I19Z61829-SEM01_SAR_Rev0_4

FCC ID: ZNFX540HM

RF Exposure Info

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FCCID_4474991

a ) 77 CAICT m EX3DV4— SN:3617 January 31, 2019 10588 AAB_| IEEE 802.11a/h WiFi 5 GHz (OFDM, 36 Mbps, 90pc duty cycle) WLAN 8.76 +9.6 % 10589 AAB IEEE 802.11a/h WiFi 5 GHz (OFDM, 48 Mbps, 90pc duty cycle) WLAN 8.35 + 9.6 % 10590 AAB IEEE 802.11a/h WiFi 5 GHz (OFDM, 54 Mbps, 90pc duty cycle) WLAN 8.67 +9.6 % 10591 AAB IEEE 802.11n (HT Mixed, 20MHz, MCSO, 90pc duty cycle) WLAN 8.63 +9.6 % 10592 AAB IEEE 802.11n (HT Mixed, 20MHz, MCS1, 90pc duty cycle) WLAN 8.79 + 9.6 % 10593 AAB IEEE 802.11n (HT Mixed, 20MHz, MCS2, 90pc duty cycle) WLAN 8.64 +9.6 % 10594 AAB IEEE 802.11n (HT Mixed, 20MHz, MCS3, 90pc duty cycle) WLAN 8.74 + 9.6 % 10595 AAB IEEE 802.11n (HT Mixed, 20MHz, MCS4, 90pc duty cycie) WLAN 8.74 + 9.6 % 10596 AAB IEEE 802.11n (HT Mixed, 20MHz, MCSS, 90pc duty cycle) WLAN 8.71 + 9.6 % 10597 AAB_| IEEE 802.11n (HT Mixed, 20MHz, MCS6, 90pc duty cycle) WLAN 8.72 + 9.6 % 10598 AAB IEEE 802.11n (HT Mixed, 20MHz, MCST, 90pc duty cycle) WLAN 8.50 £9.6 % 10599 AAB IEEE 802.11n (HT Mixed, 40MHz, MCSO, 90pc duty cycle) WLAN 8.79 £9.6 % 10600 AAB IEEE 802.11n (HT Mixed, 40MHz, MCS1, 90pc duty cycle) WLAN 8.88 £9.6 % 10601 AAB IEEE 802.11n (HT Mixed, 40MHz, MCS2, 9Opc duty cycie) WLAN 8.82 £9.6 % 10602 AAB IEEE 802.11n (HT Mixed, 40MHz, MCS3, 90pc duty cycle) WLAN 8.94 £9.6 % 10603 AAB IEEE 802.11n (HT Mixed, 40MHz, MCS4, 90pc duty cycle) WLAN 9.03 £9.6 % 10604 AAB_| IEEE 802.11n (HT Mixed, 40MHz, MCSS, 90pc duty cycle) WLAN 8.76 £9.6 % 10605 AAB IEEE 802.11n (HT Mixed, 40MHz, MCS6, 90pc duty cycle) WLAN 8.97 £9.6 % 10606 AAB_| IEEE 802.11n (HT Mixed, 40MHz, MCS7, 90pc duty cycle) WLAN 8.82 + 9.6 % 10607 AAB__| IEEE 802.11ac WiFi (20MHz, MCSO, 90pc duty cycle) WLAN 8.64 + 9.6 % 10608 AAB IEEE 802.1 1ac WiFi (20MHz, MCS1, 90pc duty cycle) WLAN 8.77 £9.6 % 10609 AAB_| IEEE 802.1 1ac WiFi (20MHz, MCS2, 90pc duty cycle) WLAN 8.57 + 9.6 % 10610 AAB IEEE 802.1 1ac WiFi (20MHz, MCS3, 90pc duty cycle) WLAN 8.78 +9.6 % 10611 AAB IEEE 802.1 1ac WiFi (20MHz, MCS4, 90pc duty cycle) WLAN 8.70 £9.6 % 10612 AAB IEEE 802.1 1ac WiFi (20MHz, MCS5, 90pc duty cycle) WLAN: 8.77 +9.6 % 10613 AAB IEEE 802.11ac WiFi (20MHz, MCS6, 90pc duty cycle) WLAN 8.94 £9.6 % 10614 AAB IEEE 802.11ac WiFi (20MHz, MCST, 90pc duty cycle) WLAN 8.59 £9.6 % 10615 AAB IEEE 802.1 1ac WiFi (20MHz, MCS8, 90pc duty cycle) WLAN 8.82 +9.6 % 10616 AAB IEEE 802.1 1ac WiFi (40MHz, MCSO, 90pc duty cycle) WLAN 8.82 + 9.6 % 10617 AAB IEEE 802.1 1ac WiFi (40MHz, MCS1, 9Opc duty cycle) WLAN 8.81 +9.6 % 10618 AAB IEEE 802.1 1ac WiFi (40MHz, MCS2, 9Opc