Test report HAC part 2

FCC ID: 2ADLJSYNC

Test Report

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FCCID_4066184

EF3DV3 — SN:4048 January 9, 2018 10i9e— |LIETDD{SCFDNA,S0%RE, isMHz, x 366 Ga6s ini8 223 800 i96% AAC 64—OAM, UL Subframe=2.3.4,7,8.9) Y 4.48 70.07 18 09 ET 2 422| Toar 1857 200 10494— |LTETDD(SCEDNMA SO%RS.20MHz. x 302 7262 i873 223 @00 196% AAG OPSK, UL Subframe=2.3.4.7.8.9) y si0_| 7asi i8966 500 z sos Troi_| zow s0.0 10495— |LTE—TDD(SGFDMA. SO%RE, 20MHz, X a62 6900 ir4e 223 800 +96% AAG 16—OAM,UL Subtrame=2.3.4.7.8.9) y «47 Tore 1836 800 2| 422| 7i12 18.90 s0.0 10496— LTE—TDD (SC—FDMA, 50% RB, 20 MHz, X 3.71 6883 1740 223 so0 £96% AAG 64—QAM, UL Subtrame=2.3.4.7.8.9) Y_| 454| 7odo ta2s 800 Z a2r Toro 1875 80.0 Tos9r— LTE—TDD (SC—FOMA, 100% RB, 14 X| is a132 agr 223 810 96% AAA NHz, QPSK, UL Subframe=2.3.4.7.8.9) Y 306 Tim 6i3 s00 2| 272| Ts3 1518 a0.0 10298— LTE—TDD (SC—FDMA, 100% RB, 1.4 X i6 sa00 7iz 223 800 196% AAA MHz, 16—QAM, UL Subframe=2,3.4,7.8.9) Y_| 245| 6585 1260 so0 z i6 6255 as4 80.0 10499— LTE—TDD (GC—FDMA, 100% RB, 14 x 117 sa00 a98 223 800 +90% AAA MHz, 64—QAM, UL Subframe=2.3,4,7.8.9) Y 2.39 65.36 1223 80.0 2 1.61 61.96 9.47 80.0 10500— |LTE—TOD{SC—FOMA. 100% RB, 3MHz, X 306 7302 1782 223 800 i96% AAA QOPSK, UL Subfame=2.3.4,7.6.9) Y—| 448| 7ase 1985 s00 2| 503| 8084 2172 s0.0 10501— |LTE—TDD(SCFDMA. 100% RB, 3MHz, x 285 6844 1530 223 800 £96% AAA 16—QAM, UL Subframe=2.3.4.7,8.9) Y 38 7ise ied Bo. 2 |_sso 7270 1822 80.0 10502 |LTE—TDD(SG—FDMA, 100% RS, aMHz, X 265 6620 is11 223 800 £96% AAA 64—GAM, UL Subframe=2,3.4.7.8.9) Y |_a0 Tiie_| inss 800 2 se3 7244 i8.00 800 10503— LTE—TDD (SC—FDMA, 100% RB, 5 MHz, X 331 Todse 1g63 223 800 i96% AAG OPSK, UL Subframe=2.3.4.7.8.9) Y ze Temi i1094 800 2| a7s Tese mso so.0 T0504— |LTETDD(SGFDNMA, 100%RB, 5MHz, X 320 6924 1688 223 Bo0 <96% AAG 16—OAM, UL Subtrame=2,3.4.7.8.9) y_| «08| 7108 1820 so0 2 sez 72os 1885 200 10505 LTE—TDD(SCFDMA, j0o% RB, sMHz, X 328 sai0 is2 225 800 296% AAG 64—GAM, UL Subframe=2.3.4.7.8.9)_ y_| 416| Tos2 1812 800 2| 398| 7170 1671 80.0 10506— LTE—TDD (SG—FDMA, 100% RS, 10 x are faee i8es 223 800 +96% AG MHz, OPSK, UL Subframe=2,3.4.7,8.9) Y so6 Tais fsa1 800 2 500 Tess 20.85 80.0 10507— LTE—TDD (GC—FDMA, 100% RB, 10 x 61 ea01 i742 223 800 £96% AAG MHz, 16—QAM, UL Subframe=2.3.4.7,8.9) y 446 Toro 1632 a0.0 Z @2 Tior 1687 EnG) Certificate No: EF3—4048_Jan16 Page 29 of 39

— neve cessn iepee> EF3DV3 — SN:4048 January 9, 2018 1 f 100% h . : 80 +9. AAC MHz, 64—OAM, UL 7, LTE—TDD (SC—FDMA, 100% RB, 1 MHz, 16—QAM, UL LTE—TDD (SC—FDMA, 100% MHz, 64—QAM, UL 4.7 TDD (SC—FDMA, 100% MHz, 16—QAM, UL 23.4 LTE—TDD ( MHz, 64—QAM, UL 427 IEEE 802.11a/h WiFi 5 GHz (OFDM, 9 IEEE 802.11a/h WiFi 5 GHz IEEE 802.11a/h WiFi 5 GHz (OFDM, 2 802.11a/h WiFi 5 GHz (OFDM, 36 Certificate No: EF3—4048_Jan18 Page 30 of 38

