I19Z61530-SEM01_SAR_Rev1_part2

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RF Exposure Info

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No.I19Z61530-SEM01 Page 136 of 240 2600 MHz Date: 9/5/2019 Electronics: DAE4 Sn771 Medium: Head 2600 MHz Medium parameters used: f = 2600 MHz; σ =1.926 mho/m; εr = 39.01; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 2600 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(7.19,7.19,7.19) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Reference Value = 117.9 V/m; Power Drift = -0.07 Fast SAR: SAR(1 g) = 13.76 W/kg; SAR(10 g) = 6.16 W/kg Maximum value of SAR (interpolated) = 25.27 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =117.9 V/m; Power Drift = -0.07 dB Peak SAR (extrapolated) = 28.65 W/kg SAR(1 g) = 14.14 W/kg; SAR(10 g) = 6.26 W/kg Maximum value of SAR (measured) = 23.52 W/kg 0 dB = 23.52 W/kg = 13.71 dB W/kg Fig.B.11 validation 2600 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 137 of 240 2600 MHz Date: 9/5/2019 Electronics: DAE4 Sn771 Medium: Body 2600 MHz Medium parameters used: f = 2600 MHz; σ =2.171 mho/m; εr = 52.9; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 2600 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(7.49,7.49,7.49) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Reference Value = 110.69 V/m; Power Drift = 0.08 Fast SAR: SAR(1 g) = 13.75 W/kg; SAR(10 g) = 6.26 W/kg Maximum value of SAR (interpolated) = 23.02 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =110.69 V/m; Power Drift = 0.08 dB Peak SAR (extrapolated) = 28.66 W/kg SAR(1 g) = 13.64 W/kg; SAR(10 g) = 6.2 W/kg Maximum value of SAR (measured) = 23.45 W/kg 0 dB = 23.45 W/kg = 13.7 dB W/kg Fig.B.12 validation 2600 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 138 of 240 5250 MHz Date: 9/6/2019 Electronics: DAE4 Sn771 Medium: Head 5250 MHz Medium parameters used: f = 5250 MHz; σ =4.763 mho/m; εr = 36.6; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 5250 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(5.39,5.39,5.39) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Maximum value of SAR (interpolated) = 17.71 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =75.27 V/m; Power Drift = -0.06 dB Peak SAR (extrapolated) = 27.81 W/kg SAR(1 g) = 19.72 W/kg; SAR(10 g) = 5.89 W/kg Maximum value of SAR (measured) = 17.94 W/kg 0 dB = 17.94 W/kg = 12.54 dB W/kg Fig.B.13 validation 5250 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 139 of 240 5250 MHz Date: 9/6/2019 Electronics: DAE4 Sn771 Medium: Body 5250 MHz Medium parameters used: f = 5250 MHz; σ =5.262 mho/m; εr = 49.88; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 5250 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(4.76,4.76,4.76) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Maximum value of SAR (interpolated) = 17.63 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =69.78 V/m; Power Drift = -0.07 dB Peak SAR (extrapolated) = 29.43 W/kg SAR(1 g) = 18.92 W/kg; SAR(10 g) = 5.27 W/kg Maximum value of SAR (measured) = 18.14 W/kg 0 dB = 18.14 W/kg = 12.59 dB W/kg Fig.B.14 validation 5250 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 140 of 240 5600 MHz Date: 9/6/2019 Electronics: DAE4 Sn771 Medium: Head 5600 MHz Medium parameters used: f = 5600 MHz; σ =5.133 mho/m; εr = 34.97; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 5600 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(5.06,5.06,5.06) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Maximum value of SAR (interpolated) = 19.87 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =73.76 V/m; Power Drift = -0.01 dB Peak SAR (extrapolated) = 30.62 W/kg SAR(1 g) = 20.71 W/kg; SAR(10 g) = 6.08 W/kg Maximum value of SAR (measured) = 19.37 W/kg 0 dB = 19.37 W/kg = 12.87 dB W/kg Fig.B.15 validation 5600 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 141 of 240 5600 MHz Date: 9/6/2019 Electronics: DAE4 Sn771 Medium: Body 5600 MHz Medium parameters used: f = 5600 MHz; σ =5.701 mho/m; εr = 48.74; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 5600 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(4.23,4.23,4.23) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Maximum value of SAR (interpolated) = 18.55 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =68.46 V/m; Power Drift = 0.09 dB Peak SAR (extrapolated) = 32.63 W/kg SAR(1 g) = 19.91 W/kg; SAR(10 g) = 5.48 W/kg Maximum value of SAR (measured) = 18.77 W/kg 0 dB = 18.77 W/kg = 12.73 dB W/kg Fig.B.16 validation 5600 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 142 of 240 5750 MHz Date: 9/6/2019 Electronics: DAE4 Sn771 Medium: Head 5750 MHz Medium parameters used: f = 5750 MHz; σ =5.263 mho/m; εr = 35.2; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 5750 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(5.07,5.07,5.07) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Maximum value of SAR (interpolated) = 18.84 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =71.11 