duty cycle) WLAN 8.58 +9.6 % 10619 AAB IEEE 802.1 1ac WiFi (40MHz, MCS3, 90pc duty cycle) WLAN 8.86 +9.6 % 10620 AAB IEEE 802.11ac WiFi (40MHz, MCS4, 90pc duty cycle) WLAN 8.87 £9.6 % 10621 AAB IEEE 802.1 1ac WiFi (40MHz, MCSS5, 90pc duty cycle) WLAN 8.77 £9.6 % 10622 AAB IEEE 802.1 1ac WiFi (40MHz, MCSG, 90pc duty cycle) WLAN 8.68 +9.6 % 10623 AAB IEEE 802.1 1ac WiFi (40MHz, MCS7, 90pc duty cycle) WLAN 8.82 £9.6 % 10624 AAB IEEE 802.1 1ac WiFi (40MHz, MCS8, 90pc duty cycle) WLAN 8.96 £9.6 % 10625 AAB IEEE 802.1 1ac WiFi (40MHz, MCS9, 90pc duty cycle) WLAN 8.96 + 9.6 % 10626 AAB_| IEEE 802.11ac WiFi (BOMHz, MCSO, 90pc duty cycle) WLAN 8.83 £9.6 % 10627 AAB IEEE 802.1 1ac WiFi (BOMHz, MCS1, 90pc duty cycle) WLAN 8.88 +9.6 % 10628 AAB_| IEEE 802.11ac WiFi (BOMHz, MCS2, 90pc duty cycle) WLAN 8.71 +9.6 % 10629 AAB_| IEEE 802.11ac WiFi (BOMHz, MCS3, 90pc duty cycle) WLAN 8.85 +9.6 % 10630 AAB_| IEEE 802.11ac WiFi (BOMHz, MCS4, 90pc duty cycle) WLAN 8.72 +9.6 % 10631 AAB IEEE 802.1 1ac WiFi (BOMHz, MCSS5, 90pc duty cycle) WLAN 8.81 +9.6 % 10632 AAB_| IEEE 802.11ac WiFi (BOMHz, MCS6, 90pc duty cycle) WLAN 8.74 +9.6 % 10633 AAB_| IEEE 802.11ac WiFi (BOMHz, MCS7, 90pc duty cycle) WLAN 8.83 + 9.6 % 10634 AAB_| IEEE 802.11ac WiFi (BOMHz, MCSB, 90pc duty cycle) WLAN 8.80 +9.6 % 10635 AAB_| IEEE 802.11ac WiFi (BOMHz, MCS9, 90pc duty cycle) WLAN 8.81 +9.6 % 10636 AAC_| IEEE 802.11ac WiFi (160MHz, MCSO, 90pc duty cycle) WLAN 8.83 +9.6 % 10637 AAC IEEE 802.1 1ac WiFi (160MHz, MCS1, 90pc duty cycle) WLAN 8.79 +9.6 % 10638 AAC IEEE 802.11ac WiFi (160MHz, MCS2, 90pc duty cycle) WLAN 8.86 +9.6 % 10639 AAC IEEE 802.1 1ac WiFi (160MHz, MCS3, 9Opc duty cycle) WLAN 8.85 +9.6 % 10640 AAC IEEE 802.1 1ac WiFi (160MHz, MCS4, 9O0pc duty cycle) WLAN 8.98 +9.6 % 10641 AAC IEEE 802.1 1ac WiFi (160MHz, MCSS, 90pc duty cycle) WLAN 9.06 +9.6 % 10642 AAC IEEE 802.1 1ac WiFi (160MHz, MCS6, 9O0pc duty cycle) WLAN 9.06 + 9.6 % 10643 AAC IEEE 802.1 1ac WiFi (160MHz, MCS7, 90pc duty cycle) WLAN 8.89 + 9.6 % 10644 AAC IEEE 802.11ac WiFi (160MHz, MCSBS, 90pc duty cycle) WLAN 9.05 +9.6 % 10645 AAC IEEE 802.1 1ac WiFi (160MHz, MCS9, 9Opc duty cycle) WLAN 9.11 £9.6 % 10646 AAF LTE—TDD (SC—FDMA, 1 RB, 5 MHz, QPSK, UL Subframe=2,7) LTE—TDD 11.96 £9.6 % 10647 AAF LTE—TDD (SC—FDMA, 1 RB, 20 MHz, QPSK, UL Subframe=2,7) LTE—TDD 11.96 £9.6 % 10648 AAA CDMA2000 (1x Advanced) CDMA2000 3.45 £9.6 % 10652 AAD LTE—TDD (OFDMA, 5 MHz, E—TM 3.1, Clipping 44%) LTE—TDD 6.91 £9.6 % 10653 AAD_| LTE—TDD (OFDMA, 10 MHz, E—TM 3.1, Clipping 44%) LTE—TDD 742 £9.6 % 10654 AAD_| LTE—TDD (OFDMA, 15 MHz, E—TM 3.1, Clipping 44%) LTE—TDD 6.96 + 9.6 % Certificate No: EX3—3617_Jan19 Page 18 of 19