EF3DV3 — SN:4048 January 9, 2018 10523— IEEE 802.1 1ah WiFi 5 GHz (OFDM, 48 X 447 68.11 16.93 0.00 150.0 £9.6 % AAB Mbps, 99pc duty cycie) Y¥ 471 67.04 16.69 150.0 Fa 457 67 88 16.98 150.0 10524— IEEE 802.1 1ath WiFi 5 GHz (OFOM, 54 X 4.50 68.14 17.05 0.00 150.0 29.6 % AAB Mbps, 99pc dutycycie) Y 460 67.94 17.04 150.0 2 4.64 67.99 1713 150.0 10525— IEEE 802.1 tac WiFi (20MHz, MCSO, X 4.53 6716 16.62 0.00 150.0 £9.6 % AAB 99pc duty cycie) Y 4.76 66.91 16.59 150.0 Z 4.63 66.95 16.67 150.0 10526— IEEE 802.1 Tac WiFi (20MHz, MCS1, X 4.67 67.49 16.75 9.00 1500 £8.6% AAB $9pc duty cycle) Y 4.97 67.34 16.74 150.0 2 4.80 67.35 16.63 150.0 10527— IEEE 802.1 Tac WiFi (20MHz, MCS2, X 4.60 67.46 16.69 0.00 150.0 £9.6 % AAB 99pc duty cycie) Y 4.88 67.31 16.69 150.0 Z 4.72 67.30 16.77 150.0 10528— IEEE 802.11ac WiFi (20MHz, MCS3, X 4.61 67.47 16.72 0.00 150.0 £9.6 % AAB 99pc duty cycle) Y 4.90 67.34 16.73 150.0 Z 4.74 67.32 16.80 150.0 10520 IEEE 802. 11ac WiFi (20MHz, MCS4, X 4.61 67.47 16.72 0.00 150.0 £9.6 % AAB 99pc duty cycle) Y 4.80 67.34 16.73 150.0 2 4.74 67.32 16.60 150.0 10531— IEEE 802. 1 Tac WiFi (20MHz, MCS6, X 4.59 67.54 16.72 0.00 150.0 £9.6 % AAB 99pc duty cycla) Y 4.92 67.51 16.77 150.0 2 4.73 67.45 16.83 150.0 10532 IEEE 802.11ac WiFi (20MHz, MCST, X 4.46 67.39 16.65 0.00 150.0 £9.6 % AAB 99pc duty cycle) Y 476 67.37 16.71 150.0 2 4.59 67.28 16.75 150.0 10533— IEEE 802. 11ac WiFi (20MHz, MCSB, X 4.62 67.56 16.73 0.00 150.0 £9.6% AAB 99pe duty cycie) Y 4.91 67.36 16.71 150.0 2 4.75 67.38 16.79 150.0 10534— IEEE 802. 1 1ac WiFi (40MHz, MCSO, X 523 67.56 16.04 0.00 150.0 £9.6 % AAB 99pe duty cycie) ¥ 5.47 67.57 16.83 150.0 2 5.36 67.55 16.95 150.0 10535— IEEE 802.11ac WiFi (40MHz, MCS1, X 5.33 67.93 17.02 0.00 150.0 +9.6 % AAB 99pc duty cycle) Y 5.55 67.74 16.90 150.0 2 5.53 68.11 17.23 150.0 10536— IEEE 802. 11ac WiFi (40MHz, MCS2, X 5.19 67.81 16.93 0.00 150.0 +9.6 % AAB 99pc duty cycle) Y 5.42 67.73 16.88 150.0 2 5.33 67.81 17.05 150.0 10537— IEEE 802. 1 Tac WiFi (40MHz, MCS3, X 5.27 67.86 16.97 0.00 150.0 £9.6 % AAB 99pc duty cycle) ¥ 5.49 67.77 16.87 150.0 2 5.39 67.79 17.04 150.0 10538— IEEE 802.11ac WiFI (40MHz, MCS4, X 5.34 67.03 16.09 0.00 1500 £986% AAB $9pc duty oycle) £ 5.60 67.80 16.95 150.0 2 5.47 67.75 17.07 150.0 10540— IEEE 802.11ac WiFi (40MHz, MCSB, X 5.22 67.62 16.90 0.00 150.0 £8.6% AAB 99pc duty cycle} Y 5.52 67.79 16.97 150.0 Z 5.43 67.58 17.15 150.0 Certificate No: EF3—4048_Jan18 Page 31 of 39

EF3DV3 — SN:4048 January 9, 2018 IEEE 802.11ac WiFi 802.1tac WiFi IEEE 802. 11a¢ WiFi 1ac WiFi (GOMHz, Tac WiFi (BOMHz, MCS4, IEEE 802.1 fac WiFi (GOMHz, MCSS IEEE 802.1tac WiFi (BOMHz, MCS9, IEEE 802.11ac WiFi (160MHz, MCSO, IEEE 802.1tac WiFi (160MHz, MCS1, IEEE 802.11ac WiFi (160MHz, MCS2, Mac (160MHz, MCS3, Certificate No: EF3—4048_Jan18 Page 32 of 39

EF3DV3 — SN:4048 January 9, 2016 10558 IEEE 802.1Tac WiFi (160MFz, 150.0 + AAG 150.0 10560— IEEE 802.1 Tac WiFi (160MHz, 150.0 150. IEEE 802.1 1ac WiFi (160MHz, MCS7, 150.0 150.0 150.0 150.0 1 IEEE 802.119 WiFi 2.4 GHz (DSSS— 9 IEEE 802.119 WiFi 1 IEEE 802.119 WiFi 2.4 GHz (DSSS— IEEE 802.119 WiFi 2.4 36 1EEE 802119 WiFi 2.4 GHz (DSSS— 48 802119 (pSSS— 54 (EEE 802.11b WiFi 2.4 GHz (DSSS, 1 IEEE 802.11b WiFi 2.4 GHz (DSSS, 5.5 Certificate No: EF3—4048_Jan18 Page 33 of 39

EF3DV3 — SN:4048 January 9, 2018 802.119 . . 130.0 £96% AAA 5efi IEEE 802.119 24 GHz (DSSS— scful<] IEEE 802.119 WiFi 24 GHz 1 oefrul—c| i2E 502119 xiral—c] 1EEE 802.119 WiFi 2.4 GHz 24 119 WiFi2.4 GHz 802.119 WiFi 119 54 IEEE 802.11@/h 5 GHz 802.11ah WiFi 5 GHz (OFDM, 12 IEEE 802.11ah 5 GHz (OFDM, 18 IEEE 802.11a/h WiFi 5 GHz (OFDM, 24 IEEE 802.11ah WiFi 5 GHz IEEE 802.11a/h WiFi 5 GHz (OFDM, 48 IEEE 802.11a/h Certificate No: EF3—4048_Jan18 Page 34 of 39

