FCC ID: 2ADINS5702L Smart phone

 

User Manual Product Name: Smart phone Model Name: X6mini Brand Name: NUU Manufacture: Sun Cupid Technology (HK) Ltd. 1 Table of Contents Safety Information ............................................................ 4 Appearance and Key Function.........................................6 Introduction ......................................................................... 9 Call Functions ..................................................................... 9 Contacts ............................................................................. 11 Message ............................................................................. 14 Camera ................................................................................ 24 Photos ................................................................................. 25 2 Music ................................................................................... 27 Sound Recorder ............................................................... 28 Alarm Clock ....................................................................... 31 Play Store ........................................................................... 33 Settings............................................................................... 34 Storage ............................................................................... 36 FCC Rules Compliance ................................................... 42 IC Notice ............................................................................. 46 3 Safety Information Please carefully read the iterms bellow:

Use Safely Do not use the phone in situations where it might cause danger. Transportation Safety Please observe all transportation laws and regulations. Please drive with both hands on the wheel. Hospitals Please follow limitations. Please turn off your mobile phone when near medical instruments. Airports Remember to follow all airport and flight safety regulations. Please do not use your phone during flight. Toxic Chemicals 4 Do not use your mobile phone around fuels or chemicals. Hazard Do not use in hazardous areas where explosions may occur. Accessories and Batteries Use only Blu authorized batteries and accessories. Backup Remember to keep a written record of all important information. Water Your phone is not waterproof. Keep it away from water and liquids. SOS Emergency Calls Make sure your mobile phone is switched on and in a service area. In home screen, tap the phone key and dial 911 and send. 5 Appearance and Key Function 1 2 6 8 9 5 10 4 11 7 6 3 1Earphone 2Sub camera 3USB port 4Power key 7Speaker 8Main camera 9Main2 camera 10Flash 5volume button 11fingerprint 6Receiver 7 Introduction Power On and Off On - Please ensure the SIM card has been properly inserted into the phone. Long press the Power key to switch on the phone. Off - In standby mode, long press on Power key until an options menu appears. Select Power Off in the menu and confirm Security You may set a security lock feature as a security measure for the phone. For further information regarding password locks, password revision and other functions please enter into the security option in system settings. 8 Call Functions At the dial keyboard, enter the phone number and then click the dial key. If dialing an and enter the number of the extension. You may also press and hold the 0 key to add a (+) sign when adding an international dialing prefix. history Every telephone number called and received will be saved in the history. All numbers in the 9 history can be dialed directly by clicking the CALL BACK on the screen. When the number appears on the list, click it to view details. Call Options There are different options that can be used in the history and dialing interface. You may press the MORE while in the dial interface and adjust speed dial and call settings. In the dialing interface, you may press the search button to browse through contacts list or set default contact resources. Contacts Add Contact 10 Enter: Click on the applications menu and select contacts. The default display is the phone contacts and SIM card contacts. The contacts are organized alphabetically by default. Click the Search icon to enter the contact search interface. Any numbers or letters associated with any of the contacts saved in the list will be shown in the search results. Add New Contact 1. Click the add contact icon (+) to add contact. 2. Select to save your contacts to the GoogleTM account, the phone or the SIM card. 3. You may enter different contact details which include adding a picture, name, telephone number, group, address, and email among other options. 4. Click to finish and save contact. 11 12 Messages You may use this function to exchange text messages and multimedia messages with your family and friends. The messages to and from the same contact or phone number will be saved into a single conversation so you may see the entire message history conveniently. 13 Send an SMS Application Menu Messaging New message (or shortcut icon) 1. Click to enter recipient (You may enter contacts from contact book or enter a new number) 2. Compose Message 3. Send Send an MMS When creating message, the default message style is SMS. The message will automatically convert to MMS when adding an attachment. 1. Click the attachment icon in the messaging interface. 2. Click to add attachments and create an MMS message. Internet Browser Menu Functions Recent tab previous page. After browsing through multiple pages, this option will return the user to the 14 Windows part of the browser. You may view all windows open by clicking the windows icon in the upper right Bookmarks Bookmark. Click the save to Bookmarks option to make the current URL as a saved Click Bookmarks/History to opened saved bookmarks. Find on page: Search current page. Share page: Select to share the current page. Bookmarks/History: Show your browsing history and view the most visited pages. Settings: Contains a variety of browser settings. 15 16 Bluetooth & Wi-Fi Bluetooth is a short-range wireless communications technology that devices can use to exchange information and connect to different types of devices which include headsets and other devices. Power on Bluetooth 17 18 1) Settings Bluetooth and select to power on Bluetooth. 2) The Bluetooth icon will appear in the notification bar. Click scan for devices and the phone will start to scan for all devices within range. 3) In Bluetooth settings all the devices found will displayed in the list under the icon. Note: The maximum detecting time of the phone is 2 minutes. Power on Wi-Fi 1) Settings Wi-Fi and select ON to power on Wi-Fi 2) Click on the desired Wi-Fi network to be connected. Unsecured networks can be connected to directly - secured networks require a password or credentials prior to connection. 19 20 Camera Camera Prior to use: Insert SD card before using the camera or video camera. All photos or videos taken by the phone are typically stored in the memory card for large storage capacity of images. Open Camera 1. Applications Menu Camera 2. Switch to video mode if you want to record videos. Note: You may place a camera shortcut icon on any of the screens Take Pictures 1. Aim the object that the picture will be taken. 2. Press the Shutter button on the screen. 3. After taking the picture, the file will be saved in the cameras gallery folder. 4. You can view the photos by clicking the preview box button.You may adjust various settings for the camera by pressing Menu while in the camera interface. When in the camera viewfinder mode, you can switch to video or photos gallery. 21 Setting Take a photo 22 Share Pictures You may share pictures by sending them through different types of installed applications. You may also send pictures through the MMS message function by composing a message and attaching the picture. Any image can also be sent via the Bluetooth function by selecting Bluetooth equipment that has been paired. Adjust Image Press Menu and Edit to adjust images You may select from different effects that may include: Vintage, Black and White, Instant, Latte, Litho, X-Process, Crop, Rotate, Mirror, Straighten, Vignette, Contrast, Exposure, Auto color, Shadows, Vibrancy, among other settings that can be used to adjust picture images. View Images In the picture interface, click on an album to view images 23 In the photo album, scroll the picture towards left to view the next picture or towards right to view the previous one. Crop Pictures If you want to adjust the size of the picture, use the crop tools. Once the arrow appears, pinch your fingers in or out to adjust the size. If you want to adjust the image and keep its proportion, please hold down any of the four corners of the image and adjust accordingly. 24 Music Open Music Application Menu Music Search Music You may choose to search for music from media folder through artist name, song name, album name. The following formats are available: AMR, MIDI, MP3, WAV, and OGG. 25 Sound Recorder The Sound Recorder can record voice or any audio. You may send any recorded audio via Bluetooth or MMS and also have the option to make any recorded audio the phones default ring tone. The recorder uses 3GPP and OGG format. Record

-Keep the phones microphone near the voice source.

-Click the record button to record the audio.

-Click the stop button to stop recording the audio. All recordings will be saved in the recording folder in the default music program and can be accessed from the sound recorder application. 26 Recording Controls 27 Alarm Clock 1. Click on the Clock icon in the application menu 2. Click set alarm button and enter the alarm clock set interface where you may delete and edit alarms 28 Click to delete alarms Click to edit alarms Click to add alarms 29 Google PlayTM Store Google PlayTM allows you to download music, movies, and even games. Click the Play icon to sign in with your GoogleTM account. 30 Search and select between different Play Store categories 31 Settings Wi-Fi Settings Wi-Fi to power on. When on, the Wi-Fi will automatically search for available networks. Any unsecured network can be used directly and any secured network requires a password or credentials prior to connection. Bluetooth Press the switch to power on Bluetooth. Once on, the Bluetooth will automatically scan for any nearby open equipment. SIM cards Press the switch to power on SIM cards.When insert two cards,click to set cellular datacallsSMS messages Data Usage Mobile and Wi-Fi Data Usage Display Brightness, Auto rotating screen, Wallpaper, Screen Timeout Sound This option sets the phone tone settings for receiving calls and notifications. Some 32 of the settings include:

Vibrate, volume, ring tones, ring tones notification, dial touchpad, and haptic feedback and tones Storage View the phone memory usage. Battery General power usage Apps & notifications Manage applications - Manage and delete installed applications. Running services - Press the Force Stop button to stop any of the services listed and removes from the running services list. Security & Location Set up screen locks: Use slide, face/voice unlock, pattern, PIN or password to lock the screen. Pattern: The first time there will be simple unlock instructions and examples. Click next step to continue the security pattern step. 33 PIN: Enter PIN number to unlock the screen. Password: Use password to unlock the screen You may stop the security feature at any time. Set up SIM card PIN lock SIM card PIN (Personal Identification Number) is used to prevent unauthorized use of SIM card. To change a blocked PIN code, you will need to unlock the SIM lock then go to the Change Password screen. The phone will automatically prompt you enter the old PIN code and ask to enter a new PIN code twice. The phone will then prompt you that the change was successful. If you enter the PIN incorrectly three times, the SIM and PIN codes will be automatically locked. You will need the PUK code to unlock the phone which is available through your service provider. If you enter the PUK code incorrectly 10 times, the SIM card will be permanently locked. Please see your service provider for a new SIM card. Password visible Make the password visible when its typed. Use security credentials - Allow applications to visit security credentials or other credentials. Mobile Network Location - Use wireless services to find locations in applications. When using the GPS, power on to set satellite positioning for accuracy. 34 Users & accounts Add accounts,include ExchangeGoogleTMIMAPPersonal(IMAP) Personal(POP3)POP3 Language & Input Language Change the language of the phone. Custom Dictionary - Add or delete words to the custom dictionary. Keyboard Settings Haptic vibration, Haptic tones, Capitalizing, Speech Input, Inputting words, Predictive text function, Auto-Text, Input keyboard method Backup Backup Data Will back up all application data, WLAN passwords, and other settings to GoogleTM 's servers Reset options Restore to Factory Settings - Clear all data stored on the phone. Date & Time 35 Date and Time adjustment. Time Zone - Select Time Zone according to where your location. Select Date Format - There are 3 kinds of formats you can choose from:

Month-Day-Year, Day-Month-Year and Year-Month-Day, and Year-Month-Day which is the default setting Accessibility Power button ends call and auto rotate screen Speak Passwords and large text Printing Need to download the "CloudPrint.apk" from the Internet and install. About phone Phone information status and firmware updates Storage Connect the phone with the USB cable provided. Once connected, a connection interface 36 will appear. In the connection mode interface, select MTP and turn on from the connection screen to be able to transfer files. Other storage options are also available. Some system settings, hardware, and UI options may vary depending on final version. 37 FCC Warning a 15.19 Labeling requirements. This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. b 15.21 Changes or modification warning. Any Changes or modifications not expressly approved by the party responsible for compliance could void the user's authority to operate the equipment. 38 c 15.105 Information to the user. Note: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by 39 one or more of the following measures:

-Reorient or relocate the receiving antenna.

