SAR REPORT

FCC ID: RC6AWU-902T

RF Exposure Info

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FCCID_752132

Report No:071L039-HPUSP09V01 SAR Test Report Product Name : IEEE 802.11g Wireless Pocket USB Model No. : AWU-902T, NV-902T, WA-2110, HWGUSB2-54, Thrustmaster FunAccess WiFi USB Key, TER/GUSB2 Applicant : Amigo Technology Inc. Address : 1F, No. 258, Sec 2, Ti-Ding Blvd., Nei Hu, Taipei, Taiwan 114, R.O.C. Date of Receipt : 2007/01/05 Issued Date : 2007/01/12 Report No. : 071L039-HPUSP09V01 The test results relate only to the samples tested. The test report shall not be reproduced except in full without the written approval of QuieTek Corporation. Page: 1 of 22 Version:1.0

Report No:071L039-HPUSP09V01 Test Report Certification Issued Date: 2007/01/12 Report No.:071L039-HPUSP09V01 Product Name : IEEE 802.11g Wireless Pocket USB Applicant : Amigo Technology Inc. Address : 1F, No. 258, Sec 2, Ti-Ding Blvd., Nei Hu, Taipei, Taiwan 114, R.O.C. Manufacturer : FAIRWAY ELECTRONICS Co., LTD. Model No. : AWU-902T, NV-902T, WA-2110, HWGUSB2-54, Thrustmaster FunAccess WiFi USB Key, TER/GUSB2 Trade Name : Amigo, Novatech, Sapido, Hercules, Amigo Communication, INC., Thrustmaster, Natopia, Guillemot Applicable Standard : FCC Oet65 Supplement C June 2001 Test Result : Max. SAR Measurement (1g) 802.11b: 0.731 W/kg 802.11g: 0.398 W/kg Application Type Certification The test results relate only to the samples tested. The test report shall not be reproduced except in full without the written approval of QuieTek Corporation. Documented By : (Eva Huang) Tested By : (Shine Hsu) Approved By : (George Chen) Page: 2 of 22 Version:1.0

Report No:071L039-HPUSP09V01 TA B L E O F C O N T E N T S Description Page 1. General Information.............................................................................. 5 1.1 EUT Description ............................................................................................................5 1.2 Test Environment ...........................................................................................................5 2. SAR Measurement System .................................................................. 6 2.1 ALSAS-10U System Description ..................................................................................6 2.1.1 Applications ................................................................................................................6 2.1.2 Area Scans...................................................................................................................6 2.1.3 Zoom Scan (Cube Scan Averaging)............................................................................7 2.1.4 ALSAS-10U Interpolation and Extrapolation Uncertainty.........................................7 2.2 Isotropic E-Field Probe ..................................................................................................7 2.2.1 Isotropic E-Field Probe Specification .........................................................................9 2.3 Boundary Detection Unit and Probe Mounting Device .................................................9 2.4 Daq-Paq (Analog to Digital Electronics) .....................................................................10 2.5 Axis Articulated Robot ................................................................................................10 2.6 ALSAS Universal Workstation.................................................................................... 11 2.7 Universal Device Positioner......................................................................................... 11 2.8 Phantom Types............................................................................................................. 11 2.8.1 APREL SAM Phantoms ...........................................................................................12 2.8.2 APREL Laboratories Universal Phantom .................................................................12 3. Tissue Simulating Liquid ................................................................... 13 3.1 The composition of the tissue simulating liquid ..........................................................13 3.2 Tissue Calibration Result .............................................................................................13 3.3 Tissue Dielectric Parameters for Head and Body Phantoms .......................................14 4. SAR Measurement Procedure ........................................................... 15 4.1 SAR System Validation................................................................................................15 4.1.1 Validation Dipoles.....................................................................................................15 4.1.2 Validation Result .......................................................................................................15 4.2 SAR Measurement Procedure......................................................................................16 5. SAR Exposure Limits ......................................................................... 17 6. Test Equipment List............................................................................ 18 7. Measurement Uncertainty.................................................................. 19 8. Test Results ......................................................................................... 20 Page: 3 of 22 Version:1.0

Report No:071L039-HPUSP09V01 8.1 SAR Test Results Summary .........................................................................................20 Appendix A. SAR System Validation Data........................................................................22 Appendix B. SAR measurement Data................................................................................22 Appendix C. Test Setup Photographs & EUT Photographs...............................................22 Appendix D. Probe Calibration Data .................................................................................22 Appendix E. Dipole Calibration Data ................................................................................22 Page: 4 of 22 Version:1.0

