LCS190923018AEB_SAR_REPORT_2

FCC ID: O55503719

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COMOSAR E—Field Probe Calibration Report Ref : ACR.281.2.18.SATU.A SHENZHEN LCS COMPLIANCE TESTING LA BORATORY LTD. 1F., XINGYUAN INDUSTRIAL PARK, TONGDA ROAD, BAO‘AN BLVD BAO‘AN DISTRICT, SHENZHEN, GUANGDONG, CHINA MVG COMOSAR DOSIMETRIC E—FIELD PROBE SERIAL NO.: SN 31/17 EPGO324 Calibrated at MVG US 2105 Barrett Park Dr. — Kennesaw, GA 30144 $ ng 14@\\? ACCREDITED Toh uks romenmerengrerznss Calibration Date: 10/08/2018 ie ‘ ;SIUHIHHI}'.‘ | This document presents the method and results from an accredited COMOSAR Dosimetric E—Field Probe calibration performed in MVG USA using the CALISAR / CALIBAIR test bench, for use with a COMOSAR system only. All calibration results are traceable to national metrology ‘ institutions

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB mvgq COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A Name Function Date Signature Prepared by : Jérome LUC Product Manager 10/8/2018 fi Checked by : Jérome LUC Product Manager 10/8/2018 fi/ Approved by : Kim RUTKOWSKI Quality Manager 10/8/2018 fum PutthowiPd Customer Name Shenzhen LCS Distribution : Compliance Testing Laboratory Ltd. Issue Date Modifications A 10/8/2018 Initial release Page: 2/10 This document shall not be reproduced, except infull orin part, without the written approval ofMVG. The information contained herein is to be used onlyfor the puposefor whichit is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 74 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB nc COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A TABLE OF CONTENTS 1 DeVi@@ UNG@P T@St ... 0000000 meemeeee n en en en neneeee en en en nee en en ennerne en ererne en 4 2 PFOGUCt D@SCMIDMOM ..... ... ... .ccscc meenenemenmnenenemeemn en en en en erne en eren en eneenee nc es 4 2.1 General Information 4 3 MEASU@ME@Nt MtROG ............ .l iesecee mm mmmmmeemememmeerenmemeemenenneenmnerneenneene en en eneeneeees 4 3.1 Linearity 4 3.2 Sensitivity 5 3.3 Lower Detection Limit 5 3.4 Isotropy 5 3.3 Boundary Effect 3 t MCASUM@MANUUINCENAIALY :——mmmmmmmmmmmmrnemcrmecommenmmescmonmmamenmemmnim 3 $ Calibration Messurement ReSUIS : ——mmmummmmemmemmmmmmmmmnnemenmmoenmeanuns 6 5.1 Sensitivity in air 6 5.2 Linearity 7 5.3 Sensitivity in liquid 7 5.4 Isotropy 8 6. Tistrof EQUIPMENE ——mmmmummmenmmenpemonnanmmnmmmenmonmememmemenemenren 10 Page: 3/10 This document shall not be reproduced, except infull orin part, without the written approval ofMVG. The information contained herein is to be used onlyfor the puposefor whichit is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 75 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A 1 DEVICE UNDER TEST Device Under Test Device Type COMOSAR DOSIMETRIC E FIELD PROBE Manufacturer MVG Model SSE2 Serial Number SN 31/17 EPGO324 Product Condition (new / used) New Frequency Range of Probe 0.15 GHz—6GHz Resistance of Three Dipoles at Connector Dipole 1: R1=0.189 MQ Dipole 2: R2=0.203 MQ Dipole 3: R3=0.218 MQ A yearly calibration interval is recommended. 2 PRODUCT DESCRIPTION 2.1 GENERAL INFORMATION MVG‘s COMOSAR E field Probes are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEIVIEC 62209 standards. Figure 1 —MVG COMOSAR Dosimetric Efield Dipole Probe Length 330 mm Length of Individual Dipoles 2 mm Maximum extemal diameter 8 mm Probe Tip Extemal Diameter 2.5 mm Distance between dipoles / probe extremity 1 mm 3 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEIIEC 62209 standards provide recommended practices for the probe calibrations, including the performance characteristics of interest and methods by which to assess their affect. All calibrations / measurements performed meet the fore mentioned standards. 3.1 LINEARITY The evaluation of the linearity was done in free space using the waveguide, performing a power sweep to cover the SAR range 0.01 W/kg to 100W/kg. Page: 4/10 This documentshall not be reproduced, except in full or in part, without the written approval ofMVG. The information contained herein is to be used onlyfor the purposefor which it is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenzhen LCS Compliance Testing Laboratory Ltd. Page 76 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A 3.2 SENSITIVITY The sensitivity factors of the three dipoles were determined using a two step calibration method (air and tissue simulating liquid) using waveguides as outlined in the standards. 3.3 LOWER DETECTION LIMIT The lower detection limit was assessed using the same measurement set up as used for the linearity measurement. The required lower detection limit is 10 mW/kg. 3.4 ISOTROPY The axial isotropy was evaluated by exposing the probe to a reference wave from a standard dipole with the dipole mounted under the flat phantom in the test configuration suggested for system validations and checks. The probe was rotated along its main axis from 0 — 360 degrees in 15 degree steps. The hemispherical isotropy is determined by inserting the probe in a thin plastic box filled with tissue—equivalent liquid, with the plastic box illuminated with the fields from a half wave dipole. The dipole is rotated about its axis (0°—180°) in 15° increments. At each step the probe is rotated about its axis (0%—360°). 