EF3DV3 — SN4048 January 9, 2018 10591— 1EEE 802.11n (HT Mixed, 20MHz, X 4.78 67.66 17.10 0.46 1300 £986% AAB MCSO, 90pc duty cycle) Y 5.05 67.55 17.18 130.0 Z 4.92 67 61 17.31 130.0 10592 1EEE 802.11n (HT Mixed, 20MHz, X 4.91 67.98 17.24 0.46 130.0 £9.6% AAB MCS1, 90pc duty cycle) Y 5.23 67.91 17.30 130.0 Z 5.07 67.97 17.45 130.0 10593— IEEE 802.11n (HT Mixed, 20MHz, X 4.83 67.07 17.10 0.46 130.0 £96% AAS MCS2, 90pc duty cycle) Y 5.16 67 88 17.22 130.0 2 5.00 67.09 17.34 130.0 10594— IEEE 802.11n (HT Mixed, 20MHz, X 4.88 68.03 17.26 0.46 130.0 £96% AAB MCS3, 90pc duty cycle) Y 521 68 00 17.35 130.0 Z 5.05 68.04 17.48 130.0 10595 1EEE 802.11n (HT Micéed, 20MHz, X 4.85 68.02 17.17 0.46 130.0 £9.6 % AAB MCS4. 90pc duty cycle) Y 5.19 68 00 17.26 130.0 2 5.02 68.02 17.39 130.0 10596— 1EEE 802.11n (HT Mixed, 20MHz, X 4.78 68.01 1718 0.46 1300 £96% AAB MCSS, 90pc duty cycie) Y 5.12 67.99 17.27 130.0 Z 4.96 63.04 1741 130.0 10597— IEEE 802.11n (HT Mixed, 20MHz, X 4.73 67.88 17.03 0.46 130.0 £9.6 % AAB MCS6, 9Opc duty cycle) Y 5.07 67.94 1717 130.0 2 4.91 67.93 1729 130.0 10598— IEEE 802.11n (HT Mixed, 20MHz, X .21 68.07 1728 0.46 130.0 £9.6% AAB MCS7, SOpe duty cycie) Y 5.05 68.15 1742 130.0 2 4.88 68.11 1762 130.0 10598— IEEE 802.11n (HT Mixed, 4OMHz, X §.M1 68.97 17.81 0.46 130.0 £9.6 % AAB MCSO. 90pc duty cycle) Y 564 68.51 17.57 130.0 2 5.81 68.83 17.91 130.0 10600— IEEE 802.11n (HT Mixed, 40MHz, X 6.12 70.36 18.47 0.46 130.0 £9.6% AAB MCS1, 90pc duty cycle) Y 649 70.59 18.61 130.0 2 6.57 71.34 19.15 130.0 10601— IEEE 802.11n (HT Mixed, 40MHz, X 5.10 69.05 17.43 0.46 130.0 £9.6 % AAB MCS2, 90pc duty cycle) Y 6.06 65.32 17.98 130.0 2 5.98 69.54 18.27 130.0 10602— IEEE 802.11n (HT Mixed, 40MHz, X 5.87 60.32 17.89 0.46 130.0 +9.6 % AAB MCS3, $0pc duty cycle) ¥ 6.11 69.18 17.53 130.0 2 6.12 69.09 18.26 130.0 10603— IEEE 802.1 in (HT Mixed, 40MHz, s 6.00 69.82 18.27 0.46 130.0 £9.6 % AAB MCS4, SOpc duty cycle) ¥ 6.16 69.32 18.01 130.0 Z 6.12 69.71 16.39 130.0 10604— IEEE 802.11n (HT Mixed, 40MHz, X 5.61 69.25 17.07 0.46 130.0 +9.6 % AAB MCSS, 8Opc duty cycle) Y 5.68 68.60 17.65 130.0 Z 5.78 68.63 17.83 130.0 10605— IEEE 802.11n (HT Mixed, 40MHz, X 5.95 69.72 18.21 0.46 130.0 £96% AAB MCSG, 9Opc duty cycle) Y¥ 6.12 69.34 18.03 130.0 2 6.28 70.38 18.72 130.0 10606— 1EEE 802.11n (HT Mixed, 40MHz, X 5.59 68.67 17.53 0.46 130.0 £9.6% AB MCS7, 90pe duty cycle) Y 5.70 68.15 17.28 130.0 2 5.60 68.23 1749 130.0 Certificate No: EF3—4048_Jan18 Page 35 of 39

EF3DV3 — SN—4048 January 9, 2018 1 296 802.11ac WiFi IEEE 802. 11ac WiFi 11ac WiFi (20MHz, MCS4, IEEE 802.11ac (20MHz, MCSS, 802.1tac WiFi IEEE 802.1tac Mac (20MHz, MCSB, IEEE 802.11ac (4OMHz, MCSO, IEEE 802.11ac WiFi (40MHz, MCS1, IEEE 802.11ac WiFi (40MHz, MCS2, IEEE 802.11ac WiFi (40MHz, MCS3, IEEE 802.11a0 WiFI (40MHz, MCSS5, IEEE 802.11ac (dOMHz, MCSG, Certificate No: EF3—4048_Jan18 Page 36 of 39

EF3DV3 — SN4048 January 9, 2018 10623— IEEE 802.11ac WiFi (40MHz, MCST, X 5.27 67.25 16.85 0.4G 130.0 +9.6 % AAB 90pc duty cycie) Y 5.56 67.41 16.95 130.0 2 5.51 67. 65 17.24 130.0 10624— IEEE 802.1 Tac WiFi (40MHz, MCSS, X 5.52 67.67 1713 046 130.0 19.6 % AAS 20pe dutycycle}) Y 5 82 67.82 17.22 130.0 Z 5.71 67.85 17.40 130.0 10625— IEEE 802.1 Tac WiFi (A0MHz, MCS9, X 5.65 67.98 17.35 0.46 1300 196 % AAB 2Opc duty cycle) Y 6.70 70.31 18.51 130.0 Z 641 69.92 18.49 130.0 10626— IEEE 802.1 fac WiFi (GOMHz, MCSO, X 5.69 67.50 16.96 0.46 130.0 +988 % AAB 20pc duty cycle) Y 5.86 67.47 16.93 130.0 Z 5.83 67.61 17.18 130.0 10627— IEEE 802.1 1ac WiFi (BOMHz, MCS1, X 6.19 68.98 17.68 0.46 130.0 £9.6 % AAB 2Ope duty cycie) Y 6.32 68.68 17.50 130.0 2 6.43 69.33 18.02 130.0 10628— IEEE 802.11ac WiFi (BOMHz, MCS2, X 5.74 67.66 16.95 0.46 130.0 £9.6 % AAB $Ope duty cycle) Y 5.99 67.87 17.03 130.0 2 5.92 67.90 17.23 130.0 10629— IEEE 802. 11a¢ WiFi (BOMHz, MCS3, X 5.94 68.16 17.20 0.46 130.0 £9.6 % AAB 9Ope duty cycle) Y 6.09 67.97 17.08 130.0 2 611 68.31 17.44 130.0 10630— IEEE 802.1 fac WiFi (GOMHz, MCS4, X 6.77 70.81 18.49 0.46 130.0 £9.6 % AAB 9Ope dutycycle) Y 8.04 1347 19.72 130.0 £ 7.75 73.08 19.73 130.0 10631— IEEE 802.11a¢ WiFi (GOMHz, MCS5, X 6.18 68.15 17.87 0.46 130.0 £9.6 % AAB 3Ope dutycycle) Y 6.78 70.26 18.39 130.0 2 644 69.57 16.23 130.0 10632— IEEE 802.1 fac WiFi (BOMHz, MCS6, X 6.23 69.30 17.98 0.46 130.0 £9.6 % AAB 90pe duty cycle) Y 6.24 68.58 17.58 130.0 2 6.37 69.33 18.15 130.0 10633— IEEE 802.1tac Wiri (GOMHz, MCST, x 5.76 eri72 1701 048 130.0 £96% AAB $Opc duty cycle) Y 6.09 68.11 17.17 130.0 2 5.89 §7.73_| 1716 130.0 10634— IEEE 802. 11a0 WiFi (BOMHz, MCSB, X 5.72 67.68 17.04 0.46 130.0 +9.0 % AAB SOpe duty cycle} Y 5.99 67.85 17.10 130.0 £ 5.58 67.80 17.25 130.0 10635— IEEE 802.11a¢ WiFi (GOMHz, MCS®, X 5.59 66.99 16.43 0.46 130.0 +9.6 % AAB 9Opc duty cycle) a 5.89 67.28 16.57 130.0 Z 5.76 67.16 16.69 130.0 10636— IEEE 802.1 1ac WiFi (160MHz, MCSO, X 6.19 68.00 1713 046 130.0 £86% AAG 90pc duty cycle) Y¥ 6.36 68.10 1715 130.0 2 6.35 68.20 17.38 130.0 10637— IEEE 802.11ac WiFi (1B0MHz, MCS1, X 6.46 68.76 17.50 0.46 1300 £96% AAC 9Ope duty cycle) ¥ 6.63 68.78 1747 130.0 £ 6.72 69.23 17.69 130.0 10638— IEEE 802.1 1ac WiFi (160MHz, MCS2, X 6.50 68.87 17.53 0.46 1300 £9.6% AAG 9Ope duty cycle) Y 6e3 6875 1744 130.0 2 6.72 69.20 17.85 130.0 Certificate No: EF3—4048_Jan18 Page 37 of 39

