TEST REPORT - CUBOT · Page 3 of 95 Report No.: GTI20140202E-8 Shenzhen General ... B 3.00% R 3 1 1 1.70 % 1.70 % ∞ 12 Probe positioned mech. restrictions B 0.40% R 3 1 1 0.20 %

Shenzhen GTI Technology Co., Ltd

1F,2 Block,Jiaquan Building,Guanlan High-tech Park Baoan District, Shenzhen,Guangdong,China Tel : +86-755-27559792 Fax: +86-755-86116468

Report no.: GTI20140202E-8Page 1 of 95

TEST REPORT

Product name ............................ : GSM Mobile Phone

Trademark ................................. : CUBOT

Model no. ................................... : S308

Test Standards .......................... :

EN50360:2001/A1:2012

EN62209-1:2006

EN62209-2:2010

EN50566:2013 EN62479:2010

Applicant ................................... : Shenzhen HuaFuRui Technology Co.,Ltd.

Address of applicant ................ : Room No. 222, Building 402(ZhongLian Building),SangDa Industrial Park, FuTian, Shenzhen, China.

Date of Receipt ......................... : June 15, 2014

Date of Test Date ....................... : June 16, 2014 -July 10, 2014

Data of issue. ............................ : July 11, 2014

Test result ...................... : Pass *

* In the configuration tested, the EUT complied with the standards specified above

The CE mark as shown above can be used, under the responsibility of the manufacturer, after

completion of an EC Declaration of Conformity and compliance with all relevant EC Directives.

The protection requirements with respect to electromagnetic compatibility contained in Directive

1999/5/EC are considered.

Page 3 of 95 Report No.: GTI20140202E-8

Shenzhen General Testing & Inspection Technology Co., Ltd.

1F,2 Block,Jiaquan Building,Guanlan High-tech Park Baoan District,Shenzhen,Guangdong,China

Tel.: (86)755-27588991 Fax.: (86)755-86116468 Http://www.sz-ctc.com.cn

Table of Contents Page

1. TEST SUMMARY .................................................................................................................................................... 4

1.1. TEST STANDARDS .......................................................................................................................................................... 41.2. SUMMARY SAR RESULTS ............................................................................................................................................... 41.3. TEST FACILITY .............................................................................................................................................................. 51.4. MEASUREMENT UNCERTAINTY ........................................................................................................................................ 5

2. GENERAL INFORMATION ....................................................................................................................................... 7

2.1. ENVIRONMENTAL CONDITIONS ........................................................................................................................................ 72.2. GENERAL DESCRIPTION OF EUT ...................................................................................................................................... 72.3. DESCRIPTION OF TEST MODES ........................................................................................................................................ 82.4. MEASUREMENT INSTRUMENTS LIST ................................................................................................................................. 8

3. SAR MEASUREMENTS SYSTEM CONFIGURATION ................................................................................................... 9

3.1 SAR MEASUREMENT SET‐UP .................................................................................................................................... 93.2 DASY5 E‐FIELD PROBE SYSTEM .............................................................................................................................. 103.3 PHANTOMS............................................................................................................................................................ 113.4 DEVICE HOLDER ..................................................................................................................................................... 113.5 SCANNING PROCEDURE ......................................................................................................................................... 113.6 DATA STORAGE AND EVALUATION ......................................................................................................................... 123.7 POSITION OF THE WIRELESS DEVICE IN RELATION TO THE PHANTOM ................................................................... 143.8 DIELECTRIC PERFORMANCE ................................................................................................................................... 203.9 SYSTEM CHECK ...................................................................................................................................................... 213.10 MEASUREMENT PROCEDURES .............................................................................................................................. 22

4. TEST CONDITIONS AND RESULTS ......................................................................................................................... 28

4.1. CONDUCTED POWER RESULTS ............................................................................................................................... 284.2. TEST REDUCTION PROCEDURE .............................................................................................................................. 314.3. SAR MEASUREMENT RESULTS ...................................................................................................................................... 324.4. SYSTEM CHECK RESULTS ........................................................................................................................................ 344.5. SAR TEST GRAPH RESULTS ...................................................................................................................................... 38

5. CALIBRATION CERTIFICATE .................................................................................................................................. 46

5.1. PROBE CALIBRATION CERTICATE ............................................................................................................................ 465.2. D900V2 DIPOLE CALIBRATION CERTICATE ............................................................................................................. 575.3. D1750V2 DIPOLE CALIBRATION CERTICATE ........................................................................................................... 655.4. D1900V2 DIPOLE CALIBRATION CERTICATE ........................................................................................................... 735.5. D2450V2 DIPOLE CALIBRATION CERITICATE ................................................................................................................... 815.6. DAE4 CALIBRATION CERTICATE .............................................................................................................................. 89

6. EUT TEST PHOTO ................................................................................................................................................ 92

7. PHOTOGRAPHS OF EUT CONSTRUCTIONAL ......................................................................................................... 95





1. TEST SUMMARY

1.1. Test Standards

The tests were performed according to following standards:

EN 50360:2001/A1:2012: Product standard to demonstrate the compliance of GSM phones with the

basic restrictions related to human exposure to electromagnetic fields (300 MHz - 3 GHz)

EN 62209-1 2006: Human exposure to radio frequency fields from hand-held and body-mounted

wireless communication devices – Human models, instrumentation, and procedures –Part 1:

Procedure to determine the specific absorption rate (SAR) for hand-held devices used in close

proximity to the ear (frequency range of 300 MHz to 3 GHz)

EN 62209-2 2010: Human exposure to radio frequency fields from hand-held and bodymounted

wireless communication devices.Human models,instrumentation, and procedures. Part 2: Procedure

to determine thespecific absorption rate (SAR) forwireless communication devices usedin close

proximity to the human body(frequency range of 30 MHz to 6 GHz)

EN 62479:2010: Assesment of the compliance of low-power electronic and electrical equipment with

the basic restrictions related to human exposure to electromagnetic fields (10 MHz to 300 GHz)

EN50566:2013: Product standard to demonstrate compliance of radio frequency fields from handheld

and body-mounted wireless communication devices used by the general public (30 MHz - 6 GHz)

1.2. Summary SAR Results

Max. SAR Measured(10g)

Exposure Configuration Technology Band Highest Measured SAR

10g(W/Kg)

Head (Separation Distance 0mm)

GSM900 0.328 DCS1800 0.198

WCDMA Band I 0.134 WLAN2450 0.278

Body-worn (Separation Distance 10mm)

GSM900 0.531 DCS1800 0.347

WCDMA Band I 0.228 WLAN2450 0.427





1.3. Test Facility

1.3.1 Address of the test laboratory


Add: 1F, 2 Block, Jiaquan Building, Guanlan High-tech Park Baoan District,

Shenzhen, Guangdong, China.

1.3.2 Laboratory accreditation

The test facility is recognized, certified, or accredited by the following organizations:

IC Registration No.: 9783A

The 3m alternate test site of Shenzhen GTI Technology Co., Ltd.EMC Laboratory has been registered

by Certification and Engineer Bureau of Industry Canada for the performance of with Registration NO.:

9783A on Aug, 2011.

FCC-Registration No.: 214666

Shenzhen GTI Technology Co., Ltd. EMC Laboratory has been registered and fully described in a

report filed with the (FCC) Federal Communications Commission. The acceptance letter from the FCC

is maintained in our files. Registration 214666, Sep 19, 2011

1.4. Measurement Uncertainty

The reported uncertainty of measurement y ± U，where expended uncertainty U is based on a standard

uncertainty multiplied by a coverage factor of k=2，providing a level of confidence of approximately

95 %

No. Error

Description Type

Uncertainty

Value

Probably Distributi

on

Div.

