmit by n(20MHz) with Beam-forming Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 36(5180MHz) Page: 38 of 134

39 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 9: Transmit by n(40MHz) with Beam-forming Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 38(5190MHz) Page: 39 of 134

40 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 10: Transmit by ac(20MHz) with Beam-forming Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 36(5180MHz) Page: 40 of 134

41 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 11: Transmit by ac(40MHz) with Beam-forming Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 38(5190MHz) Page: 41 of 134

42 Product : 1, AC1600 WLAN Telefon DSL Router : Occupied Channel Bandwidth : TR-8 Test Mode : Mode 12: Transmit by ac(80MHz) with Beam-forming Declared Occupied Occupied Nominal Frequency Channel Limit Channel Limit Channel (MHz) Bandwidth (MHz) Bandwidth (%) Bandwidth (MHz) (%) (MHz) ~ % Note 1: The Test mode and channel should be referenced by clause 1.4. Note 2: We have evaluated all antennas, shown the worst case as below. Channel 42(5210MHz) Page: 42 of 134

43 5. RF Output Power and Power Density 5.1. Test Equipment RF Output Power, Transmit Power Control (TPC) and Power Density / TR-8 Instrument Manufacturer Type No. Serial No. Cal. Due Date Power Meter Anritsu ML2495A Power Sensor Anritsu MA2411B DC Power Supply IDRC CD PR Programmable Temperature Gaoyu & Humidity Chamber TH-1P-B WIT Temperature/Humidity Meter Zhichen ZC1-2 TR8-TH EN Test system (V ) Instrument Manufacturer Type No. Serial No. Cali. Due Date X-series USB Peak and Agilent Average Power Sensor U2021XA MY X-series USB Peak and Agilent Average Power Sensor U2021XA MY X-series USB Peak and Agilent Average Power Sensor U2021XA MY X-series USB Peak and Agilent Average Power Sensor U2021XA MY Ch.Simultaneous Sampling 14 Bits 2 MS/s Agilent U2531A TW N/A 4 Ch.Simultaneous Sampling 14 Bits 2 MS/s Agilent U2531A TW N/A Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards. Page: 43 of 134

44 5.2. Test Setup For Conducted Measurement 5.3. Limit Mean EIRP limits for RF Output Power and Power Density at the Highest Power Level Frequency Range Mean EIRP Limit [dbm] Mean EIRP Density Limit [dbm/mhz] with TPC without TPC with TPC without TPC 5150 MHz to /23 (see note 1) 10 7/10 (see note 2) MHz 5470 MHz to 5725 MHz 30 (see note 3) 27 (see note 3) 17 (see note 3) 14 (see note 3) NOTE 1: The applicable limit is 20 dbm, except for transmissions whose nominal bandwidth falls completely within the band 5150 MHz to 5250 MHz, in which case the applicable limit is 23 dbm. NOTE 2: The applicable limit is 7dBm/MHz, except for transmissions whose nominal bandwidth falls completely within the band MHz to MHz, in which case the applicable limit is 10 dbm/mhz. NOTE 3: Slave devices without a Radar Interference Detection function shall comply with the limits for the band 5250 MHz to 5350 MHz. Page: 44 of 134

45 Mean EIRP Limits for RF Output Power at the Lowest Power Level of the TPC Range Frequency Range Mean EIRP [dbm] 5250 MHz to 5350 MHz MHz to 5725 MHz 24 (see note) Note: Slave devices without a Radar Interference Detection function shall comply with the limits for the band 5250 MHz to 5350 MHz Test Procedure References Rule Chapter Description ETSI EN V RF output power, Transmit Power Control (TPC) and power density RF output power at the highest power - PH: Option 1: For equipment with continuous transmission capability or for equipment operating (or with the capability to operate) with a constant duty cycle (e.g. Frame Based equipment): Option 2: For equipment without continuous transmission capability and operating (or with the capability to operate) in only one sub-band Option 3: For equipment without continuous transmission capability and having simultaneous transmissions in both sub-bands RF output power at the lowest power level of the TPC range - PL: Option 1: For equipment with continuous transmission capability or for equipment operating (or with the capability to operate) with a constant duty cycle (e.g. Frame Based equipment): Option 2: For equipment without continuous transmission capability and operating (or with the capability to operate) in only one sub-band Option 3: For equipment without continuous transmission capability and having simultaneous transmissions in both sub-bands Power density: Option 1: For equipment with continuous transmission capability or for equipment operating (or with the capability to operate) with a constant duty cycle (e.g. Frame Based equipment): Option 2: For equipment without continuous transmission capability and operating (or with the capability to operate) in only one sub-band Option 3: For equipment without continuous transmission capability and having simultaneous transmissions in both sub-bands Page: 45 of 134