-Increase the separation between the equipment and receiver.

-Connect the equipment into an outlet on a circuit different from that to which the receiver is connected.

-Consult the dealer or an experienced radio/TV technician for help. dSpecific Absorption Rate (SAR) information:

This Smart phone meets the government's requirements for exposure to radio waves. The guidelines are based on standards that were developed by independent scientific 40 organizations through periodic and thorough evaluation of scientific studies. The standards include a substantial safety margin designed to assure the safety of all persons regardless of age or health. eFCC RF Exposure Information and Statement The SAR limit of USA (FCC) is 1.6 W/kg averaged over one gram of tissue. Device types:

X6mini (FCC ID: 2ADINX6MINI) has also been tested against this SAR limit. The highest SAR value reported under this standard during product certification for use at the ear is 0.446W/kg and when properly worn on the body is 1.253W/kg. This device was tested for typical body-worn operations with the back of the handset kept 10mm from the body. To maintain 41 compliance with FCC RF exposure requirements, use accessories that maintain a 10mm separation distance between the user's body and the back of the handset. The use of belt clips, holsters and similar accessories should not contain metallic components in its assembly. The use of accessories that do not satisfy these requirements may not comply with FCC RF exposure requirements, and should be avoided. fBody-worn Operation This device was tested for typical body-worn operations. To comply with RF exposure requirements, a minimum separation distance of 10 mm must be maintained between the users body and the handset, including the antenna. Third-party belt-clips, holsters, and similar accessories used by this device should not contain any metallic components. Body-worn accessories that do not meet these requirements may not comply with RF exposure requirements and should be avoided. Use only the supplied or an approved antenna. 42

 

 

 

 

 

 

 

 

 

 

FCC Label Smart phone Model name: X6 FCC ID: 2ADINS5702L This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.

 

 

Sun Cupid Technology (HK) Ltd. 2019.12.05 MET Laboratories, Inc. 914 West Patapsco Avenue Baltimore, MD 21230 RE: LETTER OF AGENT AUTHORIZATION To Whom It May Concern:

We, Sun Cupid Technology (HK) Ltd. hereby authorize (Shenzhen STS Test Services Co., Ltd.) to act on our behalf in all matters relating to application for equipment authorization, including the signing of all documents relating to these matters. We also hereby certify that no party to the application authorized hereunder is subject to the denial of benefits, including FCC benefits, pursuant to Section 5301 of the Anti-Drug Abuse Act of 1988, 21 U.S.C.853(a). This agreement expires one year from the current date. Sincerely, Name: Danny Sit Signature:

TCBJ FORM-4 Issued by: TCB Administrator Revision 6 12/06/10

 

 

Sun Cupid Technology (HK) Ltd. 2019.12.06 MET Laboratories, Inc. 914 West Patapsco Avenue Baltimore, MD 21230 RE: CONFIDENTIALITY REQUEST FOR (Smart phone / X6 /FCC ID: 2ADINS5702L) To Whom It May Concern:

This letter serves as an official request for confidentiality under sections 0.457 and 0.459 of CFR 47. We have requested that the Tune up Procedure These materials contain trade secrets and proprietary information and are not customarily released to the public. The public disclosure of this information might be harmful to the company and provide unjustified benefits to our competitors. required to be submitted with this application be permanently withheld from public review. Please contact me if there is any information you may need. Sincerely, Name: Danny Sit Signature:

Schematics Block diagram Operation description Part List TCBJ FORM-4 Issued by: TCB Administrator Revision 6 12/06/10

 

 

COMOSAR E-Field Probe Calibration Report Ref : ACR.348.1.19.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING B, ZHUOKE SCIENCE PARK, No.190, CHONGQING ROAD,FUYONG STREET BAOAN DISTRICT,SHENZHEN,GUANGDONG,CHINA MVG COMOSAR DOSIMETRIC E-FIELD PROBE SERIAL NO.: SN 45/15 EPGO281 Calibrated at MVG US 2105 Barrett Park Dr. - Kennesaw, GA 30144 Calibration Date: 03/25/2019 Summary:

This document presents the method and results from an accredited COMOSAR Dosimetric E-Field Probe calibration performed in MVG USA using the CALISAR / CALIBAIR test bench, for use with a COMOSAR system only. All calibration results are traceable to national metrology institutions. COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A Name Function Date Prepared by :

Jrme LUC Product Manager 04/02/2019 Signature Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager 04/02/2019 04/02/2019 Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Checked by :

Approved by :

Issue A Date 04/02/2019 Initial release Modifications This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 2/10 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A TABLE OF CONTENTS 1 Device Under Test ..................................................................................................... 4 2 Product Description ................................................................................................... 4 2.1 General Information _______________________________________________________ 4 3 Measurement Method ................................................................................................ 4 3.1 3.2 3.3 3.4 3.5 Linearity ________________________________________________________________ 4 Sensitivity _______________________________________________________________ 5 Lower Detection Limit _____________________________________________________ 5 Isotropy _________________________________________________________________ 5 Boundary Effect __________________________________________________________ 5 4 Measurement Uncertainty .......................................................................................... 5 5 Calibration Measurement Results .............................................................................. 6 5.1 5.2 5.3 5.4 Sensitivity in air __________________________________________________________ 6 Linearity ________________________________________________________________ 7 Sensitivity in liquid ________________________________________________________ 7 Isotropy _________________________________________________________________ 8 6 List of Equipment .................................................................................................... 10 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 3/10 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A 1 DEVICE UNDER TEST Device Under Test Device Type Manufacturer Model Serial Number Product Condition (new / used) Frequency Range of Probe Resistance of Three Dipoles at Connector COMOSAR DOSIMETRIC E FIELD PROBE MVG SSE2 SN 45/15 EPGO281 New 0.45 GHz-6GHz Dipole 1: R1=0.186 M Dipole 2: R2=0.193M Dipole 3: R3=0.194 M A yearly calibration interval is recommended. 2 PRODUCT DESCRIPTION GENERAL INFORMATION 2.1 MVGs COMOSAR E field Probes are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. Figure 1 MVG COMOSAR Dosimetric E field Dipole Probe Length Length of Individual Dipoles Maximum external diameter Probe Tip External Diameter Distance between dipoles / probe extremity 330 mm 2 mm 8 mm 2.5 mm 1 mm 3 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards provide recommended practices for the probe calibrations, including the performance characteristics of interest and methods by which to assess their affect. All calibrations / measurements performed meet the fore mentioned standards. 3.1 LINEARITY The evaluation of the linearity was done in free space using the waveguide, performing a power sweep to cover the SAR range 0.01W/kg to 100W/kg. This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 4/10 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A 3.2 SENSITIVITY The sensitivity factors of the three dipoles were determined using a two step calibration method (air and tissue simulating liquid) using waveguides as outlined in the standards. 3.3 LOWER DETECTION LIMIT The lower detection limit was assessed using the same measurement set up as used for the linearity measurement. The required lower detection limit is 10 mW/kg. 3.4 ISOTROPY The axial isotropy was evaluated by exposing the probe to a reference wave from a standard dipole with the dipole mounted under the flat phantom in the test configuration suggested for system validations and checks. The probe was rotated along its main axis from 0 - 360 degrees in 15 degree steps. The hemispherical isotropy is determined by inserting the probe in a thin plastic box filled with tissue-equivalent liquid, with the plastic box illuminated with the fields from a half wave dipole. The dipole is rotated about its axis (0180) in 15 increments. At each step the probe is rotated about its axis (0360). 3.5 BOUNDARY EFFECT The boundary effect is defined as the deviation between the SAR measured data and the expected exponential decay in the liquid when the probe is oriented normal to the interface. To evaluate this effect, the liquid filled flat phantom is exposed to fields from either a reference dipole or waveguide. With the probe normal to the phantom surface, the peak spatial average SAR is measured and compared to the analytical value at the surface. 4 MEASUREMENT UNCERTAINTY The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed to generate the measurement uncertainty associated with an E-field probe calibration using the waveguide technique. All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. Uncertainty analysis of the probe calibration in waveguide ERROR SOURCES Incident or forward power Reflected power Liquid conductivity Liquid permittivity Field homogeneity Field probe positioning Uncertainty value (%) 3.00%

3.00%

5.00%

4.00%

3.00%

5.00%

Probability Distribution Rectangular Rectangular Rectangular Rectangular Rectangular Rectangular Divisor 1.732051 1.732051 1.732051 1.732051 1.732051 ci 1 1 1 1 1 1 Standard Uncertainty (%) 1.732%

1.732%

2.887%

2.309%

1.732%

2.887%

This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 5/10 333333333 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A Field probe linearity 3.00%

Rectangular Combined standard uncertainty Expanded uncertainty 95 % confidence level k = 2 1.732051 1 1.732%

5.831%

12.0%

5 CALIBRATION MEASUREMENT RESULTS Liquid Temperature Lab Temperature Lab Humidity Calibration Parameters 21 C 21 C 45 %

5.1 SENSITIVITY IN AIR Normx dipole 1 (V/(V/m)2) 0.76 DCP dipole 1

(mV) 90 Normy dipole 2 (V/(V/m)2) DCP dipole 2 0.82

(mV) 91 Normz dipole 3 (V/(V/m)2) 0.66 DCP dipole 3

(mV) 94 Calibration curves ei=f(V) (i=1,2,3) allow to obtain H-field value using the formula:

This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 6/10 232221EEEE3 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A 5.2 LINEARITY 5.3 SENSITIVITY IN LIQUID Permittivity Epsilon (S/m) ConvF Frequency