(Ci)1g

(Ci) 10g

Std. Unc. (1g)

Std. Unc. (10g)

Degree of

freedom

Measurement System

1 Probe

calibration B 5.50% N 1 1 1

5.50%

5.50%

∞

2 Axial

isotropy B 4.70% R 3

0.7 0.7

1.90%

1.90%

∞

3 Hemispherical

isotropy B 9.60% R 3

0.7 0.7

3.90%

3.90%

∞

4 Boundary

Effects B 1.00% R 3

1 1

0.60%

0.60%

∞

5 Probe

Linearity B 4.70% R 3

1 1

2.70%

2.70%

∞

6 Detection limit B 1.00% R 3

1 1 0.60%

0.60%

∞

7 RF ambient

conditions-noise B 0.00% R 3

1 1

0.00%

0.00%

∞





8 RF ambient

conditions-reflection

B 0.00% R 3

1 1 0.00%

0.00%

∞

9 Response time B 0.80% R 3

1 1 0.50%

0.50%

∞

10 Integration time B 5.00% R 3

1 1 2.90%

2.90%

∞

11 RF

ambient B 3.00% R 3

1 1

1.70%

1.70%

∞

12

Probe positioned

mech. restrictions

B 0.40% R 3

1 1 0.20%

0.20%

∞

13

Probe positioning with

respect to phantom shell

B 2.90% R 3

1 1 1.70%

1.70%

∞

14 Max.SAR evalation

B 3.90% R 3

1 1 2.30%

2.30%

∞

Test Sample Related

15 Test sample positioning

A 1.86% N 1 1 1 1.86%

1.86%

∞

16 Device holder

uncertainty A 1.70% N 1 1 1

1.70%

1.70%

∞

17 Drift of output

power B 5.00% R 3

1 1

2.90%

2.90%

∞

Phantom and Set-up

18 Phantom

uncertainty B 4.00% R 3

1 1

2.30%

2.30%

∞

19 Liquid

conductivity (target)

B 5.00% R 3

0.64

0.43

1.80%

1.20%

∞

20 Liquid

conductivity (meas.)

A 0.50% N 1 0.64

0.43

0.32%

0.26%

∞

21 Liquid

permittivity (target)

B 5.00% R 3

0.64

0.43

1.80%

1.20%

∞

22 Liquid

cpermittivity (meas.)

A 0.16% N 1 0.64

0.43

0.10%

0.07%

∞

Combined

standard uncertain

ty

222 2

1c

i iui

c u

/ / / / /

10.20%

10.00%

∞

Expanded

uncertainty

(confidence

interval of 95 %)

2e cu u / R K=2

/ / 20.40

% 20.00

% ∞





2. GENERAL INFORMATION

2.1. Environmental conditions

During the measurement the environmental conditions were within the listed ranges:

Normal Temperature: 25°C

Lative Humidity 55 %

Air Pressure 989 hPa

2.2. General Description of EUT

Product Name: GSM Mobile Phone

Trade Mark: CUBOT

Model/Type reference: S308

Listed Model(s):: /

Power supply: DC 3.7V

Adapter information: Model: Model:S0501 Input:100~240V, 50/60Hz, 0.15A Output: DC 5.0V 1A

2G

Operation Band: GSM900, DCS1800

Supported type: GSM/GPRS/EGPRS

Power Class: GSM900:Power Class 4

DCS1800:Power Class 1

Modilation Type: GMSK for GSM/GPRS/EGPRS

GSM Release Version R99

GPRS Multislot Class 12

EGPRS Multislot Class 12

Hardware version: K460-MB-P2_V01

Software version: Android 4.2.2

WCDMA

Operation Band: FDD Band I

Power Class: Power Class 3

Modulation Type: QPSK for WCDMA/HSUPA/HSDPA

WCDMA Release Version: R8

HSDPA Release Version: Release 8

HSUPA Release Version: Release 6

DC-HSUPA Release Version: Not Supported

Hardware version: K460-MB-P2_V01

Software version: Android 4.2.2





WIFI

Supported type: 802.11b/802.11g/802.11n(H20)/802.11n(H40)

Modulation: 802.11b: DSSS 802.11g/802.11n(H20)/802.11n(H40): OFDM

Operation frequency: 802.11b/802.11g/802.11n(H20): 2412MHz~2472MHz 802.11n(H40): 2422MHz~2462MHz

Channel number: 802.11b/802.11g/802.11n(H20): 13

802.11n(H40): 9

Channel separation: 5MHz

Antenna type: Internal Antenna

Antenna gain: 0 dBi

2.3. Description of Test Modes

The EUT battery must be fully charged and checked periodically during the test to ascertain uniform

power the EUT has been tested under typical operating condition and The Transmitter was operated

in the normal operating mode. The TX frequency was fixed which was for the purpose of the

measurements.

2.4. Measurement Instruments List

Test Equipment Manufacturer Type/ModelSerial

Number Calibrated

until Data Acquisition Electronics

DAEx SPEAG DAE4 1315 Nov 24,2014

E-field Probe SPEAG EX3DV4 3842 Jun 06,2014

System Validation Dipole D900V2

SPEAG D900V2 1d129 Dec 12,2014

System Validation Dipole D1750V2

SPEAG D1750V2 1062 Dec 11,2014

System Validation Dipole 1900V2 SPEAG D1900V2 5d150 Dec 11,2014

System Validation Dipole 2450V2 SPEAG D2450V2 884 Dec 10,2014

Dielectric Probe Kit Agilent 85070E US44020288 / Power meter Agilent E4417A GB41292254 Nov 25,2014Power sensor Agilent 8481H MY41095360 Nov 25,2014

Network analyzer Agilent 8753E US37390562 Nov 24,2014Universal Radio Communication

Tester ROHDE & SCHWARZ

CMU200 112012 Oct 22,2014





3. SAR MEASUREMENTS SYSTEM CONFIGURATION

3.1 SAR MEASUREMENT SET-UP

The DASY5 system for performing compliance tests consists of the following items:

A standard high precision 6-axis robot (Stäubli RX family) with controller and software.

An arm extension for accommodating the data acquisition electronics (DAE).

A dosimetric probe, i.e. an isotropic E-field probe optimized and calibrated for usage in tissue

simulating liquid. The probe is equipped with an optical surface detector system.

A data acquisition electronic (DAE) which performs the signal amplification, signal multiplexing, AD-

conversion, offset measurements, mechanical surface detection, collision detection, etc. The unit is

battery powered with standard or rechargeable batteries. The signal is optically transmitted to the

EOC.

A unit to operate the optical surface detector which is connected to the EOC.

The Electro-Optical Coupler (EOC) performs the conversion from the optical into a digital electric

signal of the DAE. The EOC is connected to the DASY5 measurement server.

The DASY5 measurement server, which performs all real-time data evaluation for field measurements

and surface detection, controls robot movements and handles safety operation. A computer operating

Windows 2003. DASY5 software and SEMCAD data evaluation software.

Remote control with teach panel and additional circuitry for robot safety such as warning lamps, etc.

The generic twin phantom enabling the testing of left-hand and right-hand usage.

The device holder for handheld Mobile Phones.

Tissue simulating liquid mixed according to the given recipes.

System validation dipoles allowing to validate the proper functioning of the system.





3.2 DASY5 E-FIELD PROBE SYSTEM

The SAR measurements were conducted with the dosimetric probe ES3DV3 (manufactured by

SPEAG), designed in the classical triangular configuration and optimized for dosimetric evaluation.

Probe Specification:

Construction Symmetrical design with triangular core

Interleaved sensors

Built-in shielding against static charges

PEEK enclosure material (resistant to organic solvents, e.g., DGBE)

Calibration ISO/IEC 17025 calibration service available.

Frequency 10 MHz to 4 GHz;

Linearity: ± 0.2 dB (30 MHz to 4 GHz)

Directivity ± 0.2 dB in HSL (rotation around probe axis)

± 0.3 dB in tissue material (rotation normal to probe

axis)

Dynamic Range 5 µW/g to > 100 mW/g;

Linearity: ± 0.2 dB

Dimensions Overall length: 337 mm (Tip: 20 mm)

Tip diameter: 3.9 mm (Body: 12 mm)

Distance from probe tip to dipole centers: 2.0 mm

Application General dosimetry up to 4 GHz

Dosimetry in strong gradient fields

Compliance tests of Mobile Phones

Compatibility DASY3, DASY4, DASY52 SAR and higher,

EASY4/MRI

Isotropic E-Field Probe:

The isotropic E-Field probe has been fully calibrated and assessed for isotropicity, and boundary effect

within a controlled environment. Depending on the frequency for which the probe is calibrated the

method utilized for calibration will change.