46 5.5. Test Result Product : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 Test Mode : Mode 1: Transmit by a Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 46 of 134

47 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 2: Transmit by n(20MHz) Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 47 of 134

48 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 3: Transmit by n(40MHz) Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 48 of 134

49 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 4: Transmit by ac(20MHz) Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 49 of 134

50 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 5: Transmit by ac(40MHz) Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 50 of 134

51 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 6: Transmit by ac(80MHz) Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 51 of 134

52 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 7: Transmit by a with Beam-forming Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Beam-forming Gain = 2 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 52 of 134

53 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 8: Transmit by n(20MHz) with Beam-forming Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Beam-forming Gain = 2 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 53 of 134

54 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 9: Transmit by n(40MHz) with Beam-forming Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Beam-forming Gain = 2 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 54 of 134

55 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 10: Transmit by ac(20MHz) with Beam-forming Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Beam-forming Gain = 2 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 55 of 134

56 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 11: Transmit by ac(40MHz) with Beam-forming Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Beam-forming Gain = 2 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 56 of 134

57 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : RF Output Power : TR-8 : Mode 12: Transmit by ac(80MHz) with Beam-forming Antenna #1 Gain = 3 dbi Antenna #2 Gain = 3 dbi Antenna #3 Gain = 3 dbi Beam-forming Gain = 2 dbi Test Conditions Measured Power Total Measured RF Output Frequency Limit (dbm) Power Power (MHz) (dbm) Ant 1 Ant 2 Ant 3 (dbm) (dbm) Vnom Tnom (25 ) (AC 230V) Vmax Tmax (40 ) (AC 253V) Vmin Tmax (40 ) (AC 207V) Tmin (0 ) Vmax (AC 253V) Tmin (0 ) Vmin (AC 207V) Note 1: EIRP=Measured Power + Antenna Gain Note 2: The Test mode and channel should be referenced by clause 1.4. Page: 57 of 134

58 Product : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 Test Mode : Mode 1: Transmit by a Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 36(5180MHz) Page: 58 of 134

59 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 2: Transmit by n(20MHz) Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 36(5180MHz) Page: 59 of 134

60 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 3: Transmit by n(40MHz) Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 38(5190MHz) Page: 60 of 134

61 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 4: Transmit by ac(20MHz) Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 36(5180MHz) Page: 61 of 134

62 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 5: Transmit by ac(40MHz) Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 38(5190MHz) Page: 62 of 134

63 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 6: Transmit by ac(80MHz) Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 42(5210MHz) Page: 63 of 134

64 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 7: Transmit by a with Beam-forming Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 36(5180MHz) Page: 64 of 134

65 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 8: Transmit by n(20MHz) with Beam-forming Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 36(5180MHz) Page: 65 of 134

66 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 9: Transmit by n(40MHz) with Beam-forming Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 38(5190MHz) Page: 66 of 134

67 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 10: Transmit by ac(20MHz) with Beam-forming Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 36(5180MHz) Page: 67 of 134

68 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 11: Transmit by ac(40MHz) with Beam-forming Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 38(5190MHz) Page: 68 of 134

69 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Maximum Spectral Power Density : TR-8 : Mode 12: Transmit by ac(80MHz) with Beam-forming Frequency (MHz) Total Power Density (dbm/mhz) Limit (dbm/mhz) Channel 42(5210MHz) Page: 69 of 134

70 6. Transmitter Unwanted Emissions Outside the 5GHz RLAN Bands 6.1. Test Equipment Transmitter unwanted emissions in the spurious domain / AC-6 Instrument Manufacturer Type No. Serial No. Cal. Due Date Spectrum Analyzer Agilent N9010A MY Spectrum Analyzer Agilent E4440A MY PSG Analog S.G. Agilent E8257D MY Preamplifier chengyi EMC012645SE Bilog Antenna Schaffner CBL6112B Half Wave Tuned Dipole COM-POWER Antenna AD Broad-Band Horn Schwarzbeck Antenna BBHA9120D Filter Banks QuieTek QTK-FB AC6-FB Temperature/Humidity Meter zhichen ZC1-2 AC6-TH Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards. Page: 70 of 134