V/m; Power Drift = 0.06 dB Peak SAR (extrapolated) = 30.89 W/kg SAR(1 g) = 19.97 W/kg; SAR(10 g) = 5.84 W/kg Maximum value of SAR (measured) = 19.02 W/kg 0 dB = 19.02 W/kg = 12.79 dB W/kg Fig.B.17 validation 5750 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 143 of 240 5750 MHz Date: 9/6/2019 Electronics: DAE4 Sn771 Medium: Body 5750 MHz Medium parameters used: f = 5750 MHz; σ =5.463 mho/m; εr = 47.79; ρ = 1000 kg/m3 Ambient Temperature: 22.5oC Liquid Temperature: 22.3oC Communication System: CW Frequency: 5750 MHz Duty Cycle: 1:1 Probe: EX3DV4 – SN3617 ConvF(4.36,4.36,4.36) System Validation /Area Scan (81x191x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm Maximum value of SAR (interpolated) = 19.24 W/kg System Validation /Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value =66.33 V/m; Power Drift = 0.06 dB Peak SAR (extrapolated) = 33.99 W/kg SAR(1 g) = 19.08 W/kg; SAR(10 g) = 5.38 W/kg Maximum value of SAR (measured) = 19.09 W/kg 0 dB = 19.09 W/kg = 12.81 dB W/kg Fig.B.18 validation 5750 MHz 250mW ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 144 of 240 The SAR system verification must be required that the area scan estimated 1-g SAR is within 3% of the zoom scan 1-g SAR. Table B.1 Comparison between area scan and zoom scan for system verification Area scan Zoom scan Date Band Position Drift (%) (1g) (1g) 750 Head 2.18 2.14 1.87 2019-9-1 750 Body 2.17 2.18 -0.46 835 Head 2.47 2.4 2.92 2019-9-2 835 Body 2.4 2.39 0.42 1700 Head 9.1 8.99 1.22 2019-9-3 1700 Body 9.23 9.33 -1.07 1900 Head 9.81 9.97 -1.60 2019-9-4 1900 Body 9.82 9.77 0.51 2450 Head 13.02 12.86 1.24 2019-9-5 2450 Body 12.93 13.2 -2.05 2600 Head 2.18 2.14 1.87 2019-9-5 2600 Body 2.17 2.18 -0.46 ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 145 of 240 ANNEX C SAR Measurement Setup C.1 Measurement Set-up The Dasy4 or DASY5 system for performing compliance tests is illustrated above graphically. This system consists of the following items: Picture C.1SAR Lab Test Measurement Set-up ⚫ A standard high precision 6-axis robot (StäubliTX=RX family) with controller, teach pendant and software. An arm extension for accommodating the data acquisition electronics (DAE). ⚫ An isotropic field probe optimized and calibrated for the targeted measurement. ⚫ A data acquisition electronics (DAE) which performs the signal amplification, signal multiplexing, AD-conversion, offset measurements, mechanical surface detection, collision detection, etc. The unit is battery powered with standard or rechargeable batteries. The signal is optically transmitted to the EOC. ⚫ The Electro-optical converter (EOC) performs the conversion from optical to electrical signals for the digital communication to the DAE. To use optical surface detection, a special version of the EOC is required. The EOC signal is transmitted to the measurement server. ⚫ The function of the measurement server is to perform the time critical tasks such as signal filtering, control of the robot operation and fast movement interrupts. ⚫ The Light Beam used is for probe alignment. This improves the (absolute) accuracy of the probe positioning. ⚫ A computer running WinXP and the DASY4 or DASY5 software. ⚫ Remote control and teach pendant as well as additional circuitry for robot safety such as ⚫ warning lamps, etc. ⚫ The phantom, the device holder and other accessories according to the targeted measurement. ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 146 of 240 C.2 Dasy4 or DASY5 E-field Probe System The SAR measurements were conducted with the dosimetric probe designed in the classical triangular configuration and optimized for dosimetric evaluation. The probe is constructed using the thick film technique; with printed resistive lines on ceramic substrates. The probe is equipped with an optical multifiber line ending at the front of the probe tip. It is connected to the EOC box on the robot arm and provides an automatic detection of the phantom surface. Half of the fibers are connected to a pulsed infrared transmitter, the other half to a synchronized receiver. As the probe approaches the surface, the reflection from the surface produces a coupling from the transmitting to the receiving fibers. This reflection increases first during the approach, reaches maximum and then decreases. If the probe is flatly touching the surface, the coupling is zero. The distance of the coupling maximum to the surface is independent of the surface reflectivity and largely independent of the surface to probe angle. The DASY4 or DASY5 software reads the reflection durning a software approach and looks for the maximum using 2nd ord curve fitting. The approach is stopped at reaching the maximum. Probe Specifications: Model: ES3DV3, EX3DV4 Frequency 10MHz — 6.0GHz(EX3DV4) Range: 10MHz — 4GHz(ES3DV3) Calibration: In head and body simulating tissue at Frequencies from 835 up to 5800MHz Linearity: ± 0.2 dB(30 MHz to 6 GHz) for EX3DV4 Picture C.2Near-field Probe ± 0.2 dB(30 MHz to 4 GHz) for ES3DV3 