Report No:071L039-HPUSP09V01 1. General Information 1.1 EUT Description Product Name IEEE 802.11g Wireless Pocket USB Trade Name Amigo, Novatech, Sapido, Hercules, Amigo Communication, INC., Thrustmaster, Natopia, Guillemot Model No. AWU-902T, NV-902T, WA-2110, HWGUSB2-54, Thrustmaster FunAccess WiFi USB Key, TER/GUSB2 FCC ID RC6AWU-902T TX Frequency 2412MHz ~ 2462MHz Number of Channel 11 Type of Modulation DSSS/OFDM Antenna Type Internal Device Category Portable RF Exposure Environment Uncontrolled Transfer Rate 802.11b: 11Mbps 802.11g: 54Mbps Max. Output Power 802.11b: 15.71dBm (Conducted) 802.11g: 9.23dBm 1.2 Test Environment Ambient conditions in the laboratory: Items Required Actual Temperature (°C) 18-25 21.7 Humidity (%RH) 30-70 53 Page: 5 of 22 Version:1.0

Report No:071L039-HPUSP09V01 2. SAR Measurement System 2.1 ALSAS-10U System Description ALSAS-10-U is fully compliant with the technical and scientific requirements of IEEE 1528, IEC 62209, CENELEC, ARIB, ACA, and the Federal Communications Commission. The system comprises of a six axes articulated robot which utilizes a dedicated controller. ALSAS-10U uses the latest methodologies and FDTD odeling to provide aplatform which is repeatable with minimum uncertainty. 2.1.1 Applications Predefined measurement procedures compliant with the guidelines of CENELEC, IEEE, IEC, FCC, etc are utilized during the assessment for the device. Automatic detection for all SAR maxima are embedded within the core architecture for the system, ensuring that peak locations used for centering the zoom scan are within a 1mm resolution and a 0.05mm repeatable position. System operation range currently available up-to 6 GHz in simulated tissue. 2.1.2 Area Scans Area scans are defined prior to the measurement process being executed with a user defined variable spacing between each measurement point (integral) allowing low uncertainty measurements to be conducted. Scans defined for FCC applications utilize a 10mm² step integral, with 1mm interpolation used to locate the peak SAR area used for zoom scan assessments. Where the system identifies multiple SAR peaks (which are within 25% of peak value) the system will provide the user with the option of assessing each peak location individually for zoom scan averaging. Page: 6 of 22 Version:1.0

Report No:071L039-HPUSP09V01 2.1.3 Zoom Scan (Cube Scan Averaging) The averaging zoom scan volume utilized in the ALSAS-10U software is in the shape of a cube and the side dimension of a 1 g or 10 g mass is dependent on the density of the liquid representing the simulated tissue. A density of 1000 kg/m³ is used to represent the head and body tissue density and not the phantom liquid density, in order to be consistent with the definition of the liquid dielectric properties, i.e. the side length of the 1 g cube is 10mm, with the side length of the 10 g cube 21,5mm. When the cube intersects with the surface of the phantom, it is oriented so that 3 vertices touch the surface of the shell or the center of a face is tangent to the surface. The face of the cube closest to the surface is modified in order to conform to the tangent surface. The zoom scan integer steps can be user defined so as to reduce uncertainty, but normal practice for typical test applications (including FCC) utilize a physical step of 5x5x8 (8mmx8mmx5mm) providing a volume of 32mm in the X & Y axis, and 35mm in the Z axis. 2.1.4 ALSAS-10U Interpolation and Extrapolation Uncertainty The overall uncertainty for the methodology and algorithms the used during the SAR calculation was evaluated using the data from IEEE 1528 based on the example f3 algorithm: 2.2 Isotropic E-Field Probe The isotropic E-Field probe has been fully calibrated and assessed for isotropicity, and boundary effect within a controlled environment. Depending on the frequency for which the probe is calibrated the method utilized for calibration will change. A number of methods is used for calibrating probes, and these are outlined in the table below: Calibration Frequency Air Calibration Tissue Calibration 2450MHz Waveguide Temperature Page: 7 of 22 Version:1.0

Report No:071L039-HPUSP09V01 The E-Field probe utilizes a triangular sensor arrangement as detailed in the diagram below: SAR is assessed with a calibrated probe which moves at a default height of 5mm from the center of the diode, which is mounted to the sensor, to the phantom surface (in the Z Axis). The 5mm offset height has been selected so as to minimize any resultant boundary effect due to the probe being in close proximity to the phantom surface. The following algorithm is an example of the function used by the system for linearization of the output from the probe when measuring complex modulation schemes. Page: 8 of 22 Version:1.0