71 6.2. Test Setup Transmitter unwanted emissions in the spurious domain / AC-6 (Below 1G) Transmitter unwanted emissions in the spurious domain / AC-6 (Above 1G) Page: 71 of 134

72 6.3. Limit Transmitter unwanted emission limits outside the 5 GHz RLAN bands 6.4. Test Procedure Test Method References Rule Chapter Description ETSI EN V Transmitter unwanted emissions outside the 5 GHz RLAN bands Step 1 The sensitivity of the spectrum analyser should be such that the noise floor is at least 12 db below the limits given in clause , table 3. Step 2 1,The unwanted emissions over the range 30 MHz to MHz shall be identified. 2,Spectrum analyser settings: 1)Resolution bandwidth: 100 khz 2)Video bandwidth: 300 khz 3)Detector mode: Peak 4)Trace Mode: Max Hold 5)Sweep Points: For spectrum analysers not supporting this number of sweep points, the frequency band may be segmented. For spectrum analysers capable of supporting twice this number of sweep points, the frequency adjustment in clause (step 1, last bullet) may be omitted. Page: 72 of 134

73 5) Sweep time: For non-continuous transmissions (duty cycle less than 100 %), the sweep time shall be sufficiently long, such that for each 100 khz frequency step, the measurement time is greater than two transmissions of the UUT. EXAMPLE: For non-continuous transmissions, if the UUT is using a test sequence as described in clause with a transmitter on + off time of 2 ms, then the sweep time has to be greater than 4 ms per 100 khz. 3,Allow the trace to stabilize. Any emissions identified that have a margin of less than 6 db with respect to the limits given in clause , table 3 shall be individually measured using the procedure in clause and compared to the limits given in clause , table 3. Step 3 1, The unwanted emissions over the range 1 GHz to 26 GHz shall be identified. 2, Spectrum analyser settings: 1) Resolution bandwidth: 1 MHz 2) Video bandwidth: 3 MHz 3) Detector mode: Peak 4)Trace Mode: Max Hold 5)Sweep points: For spectrum analysers not supporting this number of sweep points, the frequency band may be segmented. For spectrum analysers capable of supporting twice this number of sweep points, the frequency adjustment in clause (step 1, last bullet) may be omitted. 6)Sweep time: For non-continuous transmissions (duty cycle less than 100 %), the sweep time shall be sufficiently long, such that for each 1 MHz frequency step, the measurement time is greater than two transmissions of the UUT. EXAMPLE: For non-continuous transmissions, if the UUT is using a test sequence as described in clause with a transmitter on + off time of 2 ms, then the sweep time has to be greater than 4 ms per 1 MHz. 3, Allow the trace to stabilize. Any emissions identified that have a margin of less than 6 db with respect to the limits given in clause , table 3 shall be individually measured using the procedure in clause and compared to the limits given in clause , table 3. Step 4 1, The level of the emissions shall be measured in the time domain, using the following spectrum analyser settings: 1)Centre Frequency: Frequency of emission identified during the pre-scan 2)RBW: 100 khz (< 1 GHz) / 1 MHz (> 1 GHz) 3)VBW: 300 khz (< 1 GHz) / 3 MHz (> 1 GHz) 4)Frequency Span: 0 Hz 5)Sweep mode: Single Sweep Page: 73 of 134

74 6) Sweep Time: Suitable to capture one transmission burst. Additional measurements may be needed to identify the length of the transmission burst. In case of continuous signals, the Sweep Time shall be set to 30 ms 7) Sweep points: Sweeptime [μs] / 1 μs with a maximum of ) Trigger: Video (burst signals) or Manual (continuous signals) 9) Detector: RMS 10) Trace Mode: Clear/Write 2, Adjust the centre frequency (fine tune) to capture the highest level of one burst of the emission to be measured. This fine tuning can be omitted for spectrum analysers capable of supporting twice this number of sweep points required in step 2 and step 3 from the pre-scan procedure in clause Step 5 1, Adjust the trigger level to select the transmissions with the highest power level. 2, Set a window (start and stop lines) to match with the start and end of the burst and in which the RMS power shall be measured using the Time Domain Power function. If the spurious emission to be measured is a continuous signal, the measurement window shall be set to match the start and stop times of the sweep. 3, Select RMS power to be measured within the selected window and note the result which is the RMS power of this particular spurious emission. Compare this value with the applicable limit provided by clause , table 3. Repeat this procedure for every emission identified during the pre-scan. The values and corresponding frequencies shall be recorded. In case of conducted measurements on smart antenna systems (equipment with multiple transmit chains), the measurements shall be repeated for each of the active transmit chains. Comparison with the applicable limits shall be done using either of the options given below: 4, Option 1: the results for each of the transmit chains for the corresponding 1 MHz segments shall be added and compared with the limits provided by table 3 in clause , Option 2: the results for each of the transmit chains shall be individually compared with the limits provided by table 3 in clause after these limits have been reduced by 10 log10 (Tch) (number of active transmit chains). Page: 74 of 134

