SAR Report

FCC ID: V65SCP-27H

RF Exposure Info

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FCCID_1073301

FCC ID: V65SCP-27H SAR Test Report on Dual-Band CDMA Cellular Phone with Bluetooth FCC Part 22 & 24 Certification FCC ID: V65SCP-27H MODEL: SCP-2700 DATE: December 12, 2008 STATEMENT OF COMPLIANCE Kyocera Wireless Corp declares under its sole responsibility that the product, FCC ID: V65SCP- 27H to which this declaration relates, is in conformity with the appropriate General Population/Uncontrolled RF exposure standards, recommendations and guidelines. It also declares that the product was tested in accordance with the appropriate measurement standards, guidelines and recommended practices. Any deviations from these standards, guidelines and recommended practices are noted: NONE. Report No: KWC-V65-2sar-1208-R0 Report Prepared for: KYOCERA Corporation KYOCERA SANYO Telecom, Inc. 21605 Plummer Street Chatsworth, CA 91311 United States Date of Test: December 09 – December 10, 2008 Kyocera Wireless Corp. Test performed by: 10300 Campus Point Drive San Diego, CA 92121 Report Prepared by: Jeff Flores, Test Technician Intermediate Report Prepared and Reviewed by: Ngoc-Thi Nguyen, Regulatory Engineer Report Reviewed and Approved by: C.K. Li, Director of Regulatory Engineering Kyocera Wireless Corp. Page 1 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H Table of Contents 1 INTRODUCTION.............................................................................................................................................................. 3 2 EQUIPMENT UNDER TEST (EUT) ............................................................................................................................... 3 3 PRODUCT DESCRIPTION ............................................................................................................................................. 4 4 ACCESSORIES: ................................................................................................................................................................ 4 5 SAR TEST RESULT SUMMARY ................................................................................................................................... 5 5.1 MAXIMUM RESULTS FOUND DURING SAR EVALUATION .............................................................................................. 5 5.2 HEAD CONFIGURATION ................................................................................................................................................. 5 5.3 BODY WORN CONFIGURATION...................................................................................................................................... 5 5.4 MEASUREMENT UNCERTAINTY ..................................................................................................................................... 5 6 TEST CONDITIONS......................................................................................................................................................... 6 6.1 AMBIENT CONDITIONS .................................................................................................................................................. 6 6.2 RF CHARACTERISTICS OF THE TEST SITE ....................................................................................................................... 6 6.3 TEST SIGNAL, FREQUENCIES AND OUTPUT POWER ....................................................................................................... 6 6.3.1 CDMA2000 Test conditions ................................................................................................................................. 6 6.4 DEVICE TEST CONDITIONS ............................................................................................................................................ 7 6.5 MULTIPLE TRANSMITTERS AND ANTENNAS SAR EVALUATIONS .................................................................................. 7 6.5.1 Test requirement determination: .......................................................................................................................... 8 6.6 SAR TESTS IN MOUTH AND JAW REGIONS OF THE SAM PHANTOM ............................................................................. 9 7 DESCRIPTION OF THE TEST EQUIPMENT ........................................................................................................... 10 7.1 DOSIMETRIC SYSTEM .................................................................................................................................................. 10 7.2 ADDITIONAL EQUIPMENT NEEDED IN VALIDATION ...................................................................................................... 11 7.3 TISSUE STIMULANTS ................................................................................................................................................... 