3.5 BOUNDARY EFFECT The boundary effect is defined as the deviation between the SAR measured data and the expected exponential decay in the liquid when the probe is oriented normal to the interface. To evaluate this effect, the liquid filled flat phantom is exposed to fields from either a reference dipole or waveguide. With the probe normal to the phantom surface, the peak spatial average SAR is measured and compared to the analytical value at the surface. 4 MEASUREMENT UNCERTAINTY The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEMIEC 62209 standards were followed to generate the measurement uncertainty associated with an E—field probe calibration using the waveguide technique. All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. Uncertainty analysis of the probe calibration in waveguide Uncertainty Probability hor 4 Standard ERREOR SOURCES value (%) Distribution sisor C Uncertainty (%) Incident or forward power 3.00% Rectangular \/?: | 1 1.732% Reflected power 3.00% Rectangular \/g | 3 1.732% Liquid conductivity 5.00% Rectangular \/?: | 1 2.887% Liquid permittivity 4.00% Rectangular \/g | l 2.309% Field homogeneity 3.00% Rectangular \/5 ‘ 3 1.732% Field probe positioning 5.00% Rectangular \6 | 1 2.887% Page: 5/10 This documentshall not be reproduced, except in full or in part, without the written approval ofMVG. The information contained herein is to be used onlyfor the purposefor which it is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenzhen LCS Compliance Testing Laboratory Ltd. Page 77 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB mvgq COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A Field probe linearity 3.00% Rectangular \6 | 1 1.732% Combined standard uncertainty 5.831% Expanded uncertainty 12.0% 95 %confidence level k= 2 C * 5 CALIBRATION MEASUREMENT RESULTS Calibration Parameters Liquid Temperature 21°C Lab Temperature 21°C Lab Humidity 45 % 5.1 SENSITIVITY IN ARR Normx dipole Normy dipole Normz dipole 1 (uV/(V/m)) 2 (uV/(V/m)) 3 (uV/(V/m)) 0.80 0.83 0.68 DCP dipole 1 DCP dipole 2 DCP dipole 3 (mV) (mV) (mV) 95 90 93 Calibration curves ei=f(V) (i=1.2,3) allow to obtain H—field value using the formula: E=fE/ +E," +E," Calibration curves 63— ces so0— z_ € 400 § // Dipole 1 72 Dipole 2 © ong & Dipcle 3 100 ,/ . ooo oor omm o0 on 010 ; 013 Voltage (V) Page: 6/10 This document shall not be reproduced, except infull orin part, without the written approval ofMVG. The information contained herein is to be used onlyfor the puposefor whichit is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 78 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB mvG COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A 5.2 LINEARITY Linearity 1.00— 0.76 0.50 Linearity Enior (dB) 0.25 0.00— A.25— .50 0.76 4.007, 0 00 qs0 ato 250 ado sto E—Field (V/m) LinearityI+/1 13% (++0.050B 5.3 SENSITIVITY IN LQUID Liquid Frequency Permittivity Epsilon (S/m) ConvF MHz +/— 100MHz) HL450 450 42.17 0.86 1.56 BL450 450 57.65 0.95 1.60 HL750 750 40.03 0.93 1.45 BL750 750 56.83 1.00 1.50 HL850 835 42.19 0.90 1.55 BL850 835 54.67 1.01 1.59 HL900 900 42.08 1.01 1.54 BL900 900 55.25 1.08 1.60 HL1800 1800 41.68 1.46 1.65 BL1800 1800 53.86 1.46 1.68 HL1900 1900 38.45 1.45 1.86 BL1900 1900 §1322 1.56 1.93 HL2000 2000 38.26 1.38 1.83 BL2000 2000 52.170 1.51 1.89 HL2300 2300 39.44 1.62 1.95 BL2300 2300 54.52 117 2.01 HL2450 2450 37.50 1.80 1.91 BL2450 2450 5322 1.89 1.95 HL2600 2600 39.80 1.99 1.89 BL2600 2600 5252 2.23 1.94 HL5200 5200 35.64 4.67 1.50 BL5200 5200 48.64 5.51 1.56 HL5400 5400 36.44 4.87 1.44 BL5400 5400 46.52 5.71 1.47 HL 5600 5600 36.66 5.17 1.48 BL5600 5600 46.179 5.77 1.53 HL 5800 5800 35.31 5.31 1.50 BL5800 5800 47.04 6.10 1.55 LOWER DETECTION LIMIT: ImW/kg Page: 7/10 This document shall not be reproduced, except infull orin part, without the written approval ofMVG. The information contained herein is to be used onlyfor the puposefor whichit is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 79 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB mvG COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A 5.4 ISOTROPY HL900 MHz — Axial isotropy: 0.05 dB — Hemispherical isotropy: 0.07 dB isotropy curves 06 t o« «= 02 0 02 04 06 08 104 fo a8 as o+! g2 co o2 or os 08 10i HL1800 MHz — Axial isotropy: 0.06 dB — Hemispherical isotropy: 0.07 dB isotropy curves Dirole a0 Dicole 30 Deole at 10 to as os o« o2 oo oz o+ os os to Page: 8/10 This document shall not be reproduced, except infull orin part, without the written approval ofMVG. The information contained herein is to be used onlyfor the puposefor whichit is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 80 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB I nVvG COMOSAR E—FIELD PROBE CALIBRATION REPORT Ref: ACR.281.2.18.SATU.A HLS600 MHz — Axial isotropy: 0.06 dB — Hemispherical isotropy: 0.10 dB Isotropy curves 404 V fo as os o1 92 c0 o2 or os os 10 Page: 9/10 This document shall not be reproduced, except infull orin part, without the written approval ofMVG. The information contained hereinis to be used onlyfor the puposefor whichit is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 81 of 144

SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. FCC ID: 055503719 Report No.: LCS190923018AEB Ref: ACR.281.2.18.SATU.A LDAC COMOSAR E—FIELD PROBE CALIBRATION REPORT 6 LIST OF EQUIPMENT Equipment Summary Sheet Equipment Manufacturer / Identification No. Current Next Calibration Description Model ‘| Calibration Date Date Flat Phantom mve SW306g.gamy, NValldaled required. Noewal mlldalec required. No: cal . Validated. No cal Validated. No cal COMOSAR Test Bench Version 3 NA required. required. Network Analyzer Rhodeg‘vsAChwa'z SN100132 o22o16 022019 Reference Probe MVG EP 94 SN 37/08 10/2017 10/2019 Multimeter Keithley 2000 1188656 01/2017 01/2020 Signal Generator Agilent E4438C MY49070581 01/2017 01/2020 ie Characterized prior to \Characterized prior to Ampilfier Aethersomins $NO4s test. No cal required. |test. No cal required. Power Meter HP E4418A US38261498 01/2017 01/2020 Power Sensor HP ECP—E26A US37181460 01/2017 01/2020 Directional Coupler Narda 4216—20 o1386 Characterized pripr to |Characterized priprto test. No cal required. |test. No cal required. Waveguide Mega Industries Osgy7—158.13.742 required. Validated. No cal Validated. required. No cal Waveguide Transition Mega Industries Osgy7—158.13.701 required. Validated. No cal Validated. required. No cal Waveguide Termination| Mega Industries Osgy7—158—13.701 Validated. required. No cal Validated. required. No cal Temperature / HUMIIIRY|— control Company ensor 150798832 112017 1112020 Page: 10/10 This document shall not be reproduced, except infull or in part, without the written approval ofMVG. The information contained herein is to be used onlyfor the puposefor which it is submitted and is not to be released in whole orpart without written approval ofMVG. This report shall not be reproduced except in full, without the written approval of Shenthen LCS Compliance Testing Laboratory Ltd. Page 82 of 144