75 6.5 Test Result Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 1: Transmit by a with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 75 of 134

76 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 2: Transmit by n(20MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 76 of 134

77 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 3: Transmit by n(40MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 77 of 134

78 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 4: Transmit by ac(20MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 78 of 134

79 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 5: Transmit by ac(40MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 79 of 134

80 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 6: Transmit by ac(80MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 42 (5210MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 80 of 134

81 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 7: Transmit by a with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 81 of 134

82 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 8: Transmit by n(20MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 82 of 134

83 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 9: Transmit by n(40MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 83 of 134

84 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 10: Transmit by ac(20MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 84 of 134

85 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 11: Transmit by ac(40MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 85 of 134

86 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 12: Transmit by ac(80MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 42 (5210MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 86 of 134

87 7. Transmitter Unwanted Emissions Within the 5GHz RLAN Bands 7.1. Test Equipment Transmitter Unwanted Emissions Within the 5GHz RLAN Bands / TR-8 Instrument Manufacturer Type No. Serial No. Cali. Due Date Spectrum Analyzer Agilent E4446A MY Temperature/Humidity Meter Zhichen ZC1-2 TR8-TH Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards Test Setup For Conducted Measurement Page: 87 of 134

88 7.3. Limit Transmitter unwanted emissions within the 5 GHz RLAN bands are radio frequency emissions within the 5 GHz RLAN bands Page: 88 of 134

89 7.4. Test Procedure Test Method References Rule Chapter Description ETSI EN V Transmitter unwanted emissions within the 5 GHz RLAN bands Option 1: For equipment with continuous transmission capability The UUT shall be configured for continuous transmit mode (duty cycle equal to 100 %). If this is not possible, thenoption 2 shall be used. Step 1 1, Spectrum analyser settings:2,spectrum analyser settings: 1) Resolution bandwidth: 1 MHz 2) Video bandwidth: 30 khz 3) Detector mode: Peak 4) Trace mode: Video Average 5) Sweep Time: Coupled 6) Centre Frequency: Centre frequency of the channel being tested 7) Span: 2 Nominal Channel Bandwidth 2, Use the marker to find the highest average power level of the power envelope of the UUT. This level shall be used as the reference level for the relative measurements. Step 2 1, Adjust the frequency range of the spectrum analyser to allow the measurement to be performed within the sub-bands MHz to MHz and MHz to MHz. No other parameter of the spectrum analyser should be changed. 2, Compare the relative power envelope of the UUT with the limits defined in clause Option 2: For equipment without continuous transmission capability This method shall be used if the UUT is not capable of operating in a continuous transmit mode (duty cycle less than 100 %). In addition, this option can also be used as an alternative to option 1 for systems operating in a continuous transmit mode. Step 1 1, Spectrum analyser settings: 1) Resolution bandwidth: 1 MHz 2) Video bandwidth: 30 khz 3) Detector mode: RMS 4) Trace Mode: Max Hold 5) Sweep time: 1 minute 6) Centre Frequency: Centre frequency of the channel being tested Page: 89 of 134

90 7) Span: 2 Nominal Channel Bandwidth 2 Use the marker to find the highest average power level of the power envelope of the UUT. This level shall be used as the reference level for the relative measurements. Step 2 1, Adjust the frequency range of the spectrum analyser to allow the measurement to be performed within the sub-bands MHz to MHz and MHz to MHz. No other parameter of the spectrum analyser should be changed. 2,Compare the relative power envelope of the UUT with the limits defined in clause ) Resolution bandwidth: 1 MHz 2) Video bandwidth: 30 khz 3) Detector mode: RMS 4) Trace Mode: Max Hold 5) Sweep time: 1 minute 6) Centre Frequency: Centre frequency of the channel being tested 7) Span: 2 Nominal Channel Bandwidth 2 Use the marker to find the highest average power level of the power envelope of the UUT. This level shall be used as the reference level for the relative measurements. Radiated measurement The test set up as described in annex B shall be used with a spectrum analyser of sufficient accuracy attached to the test antenna. Page: 90 of 134

