ETSI EN 300 328 V1.6.1: 2004 TEST REPORT For 54M Wireless Router Model: MR0-WR541G / MR0-WR542G, AL7954 Trade Name: TP-LINK, JensenScandinavia Prepared for TP-LINK TECHNOLOGIES CO., LTD. BUILDING 7, SECTION 2, HONGHUALING INDUSTRIAL PARK, XILI, NANSHAN DISTRICT, SHENZHEN, P. R. C. Prepared by COMPLIANCE CERTIFICATION SERVICES (SHENZHEN) INC. NO. 5, JINAO INDUSTRIAL PARK, NO. 35 JUKENG ROAD, DASHUIKENG VILLAGE, GUANLAN TOWN, BAOAN DISTRICT, SHENZHEN, CHINA TEL: 86-755-28055000 FAX: 86-755-28055221 LAB CODE:200577-0 Note: This report shall not be reproduced except in full, without the written approval of Compliance Certification Services Inc. This document may be altered or revised by Compliance Certification Services Inc. personnel only, and shall be noted in the revision section of the document. Page 1 Total Page: 26 Rev. 00
TABLE OF CONTENTS 1. TEST RESULT CERTIFICATION... 3 2. EUT DESCRIPTION... 4 3. TEST METHODOLOGY... 5 3.1 GENERAL DESCRIPTION OF APPLIED STANDARDS... 5 3.2 DESCRIPTION OF TEST MODES... 5 4. INSTRUMENT CALIBRATION... 6 4.1 MEASURING INSTRUMENT CALIBRATION... 6 4.2 MEASUREMENT EQUIPMENT USED... 6 5. FACILITIES AND ACCREDITATIONS... 7 5.1 FACILITIES... 7 5.2 EQUIPMENT... 7 5.3 LABORATORY ACCREDITATIONS AND LISTINGS... 7 6. SETUP OF EQUIPMENT UNDER TEST... 8 6.1 SETUP CONFIGURATION OF EUT... 8 6.2 SUPPORT EQUIPMENT... 8 7. ETSI EN 300 328 REQUIREMENTS... 9 7.1 EQUIVALENT ISOTROPIC RADIATED POWER... 9 7.2 MAXIMUM SPECTRAL POWER DENSITY... 12 7.3 FREQUENCY RANGE... 14 7.4 TRANSMITTER SPURIOUS EMISSIONS... 16 7.5 RECEIVER SPURIOUS EMISSIONS... 23 APPENDIX I PHOTOGRAPHS OF TEST SETUP... 26 Page 2 Rev. 00
1. TEST RESULT CERTIFICATION Applicant: Equipment Under Test: Trade Name: Model: TP-LINK TECHNOLOGIES CO., LTD. BUILDING 7, SECTION 2, HONGHUALING INDUSTRIAL PARK, XILI, NANSHAN DISTRICT, SHENZHEN, P. R. C. 54M Wireless Router TP-LINK, JensenScandinavia Date of Test: October 27-31, 2006 MR0-WR541G / MR0-WR542G, AL7954 APPLICABLE STANDARDS STANDARD TEST RESULT ETSI EN 300 328 V1.6.1: 2004 No non-compliance noted The above equipment was tested by Compliance Certification Services Inc. for compliance with the requirements set forth in ETSI EN 300 328. The results of testing in this report apply only to the product/system, which was tested. Other similar equipment will not necessarily produce the same results due to production tolerance and measurement uncertainties. Approved by: Tested By: Henry Ding Clinton Kao/ Manager COMPLIANCE CERTIFICATION SERVICES (SHENZHEN) INC. Reviewed By: Eric Wong / Assistant manager COMPLIANCE CERTIFICATION SERVICES (SHENZHEN) INC. Page 3 Rev. 00
2. EUT DESCRIPTION Product 54M Wireless Router Trade Name Model Number Model Discrepancy Power Supply Frequency Range Transmit Power (mean EIRP) Modulation Technique Number of Channels TP-LINK, JensenScandinavia MR0-WR541G / MR0-WR542G, AL7954 MR0-WR541G are fixed antenna, MR0-WR542G and AL7954 are detachable antenna. Others are the same each other. Powered by the adapter IEEE 802.11b: 2400 ~ 2483.5 MHz IEEE 802.11g: 2400 ~ 2483.5 MHz 802.11b mode: 18.53dBm 802.11g mode: 19.48 dbm IEEE 802.11b: DSSS (CCK, DQPSK, DBPSK) IEEE 802.11g: DSSS (CCK, DQPSK, DBPSK) + OFDM (QPSK, BPSK, 16-QAM, 64-QAM) IEEE 802.11b/g: 13 Channels Channels Spacing IEEE 802.11b/g: 5MHz Antenna Specification IEEE 802.11b/g: 5 dbi Antenna Designation IEEE 802.11b/g: RF Antenna Assembly Temperature Range 0 C ~ +55 C Remark: for more details, please refer to the User s manual of the EUT. Page 4 Rev. 00