(/(.\ SATIMO The microwave vision company_A SAR Reference Dipole Calibration Report Ref : ACR.287.3.14.SATU.A SHENZHEN LCS COMPLIANCE TESTING LABORATORY LTD. 1F., XINGYUAN INDUSTRIAL PARK, TONGDA ROAD, BAO‘AN BLVD BAO‘AN DISTRICT, SHENZHEN, GUANGDONG, CHINA SATIMO COMOSAR REFERENCE DIPOLE FREQUENCY: 750 MHZ SERIAL NO.: SN 07/14 DIP 0G750—302 Calibrated at SATIMO US 2105 Barrett Park Dr. — Kennesaw, GA 30144 w¥ 0pe e CR S\ /z Tz ZrAanS (accrebitep CUAaj Wwluk®® cafttrationcent szz0e02 10/01/2018 Summary: This document presents the method and results from an accredited SAR reference dipole calibration performed in SATIMO USA using the COMOSAR test bench. All calibration results are traceable to national metrologyinstitutions.

Ref: ACR.287.3.14.SATU.A sArImo SAR REFERENCE DIPOLE CALIBRATION REPORT Name Function Date Signature Prepared by: Jérome LUC Product Manager 10/14/2018 2/5’ Checked by : Jérome LUC Product Manager 10/14/2018 //%/ Approved by : Kim RUTKOWSKI Quality Manager 10/14/2018 Jum Pautthowh? Customer Name Shenzhen LCS Distribution : Compliance Testing Laboratory Ltd. Issue Date Modifications A 10/14/2018 Initial release Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval ofSATIMO. The information contained herein is to be used onlyforthe purposefor which it is submitted and is not to be released in whole orpart without written approval ofSATIMO. = mes csw