CAICT EX3DV4— SN:3617 January 31, 2019 10655 AAE LTE—TDD (OFDMA, 20 MHz, E—TM 3.1, Clipping 44%) LTE—TDD 7.21 + 9.6 % 10658 AAA Pulse Waveform (200Hz, 10%) Test 10.00 £9.6 % 10659 AAA Pulse Waveform (200Hz, 20%) Test 6.99 + 9.6 % 10660 AAA Pulse Waveform (200Hz, 40%) Test 3.98 £9.6 % 10661 AAA Pulse Waveform (200Hz, 60%) Test 2.22 + 9.6 % 10662 AAA Pulse Waveform (200Hz, 80%) Test 0.97 + 9.6 % 10670 AAA Bluetooth Low Energy Bluetooth 2.19 + 9.6 % © Uncertainty is determined using the max. deviation from linear response applying rectangular distribution and is expressed for the square of the field value. Certificate No: EX3—3617_Jan19 Page 19 of 19

No.I19Z61829-SEM01 ANNEX H Dipole Calibration Certificate 750 MHz Dipole Calibration Certificate ©Copyright. All rights reserved by CTTL. Page 175 of 246

Calibration Laboratory of S Schweizerischer Kalibrierdienst Schmid & Partner e Service suisse d‘étalonnage Engineering AG Servizio svizzero di taratura Zeughausstrasse 43, 8004 Zurich, Switzerland S Swiss Calibration Service Accredited by the Swiss Accreditation Service (SAS) Accreditation No.: SCS 0108 The Swiss Accreditation Service is one of the signatories to the EA Multilateral Agreement for the recognition of calibration certificates Glossary: TSL tissue simulating liquid ConvF sensitivity in TSL / NORM x.y,z N/A not applicable or not measured Calibration is Performed According to the Following Standards: a) IEEE Std 1528—2013, "IEEE Recommended Practice for Determining the Peak Spatial— Averaged Specific Absorption Rate (SAR) in the Human Head from Wireless Communications Devices: Measurement Techniques", June 2013 b) IEC 62209—1, "Measurement procedure for the assessment of Specific Absorption Rate (SAR) from hand—held and body—mounted devices used next to the ear (frequency range of 300 MHz to 6 GHz)", July 2016 c) IEC 62209—2, "Procedure to determine the Specific Absorption Rate (SAR) for wireless communication devices used in close proximity to the human body (frequency range of 30 MHz to 6 GHz)", March 2010 d) KDB 865664, "SAR Measurement Requirements for 100 MHz to 6 GHz" Additional Documentation: e) DASY4/5 System Handbook Methods Applied and Interpretation of Parameters: Measurement Conditions: Further details are available from the Validation Report at the end of the certificate. All figures stated in the certificate are valid at the frequency indicated. Antenna Parameters with TSL: The dipole is mounted with the spacer to position its feed point exactly below the center marking of the flat phantom section, with the arms oriented parallel to the body axis. Feed Point Impedance and Return Loss: These parameters are measured with the dipole positioned under the liquid filled phantom. The impedance stated is transformed from the measurement at the SMA connector to the feed point. The Return Loss ensures low reflected power. No uncertainty required. Electrical Delay: One—way delay between the SMA connector and the antenna feed point. No uncertainty required. SAR measured: SAR measured at the stated antenna input power. SAR normalized: SAR as measured, normalized to an input power of 1 W at the antenna connector. SAR for nominal TSL parameters: The measured TSL parameters are used to calculate the nominal SAR result. The reported uncertainty of measurement is stated as the standard uncertainty of measurement multiplied by the coverage factor k=2, which for a normal distribution corresponds to a coverage probability of approximately 95%. Certificate No: D750V3—1017_Jul19 Page 2 of 8 toge ces ve ks