3. TEST METHODOLOGY 3.1 GENERAL DESCRIPTION OF APPLIED STANDARDS According to its specifications, the EUT must comply with the requirements of the following standards: ETSI EN 300 328 Electromagnetic compatibility and Radio spectrum Matters (ERM); Wideband Transmission systems; Data transmission equipment operating in the 2.4GHz ISM band and using spread spectrum modulation techniques: Part 2: Harmonized EN covering essential requirements under article 3.2 of the R&TTE Directive. 3.2 DESCRIPTION OF TEST MODES The EUT had been tested under operating condition. Software used to control the EUT for staying in continuous transmitting and receiving mode is programmed. IEEE802.11b: Channel Low and Channel High with 11 Mbps data rate were chosen for full testing. IEEE802.11g: Channel Low and Channel High with 6Mbps data rate were chosen for full testing. The field strength of spurious emission was measured in the following position: EUT stand-up position (Z axis), lie-down position (X, Y axis). The worst emission was found in lie-down position (X axis) and the worst case was recorded. Page 5 Rev. 00
4. INSTRUMENT CALIBRATION 4.1 MEASURING INSTRUMENT CALIBRATION The measuring equipment, which was utilized in performing the tests documented herein, has been calibrated in accordance with the manufacturer's recommendations for utilizing calibration equipment, which is traceable to recognized national standards. 4.2 MEASUREMENT EQUIPMENT USED Equipment Used for Emissions Measurement Remark: Each piece of equipment is scheduled for calibration once a year. Name of Equipment PSA Spectrum Analyzer Manufacturer Model Serial Number Calibration Due Agilent E4446A US44300399 02/08/2007 EMI Test Receiver R&S ESCI 1166.5950 03 01/13/2007 Pre-Amplifier MITEQ N/A AFS42-00102650-42-10P-42 02/14/2007 Bilog Antenna SCHWAZBECK CBL6143 5082 06/09/2007 Turn Table EMCO 2081-1.21 N/A N.C.R Antenna Tower CT N/A N/A N.C.R Controller CT N/A N/A N.C.R RF Comm. Test set HP 8920B US36142090 N.C.R Site NSA C&C N/A N/A 06/09/2007 Horn Antenna TRC N/A N/A 03/04/2007 Page 6 Rev. 00
5. FACILITIES AND ACCREDITATIONS 5.1 FACILITIES All measurement facilities used to collect the measurement data are located at No. 5, Jinao industrial park, No.35 Jukeng Road, Dashuikeng Village, Guanlan Town, Baoan District, Shenzhen, China The sites are constructed in conformance with the requirements of ANSI C63.7, ANSI C63.4 and CISPR Publication 22. 5.2 EQUIPMENT Radiated emissions are measured with one or more of the following types of linearly polarized antennas: tuned dipole, biconical, log periodic, bi-log, and/or ridged waveguide, horn. Spectrum analyzers with preselectors and quasi-peak detectors are used to perform radiated measurements. Conducted emissions are measured with Line Impedance Stabilization Networks and EMI Test Receivers. Calibrated wideband preamplifiers, coaxial cables, and coaxial attenuators are also used for making measurements. All receiving equipment conforms to CISPR Publication 16-1, Radio Interference Measuring Apparatus and Measurement Methods. 