(( [ \ SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR287 3.14.SATU.A sArImo TABLE OF CONTENTS ) IMfOducHO®:—mmmeormmmnmenememrmmmmnareroemenrarerermmarnmenmmemymmonmmernmnm 4 B DCVIC@ URCCF TESE ... ... s cmemimecmmmmmmmnnmncrmensecirmmmecmnnemmntrenmrermmrocremnmmmsnteernnccnczcne 4 3 PFOUUGCE DeSCFIPLION ——.. vemmememmmmommenmmmenmmnmiereemmenenenmmmmeminmmmnrnememenisiimmmercer 4 3.1 General Information 4 #: MeASUROMeNENCHAIOU —:——+—msmemscommmrenecncerormemiermsnctisesmemseretemecmmetimmmemisrime $ 4.1 Return Loss Requirements 5 4.2 Mechanical Requirements 5 5 MEASUT@ME@Nt UNCETEANEY ... ... en eeemmeemeememeeeeeee n n en en en ernernenneernernerne en en enene. 5 5.1 Return Loss $ 5.2 Dimension Measurement § 5.3 Validation Measurement 5 6 CalibrAtiON MEASUT@MENE RESUIS .............2.nene e en en reeneeneemneeneen e 6 6.1 Return Loss and Impedance 6 6.2 Mechanical Dimensions 6 7 Validation measurement ... 7.1 Head Liquid Measurement 7 7.2 SAR Measurement Result With Head Liquid 7 7.3 Body Liquid Measurement 9 7.4 SAR Measurement Result With Body Liquid 9 LAE OT EqUHDMIGME : 000000 rrmomevormmsecrroreeoeroremeerememrmeeaecararanmmmyrerares §1 50 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval ofSATIMO. The information contained herein is to be used onlyforthe purposefor which it is submitted and is not to be released in whole orpart without written approval ofSATIMO. t ces csw —

((( \ SAR REFERENCE DIPOLE CALIBRATION REPORT KiMexesioAugatodt 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEVIEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. 2 DEVICE UNDER TEST Device Under Test Device Type COMOSAR 750 MHz REFERENCE DIPOLE Manufacturer Satimo Model $ID750 Serial Number SN 07/14 DIP 0G750—302 Product Condition (new / used) New A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION 3.1 GENERAL INFORMATION Satimo‘s COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEIIEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 — Satimo COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except infull or in part, without the written approval ofSATIMO. The information contained herein is to be used onlyfor the purposefor which it is submitted and is not to be released in whole orpart without written approval ofSATIMO.

((( . \ SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.287.3.14.SATU.A SATIMO 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CELIIEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of —20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEIM/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURNLOSS The following uncertainties apply to the return loss measurement: Frequency band Expanded Uncertainty on Return Loss 400—6000MHz 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements: Length (mm) Expanded Uncertainty on Length 3 — 300 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEIIEC 62209 standards were followed to generate the measurement uncertainty for validation measurements. Scan Volume Expanded Uncertainty 1 g 20.30% 10 g 20.1 % Page: 5/11 This document shall not be reproduced, except infull or in part, without the written approval ofSATIMO. The information contained herein is to be used onlyfor the purposefor which it is submitted and is not to be released in whole orpart without written approval ofSATIMO.

((( SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR287 3.14.SATU.A sArImo / 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE Frequency, MHz 650660 680 700 720 740 760 780 800 820 840850 0— ,5_ C 1 __ __ o —> 20— & 40— Frequency (MHz) Return Loss (dB) Requirement (dB) Impedance 750 —34.80 —20 50.7 Q + 1.6 jG2 6.2 MECHANICAL DIMENSIONS Frequency MHz L mm h mm d mm required measured required measured required measured 300 420.0 £1 %. 250.0 £1 %. 6.35 +1 %. 450 290.0 £1 %. 166.7 £1 %. 6.35 £1 %. 750 176.0 +1 %. PASS 100.0 £1 %. PASS 6.35 £1 %. PASS 835 161.0 +1 %. 89.8 +1 %. 3.6 +1 %. 900 149.0 £1 %. 83.3 +1%. 3.6 +1 %. 1450 89.1 +1 %. 51.7 £1 %. 3.6 +1 %. 1500 80.5 £1 %. 50.0 £1 %. 3.6 +1 %. 1640 79.0 1 %. 45.7 £1%. 3.6 £1 %. 1750 75.2 £1%. 42.9 £1%. 3.6 +1 %. 1800 72.0 £1 %. 41.7 £1%. 3.6 £1 %. 1900 68.0 +1 %. 39.5 £1%. 3.6 £1 %. 1950 66.3 +1 %. 38.5 £1%. 3.6 £1 %. 2000 64.5 41 %. 37.5 £1%. 3.6 £1 %. 2100 61.0 +1 %. 35.7 £1%. 3.6 +1 %. 2300 55.5 41 %. 32.6 +1 %. 3.6 £1 %. 2450 51.5 #1%. 30.4 £1%. 3.6 +1 %. 2600 48.5 +1 %. 28.8 £1%. 3.6 +1 %. 3000 41.5 £1%. 25.0 £1 %. 3.6 £1 %. 3500 37.0%1%. 26.4 £1%. 3.6 41 %. 3700 34.7%1%. 26.4 £1%. 3.6 +1 %. Page: 6/11 This document shall not be reproduced, except in full orin part, without the written approval ofSATIMO. The information contained hereinis to be used onlyforthepurposefor whichit is submitted and is not to be released in whole orpart without writtenapproval ofSATIMO. omm e es hopeecennnn en nemvapc en geeesg en nerrernen nne m e nen ues mvir en en nee uy eermernarners ce ie eoemapeemnrnen n n emereg eee c reee e y se