(MHz +/-

100MHz) Liquid HL450 BL450 HL750 BL750 HL850 BL850 HL900 BL900 HL1800 BL1800 HL1900 BL1900 HL2000 BL2000 HL2450 BL2450 HL2600 BL2600 HL5200 BL5200 HL5400 BL5400 HL5600 BL5600 HL5800 BL5800 450 450 750 750 835 835 900 900 1800 1800 1900 1900 2000 2000 2450 2450 2600 2600 5200 5200 5400 5400 5600 5600 5800 5800 44.12 58.92 42.24 56.85 43.02 53.72 42.47 56.97 42.24 53.53 40.79 54.47 40.52 54.18 38.73 53.23 38.54 52.07 36.80 51.21 36.35 50.51 35.57 49.83 35.30 49.03 0.88 1.00 0.90 0.99 0.90 0.98 0.99 1.09 1.40 1.53 1.42 1.57 1.44 1.56 1.81 1.96 1.95 2.23 4.84 5.16 4.96 5.70 5.23 5.91 5.47 6.28 1.76 1.81 1.53 1.59 1.78 1.85 1.62 1.67 1.83 1.87 2.10 2.16 2.01 2.09 2.21 2.28 2.32 2.38 2.46 2.52 2.70 2.79 2.74 2.83 2.53 2.60 LOWER DETECTION LIMIT: 9mW/kg This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 7/10 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A 5.4 ISOTROPY HL900 MHz

- Axial isotropy:

- Hemispherical isotropy:

HL1800 MHz

- Axial isotropy:

- Hemispherical isotropy:

0.04 dB 0.06 dB 0.04 dB 0.08 dB This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 8/10 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A HL5600 MHz

- Axial isotropy:

- Hemispherical isotropy:

0.06 dB 0.08 dB This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. Page: 9/10 COMOSAR E-FIELD PROBE CALIBRATION REPORT Ref: ACR.348.1.19.SATU.A 6 LIST OF EQUIPMENT Equipment Description Flat Phantom Equipment Summary Sheet Manufacturer /

Model Identification No. Current Calibration Date Next Calibration Date MVG SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. NA Validated. required. Validated. required. No cal No cal COMOSAR Test Bench Version 3 Network Analyzer Rhode & Schwarz ZVA SN100132 02/2019 Reference Probe MVG EP 94 SN 37/08 10/2017 Multimeter Keithley 2000 1188656 Signal Generator Agilent E4438C MY49070581 01/2017 01/2017 02/2022 10/2019 01/2020 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 Power Sensor HP ECP-E26A US37181460 01/2017 01/2017 01/2020 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Waveguide Mega Industries Waveguide Transition Mega Industries Waveguide Termination Mega Industries required. 069Y7-158-13-712 Validated. No cal 069Y7-158-13-701 Validated. No cal 069Y7-158-13-701 Validated. No cal required. required. Characterized prior to test. No cal required. Validated. No cal required. Validated. No cal required. Validated. No cal required. Temperature / Humidity Sensor Control Company 150798832 11/2017 11/2020 Page: 10/10 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR Reference Dipole Calibration Report Ref : ACR.262.4.17.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING 2, ZHUOKE SCIENCE PARK,No.190, CHONGQING ROAD,FUYONG STREET, BAO AN DISTRICT, SHENZHEN,GUANGDONG,CHINA MVG COMOSAR REFERENCE DIPOLE FREQUENCY: 750 MHZ SERIAL NO.: SN 30/14 DIP0G750-331 Calibrated at MVG US 2105 Barrett Park Dr. - Kennesaw, GA 30144 08/15/2017 Summary:

This document presents the method and results from an accredited SAR reference dipole calibration performed in MVG USA using the COMOSAR test bench. All calibration results are traceable to national metrology institutions. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A Prepared by :

Name Function Jrme LUC Product Manager Checked by :

Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager Signature Date 8/25/2017 8/25/2017 8/25/2017 Approved by :

Issue A Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Date 8/25/2017 Modifications Initial release Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A TABLE OF CONTENTS 1 Introduction ................................................................................................................ 4 2 Device Under Test ..................................................................................................... 4 3 Product Description ................................................................................................... 4 3.1 General Information _______________________________________________________ 4 4 Measurement Method ................................................................................................ 5 4.1 Return Loss Requirements __________________________________________________ 5 4.2 Mechanical Requirements ___________________________________________________ 5 5 Measurement Uncertainty .......................................................................................... 5 5.1 5.2 5.3 Return Loss ______________________________________________________________ 5 Dimension Measurement ___________________________________________________ 5 Validation Measurement ____________________________________________________ 5 6 Calibration Measurement Results .............................................................................. 6 Return Loss and Impedance In Head Liquid ____________________________________ 6 6.1 Return Loss and Impedance In Body Liquid ____________________________________ 6 6.2 6.3 Mechanical Dimensions ____________________________________________________ 6 7 Validation measurement ............................................................................................ 7 7.1 7.2 7.3 7.4 Head Liquid Measurement __________________________________________________ 7 SAR Measurement Result With Head Liquid ____________________________________ 8 Body Liquid Measurement __________________________________________________ 9 SAR Measurement Result With Body Liquid __________________________________ 10 8 List of Equipment .................................................................................................... 11 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. DEVICE UNDER TEST 2 Device Under Test Device Type Manufacturer MVG Model Serial Number Product Condition (new / used) SID750 SN 30/14 DIP0G750-331 New COMOSAR 750 MHz REFERENCE DIPOLE A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION GENERAL INFORMATION 3.1 MVGs COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 MVG COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of -20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEI/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95%

confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURN LOSS The following uncertainties apply to the return loss measurement:

Frequency band 400-6000MHz Expanded Uncertainty on Return Loss 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements:

Length (mm) 3 - 300 Expanded Uncertainty on Length 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed the measurement uncertainty for validation measurements. to generate Scan Volume Expanded Uncertainty 1 g 10 g 20.3 %

20.1 %

Page: 5/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE IN HEAD LIQUID Frequency (MHz) 750 Return Loss (dB)

-25.42 Requirement (dB)

-20 6.2 RETURN LOSS AND IMPEDANCE IN BODY LIQUID Frequency (MHz) 750 Return Loss (dB)

-27.21 Requirement (dB)

-20 6.3 MECHANICAL DIMENSIONS Impedance 55.1 + 1.5 j Impedance 51.3 + 4.1 j Frequency MHz L mm h mm d mm 300 450 750 835 required measured required measured required measured 420.0 1 %. 290.0 1 %. 176.0 1 %. 161.0 1 %. PASS 250.0 1 %. 166.7 1 %. 100.0 1 %. 89.8 1 %. PASS 6.35 1 %. 6.35 1 %. 6.35 1 %. 3.6 1 %. PASS Page: 6/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 2450 2600 3000 3500 3700 149.0 1 %. 89.1 1 %. 80.5 1 %. 79.0 1 %. 75.2 1 %. 72.0 1 %. 68.0 1 %. 66.3 1 %. 64.5 1 %. 61.0 1 %. 55.5 1 %. 51.5 1 %. 48.5 1 %. 41.5 1 %. 37.01 %. 34.71 %. 83.3 1 %. 51.7 1 %. 50.0 1 %. 45.7 1 %. 42.9 1 %. 41.7 1 %. 39.5 1 %. 38.5 1 %. 37.5 1 %. 35.7 1 %. 32.6 1 %. 30.4 1 %. 28.8 1 %. 25.0 1 %. 26.4 1 %. 26.4 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEI/IEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 Relative permittivity (r) Conductivity () S/m required measured required measured 45.3 5 %

43.5 5 %

41.9 5 %

41.5 5 %

41.5 5 %

40.5 5 %

40.4 5 %

40.2 5 %

40.1 5 %

40.0 5 %

40.0 5 %

40.0 5 %

40.0 5 %

PASS 0.87 5 %

0.87 5 %

0.89 5 %

0.90 5 %

0.97 5 %

1.20 5 %

1.23 5 %

1.31 5 %

1.37 5 %

1.40 5 %

1.40 5 %

1.40 5 %

1.40 5 %

PASS Page: 7/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 2100 2300 2450 2600 3000 3500 39.8 5 %

39.5 5 %

39.2 5 %

39.0 5 %

38.5 5 %

37.9 5 %

1.49 5 %

1.67 5 %

1.80 5 %

1.96 5 %

2.40 5 %

2.91 5 %

7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEI/IEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Head Liquid Values: eps : 42.1 sigma : 0.89 15.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 750 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) required measured required measured 2.85 4.58 8.49 9.56 10.9 29 30.5 34.2 36.4 38.4 39.7 40.5 41.1 43.6 48.7 8.49 (0.85) 1.94 3.06 5.55 6.22 6.99 16 16.8 18.4 19.3 20.1 20.5 20.9 21.1 21.9 23.3 5.53 (0.55) Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 2450 2600 3000 3500 52.4 55.3 63.8 67.1 24 24.6 25.7 25 7.3 BODY LIQUID MEASUREMENT Frequency MHz 150 300 450 750 835 900 915 1450 1610 1800 1900 2000 2100 2450 2600 3000 3500 5200 5300 5400 Relative permittivity (r) Conductivity () S/m required measured required measured 61.9 5 %

58.2 5 %

56.7 5 %

55.5 5 %

55.2 5 %

55.0 5 %

55.0 5 %

54.0 5 %

53.8 5 %

53.3 5 %

53.3 5 %

53.3 5 %

53.2 5 %

52.7 5 %

52.5 5 %

52.0 5 %

51.3 5 %

49.0 10 %

48.9 10 %

48.7 10 %

PASS 0.80 5 %

0.92 5 %

0.94 5 %

0.96 5 %

0.97 5 %

1.05 5 %

1.06 5 %

1.30 5 %

1.40 5 %

1.52 5 %

1.52 5 %

1.52 5 %

1.62 5 %

1.95 5 %

2.16 5 %

2.73 5 %

3.31 5 %

5.30 10 %

5.42 10 %

5.53 10 %

PASS Page: 9/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 5500 5600 5800 48.6 10 %

48.5 10 %

48.2 10 %

5.65 10 %

5.77 10 %

6.00 10 %

7.4 SAR MEASUREMENT RESULT WITH BODY LIQUID Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Body Liquid Values: eps : 56.6 sigma : 0.99 15.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 750 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 750 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) measured 8.82 (0.88) measured 5.74 (0.57) Page: 10/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.4.17.SATU.A 8 LIST OF EQUIPMENT Equipment Summary Sheet Equipment Description Manufacturer /

Model Identification No. Current Calibration Date Next Calibration Date SAM Phantom MVG COMOSAR Test Bench Version 3 SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. NA Validated. required. Validated. required. No cal No cal Network Analyzer Rhode & Schwarz ZVA SN100132 Calipers Carrera CALIPER-01 02/2016 01/2017 Reference Probe MVG EPG122 SN 18/11 10/2016 Multimeter Keithley 2000 1188656 Signal Generator Agilent E4438C MY49070581 01/2017 01/2017 02/2019 01/2020 10/2017 01/2020 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 Power Sensor HP ECP-E26A US37181460 01/2017 01/2017 01/2020 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Temperature and Humidity Sensor Control Company 15098832 10/2015 10/2017 Page: 11/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR Reference Dipole Calibration Report Ref : ACR.262.5.17.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING B, ZHUOKE SCIENCE PARK,No.190, CHONGQING ROAD,FUYONG STREET, BAO AN DISTRICT, SHENZHEN,GUANGDONGCHINA MVG COMOSAR REFERENCE DIPOLE FREQUENCY: 835 MHZ SERIAL NO.: SN 30/14 DIP0G835-332 Calibrated at MVG US 2105 Barrett Park Dr. - Kennesaw, GA 30144 08/15/2017 Summary:

This document presents the method and results from an accredited SAR reference dipole calibration performed in MVG USA using the COMOSAR test bench. All calibration results are traceable to national metrology institutions. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A Prepared by :

Name Function Jrme LUC Product Manager Checked by :

Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager Signature Date 8/25/2017 8/25/2017 8/25/2017 Approved by :

Issue A Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Date 8/25/2017 Modifications Initial release Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A TABLE OF CONTENTS 1 Introduction ................................................................................................................ 4 2 Device Under Test ..................................................................................................... 4 3 Product Description ................................................................................................... 4 3.1 General Information _______________________________________________________ 4 4 Measurement Method ................................................................................................ 5 4.1 Return Loss Requirements __________________________________________________ 5 4.2 Mechanical Requirements ___________________________________________________ 5 5 Measurement Uncertainty .......................................................................................... 5 5.1 5.2 5.3 Return Loss ______________________________________________________________ 5 Dimension Measurement ___________________________________________________ 5 Validation Measurement ____________________________________________________ 5 6 Calibration Measurement Results .............................................................................. 6 Return Loss and Impedance In Head Liquid ____________________________________ 6 6.1 Return Loss and Impedance In Body Liquid ____________________________________ 6 6.2 6.3 Mechanical Dimensions ____________________________________________________ 6 7 Validation measurement ............................................................................................ 7 7.1 7.2 7.3 7.4 Head Liquid Measurement __________________________________________________ 7 SAR Measurement Result With Head Liquid ____________________________________ 8 Body Liquid Measurement __________________________________________________ 9 SAR Measurement Result With Body Liquid __________________________________ 10 8 List of Equipment .................................................................................................... 11 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. DEVICE UNDER TEST 2 Device Under Test Device Type Manufacturer MVG Model Serial Number Product Condition (new / used) SID835 SN 30/14 DIP0G835-332 New COMOSAR 835 MHz REFERENCE DIPOLE A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION GENERAL INFORMATION 3.1 MVGs COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 MVG COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of -20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEI/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95%

confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURN LOSS The following uncertainties apply to the return loss measurement:

Frequency band 400-6000MHz Expanded Uncertainty on Return Loss 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements:

Length (mm) 3 - 300 Expanded Uncertainty on Length 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed the measurement uncertainty for validation measurements. to generate Scan Volume Expanded Uncertainty 1 g 10 g 20.3 %

20.1 %

Page: 5/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE IN HEAD LIQUID Frequency (MHz) 835 Return Loss (dB)

-28.11 Requirement (dB)

-20 6.2 RETURN LOSS AND IMPEDANCE IN BODY LIQUID Frequency (MHz) 835 Return Loss (dB)

-23.87 Requirement (dB)

-20 6.3 MECHANICAL DIMENSIONS Impedance 51.6 + 3.6 j Impedance 49.0 + 6.3 j Frequency MHz L mm h mm d mm 300 450 750 835 required measured required measured required measured 420.0 1 %. 290.0 1 %. 176.0 1 %. 161.0 1 %. PASS 250.0 1 %. 166.7 1 %. 100.0 1 %. 89.8 1 %. PASS 6.35 1 %. 6.35 1 %. 6.35 1 %. 3.6 1 %. PASS Page: 6/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 2450 2600 3000 3500 3700 149.0 1 %. 89.1 1 %. 80.5 1 %. 79.0 1 %. 75.2 1 %. 72.0 1 %. 68.0 1 %. 66.3 1 %. 64.5 1 %. 61.0 1 %. 55.5 1 %. 51.5 1 %. 48.5 1 %. 41.5 1 %. 37.01 %. 34.71 %. 83.3 1 %. 51.7 1 %. 50.0 1 %. 45.7 1 %. 42.9 1 %. 41.7 1 %. 39.5 1 %. 38.5 1 %. 37.5 1 %. 35.7 1 %. 32.6 1 %. 30.4 1 %. 28.8 1 %. 25.0 1 %. 26.4 1 %. 26.4 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEI/IEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 Relative permittivity (r) Conductivity () S/m required measured required measured 45.3 5 %

43.5 5 %

41.9 5 %

41.5 5 %

41.5 5 %

40.5 5 %

40.4 5 %

40.2 5 %

40.1 5 %

40.0 5 %

40.0 5 %

40.0 5 %

40.0 5 %

PASS 0.87 5 %

0.87 5 %

0.89 5 %

0.90 5 %

0.97 5 %

1.20 5 %

1.23 5 %

1.31 5 %

1.37 5 %

1.40 5 %

1.40 5 %

1.40 5 %

1.40 5 %

PASS Page: 7/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 2100 2300 2450 2600 3000 3500 39.8 5 %

39.5 5 %

39.2 5 %

39.0 5 %

38.5 5 %

37.9 5 %

1.49 5 %

1.67 5 %

1.80 5 %

1.96 5 %

2.40 5 %

2.91 5 %

7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEI/IEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Head Liquid Values: eps : 42.3 sigma : 0.92 15.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 835 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) required measured required measured 2.85 4.58 8.49 9.56 10.9 29 30.5 34.2 36.4 38.4 39.7 40.5 41.1 43.6 48.7 9.63 (0.96) 1.94 3.06 5.55 6.22 6.99 16 16.8 18.4 19.3 20.1 20.5 20.9 21.1 21.9 23.3 6.15 (0.62) Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 2450 2600 3000 3500 52.4 55.3 63.8 67.1 24 24.6 25.7 25 7.3 BODY LIQUID MEASUREMENT Frequency MHz 150 300 450 750 835 900 915 1450 1610 1800 1900 2000 2100 2450 2600 3000 3500 5200 5300 5400 Relative permittivity (r) Conductivity () S/m required measured required measured 61.9 5 %

58.2 5 %

56.7 5 %

55.5 5 %

55.2 5 %

55.0 5 %

55.0 5 %

54.0 5 %

53.8 5 %

53.3 5 %

53.3 5 %

53.3 5 %

53.2 5 %

52.7 5 %

52.5 5 %

52.0 5 %

51.3 5 %

49.0 10 %

48.9 10 %

48.7 10 %

PASS 0.80 5 %

0.92 5 %

0.94 5 %

0.96 5 %

0.97 5 %

1.05 5 %

1.06 5 %

1.30 5 %

1.40 5 %

1.52 5 %

1.52 5 %

1.52 5 %

1.62 5 %

1.95 5 %

2.16 5 %

2.73 5 %

3.31 5 %

5.30 10 %

5.42 10 %

5.53 10 %

PASS Page: 9/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 5500 5600 5800 48.6 10 %

48.5 10 %

48.2 10 %

5.65 10 %

5.77 10 %

6.00 10 %

7.4 SAR MEASUREMENT RESULT WITH BODY LIQUID Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Body Liquid Values: eps : 54.1 sigma : 0.97 15.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 835 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 835 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) measured 9.93 (0.99) measured 6.35 (0.63) Page: 10/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.5.17.SATU.A 8 LIST OF EQUIPMENT Equipment Summary Sheet Model Manufacturer /

Equipment Description SAM Phantom MVG SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. Identification No. Current Version 3 NA Calibration Date COMOSAR Test Bench Next Calibration Date Validated. required. Validated. required. No cal No cal Network Analyzer Rhode & Schwarz ZVA SN100132 02/2016 02/2019 Calipers Carrera CALIPER-01 01/2017 01/2020 Reference Probe MVG EPG122 SN 18/11 10/2016 10/2017 Multimeter Keithley 2000 1188656 01/2017 01/2020 Signal Generator Agilent E4438C MY49070581 01/2017 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 01/2017 01/2020 Power Sensor HP ECP-E26A US37181460 01/2017 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Temperature and Humidity Sensor Control Company 150798832 10/2015 10/2017 Page: 11/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR Reference Dipole Calibration Report Ref : ACR.262.7.17.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING B, ZHUOKE SCIENCE PARK,No.190, CHONGQINGROAD,FUYONG STREET, BAO AN DISTRICT, SHENZHEN,GUANGDONG,CHINA MVG COMOSAR REFERENCE DIPOLE FREQUENCY: 1800 MHZ SERIAL NO.: SN 30/14 DIP1G800-329 Calibrated at MVG US 2105 Barrett Park Dr. - Kennesaw, GA 30144 08/15/2017 Summary:

This document presents the method and results from an accredited SAR reference dipole calibration performed in MVG USA using the COMOSAR test bench. All calibration results are traceable to national metrology institutions. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A Prepared by :

Name Function Jrme LUC Product Manager Checked by :

Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager Signature Date 8/25/2017 8/25/2017 8/25/2017 Approved by :

Issue A Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Date 8/25/2017 Modifications Initial release Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A TABLE OF CONTENTS 1 Introduction ................................................................................................................ 4 2 Device Under Test ..................................................................................................... 4 3 Product Description ................................................................................................... 4 3.1 General Information _______________________________________________________ 4 4 Measurement Method ................................................................................................ 5 4.1 Return Loss Requirements __________________________________________________ 5 4.2 Mechanical Requirements ___________________________________________________ 5 5 Measurement Uncertainty .......................................................................................... 5 5.1 5.2 5.3 Return Loss ______________________________________________________________ 5 Dimension Measurement ___________________________________________________ 5 Validation Measurement ____________________________________________________ 5 6 Calibration Measurement Results .............................................................................. 6 Return Loss and Impedance In Head Liquid ____________________________________ 6 6.1 Return Loss and Impedance In Body Liquid ____________________________________ 6 6.2 6.3 Mechanical Dimensions ____________________________________________________ 6 7 Validation measurement ............................................................................................ 7 7.1 7.2 7.3 7.4 Head Liquid Measurement __________________________________________________ 7 SAR Measurement Result With Head Liquid ____________________________________ 8 Body Liquid Measurement __________________________________________________ 9 SAR Measurement Result With Body Liquid __________________________________ 10 8 List of Equipment .................................................................................................... 11 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17SATU.A 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. DEVICE UNDER TEST 2 Device Under Test Device Type Manufacturer MVG Model Serial Number Product Condition (new / used) SID1800 SN 30/14 DIP1G800-329 New COMOSAR 1800 MHz REFERENCE DIPOLE A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION GENERAL INFORMATION 3.1 MVGs COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 MVG COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of -20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEI/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95%

confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURN LOSS The following uncertainties apply to the return loss measurement:

Frequency band 400-6000MHz Expanded Uncertainty on Return Loss 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements:

Length (mm) 3 - 300 Expanded Uncertainty on Length 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed the measurement uncertainty for validation measurements. to generate Scan Volume Expanded Uncertainty 1 g 10 g 20.3 %

20.1 %

Page: 5/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE IN HEAD LIQUID Frequency (MHz) 1800 Return Loss (dB)

-29.51 Requirement (dB)

-20 6.2 RETURN LOSS AND IMPEDANCE IN BODY LIQUID Frequency (MHz) 1800 Return Loss (dB)

-24.59 Requirement (dB)

-20 6.3 MECHANICAL DIMENSIONS Impedance 46.7 - 0.1 j Impedance 44.8 - 2.8 j Frequency MHz L mm h mm d mm 300 450 750 835 required measured required measured required measured 420.0 1 %. 290.0 1 %. 176.0 1 %. 161.0 1 %. 250.0 1 %. 166.7 1 %. 100.0 1 %. 89.8 1 %. 6.35 1 %. 6.35 1 %. 6.35 1 %. 3.6 1 %. Page: 6/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 2450 2600 3000 3500 3700 SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 149.0 1 %. 89.1 1 %. 80.5 1 %. 79.0 1 %. 75.2 1 %. 72.0 1 %. 68.0 1 %. 66.3 1 %. 64.5 1 %. 61.0 1 %. 55.5 1 %. 51.5 1 %. 48.5 1 %. 41.5 1 %. 37.01 %. 34.71 %. PASS 83.3 1 %. 51.7 1 %. 50.0 1 %. 45.7 1 %. 42.9 1 %. 41.7 1 %. 39.5 1 %. 38.5 1 %. 37.5 1 %. 35.7 1 %. 32.6 1 %. 30.4 1 %. 28.8 1 %. 25.0 1 %. 26.4 1 %. 26.4 1 %. PASS 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. PASS 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEI/IEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 Relative permittivity (r) Conductivity () S/m required measured required measured 45.3 5 %

43.5 5 %

41.9 5 %

41.5 5 %

41.5 5 %

40.5 5 %

40.4 5 %

40.2 5 %

40.1 5 %

40.0 5 %

40.0 5 %

40.0 5 %

40.0 5 %

PASS 0.87 5 %

0.87 5 %

0.89 5 %

0.90 5 %

0.97 5 %

1.20 5 %

1.23 5 %

1.31 5 %

1.37 5 %

1.40 5 %

1.40 5 %

1.40 5 %

1.40 5 %

PASS Page: 7/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 2100 2300 2450 2600 3000 3500 39.8 5 %

39.5 5 %

39.2 5 %

39.0 5 %

38.5 5 %

37.9 5 %

1.49 5 %

1.67 5 %

1.80 5 %

1.96 5 %

2.40 5 %

2.91 5 %

7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEI/IEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Head Liquid Values: eps : 41.3 sigma : 1.38 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 1800 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) required measured required measured 2.85 4.58 8.49 9.56 10.9 29 30.5 34.2 36.4 38.4 39.7 40.5 41.1 43.6 48.7 38.31 (3.83) 1.94 3.06 5.55 6.22 6.99 16 16.8 18.4 19.3 20.1 20.5 20.9 21.1 21.9 23.3 19.96 (2.00) Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 2450 2600 3000 3500 52.4 55.3 63.8 67.1 24 24.6 25.7 25 7.3 BODY LIQUID MEASUREMENT Frequency MHz 150 300 450 750 835 900 915 1450 1610 1800 1900 2000 2100 2450 2600 3000 3500 5200 5300 5400 Relative permittivity (r) Conductivity () S/m required measured required measured 61.9 5 %

58.2 5 %

56.7 5 %

55.5 5 %

55.2 5 %

55.0 5 %

55.0 5 %

54.0 5 %

53.8 5 %

53.3 5 %

53.3 5 %

53.3 5 %

53.2 5 %

52.7 5 %

52.5 5 %

52.0 5 %

51.3 5 %

49.0 10 %

48.9 10 %

48.7 10 %

PASS 0.80 5 %

0.92 5 %

0.94 5 %

0.96 5 %

0.97 5 %

1.05 5 %

1.06 5 %

1.30 5 %

1.40 5 %

1.52 5 %

1.52 5 %

1.52 5 %

1.62 5 %

1.95 5 %

2.16 5 %

2.73 5 %

3.31 5 %

5.30 10 %

5.42 10 %

5.53 10 %

PASS Page: 9/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 5500 5600 5800 48.6 10 %

48.5 10 %

48.2 10 %

5.65 10 %

5.77 10 %

6.00 10 %

7.4 SAR MEASUREMENT RESULT WITH BODY LIQUID Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Body Liquid Values: eps : 53.3 sigma : 1.51 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 1800 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 1800 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) measured 39.36 (3.94) measured 20.47 (2.05) Page: 10/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.7.17.SATU.A 8 LIST OF EQUIPMENT Equipment Summary Sheet Equipment Description Manufacturer /

Model Identification No. Current Calibration Date Next Calibration Date SAM Phantom MVG COMOSAR Test Bench Version 3 SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. NA Validated. required. Validated. required. No cal No cal Network Analyzer Rhode & Schwarz ZVA SN100132 Calipers Carrera CALIPER-01 02/2016 01/2017 Reference Probe MVG EPG122 SN 18/11 10/2016 Multimeter Keithley 2000 1188656 Signal Generator Agilent E4438C MY49070581 01/2017 01/2017 02/2019 01/2020 10/2017 01/2020 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 Power Sensor HP ECP-E26A US37181460 01/2017 01/2017 01/2020 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Temperature and Humidity Sensor Control Company 150798832 10/2015 8/2018 Page: 11/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR Reference Dipole Calibration Report Ref : ACR.262.8.17.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING B, ZHUOKE SCIENCE PARK,No.190, CHONGQING ROAD FUYONG STREET, BAO AN DISTRICT, SHENZHEN,GUANGDONG,CHINA

COMOSAR REFERENCE DIPOLE FREQUENCY: 1900 MHZ SERIAL NO.: SN 30/14 DIP1G900-333 Calibrated at US 2105 Barrett Park Dr. - Kennesaw, GA 30144 08/15/2017 Summary:

This document presents the method and results from an accredited SAR reference dipole calibration performed in MVG USA using the COMOSAR test bench. All calibration results are traceable to national metrology institutions. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A Prepared by :

Name Function Jrme LUC Product Manager Checked by :

Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager Signature Date 8/25/2017 8/25/2017 8/25/2017 Approved by :

Issue A Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Date 8/25/2017 Modifications Initial release Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A TABLE OF CONTENTS 1 Introduction ................................................................................................................ 4 2 Device Under Test ..................................................................................................... 4 3 Product Description ................................................................................................... 4 3.1 General Information _______________________________________________________ 4 4 Measurement Method ................................................................................................ 5 4.1 Return Loss Requirements __________________________________________________ 5 4.2 Mechanical Requirements ___________________________________________________ 5 5 Measurement Uncertainty .......................................................................................... 5 5.1 5.2 5.3 Return Loss ______________________________________________________________ 5 Dimension Measurement ___________________________________________________ 5 Validation Measurement ____________________________________________________ 5 6 Calibration Measurement Results .............................................................................. 6 Return Loss and Impedance In Head Liquid ____________________________________ 6 6.1 Return Loss and Impedance In Body Liquid ____________________________________ 6 6.2 6.3 Mechanical Dimensions ____________________________________________________ 6 7 Validation measurement ............................................................................................ 7 7.1 7.2 7.3 7.4 Head Liquid Measurement __________________________________________________ 7 SAR Measurement Result With Head Liquid ____________________________________ 8 Body Liquid Measurement __________________________________________________ 9 SAR Measurement Result With Body Liquid __________________________________ 10 8 List of Equipment .................................................................................................... 11 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval of . The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of . SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. DEVICE UNDER TEST 2 Device Under Test Device Type Manufacturer MVG Model Serial Number Product Condition (new / used) SID1900 SN 30/14 DIP1G900-333 New COMOSAR 1900 MHz REFERENCE DIPOLE A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION GENERAL INFORMATION 3.1 MVGs COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 MVG COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of -20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEI/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95%

confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURN LOSS The following uncertainties apply to the return loss measurement:

Frequency band 400-6000MHz Expanded Uncertainty on Return Loss 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements:

Length (mm) 3 - 300 Expanded Uncertainty on Length 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed the measurement uncertainty for validation measurements. to generate Scan Volume Expanded Uncertainty 1 g 10 g 20.3 %

20.1 %

Page: 5/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE IN HEAD LIQUID Frequency (MHz) 1900 Return Loss (dB)

-23.68 Requirement (dB)

-20 6.2 RETURN LOSS AND IMPEDANCE IN BODY LIQUID Frequency (MHz) 1900 Return Loss (dB)

-20.22 Requirement (dB)

-20 6.3 MECHANICAL DIMENSIONS Impedance 51.2 + 6.4 j Impedance 48.8 + 9.6 j Frequency MHz L mm h mm d mm 300 450 750 835 required measured required measured required measured 420.0 1 %. 290.0 1 %. 176.0 1 %. 161.0 1 %. 250.0 1 %. 166.7 1 %. 100.0 1 %. 89.8 1 %. 6.35 1 %. 6.35 1 %. 6.35 1 %. 3.6 1 %. Page: 6/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 2450 2600 3000 3500 3700 SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 149.0 1 %. 89.1 1 %. 80.5 1 %. 79.0 1 %. 75.2 1 %. 72.0 1 %. 68.0 1 %. 66.3 1 %. 64.5 1 %. 61.0 1 %. 55.5 1 %. 51.5 1 %. 48.5 1 %. 41.5 1 %. 37.01 %. 34.71 %. PASS 83.3 1 %. 51.7 1 %. 50.0 1 %. 45.7 1 %. 42.9 1 %. 41.7 1 %. 39.5 1 %. 38.5 1 %. 37.5 1 %. 35.7 1 %. 32.6 1 %. 30.4 1 %. 28.8 1 %. 25.0 1 %. 26.4 1 %. 26.4 1 %. PASS 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. PASS 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEI/IEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 Relative permittivity (r) Conductivity () S/m required measured required measured 45.3 5 %