The E-Field probe utilizes a triangular sensor arrangement as detailed in the diagram below:





3.3 PHANTOMS

The phantom used for all tests i.e. for both system

checks and device testing, was the twin-headed "SAM

Phantom", manufactured by SPEAG. The SAM twin

phantom is a fibreglass shell phantom with 2mm shell

thickness (except the ear region, where shell thickness

increases to 6mm).

System checking was performed using the flat section,

whilst Head SAR tests used the left and right head

profile sections. Body SAR testing also used the flat

section between the head profiles.

SAM Twin Phantom

3.4 DEVICE HOLDER

The device was placed in the device holder

(illustrated below) that is supplied by SPEAG as an

integral part of the DASY system.

The DASY device holder is designed to cope with the

different positions given in the standard. It has two

scales for device rotation (with respect to the body

axis) and device inclination (with respect to the line

between the ear reference points). The rotation

centers for both scales is the ear reference point

(ERP). Thus the device needs no repositioning when

changing the angles.

Device holder supplied by SPEAG

3.5 SCANNING PROCEDURE

The DASY5 installation includes predefined files with recommended procedures for measurements

and validation. They are read-only document files and destined as fully defined but unmeasured masks.

All test positions (head or body-worn) are tested with the same configuration of test steps differing only

in the grid definition for the different test positions.

The “reference” and “drift” measurements are located at the beginning and end of the batch process.

They measure the field drift at one single point in the liquid over the complete procedure. The indicated

drift is mainly the variation of the DUT’s output power and should vary max. ± 5 %.

The “surface check” measurement tests the optical surface detection system of the DASY5 system by

repeatedly detecting the surface with the optical and mechanical surface detector and comparing the

results. The output gives the detecting heights of both systems, the difference between the two

systems and the standard deviation of the detection repeatability. Air bubbles or refraction in the liquid

due to separation of the sugar-water mixture gives poor repeatability (above ± 0.1mm). To prevent

wrong results tests are only executed when the liquid is free of air bubbles. The difference between the

optical surface detection and the actual surface depends on the probe and is specified with each probe

(It does not depend on the surface reflectivity or the probe angle to the surface within ± 30°.)





Area Scan

The Area Scan is used as a fast scan in two dimensions to find the area of high field values before

running a detailed measurement around the hot spot.Before starting the area scan a grid spacing of 15

mm x 15 mm is set. During the scan the distance of the probe to the phantom remains unchanged.

After finishing area scan, the field maxima within a range of 2 dB will be ascertained.

Zoom Scan

Zoom Scans are used to estimate the peak spatial SAR values within a cubic averaging volume

containing 1 g and 10 g of simulated tissue. The default Zoom Scan is done by 7x7x7 points within a

cube whose base is centered around the maxima found in the preceding area scan.

Spatial Peak Detection

The procedure for spatial peak SAR evaluation has been implemented and can determine values of

masses of 1g and 10g, as well as for user-specific masses.The DASY5 system allows evaluations that

combine measured data and robot positions, such as: • maximum search • extrapolation • boundary

correction • peak search for averaged SAR During a maximum search, global and local maxima

searches are automatically performed in 2-D after each Area Scan measurement with at least 6

measurement points. It is based on the evaluation of the local SAR gradient calculated by the

Quadratic Shepard’s method. The algorithm will find the global maximum and all local maxima within -2

dB of the global maxima for all SAR distributions.

Extrapolation routines are used to obtain SAR values between the lowest measurement points and the

inner phantom surface. The extrapolation distance is determined by the surface detection distance and

the probe sensor offset. Several measurements at different distances are necessary for the

extrapolation. Extrapolation routines require at least 10 measurement points in 3-D space. They are

used in the Zoom Scan to obtain SAR values between the lowest measurement points and the inner

phantom surface. The routine uses the modified Quadratic Shepard’s method for extrapolation. For a

grid using 7x7x7 measurement points with 5mm resolution amounting to 343 measurement points, the

uncertainty of the extrapolation routines is less than 1% for 1g and 10g cubes.

A Z-axis scan measures the total SAR value at the x-and y-position of the maximum SAR value found

during the cube 7x7x7 scan. The probe is moved away in z-direction from the bottom of the SAM

phantom in 5mm steps.

3.6 DATA STORAGE AND EVALUATION

Data Storage

The DASY5 software stores the acquired data from the data acquisition electronics as raw data (in

microvolt readings from the probe sensors), together with all necessary software parameters for the

data evaluation (probe calibration data, liquid parameters and device frequency and modulation data)

in measurement files with the extension “.DA4”. The software evaluates the desired unit and format for

output each time the data is visualized or exported. This allows verification of the complete software

setup even after the measurement and allows correction of incorrect parameter settings. For example,

if a measurement has been performed with a wrong crest factor parameter in the device setup, the

parameter can be corrected afterwards and the data can be re-evaluated.

The measured data can be visualized or exported in different units or formats, depending on the

selected probe type ([V/m], [A/m], [°C], [mW/g], [mW/cm²], [dBrel], etc.). Some of these units are not

available in certain situations or show meaningless results, e.g., a SAR output in a lossless media will

always be zero. Raw data can also be exported to perform the evaluation with other software

packages.





Data Evaluation The SEMCAD software automatically executes the following procedures to calculate the field units

from the microvolt readings at the probe connector. The parameters used in the evaluation are stored

in the configuration modules of the software:

Probe parameters: - Sensitivity Normi, ai0, ai1, ai2

- Conversion factor ConvFi

- Diode compression point Dcpi

Device parameters: - Frequency f

- Crest factor cf

Media parameters: - Conductivity σ

- Density ρ

These parameters must be set correctly in the software. They can be found in the component

documents or they can be imported into the software from the configuration files issued for the DASY5

components. In the direct measuring mode of the multimeter option, the parameters of the actual

system setup are used. In the scan visualization and export modes, the parameters stored in the

corresponding document files are used.

The first step of the evaluation is a linearization of the filtered input signal to account for the

compression characteristics of the detector diode. The compensation depends on the input signal, the

diode type and the DC-transmission factor from the diode to the evaluation electronics. If the exciting

field is pulsed, the crest factor of the signal must be known to correctly compensate for peak power.

The formula for each channel can be given as:

With Vi = compensated signal of channel i ( i = x, y, z ) Ui = input signal of channel i ( i = x, y, z ) cf = crest factor of exciting field (DASY parameter) dcpi = diode compression point (DASY parameter)

From the compensated input signals the primary field data for each channel can be evaluated:

With Vi = compensated signal of channel i (i = x, y, z)

Normi = sensor sensitivity of channel i (i = x, y, z) [mV/(V/m)2] for E-field Probes

ConvF = sensitivity enhancement in solution aij = sensor sensitivity factors for H-field probes f = carrier frequency [GHz] Ei = electric field strength of channel i in V/m Hi = magnetic field strength of channel i in A/m





The RSS value of the field components gives the total field strength (Hermitian magnitude):

The primary field data are used to calculate the derived field units.

with SAR = local specific absorption rate in mW/g

Etot = total field strength in V/m σ = conductivity in [mho/m] or [Siemens/m] ρ = equivalent tissue density in g/cm3

Note that the density is normally set to 1 (or 1.06), to account for actual brain density rather than the density of the simulation liquid.

3.7 POSITION OF THE WIRELESS DEVICE IN RELATION TO THE PHANTOM

General considerations

This standard specifies two handset test positions against the head phantom – the “cheek” position

and the “tilt” position.

Wt : Width of the handset at the level of the acoustic Wb: Width of the bottom of the handset A: Midpoint of the width wt of the handset at the level of the acoustic output B: Midpoint of the width wb of the bottom of the handset

Picture1 Left: Typical “fixed” case handset Picture1 Right: Typical “clam-shell” case handset





Picture 2 Cheek position of the wireless device on the left side of SAM

Picture 3 Tilt position of the wireless device on the left side of SAM

Body-worn device

A typical example of a body-worn device is a mobile phone, wireless enabled PDA or other battery

operated wireless device with the ability to transmit while mounted on a person’s body using a carry

accessory approved by the wireless device manufacturer.