5.3 LABORATORY ACCREDITATIONS AND LISTINGS The test facilities used to perform radiated and conducted emissions tests are accredited by National Voluntary Laboratory Accreditation Program for the specific scope of accreditation under Lab Code: 200577-0 to perform Electromagnetic Interference tests according to FCC PART 15 AND CISPR 22 requirements. No part of this report may be used to claim or imply product endorsement by NVLAP or any agency of the US Government. Page 7 Rev. 00
6. SETUP OF EQUIPMENT UNDER TEST 6.1 SETUP CONFIGURATION OF EUT See test photographs attached in Appendix 1 for the actual connections between EUT and support equipment. 6.2 SUPPORT EQUIPMENT No Equipment Model Serial No. FCC ID Trade Name Data Cable Power Cord 1. Notebook 992F2VG N/A DoC IBM N/A 2. AC/AC Adaptor G090080A34 N/A DoC TEN PAO N/A 3. AC/AC Adaptor 4. AC/AC Adaptor KA23A0900 80044G A41090080- C5 N/A DoC Ktec N/A N/A DoC LEADER N/A Unshielded 1.8m Unshielded 1.8m Unshielded 1.8m Unshielded 1.8m Remark: 1. All the equipment/cables were placed in the worst-case configuration to maximize the emission during the test. 2. Grounding was established in accordance with the manufacturer s requirements and conditions for the intended use. Page 8 Rev. 00
7. ETSI EN 300 328 REQUIREMENTS 7.1 EQUIVALENT ISOTROPIC RADIATED POWER LIMIT EN 300 328 Clause 4.3.1 The equivalent isotropic radiated power shall be equal to or less than -10 dbw (100 mw) e.i.r.p. This limit shall apply for any combination of power and intended antenna assembly. Test Configuration Temperature and Voltage Measurement (under normal and extreme test conditions) OSCILLOSCOPE DETECTOR Temperature Chamber SPLITTER EUT POWER METER AC/DC Power supply TEST PROCEDURE 1. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.3 for the test conditions. 2. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.7.2.2 for the measurement method. Page 9 Rev. 00
TEST RESULTS Operation Mode: IEEE 802.11b Test Date: October 29, 2006 Temperature: 25 o C Tested by: Henry Humidity: 55 % RH Polarity: Ver. / Hor. Duty Cycle measurement x: Ton / (Ton + Toff) = 0.99 10 * log (1/x) = 0.04 db Antenna Assembly Gain = 5 dbi Cable Loss = Channel 2412 2442 2472 Test Conditions Transmitter Power Temp (25) C Temp (0) C Temp (55) C 2.50 db Voltage Power 230v 207v 253v 207v 253v Reading 10.65 10.99 10.78 10.80 10.78 EIRP 18.19 18.53 18.32 18.34 18.32 Reading 9.51 9.29 9.28 9.21 9.20 EIRP 17.05 16.83 16.82 16.75 16.74 Reading 9.37 9.47 9.46 9.42 9.41 EIRP 16.91 17.01 17.00 16.96 16.95 Average = 20 dbm Measurement Uncertainty + 0.28dB / - 0.30dB Operation Mode: IEEE 802.11g Test Date: October 29, 2006 Temperature: 25 o C Tested by: Henry Humidity: 55 % RH Polarity: Ver. / Hor. Duty Cycle measurement x: Ton / (Ton + Toff) = 0.94 10 * log (1/x) = 0.27 db Antenna Assembly Gain = 5 dbi Cable Loss = 2.50 db Test Conditions Transmitter Power Temp (25) C Temp (0) C Temp (55) C Channel Voltage Power 230v 207v 253v 207v 253v 2412 Reading 11.07 11.05 11.10 11.02 11.01 EIRP 18.84 18.82 18.87 18.79 18.78 2442 Reading 11.56 11.25 11.21 10.97 10.98 EIRP 19.33 19.02 18.98 18.74 18.75 2472 Reading 11.53 11.62 11.71 11.14 11.13 EIRP 19.30 19.39 19.48 18.91 18.90 Average = 20 dbm Measurement Uncertainty + 0.28dB / - 0.30dB Remark: EIRP = A+G-AL+CL+10log(1/x) Page 10 Rev. 00