43.5 5 %

41.9 5 %

41.5 5 %

41.5 5 %

40.5 5 %

40.4 5 %

40.2 5 %

40.1 5 %

40.0 5 %

40.0 5 %

40.0 5 %

40.0 5 %

PASS 0.87 5 %

0.87 5 %

0.89 5 %

0.90 5 %

0.97 5 %

1.20 5 %

1.23 5 %

1.31 5 %

1.37 5 %

1.40 5 %

1.40 5 %

1.40 5 %

1.40 5 %

PASS Page: 7/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 2100 2300 2450 2600 3000 3500 39.8 5 %

39.5 5 %

39.2 5 %

39.0 5 %

38.5 5 %

37.9 5 %

1.49 5 %

1.67 5 %

1.80 5 %

1.96 5 %

2.40 5 %

2.91 5 %

7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEI/IEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Head Liquid Values: eps : 41.1 sigma : 1.42 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 1900 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) required measured required measured 2.85 4.58 8.49 9.56 10.9 29 30.5 34.2 36.4 38.4 39.7 40.5 41.1 43.6 48.7 39.84 (3.98) 1.94 3.06 5.55 6.22 6.99 16 16.8 18.4 19.3 20.1 20.5 20.9 21.1 21.9 23.3 20.20 (2.02) Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 2450 2600 3000 3500 52.4 55.3 63.8 67.1 24 24.6 25.7 25 7.3 BODY LIQUID MEASUREMENT Frequency MHz 150 300 450 750 835 900 915 1450 1610 1800 1900 2000 2100 2450 2600 3000 3500 5200 5300 5400 Relative permittivity (r) Conductivity () S/m required measured required measured 61.9 5 %

58.2 5 %

56.7 5 %

55.5 5 %

55.2 5 %

55.0 5 %

55.0 5 %

54.0 5 %

53.8 5 %

53.3 5 %

53.3 5 %

53.3 5 %

53.2 5 %

52.7 5 %

52.5 5 %

52.0 5 %

51.3 5 %

49.0 10 %

48.9 10 %

48.7 10 %

PASS 0.80 5 %

0.92 5 %

0.94 5 %

0.96 5 %

0.97 5 %

1.05 5 %

1.06 5 %

1.30 5 %

1.40 5 %

1.52 5 %

1.52 5 %

1.52 5 %

1.62 5 %

1.95 5 %

2.16 5 %

2.73 5 %

3.31 5 %

5.30 10 %

5.42 10 %

5.53 10 %

PASS Page: 9/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 5500 5600 5800 48.6 10 %

48.5 10 %

48.2 10 %

5.65 10 %

5.77 10 %

6.00 10 %

7.4 SAR MEASUREMENT RESULT WITH BODY LIQUID Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Body Liquid Values: eps : 54.2 sigma : 1.54 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 1900 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 1900 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) measured 43.33 (4.33) measured 21.59 (2.16) Page: 10/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 8 LIST OF EQUIPMENT Equipment Summary Sheet Equipment Description Manufacturer /

Model Identification No. Current Calibration Date Next Calibration Date SAM Phantom MVG COMOSAR Test Bench Version 3 SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. NA Validated. required. Validated. required. No cal No cal Network Analyzer Rhode & Schwarz ZVA SN100132 Calipers Carrera CALIPER-01 02/2016 01/2017 Reference Probe MVG EPG122 SN 18/11 10/2016 Multimeter Keithley 2000 1188656 Signal Generator Agilent E4438C MY49070581 01/2017 01/2017 02/2019 01/2020 10/2017 01/2020 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 Power Sensor HP ECP-E26A US37181460 01/2017 01/2017 01/2020 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Temperature and Humidity Sensor Control Company 150798832 10/2015 10/2017 Page: 11/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR Reference Dipole Calibration Report Ref : ACR.262.10.17.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING B, ZHUOKE SCIENCE PARK,No.190, CHONGQING ROAD,FUYONG STREET, BAO AN DISTRICT, SHENZHEN,GUANGDONG,CHINA MVG COMOSAR REFERENCE DIPOLE FREQUENCY: 2450 MHZ SERIAL NO.: SN 30/14 DIP2G450-335 Calibrated at MVG US 2105 Barrett Park Dr. - Kennesaw, GA 30144 08/15/2017 Summary:

This document presents the method and results from an accredited SAR reference dipole calibration performed in MVG USA using the COMOSAR test bench. All calibration results are traceable to national metrology institutions. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A Prepared by :

Name Function Jrme LUC Product Manager Checked by :

Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager Signature Date 8/25/2017 8/25/2017 8/25/2017 Approved by :

Issue A Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Date 8/25/2017 Modifications Initial release Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A TABLE OF CONTENTS 1 Introduction ................................................................................................................ 4 2 Device Under Test ..................................................................................................... 4 3 Product Description ................................................................................................... 4 3.1 General Information _______________________________________________________ 4 4 Measurement Method ................................................................................................ 5 4.1 Return Loss Requirements __________________________________________________ 5 4.2 Mechanical Requirements ___________________________________________________ 5 5 Measurement Uncertainty .......................................................................................... 5 5.1 5.2 5.3 Return Loss ______________________________________________________________ 5 Dimension Measurement ___________________________________________________ 5 Validation Measurement ____________________________________________________ 5 6 Calibration Measurement Results .............................................................................. 6 Return Loss and Impedance In Head Liquid ____________________________________ 6 6.1 Return Loss and Impedance In Body Liquid ____________________________________ 6 6.2 6.3 Mechanical Dimensions ____________________________________________________ 6 7 Validation measurement ............................................................................................ 7 7.1 7.2 7.3 7.4 Head Liquid Measurement __________________________________________________ 7 SAR Measurement Result With Head Liquid ____________________________________ 8 Body Liquid Measurement __________________________________________________ 9 SAR Measurement Result With Body Liquid __________________________________ 10 8 List of Equipment .................................................................................................... 11 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. DEVICE UNDER TEST 2 Device Under Test Device Type Manufacturer MVG Model Serial Number Product Condition (new / used) SID2450 SN 30/14 DIP2G450-335 New COMOSAR 2450 MHz REFERENCE DIPOLE A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION GENERAL INFORMATION 3.1 MVGs COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 MVG COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of -20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEI/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95%

confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURN LOSS The following uncertainties apply to the return loss measurement:

Frequency band 400-6000MHz Expanded Uncertainty on Return Loss 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements:

Length (mm) 3 - 300 Expanded Uncertainty on Length 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed the measurement uncertainty for validation measurements. to generate Scan Volume Expanded Uncertainty 1 g 10 g 20.3 %

20.1 %

Page: 5/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE IN HEAD LIQUID Frequency (MHz) 2450 Return Loss (dB)

-26.00 Requirement (dB)

-20 6.2 RETURN LOSS AND IMPEDANCE IN BODY LIQUID Frequency (MHz) 2450 Return Loss (dB)

-32.75 Requirement (dB)

-20 6.3 MECHANICAL DIMENSIONS Impedance 46.1 + 3.2 j Impedance 48.8 + 1.9 j Frequency MHz L mm h mm d mm 300 450 750 835 required measured required measured required measured 420.0 1 %. 290.0 1 %. 176.0 1 %. 161.0 1 %. 250.0 1 %. 166.7 1 %. 100.0 1 %. 89.8 1 %. 6.35 1 %. 6.35 1 %. 6.35 1 %. 3.6 1 %. Page: 6/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 2450 2600 3000 3500 3700 SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 149.0 1 %. 89.1 1 %. 80.5 1 %. 79.0 1 %. 75.2 1 %. 72.0 1 %. 68.0 1 %. 66.3 1 %. 64.5 1 %. 61.0 1 %. 55.5 1 %. 51.5 1 %. 48.5 1 %. 41.5 1 %. 37.01 %. 34.71 %. PASS 83.3 1 %. 51.7 1 %. 50.0 1 %. 45.7 1 %. 42.9 1 %. 41.7 1 %. 39.5 1 %. 38.5 1 %. 37.5 1 %. 35.7 1 %. 32.6 1 %. 30.4 1 %. 28.8 1 %. 25.0 1 %. 26.4 1 %. 26.4 1 %. PASS 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. PASS 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEI/IEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 Relative permittivity (r) Conductivity () S/m required measured required measured 45.3 5 %

43.5 5 %

41.9 5 %

41.5 5 %

41.5 5 %

40.5 5 %

40.4 5 %

40.2 5 %

40.1 5 %

40.0 5 %

40.0 5 %

40.0 5 %

40.0 5 %

0.87 5 %

0.87 5 %

0.89 5 %

0.90 5 %

0.97 5 %

1.20 5 %

1.23 5 %

1.31 5 %

1.37 5 %

1.40 5 %

1.40 5 %

1.40 5 %

1.40 5 %

Page: 7/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 2100 2300 2450 2600 3000 3500 39.8 5 %

39.5 5 %

39.2 5 %

39.0 5 %

38.5 5 %

37.9 5 %

PASS 1.49 5 %

1.67 5 %

1.80 5 %

1.96 5 %

2.40 5 %

2.91 5 %

PASS 7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEI/IEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Head Liquid Values: eps : 39.0 sigma : 1.77 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 2450 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) required measured required measured 2.85 4.58 8.49 9.56 10.9 29 30.5 34.2 36.4 38.4 39.7 40.5 41.1 43.6 48.7 1.94 3.06 5.55 6.22 6.99 16 16.8 18.4 19.3 20.1 20.5 20.9 21.1 21.9 23.3 Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 2450 2600 3000 3500 52.4 55.3 63.8 67.1 54.70 (5.47) 24 24.6 25.7 25 24.11 (2.41) 7.3 BODY LIQUID MEASUREMENT Frequency MHz 150 300 450 750 835 900 915 1450 1610 1800 1900 2000 2100 2450 2600 3000 3500 5200 5300 5400 Relative permittivity (r) Conductivity () S/m required measured required measured 61.9 5 %

58.2 5 %

56.7 5 %

55.5 5 %

55.2 5 %

55.0 5 %

55.0 5 %

54.0 5 %

53.8 5 %

53.3 5 %

53.3 5 %

53.3 5 %

53.2 5 %

52.7 5 %

52.5 5 %

52.0 5 %

51.3 5 %

49.0 10 %

48.9 10 %

48.7 10 %

PASS 0.80 5 %

0.92 5 %

0.94 5 %

0.96 5 %

0.97 5 %

1.05 5 %

1.06 5 %

1.30 5 %

1.40 5 %

1.52 5 %

1.52 5 %

1.52 5 %

1.62 5 %

1.95 5 %

2.16 5 %

2.73 5 %

3.31 5 %

5.30 10 %

5.42 10 %

5.53 10 %

PASS Page: 9/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 5500 5600 5800 48.6 10 %