Picture 4 Test positions for body-worn devices

Devices with hinged or swivel antenna(s) For devices that employ one or more external antennas with variable positions (e.g. antenna extended,

retracted, rotated), these shall be positioned in accordance with the user instructions provided by the

manufacturer. For a device with only one antenna, if no intended antenna position is specified, tests

shall be performed if applicable in both the horizontal and vertical positions relative to the phantom,

and with the antenna oriented away from the body of the DUT (Figure 5) and/or with the antenna

extended and retracted such as to obtain the highest exposure condition. For antennas that may be

rotated through one or two planes, an evaluation should be made and documented in the





measurement report to the highest exposure scenario and only that position(s) need(s) to be tested.

For devices with multiple detachable antennas see provisions of 6.2.2.

Figure 5– Device with swivel antenna (example of desktop device)

Body-supported device A typical example of a body supported device is a wireless enabled laptop device that among other

orientations may be supported on the thighs of a sitting user. To represent this orientation, the device

shall be positioned with its base against the flat phantom. Other orientations may be specified by the

manufacturer in the user instructions. If the intended use is not specified, the device shall be tested

directly against the flat phantom in all usable orientations.

The screen portion of the device shall be in an open position at a 90° angle as seen in Figure 6a (left

side), or at an operating angle specified for intended use by the manufacturer in the operating

instructions. Where a body supported device has an integral screen required for normal operation,

then the screen-side will not need to be tested if the antenna(s) integrated in it ordinarily remain(s) 200

mm from the body. Where a screen mounted antenna is present, the measurement shall be performed

with the screen against the flat phantom as shown in Figure 6a) (right side), if operating the screen

against the body is consistent with the intended use.

Other devices that fall into this category include tablet type portable computers and credit card

transaction authorization terminals, point-of-sale and/or inventory terminals. Where these devices may

be torso or limb-supported, the same principles for body-supported devices are applied.

The example in Figure 6b) shows a tablet form factor portable computer for which SAR should be

separately assessed with

c). each surface and

d). the separation distances

positioned against the flat phantom that correspond to the intended use as specified by the

manufacturer. If the intended use is not specified in the user instructions, the device shall be tested

directly against the flat phantom in all usable orientations.

Some body-supported devices may allow testing with an external power supply (e.g. a.c. adapter)

supplemental to the battery, but it shall be verified and documented in the measurement report that

SAR is still conservative.

For devices that employ an external antenna with variable positions (e.g. swivel antenna), see

6.1.4.5 and Figure 5.





a) Portable computer with external antenna plug-in-radio-card (left side) or with internal antenna

located in screen section (right side)

b) Tablet form factor portable computer

c) Wireless credit card transaction authorisation terminal

Figure 6 – Test positions for body supported devices





Desktop device A typical example of a desktop device is a wireless enabled desktop computer placed on a table or

desk when used.

The DUT shall be positioned at the distance and in the orientation to the phantom that corresponds to

the intended use as specified by the manufacturer in the user instructions. For devices that employ an

external antenna with variable positions, tests shall be performed for all antenna positions specified.

Picture 14 shows positions for desktop device SAR tests. If the intended use is not specified, the

device shall be tested directly against the flat phantom.

Picture 7 Test positions for desktop devices

Front-of-face device

A typical example of a front-of-face device is a two-way radio that is held at a distance from the face of

the user when transmitting. In these cases the device under test shall be positioned at the distance to

the phantom surface that corresponds to the intended use as specified by the manufacturer in the user

instructions (Figure 8a). If the intended use is not specified, a separation distance of 25 mm between

the phantom surface and the device shall be used.

a) Two-way radios





b) Still cameras and video cameras

Figure 8 – Test positions for front-of-face devices

Other devices that fall into this category include wireless-enabled still cameras and video cameras that

can send data to a network or other device (Figure 8b). In the case of a device whose intended use

requires a separation distance from the user (e.g., device with a viewing screen), this shall be

positioned at the distance to the phantom surface that corresponds to the intended use as specified by

the manufacturer in the user instructions (Figure 8b, left side). If the intended use is not specified, a

separation distance of 25 mm between the phantom surface and the device shall be used.

For a device whose intended use requires the user’s face to be in contact with the device (e.g., device

with an optical viewfinder), this shall be placed directly against the phantom (Figure 8b, right side). Hand-held usage of the device, not at the head or torso

Additional studies remain needed for devising a representative method for evaluating SAR in the hand

of hand-held devices. Future versions of this standard are intended to contain a test method based on

scientific data and rationale. Annex J presents the currently available test procedure.

Limb-worn device

A limb-worn device is a unit whose intended use includes being strapped to the arm or leg of the user

while transmitting (except in idle mode). It is similar to a body-worn device. Therefore, the test

positions of 6.1.4.4 also apply. The strap shall be opened so that it is divided into two parts as shown

in Figure 9. The device shall be positioned directly against the phantom surface with the strap

straightened as much as possible and the back of the device towards the phantom.

If the strap cannot normally be opened to allow placing in direct contact with the phantom surface, it

may be necessary to break the strap of the device but ensuring to not damage the antenna.





Figure 9 – Test position for limb-worn devices

Clothing-integrated device

A typical example of a clothing-integrated device is a wireless device (mobile phone) integrated into a

jacket to provide voice communications through an embedded speaker and microphone. This category

also includes headgear with integrated wireless devices.

All wireless or RF transmitting components shall be placed in the orientation and at the separation

distance to the phantom surface that correspond to intended use of the device when it is integrated

into the clothing (Figure 10).

Figure 10– Test position for clothing-integrated wireless devices

3.8 DIELECTRIC PERFORMANCE

Dielectric Performance of Head Tissue Simulating Liquid Measurement is made at temperature 22.0℃ and relative humidity 55%. Liquid temperature during the test: 22.0℃ Measurement Date: 900 MHz July 03th, 2014;1800 MHz July 03th , 2014;1900 MHz July 03th, 2014;2450 MHz July 03th, 2014

/ Frequency Frequency ε Conductivity σ (S/m)

Measurement value

900 MHz 41.50 0.97 1800 MHz 40.00 1.40 1900 MHz 40.00 1.40 2450 MHz 39.20 1.80





3.9 SYSTEM CHECK

The purpose of the system check is to verify that the system operates within its specifications at the

device test frequency. The system check is simple check of repeatability to make sure that the system

works correctly at the time of the compliance test;

System check results have to be equal or near the values determined during dipole calibration with the

relevant liquids and test system (±10 %).

System check is performed regularly on all frequency bands where tests are performed with the

DASY5 system.

The output power on dipole port must be calibrated to 24 dBm (250mW) before dipole is connected.

Photo of Dipole Setup





System Validation of Head Measurement is made at temperature 22.0 ℃ and relative humidity 55%. Measurement Date: 900 MHz July 03th, 2014;1800 MHz July 03th , 2014;1900 MHz July 03th, 2014;2450 MHz July 03th, 2014

Verification results

Frequency (MHz)

Target value (W/kg)

Measured value (W/kg)

Deviation

1 g Average

10 g Average

1 g Average

10 g Average

1 g Average

10 g Average

900 2.62 1.69 2.59 1.65 -1.91% -2.96% 1750 9.72 5.21 9.52 4.93 -1.34% -5.56% 1900 9.71 5.08 9.55 4.97 -1.65% -1.97% 2450 13.0 6.05 12.69 5.89 -1.85% -1.98%

3.10 MEASUREMENT PROCEDURES

Tests to be performed

In order to determine the highest value of the peak spatial-average SAR of a handset, all device

positions, configurations and operational modes shall be tested for each frequency band according to

steps 1 to 3 below. A flowchart of the test process is shown in Picture 11

Step 1: The tests described in 11.2 shall be performed at the channel that is closest to the centre of the

transmit frequency band (fc) for:

a) all device positions (cheek and tilt, for both left and right sides of the SAM phantom, as described in

Chapter 8),

b) all configurations for each device position in a), e.g., antenna extended and retracted, and

c) all operational modes, e.g., analogue and digital, for each device position in a) and configuration in

b) in each frequency band.

d) If more than three frequencies need to be tested according to 11.1 (i.e., Nc > 3), then all

frequencies, configurations and modes shall be tested for all of the above test conditions.