A = Reading G = Antenna Gain AL = Assembly Loss CL = Cable Loss x = Tx on / (Tx on + Tx off) (0 < X 1) Remarks: Steps for determining the ERP/EIRP 1. Substitution method: pseudo-eut is consisted by an appropriated antenna (chosen among the frequency range: Conic antenna for 25MHz to 300MHz ; Dipole antenna for 300MHz to 1000MHz and 1GHz to 18GHz) and signal generator (with a pre-defined in strength signal fed). 2. The pseudo-eut is then placed at the center of the turntable about 1.5m in height where the location EUT to be tested. 3. Receiver is placed 3m away from the pseudo-eut while measuring the strength below 1GHz. For the strength above 1GHz, the distance between the pseudo-eut and the receiver varies with the size of the EUT. 4. Receiving antenna will be risen from 1m to 4m measuring the emission of the pseudo-eut per each azithum with horizontal or vertical antenna polarization. 5. The difference between the signal generator and the receiver, by taking all the factor (antenna factor, cable lose and free space loss etc.) into account and yield the value for the product of the evaluation. 6. By substitute the product and yield the ERP or EIRP at the EUT s antenna. Page 11 Rev. 00
7.2 MAXIMUM SPECTRAL POWER DENSITY LIMIT ETSI EN 300 328 clause 4.3.2.2 For wide band modulations other than FHSS (e.g. DSSS, OFDM, etc.), the maximum spectrum power density is limited to 10 mw per MHz e.i.r.p. Test Configuration 3 5 7 Main 230Vac 2 6 4 1 Legend 1. Wooden table 2. Test cable 3. Spectrum analyzer 4. EUT 5. DC block 6. Power meter 7. Power supply TEST PROCEDURE 1. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.3 for the test conditions. 2. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.7.3 for the measurement method. TEST RESULTS No non-compliance noted Please refer to ETSI EN 300 328 clause 5.7.3 For wide band modulations other then FHSS (e.g. DSSS, OFDM, etc.), the maximum spectral power density shall be measured and recorded. Page 12 Rev. 00
TEST RESULTS Operation Mode: IEEE 802.11b Test Date: October 29, 2006 Temperature: 25 o C Tested by: Henry Humidity: 55 % RH Polarity: Ver. / Hor. Test Conditions Measured Power Density Measurement Uncertainty Reading (dbm/mhz) (A) Antenna Gain (dbi) (B) 10*log (1/x) (C) Cable Loss (D) Measured Power Density (dbm/mhz) (A+B+C+D) Low 2.13 9.67 Mid 2.23 5.00 0.04 2.50 9.77 High 1.65 10 dbm/mhz +1.5dB / -1.4dB 9.19 Operation Mode: IEEE 802.11g Test Date: October 29, 2006 Temperature: 25 o C Tested by: Henry Humidity: 55 % RH Polarity: Ver. / Hor. Test Conditions Measured Power Density Reading (dbm/mhz) (A) Antenna Gain (dbi) (B) 10*log (1/x) (C) Cable Loss (D) Measured Power Density (dbm/mhz) (A+B+C+D) Low 0.12 7.89 Mid 1.18 5.00 0.27 2.50 8.95 High 1.42 9.19 Measurement Uncertainty 10 dbm/mhz +1.5dB / -1.4dB Remarks: Steps for determining the Peak Power Density 1. Remove the EUT s antenna and the directly connected to the spectrum analyzer with appropriate cable with connector and attenuator/dc block. 2. Observation is made under the continue operation by the PEAK detector mode, by taking all the factor into account and yield the Peak Power Density. Page 13 Rev. 00