91 7.5. Test Result Product : 1, AC1600 WLAN Telefon DSL Router : Transmiter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 Test Mode : Mode 1: Transmit by a Channel 36(5180MHz) Page: 91 of 134

92 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 2: Transmit by n(20MHz) Channel 36(5180MHz) Page: 92 of 134

93 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmiter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 3: Transmit by n(40MHz) Channel 38(5190MHz) Page: 93 of 134

94 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmiter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 4: Transmit by ac(20MHz) Channel 36(5180MHz) Page: 94 of 134

95 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmiter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 5: Transmit by ac(40MHz) Channel 38(5190MHz) Page: 95 of 134

96 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 6: Transmit by ac(80MHz) Channel 42(5210MHz) Page: 96 of 134

97 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 7: Transmit by a with Beam-forming Channel 36(5180MHz) Page: 97 of 134

98 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 8: Transmit by n(20MHz) with Beam-forming Channel 36(5180MHz) Page: 98 of 134

99 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 9: Transmit by n(40MHz) with Beam-forming Channel 38(5190MHz) Page: 99 of 134

100 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 10: Transmit by ac(20MHz) with Beam-forming Channel 36(5180MHz) Page: 100 of 134

101 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 11: Transmit by ac(40MHz) with Beam-forming Channel 38(5190MHz) Page: 101 of 134

102 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter Unwanted Emissions Within the 5GHz RLAN Bands : TR-8 : Mode 12: Transmit by ac(80MHz) with Beam-forming Channel 42(5210MHz) Page: 102 of 134

103 8. Receiver Spurious Emissions 8.1. Test Equipment Receiver Spurious Emissions / AC-6 Instrument Manufacturer Type No. Serial No. Cal. Due Date Spectrum Analyzer Agilent E4440A MY PSG Analog S.G. Agilent E8257D MY Preamplifier Agilent 8449B 3008A Bilog Antenna Schaffner CBL6112B Half Wave Tuned Dipole COM-POWER Antenna AD Broad-Band Horn Schwarzbeck Antenna BBHA9120D Filter Banks QuieTek QTK-FB AC6-FB Temperature/Humidity Meter zhicheng ZC1-2 AC6-TH Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards. Page: 103 of 134

104 8.2. Test Setup Receiver Spurious Emissions / AC-6 (Below 1G) Receiver Spurious Emissions / AC-6 (Above 1G) 8.3. Limit Spurious radiated emission limits Page: 104 of 134

105 8.4. Test Procedure Test Method References Rule Chapter Description ETSI EN V Transmitter unwanted emissions outside the 5 GHz RLAN bands Step 1 The sensitivity of the spectrum analyser should be such that the noise floor is at least 12 db below the limits given in clause 4.6.2, table 4. Step 2 1,The emissions shall be measured over the range 30 MHz to MHz.2,Spectrum analyser settings: 2,Spectrum analyser settings:2)video bandwidth: 300 khz 3) Resolution bandwidth: 100 khz 4) Video bandwidth: 300 khz 5) Detector mode: Peak 6)Trace Mode: Max Hold 7) Sweep Points: For spectrum analysers not supporting this number of sweep points, the frequency band may be segmented. For spectrum analysers capable of supporting twice this number of sweep points, the frequency adjustment in clause (step 1, last bullet) may be omitted. 8) Sweep time: Auto 3, Wait for the trace to stabilize. Any emissions identified that have a margin of less than 6 db with respect to the limits given in clause 4.6.2, table 4, shall be individually measured using the procedure in clause and compared to the limits given in clause 4.6.2, table 4. Step 3 1, The emissions shall now be measured over the range 1 GHz to 26 GHz. 2, Spectrum analyser settings: 1) Resolution bandwidth: 1 MHz 2) Video bandwidth: 3 MHz 3) Detector mode: Peak 4) Trace mode: Max Hold 5) Sweep Points: For spectrum analysers not supporting this high number of sweep points, the frequency band may need to be segmented. For spectrum analysers capable of supporting twice this number of sweep points, the frequency adjustment in Page: 105 of 134