48.5 10 %

48.2 10 %

5.65 10 %

5.77 10 %

6.00 10 %

7.4 SAR MEASUREMENT RESULT WITH BODY LIQUID Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Body Liquid Values: eps : 53.0 sigma : 1.93 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 2450 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 2450 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) measured 55.65 (5.57) measured 24.56 (2.46) Page: 10/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.8.17.SATU.A 8 LIST OF EQUIPMENT Equipment Summary Sheet Equipment Description Manufacturer /

Model Identification No. Current Calibration Date Next Calibration Date SAM Phantom MVG COMOSAR Test Bench Version 3 SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. NA Validated. required. Validated. required. No cal No cal Network Analyzer Rhode & Schwarz ZVA SN100132 Calipers Carrera CALIPER-01 02/2016 01/2017 Reference Probe MVG EPG122 SN 18/11 10/2016 Multimeter Keithley 2000 1188656 Signal Generator Agilent E4438C MY49070581 01/2017 01/2017 02/2019 01/2020 10/2017 01/2020 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 Power Sensor HP ECP-E26A US37181460 01/2017 01/2017 01/2020 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Temperature and Humidity Sensor Control Company 150798832 10/2015 10/2017 Page: 11/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR Reference Dipole Calibration Report Ref : ACR.262.11.17.SATU.A SHENZHEN STS TEST SERVICES CO., LTD. 1/F., BUILDING B, ZHUOKE SCIENCE PARK,No.190, CHONG QING ROAD, FUYONG STREET, BAO AN DISTRICT, SHENZHEN,GUANGDONG,CHINA MVG COMOSAR REFERENCE DIPOLE FREQUENCY: 2600 MHZ SERIAL NO.: SN 30/14 DIP2G600-336 Calibrated at MVG US 2105 Barrett Park Dr. - Kennesaw, GA 30144 08/15/2017 Summary:

This document presents the method and results from an accredited SAR reference dipole calibration performed in MVG USA using the COMOSAR test bench. All calibration results are traceable to national metrology institutions. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A Prepared by :

Name Function Jrme LUC Product Manager Checked by :

Jrme LUC Product Manager Kim RUTKOWSKI Quality Manager Signature Date 8/25/2017 8/25/2017 8/25/2017 Approved by :

Issue A Distribution :

Customer Name Shenzhen STS Test Services Co., Ltd. Date 8 8/25/2017 Initial release Modifications Page: 2/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A TABLE OF CONTENTS 1 Introduction ................................................................................................................ 4 2 Device Under Test ..................................................................................................... 4 3 Product Description ................................................................................................... 4 3.1 General Information _______________________________________________________ 4 4 Measurement Method ................................................................................................ 5 4.1 Return Loss Requirements __________________________________________________ 5 4.2 Mechanical Requirements ___________________________________________________ 5 5 Measurement Uncertainty .......................................................................................... 5 5.1 5.2 5.3 Return Loss ______________________________________________________________ 5 Dimension Measurement ___________________________________________________ 5 Validation Measurement ____________________________________________________ 5 6 Calibration Measurement Results .............................................................................. 6 Return Loss and Impedance In Head Liquid ____________________________________ 6 6.1 Return Loss and Impedance In Body Liquid ____________________________________ 6 6.2 6.3 Mechanical Dimensions ____________________________________________________ 6 7 Validation measurement ............................................................................................ 7 7.1 7.2 7.3 7.4 Head Liquid Measurement __________________________________________________ 7 SAR Measurement Result With Head Liquid ____________________________________ 8 Body Liquid Measurement __________________________________________________ 9 SAR Measurement Result With Body Liquid __________________________________ 10 8 List of Equipment .................................................................................................... 11 Page: 3/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 1 INTRODUCTION This document contains a summary of the requirements set forth by the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards for reference dipoles used for SAR measurement system validations and the measurements that were performed to verify that the product complies with the fore mentioned standards. DEVICE UNDER TEST 2 Device Under Test Device Type Manufacturer MVG Model Serial Number Product Condition (new / used) SID2600 SN 30/14 DIP2G600-336 New COMOSAR 2600 MHz REFERENCE DIPOLE A yearly calibration interval is recommended. 3 PRODUCT DESCRIPTION GENERAL INFORMATION 3.1 MVGs COMOSAR Validation Dipoles are built in accordance to the IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards. The product is designed for use with the COMOSAR test bench only. Figure 1 COMOSAR Validation Dipole Page: 4/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 4 MEASUREMENT METHOD The IEEE 1528, OET 65 Bulletin C and CEI/IEC 62209 standards provide requirements for reference dipoles used for system validation measurements. The following measurements were performed to verify that the product complies with the fore mentioned standards. 4.1 RETURN LOSS REQUIREMENTS The dipole used for SAR system validation measurements and checks must have a return loss of -20 dB or better. The return loss measurement shall be performed against a liquid filled flat phantom, with the phantom constucted as outlined in the fore mentioned standards. 4.2 MECHANICAL REQUIREMENTS The IEEE Std. 1528 and CEI/IEC 62209 standards specify the mechanical components and dimensions of the validation dipoles, with the dimensions frequency and phantom shell thickness dependent. The COMOSAR test bench employs a 2 mm phantom shell thickness therefore the dipoles sold for use with the COMOSAR test bench comply with the requirements set forth for a 2 mm phantom shell thickness. 5 MEASUREMENT UNCERTAINTY All uncertainties listed below represent an expanded uncertainty expressed at approximately the 95%

confidence level using a coverage factor of k=2, traceable to the Internationally Accepted Guides to Measurement Uncertainty. 5.1 RETURN LOSS The following uncertainties apply to the return loss measurement:

Frequency band 400-6000MHz Expanded Uncertainty on Return Loss 0.1 dB 5.2 DIMENSION MEASUREMENT The following uncertainties apply to the dimension measurements:

Length (mm) 3 - 300 Expanded Uncertainty on Length 0.05 mm 5.3 VALIDATION MEASUREMENT The guidelines outlined in the IEEE 1528, OET 65 Bulletin C, CENELEC EN50361 and CEI/IEC 62209 standards were followed the measurement uncertainty for validation measurements. to generate Scan Volume Expanded Uncertainty 1 g 10 g 20.3 %

20.1 %

Page: 5/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 6 CALIBRATION MEASUREMENT RESULTS 6.1 RETURN LOSS AND IMPEDANCE IN HEAD LIQUID Frequency (MHz) 2600 Return Loss (dB)

-34.35 Requirement (dB)

-20 6.2 RETURN LOSS AND IMPEDANCE IN BODY LIQUID Frequency (MHz) 2600 Return Loss (dB)

-24.18 Requirement (dB)

-20 6.3 MECHANICAL DIMENSIONS Impedance 50.2 + 1.9 j Impedance 45.7 - 4.5 j Frequency MHz L mm h mm d mm 300 450 750 835 required measured required measured required measured 420.0 1 %. 290.0 1 %. 176.0 1 %. 161.0 1 %. 250.0 1 %. 166.7 1 %. 100.0 1 %. 89.8 1 %. 6.35 1 %. 6.35 1 %. 6.35 1 %. 3.6 1 %. Page: 6/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 2450 2600 3000 3500 3700 SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 149.0 1 %. 89.1 1 %. 80.5 1 %. 79.0 1 %. 75.2 1 %. 72.0 1 %. 68.0 1 %. 66.3 1 %. 64.5 1 %. 61.0 1 %. 55.5 1 %. 51.5 1 %. 48.5 1 %. 41.5 1 %. 37.01 %. 34.71 %. PASS 83.3 1 %. 51.7 1 %. 50.0 1 %. 45.7 1 %. 42.9 1 %. 41.7 1 %. 39.5 1 %. 38.5 1 %. 37.5 1 %. 35.7 1 %. 32.6 1 %. 30.4 1 %. 28.8 1 %. 25.0 1 %. 26.4 1 %. 26.4 1 %. PASS 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. 3.6 1 %. PASS 7 VALIDATION MEASUREMENT The IEEE Std. 1528, OET 65 Bulletin C and CEI/IEC 62209 standards state that the system validation measurements must be performed using a reference dipole meeting the fore mentioned return loss and mechanical dimension requirements. The validation measurement must be performed against a liquid filled flat phantom, with the phantom constructed as outlined in the fore mentioned standards. Per the standards, the dipole shall be positioned below the bottom of the phantom, with the dipole length centered and parallel to the longest dimension of the flat phantom, with the top surface of the dipole at the described distance from the bottom surface of the phantom. 7.1 HEAD LIQUID MEASUREMENT Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 Relative permittivity (r) Conductivity () S/m required measured required measured 45.3 5 %

43.5 5 %

41.9 5 %

41.5 5 %

41.5 5 %

40.5 5 %

40.4 5 %

40.2 5 %

40.1 5 %

40.0 5 %

40.0 5 %

40.0 5 %

40.0 5 %

0.87 5 %

0.87 5 %

0.89 5 %

0.90 5 %

0.97 5 %

1.20 5 %

1.23 5 %

1.31 5 %

1.37 5 %

1.40 5 %

1.40 5 %

1.40 5 %

1.40 5 %

Page: 7/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 2100 2300 2450 2600 3000 3500 39.8 5 %

39.5 5 %

39.2 5 %

39.0 5 %

38.5 5 %

37.9 5 %

PASS 1.49 5 %

1.67 5 %

1.80 5 %

1.96 5 %

2.40 5 %

2.91 5 %

PASS 7.2 SAR MEASUREMENT RESULT WITH HEAD LIQUID The IEEE Std. 1528 and CEI/IEC 62209 standards state that the system validation measurements should produce the SAR values shown below (for phantom thickness of 2 mm), within the uncertainty for the system validation. All SAR values are normalized to 1 W forward power. In bracket, the measured SAR is given with the used input power. Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Head Liquid Values: eps : 38.3 sigma : 1.92 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 2600 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 300 450 750 835 900 1450 1500 1640 1750 1800 1900 1950 2000 2100 2300 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) required measured required measured 2.85 4.58 8.49 9.56 10.9 29 30.5 34.2 36.4 38.4 39.7 40.5 41.1 43.6 48.7 1.94 3.06 5.55 6.22 6.99 16 16.8 18.4 19.3 20.1 20.5 20.9 21.1 21.9 23.3 Page: 8/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 2450 2600 3000 3500 52.4 55.3 63.8 67.1 56.19 (5.62) 24 24.6 25.7 25 24.08 (2.41) 7.3 BODY LIQUID MEASUREMENT Frequency MHz 150 300 450 750 835 900 915 1450 1610 1800 1900 2000 2100 2450 2600 3000 3500 5200 5300 5400 Relative permittivity (r) Conductivity () S/m required measured required measured 61.9 5 %

