test report part 15B (JPB)

FCC ID: O2Z-BTXZ0

Test Report

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FCCID_1851985

FCC Test Report FOR: Manufacturer: Intel Corporation Model Number: BT210/BT230/BT510 Product Description: Smartphone with GSM/GPRS/EDGE, UMTS/HSDPA, Wi-Fi, BT, GPS and FM-Rx Radios FCC- Part 15B TEST REPORT #: EMC_INTEL-023-12001_FCC15B DATE: 2012-11-30 FCC listed: A2LA Accredited IC recognized # 3462B-1 CETECOM Inc. 411 Dixon Landing Road  Milpitas, CA 95035  U.S.A. Phone: + 1 (408) 586 6200  Fax: + 1 (408) 586 6299  E-mail: info@cetecomusa.com  http://www.cetecom.com CETECOM Inc. is a Delaware Corporation with Corporation number: 2905571 V4.0 2012-07-20 The BLUETOOTH trademarks are owned by Bluetooth SIG, Inc., U.S.A. and licensed to CETECOM Inc. © Copyright by CETECOM

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 2 of 20 TABLE OF CONTENTS 1 Assessment_____________________________________________________________________ 3 2 Administrative Data _____________________________________________________________ 4 2.1 Identification of the Testing Laboratory Issuing the Test Report __________________________ 4 2.2 Identification of the Client __________________________________________________________ 4 2.3 Identification of the Manufacturer ___________________________________________________ 4 3 Equipment under Test (EUT) ______________________________________________________ 5 3.1 Specification of the Equipment under Test ____________________________________________ 5 3.2 Identification of the Equipment Under Test (EUT) _____________________________________ 5 3.3 Identification of Accessory equipment ________________________________________________ 6 4 Subject of Investigation __________________________________________________________ 7 5 Summary of Measurement Results _________________________________________________ 8 6 Radiated Emissions ______________________________________________________________ 9 6.1 §15.109 Radiated emission limits- Unintentional Radiators: _____________________________ 9 6.2 Measurement Procedure: __________________________________________________________ 10 6.3 Sample Calculations for Radiated Measurements______________________________________ 12 6.4 Testing Notes: ___________________________________________________________________ 12 6.5 Results _________________________________________________________________________ 13 7 AC Power Line Conducted Emissions ______________________________________________ 15 7.1 § 15.107 Conducted limits- Unintentional Radiators __________________________________ 15 7.2 Measurement Procedure: __________________________________________________________ 16 7.3 Results: _________________________________________________________________________ 18 8 Test Equipment and ancillaries used for tests ________________________________________ 19 9 Test Setup Diagrams ____________________________________________________________ 20

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 3 of 20 1 Assessment The following device was tested against the applicable criteria specified in FCC rules Part 15B of the Code of Federal Regulations and no deviations were ascertained during the course of the tests performed. Company Description Model # Smartphone with GSM/GPRS/EDGE, Intel Corporation UMTS/HSDPA, Wi-Fi, BT, GPS and FM-Rx BT210, BT230, BT510 Radios Responsible for Testing Laboratory: Sajay Jose 2012-11-30 Compliance (Test Lab Manager) Date Section Name Signature Responsible for the Report: Digitally signed by Daniel Salinas Daniel Salinas DN: cn=Daniel Salinas, c=US, o=Cetecom, Inc., ou=Compliance, email=daniel.salinas@cetecom.com 2012-11-30 Compliance (EMC Engineer) Date: 2012.11.30 19:07:41 -08'00' Date Section Name Signature The test results of this test report relate exclusively to the test item specified in Section3. CETECOM Inc. USA does not assume responsibility for any conclusions and generalizations drawn from the test results with regard to other specimens or samples of the type of the equipment represented by the test item. The test report may only be reproduced or published in full. Reproduction or publication of extracts from the report requires the prior written approval of CETECOM Inc. USA.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 4 of 20 2 Administrative Data 2.1 Identification of the Testing Laboratory Issuing the Test Report Company Name: CETECOM Inc. Department: Compliance Address: 411 Dixon Landing Road Milpitas, CA 95035 U.S.A. Telephone: +1 (408) 586 6200 Fax: +1 (408) 586 6299 Test Lab Manager: Sajay Jose Test Engineer: Daniel Salinas 2.2 Identification of the Client Client: Intel Corporation Street Address: 2200 Mission College Blvd City/Zip Code Santa Clara, 95054 Country United States Contact Person: Christine Ryan Phone No. +1 (408) 300 2167 2.3 Identification of the Manufacturer Manufacturer’s Name: Manufacturers Address: Same as Client City/Zip Code Country