106 clause (step 1, last bullet) may be omitted. 6)Sweep time: Auto 3,Wait for the trace to stabilize. Any emissions identified that have a margin of less than 6 db with respect to the limits given in clause 4.6.2, table 4, shall be individually measured using the procedure in clause and compared to the limits given in clause 4.6.2, table 4. Step 4 1, The level of the emissions shall be measured using the following spectrum analyser settings: 1) Measurement Mode: Time Domain Power 2) Centre Frequency: Frequency of the emission identified during the pre-scan 3) Resolution Bandwidth: 100 khz (emissions < 1 GHz) / 1 MHz (emissions > 1 GHz) 4) Video Bandwidth: 300 khz (emissions < 1 GHz) / 3 MHz (emissions > 1 GHz) 5) Frequency Span: Zero Span 6) Sweep mode: Single Sweep 7) Sweep time: 30 ms 8) Sweep points: ) Trigger: Video (for burst signals) or Manual (for continuous signals) 10) Detector: RMS 2, Adjust the centre frequency (fine tune) to capture the highest level of one burst of the emission to be measured. This fine tuning can be omitted for spectrum analysers capable of supporting twice this number of sweep points required in step 2 and step 3 from the pre-scan procedure in clause Step 5 1, Set a window where the start and stop indicators match the start and end of the burst with the highest level and record the value of the power measured within this window. 2, If the spurious emission to be measured is a continuous transmission, the measurement window shall be set to the start and stop times of the sweep. Step 6 1, Set a window where the start and stop indicators match the start and end of the burst with the highest level and record the value of the power measured within this window. 2, Sum the measured power (within the observed window) for each of the active receive chains. Step 7 1, The value defined in step 3 shall be compared to the limits defined in clause 4.6.2, table 4. Radiated measurement The test set up as described in annex B shall be used with a spectrum analyser attached to the test antenna (see clause 5.2). Page: 106 of 134

107 8.5. Test Result Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 13: Receive by a with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 107 of 134

108 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 14: Receive by n(20MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 108 of 134

109 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 15: Receive by n(40MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 109 of 134

110 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 16: Receive by ac(20MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 110 of 134

111 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 17: Receive by ac(40MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 111 of 134

112 Product : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 Test Mode : Mode 18: Receive by ac(80MHz) with Ant Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 42 (5210MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 112 of 134

113 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 19: Transmit by a with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 113 of 134

114 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 20: Receive by n(20MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 114 of 134

115 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 21: Receive by n(40MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 115 of 134

116 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 22: Receive by ac(20MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 36 (5180MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 116 of 134

117 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 23: Receive by ac(40MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 38 (5190MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 117 of 134

118 Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Transmitter spurious emissions : AC-6 : Mode 24: Receive by ac(80MHz) with Ant with Beam-forming Frequency Polarization Measure Level Limit Over Limit (MHz) (H/V) (dbm) (dbm) (db) Detector Channel 42 (5210MHz) H PK V PK H PK V PK H PK V PK H PK V PK Note 1:The final result only applies for using RMS detector, if the pre-test result on peak is 6dB lower than limit, then RMS measurement needn t be performed. Page: 118 of 134

119 9. Adaptivity (Channel Access Mechanism) 9.1. Test Equipment Adaptivity / TR-8 Instrument Manufacturer Type No. Serial No Cal. Due Date Spectrum Analyzer Agilent N9010A MY dB Coaxial Coupler Agilent 87300C MY N/A Splitter/Combiner (Qty: 2) Mini-Circuits ZAPD-50W NN GHz N/A Splitter/Combiner (Qty: 2) MCLI PS /4464 N/A PSG Analog Signal Generator Agilent E8257D MY ESG Vector Signal Generator Agilent E4438C MY Temperature/Humidity Meter Zhichen ZC1-2 TR8-TH Note: All equipments are calibrated with traceable calibrations. Each calibration is traceable to the national or international standards Test Setup For Conducted Measurement Page: 119 of 134