Step 2: For the condition providing highest peak spatial-average SAR determined in Step 1, perform all

tests described in 11.2 at all other test frequencies, i.e., lowest and highest frequencies. In addition, for

all other conditions (device position, configuration and operational mode) where the peak

spatial-average SAR value determined in Step 1 is within 3 dB of the applicable SAR limit, it is

recommended that all other test frequencies shall be tested as well.

Step 3: Examine all data to determine the highest value of the peak spatial-average SAR found in

Steps 1 to 2.





Picture 11 Block diagram of the tests to be performed





Picture 12 Block diagram of the tests to be performed





Measurement procedure The following procedure shall be performed for each of the test conditions (see Picture 11) described in

11.1:

a) Measure the local SAR at a test point within 8 mm or less in the normal direction from the inner

surface of the phantom.

b) Measure the two-dimensional SAR distribution within the phantom (area scan procedure). The

boundary of the measurement area shall not be closer than 20 mm from the phantom side walls.

The distance between the measurement points should enable the detection of the location of local

maximum with an accuracy of better than half the linear dimension of the tissue cube after

interpolation. A maximum grip spacing of 20 mm for frequencies below 3 GHz and (60/f [GHz]) mm

for frequencies of 3GHz and greater is recommended. The maximum distance between the

geometrical centre of the probe detectors and the inner surface of the phantom shall be 5 mm for

frequencies below 3 GHz andδIn(2)/2 mm for frequencies of 3 GHz and greater, whereδis the

plane wave skin depth and In(x) is the natural logarithm. The maximum variation of the

sensor-phantom surface shall be ±1 mm for frequencies below 3 GHz and ±0.5 mm for frequencies

of 3 GHz and greater. At all measurement points the angle of the probe with respect to the line

normal to the surface should be less than 5°. If this cannot be achieved for a measurement

distance to the phantom inner surface shorter than the probe diameter, additional measurement

distance to the phantom inner surface shorter than the probe diameter, additional

c) From the scanned SAR distribution, identify the position of the maximum SAR value, in addition

identify the positions of any local maxima with SAR values within 2 dB of the maximum value that

are not within the zoom-scan volume; additional peaks shall be measured only when the primary

peak is within 2 dB of the SAR limit. This is consistent with the 2 dB threshold already stated;

d) Measure the three-dimensional SAR distribution at the local maxima locations identified in step

e) The horizontal grid step shall be (24 / f[GHz] ) mm or less but not more than 8 mm. The minimum

zoom size of 30 mm by 30 mm and 30 mm for frequencies below 3 GHz. For higher frequencies,

the minimum zoom size of 22 mm by 22 mm and 22 mm. The grip step in the vertical direction shall

be ( 8-f[GHz] ) mm or less but not more than 5 mm, if uniform spacing is used. If variable spacing is

used in the vertical direction, the maximum spacing between the two closest measured points to

the phantom shell shall be (12 / f[GHz]) mm or less but not more than 4 mm, and the spacing

between father points shall increase by an incremental factor not exceeding 1.5. When variable

spacing is used, extrapolation routines shall be tested with the same spacing as used in

measurements. The maximum distance between the geometrical centre of the probe detectors and

the inner surface of the phantom shall be 5 mm for frequencies below 3 GHz and δIn(2)/2 mm for

frequencies of 3 GHz and greater, where δis the plane wave skin depth and In(x) is the natural

logarithm. Separate grids shall be centered on each of the local SAR maxima found in step c).

Uncertainties due to field distortion between the media boundary and the dielectric enclosure of the

probe should also be minimized, which is achieved is the distance between the phantom surface

and physical tip of the probe is larger than probe tip diameter. Other methods may utilize correction

procedures for these boundary effects that enable high precision measurements closer than half

the probe diameter. For all measurement points, the angle of the probe with respect to the flat

phantom surface shall be less than 5. If this cannot be achieved an additional uncertainty

evaluation is needed.

f) Use post processing ( e.g. interpolation and extrapolation ) procedures to determine the local SAR

values at the spatial resolution needed for mass averaging.





WCDMA Measurement Procedures for SAR

The following procedures are applicable to WCDMA handsets operating under 3GPP

Release99,Release 5 and Release 6. The default test configuration is to measure SAR with an

established radio link between the DUT and a communication test set using a 12.2kbps RMC

(reference measurement channel) configured in Test Loop Mode 1. SAR is selectively confirmed for

other physical channel configurations (DPCCH & DPDCHn), HSDPA and HSPA (HSUPA/HSDPA)

modes according to output power, exposure conditions and device operating capabilities. Both uplink

and downlink should be configured with the same RMC or AMR, when required. SAR for Release 5

HSDPA and Release 6 HSPA are measured using the applicable FRC (fixed reference channel) and

E-DCH reference channel configurations. Maximum output power is verified

according to applicable versions of 3GPP TS 34.121 and SAR must be measured according to these

maximum output conditions. When Maximum Power Reduction (MPR) is not implemented according to

Cubic Metric (CM) requirements for Release 6 HSPA, the following procedures do not apply. For Release 5 HSDPA Data Devices:

Sub-test c d d（SF） c/ d hs CM/dB 1 2/15 15/15 64 2/15 4/15 0.0 2 12/15 15/15 64 12/15 24/25 1.0 3 15/15 8/15 64 15/8 30/15 1.5 4 15/15 4/15 64 15/4 30/15 1.5

For Release 6 HSUPA Data Devices

Sub-test c d d

(SF) c/ d

hs ec ed ed

(SF)

ed (codes)

CM (dB)

MPR (dB)

AG Index

E-TFCI

1 11/15 15/15 64 11/15 22/15 209/225 1039/225 4 1 1.0 0.0 20 75 2 6/15 15/15 64 6/15 12/15 12/15 12/15 4 1 3.0 2.0 12 67

3 15/15 9/15 64 15/9 30/15 30/15

ed1 :47/15 　

ed2 :47/15

4 2 2.0 1.0 15 92

4 2/15 15/15 64 2/15 4/15 4/15 56/75 4 1 3.0 2.0 17 71 5 15/15 15/15 64 15/15 24/15 30/15 134/15 4 1 1.0 0.0 21 81

Bluetooth & Wi-Fi Measurement Procedures for SAR

Normal network operating configurations are not suitable for measuring the SAR of 802.11 transmitters

in general. Unpredictable fluctuations in network traffic and antenna diversity conditions can introduce

undesirable variations in SAR results. The SAR for these devices should be measured using chipset

based test mode software to ensure that the results are consistent and reliable.

Chipset based test mode software is hardware dependent and generally varies among manufacturers.

The device operating parameters established in a test mode for SAR measurements must be identical

to those programmed in production units, including output power levels, amplifier gain settings and

other RF performance tuning parameters. The test frequencies should correspond to actual channel

frequencies defined for domestic use. SAR for devices with switched diversity should be measured

with only one antenna transmitting at a time during each SAR measurement, according to a fixed

modulation and data rate. The same data pattern should be used for all measurements.

GSM Test Configuration

SAR tests for GSM900 and GSM1800, a communication link is set up with a System Simulator (SS) by

air link. Using CMU200 the power level is set to “5” for GSM900, set to “0” for GSM1800. Since the

GPRS class is 12 for this EUT, it has at most 4 timeslots in uplink and at most 4 timeslots in downlink,

the maximum total timeslots is 5. The EGPRS class is 12 for this EUT, it has at most 4 timeslots in





uplink and at most 4 timeslots in downlink, the maximum total timeslots is 5.

When SAR tests for EGPRS mode is necessary, GMSK modulation should be used to minimize SAR

measurement error due to higher peak-to-average power (PAR) ratios inherent in 8-PSK.

According to specification 3GPP TS 51.010, the maximum power of the GSM can do the power

reduction for the multi-slot. The allowed power reduction in the multi-slot configuration is as following:

Output power of reductions: The allowed power reduction in the multi-slot configuration

Number of timeslots in uplink assignment Permissible nominal reduction of maximum output power (dB)

1 0 2 0 to 3.0 3 1.8 to 4.8 4 3.0 to 6.0

Power Drift

To control the output power stability during the SAR test, DASY5 system calculates the power drift by

measuring the E-field at the same location at the beginning and at the end of the measurement for

each test position. These drift values can be found in Table 2 to Table 6 labeled as: (Power Drift [dB]).

This ensures that the power drift during one measurement is within 5%.