11 7.4 PHANTOMS DESCRIPTION ............................................................................................................................................ 11 7.5 ISOTROPIC E-FIELD PROBE.......................................................................................................................................... 12 8 SYSTEM VALIDATION ................................................................................................................................................ 13 9 DESCRIPTION OF THE TEST PROCEDURE........................................................................................................... 14 9.1 TEST POSITIONS .......................................................................................................................................................... 14 9.1.1 Initial Ear Position............................................................................................................................................. 14 9.1.2 Cheek Position.................................................................................................................................................... 15 9.1.3 Tilt Position ........................................................................................................................................................ 15 9.1.4 Body Worn Configuration .................................................................................................................................. 16 9.2 SCAN PROCEDURES ..................................................................................................................................................... 16 9.3 SAR AVERAGING METHODS ....................................................................................................................................... 16 10 MEASUREMENT UNCERTAINTY ......................................................................................................................... 17 11 TEST DATA ................................................................................................................................................................. 18 11.1 HEAD SAR TEST RESULTS .......................................................................................................................................... 18 11.2 BODY WORN SAR TEST RESULT ................................................................................................................................ 20 12 LIST OF APPENDIX .................................................................................................................................................. 22 Kyocera Wireless Corp. Page 2 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 1 INTRODUCTION This test report describes an environmental evaluation measurement of specific absorption rate (SAR) distribution in simulated human head tissues exposed to radio frequency (RF) radiation from a wireless portable device manufactured by Kyocera Wireless Corp. (KWC). These measurements were performed for compliance with the rules and regulations of the U.S. Federal Communications Commission (FCC). The testing was performed in accordance with FCC OET Bulletin 65 Supplement C (01/01) and IEEE P1528/D1.2 issued on April 21, 2003. 2 EQUIPMENT UNDER TEST (EUT) The wireless device is described as follows: KYOCERA Corporation KYOCERA SANYO Telecom, Inc. Applicant: 21605 Plummer Street Chatsworth California United States 91311 FCC ID: V65SCP-27H Product: Dual-Band CDMA Phone with Bluetooth Trade Name: Kyocera Wireless Corp. Model Number: SCP-2700 EUT S/N: 2700D306 Type: [X] Identical Prototype, [ ] Pre-production Device Category: Portable RF Exposure Environment: General Population / Uncontrolled Antenna Type: Internal Antenna Location: Bottom Detachable Antenna: No Antenna Dimensions (mm): 42.27(L), 9.33 (W) External Input: Audio/Digital Data Quantity: Quantity production is planned FCC Rule Parts: §22H §24H Modes: 800 CDMA 1900 CDMA Multiple Access Scheme: CDMA CDMA Duty Cycle: 1:1 1:1 TX Frequency (MHz): 824 – 849 1850 - 1910 Emission Designators: 1M25F9W 1M25F9W Conducted Output Power (dBm): 24.5 24.5 Kyocera Wireless Corp. Page 3 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 3 PRODUCT DESCRIPTION The phones V65SCP-27H are Dual-Band CDMA products with Bluetooth. The phones have assisted GPS software feature enabled to meet the emergency location requirements of the FCC’s E911 Phase II mandate. The CDMA architecture is defined as 1900MHz (PCS CDMA) and 800MHz (cellular CDMA). The phone is designed in compliance with the technical specifications for compatibility of mobile and base stations in the Cellular Radio telephone service contained in “Cellular System Mobile Station -Land Station Compatibility Specification” as specified in OET Bulletin 53 and TIA Standards The phone will support certain CDMA2000 radio-configurations (RC) as describes in Exhibit 1 (operation description). 