7.3 FREQUENCY RANGE LIMIT ETSI EN 300 328 clause 4.3.3.2 For all equipment the frequency shall lie within the band 2.4GHz to 2.4835GHz (f L >2.4GHz and f H <2.4835GHz) Test Configuration Temperature and Voltage Measurement (under normal and extreme test conditions) Temperature Chamber Spectrum Analyzer EUT TEST PROCEDURE AC/DC Power supply 1. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.3 for the test conditions. 2. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.7.4 for the measurement method. Page 14 Rev. 00
TEST RESULTS Operation Mode: IEEE 802.11b Test Date: October 29, 2006 Temperature: 25 o C Tested by: Henry Humidity: 55 % RH Polarity: Ver. / Hor. Test Conditions Low Frequency Frequency Range High Frequency 25 C Vnor 230.00 2402.50 2481.42 0 C Vmin 207.00 2402.52 2481.43 Vmax 253.00 2402.49 2481.45 55 C Vmin 207.00 2402.58 2481.33 Vmax 253.00 2402.59 2481.32 Measured frequencies (Lowest and Highest) 2402.49 2481.45 F L > 2400MHz F H < 2483.5MHz Measurement Uncertainty +/- 20.53 khz Operation Mode: IEEE 802.11g Test Date: October 29, 2006 Temperature: 25 o C Tested by: Henry Humidity: 55 % RH Polarity: Ver. / Hor. Test Conditions Low Frequency Frequency Range High Frequency 25 C Vnor 230.00 2401.25 2481.83 0 C Vmin 207.00 2402.17 2482.01 Vmax 253.00 2402.19 2482.02 55 C Vmin 207.00 2402.42 2481.75 Vmax 253.00 2402.44 2481.76 Measured frequencies (Lowest and Highest) 2401.25 2482.02 F L > 2400MHz F H < 2483.5MHz Measurement Uncertainty +/- 20.53 khz Page 15 Rev. 00
7.4 TRANSMITTER SPURIOUS EMISSIONS LIMIT The spurious emissions of the transmitter shall not exceed the values in tables in the indicated bands: Transmitter limits for NARROWBAND spurious emissions Frequency Range when operating when in stand-by 30 MHz to 1 GHz -36 dbm -57 dbm Above 1 GHz to 12.75 GHz -30 dbm -47 dbm 1.8 GHz to 1.9GHz 5.15 GHz to 5.3GHz -47 dbm -47 dbm The above limit values apply to narrowband emissions, e.g. as caused by local oscillator leakage. The measurement bandwidth for such emission may be as small as necessary to achieve a reliable measurement result. Wideband emissions shall not exceed the values given as below: Transmitter limits for WIDEBAND spurious emissions Frequency Range when operating when in stand-by 30 MHz to 1 GHz -86 dbm -107 dbm Above 1 GHz to 12.75 GHz -80 dbm -97 dbm 1.8 GHz to 1.9GHz 5.15 GHz to 5.3GHz -97 dbm -97 dbm Page 16 Rev. 00
MEASUREMENT EQUIPMENT USED 966 RF CHAMBER 2 Name of Equipment Manufacturer Model Serial Number Calibration Due PSA Spectrum Analyzer Agilent E4446A US44300399 02/08/2007 EMI Test Receiver R&S ESCI 1166.5950 03 01/13/2007 Pre-Amplifier MITEQ N/A AFS42-00102650-42-10P-42 02/14/2007 Bilog Antenna SCHWAZBECK CBL6143 5082 06/09/2007 Turn Table EMCO 2081-1.21 N/A N.C.R Antenna Tower CT N/A N/A N.C.R Controller CT N/A N/A N.C.R RF Comm. Test set HP 8920B US36142090 N.C.R Site NSA C&C N/A N/A 06/09/2007 Horn Antenna TRC N/A N/A 03/04/2007 Remark: Each piece of equipment is scheduled for calibration once a year. Test Configuration Below 1GHz Antenna tower EUT 3m 4m Bi-log or Loop antenna Spectrum analyzer Turntable 1.5m 1m Reference ground plane Page 17 Rev. 00