Report No:071L039-HPUSP09V01 2.2.1 Isotropic E-Field Probe Specification Calibration in Air Frequency Dependent Below 2GHz Calibration in air performed in a TEM Cell Above 2GHz Calibration in air performed in waveguide Sensitivity 0.70 µV/(V/m)² to 0.85 µV/(V/m)² Dynamic Range 0.0005 W/kg to 100W/kg Isotropic Response Better than 0.2dB Diode Compression point Calibration for Specific Frequency (DCP) Probe Tip Radius < 5mm Sensor Offset 1.56 (+/- 0.02mm) Probe Length 290mm Video Bandwidth @ 500 Hz: 1dB @1.02 KHz: 3dB Boundary Effect Less than 2% for distance greater than 2.4mm Spatial Resolution Diameter less than 5mm Compliant with Standards 2.3 Boundary Detection Unit and Probe Mounting Device ALSAS-10U incorporates a boundary detection unit with a sensitivity of 0.05mm for detecting all types of surfaces. The robust design allows for detection during probe tilt (probe normalize) exercises, and utilizes a second stage emergency stop. The signal electronics are fed directly into the robot controller for high accuracy surface detection in lateral and axial detection modes (X, Y, & Z). The probe is mounted directly onto the Boundary Detection unit for accurate tooling and displacement calculations controlled by the robot kinematics. The probe is connect to an isolated probe interconnect where the output stage of the probe is fed directly into the amplifier stage of the Daq-Paq Page: 9 of 22 Version:1.0

Report No:071L039-HPUSP09V01 2.4 Daq-Paq (Analog to Digital Electronics) ALSAS-10U incorporates a fully calibrated Daq-Paq (analog to digital conversion system) which has a 4 channel input stage, sent via a 2 stage auto-set amplifier module. The input signal is amplified accordingly so as to offer a dynamic range from 5µV to 800mV. Integration of the fields measured is carried out at board level utilizing a Co-Processor which then sends the measured fields down into the main computational module in digitized form via an RS232 communications port. Probe linearity and duty cycle compensation is carried out within the main Daq-Paq module. ADC 12 Bit Amplifier Range 20mV to 200mV and 150mV to 800mV Field Integration Local Co-Processor utilizing proprietary integration algorithms Number of Input Channels 4 in total 3 dedicated and 1 spare Communication Packet data via RS232 2.5 Axis Articulated Robot ALSAS-10U utilizes a six axis articulated robot, which is controlled using a Pentium based real-time movement controller. The movement kinematics engine utilizes proprietary (Thermo CRS) interpolation and extrapolation algorithms, which allow full freedom of movement for each of the six joints within the working envelope. Utilization of joint 6 allows for full probe rotation with a tolerance better than 0.05mm around the central axis. Robot/Controller Manufacturer Thermo CRS Number of Axis Six independently controlled axis Positioning Repeatability 0.05mm Controller Type Single phase Pentium based C500C Robot Reach 710mm Communication RS232 and LAN compatible Page: 10 of 22 Version:1.0

Report No:071L039-HPUSP09V01 2.6 ALSAS Universal Workstation ALSAS Universal workstation allows for repeatability and fast adaptability. It allows users to do calibration, testing and measurements using different types of phantoms with one set up, which significantly speeds up the measurement process. 2.7 Universal Device Positioner The universal device positioner allow complete freedom of movement of the EUT. Developed to hold a EUT in a free-space scenario any additional loading attributable to the material used in the construction of the positioner has been eliminated. Repeatability has been enhanced through the linear scales which form the design used to indicate positioning for any given test scenario in all major axes. A 15° tilt indicator is included for the of aid cheek to tilt movements for head SAR analysis. Overall uncertainty for measurements have been reduced due to the design of the Universal device positioner, which allows positioning of a device in as near to a free-space scenario as possible, and by providing the means for complete repeatability. 2.8 Phantom Types The ALSAS-10U allows the integration of multiple phantom types. SAM Phantoms fully compliant with IEEE 1528, Universal Phantom, and Universal Flat. Page: 11 of 22 Version:1.0