EF3DV3 — SN4048 January 9, 2018 ©02.1Tac (160MHz, . 0 & IEEE 802.11ac WiFi (160MHz, 1EEE 802.11ac WiFi (160MHz, 1ac WiFi (160MHz, IEEE 11ac WiFi (160MHz, MCSB, E 802.11ac 44 LTE—TDOD DMA, 10 MHz, E—TM 3.1, LTE—TDD (OFDMA, 15 MHz, E—TM 3.1, 44% TOD ( 20 MHz, E—TM 3.1, 44% Pulse Waveform Pulse Wavetorm (200rz, 20%) Certificate No: EF3—4048_Jan18 Page 38 of 39

EF3SDV3 — SN:4048 January 9, 2018 10660— Pulse Waveform (200Hz, 40%) xX 0.98 63.30 6.61 3.99 80.0 £9.6 % AAA Y 10000 10516 2165 80.0 2 10000 10596 2142 80.0 10661— Pulse Waveform (200Hz, 60%) X 0.56 62.24 5.43 2.22 100.0 £9.6 % AAA Y 10000 10368 1983 100.0 2 100.00 100.21 17.94 100.0 10662— Pulse Waveform (200Hz, 80%) X 0.16 60.00 336 0.97 1200 £96% AAA Y 100.00 10295 1813 120.0 2 99.98 90.06 1254 120.0 * 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: EF3—4048_Jan18 Page 39 of 39

Calibration Laboratory of «95 i sAz S Schweizerischer Kalibrierdienst Schmid & Partner M\ N7 ’E'. ; Service suisse détalonnage Engineering AG Lrresug g_ Servizio svizzero ditaratura Zeughausstrasse 43, 8004 Zurich, Switzerland h41/’?\\"“@ 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 Client TA—SH (Auden) Certificate No: CD835V3—1133_Nov17 CALIBRATION CERTIFICATE Object CD835V3 — SN: 1133 Calibration procedure(s) QA CAL—20.v6 Calibration procedure for dipoles in air Calibration date: November 22, 2017 This calibration certificate documents the traceability to national standards, which realize the physical units 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 04—Apr—17 (No. 217—02521/02522) Apr—18 Power sensor NRP—Z91 SN: 103244 04—Apr—17 (No. 217—02521) Apr—18 Power sensor NRP—Z91 SN: 103245 04—Apr—17 (No. 217—02522) Apr—18 Reference 20 dB Attenuator SN: 5058 (20k) 07—Apr—17 (No. 217—02528) Apr—18 Type—N mismatch combination SN: 5047.2 / 06327 07—Apr—17 (No. 217—02529) Apr—18 Probe ERSDV6 SN: 2336 30—Dec—16 (No. ER3—2336_Dec16) Dec—17 DAE4 SN: 781 18—Jul—17 (No, DAE4—781_Jul17) Jul—18 Secondary Standards ID # Check Date (in house) Scheduled Check Power meter Agilent 44198 SN: GB42420191 09—Oct—09 (in house check Oct—17) In house check: Oct—20 Power sensor HP E4412A SN: US38485102 O5—Jan—10 (in house check Oct—17) In house check: Oct—20 Power sensor HP 8482A SN: US37295597 09—Oct—09 (in house check Oct—17) In house check: Oct—20 RF generator R&S SMT—06 SN: 832289/011 27—Aug—12 (in house check Oct—17) In house check: Oct—20 Network Analyzer HP 8753E SN: US37390585 18—Oct—01 (in house check Oct—17) In house check: Oct—18 Name Function Signature Calibrated by: {Leif Klysner Laboratory Technician &/ % Approved by: |Katia Pokovie"*~" "‘Technical Manager *‘ m Issued: November 23, 2017 This calibration certificate shall not be reproduced exceptin full without written approval of the laboratory. Certificate No: CD835V3—1133_Nov17 Page 1 of 5