Above 1GHz Antenna tower EUT 3m 4m Horn antenna Spectrum analyzer Turntable 1.5m 1m Pre-amp TEST PROCEDURE 1. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.3 for the test conditions. 2. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.7.5 for the measurement methods. Measurement Uncertainty The measurement uncertainty of the test is ±2.65dB. Page 18 Rev. 00
TEST RESULTS Below 1GHz Test Mode: IEEE 802.11b (CH Low) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 51.600-47.37 V -59.71 0.52-4.40-64.63-36.00-28.63 79.950-47.53 V -63.64 0.64-0.50-64.78-36.00-28.78 100.200-53.32 V -64.43 0.70 0.91-64.22-36.00-28.22 219.900-44.39 V -61.24 1.07 5.59-56.72-36.00-20.72 319.833-59.73 V -73.53 1.31 6.10-68.74-36.00-32.74 398.000-65.71 V -78.32 1.46 6.55-73.23-36.00-37.23 200.100-44.14 H -60.28 0.98 0.74-60.52-36.00-24.52 219.900-46.38 H -65.18 1.07 5.59-60.66-36.00-24.66 240.150-43.75 H -60.58 1.12 5.70-56.00-36.00-20.00 276.150-40.56 H -57.21 1.20 5.62-52.79-36.00-16.79 323.333-50.36 H -66.01 1.32 6.12-61.21-36.00-25.21 367.666-62.66 H -77.01 1.37 5.98-72.40-36.00-36.40 Test Mode: IEEE 802.11b (CH High) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 79.950-42.68 V -58.79 0.64-0.50-59.93-36.00-23.93 140.250-47.93 V -61.54 0.86 0.70-61.70-36.00-25.70 200.100-46.12 V -58.91 0.98 0.74-59.15-36.00-23.15 240.150-50.57 V -66.79 1.12 5.70-62.21-36.00-26.21 319.833-59.94 V -73.74 1.31 6.10-68.95-36.00-32.95 688.500-70.36 V -76.28 1.93 6.56-71.65-36.00-35.65 79.950-56.62 H -73.63 0.64-0.50-74.77-36.00-38.77 124.950-56.03 H -75.37 0.80 0.85-75.32-36.00-39.32 200.100-50.48 H -66.62 0.98 0.74-66.86-36.00-30.86 276.150-43.14 H -59.79 1.20 5.62-55.37-36.00-19.37 323.333-53.86 H -69.51 1.32 6.12-64.71-36.00-28.71 367.666-62.57 H -76.92 1.37 5.98-72.31-36.00-36.31 Note: 1. The emission behaviour belongs to narrowband spurious emission. 2. Remark --- means that the emission is too low to be measured 3. Calculation of result is: Emission Level = Reading + Correction Factor Page 19 Rev. 00
Test Mode: IEEE 802.11g (CH Low) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 58.350-44.07 V -58.38 0.56-3.11-62.05-36.00-26.05 100.200-54.57 V -65.68 0.70 0.91-65.47-36.00-29.47 200.100-46.40 V -59.19 0.98 0.74-59.43-36.00-23.43 276.150-54.72 V -70.27 1.20 5.62-65.85-36.00-29.85 321.000-59.20 V -72.98 1.31 6.10-68.19-36.00-32.19 374.666-63.65 V -76.16 1.41 6.05-71.52-36.00-35.52 120.000-49.73 H -68.70 0.78 1.00-68.48-36.00-32.48 200.100-51.08 H -67.22 0.98 0.74-67.46-36.00-31.46 276.150-40.96 H -57.61 1.20 5.62-53.19-36.00-17.19 323.333-53.63 H -69.28 1.32 6.12-64.48-36.00-28.48 367.666-61.89 H -76.24 1.37 5.98-71.63-36.00-35.63 800.500-70.08 H -76.31 1.97 6.90-71.38-36.00-35.38 Test Mode: IEEE 802.11g (CH High) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 79.950-46.43 V -62.54 0.64-0.50-63.68-36.00-27.68 100.200-53.95 V -65.06 0.70 0.91-64.85-36.00-28.85 219.900-51.14 V -67.99 1.07 5.59-63.47-36.00-27.47 240.150-46.87 V -63.09 1.12 5.70-58.51-36.00-22.51 323.333-59.18 V -72.96 1.32 6.12-68.16-36.00-32.16 380.500-62.74 V -75.16 1.44 6.11-70.49-36.00-34.49 120.000-50.51 H -69.48 0.78 1.00-69.26-36.00-33.26 219.900-47.30 H -66.10 1.07 5.59-61.58-36.00-25.58 240.150-50.38 H -67.21 1.12 5.70-62.63-36.00-26.63 276.150-41.99 H -58.64 1.20 5.62-54.22-36.00-18.22 324.500-55.24 H -70.90 1.32 6.12-66.10-36.00-30.10 394.500-64.63 H -78.52 1.45 6.46-73.51-36.00-37.51 Remark: 1. The emission behaviour belongs to narrowband spurious emission. 2. Calculation of result is: Emission Level = S.G. - Cable loss + Ant. Gain (dbi) Page 20 Rev. 00