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 5 of 20 3 Equipment under Test (EUT) 3.1 Specification of the Equipment under Test Model No: BT210, BT230, BT510 Smartphone with GSM/GPRS/EDGE, UMTS/HSDPA, Wi-Fi, BT, GPS Product Description: and FM-Rx Radios GSM/GPRS/EGPRS 850/900/1800/1900 Radios included: UMTS I/II/V/VIII BT 3.0+EDR: 2402-2480 MHz Wi-Fi 802.11b/g/n: 2400-2483.5MHz; HT20 FCC ID: O2Z-BTXZ0 GSM Bands: 850/900/1800/1900 Frequency range of UMTS Bands: 850/900/1800/1900 operation: Wi-Fi: 2.4 GHz BT: 2.4 GHz GSM: GMSK, 8PSK UMTS: QPSK, 16QAM, 64QAM Modulations supported: BT: GFSK, Pi/4-DQPSK, 8DPSK Wi-Fi: QPSK,OFDM Rated Operating Voltage Battery powered. Range: Vlow: 3.6V/ Vnom: 3.7V/ Vmax: 4.2V Rated Operating Tlow: -10°C/ Tmax: 55°C Temperature Range: 3.2 Identification of the Equipment Under Test (EUT) EUT # Serial Number HW Version SW Version 1 LEXP1LPEM103716 ZQB DV 1.1B ZYB ICS 8184 2 LEXP1LP1EM102750 ZQB DV 1 ZYB ICS 8184

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 6 of 20 3.3 Identification of Accessory equipment AE # Type Manufacturer Model Comments 1 Headset PCH INTERNATIONAL G64341--002 - SHENZHEN YIHUAXING 2 USB Cable G84460-001 1.5m cable ELECTRONICS CO., LTD 3 Laptop Dell Latitude D510 Ident: 97GL391

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 7 of 20 4 Subject of Investigation Testing was performed on the BT510 model to evaluate compliance against the applicable criteria specified in FCC CFR 47 Part 15 Subpart B. Radiated Emission tests are carried out to show that the EUT complies with FCC15.109 (a) radiated emissions limit for Class B device. Conducted Emission tests are carried out to show that the EUT complies with FCC15.107 (a) radiated emissions limit for Class B device. This test report includes data from measurements on model number BT510. There are two additional variants- BT210 and BT230, which are HW identical to BT510, per manufacturer stated product declaration. Hence test results from BT510 are deemed to be valid for the variants BT210 and BT230.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 8 of 20 5 Summary of Measurement Results Temperature Test Test Case and Voltage Mode Pass Fail NA NP Result Specification Conditions RX Spurious §15.109 Emissions Nominal RX Mode     Complies Radiated Conducted §15.107(a) Emissions Nominal RX Mode     Complies <30MHz Note: NA= Not Applicable; NP= Not Performed.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 9 of 20 6 Radiated Emissions 6.1 §15.109 Radiated emission limits- Unintentional Radiators: (a) Except for Class A digital devices, the field strength of radiated emissions from unintentional radiators at a distance of 3 meters shall not exceed the following values: Frequency of emission (MHz) Field strength (µV/m) 30–88 100 88–216 150 216–960 200 Above 960 500 (b) The field strength of radiated emissions from a Class A digital device, as determined at a distance of 10 meters, shall not exceed the following: Frequency of emission (MHz) Field strength (µV/m) 30–88 90 88–216 150 216–960 210 Above 960 300