Report No:071L039-HPUSP09V01 2.8.1 APREL SAM Phantoms The SAM phantoms developed using the IEEE SAM CAD file. They are fully compliant with the requirements for both IEEE 1528 and FCC Supplement C. Both the left and right SAM phantoms are interchangeable, transparent and include the IEEE 1528 grid with visible NF and MB lines. 2.8.2 APREL Laboratories Universal Phantom The Universal Phantom is used on the ALSAS-10U as a system validation phantom.The Universal Phantom has been fully validated both experimentally from 800MHz to 6GHz and numerically using XFDTD numerical software. The shell thickness is 2mm overall, with a 4mm spacer located at the NF/MB intersection providing an overall thickness of 6mm in line with the requirements of IEEE-1528. The design allows for fast and accurate measurements, of handsets, by allowing the conservative SAR to be evaluated at on frequency for both left and right head experiments in one measurement. Page: 12 of 22 Version:1.0

Report No:071L039-HPUSP09V01 3. Tissue Simulating Liquid 3.1 The composition of the tissue simulating liquid INGREDIENT 900MHz 1800MHz 2450MHz 2450MHz (% Weight) Head Head Head Body Water -- -- 46.7 73.2 Salt -- -- 0.00 0.04 Sugar -- -- 0.00 0.00 HEC -- -- 0.00 0.00 Preventol -- -- 0.00 0.00 DGBE -- -- 53.3 26.7 3.2 Tissue Calibration Result The dielectric parameters of the liquids were verified prior to the SAR evaluation using APREL Dielectric Probe Kit and Anritsu MS4623B Vector Network Analyzer Head Tissue Simulant Measurement Frequency Dielectric Parameters Tissue Temp. Description [MHz] εr σ [s/m] [°C] Reference result 39.2 1.8 N/A 2450MHz ± 5% window 37.24 to 41.16 1.71 to 1.89 09-Jan-06 38.36 1.858 21.7 Body Tissue Simulant Measurement Frequency Dielectric Parameters Tissue Temp. Description [MHz] εr σ [s/m] [°C] Reference result 52.7 1.95 N/A 2450MHz ± 5% window 50.065 to 55.335 1.8525 to 2.0475 09-Jan-06 51.35 1.981 21.7 2412 MHz Low channel 51.58 2.015 21.7 2437 MHz Mid channel 51.42 1.992 21.7 2462 MHz High channel 51.28 1.969 21.7 Page: 13 of 22 Version:1.0

Report No:071L039-HPUSP09V01 3.3 Tissue Dielectric Parameters for Head and Body Phantoms The head tissue dielectric parameters recommended by the IEEE SCC-34/SC-2 in P1528 have been incorporated in the following table. These head parameters are derived from planar layer models simulating the highest expected SAR for the dielectric properties and tissue thickness variations in a human head. Other head and body tissue parameters that have not been specified in P1528 are derived from the tissue dielectric parameters computed from the 4-Cole-Cole equations described in Reference [12] and extrapolated according to the head parameters specified in P1528. Target Frequency Head Body (MHz) εr σ (S/m) εr σ (S/m) 150 52.3 0.76 61.9 0.80 300 45.3 0.87 58.2 0.92 450 43.5 0.87 56.7 0.94 835 41.5 0.90 55.2 0.97 900 41.5 0.97 55.0 1.05 915 41.5 0.98 55.0 1.06 1450 40.5 1.20 54.0 1.30 1610 40.3 1.29 53.8 1.40 1800 – 2000 40.0 1.40 53.3 1.52 2450 39.2 1.80 52.7 1.95 3000 38.5 2.40 52.0 2.73 5800 35.3 5.27 48.2 6.00 (εr = relative permittivity, σ = conductivity and ρ = 1000 kg/m3) Page: 14 of 22 Version:1.0

Report No:071L039-HPUSP09V01 4. SAR Measurement Procedure 4.1 SAR System Validation 4.1.1 Validation Dipoles The dipoles used is based on the IEEE-1528 standard, and is complied with mechanical and electrical specifications in line with the requirements of both IEEE and FCC Supplement C. the table below provides details for the mechanical and electrical specifications for the dipoles. Frequency L (mm) h (mm) d (mm) 2450MHz 53.5 30.4 3.6 4.1.2 Validation Result System Performance Check at 2450MHz Validation Kit: ASL-D-2450-S-2 Frequency SAR [w/kg] SAR [w/kg] Tissue Temp. Description [MHz] 1g 10g [°C] Reference result 52.4 24 N/A 2450 MHz ± 5% window 49.78 to 55.02 22.8 to 25.2 09-Jan-06 51.368 23.004 21.7 Note: All SAR values are normalized to 1W forward power. Page: 15 of 22 Version:1.0