4 ACCESSORIES: KWC Battery Model: 1. Standard – SCP-33LBPS (3.7V, 3.2Wh, 840mAh) Kyocera Wireless Corp. Page 4 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 5 SAR TEST RESULT SUMMARY This device has been tested for localised specific absorption rate (SAR) for uncontrolled environment/general population exposure limits specified in ANSI/IEEE Std. C95.1 ~ 1992 and has been tested in accordance with the measurement procedures specified in IEEE P1528_D1.2. Normal antenna operating positions were incorporated, with the device transmitting at frequencies consistent with normal usage of the device. The device has been shown capable of compliance for localised specific absorption rate (SAR) for uncontrolled environment/general population exposure limits specified in ANSI/IEEE std. C95.1-1992 5.1 Maximum Results Found during SAR Evaluation The equipment is deemed to fulfil the requirements if the measured values are less than or equal to the limit. 5.2 Head Configuration Conducted Device Measured Mode Ch/f(MHz) Power Result (dBm) Position (mW/g) CDMA-800 777 (848.31) 24.59 Right Cheek 1.25 PASSED CDMA-1900 1175 (1908.75) 24.67 Right Cheek 1.16 PASSED Bluetooth-2450 0 (2402) 1.32 Right Cheek 0.023 PASSED 5.3 Body Worn Configuration Conducted Device Measured Mode Ch/f(MHz) Power Result Position (mW/g) (dBm) 22mm Air CDMA-800 383 (836.49) 24.64 0.647 PASSED Gap 22mm Air CDMA-1900 600 (1880) 24.59 0.524 PASSED Gap 22mm Air Bluetooth-2450 0 (2402) 1.32 0.000755 PASSED Gap 5.4 Measurement Uncertainty Combined Uncertainty (Assessment & Source) ± 10.46 Extended Uncertainty (k=2) ± 21.22 Kyocera Wireless Corp. Page 5 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 6 TEST CONDITIONS 6.1 Ambient Conditions All tests were performed under the following environmental conditions: Ambient Temperature: 22 ± 1 Degrees C Tissue simulating liquid temperature: 22 ± 1 Degrees C Humidity: 38 % Pressure: 1015 mB 6.2 RF characteristics of the test site All SAR measurements were performed inside a shielded room that provide isolation from external EM fields. The E-field probes of the DASY 4 system are capable of detecting signals as low as 5µW/g in the liquid dielectric. External fields are minimising by the shielded room, leaving the phone as the dominant radiation source. Two 2-foot square ferrite panels are placed on the floor of the room beneath the phantom area of the DASY system to minimise reflected energy that would otherwise re-enter the phantom and combine constructively or destructively with the desired fields. These ferrite panels provide roughly 12 to 13 dB of attenuation in the frequency range of 900 MHz, and 7 to 8 dB of attenuation in the frequency range of 1.9 GHz. 6.3 Test Signal, Frequencies and Output Power In all operating bands, the measurements were performed on low, mid and high channels. The phone was set to nominal maximum power level during all tests and at the beginning of each test. DASY4 system measures power drift during SAR testing by comparing E-field in the same location at the beginning and at the end of measurement. These records were used to monitor stability of power output. 6.3.1 CDMA2000 Test conditions The device supports CDMA2000 in 1X (Phase I, Protocol revision 6) mode only. CDMA2000 1X includes TIA/EIA-95B as a subset and was approved for publishing in July 1999. It provides voice and data capabilities within a standard 1.25 MHz CDMA channel. This RF bandwidth is identical to the legacy IS-95 B system standard. 6.3.1.1 Head SAR Measurements SAR for head exposure configurations was measured in RC3 with the EUT configured to transmit at full rate using Loopback Service Option SO55. SAR for RC1 was not required when the maximum average output of each channel was less than ¼ dB higher than that measured in RC3. Otherwise, SAR was measured on the maximum output channel in RC1 using the exposure configuration that results in the highest SAR for that channel in RC3. Kyocera Wireless Corp. Page 6 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 6.3.1.2 Body SAR Measurements SAR for body exposure configurations was measured in RC3 with the DUT configured to transmit at full rate on FCH with all other code channels disabled using TDSO / SO32. SAR for multiple code channels (FCH + SCHn) was not required when the maximum average output of each RF channel was less than ¼ dB higher than that measured with FCH only. Otherwise, SAR was measured on the maximum output channel (FCH + SCHn) with FCH at full rate and SCH0 enabled at 9600 bps using the exposure configuration that results in the highest SAR for that channel with FCH only. When multiple code channels were enabled, the DUT output may shift by more than 0.5 dB