Measurement Conditions DASY system configuration, as far as not given on page 1. DASY Version DASY5 V52.10.2 Extrapolation Advanced Extrapolation Phantom Modular Flat Phantom Distance Dipole Center — TSL 15 mm with Spacer Zoom Scan Resolution dx, dy, dz =5 mm Frequency 750 MHz +1 MHz Head TSL parameters The following parameters and calculations were applied. Temperature Permittivity Conductivity Nominal Head TSL parameters 22.0 °C 41.9 0.89 mho/m Measured Head TSL parameters (22.0 + 0.2) °C 42.2 +6 % 0.89 mho/m + 6 % Head TSL temperature change during test <0.5 °C SAR result with Head TSL SAR averaged over 1 cm* (1 g) of Head TSL Condition SAR measured 250 mW input power 2.14 W/kg SAR for nominal Head TSL parameters normalized to 1W 8.57 Wikg + 17.0 % (k=2) SAR averaged over 10 cm* (10 g) of Head TSL condition SAR measured 250 mW input power 1.39 Wikg SAR for nominal Head TSL parameters normalized to 1W 5.57 Wikg + 16.5 % (k=2) Body TSL parameters The following parameters and calculations were applied. Temperature Permittivity Conductivity Nominal Body TSL parameters 22.0 °C §5.5 0.96 mho/m Measured Body TSL parameters (22.0 + 0.2) °C 55.1 +6 % 0.96 mho/m + 6 % Body TSL temperature change during test <0.5 °C sese wes— SAR result with Body TSL SAR averaged over 1 cm* (1 g) of Body TSL Condition SAR measured 250 mW input power 2.14 W/kg SAR for nominal Body TSL parameters normalized to 1W 8.55 W/kg + 17.0 % (k=2) SAR averaged over 10 cm* (10 g) of Body TSL condition SAR measured 250 mW input power 141 Wikg SAR for nominal Body TSL parameters normalized to 1W 5.63 W/kg + 16.5 % (k=2) Certificate No: D750V3—1017_Jul19 Page 3 of 8

(J) "A ET non snn on se sn e n laz ww r w Appendix (Additional assessments outside the scope of SCS 0108) Antenna Parameters with Head TSL Impedance, transformed to feed point 53.1 Q — 1.3 jQ Return Loss —29.6 dB Antenna Parameters with Body TSL Impedance, transformed to feed point 48.9 Q — 4.3 jQ Return Loss — 27.0 dB General Antenna Parameters and Design Electrical Delay (one direction) L 1.041 ns After long term use with 100W radiated power, only a slight warming of the dipole near the feedpoint can be measured. The dipole is made of standard semirigid coaxial cable. The center conductor of the feeding line is directly connected to the second arm of the dipole. The antenna is therefore short—circuited for DC—signals. On some of the dipoles, small end caps are added to the dipole arms in order to improve matching when loaded according to the position as explained in the "Measurement Conditions" paragraph. The SAR data are not affected by this change. The overall dipole length is still according to the Standard. No excessive force must be applied to the dipole arms, because they might bend or the soldered connections near the feedpoint may be damaged. Additional EUT Data Manufactured by SPEAG Certificate No: D750V3—1017_Jul19 Page 4 of 8 toge ces ve ks