Report No:071L039-HPUSP09V01 4.2 SAR Measurement Procedure The ALSAS-10U calculates SAR using the following equation, σ: represents the simulated tissue conductivity ρ: represents the tissue density The EUT is set to transmit at the required power in line with product specification, at each frequency relating to the LOW, MID, and HIGH channel settings. Pre-scans are made on the device to establish the location for the transmitting antenna, using a large area scan in either air or tissue simulation fluid. The EUT is placed against the Universal Phantom where the maximum area scan dimensions are larger than the physical size of the resonating antenna. When the scan size is not large enough to cover the peak SAR distribution, it is modified by either extending the area scan size in both the X and Y directions, or the device is shifted within the predefined area. The area scan is then run to establish the peak SAR location (interpolated resolution set at 1mm² )which is then used to orient the center of the zoom scan. The zoom scan is then executed and the 1g and 10g averages are derived from the zoom scan volume (interpolated resolution set at 1mm³ ). Page: 16 of 22 Version:1.0

Report No:071L039-HPUSP09V01 5. SAR Exposure Limits SAR assessments have been made in line with the requirements of IEEE-1528, FCC Supplement C, and comply with ANSI/IEEE C95.1-1992 “Uncontrolled Environments” limits. These limits apply to a location which is deemed as “Uncontrolled Environment” which can be described as a situation where the general public may be exposed to an RF source with no prior knowledge or control over their exposure. Limits for General Population/Uncontrolled Exposure (W/kg) Type Exposure Uncontrolled Environment Limit Spatial Peak SAR (1g cube tissue for brain or body) 1.60 W/kg Spatial Average SAR (whole body) 0.08 W/kg Spatial Peak SAR (10g for hands, feet, ankles and wrist) 4.00 W/kg Page: 17 of 22 Version:1.0

Report No:071L039-HPUSP09V01 6. Test Equipment List Instrument Manufacturer Model No. Serial No. Last Calibration Data Acquisition Package Aprel ALS-DAQ-PAQ-2 QTK-337 Nov. 2005 Aprel Laboratories Probe Aprel ALS-E020 264 Mar. 2006 Aprel Reference Dipole Aprel ALS-D-900-S-2 QTK-316 Jun. 2006 900Mhz Aprel Reference Dipole Aprel ALS-D-1800-S-2 QTK-317 Jun. 2006 1800Mhz Aprel Reference Dipole Aprel ALS-D-2450-S-2 QTK-319 Jun. 2006 2450Mhz Boundary Detection Sensor Aprel ALS-PMDPS-2 QTK-336 N/A System Dielectric Probe Kit Aprel ALS-PR-DIEL QTK-296 N/A Universal Work Station Aprel ALS-UWS QTK-326 N/A Device Holder 2.0 Aprel ALS-H-E-SET-2 QTK-294 N/A Left Ear SAM Phantom Aprel ALS-P-SAM-L QTK-292 N/A Right Ear SAM Phantom Aprel ALS-P-SAM-R QTK-288 N/A Universal Phantom Aprel ALS-P-UP-1 QTK-246 N/A Aprel Dipole Spacer Aprel ALS-DS-U QTK-295 N/A SAR Software Aprel ALSAS-10 Ver. 2.3.0 N/A CRS C500C Controller Thermo ALS-C500 RCF0404433 N/A CRF F3 Robot Thermo ALS-F3 RAF0412222 N/A Power Amplifier Mini-Circuit ZHL-42 D051404-20 N/A Directional Coupler Agilent 778D-012 50550 N/A Universal Radio Rohde & CMU 200 104846 Mar. 2006 Communication Tester Schwarz Vector Network Anritsu MS4623B 992801 Mar 2006 Signal Generator Anritsu MG3692A 042319 Jun. 2006 Power Meter Anritsu ML2487A 6K00001447 Jan. 2006 Wide Bandwidth Sensor Anritsu MA2491 030677 Jan. 2006 Page: 18 of 22 Version:1.0