and lead to higher SAR drifts and SCH dropouts. Body SAR in RC1 was not required when the maximum average output of each channel was less than ¼ dB higher than that measured in RC3. Otherwise, SAR was measured on the maximum output channel in RC1; with Loopback Service Option SO55, at full rate, using the body exposure configuration that resulted in the highest SAR for that channel in RC3. Table 6.3 below shows the maximum power level vs RCs CDMA 800 CDMA 1900 Configuration Ch 1013 Ch 383 Ch 777 Ch 25 Ch 600 Ch 1175 Avg Avg Avg Avg Avg Avg SO2, RC1 Full Rate 24.57 24.64 24.56 24.49 24.58 24.60 SO2, RC3 Full Rate 24.59 24.62 24.58 24.46 24.55 24.66 SO55, RC1 Full Rate 24.56 24.62 24.54 24.48 24.60 24.64 SO55, RC3 Full Rate 24.61 24.68 24.59 24.51 24.62 24.67 TDSO SO32, RC3 (F+SCH) 24.60 24.65 24.56 24.48 24.56 24.63 TDSO SO32, RC3 (-SCH) 24.58 24.64 24.57 24.50 24.59 24.65 Table 6.3 RC Configuration tested at “all up” power control bit. 6.4 Device Test Conditions The EUT was tested with a fully charged battery as supplied with the handset. Conducted RF power measurements were performed before and after each SAR measurements to confirm the output power. 6.5 Multiple Transmitters and Antennas SAR evaluations Licensed transmitters required routine SAR evaluation as followed by IEEE 1528 Supplement C 3G FCC SAR Procedures. Stand-alone SAR measurements were tested for each licensed transmitter and reported. Kyocera Wireless Corp. Page 7 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H For an unlicensed transmitter such as 802.11 a/b/g and Bluetooth devices that does not transmit simultaneously with other transmitters and its output conducted power is < 60/f(GHz) mW, SAR evaluation is not required. If the handset contains unlicensed transmitters which may simultaneously transmit with the licensed transmitter, then SAR evaluation procedures “FCC SAR Considerations for Handsets with Multiple Transmitters and antennas, February 2008” were followed. Antenna separation was determined by the closest distance between the antennas. The conducted output power of the unlicensed transmitter was measured and compared with the power reference (Pref) as shown in table 6.5. Both criteria were evaluated to determine whether stand-alone SAR or simultaneous transmission SAR testing is required. SIMULTANEOUS TRANSMISSION Antenna Separation Pref (cm) Bluetooth (2.45GHz) ≤ 2.5 NA / Standalone SAR Required > 2.5 and ≤ 5.0 12 mW > 5.0 24 mW Table 6.5 Antenna Separation and Unlicensed Transmitter Output Power Threshold 6.5.1 Test requirement determination: Based on the Antenna separation and output power, Stand-Alone and Simultaneous Transmission SAR testing requirements are listed below: MEASURED PARAMETERS (UNLICENSED TRANSMITTER) Transmitter Antenna Output Power Highest SAR value Separation (CDMA transmitter + Bluetooth transmitter) Bluetooth 1.984 cm 1.36 mW 1.273 mW/g SAR PROCEDURES TEST REQUIRED Stand Alone SAR: Yes Simultaneous Transmission SAR: No Kyocera Wireless Corp. Page 8 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 6.6 SAR Tests in Mouth and Jaw Regions of the SAM Phantom Antennas located near the bottom of a phone may require SAR measurements around the mouth and jaw regions of the SAM head phantom. This typically applies to clam-shell style phones that are generally longer in the unfolded normal use positions or to certain older style long rectangular phones. It has been known for some time that there are SAR measurement difficulties in these regions of the SAM phantom. SAR probes are calibrated in tissue-equivalent liquids with sufficient separation between the probe sensors and nearby physical boundaries to ensure scattering does not affect probe calibration. When the probe tip is moved into tight regions with multiple boundaries surrounding its sensors, probe calibration and measurement accuracy can become questionable. In addition, these measurement locations often require a probe to be tilted at steep angles, where it may no longer comply with calibration requirements and measurement protocols, or satisfy the required measurement uncertainty. In some situations it is not feasible to tilt the probe or rotate the phantom, as suggested by measurement standards, to conduct these measurements. In order to ensure there is sufficient conservativeness for ensuring compliance until practical solutions are available, additional measurement considerations are necessary to address these technical difficulties. When measurements are required near the mouth, nose, jaw or similar tight regions of the SAM phantom, area or zoom scans are often unable to fully enclose the peak SAR location as required by IEEE 1528 and Supplement C, due to probe orientation and positioning difficulties. Even when limited measurements are possible, the test results could be questionable due to probe calibration and measurement uncertainty