DynamicRange: 10 mW/kg — 100W/kg Probe Length: 330 mm Probe Tip Length: 20 mm Body Diameter: 12 mm Tip Diameter: 2.5 mm (3.9 mm for ES3DV3) Tip-Center: 1 mm (2.0mm for ES3DV3) Application:SAR Dosimetry Testing Compliance tests ofmobile phones Dosimetry in strong gradient fields Picture C.3E-field Probe C.3 E-field Probe Calibration Each E-Probe/Probe Amplifier combination has unique calibration parameters. A TEM cell calibration procedure is conducted to determine the proper amplifier settings to enter in the probe parameters. The amplifier settings are determined for a given frequency by subjecting the probe to a known E-field density (1 mW/cm2) using an RF Signal generator, TEM cell, and RF Power Meter. The free space E-field from amplified probe outputs is determined in a test chamber. This calibration can be performed in a TEM cell if the frequency is below 1 GHz and inn a waveguide or other methodologies above 1 GHz for free space. For the free space calibration, the probe is placed ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 147 of 240 in the volumetric center of the cavity and at the proper orientation with the field. The probe is then rotated 360 degrees until the three channels show the maximum reading. The power density readings equates to 1 mW/cm2.. E-field temperature correlation calibration is performed in a flat phantom filled with the appropriate simulated brain tissue. The E-field in the medium correlates with the temperature rise in the dielectric medium. For temperature correlation calibration a RF transparent thermistor-based temperature probe is used in conjunction with the E-field probe. T SAR = C t Where: ∆t = Exposure time (30 seconds), C = Heat capacity of tissue (brain or muscle), ∆T = Temperature increase due to RF exposure. E  2 SAR =  Where: σ = Simulated tissue conductivity, ρ = Tissue density (kg/m3). C.4 Other Test Equipment C.4.1 Data Acquisition Electronics(DAE) The data acquisition electronics consist of a highly sensitive electrometer-grade preamplifier with auto-zeroing, a channel and gain-switching multiplexer, a fast 16 bit AD-converter and a command decoder with a control logic unit. Transmission to the measurement server is accomplished through an optical downlink for data and status information, as well as an optical uplink for commands and the clock. The mechanical probe mounting device includes two different sensor systems for frontal and sideways probe contacts. They are used for mechanical surface detection and probe collision detection. The input impedance of the DAE is 200 MOhm; the inputs are symmetrical and floating. Common mode rejection is above 80 dB. PictureC.4: DAE ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 148 of 240 C.4.2 Robot The SPEAG DASY system uses the high precision robots (DASY4: RX90XL; DASY5: RX160L) type from Stäubli SA (France). For the 6-axis controller system, the robot controller version from Stäubli is used. The Stäubli robot series have many features that are important for our application: ➢ High precision (repeatability 0.02mm) ➢ High reliability (industrial design) ➢ Low maintenance costs (virtually maintenance free due to direct drive gears; no belt drives) ➢ Jerk-free straight movements (brushless synchron motors; no stepper motors) ➢ Low ELF interference (motor control fields shielded via the closed metallic construction shields) Picture C.5DASY 4 Picture C.6DASY 5 C.4.3 Measurement Server The Measurement server is based on a PC/104 CPU broad with CPU (dasy4: 166 MHz, Intel Pentium; DASY5: 400 MHz, Intel Celeron), chipdisk (DASY4: 32 MB; DASY5: 128MB), RAM (DASY4: 64 MB, DASY5: 128MB). The necessary circuits for communication with the DAE electronic box, as well as the 16 bit AD converter system for optical detection and digital I/O interface are contained on the DASY I/O broad, which is directly connected to the PC/104 bus of the CPU broad. The measurement server performs all real-time data evaluation of field measurements and surface detection, controls robot movements and handles safety operation. The PC operating system cannot interfere with these time critical processes. All connections are supervised by a watchdog, and disconnection of any of the cables to the measurement server will automatically disarm the robot and disable all program-controlled robot movements. Furthermore, the measurement server is equipped with an expansion port which is reserved for future applications. Please note that this expansion port does not have a standardized pinout, and therefore only devices provided by SPEAG can be connected. Devices from any other supplier could seriously damage the measurement server. ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 149 of 240 Picture C.7 Server for DASY 4 Picture C.8 Server for DASY 5 C.4.4 Device Holder for Phantom The SAR in the phantom is approximately inversely proportional to the square of the distance between the source and the liquid surface. For a source at 5mm distance, a positioning uncertainty of ±0.5mm would produce a SAR uncertainty of ±20%. Accurate device positioning is therefore crucial for accurate and repeatable measurements. The positions in which the devices must be measured are defined by the standards. The DASY device holder is designed to cope with the different positions given in the standard. It has two scales for device rotation (with respect to the body axis) and device inclination (with respect to the line between the ear reference points). The rotation centers for both scales are the ear reference point (ERP). Thus the device needs no repositioning when changing the angles. The DASY device holder is constructed of low-loss POM material having the following dielectric parameters: relative permittivity  =3 and loss tangent  =0.02. The amount of dielectric material has been reduced in the closest vicinity of the device, since measurements have suggested that the influence of the clamp on the test results could thus be lowered. <Laptop Extension Kit> The extension is lightweight and made of POM, acrylic glass and foam. It fits easily on the upper part of the Mounting Device in place of the phone positioner. The extension is fully compatible with the Twin-SAM and ELI phantoms. Picture C.9-1: Device Holder Picture C.9-2: Laptop Extension Kit ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 150 of 240 C.4.5 Phantom The SAM Twin Phantom V4.0 is constructed of a fiberglass shell integrated in a table. The shape of the shell is based on data from an anatomical study designed to Represent the 90th percentile of the population. The phantom enables the dissymmetric evaluation of SAR for both left and right handed handset usage, as well as body-worn usage using the flat phantom region. Reference markings on the Phantom allow the complete setup of all predefined phantom positions and measurement grids by manually teaching three points in the robot. The shell phantom has a 2mm shell thickness (except the ear region where shell thickness increases to 6 mm). Shell Thickness: 2±0. 2 mm Filling Volume: Approx. 25 liters Dimensions: 810 x l000 x 500 mm (H x L x W) Available: Special Picture C.10: SAM Twin Phantom ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 151 of 240 ANNEX D Position of the wireless device in relation to the phantom D.1 General considerations This standard specifies two handset test positions against the head phantom – the “cheek” position and the “tilt” position. wt Width of the handset at the level of the acoustic wb Width of the bottom of the handset A Midpoint of the width wt of the handset at the level of the acoustic output B Midpoint of the width wb of the bottom of the handset Picture D.1-a Typical “fixed” case handset Picture D.1-b Typical “clam-shell” case handset Picture D.2 Cheek position of the wireless device on the left side of SAM ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 152 of 240 Picture D.3 Tilt position of the wireless device on the left side of SAM D.2 Body-worn device A typical example of a body-worn device is a mobile phone, wireless enabled PDA or other battery operated wireless device with the ability to transmit while mounted on a person’s body using a carry accessory approved by the wireless device manufacturer. Picture D.4Test positions for body-worn devices D.3 Desktop device A typical example of a desktop device is a wireless enabled desktop computer placed on a table or desk when used. The DUT shall be positioned at the distance and in the orientation to the phantom that corresponds to the intended use as specified by the manufacturer in the user instructions. For devices that employ an external antenna with variable positions, tests shall be performed for all antenna positions specified. Picture8.5 show positions for desktop device SAR tests. If the intended use is not specified, the device shall be tested directly against the flat phantom. ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 153 of 240 Picture D.5 Test positions for desktop devices D.4 DUT Setup Photos Picture D.6 ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 154 of 240 ANNEX E Equivalent Media Recipes The liquid used for the frequency range of 800-3000 MHz consisted of water, sugar, salt, preventol, glycol monobutyl and Cellulose. The liquid has been previously proven to be suited for worst-case. The Table E.1 shows the detail solution. It’s satisfying the latest tissue dielectric parameters requirements proposed by the IEEE 1528 and IEC 62209. TableE.1: Composition of the Tissue Equivalent Matter Frequency 1900 1900 2450 2450 5800 5800 835Head 835Body (MHz) Head Body Head Body Head Body Ingredients (% by weight) Water 41.45 52.5 55.242 69.91 58.79 72.60 65.53 65.53 Sugar 56.0 45.0 \ \ \ \ \ \ Salt 1.45 1.4 0.306 0.13 0.06 0.18 \ \ Preventol 0.1 0.1 \ \ \ \ \ \ Cellulose 1.0 1.0 \ \ \ \ \ \ Glycol \ \ 44.452 29.96 41.15 27.22 \ \ Monobutyl Diethylenglycol \ \ \ \ \ \ 17.24 17.24 monohexylether Triton X-100 \ \ \ \ \ \ 17.24 17.24 Dielectric ε=41.5 ε=55.2 ε=40.0 ε=53.3 ε=39.2 ε=52.7 ε=35.3 ε=48.2 Parameters σ=0.90 σ=0.97 σ=1.40 σ=1.52 σ=1.80 σ=1.95 σ=5.27 σ=6.00 Target Value Note: There are a little adjustment respectively for 750, 1750, 2600, 5200, 5300 and 5600 based on the recipe of closest frequency in table E.1. ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 155 of 240 ANNEX F System Validation The SAR system must be validated against its performance specifications before it is deployed. When SAR probes, system components or software are changed, upgraded or recalibrated, these must be validated with the SAR system(s) that operates with such components. Table F.1: System Validation for 3617 Probe SN. Liquid name Validation date Frequency point Status (OK or Not) 3617 Head 750MHz Feb.14,2019 750 MHz OK 3617 Head 850MHz Feb.14,2019 835 MHz OK 3617 Head 900MHz Feb.14,2019 900 MHz OK 3617 Head 1750MHz Feb.14,2019 1750 MHz OK 3617 Head 1810MHz Feb.14,2019 1810 MHz OK 3617 Head 1900MHz Feb.15,2019 1900 MHz OK 3617 Head 2000MHz Feb.15,2019 2000 MHz OK 3617 Head 2100MHz Feb.15,2019 2100 MHz OK 3617 Head 2300MHz Feb.15,2019 2300 MHz OK 3617 Head 2450MHz Feb.15,2019 2450 MHz OK 3617 Head 2600MHz Feb.16,2019 2600 MHz OK 3617 Head 3500MHz Feb.16,2019 3500 MHz OK 3617 Head 3700MHz Feb.16,2019 3700 MHz OK 3617 Head 5200MHz Feb.16,2019 5250 MHz OK 3617 Head 5500MHz Feb.16,2019 5600 MHz OK 3617 Head 5800MHz Feb.16,2019 5800 MHz OK 3617 Body 750MHz Feb.16,2019 750 MHz OK 3617 Body 850MHz Feb.13,2019 835 MHz OK 3617 Body 900MHz Feb.13,2019 900 MHz OK 3617 Body 1750MHz Feb.13,2019 1750 MHz OK 3617 Body 1810MHz Feb.13,2019 1810 MHz OK 3617 Body 1900MHz Feb.13,2019 1900 MHz OK 3617 Body 2000MHz Feb.17,2019 2000 MHz OK 3617 Body 2100MHz Feb.17,2019 2100 MHz OK 3617 Body 2300MHz Feb.17,2019 2300 MHz OK 3617 Body 2450MHz Feb.17,2019 2450 MHz OK 3617 Body 2600MHz Feb.17,2019 2600 MHz OK 3617 Body 3500MHz Feb.12,2019 3500 MHz OK 3617 Body 3700MHz Feb.12,2019 3700 MHz OK 3617 Body 5200MHz Feb.12,2019 5250 MHz OK 3617 Body 5500MHz Feb.12,2019 5600 MHz OK 3617 Body 5800MHz Feb.12,2019 5800 MHz OK ©Copyright. All rights reserved by CTTL.

No.I19Z61530-SEM01 Page 156 of 240 ANNEX G Probe Calibration Certificate Probe 3617 Calibration Certificate ©Copyright. All rights reserved by CTTL.

() R Calibration Laboratory of Schmid & Partner Engineering AG Zeughausstrasse 43, 8004 Zurich, Switzerland fi“@"’& ifi\t_//El Lorne IE}". 4'/,,/'fi\\“\c g ( 53 Schweizerischer Kalibrierdienst Service suisse d‘étalonnage Servizio svizzero di taratura Swiss Calibration Service Accredited by the Swiss Accreditation Service (SAS) Accreditation No.: SCS 0108 The Swiss Accreditation Service is one ofthe signatories to the EA Multilateral Agreementfor the recognition of calibration certificates Glossary: TSL tissue simulating liquid NORMx,y,z sensitivity in free space ConvF sensitivity in TSL / NORMx,y,z DCP diode compression point CF crest factor (1/duty_cycle) of the RF signal A, B, C, D modulation dependent linearization parameters Polarization q ip rotation around probe axis Polarization 8 8 rotation around an axis that is in the plane normal to probe axis (at measurement center), i.e., $ = 0 is normal to probe axis Connector Angle information used in DASY system to align probe sensor X to the robot coordinate system 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 ©) 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" Methods Applied and Interpretation of Parameters: NORMx,y,z: Assessed for E—field polarization 9 = 0 (f < 900 MHz in TEM—cell; f > 1800 MHz: R22 waveguide). NORMx,y,z are only intermediate values, i.e., the uncertainties of NORMx,y,z does not affect the E*—field uncertainty inside TSL (see below ConvF). NORM(Mx,y,z = NORMx,y,z * frequency_response (see Frequency Response Chart). This linearization is implemented in DASY4 software versions later than 4.2. The uncertainty of the frequency response is included in the stated uncertainty of ConvF. DCPx,y,z: DCP are numerical linearization parameters assessed based on the data of power sweep with CW signal (no uncertainty required). DCP does not depend on frequency nor media. PAR: PAR is the Peak to Average Ratio that is not calibrated but determined based on the signal characteristics Axy.z; Bxy.z: Cx,y,z; Dx,y,z; VRx,y,z: A, B, C, D are numerical linearization parameters assessed based on the data of power sweep for specific modulation signal. The parameters do not depend on frequency nor media. VR is the maximum calibration range expressed in RMS voltage across the diode. ConvF and Boundary Effect Parameters: Assessed in flat phantom using E—field (or Temperature Transfer Standard for f < 800 MHz) and inside waveguide using analytical field distributions based on power measurements for f > 800 MHz. The same setups are used for assessment of the parameters applied for boundary compensation (alpha, depth) of which typical uncertainty values are given. These parameters are used in DASY4 software to improve probe accuracy close to the boundary. The sensitivity in TSL corresponds to NORMx,y,z * ConvF whereby the uncertainty corresponds to that given for ConvF. A frequency dependent ConvF is used in DASY version 4.4 and higher which allows extending the validity from + 50 MHz to + 100 MHz. Spherical isotropy (3D deviation from isotropy): in a field of low gradients realized using a flat phantom exposed by a patch antenna. Sensor Offset: The sensoroffset corresponds to the offset of virtual measurement center from the probe tip (on probe axis). No tolerance required. Connector Angle: The angle is assessed using the information gained by determining the NORMx (no uncertainty required). Certificate No: EX3—3617_Jan19 Page 2 of 19