DASY5 Validation Report for Head TSL Date: 18.07.2019 Test Laboratory: SPEAG, Zurich, Switzerland DUT: Dipole 750 MHz; Type: D750V3; Serial: D750V3 — SN:1017 Communication System: UID 0 — CW; Frequency: 750 MHz Medium parameters used: f = 750 MHz; 0 = 0.89 S/m; &, = 42.2; p = 1000 kg/m3 Phantom section: Flat Section Measurement Standard: DASY5 (IEEE/IEC/ANSI C63.19—2011) DASY52 Configuration: e Probe: EX3DV4 — SN7349; ConvF(10.07, 10.07, 10.07) @ 750 MHz; Calibrated: 29.05.2019 e Sensor—Surface: 1.4mm (Mechanical Surface Detection) e Electronics: DAE4 Sn601; Calibrated: 30.04.2019 e Phantom: Flat Phantom 4.9 (front); Type: QD OOL P49 AA; Serial: 1001 «_ DASY52 52.10.2(1504); SEMCAD X 14.6.12(7470) Dipole Calibration for Head Tissue/Pin=250 mW, d=15mm/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 59.72 V/m; Power Drift = 0.00 dB Peak SAR (extrapolated) =3.21 W/kg SAR(I g) = 2.14 W/kg; SAR(10 g) = 1.39 W/kg Maximum value of SAR (measured) = 2.84 W/kg dB 0 —2.00 —4.00 —6.00 —8.00 —10.00 0 dB = 2.84 W/kg = 4.53 dBW/kg Certificate No: D750V3—1017_Jul19 Page 5 of 8

mm\ /77 -‘ CA IET Impedance Measurement Plot for Head TSL File View Channel Sweep Calibration Trace Scale Marker System Window Help 53.148 O ~1.3174 0 33.079 mU ~21.979° Ch1Aug= 20 Chi: Start 550.000 MHz —— Stop 950000 MHz 750.000000 MHz __—2$9.609 dB 00 .00 00 .00 00 Chi: Start Status CH 1: B _ L — Avg=20 Delay Certificate No: D750V3—1017_Jul19 Page 6 of 8 songn en en +

DASY5 Validation Report for Body TSL Date: 18.07.2019 Test Laboratory: SPEAG, Zurich, Switzerland DUT: Dipole 750 MHz; Type: D750V3; Serial: D750V3 — SN:1017 Communication System: UID 0 — CW; Frequency: 750 MHz Medium parameters used: f = 750 MHz; 0 = 0.96 $/m; & = 55.1; p = 1000 kg/m3 Phantom section: Flat Section Measurement Standard: DASY5 (IEEE/IEC/ANSI C63.19—2011) DASY352 Configuration: e Probe: EX3DV4 — SN7349; ConvF(10.4, 10.4, 10.4) @ 750 MHz; Calibrated: 29.05.2019 e Sensor—Surface: 1.4mm (Mechanical Surface Detection) e Electronics: DAE4 Sn601; Calibrated: 30.04.2019 & Phantom: Flat Phantom 4.9 (Back); Type: QD OOR P49 AA; Serial: 1005 & DASY52 52.10.2(1504); SEMCAD X 14.6.12(7470) Dipole Calibration for Body Tissue/Pin=250 mW, d=15mm/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 55.74 V/m; Power Drift = —0.02 dB Peak SAR (extrapolated) = 3.18 W/kg SAR(1 g) = 2.14 W/kg; SAR(10 g) = 1.41 W/kg Maximum value of SAR (measured) = 2.84 W/kg dB 0 —2.00 ~4.00 —6.00 —8.00 —10.00 0 dB = 2.84 W/kg = 4.53 dBW/kg Certificate No: D750V3—1017_Jul19 Page 7 of 8

mm\ .TTL &A 1IE*T Impedance Measurement Plot for Body TSL File View Channel Swesp Calibration Trace Scale Marker Window. I _ 750.000000 MHz 48.897 O 49.656 pF —4.2735 Q 50 000000 MHz 44.586 mU 3 ~101.99 ° Chi1Aug= 20 Chi1: Start 550.000 MHa __—— Stop 950.000 MHz 750.000000 MHz —2f.016 dB .00 .00 .00 00 00 Ch 1 ® _Ch1: Start 550.000 MHa __—— Stop 950.000 MHz Status CH 1: En' ~TJCET—Pot "Avg=20 Delay e LEL Certificate No: D750V3—1017_Jul19 Page 8 of 8