issues. Under these circumstances, the following procedures apply: The SAR required in these regions of SAM should be measured using a flat phantom. • Rectangular shaped phones should be positioned with its bottom edge positioned from the flat phantom with the same distance provided by the cheek touching position using SAM. The ear reference point (ERP, as defined for SAM) of the phone should be positioned ½ cm from the flat phantom shell. • Clam-shell phones should be positioned with the hinge against a smooth edge of the flat phantom where the upper half of the phone is unfolded and extended beyond the phantom side wall. The lower half of the phone is secured in the test device holder at a fixed distance below the flat phantom determined by the minimum separation along the lower edge of the phone in the cheek touching position using SAM. If there is substantial variation in separation distance along the lower edge of a clam- shell phone when placed in the cheek touching position using SAM, the FCC Laboratory may be contacted for additional guidance to position the phone for testing. The flat phantom data should allow test results to be compared uniformly across measurement systems, until suitable solutions are available in measurement standards to address certain probe calibration and positioning issues, due to implementation differences between horizontal and up- right SAM configurations. These flat phantom procedures are only applicable to stand-alone SAR evaluation in tight regions of the SAM phantom, where measurement is not feasible or test results can be questionable due to probe calibration and accessibility issues. Details on device positioning and photos showing how separation distances are determined should be included in the SAR report. SAR for other regions of the head must be evaluated using SAM; therefore, a phone with antennas at different locations may require flat and SAM phantom evaluation for the different antennas. When simultaneous transmission SAR evaluation is necessary in these regions of SAM and until practical solutions are available, the FCC Laboratory should be contacted for interim guidance. Kyocera Wireless Corp. Page 9 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 7 DESCRIPTION OF THE TEST EQUIPMENT 7.1 Dosimetric System The measurements were performed with an automated near-field scanning system (as shown in Figure 7.1), DASY4, manufactured by Schmid & Partner Engineering AG (SPEAG) of Zurich, Switzerland. The system is comprised of high precision robot, robot controller, computer, near-field probe, probe alignment sensor and the SAM phantom containing brain or muscle equivalent material. The overall RSS uncertainty of the measurement system is ±10.46% with an expanded uncertainty of ±21.22% (K=2). The measurement uncertainty budget is given in section 10. Below is a list of the calibrated equipment used for the measurements: Test Equipment Serial Number Cal. Due Date DASY4 DAE4 602 06-25-09 E-field Probe ET3DV6 1664 06-23-09 E-field Probe ES3DV3 3078 06-23-09 Dipole Validation kit, D835V2 467 09-16-09 Dipole Validation kit, D1900V2 5d016 09-15-09 Dipole Validation kit, D2450V2 776 04-22-09 The calibration records of E-field probe and dipoles are attached in Appendix C and Appendix D respectively. Figure 7.1 DASY 4 System Kyocera Wireless Corp. Page 10 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 7.2 Additional equipment needed in validation Test Equipment Serial Number Cal. Due Date Communication Test Set Agilent 8960 GB44052736 06-03-10 Signal Generator, Agilent ESG-D3000A US37231039 04-05-09 Power meter, Giga-tronics 8541C 1833726 03-26-09 Power Sensor, Giga-tronics 80601A 1831776 04-07-09 Serial Network Analyzer, Agilent E5062A MY44100250 02-05-09 Electronic Calibration Module, Agilent 1763 02-14-09 Thermometer 186700 06-10-09 Dielectric Probe, HP 85070E -- No cal required 7.3 Tissue Stimulants All dielectric parameters of tissue stimulants were measured within 24 hours of SAR measurements. The depth of the tissue stimulant in the ear reference point and flat reference point of the phantom were at least 15 cm. during all the tests. The depth of the liquid is measured by running a program that brings the probe to the bottom surface of the phantom then raise it up 15 centimeters. The operator at this point performs a visual inspection and makes sure that the liquid level is at or above the probe tip. The list of ingredients and the percent composition used for the Head and Muscle tissue simulates are listed in the table below: 835 MHz 1900 MHz 2450MHz Ingredient HEAD MUSCLE HEAD MUSCLE HEAD MUSCLE Water 51.07% 65.45% 54% 69.91% 55 % 68.64% Cellulose 0.23% -- -- -- -- -- Glycol monobuthyl -- -- 44.91% 29.96% 45% 31.37% Sugar 47.31% 34.31% -- -- -- -- Preventol 0.24% 0.1% -- -- -- -- Salt 1.15% 0.62% 0.21% 0.13% -- -- The ingredients above are adopted from Application Note: Recipes for Head/Muscle Tissue Simulating Liquid by SPEAG. 