w94 Callbl:atlon Laboratory of Q\\\/\‘\/, /4 G Schwelzerischer Kalibrierdienst Schm[d & Eanner : Cc Service sulsso d‘étalonnage Englneenng AG T /‘\ & 5 Servizlo avizzero di taratura Zeughausstrasse 43, 8004 Zurich, Switzerland *4,‘fi\,a* Swiss Callbration 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 References [1] ANSN—C63.19—2011 American National Standard, Methods of Measurement of Compatibility between Wireless Communications Devices and Hearing Aids. Methods Applied and Interpretation of Parameters: Coordinate System:y—axis is in the direction of the dipole arms. z—axis is from the basis of the antenna (mounted on the table) towardsits feed point between the two dipole arms. x—axis is normalto the other axes. In coincidence with the standards [1], the measurement planes (probe sensor center) are selected to be at a distance of 15 mm above the top metal edge of the dipole arms. Measurement Conditions: Further details are available from the hardcopies at the end of the certificate. All figures stated in the certificate are valid at the frequency indicated. The forward powerto the dipole connector is set with a calibrated power meter connected and monitored with an auxiliary power meter connected to a directional coupler. While the dipole undertest is connected, the forward poweris adjusted to the same level. Antenna Positioning: The dipole is mounted on a HAC Test Arch phantom using the matching dipole positioner with the arms horizontal and the feeding cable coming from the floor, The measurements are performed in a shielded room with absorbers around the setup to reduce the reflections. It is verified before the mounting of the dipole under the Test Arch phantom, that its arms are perfectly in a line. It is installed on the HAC dipole positioner with its arms parallel below the dielectric reference wire and able to move elastically in vertical direction without changing its relative position to the top center of the Test Arch phantom. The vertical distanceto the probe is adjusted after dipole mounting with a DASY5 Surface Check job. Before the measurement, the distance between phantom surface and probe tip is verified. The proper measurement distanceis selected by choosing the matching section of the HAC Test Arch phantom with the proper device reference point (upper surface of the dipole) and the matching grid reference point (tip of the probe) considering the probe sensor offset. The vertical distance to the probeis essential for the accuracy. Feed Point Impedance and Return Loss: These parameters are measured using a HP 8753E Vector Network Analyzer. The impedance is specified at the SMA connector of the dipole. The influence of reflections was eliminating by applying the averaging function while moving the dipole in the air, at least 70cm away from any obstacles. E—field distribution: E field is measured in the x—y—plane with an isotropic ERSD—field probe with 100 mW forward powerto the antenna feed point. In accordance with [1], the scan area is 20mm wide, its length exceeds the dipole arm length (180 or $Omm). The sensor centeris 15 mm (in z) above the metal top of the dipole arms. Two 3D maxima are available near the end of the dipole arms. Assuming the dipole arms are perfectly in one line, the average of these two maxima (in subgrid 2 and subgrid 8) is determined to compensate for any non—parallelity to the measurement plane as well as the sensor displacement. The E—field value stated as calibration value represents the maximum of the interpolated 3D—E—field, in the plane above the dipole surface. The reported uncertainty of measurement is stated as the standard uncertainty of measurement multiplied by the covera ge factor k=2, which for a normal distribution corresponds to a coverage probability of approximately 95%. Certificate No: CD835V3—1133_Nov17 Page 2 of 5

C Measurement Conditions DASY system configuration, as far as not given on page 1. DASY Version DASY5 V52.10.0 Phantom HAC Test Arch Distance Dipole Top — Probe Center 15 mm Scan resolution dx, dy = 5 mm Frequency 835 MHz & 1 MHz Input power drift <0.05 dB Maximum Field values at 835 MHz E—field 15 mm above dipole surface condition Interpolated maximum Maximum measured above high end 100 mW input power 106.6 V/im = 40.56 dBV/m Maximum measured above low end 100 mW input power 104.9 V/m = 40.42 dBV/m Averaged maximum above arm 100 mW input power 105.8 V/m £ 12.8 % (k=2) Appendix (Additional assessments outside the scope of SCS 0108) Antenna Parameters Frequency Return Loss Impedance 800 MHz 16.1 dB 40.1 Q — 10.1 jQ 835 MHz 28.4 dB 52.7 Q + 2.8 jQ 900 MHz 17.0 dB 48.5 Q — 14.0 jQ 950 MHz 20.0 dB 49.4 9 + 10.0 jQ 960 MHz 15.0 dB 61.5 0+ 16.3 jQ 3.2 Antenna Design and Handling The calibration dipole has a symmetric geometry with a built—in two stub matching network, which leads to the enhanced bandwidth. The dipole is built of standard semirigid coaxial cable. The internal matching line is open ended. The antennais therefore open for DC signals. Do not apply force to dipole arms, as they areliable to bend. The soldered connections near the feedpoint may be damaged. After excessive mechanical stress or overheating, check the impedance characteristics to ensure that the internal matching network is not affected. After long term use with 40W radiated power, only a slight warming of the dipole near the feedpoint can be measured. Certificate No: CD835V3—1133_Nov17 Page 3 of 5

Impedance Measurement Plot 22 Nov 2017 16:35:16 CHI sii _Los 5 dB/REF —15 4B 11—28.368 dB 835.000 000 MHz CH1 Markers 2—16.147 dB Cor 800.000 MHz 3:—16.969 dB 900.000 MHz 41—20,0093 dB 950.000 MHz five 16 5:—15.047 dB 960.000 MHz H1d CH2 Si1 i U FS 1:52.717 0 2.02620 538.68 pH 835.000 000 MHz zmfi CH2 Markers 2 40.115 o Cor ~10.098 a ©00.000 MHz 3: 40.484 a ~14,021 n 900.000 MHz Av 18° 4149,404 9.976 &2A 9$50.000 MHz St 51.5%& & Hid 16.266 a 960.000 MHz CENTER 635.000 000 MHz SPAN 1 000.000 @00 MHz Certificate No: CD835V3—1133_Nov17 Page 4 of 5

DASY5 E—field Result Date: 22.11.2017 Test Laboratory: SPEAG Lab2 DUT: HAC—Dipole 835 MHz; Type: CD835V3; Serial: CD835V3 — SN: 1133 Communication System: UID 0 — CW; Frequency: 835 MHz Medium parameters used: 0 = 0 S/m, c = 1; p = 1000 kg/m‘ Phantom section: RF Section Measurement Standard: DASYS (IEEEAEC/ANSI €63.19—2011) DASY52 Configuration: Probe: ER3DV6 — SN2336; ConvF(1, 1, 1); Calibrated: 30.12.2016; Sensor—Surface:(Fix Surface) Electronics: DAE4 $n781; Calibrated: 13.07.2017 Phantom: HAC Test Arch with AMCC; Type: SD HAC PO1 BA; Serial: 1070 DASY52 52.10.0(1446); SEMCAD X 14.6.10(7417) Dipole E—Field measurement @ 835MHz/E—Scan — 835MHz d=15mm/Hearing Aid Compatibility Test (41x361x1): Interpolated grid; dx=0.5000 mm, dy=0.5000 mm Device Reference Point: 0, 0, —6.3 mm Reference Value = 109.1 V/m; Power Drift =—0.00 dB Applied MIF = 0.00 dB RF audio interference level = 40.56 dBV/m Emission category: M3 MIF scaled E—field Grid 1 M3 Grid 2 M3 Grid 3 M3 40.18 dBV/m|40.42 dBV/m |40.33 dBV/m Grid 4 M4 Grid 6 M4 35.75 dBV/m 35.79 dBV/m Grid 7 M3 Grid 8 M3 Grid 9 M3 40.44 dBV/m|40.56 dBV/m |40.39 dBV/m dB 0 —1.91 —3.82 5.12 —1.63 —9.54 0 dB = 106.6 V/m = 40.56 dBV/m Certificate No: CD835V3—1133_Nov17 Page 5 of 5