TTL DA IE"T non n n n se se e n ve n esn w Calibration Laboratory of \\‘\‘“3'“/" Schweizerischer Kalibrierdienst S )C m oo Schmid & Partner shes Service suisse d‘étalonnage Engineering AG esc C Servizio svizzero di taratura YA w\w Zeughausstrasse 43, 8004 Zurich, Switzerland 4/ //I\\ S S swiss Calibration Service thiluls® Accredited by the Swiss Accreditation Service (SAS) Accreditation No.: SCS 0108 The Swiss Accreditation Service is one of the signatories to the EA Multilateral Agreement for the recognition of calibration certificates Client CTTL (Auden) Certificate No: D835V2—4d069_Jul19 [CALIBRATION CERTIFICATE Object D835V2 — SN:4d069 Calibration procedure(s) QA CAL—O05.v11 Calibration Procedure for SAR Validation Sources between 0.7—3 GHz Calibration date: July 18, 2019 This calibration certificate documents the traceability to national standards, which realize the physicalunits of measurements (S1). The measurements and the uncertainties with confidence probability are given on the following pages and are part of the certificate. All calibrations have been conducted in the closed laboratory facility: environment temperature (22 + 3)°C and humidity < 70%. Calibration Equipment used (M&TE critical for calibration) Primary Standards ID # Cal Date (Certificate No.) Scheduled Calibration Power meter NRP SN: 104778 03—Apr—19 (No. 217—02892/02893) Apr—20 Power sensor NRP—Z91 SN: 103244 03—Apr—19 (No. 217—02892) Apr—20 Power sensor NRP—Z291 SN: 103245 03—Apr—19 (No. 217—02893) Apr—20 Reference 20 dB Attenuator SN: 5058 (20k) 04—Apr—19 (No. 217—02894) Apr—20 Type—N mismatch combination SN: 5047.2 / 06827 04—Apr—19 (No. 217—02895) Apr—20 Reference Probe EX3DV4 SN: 7349 29—May—19 (No. EX3—7349_May19) May—20 DAE4 SN: 601 30—Apr—19 (No. DAE4—601_Apr19) Apr—20 Secondary Standards ID # Check Date (in house) Scheduled Check Power meter E4419B SN: GB39512475 30—Oct—14 (in house check Feb—19) In house check: Oct—20 Power sensor HP 8481A SN: US37202783 07—Oct—15 (in house check Oct—18) In house check: Oct—20 Power sensor HP 8481A SN: MY41092317 07—Oct—15 (in house check Oct—18) In house check: Oct—20 RF generator R&S SMT—06 SN: 100972 15—Jun—15 (in house check Oct—18) In house check: Oct—20 Network Analyzer Agilent E8358A SN: US41080477 31—Mar—14 (in house check Oct—18) In house check: Oct—19 Name Function C Calibrated by: Claudio Leubler Laboratory Technician ‘ QG Approved by: Katia Pokovic Technical Manager e Issued: July 19, 2019 This calibration certificate shall not be reproduced except in full without written approval of the laboratory. Certificate No: D835V2—40069_Jul19 Page 1 of 8

) sTTL DA IE"T C & a¥bP j Calibration Laboratory of s\\\\\\i'/;// G Schweizerischer Kalibrierdienst Schmid & Partner i ~=~mk Service suisse d‘étalonnage Engineering AG 3lac=vrk& §ons C o Servizio svizzero di taratura Zeughausstrasse 43, 8004 Zurich, Switzerland *g/7\\\\\3‘ S Swiss Calibration Service "thiluls Accredited by the Swiss Accreditation Service (SAS) Accreditation No.: SCS 0108 The Swiss Accreditation Service is one of the signatories to the EA Multilateral Agreementfor the recognition of calibration certificates Glossary: TSL tissue simulating liquid ConvF sensitivity in TSL / NORM x.y,z N/A not applicable or not measured Calibration is Performed According to the Following Standards: a) IEEE Std 1528—2013, "IEEE Recommended Practice for Determining the Peak Spatial— Averaged Specific Absorption Rate (SAR) in the Human Head from Wireless Communications Devices: Measurement Techniques", June 2013 b) IEC 62209—1, "Measurement procedure for the assessment of Specific Absorption Rate (SAR) from hand—held and body—mounted devices used next to the ear (frequency range of 300 MHz to 6 GHz)", July 2016 c) IEC 62209—2, "Procedure to determine the Specific Absorption Rate (SAR) for wireless communication devices used in close proximity to the human body (frequency range of 30 MHz to 6 GHz)", March 2010 d) KDB 865664, "SAR Measurement Requirements for 100 MHz to 6 GHz" Additional Documentation: e) DASY4/5 System Handbook Methods Applied and Interpretation of Parameters: e Measurement Conditions: Further details are available from the Validation Report at the end of the certificate. All figures stated in the certificate are valid at the frequency indicated. e Antenna Parameters with TSL: The dipole is mounted with the spacer to position its feed point exactly below the center marking of the flat phantom section, with the arms oriented paralle! to the body axis. e Feed Point Impedance and Return Loss: These parameters are measured with the dipole positioned under the liquid filled phantom. The impedance stated is transformed from the measurement at the SMA connector to the feed point. The Return Loss ensures low reflected power. No uncertainty required. e Electrical Delay: One—way delay between the SMA connector and the antenna feed point. No uncertainty required. e SAR measured: SAR measured at the stated antenna input power. e SAR normalized: SAR as measured, normalized to an input power of 1 W at the antenna connector. e SAR for nominal TSL parameters: The measured TSL parameters are used to calculate the nominal SAR result. The reported uncertainty of measurement is stated as the standard uncertainty of measurement multiplied by the coverage factor k=2, which for a normal distribution corresponds to a coverage probability of approximately 95%. Certificate No: D835V2—4d069_Jul19 Page 2 of 8