7.4 Phantoms Description SAM v4.0 phantom, manufactured by SPEAG, was used during the measurement. It has fiberglass shell integrated in a wooden table. The shape of the shell corresponds to the phantom defined in IEEE 1528/D1.2. It enables the dosimetric evaluation of left and right hand phone usage as well as body mounted usage at the flat phantom region. Reference markings on the phantom allow the complete set-up of all predefined phantom positions and measurement grids by manually teaching three points in the robot. The thickness of phantom shell is 2mm except for the ear, where an integrated ear spacer provides 6mm spacing from the tissue boundary. Manufacturer reports tolerance in shell thickness to be ± 0.1mm. Kyocera Wireless Corp. Page 11 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 7.5 Isotropic E-Field Probe Model: • ET3DV6 • Symmetrical design with triangular core • Built-in optical fiber for surface detection system Construction: • Built-in shielding against static charges • PEEK enclosure material (resistant to organic solvents, e.g., glycol) Calibration: • Calibration certificate in Appendix C • 10MHz to 3GHz (dosimetry); Linearity: ± 0.2dB (30MHz to Frequency: 3GHz) Optical Surface: • ± 0.2mm repeatability in air and clear liquid over diffuse reflecting Detection: • Surface Directivity: • ± 0.2dB in HSL (rotation around probe axis) • ± 0.4dB in HSL (rotation normal to probe axis) Dynamic Range: • 5 uW/g to > 100 mW/g; Linearity: ± 0.2dB • Overall length: 330mm • Tip length: 16mm Dimensions: • Body diameter: 12mm • Tip diameter: 6.8mm • Distance from probe tip to dipole centers: 2.7mm • General dosimetry up to 3GHz Application: • Compliance tests of mobile phones • Fast automatic scanning in arbitrary phantoms. Kyocera Wireless Corp. Page 12 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 8 SYSTEM VALIDATION The probes are calibrated annually by the manufacturer. Dielectric parameters of the stimulating liquids are measured with an automated Hewlett Packard 85070E dielectric probe in conjunction with an Agilent E5062A ENA serial network analyser. The SAR measurements of the device were done within 24 hours of system accuracy verification, which was done using the dipole validation kit. Power level of 20dBm was supplied to a dipole antenna placed under the flat section of SAM phantom. The validation results are in the table below and printouts of the validation test are attached in Appendix A. All the measured parameters are within the specification. The system validation with head tissues was used for the device testing in muscle. Based on OET 65 Supplement C EAB Part 22/24 SAR review Reminder Sheet 01/2002, this is a valid test. Dielectric Validation Parameters Comments Freq. SAR Temp. Test Tissue (MHz) Description (mW/g), 1g εr σ o ( C) date Validation testing - (S/m) Measured 0.922 42.06 0.908 22±1 12-09-08 For device testing in Head. SPEAG 0.940 41.20 0.880 22.0 09-16-08 From Speag Certificate 835 Reference FCC -- 41.50 0.900 20-26 -- Reference* Measured 4.07 39.36 1.45 22±1 12-10-08 For device testing in Head. SPEAG 4.12 40.70 1.47 22.0 09-15-08 From Speag Certificate Head 1900 Reference FCC -- 40.00 1.40 20-26 -- Reference* For device testing in Head Measured 5.55 39.43 1.84 22±1 12-11-08 and Muscle. SPEAG 2450 5.48 39.40 1.84 22.0 04-22-08 From Speag Certificate Reference FCC -- 39.20 1.80 20-26 -- Reference* Measured 0.972 55.66 0.981 22±1 12-09-08 For device testing in Muscle SPEAG 0.996 53.30 1.01 22.0 09-16-08 From Speag Certificate Reference 835 FCC -- 55.20 0.970 -- -- Reference* Muscle Measured 4.16 52.15 1.49 22±1 12-10-08 For device testing in Muscle SPEA 4.08 52.10 1.60 22.0 09-15-08 From Speag Certificate 1900 Reference FCC -- 53.30 1.52 20-26 -- Reference* FCC reference values are adopted from OET Bulletin 65 (97-01) Supplement C (01-01). Kyocera Wireless Corp. Page 13 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 9 DESCRIPTION OF THE TEST PROCEDURE Measurements were made on both left hand side and right hand side of the phantom. The device was position against phantom according to OET Bulletin 65 (97-01) Supplement C (01-01). Definitions of terms used in aligning the device to a head phantom are available in IEEE Standard P1528/D1.2 “Recommended Practice for Determining the Spatial-Peak Specific Absorption Rate (SAR) in the Human Body Due to Wireless Communications Devices: Experimental Techniques” 9.1 Test Positions The device was placed in the holder. The bottom of the device aligns with the bottom of the holder clamp to provide a standard positioning and ensure enough free space for antenna. Device holder was provided by SPEAG together with DASY4. 