58.2 5 %

56.7 5 %

55.5 5 %

55.2 5 %

55.0 5 %

55.0 5 %

54.0 5 %

53.8 5 %

53.3 5 %

53.3 5 %

53.3 5 %

53.2 5 %

52.7 5 %

52.5 5 %

52.0 5 %

51.3 5 %

49.0 10 %

48.9 10 %

48.7 10 %

PASS 0.80 5 %

0.92 5 %

0.94 5 %

0.96 5 %

0.97 5 %

1.05 5 %

1.06 5 %

1.30 5 %

1.40 5 %

1.52 5 %

1.52 5 %

1.52 5 %

1.62 5 %

1.95 5 %

2.16 5 %

2.73 5 %

3.31 5 %

5.30 10 %

5.42 10 %

5.53 10 %

PASS Page: 9/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 5500 5600 5800 48.6 10 %

48.5 10 %

48.2 10 %

5.65 10 %

5.77 10 %

6.00 10 %

7.4 SAR MEASUREMENT RESULT WITH BODY LIQUID Software Phantom Probe Liquid Distance between dipole center and liquid Area scan resolution Zoon Scan Resolution Frequency Input power Liquid Temperature Lab Temperature Lab Humidity OPENSAR V4 SN 20/09 SAM71 SN 18/11 EPG122 Body Liquid Values: eps : 51.8 sigma : 2.19 10.0 mm dx=8mm/dy=8mm dx=8mm/dy=8m/dz=5mm 2600 MHz 20 dBm 21 C 21 C 45 %

Frequency MHz 2600 1 g SAR (W/kg/W) 10 g SAR (W/kg/W) measured 57.49 (5.75) measured 24.88 (2.49) Page: 10/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG. SAR REFERENCE DIPOLE CALIBRATION REPORT Ref: ACR.262.11.17.SATU.A 8 LIST OF EQUIPMENT Equipment Summary Sheet Equipment Description Manufacturer /

Model Identification No. Current Calibration Date Next Calibration Date SAM Phantom MVG COMOSAR Test Bench Version 3 Network Analyzer Rhode & Schwarz ZVA SN-20/09-SAM71 Validated. No cal required. Validated. No cal required. NA Validated. required. Validated. required. No cal No cal SN100132 02/2016 02/2019 Calipers Carrera CALIPER-01 01/2017 01/2020 Reference Probe MVG EPG122 SN 18/11 10/2016 10/2017 Multimeter Keithley 2000 1188656 01/2017 01/2020 Signal Generator Agilent E4438C MY49070581 01/2017 01/2020 Amplifier Aethercomm SN 046 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Power Meter HP E4418A US38261498 01/2017 01/2020 Power Sensor HP ECP-E26A US37181460 01/2012 01/2020 Directional Coupler Narda 4216-20 01386 Characterized prior to test. No cal required. Characterized prior to test. No cal required. Temperature and Humidity Sensor Control Company 150798832 10/2015 10/2017 Page: 11/11 This document shall not be reproduced, except in full or in part, without the written approval of MVG. The information contained herein is to be used only for the purpose for which it is submitted and is not to be released in whole or part without written approval of MVG.

 

 

S T S L A B SAR Dipole Performance Measurement Report EUT Type SAR Validation Dipole and Waveguide Model Name DIP 0G750-331,DIP 0G835-332, DIP 1G800-329, DIP 1G900-333, DIP 2G450-335, DIP 2G600-336 Brand Name:

SATIMO Test Conclusion Pass Test Date 14 Aug. 2019~16 Aug. 2019 Date of Issue 17 Aug. 2019 Testing Engineer

Technical Manager

Authorized Signatory :

(Aaron Bu)

(Jason Lu)

(Vita Li) Any reproduction of this document must be done in full. No single part of this document may be reproduced without permission from STS, All Test Data Presented in this report is only applicable to presented Test sample. Shenzhen STS Test Services Co., Ltd. 1/F., Building B, Zhuoke Science Park, No.190,Chongqing Road, Fuyong Street, Baoan District, Shenzhen, Guangdong, China TEL: +86-755 3688 6288 FAX: +86-755 3688 6277 E-mail:sts@stsapp.com 1. Equipment List ISSUED BY Shenzhen STS Test Services Co., Ltd. Kind of Equipment Manufacturer Type No. Serial No. Last Calibration Calibrated Until PC Acer N/A N/A N/A N/A E-Field Probe MVG SSE5 SN 14/16 EP309 2018.12.13 2019.12.12 Dielectric Probe Kit MVG SCLMP Phantom1 Phantom2 MVG MVG SAM SAM SN 32/14 OCPG67 SN 32/14 SAM115 SN 32/14 SAM116 Attenuator Agilent 99899 DC-18GHz Directional coupler Narda 4226-20 3305 2018.12.01 2019.11.30 N/A N/A N/A N/A N/A N/A N/A N/A Network Analyzer Agilent 8753ES US38432810 2019.03.02 2020.03.01 Multi Meter Keithley Multi Meter 2000 4050073 2018.10.13 2019.10.12 Signal Generator Agilent N5182A MY50140530 2018.10.16 2019.10.15 Power Amplifier DESAY ZHL-42W 9638 2018.10.13 2019.10.12 Power Meter R&S NRP 100510 2018.10.26 2019.10.25 Power Sensor R&S NRP-Z11 101919 2018.10.13 2019.10.12 Power Sensor Agilent E9301A MY41497725 2018.10.13 2019.10.12 hygrothermograph MiEO HH660 N/A 2018.10.15 2019.10.14 2.<Justification of the extended calibration>

ISSUED BY Shenzhen STS Test Services Co., Ltd. Referring to KDB 865664 D01, if dipoles are verified in return loss<-20dB, (within 20% of prior calibration),and in impedance (within 5 ohm of prior calibration), the annual calibration is not necessary and the calibration interval can be extended. Head 750 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-25.42 2018.08.15

-23.45 2019.8.14

-23.25 Delta (%) Impedance Delta(ohm)

-7.75

-0.85 55.1 55.84 56.98

0.74 1.14 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Head 750 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Body 750 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-27.21 2018.08.15

-26.44 2019.08.14

-26.17 Delta (%) Impedance Delta(ohm)

-2.82

-1.02 51.3 51.50 52.89

0.20 1.39 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Body 750 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Head 835 MHz Date of Measurement Return Loss

(dB) Delta (%) Impedance Delta(ohm) 2017.08.15

-28.11

2018.08.15

-27.05

-3.77 2019.08.14

-26.41

-2.37 51.6 54.69 52.62

3.09

-2.07 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Head 835MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Body 835 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-23.87 2018.08.15

-22.21 2019.08.14

-24.25 Delta (%) Impedance Delta(ohm)

-6.95 9.19 49.0 52.59 52.65

3.59 0.06 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Body 835MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Head 1800 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-29.51 2018.08.16

-25.32 2019.08.15

-26.39 Delta (%) Impedance Delta(ohm)

-14.2 4.23 46.7 45.24 44.94

-1.46

-0.30 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Head 1800 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Body 1800 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-24.59 2018.08.16

-24.95 2019.08.15

-26.77 Delta (%) Impedance Delta(ohm)

1.46 7.29 48.8 45.42 46.31

-3.38 0.79 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Body 1800 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Head 1900 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-23.68 2018.08.16

-25.00 2019.08.15

-23.79 Delta (%) Impedance Delta(ohm)

5.57

-4.84 51.2 47.12 48.62

-4.08 1.50 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Head 1900 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Body 1900 MHz Date of Measurement Return Loss

(dB) Delta (%) Impedance Delta(ohm) 2017.08.15

-20.22

2018.08.16

-23.26 2019.08.15

-24.15 15.03 3.83 48.8 47.11 48.71

-1.79 1.60 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Body 1900 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Head 2450 MHz Date of Measurement Return Loss

(dB) Delta (%) Impedance Delta(ohm) 2017.08.15

-26.00

2018.08.16

-29.56 2019.08.16

-28.39 13.69

-3.96 46.1 47.53 48.46

1.43 0.93 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Head 2450 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Body 2450 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-32.75 2018.08.16

-31.06 2019.08.16

-30.52 Delta (%) Impedance Delta(ohm)

-5.16

-1.74 48.8 45.61 46.33

-3.19 0.72 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Body 2450 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Head 2600 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-34.35 2018.08.16

-31.25 2019.08.16

-31.54 Delta (%) Impedance Delta(ohm)

-9.02 0.93 50.2 53.76 53.82

3.56 0.06 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Head 2600 MHz ISSUED BY Shenzhen STS Test Services Co., Ltd. Body 2600 MHz Date of Measurement Return Loss

(dB) 2017.08.15

-24.18 2018.08.16

-23.36 2019.08.16

-23.02 Delta (%) Impedance Delta(ohm)

-7.52

-1.46 45.7 46.79 44.37

1.09

-2.42 The return loss is <-20dB, within 20% of prior calibration; the impedance is within 5 ohm of prior calibration. Therefore the verification result should support extended calibration.

<Dipole Verification Data>

Body 2600 MHz

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Chip Declaration Letter We Sun Cupid Technology (HK) Ltd. state:

Product Smart phone Model Name X6 FCC ID: 2ADINS5702L These requirements are met by way of the operation of the chip setup. 15.247 (g) and (h)

(g) Frequency hopping spread spectrum systems are not required to employ all available hopping channels during each transmission. However, the system, consisting of both the transmitter and the receiver, must be designed to comply with all of the regulations in this section should the transmitter be presented with a continuous data (or information) stream. In addition, a system employing short transmission bursts must comply with the definition of a frequency hopping system and must distribute its transmissions over the minimum number of hopping channels specified in this section.

(h) The incorporation of intelligence within a frequency hopping spread spectrum system that permits the system to recognize other users within the spectrum band so that it individually and independently chooses and adapts its hopsets to avoid hopping on occupied channels is permitted. The coordination of frequency hopping systems in any other manner for the express purpose of avoiding the simultaneous occupancy of individual hopping frequencies by multiple transmitters is not permitted. Signatory Date 2019-12-06 Signature Name: Danny Sit Title: Project Manager Company: Sun Cupid Technology (HK) Ltd. Address: 16/F, CEO Tower, 77 Wing Hong St, Cheung Sha Wan, Kowloon, Hong Kong, China.