® EX3DV4 — SN:3617 DASY/EASY — Parameters of Probe: EX3DV4 — SN:3617 Basic Calibration Parameters Sensor X Sensor Y Sensor Z January 31, 2019 Unc (k=2) Norm (uV/(V/m))* 0.35 0.21 0.32 101 % DCP (mV)" 102.9 95.7 101.9 Calibration Results for Modulation Response UID Communication System Name A B C D VR Max Max dB dB\uV dB mV dev. Unc® (k=2) 0 Cw x |_0.00 0.00 1.00 0.00 1514 £3.0% £4.7% y |_0.00 0.00 1.00 154.7 z |_0.00 0.00 1.00 150.4 10352— Pulse Waveform (200Hz, 10%) x 5.31 7342 i4.63 10.00 60.0 £26% £96% AAA Y 286 6584 11.90 60.0 z 15.00 87.67 20.10 60.0 10353— Pulse Waveform (200Hz, 20%) x 1057 8197 1623 6.99 80.0 £1.7% £96% AAA y 2.03 65.40 10.27 80.0 z 15.00 89.79 19.80 80.0 10354— Pulse Waveform (200Hz, 40%) x 15.00 86.62 1629 3.98 95.0 #11% £96% AAA Y 082 6150 6.58 95.0 z 15.00 97.47 22.01 95.0 10355— Pulse Waveform (200Hz, 60%) x 15.00 8999 1664 222 1200 £12% £9.6% AAA y 0.40 60.00 3.98 120.0 Z 15.00 114.21 28.32 120.0 10387— QPSK Waveform, 1 MHz x 0.65 6236 8.93 0.00 150.0 £39% £96% AAA y 0.45 60.00 5.43 150.0 z 0.90 65.62 10.92 150.0 10388— QPSK Waveform, 10 MHz x 242 foss i716 0.00 1500 £18% £9.6% AAA y 1.99 67.57 15.24 150.0 z2 |_271 7239 1822 150.0 10396— 64—QAM Waveform, 100 kHz x s7s 7533 2079 301 150.0 £07% £9.6% AAA y 323 .01 1881 150.0 z 371 7494 20.97 150.0 10399— 64—QAM Waveform, 40 MHz x 358 6811 1637 0.00 |150.0 £4.0% £96% AAA y 3.32 66.75 15.59 150.0 z 3.71 68.68 16.83 150.0 10414— WLAN CCDF, 64—QAM, 40MHz x 484 6621 15.87 0.00 150.0 £67% £9.6% AAA y 448 64.72 1519 150.0 z 4.93 6643 1614 150.0 Note: For details on UID parameters see Appendix 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%. * The uncertainties of Norm X,Y,Z do not affect the E*—field uncertainty inside TSL (see Pages 5 and 6). © Numerical linearization parameter: uncertainty not required. £ 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 3 of 19

EX3DV4— SN:3617 January 31, 2019 DASY/EASY — Parameters of Probe: EX3DV4 — SN:3617 Sensor Model Parameters 61 C2 a T1 T2 T3 T4 T5 T6 fF fF V ms.V~* ms.V~‘ ms v— V X 38.8 281.02 33.02 10.58 0.71 4.99 1.88 0.20 1.01 ¥ 39.2 310.65 39.54 8.92 1.27 5.05 0.00 0.75 1.01 2 40.7 300.62 35.22 10.39 0.59 5.05 1.28 0.33 1.01 Other Probe Parameters Sensor Arrangement Triangular Connector Angle (°) 14.6 Mechanical Surface Detection Mode enabled Optical Surface Detection Mode disabled Probe Overall Length 337 mm Probe Body Diameter 10 mm Tip Length 9 mm Tip Diameter 2.5 mm Probe Tip to Sensor X Calibration Point 1 mm Probe Tip to Sensor Y Calibration Point 1 mm Probe Tip to Sensor Z Calibration Point 1 mm Recommended Measurement Distance from Surface 1.4 mm Certificate No: EX3—3617_Jan19 Page 4 of 19

® EX3DV4— SN:3617 DASY/EASY — Parameters of Probe: EX3DV4 — SN:3617 Calibration Parameter Determined in Head Tissue Simulating Media January 31, 2019 Relative Conductivity Depth ° Une f(MHz)© Permittivity" (S/m)" ConvFX ConvF¥Y ConvFZ Aipha® _(mm) (k=2) 64 54.2 0.75 1245 1245 12.45 0.00 1.00 £13.3% 150 52.3 0.76 11.88 11.88 11.88 0.00 1.00 £13.3% 300 45.3 0.87 11.40 11.40 11.40 0.08 1.20 £13.3% 450 43.5 0.87 10.54 10.54 10.54 0.14 1.40 £13.3% 750 41.9 0.89 10.03 10.03 10.03 0.63 0.84 £12.0 % 835 41.5 0.90 9.75 9.75 9.75 0.39 0.95 £12.0 % 900 41.5 0.97 9.66 9.66 9.66 0.47 0.85 £12.0 % 1450 40.5 1.20 8.68 8.68 8.68 0.37 0.80 +12.0 % 1640 40.2 1.31 8.48 8.48 8.48 0.38 0.80 £12.0 % 1750 40.1 187 8.38 8.38 8.38 0.36 0.82 £12.0 % 1810 40.0 1.40 8.11 8.11 811 0.32 0.84 £12.0 % 1900 40.0 1.40 8.14 8.14 8.14 0.32 0.85 £12.0 % 2000 40.0 1.40 8.13 8.13 8.13 0.28 0.84 £12.0 % 2100 39.8 1.49 8.30 8.30 8.30 0.37 0.85 £12.0 % 2300 39.5 1.67 7.74 7.74 7.74 0.32 0.84 £12.0 % 2450 39.2 1.80 7.62 7.62 7.62 0.31 0.95 £12.0 % 2600 39.0 1.96 7.19 7.19 719 0.43 0.85 £12.0 % 3300 38.2 971 6.98 6.98 6.98 0.25 1.20 £13.1% 3500 37.9 2.91 6.97 6.97 6.97 0.50 1.20 £13.1% 3700 37.7 3.12 6.89 6.89 6.89 0.20 1.20 £13.1% 3900 37.5 3.32 6.88 6.88 6.88 0.20 1.20 £13.1% 4600 36.7 4.04 6.84 6.84 6.84 0.20 1.50 £13.1% 4950 36.3 4.40 5.60 5.60 5.60 0.40 1.80 £13.1% 5200 36.0 4.66 5.50 5.50 5.50 0.40 1.80 £13.1% 5250 35.9 4.71 5.39 5.39 5.39 0.40 1.80 £13.1% 5300 35.9 4.76 5.25 5.25 525 0.40 1.80 £13.1% 5500 35.6 4.96 5.18 5.18 518 0.40 1.80 £13.1% 5600 35.5 5.07 5.06 5.06 5.06 0.40 1.80 £13.1% 5750 35.4 5.22 5.07 5.07 5.07 0.40 1.80 £13.1% 5800 35.3 5.27 5.04 5.04 5.04 0.40 1.80 £13.1% © Frequency validity above 300 MHz of + 100 MHz only applies for DASY v4.4 and higher (see Page 2), else it is restricted to + 50 MHz. The uncertainty is the RSS of the ConvF uncertainty at calibration frequency and the uncertainty for the indicated frequency band. Frequency validity below 300 MHzis + 10, 25, 40, 50 and 70 MHz for ConvF assessments at 30, 64, 128, 150 and 220 MHz respectively. Validity of ConvF assessed at 6 MHz is 4—9 MHz, and ConvF assessed at 13 MHz is 9—19 MHz. Above 5 GHz frequency validity can be extended to + 110 MHz. " At frequencies below 3 GHz, the validity of tissue parameters ( and a) can be relaxed to + 10% if liquid compensation formula is applied to measured SAR values. At frequencies above 3 GHz, the validity of tissue parameters (c and a) is restricted to + 5%. The uncertainty is the RSS of the ConvF uncertainty for indicated target tissue parameters. © Alpha/Depth are determined during calibration. SPEAG warrants that the remaining deviation due to the boundary effect after compensation is always less than + 1% for frequencies below 3 GHz and below + 2% for frequencies between 3—6 GHz at any distance larger than half the probe tip diameter from the boundary. Certificate No: EX3—3617_Jan19 Page 5 of 19

8 EX3DV4— SN:3617 DASY/EASY — Parameters of Probe: EX3DV4 — SN:3617 Calibration Parameter Determined in Body Tissue Simulating Media January 31, 2019 Relative Conductivity Depth ° Unc f(MHz)© Permittivity" (S/m)" ConvFX ConvFY ConvFZ Aipha® _(mm) (k=2) 150 61.9 0.80 11.45 11.45 11.45 0.00 1.00 £13.3% 300 58.2 0.92 10.57 10.57 10.57 0.03 1.20 £13.3 % 450 56.7 0.94 10.39 10.39 10.39 0.08 1.20 £13.3 % 750 55.5 0.96 9.85 9.85 9.85 0.50 0.84 + 12.0 % 835 55.2 0.97 9.61 9.61 9.61 0.37 0.95 + 12.0 % 900 55.0 1.05 9.57 9.57 9.57 0.45 0.84 + 12.0 % 1450 54.0 1.30 8.33 8.33 8.33 0.34 0.80 + 12.0 % 1640 53.7 1.42 8.53 8.53 8.53 0.35 0.80 +12.0 % 1750 53.4 1.49 8.03 8.03 8.03 0.39 0.84 +12.0 % 1810 53.3 1.52 7.94 7.94 7.94 0.43 0.84 + 12.0 % 1900 53.3 1.52 7.78 7.78 7.78 0.38 0.87 + 12.0 % 2000 53.3 1.52 8.00 8.00 8.00 0.22 1.15 * 12.0 % 2100 53.2 1.62 8.23 8.23 8.23 0.41 0.85 + 12.0 % 2300 52.9 1.81 7.84 7.84 784 0.40 0.84 + 12.0 % 2450 52.7 1.95 7.79 7.79 7.19 0.31 0.86 +12.0 % 2600 52.5 216 7.49 7.49 749 0.26 0.98 + 12.0 % 3500 51.3 3.31 6.86 6.86 6.86 0.25 1.20 #13.1 % 3700 51.0 3.55 6.60 6.60 6.60 0.26 1.25 £13.1% 3900 51.2 3.78 6.69 6.69 6.69 0.26 1.25 £13.1% 4600 49.8 4.60 6.50 6.50 6.50 0.28 1.30 £13.1% 3500 51.3 3.31 6.46 6.46 646 0.20 1.70 £13.1% 4950 49.4 5.01 4.99 4.99 4.99 0.50 1.90 £13.1% 5200 49.0 5.30 4.84 4.84 4.84 0.50 1.90 £13.1% 5250 48.9 5.36 4.76 4.76 4.76 0.50 1.90 £13.1% 5300 48.9 5.42 4.63 4.63 4.63 0.50 1.90 £13.1% 5500 48.6 5.65 4.32 4.32 4.32 0.50 1.90 £13.1% 5600 48.5 5.77 4.23 4.23 4.23 0.50 1.90 £13.1% 5750 48.3 5.94 4.36 4.36 4.36 0.50 1.90 £13.1 % 5800 48.2 6.00 4.24 4.24 4.24 0.50 1.90 £13.1 % © Frequency validity above 300 MHz of + 100 MHz only applies for DASY v4.4 and higher (see Page 2), else it is restricted to + 50 MHz. The uncertainty is the RSS of the ConvF uncertainty at calibration frequency and the uncertainty forthe indicated frequency band. Frequency validity below 300 MHz is + 10, 25, 40, 50 and 70 MHz for ConvF assessments at 30, 64, 128, 150 and 220 MHz respectively. Validity of ConvF assessed at 6 MHz is 4—9 MHz, and ConvF assessed at 13 MHz is 9—19 MHz. Above 5 GHz frequency validity can be extended to + 110 MHz. " At frequencies below 3 GHz, the validity of tissue parameters (e and a) can be relaxed to + 10% if liquid compensation formula is applied to measured SAR values. At frequencies above 3 GHz, the validity of tissue parameters (c and 0) is restricted to + 5%. The uncertainty is the RSS of the ConvF uncertainty for indicated target tissue parameters. © Alpha/Depth are determined during calibration. SPEAG warrants thatthe remaining deviation due to the boundary effect after compensation is always less than + 1% for frequencies below 3 GHz and below + 2% for frequencies between 3—6 GHz at any distance largerthan half the probe tip diameter from the boundary. Certificate No: EX3—3617_Jan19 Page 6 of 19

EX3DV4— SN:3617 January 31, 2019 Frequency Response of E—Field (TEM—Cell:ifi110 EXX, Waveguide: R22) HTTTT T¥ Frequency response (normalized) 5 1 l10i00 o Ten Uncertainty of Frequency Response of E—field: £ 6.3% (k=2) Certificate No: EX3—3617_Jan19 Page 7 of 19

EX3DV4— SN:3617 January 31, 2019 Receiving Pattern (¢), 9 = 0° f=600 MHz,TEM f=1800 MHz,R22 135 nA * +s a5 & | y | & ms «* * is # & f ® ® e &* ® e niol Tot X Y Tot x Y Z Error [dB] 10%2 GOE Mriz 190%Hz 25@& Uncertainty of Axial Isotropy Assessment: £ 0.5% (k=2) Certificate No: EX3—3617_Jan19

TTL T EX3DV4— SN:3617 January 31, 2019 Dynamic Range f(SARneaq) (TEM cell , fevai= 1900 MHz) Input Signal [uV] 103 102 101 10 10‘ 10 10 SAR [mW/cm3] not compensated compensated Error [dB] 103 102 101 100 101 102 103 SAR [mW/cm3] Ce] not compensated compensated Uncertainty of Linearity Assessment: £ 0.6% (k=2) Certificate No: EX3—3617_Jan19 Page 9 of 19