Above 1GHz Test Mode: IEEE 802.11b (CH Low) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 2286.666-48.20 V -50.47 3.58 9.74-44.31-30.00-14.31 2576.666-45.20 V -46.39 3.82 9.43-40.78-30.00-10.78 2850.000-48.63 V -49.08 4.02 8.98-44.12-30.00-14.12 6450.000-59.73 V -49.19 6.14 12.32-43.01-30.00-13.01 N/A 1170.000-55.94 H -60.57 2.50 11.30-51.77-30.00-21.77 2576.666-55.57 H -57.26 3.82 9.43-51.65-30.00-21.65 2810.000-56.69 H -57.04 3.99 9.05-51.98-30.00-21.98 4783.333-59.61 H -52.75 5.17 10.57-47.35-30.00-17.35 N/A Test Mode: IEEE 802.11b (CH High) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 2286.666-48.63 V -50.90 3.58 9.74-44.74-30.00-14.74 2576.666-47.23 V -48.42 3.82 9.43-42.81-30.00-12.81 2813.333-48.46 V -49.01 3.99 9.04-43.96-30.00-13.96 4950.000-57.74 V -51.00 5.18 10.12-46.06-30.00-16.06 N/A 1120.000-55.46 H -60.02 2.44 11.27-51.19-30.00-21.19 1486.666-55.59 H -60.66 2.88 11.46-52.08-30.00-22.08 2760.000-55.93 H -56.57 3.95 9.13-51.39-30.00-21.39 4941.666-60.70 H -52.91 5.18 10.15-47.94-30.00-17.94 N/A Note: 1. The emission behaviour belongs to narrowband spurious emission. 2. Measurements above show only up to 6 Chris Hsiehimum emissions noted, or would be lesser if no specific emissions from the EUT are recorded (ie: margin>20db from the applicable limit) and considered that's already beyond the background noise floor. 3. Calculation of result is: Emission Level = Reading + Correction Factor Page 21 Rev. 00
Test Mode: IEEE 802.11g (CH Low) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 2286.666-46.24 V -48.51 3.58 9.74-42.35-30.00-12.35 2576.666-41.16 V -42.35 3.82 9.43-36.74-30.00-6.74 2760.000-46.62 V -47.32 3.95 9.13-42.14-30.00-12.14 3216.666-51.25 V -50.65 4.25 9.46-45.44-30.00-15.44 N/A 1193.333-55.52 H -60.18 2.53 11.31-51.40-30.00-21.40 2576.666-52.92 H -54.61 3.82 9.43-49.00-30.00-19.00 2670.000-55.95 H -57.10 3.89 9.27-51.72-30.00-21.72 4883.333-60.36 H -52.91 5.17 10.30-47.78-30.00-17.78 N/A Test Mode: IEEE 802.11g (CH High) Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 27, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 2113.333-47.35 V -50.33 3.43 9.90-43.86-30.00-13.86 2286.666-46.78 V -49.05 3.58 9.74-42.89-30.00-12.89 2576.666-41.51 V -42.70 3.82 9.43-37.09-30.00-7.09 4941.666-55.45 V -48.76 5.18 10.15-43.79-30.00-13.79 N/A 2240.000-55.49 H -57.99 3.54 9.78-51.75-30.00-21.75 2576.666-53.52 H -55.21 3.82 9.43-49.60-30.00-19.60 2853.333-56.18 H -56.28 4.02 8.98-51.32-30.00-21.32 4850.000-60.37 H -53.12 5.17 10.39-47.90-30.00-17.90 N/A Remark: 1. The emission behaviour belongs to narrowband spurious emission. 2. Measurements above show only up to 6 maximum emissions noted, or would be lesser if no specific emissions from the EUT are recorded (ie: margin>20db from the applicable limit) and considered that's already beyond the background noise floor. 3. Calculation of result is: Emission Level = S.G. - Cable loss + Ant. Gain (dbi) Page 22 Rev. 00