120 9.3. Limit Adaptivity Limit Frame Based Equipment 1)Minimum Clear Channel Assessment (CCA) time = 20 us; 2)CCA observation time used by the equipment declared by the manufacturer; 3)COT = 1 ms to 10 ms; 4)Idle Period 5% of COT; 5)Detection threshold level = -73dBm/MHz + (23 Ph)/(1MHz); LBT based Detect and Avoid (Load Based Equipment with spectrum sharing mechanism IEEE Std.): 1)LBT Based spectrum sharing mechanism may implement IEEE Std clauses 9 and 17, in IEEE Std n-2009 clauses 9, 11 and 20. LBT based Detect and Avoid (Load Based Equipment) -Option A 1)Minimum Clear Channel Assessment (CCA) time = 20 us; 2)CCA observation time used by the equipment declared by the manufacturer; 3)COT (13 / 32) * q ms; q = [4~32]; 1.625ms~13ms; 4)N = number of clear idle slots are randomly [1~q]. Every time an Extended CCA is required and 5)the N value stored in a counter. Extended CCA = N * CCA; 6)Detection threshold level = -73dBm/MHz + (23 Ph)/ (1MHz); LBT based Detect and Avoid (Load Based Equipment) -Option B 1)Minimum Clear Channel Assessment (CCA) time = 20 us; 2)CCA observation time used by the equipment declared by the manufacturer; 3)Extended CCA time = The initial value of q is 16 and shall be doubled for every new Extended CCA check until q has reached Once q has reached a value of 1 024, the value of q may be reset to the initial value of 16. 4)COT 10ms; 5)N = number of clear idle slots are randomly [1~q]. Every time an Extended CCA is required and the N value stored in a counter. Extended CCA = N * CCA; 6)Detection threshold level = -73dBm/MHz + (23 Ph)/ (1MHz); Short Control Signalling Transmissions: Short Control Signalling Transmissions shall have a maximum duty cycle of 5% within an observation period of 50ms. Page: 120 of 134

121 9.4. Test Procedure Test Method References Rule Chapter Description ETSI EN V Adaptivity The different steps below define the procedure to verify the efficiency of the adaptivity mechanism of the equipment. Step 1 1,The UUT shall connect to a companion device during the test. The signal generator, spectrum analyser, UUT and the companion device are connected using a Set-up equivalent to the example given by figure 13 although the signal generator does not generate any signals at this point in time. The spectrum analyser is used to monitor the transmissions of the UUT in response to the interference signal. 2,The received signal level (wanted signal from the companion device) at the UUT shall be sufficient to maintain a reliable link for the duration of the test. A typical value for the received signal level which can be used in most cases is -50 dbm/mhz. 3,The analyser shall be set as follows: 1) RBW: Occupied Channel Bandwidth (if the analyser does not support this setting, the highest available setting shall be used) 2) VBW: 3 RBW (if the analyser does not support this setting, the highest available setting shall be used) 4)Detector Mode: RMS 5) Centre Frequency: Equal to the centre frequency of the operating channel 6) Span: 0 Hz 7) Sweep time: > Channel Occupancy Time 8) Trace Mode: Clear/Write 9) Trigger Mode: Video or External Step 2 1, Configure the UUT for normal transmissions with a payload resulting in a minimum transmitter activity ratio of 30 %. Where this is not possible, the UUT shall be configured to the maximum payload possible. 2, Using the procedure defined in clause , it shall be verified that the UUT complies with the maximum Channel Occupancy Time and the (minimum) Idle Period defined in clause for Frame Based Equipment and defined in clause for Load Based Equipment. NOTE 1: For IEEE [8] and IEEE ac [9] equipment (see first paragraph of clause ), the limits to be applied for the (minimum) Idle Period and the maximum Channel Occupancy Time are as defined for other types of Load Based Equipment (see clause , Option A point 2) and point 3) or Option B point 2) and point 3). Page: 121 of 134