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 10 of 20 6.2 Measurement Procedure: ANSI C63.4 (2009) Section 8.3.1.1: Exploratory radiated emission measurements Exploratory radiated measurements shall be performed at the measurement distance or at a closer distance than that specified for compliance to determine the emission characteristics of the EUT. At near distances, for EUTs of comparably small size, it is relatively easy to determine the spectrum signature of the EUT and, if applicable, the EUT configuration that produces the maximum level of emissions. A shielded room may be used for exploratory testing, but may have anomalies that can lead to significant errors in amplitude measurements. Broadband antennas and a spectrum analyzer or a radio-noise meter with a panoramic display are often useful in this type of testing. It is recommended that either a headset or loudspeaker be connected as an aid in detecting ambient signals and finding frequencies of significant emission from the EUT when the exploratory and final testing is performed in an OATS with strong ambient signals. Caution should be taken if either antenna height between 1 and 4 meters or EUT azimuth is not fully explored. Not fully exploring these parameters during exploratory testing may require complete testing at the OATS or semi-anechoic chamber when the final full spectrum testing is conducted. The EUT should be set up in its typical configuration and arrangement, and operated in its various modes. For tabletop systems, cables or wires should be manipulated within the range of likely arrangements. For floor-standing equipment, the cables or wires should be located in the same manner as the user would install them and no further manipulation is made. For combination EUTs, the tabletop and floor-standing portions of the EUT shall follow the procedures for their respective setups and cable manipulation. If the manner of cable installation is not known, or if it changes with each installation, cables or wires for floor-standing equipment shall be manipulated to the extent possible to produce the maximum level of emissions. For each mode of operation required to be tested, the frequency spectrum shall be monitored. Variations in antenna height between 1 and 4 m, antenna polarization, EUT azimuth, and cable or wire placement (each variable within bounds specified elsewhere) shall be explored to produce the emission that has the highest amplitude relative to the limit. A step-by-step technique for determining this emission can be found in Annex C. When measuring emissions above 1 GHz, the frequencies of maximum emission shall be determined by manually positioning the antenna close to the EUT and by moving the antenna over all sides of the EUT while observing a spectral display. It will be advantageous to have prior knowledge of the frequencies of emissions above 1 GHz. If the EUT is a device with dimensions approximately equal to that of the measurement antenna beamwidth, the measurement antenna shall be aligned with the EUT.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 11 of 20 ANSI C63.4 (2009) Section 8.3.1.2: Final radiated emission measurements Based on the measurement results in 8.3.1.1, the one EUT, cable and wire arrangement, and mode of operation that produces the emission that has the highest amplitude relative to the limit is selected for the final measurement. The final measurement is then performed on a site meeting the requirements of 5.3, 5.4, or 5.5 as appropriate without variation of the EUT arrangement or EUT mode of operation. If the EUT is relocated from an exploratory test site to a final test site, the highest emission shall be remaximized at the final test location before final radiated emissions measurements are performed. However, antenna height and polarity and EUT azimuth are to be varied. In addition, the full frequency spectrum (for the range to be checked for meeting compliance) shall be investigated. This investigation is performed with the EUT rotated 360°, the antenna height scanned between 1 m and 4 m, and the antenna rotated to repeat the measurements for both the horizontal and vertical antenna polarizations. During the full frequency spectrum investigation, particular focus should be made on those frequencies found in exploratory testing that were used to find the final test configuration, mode of operation, and arrangement (associated with achieving the least margin with respect to the limit). This full spectrum test constitutes the compliance measurement. For measurements above 1 GHz, use the cable, EUT arrangement, and mode of operation determined in the exploratory testing to produce the emission that has the highest amplitude relative to the limit. Place the measurement antenna away from each area of the EUT determined to be a source of emissions at the specified measurement distance, while keeping the antenna in the ―cone of radiation‖ from that area and pointed at the area both in azimuth and elevation, with polarization oriented for maximum response. The antenna may have to be higher or lower than the EUT, depending on the EUT’s size and mounting height, but the antenna should be restricted to a range of heights of from 1 m to 4 m above the ground or reference ground plane. If the transmission line for the measurement antenna restricts its range of height and polarization, the steps needed to ensure the correct measurement of the maximum emissions, shall be described in detail in the report of measurements. Data collected shall satisfy the report requirements of Clause 10. NOTES 1— Where limits are specified by agencies for both average and peak (or quasi-peak) detection, if the peak (or quasi-peak) measured value complies with the average limit, it is unnecessary to perform an average measurement. 2—Use of waveguide and flexible waveguide may be necessary at frequencies above 10 GHz to achieve usable signal-to noise ratios at required measurement distances. If so, it may be necessary to restrict the height search of the antenna, and special care should be taken to ensure that maximum emissions are correctly measured. 3—All presently known devices causing emissions above 10 GHz are physically small compared with the beam-widths of typical horn antennas used for EMC measurements. For such EUTs and frequencies, it may be preferable to vary the height and polarization of the EUT instead of the receiving antenna to maximize the measured emissions.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 12 of 20 6.3 Sample Calculations for Radiated Measurements 6.3.1.1 Field Strength Measurements: Measurements from the Spectrum Analyzer/ Receiver is used to calculate the Field Strength, taking into account the following parameters: 1. Measured reading in dBµV 2. Cable Loss between the receiving antenna and SA in dB and 3. Antenna Factor in dB/m FS (dBµV/m)= Measured Value on SA (dBµV)+ Cable Loss (dB)+ Antenna Factor (dB/m) Eg: Antenna Factor Field Strength Frequency Measured SA Cable Loss Correction Result (MHz) (dBµV) (dB) (dB) (dBµV/m) 1000 80.5 3.5 14 98.0 All radiated measurement plots in this report are taken from a test SW that calculates the Field Strength based on the above equation. 6.4 Testing Notes: The relevant procedures of ANSI C63.4: 2009 have been followed. All radiated test data in this report shows the worst case emissions for H/V measurement antenna polarizations and for all three orthogonal orientations of the EUT.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 13 of 20 6.5 Results Radiated Emissions: 30M- 1GHz 70 65 60 55 FCC 15 263.173077 MHz 37.870 dBµV/m 50 45 Level in dBµV/m 40 35 30 25 20 15 10 5 0 30M 50 60 80 100M 200 300 400 500 800 1G Frequency in Hz FCC 15 Preview Result 1-PK+ Data Reduction Result 1 [3]-PK+