7.5 RECEIVER SPURIOUS EMISSIONS LIMIT The spurious emissions of the receiver shall not exceed the values in tables in the indicated bands: Receiver limits for NARROWBAND spurious emissions Frequency Range when in stand-by 30 MHz to 1 GHz -57 dbm Above 1 GHz to 12.75 GHz -47 dbm The above limit values apply to narrowband emissions, e.g. as caused by local oscillator leakage. The measurement bandwidth for such emission may be as small as necessary to achieve a reliable measurement result. Wideband emissions shall not exceed the values given as below: Receiver limits for WIDEBAND spurious emissions Frequency Range when in stand-by 30 MHz to 1 GHz -107 dbm Above 1 GHz to 12.75 GHz -97 dbm Test Configuration Conducted Spurious Emissions: (Same as section 6.4 in this test report) Radiated Spurious Emissions: (Same as section 6.4 in this test report) TEST PROCEDURE 1. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.3 for the test conditions. 2. Please refer to ETSI EN 300 328 (V1.6.1) clause 5.7.6 for the measurement methods. Measurement Uncertainty The measurement uncertainty of the test is ± 2.65dB. Page 23 Rev. 00
TEST RESULTS Below 1GHz Test Mode: RX Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 30, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 55.200-43.15 V -56.55 0.54-3.71-60.80-57.00-3.80 92.100-51.11 V -65.90 0.68 0.43-66.15-57.00-9.15 200.100-56.18 V -68.97 0.98 0.74-69.21-57.00-12.21 276.150-47.54 V -63.09 1.20 5.62-58.67-57.00-1.67 367.666-64.80 V -77.41 1.37 5.98-72.80-57.00-15.80 650.000-70.91 V -77.72 1.87 6.60-72.99-57.00-15.99 200.100-57.27 H -73.41 0.98 0.74-73.65-57.00-16.65 224.850-56.13 H -74.69 1.08 5.75-70.02-57.00-13.02 250.050-52.72 H -69.45 1.14 5.70-64.89-57.00-7.89 276.150-47.34 H -63.99 1.20 5.62-59.57-57.00-2.57 350.166-60.93 H -76.22 1.35 6.05-71.52-57.00-14.52 367.666-61.43 H -75.78 1.37 5.98-71.17-57.00-14.17 Above 1GHz Test Mode: RX Tested by: Henry Ambient temperature: 25 o C Relative humidity: 55 % RH Date: October 30, 2006 Frequency Reading Antenna Polarization S.G. Cable loss Ant.Gain (dbi) Emission Margin 1110.000-57.15 V -63.56 2.42 11.27-54.71-47.00-7.71 1190.000-57.12 V -63.49 2.52 11.31-54.70-47.00-7.70 1540.000-57.79 V -63.74 2.93 11.35-55.32-47.00-8.32 1873.333-58.54 V -62.68 3.22 10.37-55.53-47.00-8.53 2260.000-58.34 V -60.72 3.55 9.77-54.50-47.00-7.50 2673.333-58.59 V -59.51 3.89 9.27-54.13-47.00-7.13 1166.666-57.14 H -61.76 2.49 11.30-52.95-47.00-5.95 1406.666-58.14 H -63.10 2.79 11.42-54.47-47.00-7.47 1726.666-57.81 H -61.88 3.09 10.80-54.17-47.00-7.17 2063.333-57.91 H -60.66 3.38 9.94-54.10-47.00-7.10 2246.666-58.23 H -60.72 3.54 9.78-54.48-47.00-7.48 2463.333-58.81 H -60.99 3.73 9.58-55.14-47.00-8.14 Note: 1. The emission behaviour belongs to narrowband spurious emission. 2. Remark --- means that the emission is too low to be measured 3. Calculation of result is: Emission Level = Reading + Correction Factor Page 24 Rev. 00
Above 1GHz No spurious emission were detected above the system noise floor from the transmitter. Page 25 Rev. 00
APPENDIX I PHOTOGRAPHS OF TEST SETUP Page 26 Rev. 00