) <|| S EX3DV4— SN:3617 10 f= 835 MHz,WGLS R9 (H_convF) Conversion Factor Assessment January 31, 2019 f= 1900 MHz,WGLS R22 (H_convF) 20| } 20 & % , % % y 2 20 | &0 46 c 1 | is ‘ 04 10 I | P o a [() : ho s & 0n o s [W O ao Deviation from Isotropy in Liquid Error (¢, 8), f = 900 MHz Deviation M —~1.0 —0.8 —0.6 —0.4 —0.2 00 02 0.4 0.6 08 1.0 Uncertainty of Spherical Isotropy Assessment: £ 2.6% (k=2) Certificate No: EX3—3617_Jan19 Page 10 of 19

) (@ S EX3DV4— SN:3617 January 31, 2019 Appendix: Modulation Calibration Parameters UID Rev Communication System Name Group PAR Unc® (dB) (k=2) 0 Cw CW 0.00 * 4.7 % 10010 CAA SAR Validation (Square, 100ms, 10ms) Test 10.00 £9.6 % 10011 CAB UMTS—FDD (WCDMA) WCDMA 2.91 +9.6 % 10012 CAB IEEE 802.11b WiFi 2.4 GHz (DSSS, 1 Mbps) WLAN 1.87 + 9.6 % 10013 CAB_| IEEE 802.11g WiFi 2.4 GHz (DSSS—OFDM, 6 Mbps) WLAN 9.46 +9.6 % 10021 DAC GSM—FDD (TDMA, GMSK) GSM 9.39 + 9.6 % 10023 DAC GPRS—FDD (TDMA, GMSK, TN 0) GSM 9.57 + 9.6 % 10024 DAC GPRS—FDD (TDMA, GMSK, TN 0—1) GSM 6.56 + 9.6 % 10025 DAC EDGE—FDD (TDMA, 8PSK, TN 0) GSM 12.62 £9.6 % 10026 DAC EDGE—FDD (TDMA, 8PSK, TN 0—1) GSM 9.55 + 9.6 % 10027 DAC GPRS—FDD (TDMA, GMSK, TN 0—1—2) GSM 4.80 + 9.6 % 10028 DAC GPRS—FDD (TDMA, GMSK, TN 0—1—2—3) GSM 3.55 + 9.6 % 10029 DAC EDGE—FDD (TDMA, 8PSK, TN 0—1—2) GSM 7.78 + 9.6 % 10030 CAA IEEE 802.15.1 Bluetooth (GFSK, DH1) Bluetooth 5.30 + 9.6 % 10031 CAA IEEE 802.15.1 Bluetooth (GFSK, DH3) Bluetooth 1.87 * 9.6 % 10032 CAA IEEE 802.15.1 Bluetooth (GFSK, DH5) Bluetooth 1.16 + 9.6 % 10033 CAA IEEE 802.15.1 Bluetooth (PI4—DQPSK, DH1) Bluetooth 7.74 + 9.6 % 10034 CAA IEEE 802.15.1 Bluetooth (PI/4—DQPSK, DH3) Bluetooth 4.53 + 9.6 % 10035 CAA IEEE 802.15.1 Bluetooth (PI4—DQPSK, DH5) Bluetooth 3.83 + 9.6 % 10036 CAA IEEE 802.15.1 Bluetooth (8—DPSK, DH1) Bluetooth 8.01 + 9.6 % 10037 CAA IEEE 802.15.1 Bluetooth (8—DPSK, DH3) Bluetooth 4.77 * 9.6 % 10038 CAA IEEE 802.15.1 Bluetooth (8—DPSK, DH5) Bluetooth 4.10 + 9.6 % 10039 CAB__| CDMA2000 (1xRTT, RC1) CDMA2000 4.57 + 9.6 % 10042 CAB__| 1S—54 / 1S—136 FDD (TDMA/FDM, PI/4—DQPSK, Halfrate) AMPS 7.78 + 9.6 % 10044 CAA IS—91/EIA/TIA—553_FDD (FDMA, FM) AMPS 0.00 + 9.6 % 10048 CAA DECT (TDD, TDMA/FDM, GFSK, Full Slot, 24) DECT 13.80 £9.6 % 10049 CAA DECT (TDD, TDMA/FDM, GFSK, Double Slot, 12) DECT 10.79 £9.6 % 10056 CAA UMTS—TDD (TD—SCDMA, 1.28 Mops) TD—SCDMA 11.01 +9.6 % 10058 DAC EDGE—FDD (TDMA, 8PSK, TN 0—1—2—3) GSM 6.52 + 9.6 % 10059 CAB IEEE 802.11b WiFi 2.4 GHz (DSSS, 2 Mbps) WLAN 212 + 9.6 % 10060 CAB IEEE 802.1 1b WiFi 2.4 GHz (DSSS, 5.5 Mbps) WLEAN 2.83 + 9.6 % 10061 CAB_| IEEE 802.11b WiFi 2.4 GHz (DSSS, 11 Mbps) WLAN 3.60 + 9.6 % 10062 CAC IEEE 802.11a/h WiFi 5 GHz (OFDM, 6 Mbps) WLAN 8.68 + 9.6 % 10063 CAC IEEE 802.1 1a/h WiFi 5 GHz (OFDM, 9 Mbps) WLAN 8.63 + 9.6 % 10064 CAC IEEE 802.1 1a/h WiFi 5 GHz (OFDM, 12 Mbps) WLAN 9.09 + 9.6 % 10065 CAC IEEE 802.11a/h WiFi 5 GHz (OFDM, 18 Mbps) WLAN 9.00 + 9.6 % 10066 CAC IEEE 802.11a/h WiFi 5 GHz (OFDM, 24 Mbps) WLAN 9.38 + 9.6 % 10067 CAC IEEE 802.1 1a/h WiFi 5 GHz (OFDM, 36 Mbps) WLAN 10.12 £9.6 % 10068 CAC IEEE 802.11a/h WiFi 5 GHz (OFDM, 48 Mbps) WLAN: 10.24 £9.6 % 10069 CAC IEEE 802.11a/h WiFi 5 GHz (OFDM, 54 Mbps) WLAN: 10.56 £9.6 % 10071 CAB IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 9 Mbps) WLAN 9.83 + 9.6 % 10072 CAB_| IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 12 Mbps) WLAN 9.62 + 9.6 % 10073 CAB IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 18 Mbps) WLAN 9.94 + 9.6 % 10074 CAB_| IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 24 Mbps) WLAN 10.30 £9.6 % 10075 CAB_| IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 36 Mbps) WLAN 10.77 £9.6 % 10076 CAB IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 48 Mbps) WLAN 10.94 £9.6 % 10077 CAB_| IEEE 802.11g WiFi 2.4 GHz (DSSS/OFDM, 54 Mbps) WLAN 11.00 £9.6 % 10081 CAB__| CDMA2000 (1xRTT, RC3) CDMA2000 3.97 + 9.6 % 10082 CAB 1S—54 / IS—136 FDD (TDMA/FDM, PI/4—DQPSK, Fullrate) AMPS 4.77 + 9.6 % 10090 DAC GPRS—FDD (TDMA, GMSK, TN 0—4) GSM 6.56 + 9.6 % 10097 CAB__| UMTS—FDD (HSDPA) WCDMA 3.98 + 9.6 % 10098 CAB UMTS—FDD (HSUPA, Subtest 2) WCDMA 3.98 + 9.6 % 10099 DAC EDGE—FDD (TDMA, 8PSK, TN 0—4) GSM 9.55 + 9.6 % 10100 CAE LTE—FDD (SC—FDMA, 100% RB, 20 MHz, QPSK) LTE—FDD 5.67 + 9.6 % 10101 CAE LTE—FDD (SC—FDMA, 100% RB, 20 MHz, 16—QAM) LTE—FDD 6.42 + 9.6 % 10102 CAE LTE—FDD (SC—FDMA, 100% RB, 20 MHz, 64—QAM) LTE—FDD 6.60 + 9.6 % 10103 CAG LTE—TDD (SC—FDMA, 100% RB, 20 MHz, QPSK) LTE—TDD 9.29 + 9.6 % 10104 CAG LTE—TDD (SC—FDMA, 100% RB, 20 MHz, 16—QAM) LTE—TDD 9.97 + 9.6 % 10105 CAG LTE—TDD (SC—FDMA, 100% RB, 20 MHz, 64—QAM) LTE—TDD 10.01 £9.6 % 10108 CAG LTE—FDD (SC—FDMA, 100% RB, 10 MHz, QPSK) LTE—FDD 5.80 + 9.6 % Certificate No: EX3—3617_Jan19 Page 11 of 19


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Document Modified: 2019-09-19 14:35:04
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