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 14 of 20 Radiated Emissions: 1 GHz- 18 GHz 80 75 74 dBuV per m 70 1.663461539 GHz 65 57.623 dBµV/ m 60 55 54 dBuV per m 50 Level in dBµV/m 45 40 35 30 25 20 15 10 5 0 1G 2G 3G 4G 5G 6 8 10G 18G Frequency in Hz 74 dBuV per m 54 dBuV per m Preview Result 1-PK+ Preview Result 2-AVG Data Reduction Result 2 [4]-AVG

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 15 of 20 7 AC Power Line Conducted Emissions 7.1 § 15.107 Conducted limits- Unintentional Radiators (a) Except for Class A digital devices, for equipment that is designed to be connected to the public utility (AC) power line, the radio frequency voltage that is conducted back onto the AC power line on any frequency or frequencies within the band 150 kHz to 30 MHz shall not exceed the limits in the following table, as measured using a 50 μH/50 ohms line impedance stabilization network (LISN). Compliance with the provisions of this paragraph shall be based on the measurement of the radio frequency voltage between each power line and ground at the power terminal. The lower limit applies at the band edges. Conducted limit (dBμV) Frequency of emission (MHz) Quasi-peak Average 0.15–0.5 66 to 56* 56 to 46* 0.5–5 56 46 5–30 60 50 *Decreases with the logarithm of the frequency. (b) For a Class A digital device that is designed to be connected to the public utility (AC) power line, the radio frequency voltage that is conducted back onto the AC power line on any frequency or frequencies within the band 150 kHz to 30 MHz shall not exceed the limits in the following table, as measured using a 50 μH/50 ohms LISN. Compliance with the provisions of this paragraph shall be based on the measurement of the radio frequency voltage between each power line and ground at the power terminal. The lower limit applies at the boundary between the frequency ranges. Conducted limit (dBμV) Frequency of emission (MHz) Quasi-peak Average 0.15–0.5 79 66 0.5–5 73 60