m Calibration a Laboratory of «u/s mt‘ Schwelzerischer Kalibrierdienst Schmid & Partner M\ wwA /E (S: Service sulsse d‘étalonnage Engineering AG pre 5 Servizlo svizzero di taratura Zeughausstrasse 43, 8004 Zurich, Switzerland *’fl“‘\‘} 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 Client ‘TASH (Auden) ' cA ‘Certificate No: CD1880V3—1115_Nov17 CALIBRATION CERTIFICATE Object CD1880V3 — SN: 1115 Calibration procedure(s) QA CaL—20v6 ~~~~ J ® 4 S Calibration procedure for dipoles in air Calibration date: November 22, 2017 esmm This calibration certificate documents the traceabilty to national standards, which realize the physical units 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 04—Apr—17 (No. 217—02521/02522) Apr—18 Power sensor NRP—Z91 SN: 103244 04—Apr—17 (No. 217—02521) Apr—18 Power sensor NRP—Z91 SN: 103245 04—Apr—17 (No. 217—02522) Apr—18 Reference 20 dB Attenuator SN: 5058 (20k) 07—Apr—17 (No. 217—02528) Apr—18 Type—N mismatch combination SN: 5047.2 / 06327 07—Apr—17 (No. 217—02529) Apr—18 Probe ER3DV6 SN: 2336 30—Dec—16 (No. ER3—2336_Dec16) Dec—17 DAE4 SN: 781 13—Jul—17 (No. DAE4—781_Jul17) JuM18 Secondary Standards ID # Check Date (in house) Scheduled Check Power meter Agilent 4419B SN: GB42420191 09—Oct—08 (in house check Oct—17) In house check: Oct—20 Power sensor HP E4412A SN: US38485102 05—Jan—10 (in house check Oct—17) In house check: Oct—20 Power sensor HP 8482A SN: US37295597 09—Oct—09(in house check Oct—17) In house check: Oct—20 RF generator R&S SMT—06 SN: 832283/011 27—Aug—12 (in house chack Oct—17) In house check: Oct—20 Network Analyzer HP 8753E SN: USs37390585 18—Oct—01 (in house chack Oct—17) In house check: Oct—18 Name Function Signature Calbrated by: (Leit Kiysnert mm m mmmmum=mtabsratory Technician \Zgé = Approved by: (Kata Pokovie T * ~mmomm—rechnical Manager ""* //;;: Issued: November 23, 2017 This calibration certificate shall not be reproduced except in full without written approval of the laboratory. Certificate No: CD1880V3—1115_Nov17 Page 1 of 5

nirw rewe rroprares Calibration Laboratory of i. Schweizerischer Kalibrierdienst a S : S Schmid & Partner M C Service suisse d‘étalonnage Engineering AG Le 5 Servizio svizzero dtaratura Zeughausstrasse 43, 8004 Zurich, Switzerland "ffas® Ns 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 References (1] ANS1—C63.19—2011 American National Standard, Methods of Measurement of Compatibility between Wireless Communications Devices and Hearing Aids. Methods Applied and Interpretation of Parameters: Coordinate System: y—axisis in the direction of the dipole arms. z—axis is from the basis of the antenna (mounted on the table) towards its feed point between the two dipole arms. x—axis is normal to the other axes. In coincidence with the standards [1], the measurement planes (probe sensor center) are selected to be at a distance of 15 mm above the top metal edge of the dipole arms. Measurement Conditions: Further details are available from the hardcopies at the end of the certificate. All figures stated in the certificate are valid at the frequency indicated. The forward power to the dipole connector is set with a calibrated power meter connected and monitored with an auxiliary power meter connected to a directional coupler. While the dipole undertest is connected, the forward power is adjusted to the same level. Antenna Positioning: The dipole is mounted on a HAC Test Arch phantom using the matching dipole positioner with the arms horizontal and the feeding cable coming from the floor. The measurements are performed in a shielded room with absorbers around the setup to reduce the reflections. It is verified before the mounting of the dipole under the Test Arch phantom, that its arms are perfectly in a line. It is installed on the HAC dipole positioner with its arms parallel below the dielectric reference wire and able to move elastically in vertical direction without changing its relative position to the top center of the Test Arch phantom. The vertical distance to the probeis adjusted after dipole mounting with a DASY5 Surface Check job. Before the measurement, the distance between phantom surface and probe tip is verified. The proper measurement distance is selected by choosing the matching section of the HAC Test Arch phantom with the proper device reference point (upper surface of the dipole) and the matching grid reference point (tip of the probe) considering the probe sensoroffset. The vertical distance to the probe is essential for the accuracy. Feed Point Impedance and Return Loss: These parameters are measured using a HP 8753E Vector Network Analyzer. The impedanceis specified at the SMA connector of the dipole. The influence of reflections was eliminating by applying the averaging function while moving the dipole in the air, at least 70cm away from any obstacles. E—field distribution: E field is measured in the x—y—plane with an isotropic ER3D—field probe with 100 mW forward powerto the antenna feed point. In accordance with [1], the scan area is 20mm wide,its length exceeds the dipole arm length (180 or 9Omm). The sensor center is 15 mm (in z) above the metal top of the dipole arms. Two 3D maxima are available near the end of the dipole arms. Assuming the dipole arms are perfectly in oneline, the average of these two maxima (in subgrid 2 and subgrid 8) is determined to compensate for any non—parallelity to the measurementplane as well as the sensor displacement. The E—field value stated as calibration value represents the maximum of the interpolated 3D—E—field, in the plane above the dipole surface. The reported uncertainty of measurement is stated as the standard uncertainty of measurement multiplied by the coverage factor k=2, which for a normaldistribution corresponds to a coverage probability of approximately 95%. Certificate No: CD1880V3—1115_Nov17 Page 2 of 5 11115 1EDUL C 3411 NOE NE 16 por rricire ce pa en g en en sw ns mc n nc n