Quielex Exposure Assessment Measurement Uncertainty Source of Tolerance Probability Divisor ¢, ¢, Standard Standard Uncertainty Yalue Distribution (1—g) (10—g) Uncertainty Uncertainty (1—g) (10—g) & & & Measurement System Probe Calibration i.3 normnal 1 1 1 3.5 3.5 Axial Isotropy 3. rectangular |,3 (1—l fl—’ 1.5 1.5 cp) cp) emispherical 10.3 rectangular |,3 cp cp .4 i.2 Isotrop Eoundary Effect 1.0 rectangular ; : 1 1 0.6 0.6 Linearity 4.7 rectangul ar Ne 1 1 2.7 2.7 Detection Limit 1.0 rectangular ;3 1 1 0.6 0.6 Readout Electronics |1.0 normal 1 1 1 1.0 1. 0 Response Tie 0.3 rectangular ,3 1 1 0.5 o.5 Integration Time 1.7 rectangular ;3 1 1 1.0 1. 0 RF Ambient Condition 3.0 rectangular ; 1 1 1.7 1.7 Probe Positioner 0.4 rectangular |\3 1 1 0.2 0.2 Mech. Restriction Probe Positioning 2.3 rectangular |\3 1 1 1.7 1.7 with respect to Phantom Shell Extrapolation and 3. rectangular 3 1 1 2.1 2.1 Integration Test Sanple 4.0 normal 1 1 1 4.0 4.0 Positioning Device Holder 2.0 normal 1 1 1 2.0 2.0 Uncertainty Drift of Output 0.1 rectangular |\3 1 1 0.0 0.0 Power Phantom and Setup Phant on 324 rectangular |\3 1 1 2.0 2.0 Uncertainty(shape & thickness tolerance) Liquid 5.0 rectangular |\3 0. 0.5 2.0 1.4 Conductivity (target ) Liquid 0.1 rectangular |\3 0.5 0.0 0.0 Conductivity (meas.) Liquid 2.0 rectangular |\3 0.6 0.5 0.7 0.6 Permittivity (target) Liquid 4.2 rectangular |\3 0. 0.5 1.4 1.2 Permittivity (meas . ) Combined Uncertainty RSS 9.2 5.1 Combined Uncertainty Normal (k=2) 18 .4 18.1 (coverage factor—2)

Report No:071L039-HPUSP09V01 8. Test Results 8.1 SAR Test Results Summary SAR MEASUREMENT Ambient Temperature (°C) : 21.7 ±2 Relative Humidity (%): 53 Liquid Temperature (°C) : 21.4 ±2 Depth of Liquid (cm):>15 Product: IEEE 802.11g Wireless Pocket USB Test Mode: 802.11b Test Position Antenna Frequency Conducted SAR 1g Limit Power Body Position (W/kg) (W/kg) Channel MHz (dBm) Back Fixed 1 2412 15.71 0.731 1.6 Back Fixed 6 2437 13.72 0.564 1.6 Back Fixed 11 2462 13.37 0.457 1.6 Top Fixed 1 2412 ** ** 1.6 Top Fixed 6 2437 13.72 0.224 1.6 Top Fixed 11 2462 ** ** 1.6 Front Fixed 1 2412 ** ** 1.6 Front Fixed 6 2437 13.72 0.175 1.6 Front Fixed 11 2462 ** ** 1.6 Note: The SAR measured at the middle channel for this configuration is at least 3 dB lower than SAR limit, testing at the high and low channels is option. Page: 20 of 22 Version:1.0

Report No:071L039-HPUSP09V01 SAR MEASUREMENT Ambient Temperature (°C) : 21.7 ±2 Relative Humidity (%): 53 Liquid Temperature (°C) : 21.4 ±2 Depth of Liquid (cm):>15 Product: IEEE 802.11g Wireless Pocket USB Test Mode: 802.11g Test Position Antenna Frequency Conducted SAR 1g Limit Power Head Position (W/kg) (W/kg) Channel MHz (dBm) Back Fixed 1 2412 9.23 0.398 1.6 Back Fixed 6 2437 7.83 0.26 1.6 Back Fixed 11 2462 7.67 0.321 1.6 Top Fixed 1 2412 ** ** 1.6 Top Fixed 6 2437 7.83 0.106 1.6 Top Fixed 11 2462 ** ** 1.6 Front Fixed 1 2412 ** ** 1.6 Front Fixed 6 2437 7.83 0.108 1.6 Front Fixed 11 2462 ** ** 1.6 Note: The SAR measured at the Top position for this configuration is at least 3 dB lower than SAR limit, , testing at the high and low channels is option. Page: 21 of 22 Version:1.0

Report No:071L039-HPUSP09V01 Appendix A. SAR System Validation Data Appendix B. SAR measurement Data Appendix C. Test Setup Photographs & EUT Photographs Appendix D. Probe Calibration Data Appendix E. Dipole Calibration Data Page: 22 of 22 Version:1.0


Document Created: 2007-01-15 17:53:40
Document Modified: 2007-01-15 17:53:40
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