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 16 of 20 7.2 Measurement Procedure: ANSI C63.4 (2009) Section 7.3.1: Measurements at a test site Tabletop devices shall be placed on a nonconducting platform, of nominal size 1 m by 1.5 m, raised 80 cm above the reference ground plane. The vertical conducting plane, when used, or wall of a screened room shall be located 40 cm to the rear of the EUT. Floor-standing devices shall be placed either directly on the reference ground plane or on insulating material. All other surfaces of tabletop or floor-standing EUTs shall be at least 80 cm from any other grounded conducting surface, including the case or cases of one or more LISNs. AC power-line adapters that are used with EUTs, such as notebook computers, should be placed as typically used (i.e., on the tabletop) if the adapter-to-EUT cord is too short to allow the power adapter to reach the floor. Each current-carrying conductor of the EUT power cord(s), except the ground (safety) conductor(s), shall be individually connected through a LISN to the input power source. All 50 Ω ports of the LISN shall be resistively terminated into 50 Ω loads when not connected to the measuring instrument. When the test configuration consists of multiple units (EUT and associated/peripheral equipment, or EUT consisting of multiple equipment) that have their own power cords, ac power-line conducted emissions measurements shall be performed with the ac power-line cord of the particular unit under test connected to one LISN that is connected to the measuring instrument. Those power cords for the units in the remainder of the configuration not under measurement shall be connected to a separate LISN or LISNs. This connection may be made using a multiple-receptacle device. Emissions from each current-carrying conductor of the EUT shall be individually measured. Where multiple portions of the EUT receive ac power from a common power strip, which is furnished by the manufacturer as part of the EUT, measurements need only be made on the current-carrying conductors of the common power strip. Adapters or extension cords connected between the EUT power cord plug and the LISN power receptacle shall be included in the LISN setup, such that the calibration of the combined adapter or extension cord with an adapter and the LISN meets the requirements of 5.2.3. If the EUT consists of a number of devices that have their own separate ac power connections, e.g., a floorstanding frame with independent power cords for each shelf, that are able to connect directly to the ac power network, each current-carrying conductor of one device is measured while the other devices are connected to a second (or more) LISN(s). All devices shall be separately measured. If the manufacturer provides a power strip to supply power to all of the devices making up the EUT, only the conductors in the common power cord to the power strip shall be measured. If the EUT is normally operated with a ground (safety) connection, the EUT shall be connected to the ground at the LISN through a conductor provided in the lead from the ac power to the LISN. The excess length of the power cord between the EUT and the LISN receptacle (or ac power receptacle where a LISN cannot be used), or an adapter or extension cord connected to and measured with the LISN, shall be folded back and forth at the center of the lead to form a bundle not exceeding 40 cm in length. If the EUT does not have a flexible power lead, the EUT shall be placed at a distance of 80 cm from the LISN (or power receptacle where a LISN cannot be used) and connected thereto by a power lead or appropriate connection no more than 1 m long. The measurement shall be made at the LISN end of this power lead or connection. The LISN housing, measuring instrument case, reference ground plane, vertical conducting plane, if used, shall be bonded together.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 17 of 20 ANSI C63.4 (2009) Section 7.3.3: Exploratory ac power-line conducted emission measurements Exploratory measurements shall be used to identify the frequency of the emission that has the highest amplitude relative to the limit by operating the EUT in a range of typical modes of operation, cable positions, and with a typical system equipment configuration and arrangement. For each mode of operation and for each ac power current-carrying conductor, cable manipulation may be performed within the range of likely configurations. For this measurement or series of measurements, the frequency spectrum of interest shall be monitored looking for the emission that has the highest amplitude relative to the limit. Once that emission is found for each current-carrying conductor of each power cord associated with the EUT (but not the cords associated with non-EUT equipment in the overall system), the one configuration and arrangement and mode of operation that produces the emission closest to the limit across all the measured conductors is recorded. ANSI C63.4 (2003) Section 7.3.4: Final ac power-line conducted emission measurements Based on the exploratory tests of the EUT, the one EUT cable configuration and arrangement and mode of operation that produced the emission with the highest amplitude relative to the limit is selected for the final measurement. If the EUT is relocated from an exploratory test site to a final test site, the highest emissions shall be remaximized at the final test location before final ac power-line conducted emission measurements are performed. The final test on all current-carrying conductors of all of the power cords to the equipment that comprises the EUT (but not the cords associated with other non-EUT equipment in the system) is then performed for the full frequency range for which the EUT is being tested for compliance without additional variation of the EUT arrangement, cable positions, or EUT mode of operation. If the EUT consists of equipment units that have their own separate ac power connections (e.g., a floor-standing frame with independent power cords for each shelf that are able to connect directly to the ac power network), then each current-carrying conductor of one unit is measured while the other units are connected to a second (or more) LISN(s). All units shall be measured separately. If the manufacturer provides a power strip to supply all the units making up the EUT, only the conductors in the power cord of the power strip shall be measured.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 18 of 20 7.3 Results: Plots below show the worst case representation of emissions into LINE and NEUTRAL. 80 75 70 65 EN 55022 Voltage on Mains QP 60 55 EN 55022 Voltage on Mains AV 50 45 Level in dBµV 40 35 30 25 20 15 10 5 0 -5 -10 150k 300 400 500 800 1M 2M 3M 4M 5M 6 8 10M 20M 30M Frequency in Hz EN 55022 Voltage on Mains QP EN 55022 Voltage on Mains AV Preview Result 1-PK+ Preview Result 2-AVG