C Measurement Conditions DASY system configuration, as far as not given on page 1. DASY Version DASYS V52.10.0 Phantom HAC Test Arch Distance Dipole Top — Probe Center 15 mm Scan resolution dx, dy = 5 mm Frequency 1880 MHz & 1 MHz Input power drift <0.05 dB Maximum Field values at 1880 MHz E—field 15 mm above dipole surface condition Interpolated maximum Maximum measured above high end 100 mW input power 90.5 V/m = 39.13 dBV/m Maximum measured above low end 100 mW input power 87.8 V/m = 38.87 dBV/m Averaged maximum above arm 100 mW input power 89.2 V/m 2 12.8 % (k=2) Appendix (Additional assessments outside the scope of SCS 0108) Antenna Parameters Frequency Return Loss Impedance 1730 MHz 31.0 dB 52.8 0 — 0.7 jQ 1880 MHz 21.1 dB 51.9 Q + 8.8 jQ 1900 MHz 21.6 dB 54.2 Q +7.6 jQ 1950 MHz 29.7 dB 52.3 Q + 2.4 jQ 2000 MHz 18.9 dB 46.8 Q + 10.6 jQ 3.2 Antenna Design and Handling The calibration dipole has a symmetric geometry with a built—in two stub matching network, which leads to the enhanced bandwidth. The dipole is built of standard semirigid coaxial cable. The internal matching line is open ended. The antenna is therefore open for DC signals. Do not apply force to dipole arms, as they are liable to bend. The soldered connections near the feedpoint may be damaged. After excessive mechanical stress or overheating, check the impedance characteristics to ensure that the internal matching network is not affected. After long term use with 40W radiated power, only a slight warming of the dipole near the feedpoint can be measured. Certificate No: CD1880V3—1115_Nov17 Page 3 of 5

Impedance Measurement Plot 22 Nov 2017 16143137 CHI) sii _Los 5 dB/REF —18 dB 11—21.108 dB i 680.000 000 MHz CH1 Markens Sn 21—91.012 dB 1.73000 GHz 31—21.639 dB 1.90000 GHz 41—29.691 4B 1.95000 GHz is 16 5:—18.864 dB 2.00000 GHz H1d CH2 $11 1 U Fs 1: 51.899 0 ©.7949 6 744.55 pH 1 880.000 000 MHz CH2 Markers ter 2: 52.916 a ~652.34 ma 1.73000 GHz * SAE a 7.95966 a 1.90000 GHz 4: 52.940 a is 4825 & 1.95000 GHz 5t 46.762 a Hia 10.611 a 200000 GHz CENTER 1 880.000 000 MHz SPaN 1 000.000 000 MHz Certificate No: CD1880V3—1115_Nov17 Page 4 of 5

DASY5 E—field Result Date: 22.11.2017 Test Laboratory: SPEAG Lab2 DUT: HAC Dipole 1880 MHz; Type: CD1880V3; Serial: CD1880V3 — SN: 1115 Communication System: UID 0 — CW; Frequency: 1880 MHz Medium parameters used: 0 =0 S/m, & = 1; p = 1000 kg/m‘ Phantom section: RF Section Measurement Standard: DASY5 (IEEEAEC/ANSI C63.19—2011) DASY52 Configuration: Probe: ER3DV6 — SN2336; ConvF(1, 1, 1); Calibrated: 30.12.2016; Sensor—Surface:(Fix Surface) Electronics: DAE4 $n781; Calibrated: 13.07.2017 Phantom: HAC Test Arch with AMCC; Type: SD HAC PO1 BA; Serial: 1070 DASY52 52.10.0(1446); SEMCAD X 14.6.10(7417) Dipole E—Field measurement @ 1880MHz/E—Scan — 1880MHz d=15mm/Hearing Aid Compatibility Test (41x181x1): Interpolated grid: dx=0.5000 mm, dy=0.5000 mm Device Reference Point: 0, 0, —6.3 mm Reference Value = 155.7 V/m; Power Drift =—0.01 dB Applied MIF = 0.00 dB RF audio interference level = 39.13 dBV/m Emission category: M2 MIF scaled E—field Grid 1 M2 |Grid 2 M2 Grid 3 M2 38.94 dBV/m[39.13 dBv/m 39.02 dBV/m Grid 4 M2 |c Grid 6 M2 36.82 dBV/m |36.82 dBv/m Grid 7 M2 |Grid 8 M2 Grid 9 M2 38.67 dBV/m|38.87 dBV/m 38.79 dBV/m —0.97 "1.93 —2.90 —3.86 ~4.83 0 dB = 90.50 V/m = 39.13 dBV/m Certificate No: CD1880V3—1115_Nov17 Page 5 of 5

Calibration Laboratory of CE o Schweizerischer Kailbrierdlonst Schmid & Partner * g Service suisse d‘étalonnage Engineering AG P < Servizio svizzero di taratura Mugnlmhuugsmm Switzerand @ \\_ fi" S swiss Colibration 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 calioration certificates This callbration certificate documents the traceabilty to national standards, which realize the physical units of measurements (St). The measurements and the uncertainties with confidence probabilty are given on the following pages and are part of the certificate. All callbrations have been conducted in the closed laboratory laclity: environment temperature (22 x 3)°G and humnidity < 70%. Callbration Equipment used (M&TE crtical for calibration) Primary Standards 10 Cal Date (Certiicate No)) Scheduled Calibration Keithley Multimeter Typa 2001 SN: 0810278 31+Auge17 (No#21092) Aug18 Secondary Standards 10 i Chock Date (in house) Sehediuled Chack Auto DAE Calibration Unit §E UWS 053 AA 1001 04Jan—18 (in house check) In house check: Jan—10 Callbrator Box V2.1 §E UMS 006 AA 1002 C4Jan—18 (in house check) In house chacic Jan—19 Approved by: ‘This calbration certificate shall not be repraduced except in full without wntten approval of the laboratory. Certificate No: DAE4—1317_MartB Page 1 of 5