((( . \ SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.287.3.14.SATU.A SATIMO 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEIIEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Fre’?/lu:zncy Relative permittivity (€,‘) Conductivity {0) S/m required measured required measured 300 45.3 15 % 0.87 £5 % 450 43.5 25 % 0.87 £5 % 750 41.9 25 % PASS 0.89 £5 % PASS 835 41.5 25 % 0.90 £5 % 900 41.5 25 % 0.97 £5 % 1450 40.5 45 % 1.20 25 % 1500 40.4 15 % 123125 % 1640 40.2 25 % 1.31 15 % 1750 40.1 25 % 1.37 25 % 1800 40.0 25 % 1.40 25 % 1900 40.0 25 % 1.40 25 % 1950 40.0 25 % 140 £5 % 2000 40.0 25 % 140 25 % 2100 39.8 45 % 149 £5 % 2300 39.5 25 % 1.67 25 % 2450 39.2 25 % 1.80 25 % 2600 39.0 25 % 1.96 25 % 3000 38.5 15 % 2.40 £5 % 3500 37.9 25 % 2.91 +5 % 7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEVIEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software OPENSAR V4 Phantom SN 20/09 SAM71 Probe SN 18/11 BPG122 Liquid Head Liquid Values: eps‘ : 42.1 sigma : 0.89 Distance between dipole center and liquid 15.0 mm Area scan resolution dx=8mm/dy=8mm Page: 7/11 This document shall not be reproduced, except infull or in part, without the written approval ofSATIMO. The information contained herein is to be used onlyfor the purposefor which it is submitted and is not to be released in whole orpart without written approval ofSATIMO. t nan c y —

((/.\ SAR REFERENCE DIPOLE CALIBRATION REPORT LRenestoAtgArodt SATIMO Zoon Scan Resolution dx=8mm/dy=8m/dz=5mm Frequency 750 MHz Input power 20 dBm Liquid Temperature 71 °C Lab Temperature 21 °C Lab Humidity 45 % F 'e&":z"“’ 1 g SAR (W/ke/w) 10 g SAR (W/kg/w) required measured required measured 300 2.85 1.94 450 4.58 3.06 750 8.49 8.38 (0.84) 5.55 5.53 (0.55) 835 9.56 6.22 900 10.9 6.99 1450 29 16 1500 30.5 16.8 1640 34.2 18.4 1750 36.4 19.3 1800 38.4 20.1 1900 $9.7 20.5 1950 40.5 20.9 2000 41.1 21.1 2100 43.6 21.9 2300 48.7 23.3 2450 52.4 24 2600 55.3 24.6 3000 63.8 25.7 3500 67.1 25 oreeetaomn 7 Sutsen nesice meros _termos_| ’; JR 1 l'\ 10 7 Zunters a.l§:: |NA rar o» & os [A ] & in as we} gol) a2—, W t [ ximet B Yieet 8 2 4 608 10 12 WZIL"‘::I 18 20 22 M m 2 30 Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval ofSATIMO. The information contained herein is to be used onlyforthe purposefor which it is submitted and is not to be released in whole orpart without written approval ofSATIMO. t cesc c —


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Document Modified: 2019-11-04 18:19:11
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