4. TEST CONDITIONS AND RESULTS

4.1. CONDUCTED POWER RESULTS

During the process of testing, the EUT was controlled via Rhode & Schwarz Digital Radio

Communication tester (CMU200) to ensure the maximum power transmission and proper modulation.

This result contains conducted output power for the EUT. In all cases, the measured peak output

power should be greater and within 5% than EMI measurement. The conducted power measurement results for GSM900/DCS1800

GSM900

Conducted Power (dBm)

Channel 980 (880.20MHz)



33.47 33.57 33.58

DCS1800

Conducted Power (dBm) Channel 520 (1710.20MHz)



30.25 30.47 30.45

The conducted power measurement results for GPRS/EGPRS

GPRS 900

(GMSK)

Measured Power (dBm) Calculation

(dB)

Averaged Power (dBm) 880.2 MHz

879.6 MHz

914.8 MHz

880.2 MHz

879.6 MHz

914.8 MHz

1 Txslot 30.25 30.58 30.47 -9.03 21.22 21.55 21.44 2 Txslot 30.26 30.68 30.57 -6.02 24.24 24.66 24.55 3 Txslot 30.47 30.75 30.59 -4.26 26.21 26.49 26.33 4 Txslot 31.33 31.42 31.51 -3.01 28.32 28.41 28.50 EGPRS

900 (GMSK)


(dB)


879.6 MHz

914.8 MHz

880.2 MHz

879.6 MHz

914.8 MHz

1 Txslot 30.14 30.25 30.30 -9.03 21.11 21.22 21.27 2 Txslot 30.35 30.35 30.33 -6.02 24.33 24.33 24.31 3 Txslot 30.58 30.53 30.47 -4.26 26.32 26.27 26.21 4 Txslot 30.62 30.60 30.58 -3.01 27.61 27.59 27.57

GPRS 1800 (GMSK)


(dB)


1747.8 MHz

1784.8 MHz

1710.2 MHz

1747.8 MHz

1784.8 MHz


EGPRS 1800 (GMSK)


(dB)


1747.8 MHz

1784.8 MHz

1710.2 MHz

1747.8 MHz

1784.8 MHz


Note: 1. Division Factors

To average the power, the division factor is as follows:

1TX-slot = 1 transmit time slot out of 8 time slots=> conducted power divided by (8/1) => -9.03dB

2TX-slots = 2 transmit time slots out of 8 time slots=> conducted power divided by (8/2) => -6.02dB







2. According to the conducted power as above, the body measurements are performed with 4Txslots for

900MHz and 4 Txslots for 1800MHz at GPRS.

The conducted power measurement results for WCDMA

Item band

FDD Band I result (dBm)

Test Channel

ARFCN 9613 9750 9887

5.2(WCDMA) \ 22.41 22.32 22.44

5.2AA (HSDPA)

2/15 22.45 22.56 22.62

12/15 22.39 22.66 22.51

15/8 22.38 22.47 22.48

15/4 21.85 22.58 22.51

5.2B (HSUPA)

11/15 22.71 22.56 22.40

6/15 22.81 22.35 22.15

15/9 22.97 22.23 22.35

2/15 22.92 22.40 22.57

15/15 22.33 22.23 22.46

The conducted power measurement results for WLAN

Mode Channel Frequency

(MHz) Conducted Output Power Test Rate

Data (dBm) (mW)

802.11b

1 2412 16.41 43.75 1 Mbps

7 2442 16.44 44.06 1 Mbps

13 2472 17.23 52.84 1 Mbps

802.11g

1 2412 14.24 26.55 6 Mbps

7 2442 14.27 26.73 6 Mbps

13 2472 14.36 27.29 6 Mbps

802.11n(20MHz)

1 2412 12.73 18.75 6.5 Mbps

7 2442 13.32 21.48 6.5 Mbps

13 2472 12.90 19.50 6.5 Mbps

802.11n(40MHz)

3 2422 10.42 11.02 13.5 Mbps

7 2442 10.12 10.28 13.5 Mbps

11 2462 10.04 10.09 13.5 Mbps

Note: 1.The output power was test all data rate and recorded worst case at recorded data rate.





The conducted power measurement results for Bluetooth

Mode Channel Frequency

(MHz) Conducted Output Power

(dBm) (mW)

GFSK-BLE

00 2402 -2.99 1.37 19 2440 -4.15 1.36 39 2480 -3.86 1.38

GFSK

00 2402 3.65 3.62

39 2441 4.22 3.94 78 2480 3.29 3.78

8DPSK

00 2402 2.42 3.03

39 2441 3.09 3.35 78 2480 2.65 3.26

π/4DQPSK

00 2402 2.44 2.97

39 2441 1.81 3.35 78 2480 1.92 3.19

Note: 1. because the output power(eirp) of Bluetooth of the mobile phone is less than 20mW(13dBm), so standalone SAR are exempt according EN62479.





4.2. TEST REDUCTION PROCEDURE

Maximum power level

The maximum power level, Pmax,m, that can be transmitted by a device before the SAR averaged over a

mass, m, exceeds a given limit, SARlim, can be defined. Any device transmitting at power levels below

Pmax,m can then be excluded from SAR testing. The lowest possible value for Pmax,m is: Pmax,m =

SARlim* m.　

When working alone, the averages transmit power of BT module should be less than 20mW. According

to the test results, when working alone, the testing of BT is not necessary.

Simultaneous multi-band transmission

Simultaneous multi-band transmission means that the device can transmit multiple transmission modes at

the same time. The time-averaged output power of a secondary transmitter may be much lower than that of

the primary transmitter. In some cases, the secondary transmitter can be excluded from SAR testing when

used alone. However, when the primary and secondary transmitters are used together, the SAR limit may

still be exceeded. A means of determining the threshold power for the secondary transmitter that allows it to

be excluded from SAR testing is needed.

One way of determining the threshold power level available to the secondary transmitter (Pavailable) is to

calculate it from the measured peak spatial-average SAR of the primary transmitter (SAR1) according to the

equation:Pavailable = Pth,m (SARlim - SAR1) / SARlim

where Pth,m is the threshold exclusion power level taken from Annex B of IEC 62479 for the frequency of the

secondary transmitter at the separation distance used in the testing. If the output power of the secondary

transmitter is less than Pavailable, SAR measurement for the secondary transmitter is not necessary.

For the DUT, the WLAN and BT modules sharing a single antenna, and so these two modules can’t transmit

signal simultaneously. WCDMA and GSM modules sharing a single antenna, so these two modules can’t

transmit signal simultaneously.

So we can get following combination that can transmit signal simultaneously.

GSM and BT;

GSM and WLAN;

WCDMA2100 and BT;

WCDMA2100 and WLAN.

According to the description of Annex B of IEC 62479, the approximate Pavailable = 90 (2 – 0.580) /

2=63.90mW. Both WLAN and BT average conducted power are less than 63.90mW. So no simultaneous

multi-band transmission test is required.

Antennas Wireless Interface WWAN Antenna GSM900/DCS1800/WCDMA Band I BT and WLAN Antenna WLAN 2.4GHz/BLuetooth





4.3. SAR Measurement Results

SAR Values for GSM900 Band- Head

Frequency Mode/Band Side

Test Position

SAR(10g) (W/kg)

Power Drift(dB)

Ref. Plot # MHz Channel

897.60 62 GSM900 Left Touch 0.330 -0.15 1

897.60 62 GSM900 Left Tilt 0.315 -0.10 --

897.60 62 GSM900 Right Touch 0.322 -0.09 --

897.60 62 GSM900 Right Tilt 0.305 -0.10 --

880.20 120 GSM900 Left Touch 0.318 -0.12 --

914.80 980 GSM900 Left Touch 0.320 -0.11 --

SAR Values for GSM900 Band-Body

Frequency Service/Headset

Test Position Spacing(mm)

SAR(10G) (W/kg)

Power Drift(dB)

Ref. Plot

# MHz Channel

897.60 62 GPRS 4TS Rear 10 0.557 -0.05 2

897.60 62 GPRS 4TS Front 10 0.545 -0.15 --

880.20 120 GPRS 4TS Rear 10 0.526 -0.12 --

914.80 980 GPRS 4TS Rear 10 0.510 -0.10 --

897.60 62 EGPRS 4TS Rear 10 0.511 -0.11 --

SAR Values for DCS1800 Band-Head


Test Position

SAR(10g) (W/kg)