Calibration Laboratory of Cl‘ uns Schweltorlscher Kallbrlerdianst Schmid & Partner 6 se +« 8 Service sulsse d‘étaionnage Engineering AG 5 f o C sorvitio avizzors di taraturn Zoughausstrasse 43, 8004 Zurich, Switzertand *ffarys Wesys 5 Swiss CalibrationService Accrecited by the Sutss Accreditation Service (SAS) Accraditation No.: SCS 0108 The Swiss Accreditation Service is ona of the signatories to the EA Multilateral Agreement for the recognition of callbration certlficatas Glossary DAE data acquisition electronics Cannector angle information used in DASY system to align probe sensor X to the rabot coordinate system. Methods Applied and Interpretation of Parameters «DC Voltage Measurement: Calibration Factor assessed for use in DASY system by comparison with a calibrated instrument traceable to national standards. The figure given corresponds to the full scale range of the voltmeter in the respective range. «_ Connector angle; The angle of the connector is assessed measuring the angle mechanically by a tool inserted. Uncertainty is not required. «* The following parameters as documented in the Appendix contain technical information as a result from the performance lest and require no uncertainty. DC Voltage Measurement Linearity: Verification of the Lineatity at +10% and —10% of the nominal calibration voltage. Influence of offset voltage is included in this measurement. Common mode sensitivity: Influence of a positive or negative common mode voltage on the differential measurement. Channel separation: Influence of a voltage on the neighbor channels not subject to an input voltage. AD Converter Values with inputs shorted: Values on the internal AD converter corresponding to zero input valtage Input Offset Measurement. Output voltage and statistical results over a large number of zero voltage measurements. Input Offset Current: Typical value for information; Maximum channel input offset current, not considering the input resistance. Input resistance: Typical value for information: DAE input resistance at the connector, during internal auto—zeroing and during measurement. Low Battery Alarm Voltage: Typical value for information. Below this voltage, a battery alarm signal is generated. Power consumption: Typical value for information. Supply currents in various operating modes. Certificate No: DAE4—1317_MartB Page 2 of &

DC Voltage Measurement AID — Converter Resolution nominal High Renge: 1LSB= 6ApV , full range= ~100...4300 mV Low Range: 1LSB = 61nV , full range = ~1.u...+gmV DASY measurement parameters: Auto Zero Time: 3 see; Measuring time; 3 se Calibration Factors x Y 2 High Range 403.713 + 0,02% (k=8) 404,474 £0,02% (k=2) 403.830+0.02% (k=2) Low Range 8.97916 + 1.50% (k=2) 3.99031 + 1.50% (k=2) 9.96832+1.50% (k=2) Connector Angle [ Connector Angle to be used in DASY system s82.0°41° Cartficate No: DAE4—1317_Mar18 Page Sof 5

Appendix (Additional assessments outside the scope of SCSO108) 1. DC Voltage Linearity High Range Reading (@V) Difference (uV) Error (%) Channel X + Input 200033.59 2.49 1.00 Channel X +Input 20006.23 0.60 0.00 Channel X ~Input ©20003.30 2.01 —0.01 Channel ¥ + Input 200032.59 —5.60 —0.00 Channel Y + Input 20003.70 ~1.29 —0.01 Channel ¥ +Input +20004.09 1.35 —0.01 Channel 2 + Input 200035.04 —0.93 —0.00 Channel Z + Input 20005.33 0.22 ~0.00 Channel Z =Input ~20006.76 125 0.01 Low Range Reading (uV) Difference (1V) Error (%) Channel X +Input 2001.75 0.20 0.01 Channel X +Input 200.99 —0.43 +0.21 Channel X ~Input 4197113 149 0.75 Channel Y + Input 2001.26 —0.25 +0.01 Channel ¥ + Input 200.67 —0.55 ~0.28 Channel Y —Input ~199.10 —0.34 0.17 Channel 2 + Input 2000.98 —0.47 —0.02 Channel Z + Input 200.06 147 —0.58 Channel Z =Input +199.95 119 0.60 2. Common mode sensitivity DASY measurement parameters: Auto Zero Time: 3 seo; Measuting time: 3 see Common mode High Range Low Range Input Voltage (mV) Average Reading (1V) Average Reading (xV) Channel X 200 11.88 10.25 ~200 5.60 ~10.35 Channel ¥ 200 11.35 11.40 =200 ~13,19 —12.90 Channel 2 200 1.73 1.34 200 —2.98 358 3. Channel separation DASY measurement parameters: Auto Zero Time: 3 see; Measuring time: 3. sec Input Voltage (mV) Channel X (iV) Channel ¥ (wV) ChannelZ(V) Channel X 200 — 222 ~4.03 Channel Y 200 8.79 — 8.02 Channel 2 200 10.60 605 Certificate No: DAE4—1317_Mart8 Page 4 of 5

4. AD—Converter Values with inputs shorted DASY measurement parameters; Auto Zero Time: 3 sec: Measuring time: 3 see High Range (LSB) Low Range (LSB) Channel K 15758 16030 Channel Y 16498 16052 Channel 2 16107 15724 5. Input Offset Measurement DASY measurement parameters: Auta Zeto Time: 3 sec; Measuring time: 3 sec Input 10M0 Average (gV) min. Oftset(@V) max. Offset (uv) 5** 'f:;’"“"“ Channel X 103 —0.09 236 048 Channel Y «.33 Alul 1122 0.54 Channel Z <1.81 —3.67 —0.40 0.67 6. Input Offset Current Nominal Input circuitry offset current on all channols: <25tA 7. Input Resistance (Typical values for information) Zeroing (kOhm) Measuring {(MOhm) Channel X 200 200 Channel Y 200 200 Channel 2 200 200 8. Low Battery Alarm Voltage (Typical values for intormation} Typical values Alarm Level (VDC) Supply (+ Voo) +789 Supply (— Vee) T6 9. Power Consumption (Typical values for information) Typical values Switched off (mA) Stand by (mA) Transmitting (mA) Supply (+ Vee) +0.01 +6 +14 Supply (— Vee) ~0.01 —8 «9 Certificate No: DAE4—1317_Mart8 Page 5 of 5

HAC Test Report Report No: R1810A0448‐H1 ANNEX G: The EUT Appearances and Test Configuration EUT Picture 1: Constituents of EUT TA Technology (Shanghai) Co., Ltd. TA-MB-04-001H Page 88 of 89 This report shall not be reproduced except in full, without the written approval of TA Technology (Shanghai) Co., Ltd.

HAC Test Report Report No: R1810A0448‐H1 Picture 2: Test Setup TA Technology (Shanghai) Co., Ltd. TA-MB-04-001H Page 89 of 89 This report shall not be reproduced except in full, without the written approval of TA Technology (Shanghai) Co., Ltd.


Document Created: 2018-11-08 16:19:11
Document Modified: 2018-11-08 16:19:11
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