122 Step 3: Adding the interference signal An interference signal as defined in clause B.7 is injected on the current operating channel of the UUT. The power spectral density level (at the input of the UUT) of this interference signal shall be equal to the applicable CCA threshold level (TL) defined in clause or clause Step 4: Verification of reaction to the interference signal 1, The spectrum analyser shall be used to monitor the transmissions of the UUT on the selected operating channel after the interference signal was injected. This may require the spectrum analyser sweep to be triggered by the start of the interfering signal. 2 Using the procedure defined in clause , it shall be verified that: i) The UUT stops transmissions on the current operating channel. NOTE 2: The UUT is assumed to stop transmissions within a period equal to the Maximum Channel Occupancy Time defined in clause for Frame Based Equipment or clause for Load Based Equipment. The UUT is allowed to have Short Control Signalling Transmissions on the current operating channel, see ii) and iii). NOTE 3: For equipment having simultaneous transmissions on multiple (adjacent or non-adjacent) operating channels, the equipment is allowed to continue transmissions on other Operating Channels. ii) Apart from Short Control Signalling Transmissions there shall be no subsequent transmissions while the interfering signal is present. iii) The Short Control Signalling Transmissions shall comply with the limits defined in clause The verification of the Short Control Signalling transmissions may require the analyser settings to be changed (e.g. sweep time). 3,To verify that the UUT is not resuming normal transmissions as long as the interference signal is present, the monitoring time may need to be 60 s or more, in which case a segmented measurement may need to be performed in order to achieve the required resolution. 4, Once the test is completed and the interference signal is removed, the UUT may start transmissions again on this channel however this is not a requirement and therefore does not require testing. Step 5 Step 2 to step 4 shall be repeated for each of the channels to be tested. Generic test procedure for measuring channel/frequency usage This is a generic test method to evaluate transmissions on the operating channel being investigated. This test is only performed as part of the procedure described in clause Step 1: 1, The analyser shall be set as follows: 1)Centre Frequency: equal to the centre frequency of the channel being investigated 2)Frequency Span: 0 Hz Page: 122 of 134

123 3)RBW: approximately 50 % of the Occupied Channel Bandwidth (if the analyser does not support this setting, the highest available setting shall be used) 4) VBW: RBW (if the analyser does not support this setting, the highest available setting shall be used) 5)Detector Mode: RMS 6) Sweep time: > the Channel Occupancy Time 7) Sweep points: at least one sweep point per μs 8) Trace mode: Clear/Write 9) Trigger: Video or External Step 2: Save the trace data to a file for further analysis by a computing device using an appropriate software application or program. Step 3: 1, Identify the data points related to the channel being investigated by applying a threshold. 2, Count the number of consecutive data points identified as resulting from a single transmission on the channel being investigated and multiply this number by the time difference between two consecutive data points. Repeat this for all the transmissions within the measurement window. 3 For measuring idle or silent periods, count the number of consecutive data points identified as resulting from a single transmitter off period on the channel being investigated and multiply this number by the time difference between two consecutive data points. Repeat this for all the transmitter off periods within the measurement window. Radiated measurements For a UUT with integral antenna(s) and without temporary antenna connector(s), radiated measurements shall be used. The output power of the signal generator simulating the interference signal shall provide a signal power at the antenna of the UUT with a level equal to CCA Threshold Level (TL) defined in clause or clause When performing radiated testing on a UUT with a directional antenna (including smart antenna systems and systems capable of beamforming), the wanted communications link (between the UUT and the companion device) and the interference test signals shall be aligned to the direction corresponding to the UUT's maximum antenna gain. The test set up as described in annex B and applicable measurement procedures as described in annex C shall be used totest the adaptivity of the UUT. The test procedure is further as described under clause Page: 123 of 134

124 9.5. Test Result Product Test Mode : 1, AC1600 WLAN Telefon DSL Router : Adaptivity : TR-8 : Mode 25: Normal Operation by ac(80MHz) Frequency (MHz) COT (ms) Idle Period (ms) Limit (ms) Short Control Signalling Transmissions Time Limit (ms) Result 5210MHz Pass Channel Occupancy & Idle Period: Page: 124 of 134

125 Interference Signal Calibration Page: 125 of 134

126 Verification of reaction to the interference signal Page: 126 of 134

127 10. Attachment Test Photograph Description: Transmitter/Receiver Spurious Emissions Test Setup for Below 1GHz Description: Transmitter/Receiver Spurious Emissions Test Setup for 1~18GHz Page: 127 of 134

128 Description: Transmitter/Receiver Spurious Emissions Test Setup for above 18GHz Description: Conducted Normal Environment Setup Photograph Page: 128 of 134

129 Description: Conducted Extreme Environment Setup Photograph Description: Adaptivity Setup Photograph Page: 129 of 134

130 10.2. EUT Photograph (1) EUT Photo (2) EUT Photo Page: 130 of 134

131 (3) EUT Photo (4) EUT Photo Page: 131 of 134

132 (5) EUT Photo (6) EUT Photo Page: 132 of 134

133 (7) EUT Photo (8) EUT Photo Page: 133 of 134