Power Drift(dB)

Ref. Plot # MHz Channel

1747.80 698 DCS1800 Left Touch 0.201 -0.15 --

1747.80 698 DCS1800 Left Tilt 0.220 -0.14 3

1747.80 698 DCS1800 Right Touch 0.165 -0.10 --

1747.80 698 DCS1800 Right Tilt 0.168 -0.15 --

1710.20 520 DCS1800 Left Tilt 0.165 -0.13 --

1784.80 880 DCS1800 Left Tilt 0.136 -0.10 --

SAR Values for DCS1800 Band-Body

Frequency Service/Headset


SAR(10G) (W/kg)

Power Drift(dB)

Ref. Plot

# MHz Channel

1747.80 698 GPRS 4TS Rear 10 0.369 -0.05 4

1747.80 698 GPRS 4TS Front 10 0.336 -0.11 --

1710.20 520 GPRS 4TS Rear 10 0.341 -0.09 --

1784.80 880 GPRS 4TS Rear 10 0.320 -0.06 --

1747.80 698 EGPRS 4TS Rear 10 0.318 -0.05 --





SAR Values for WCDMABand I -Head

Frequency Service/Headset Side

Test Position

SAR(10g) (W/kg)

Power Drift(dB)

Ref. Plot# MHz Channel

1950.00 9750 RMC Left Touch 0.142 -0.15 5

1950.00 9750 RMC Left Tilt 0.132 -0.10 --

1950.00 9750 RMC Right Touch 0.133 -0.14 --

1950.00 9750 RMC Right Tilt 0.120 -0.10 --

1977.60 9887 RMC Left Touch 0.111 -0.10 --

1922.40 9613 RMC Left Touch 0.132 -0.14 --

SAR Values for WCDMA Band I -Body

Frequency Mode/Band


SAR(10G) (W/kg)

Power Drift(dB)


1950.00 9750 RMC Rear 10 0.232 -0.11 6

1950.00 9750 RMC Front 10 0.201 -0.09 --

1977.60 9887 RMC Rear 10 0.215 -0.10 --

1922.40 9613 RMC Rear 10 0.216 -0.15 --

SAR Values for WLAN2450 Band -Head


Test Position

SAR(10g) (W/kg)

Power Drift(dB)


2442 7 802.11b Left Touch 0.270 -0.10 7

2442 7 802.11b Left Tilt 0.262 -0.11 --

2442 7 802.11b Right Touch 0.242 0.13 --

2442 7 802.11b Right Tilt 0.232 -0.05 --

2412 1 802.11b Left Touch 0.257 -0.18 --

2472 13 802.11b Left Touch 0.269 -0.10 --

SAR Values for WLAN2450 Band -Body

Frequency Mode/Band


SAR(10G) (W/kg)

Power Drift(dB)


2442 7 802.11b Rear 10 0.432 -0.18 8

2442 7 802.11b Front 10 0.410 -0.15 --

2412 1 802.11b Rear 10 0.420 0.16 --

2472 13 802.11b Rear 10 0.419 0.11 --





4.4. SYSTEM CHECK RESULTS

System Performance Check at 900 MHz DUT: Dipole 900 MHz; Type: D900V2; Serial: D900V2 Date/Time: 07/03/2014 AM Communication System: CW; Frequency: 900 MHz;Duty Cycle: 1:1 Medium parameters used (interpolated): f = 900 MHz; σ = 0.95 S/m; εr = 42.16; ρ = 1000 kg/m3 Phantom section: Flat Section DASY5 Configuration: Probe: ES3DV3 - SN3842; ConvF(8.78, 8.78, 8.78); Calibrated: 06/06/2014; Sensor-Surface: 3mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.5 (6469) Area Scan (61x91x1): Measurement grid: dx=15.00 mm, dy=15.00 mm Maximum value of SAR (interpolated) = 3.48 W/kg Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 62.1 V/m; Power Drift = -0.08 dB Peak SAR (extrapolated) = 4.06 mW/g SAR(1 g) = 2.59 mW/g; SAR(10 g) = 1.65 mW/g Maximum value of SAR (measured) = 3.16 W/kg

0 dB = 3.16mW/g

System Performance Check 900MHz 250mW





System Performance Check at 1750 MHz DUT: Dipole 1750 MHz; Type: D1750V2; Serial: D1750V2 Date/Time: 07/03/2014 PM Communication System: CW; Frequency: 1750 MHz;Duty Cycle: 1:1 Medium parameters used (interpolated): f = 1750 MHz; σ = 1.42 S/m; εr = 39.86; ρ = 1000 kg/m3 Phantom section: Flat Section DASY5 Configuration: Probe: ES3DV3 - SN3842; ConvF(7.68, 7.68, 7.68); Calibrated: 06/06/2013; Sensor-Surface: 3mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (1); SEMCAD X Version 14.6.5 (6469) Area Scan (61x91x1): Measurement grid: dx=15.00 mm, dy=15.00 mm Maximum value of SAR (interpolated) = 12.6 W/kg Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 99.561 V/m; Power Drift = -0.04 dB Peak SAR (extrapolated) = 16.828 mW/g SAR(1 g) =9.52 mW/g; SAR(10 g) = 4.93 mW/g Maximum value of SAR (measured) = 13.0 W/kg

0 dB = 13.0mW/g=22.279 dB mW/g






System Performance Check at 1900 MHz DUT: Dipole 1900 MHz; Type: D1900V2; Serial: D1900V2 Date/Time: 07/03/2014 PM Communication System: CW; Frequency: 1900 MHz;Duty Cycle: 1:1 Medium parameters used (interpolated): f = 1900 MHz; σ = 1.45 S/m; εr = 40.15; ρ = 1000 kg/m3 Phantom section: Flat Section DASY5 Configuration: Probe: ES3DV3 - SN3842; ConvF(7.55, 7.55, 7.55); Calibrated: 06/06/2013; Sensor-Surface: 3mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (1); SEMCAD X Version 14.6.5 (6469) Area Scan (61x91x1): Measurement grid: dx=15.00 mm, dy=15.00 mm Maximum value of SAR (interpolated) = 2.01 W/kg Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 35.069 V/m; Power Drift = 0.02 dB Peak SAR (extrapolated) = 2.872 mW/g SAR(1 g) = 9.55 mW/g; SAR(10 g) = 4.97 mW/g Maximum value of SAR (measured) = 1.87 W/kg

0 dB=2.01 mW/g=6.05dB mW/g






System Performance Check at 2450 MHz

DUT: Dipole 2450 MHz; Type: D2450V2; Serial: 884 Date/Time: 07/03/2014 AM Communication System: CW; Frequency: 2450 MHz;Duty Cycle: 1:1 Medium parameters used (interpolated): f = 2450 MHz; σ = 1.76 S/m; εr = 38.67; ρ = 1000 kg/m3 Phantom section: Flat Section DASY5 Configuration: Probe: ES3DV3 - SN3842; ConvF(7.26, 7.26, 7.26); Calibrated: 06/06/2013; Sensor-Surface: 3mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.5 (6469) Area Scan (61x91x1): Measurement grid: dx=15.00 mm, dy=15.00 mm Maximum value of SAR (interpolated) = 12.97W/kg Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 99.872 V/m; Power Drift = 0.02 dB Peak SAR (extrapolated) = 17.651 mW/g SAR(1 g) = 12.69 mW/g; SAR(10 g) = 5.89 mW/g Maximum value of SAR (measured) = 13.563 W/kg

0 dB = 13.563mW/g=22.647dB mW/g






4.5. SAR TEST GRAPH RESULTS

Left Head Cheek (GSM900 Middle Channel) Communication System: Customer System; Frequency: 897.6 MHz;Duty Cycle:1:8.30042 Medium parameters used (interpolated): f = 897.6 MHz; σ = 0.96 S/m; εr = 41.10; ρ = 1000 kg/m3

Phantom section: Left Head Section: Probe: ES3DV3 - SN3842; ConvF(8.78, 8.78, 8.78); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (61x81x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.647 W/kg Zoom Scan (5x5x5)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 7.541 V/m; Power Drift = -0.15 dB Peak SAR (extrapolated) = 0.793 W/kg SAR(1 g) = 0.586 W/kg; SAR(10 g) = 0.332 W/kg Maximum value of SAR (measured) = 0.666 W/kg