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 19 of 20 8 Test Equipment and ancillaries used for tests No. Equipment Name Manufacturer Type/model Serial No. Cal Date Cal Interval 3m Semi- Anechoic Chamber: Turn table EMCO 2075 N/A N/A N/A MAPS Position Controller ETS Lindgren 2092 0004-1510 N/A N/A Antenna Mast EMCO 2075 N/A N/A N/A Relay Switch Unit Rohde&Schwarz RSU 338964/001 N/A N/A EMI Receiver/Analyzer Rohde&Schwarz ESU 40 100251 May 2012 1 Year Spectrum Analyzer Rohde&Schwarz FSU 200302 May 2011 2 Years 1500MHz HP Filter Filtek HP12/1700 14c48 N/A N/A 2800 MHz HP Filter Filtek HP12/2800 14C47 N/A N/A Pre-Amplifier Miteq JS40010260 340125 N/A N/A Binconilog Antenna EMCO 3141 0005-1186 Apr 2012 3 Years Binconilog Antenna ETS 3149 J000123908 Feb 2012 3 years Horn Antenna EMCO 3115 35114 Mar 2012 3 Years LISN FCC 50-25-2-08 08014 Jul 2012 1 Year Ancillary equipment Multimeter Klein Tools MM200 001 Apr 2011 2 Years Humidity Temperature Logger Dickson TM320 03280063 Mar 2012 1 Year Digital Barometer VWR 35519-055 91119547 Nov 2011 2 Years DC Power Supply HP E3610A KR83023316 N/A N/A DC Power Supply Protek 3003B H012771 N/A N/A Communication Antenna IBP5-900/1940 Kathrein N/A N/A N/A Equipment used meets the measurement uncertainty requirements as required per applicable standards for 95% confidence levels. Calibration due dates, unless defined specifically, falls on the last day of the month. Items indicated ―N/A‖ for cal status either do not specifically require calibration or is internally characterized before use.

Test Report #: EMC_ INTEL-023-12001_FCC15B Date of Report 2012-11-30 Page 20 of 20 9 Test Setup Diagrams Test Setup for 30M-1GHz Measurements Height Scan 1-4m 3 m Distance EUT at 80 cm BiLog Measurement Antenna Turn-Table Chamber Ground plane EMI Receiver Test Setup for >1GHz Measurements Height Scan 3m Distance 1-4m EUT at 80cm Horn Measurement Antenna Turn-Table EMI Receiver


Document Created: 2012-11-30 19:07:41
Document Modified: 2012-11-30 19:07:41
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