9.1.1 Initial Ear Position The device was initially positioned with the earpiece region pressed against the ear spacer of a head phantom parallel to the “Neck-Front” (N-F) line defined along the base of the ear spacer that contains the “Ear Reference Point” (ERP). The “test device reference point” (point A) is aligned to the ERP on the head phantom and the “vertical centerline” is aligned to the “phantom reference plane”. vertical center line wt/2 wt/2 . horizontal line A acoustic output B bottom of handset wb/2 wb/2 Figure 7-1 – Handset vertical and horizontal Figure 7-2 - Close up side view of phantom reference lines. showing the ear region. Kyocera Wireless Corp. Page 14 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 9.1.2 Cheek Position “Initial ear position” alignments are maintained and the device is brought toward the mouth of the head phantom by pivoting along the “Neck-Front” line until any point on the display, keypad or mouthpiece portions of the handset is in contact with the phantom or when any portion of a foldout, sliding or similar keypad cover opened to its intended self-adjusting normal use position is in contact with the cheek or mouth of the phantom. Figure 7.3 - Phone position 1, “cheek” or “touch” position. 9.1.3 Tilt Position In the “cheek position”, if the earpiece of the device is not in full contact with the phantom’s ear spacer and the peak SAR location for the “cheek position” is located at the ear spacer region or corresponds to the earpiece region of the handset, the device is returned to the “initial ear position” by rotating it away from the mouth until the earpiece is in full contact with the ear spacer. Otherwise, the device is moved away from the cheek perpendicular to the line passes through both “ear reference points” for approximate 2-3cm. While it is in this position, the device is tilted away from the mouth with respect to the “test device reference point” by 15o. After the tilt, it is then moved back toward the head perpendicular to the line passes through both “ear reference point” until the device touches the phantom or the ear spacer. If the antenna touches the head first, the positioning process is repeated with a tilt angle less than 15o so that the device and its antenna would touch the phantom simultaneously. Figure 7.3 - Phone position 2, “tilted” position. Kyocera Wireless Corp. Page 15 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 9.1.4 Body Worn Configuration KWC body worn accessories were tested for the FCC RF exposure compliance. The device was positioned into the carrying case and placed below the flat phantom. Hands-free headset was connected during measurements. The SAR levels were also measured with 22mm air space for the hands-free application, which allow user to use other body-worn accessories that contains no metal and provides at least 15mm separation from the closest point of the handset to the body. 9.2 Scan Procedures First, coarse scans are used for a quick determination of the field distribution. Then an area scan measures all reachable points, it computes all of the field maxima found in the scanned area, within a range of 2dB as specified in IEEE P1528, (see the configuration below). For cases where multiple maxima were detected, the number of zoom scans could be increased accordingly. Next a cube scan, 7x7x7 points (spacing between each point is 5x5x5mm), is performed around the highest E-field value to determine the averaged SAR-distribution over 1g. If two peaks are within 2dB of the highest one, two zoom scans are performed to provide the evaluations. A fine resolution volume scan determines the one-gram average SAR for both peaks. 9.3 SAR Averaging Methods The maximum SAR value is average over its volume using interpolation and extrapolation. The interpolation of the points is done with a 3d-Spline. The 3d-Spline is composed of three one- dimensional splines with the “Not a knot” –condition [W. Gander, Computermathematik, p. 141-150] (x, y and z – directions) [numerical Recipes in C, Second Edition, p 123]. The extrapolation is based on least square algorithm [W. Gander, Computermathematik, p. 168-180]. Through the points in the first 30mm in all z-axis, polynomials of order four are calculated. This polynomial is then used to evaluate the points between the surface and the probe tip. The points, calculated from the surface, have a distance of 1mm from one another. Kyocera Wireless Corp. Page 16 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 10 MEASUREMENT UNCERTAINTY Description of individual measurement uncertainty Uncert. Stand. Uncert Prob. Ci1 Vi2 or Uncertainty Description Value Div (1g) Dist. 1g Veff (± %) (±%) Measurement system Probe calibration 4.8 N 1 1 4.8 ∞ Axial isotropy 4.7 R √3 0.7 1.9 ∞ Hemispherical Isotropy 9.6 R √3 0.7 3.9 ∞ Boundary effects 1.0 R √3 1 0.6 ∞ Linearity 4.7 R √3 1 1.0 ∞ System Detection limit 1.0 R √3 1 0.5 ∞ Readout Electronics 1.0 N 1 1 1.0 ∞ Response Time 0.8 R √3 1 0.5 ∞ Integration Time 