0dB = 0.666 W/kg = -1.76 dBW/kg

Plot 1: Left Head Cheek (GSM900 Middle Channel)





Body- worn Rear Side (GSM900 GPRS 4TS Middle Channel) Communication System: Customer System; Frequency: 897.6 MHz;Duty Cycle:1:2 Medium parameters used (interpolated): f = 897.6 MHz; σ = 0.96 S/m; εr = 41.10; ρ = 1000 kg/m3

Phantom section : Body- worn Probe: ES3DV3 - SN3842; ConvF(9.16, 9.16, 9.16); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (61x81x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.927 W/kg Zoom Scan (5x5x5)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 9.685 V/m; Power Drift = -0.05 dB Peak SAR (extrapolated) = 1.07 W/kg SAR(1 g) = 0.789 W/kg; SAR(10 g) = 0.557 W/kg Maximum value of SAR (measured) = 1.20 W/kg

0dB = 1.12 W/kg = 1.06 dBW/kg

Plot 2: Body- worn Rear Side (GSM900 GPRS 4TS Middle Channel)





Left Head Tilt (DCS1800 Middle Channel) Communication System: Customer System; Frequency: 1747.80 MHz;Duty Cycle: 1:8.30042 Medium parameters used (interpolated): f = 1747.80 MHz; σ = 1.38 S/m; εr = 40.17; ρ = 1000 kg/m3 Phantom section: Left Head Section DASY5 Configuration: Probe: ES3DV3 - SN3842; ConvF(7.68, 7.68, 7.68); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (41x81x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) =0.282 W/kg Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 6.856 V/m; Power Drift = -0.14 dB Peak SAR (extrapolated) = 0.230 W/kg SAR(1 g) = 0.295 W/kg; SAR(10 g) = 0.220 W/kg Maximum value of SAR (measured) = 0.227 W/kg

0 dB = 0.227 W/kg = -6.34 dB W/kg

Plot 3: Left Head Tilt (DCS1800 Middle Channel)





Body- worn Rear Side (DCS1800 GPRS 4TS Middle Channel) Communication System: Customer System; Frequency: 1747.80 MHz;Duty Cycle: 1:2 Medium parameters used (interpolated): f = 1747.80 MHz; σ = 1.38 S/m; εr = 40.17; ρ = 1000 kg/m3 Phantom section: Body- worn Back Section DASY5 Configuration: Probe: ES3DV3 - SN3842; ConvF(7.78, 7.78, 7.78); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (41x81x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.835 W/kg Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 8.958 V/m; Power Drift = 0.05 dB Peak SAR (extrapolated) = 1.15 W/kg SAR(1 g) = 0.670 W/kg; SAR(10 g) = 0.368 W/kg Maximum value of SAR (measured) = 0.979 W/kg

0 dB = 0.979 W/kg = -1.05 dB W/kg

Plot 4: Body- worn Rear Side (DCS1800 GPRS 4TS Middle Channel)





Left Head Cheek (WCDMA Band I Middle Channel) Communication System: Customer System; Frequency: 1950.0 MHz;Duty Cycle:1:1 Medium parameters used (interpolated): f =1950.0 MHz; σ = 1.44 S/m; εr = 40.75; ρ = 1000 kg/m3 Phantom section: Left Head Section: Probe: ES3DV3 - SN3842; ConvF(7.55, 7.55, 7.55); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (91x51x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.140 W/kg Zoom Scan (6x6x5)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 4.654 V/m; Power Drift = -0.15 dB Peak SAR (extrapolated) = 0.187 W/kg SAR(1 g) = 0.180 W/kg; SAR(10 g) = 0.142 W/kg Maximum value of SAR (measured) = 0.180 W/kg

0 dB = 0.180 W/kg = -7.24 dB W/kg

Plot 5: Left Head Cheek (WCDMA Band I Middle Channel)





Body- worn Rear Side (WCDMA Band I Middle Channel) Communication System: Customer System; Frequency: 1950.0 MHz;Duty Cycle:1:1 Medium parameters used (interpolated): f =1950.0 MHz; σ = 1.44 S/m; εr = 40.75; ρ = 1000 kg/m3 Phantom section: Body- worn Back Section Probe: ES3DV3 - SN3842; ConvF(7.43, 7.43, 7.43); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (51x91x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.585 W/kg Zoom Scan (6x6x5)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 8.895 V/m; Power Drift = -0.11 dB Peak SAR (extrapolated) = 0.817 W/kg SAR(1 g) = 0.432 W/kg; SAR(10 g) = 0.232 W/kg Maximum value of SAR (measured) = 0.556 W/kg

0 dB = 0.556 W/kg = -2.78 dB W/kg

Plot 6: Body- worn Rear Side (WCDMA Band I Middle Channel)





Left Head Cheek (WLAN2450 Middle Channel) Communication System: Customer System; Frequency: 2442.0 MHz;Duty Cycle:1:1 Medium parameters used (interpolated): f =2442.0 MHz; σ = 1.82 S/m; εr = 38.80; ρ = 1000 kg/m3 Phantom section: Left Head Section: Probe: ES3DV3 - SN3842; ConvF(7.26, 7.26, 7.26); Calibrated: 06/06/2014; Sensor-Surface: 4mm (Mechanical Surface Detection) Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (91x51x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.696 W/kg Zoom Scan (6x6x5)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 5.346 V/m; Power Drift = -0.10 dB Peak SAR (extrapolated) = 0.542 W/g SAR(1 g) = 0.477 W/g; SAR(10 g) = 0.268 W/g Maximum value of SAR (measured) = 0.693 W/kg

0dB = 0.699 W/kg = -3.16 dBW/kg

Plot 7: Left Head Cheek (WLAN2450 Middle Channel)





Body- worn Rear side ( WLAN 802.11b Middle Channel) Communication System: Customer System; Frequency: 2442.0 MHz;Duty Cycle:1:1 Medium parameters used (interpolated): f =2442.0 MHz; σ = 1.82 S/m; εr = 38.80; ρ = 1000 kg/m3 Phantom section : Body- worn Probe: ES3DV3 - SN3842; ConvF(6.93, 6.93, 6.93); Calibrated: 06/06/2014; Electronics: DAE4 Sn1315; Calibrated: 25/11/2013 Phantom: SAM 1; Type: SAM; Measurement SW: DASY52, Version 52.8 (2); SEMCAD X Version 14.6.6 (6824) Area Scan (61x81x1): Measurement grid: dx=1.50 mm, dy=1.50 mm Maximum value of SAR (interpolated) = 0.593 mW/g Zoom Scan (5x5x5)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 6.347 V/m; Power Drift = -0.18 dB Peak SAR (extrapolated) = 0.652 mW/g SAR(1 g) = 0.626 mW/g; SAR(10 g) = 0.432 mW/g Maximum value of SAR (measured) = 0.610 W/kgs

0dB = 0.610 W/kg = -6.85 dB W/kg

Plot 8: Body- worn Rear side (WLAN802.11b Middle Channel)





5. CALIBRATION CERTIFICATE

5.1. PROBE CALIBRATION CERTICATE













































5.2. D900V2 DIPOLE CALIBRATION CERTICATE



































































































5.5. D2450V2 Dipole Calibration Ceriticate

































5.6. DAE4 CALIBRATION CERTICATE













6. EUT TEST PHOTO

Photograph of the depth in the Phantom (900MHz)







Right Head Tilt Setup Photo

Right Head Touch Setup Photo

Left Head Tilt Setup Photo





Left Head Touch Setup Photo

10mm Body-worn Rear Side Setup Photo

10mm Body-worn Front Side Setup Photo





7. PHOTOGRAPHS OF EUT CONSTRUCTIONAL Reference to the test report No. GTI20140202E-1

**********************THE END**********************

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TEST REPORT - CUBOT · Page 3 of 95 Report No.: GTI20140202E-8 Shenzhen General ... B 3.00% R 3 1 1 1.70 % 1.70 % ∞ 12 Probe positioned mech. restrictions B 0.40% R 3 1 1 0.20 %