7A 1E «en en e se en e nc e nsmd i y Measurement Conditions DASY system configuration, as far as not given on page 1. DASY Version DASY5 V52.10.2 Extrapolation Advanced Extrapolation Phantom Modular Flat Phantom Distance Dipole Center — TSL 15 mm with Spacer Zoom Scan Resolution dx, dy, dz =5 mm Frequency 835 MHz + 1 MHz Head TSL parameters The following parameters and calculations were applied. Temperature Permittivity Conductivity Nominal Head TSL parameters 22.0 °C 41.5 0.90 mho/m Measured Head TSL parameters (22.0 + 0.2) °C 42.0 +6 % 0.91 mho/m + 6 % Head TSL temperature change during test <0.5 °C ——«~ wo«+ SAR result with Head TSL SAR averaged over 1 cm* (1 g) of Head TSL Condition SAR measured 250 mW input power 2.44 W/kg SAR for nominal Head TSL parameters normalized to 1W 9.70 Wikg x 17.0 %(k=2) SAR averaged over 10 cm* (10 g) of Head TSL condition SAR measured 250 mW input power 1.58 Wikg SAR for nominal Head TSL parameters normalized to 1W 6.29 W/kg + 16.5 % (k=2) Body TSL parameters The following parameters and calculations were applied. Temperature Permittivity Conductivity Nominal Body TSL parameters 22.0 °C 55.2 0.97 mho/m Measured Body TSL parameters (22.0 £ 0.2) °C 54.9 + 6 % 0.99 mho/m + 6 % Body TSL temperature change during test «0.5°C SAR result with Body TSL SAR averaged over 1 cm* (1 g) of Body TSL Condition SAR measured 250 mW input power 2. 46 W/kg SAR for nominal Body TSL parameters normalized to 1W 9.68 Wi/kg + 17.0 %(k=2) SAR averaged over 10 cm* (10 g) of Body TSL condition SAR measured 250 mW input power 1.60 Wikg SAR for nominal Body TSL parameters normalized to 1W 6.32 W/kg + 16.5 % (k=2) Certificate No: D835V2—40069_Jul19 Page 3 of 8

m T°5TL ‘ar_\ as a sn n n e en e es Nee w i Appendix (Additional assessments outside the scope of SCS 0108) Antenna Parameters with Head TSL Impedance, transformed to feed point 50.8 Q — 2.4 jQ Return Loss — 32.1 dB Antenna Parameters with Body TSL Impedance, transformed to feed point 47.1 Q — 3.9 jQ Return Loss — 25.9 dB General Antenna Parameters and Design Electrical Delay (one direction) T 1.393 ns After long term use with 100W radiated power, only a slight warming of the dipole near the feedpoint can be measured. The dipole is made of standard semirigid coaxial cable. The center conductor of the feeding line is directly connected to the second arm of the dipole. The antenna is therefore short—circuited for DC—signals. On some of the dipoles, small end caps are added to the dipole arms in order to improve matching when loaded according to the position as explained in the "Measurement Conditions" paragraph. The SAR data are not affected by this change. The overall dipole length is still according to the Standard. No excessive force must be applied to the dipole arms, because they might bend or the soldered connections near the feedpoint may be damaged. Additional EUT Data Manufactured by SPEAG Certificate No: D835V2—4d069_Jul19 Page 4 of 8


Document Created: 2019-10-10 17:15:13
Document Modified: 2019-10-10 17:15:13
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