2.6 R √3 1 1.5 ∞ RF ambient conditions 3.0 R √3 1 1.7 ∞ Mech. Constrains of robot 0.4 R √3 1 0.2 ∞ Probe positioning 2.9 R √3 1 1.7 ∞ Extrapolation, integration and Integration 1.0 R √3 1 0.6 ∞ Algorithms for Max. SAR Evaluation Test Sample Related Device positioning 3.0 N 1 1 3.0 ∞ Device Holder 3.0 N 1 1 3.0 ∞ Power drift 7.0 N √3 1 4.0 ∞ Phantom and setup Phantom uncertainty 4.0 R √3 1 2.3 ∞ Liquid conductivity (target) 5.0 R √3 0.6 1.7 ∞ Liquid conductivity (meas.) 5.0 N 1 0.6 3.0 ∞ Liquid permittivity (target) 5.0 R √3 0.6 1.7 ∞ Liquid permittivity (meas.) 5.0 N 1 0.6 1.5 ∞ Combined Standard Uncertainty: 10.46 Extended Standard Uncertainty (k=2): 21.22 N: Normal R: Rectangular Kyocera Wireless Corp. Page 17 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 11 TEST DATA 11.1 Head SAR Test Results The following tables list the SAR results in each configuration and operating mode. The channels tested for each configuration have similar SAR distributions. Highest SAR (bold blue color) plots for each configuration is provided in Appendix B. CDMA 800 Channel: 1013 383 777 HEAD Frequency (MHz): 824.70 836.49 848.31 Antenna Configuration Test Position Battery SAR, 1g (W/kg) Position Left Cheek/Touch Standard Fixed 0.882 1.13 1.22 Left Ear/Tilt Standard Fixed 0.594 RC3-SO55 Right Cheek/Touch Standard Fixed 0.900 1.17 1.25 Right Ear/Tilt Standard Fixed 0.627 CDMA 1900 Channel: 25 600 1175 HEAD Frequency (MHz): 1851.25 1880 1908.75 Antenna Configuration Test Position Battery SAR, 1g (W/kg) Position Left Cheek/Touch Standard Fixed 0.772 0.924 1.02 Left Ear/Tilt Standard Fixed 0.428 RC3-SO55 Right Cheek/Touch Standard Fixed 0.994 1.11 1.16 Right Ear/Tilt Standard Fixed 0.326 Note: If the SAR measured at the mid-channel is at least 3dB lower than the SAR limit, testing at the low and high channels were no longer performed. Kyocera Wireless Corp. Page 18 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H Channel: 0 39 78 Bluetooth 2450Mhz Frequency (MHz): 2402 2441 2480 HEAD Conducted Power (dBm): 1.32 0.47 0.03 Antenna Configuration Test Position Battery SAR, 1g (W/kg) Position Bluetooth ** Left Cheek/Touch Standard Fixed 0.00357 Bluetooth ** Right Cheek/Touch Standard Fixed 0.023 ** Tested at worst position and if the SAR measured at the highest conducted power is at least 3dB lower than the SAR limit, testing at the other channels were no longer performed. Kyocera Wireless Corp. Page 19 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 11.2 Body Worn SAR Test Result For each mode, corresponding SAR distribution printouts of maximum results per set-up (in blue below), i.e., the device was tested with a 15mm air gap or with KWC leather case are shown in Appendix B. The rest of SAR distributions is substantially similar or equivalent to the plots submitted regardless of used channel. Only the worst-case result was reported. Waist Level SAR with KWC Body Worn Accessories CDMA 800 Channel: 1013 383 777 BODY Frequency (MHz): 824.70 836.49 848.31 Test Flip Phone Accessory Configuration SAR, 1g (W/kg) Position Position Position RC3 – SO32 Face Flat Open 0.647 (FCH) Down Air Gap – 22mm RC3 – SO32 Flat Open Face Up 0.548 (FCH) CDMA 1900 Channel: 25 600 1175 BODY Frequency (MHz): 1851.25 1880 1908.75 Test Flip Phone Accessory Configuration SAR, 1g (W/kg) Position Position Position RC3 – SO32 Face Flat Open 0.524 (FCH) Down Air Gap – 22mm RC3 – SO32 Flat Open Face Up 0.226 (FCH) Note: If the SAR measured at the mid-channel is at least 3dB lower than the SAR limit, testing at the low and high channels were no longer performed. . Kyocera Wireless Corp. Page 20 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H Channel: 0 39 78 Bluetooth 2450Mhz Frequency (MHz): 2402 2441 2480 BODY Conducted Power: 1.32 0.47 0.03 Test Flip Phone Accessory Configuration SAR, 1g (W/kg) Position Position Position Face Air Gap –22mm Bluetooth ** Flat Open 0.000429 Down Air Gap –22mm Bluetooth ** Flat Open Face Up 0.000755 ** Tested at worst position and if the SAR measured at the highest conducted power is at least 3dB lower than the SAR limit, testing at the other channels were no longer performed. Kyocera Wireless Corp. Page 21 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.

FCC ID: V65SCP-27H 12 LIST OF APPENDIX Appendix Description Note A Validation Test Plots Please see separate attachment B SAR Distribution Plots Please see separate attachment C Probe Calibration Parameters Please see separate attachment D Dipole Calibration Parameters Please see separate attachment E EUT Setup Photos Please see separate attachment Kyocera Wireless Corp. Page 22 of 22 Report #: KWC-V65-2sar-1208-R0 This report shall not be reproduced except in full, without the written consent of Kyocera Wireless Corp.


Document Created: 2009-01-16 09:44:35
Document Modified: 2009-01-16 09:44:35
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