EUCLID1 Intel Euclid Developer Kit RF Exposure Info SA170103W003_CCS-G003_FCC SAR_Report_WLAN&BT Intel Corporation

Intel Corporation Intel Euclid Developer Kit

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FCC SAR Test Report
FCC SAR Test Report
Report No.
: SA170103W003
Applicant
: Intel Corporation
Address
: 2191 Laurelwood Road M/S SC11-201 Santa Clara, CA 95054 USA
Product
: Intel Euclid Developer Kit
FCC ID
: 2AK6WEUCLID1
Brand
: INTEL
Model No.
: CCS-G003
Standards
: FCC 47 CFR Part 2 (2.1093) / IEEE C95.1:1992 / IEEE 1528:2013
KDB 865664 D01 v01r04 / KDB 865664 D02 v01r02
KDB 248227 D01 v02r02
KDB 447498 D01 v06
Sample Received Date
: Mar. 22, 2017
Date of Testing
: Mar. 25, 2017 ~ Mar. 26, 2017
CERTIFICATION: The above equipment have been tested by Bureau Veritas Shenzhen Co., Ltd. Dongguan
Branch, and found compliance with the requirement of the above standards. The test record, data evaluation &
Equipment Under Test (EUT) configurations represented herein are true and accurate accounts of the
measurements of the sample’s SAR characteristics under the conditions specified in this report. It should not be
reproduced except in full, without the written approval of our laboratory. The client should not use it to claim product
certification, approval, or endorsement by A2LA or any government agencies.
Prepared By :
Yihu Xiong / Engineer
Certificate #2951.01
Approved By :
Bill Yao / Manager
This report is for your exclusive use. Any copying or replication of this report to or for any other person or entity, or use of our name or trademark, is permitted only
with our prior written permission. This report sets forth our findings solely with respect to the test samples identified herein. The results set forth in this report are
not indicative or representative of the quality or characteristics of the lot from which a test sample was taken or any similar or identical product unless specifically
and expressly noted. Our report includes all of the tests requested by you and the results thereof based upon the information that you provided to us. You have 60
days from date of issuance of this report to notify us of any material error or omission caused by our negligence, provided, however, that such notice shall be in
writing and shall specifically address the issue you wish to raise. A failure to raise such issue within the prescribed time shall constitute your unqualified
acceptance of the completeness of this report, the tests conducted and the correctness of the report contents. Unless specific mention, the uncertainty of
measurement has been explicitly taken into account to declare the compliance or non-compliance to the specification.
Report Format Version 5.0.0
Report No. : SA170103W003
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FCC SAR Test Report
Table of Contents
Release Control Record ............................................................................................................................................................... 3
1. Summary of Maximum SAR Value ....................................................................................................................................... 4
2. Description of Equipment Under Test ................................................................................................................................. 5
3. SAR Measurement System ................................................................................................................................................... 6
3.1
Definition of Specific Absorption Rate (SAR) ............................................................................................................... 6
3.2
SPEAG DASY System ................................................................................................................................................. 6
3.2.1 Robot.................................................................................................................................................................. 7
3.2.2 Probes ................................................................................................................................................................ 8
3.2.3 Data Acquisition Electronics (DAE) .................................................................................................................... 8
3.2.4 Phantoms ........................................................................................................................................................... 9
3.2.5 Device Holder................................................................................................................................................... 10
3.2.6 System Validation Dipoles ................................................................................................................................ 10
3.2.7 Tissue Simulating Liquids ................................................................................................................................. 11
3.3
SAR System Verification ............................................................................................................................................ 14
3.4
SAR Measurement Procedure ................................................................................................................................... 15
3.4.1 Area & Zoom Scan Procedure ......................................................................................................................... 15
3.4.2 Volume Scan Procedure................................................................................................................................... 15
3.4.3 Power Drift Monitoring ...................................................................................................................................... 16
3.4.4 Spatial Peak SAR Evaluation ........................................................................................................................... 16
3.4.5 SAR Averaged Methods ................................................................................................................................... 16
4. SAR Measurement Evaluation ............................................................................................................................................ 17
4.1
EUT Configuration and Setting................................................................................................................................... 17
4.2
EUT Testing Position .................................................................................................................................................. 19
4.2.1 SAR Test Exclusion Evaluations ...................................................................................................................... 19
4.3
Tissue Verification ...................................................................................................................................................... 20
4.4
System Validation....................................................................................................................................................... 20
4.5
System Verification..................................................................................................................................................... 20
4.6
Maximum Output Power............................................................................................................................................. 21
4.6.1 Maximum Conducted Power ............................................................................................................................ 21
4.6.2 Measured Conducted Power Result................................................................................................................. 21
4.7
SAR Testing Results .................................................................................................................................................. 23
4.7.1 SAR Test Reduction Considerations ................................................................................................................ 23
4.7.2 SAR Results for Body Exposure Condition (Separation Distance is 0 cm Gap) ............................................... 24
4.7.3 SAR Measurement Variability........................................................................................................................... 25
5. Calibration of Test Equipment ............................................................................................................................................ 26
6. Measurement Uncertainty ................................................................................................................................................... 27
7. Information on the Testing Laboratories ........................................................................................................................... 29
Appendix A. SAR Plots of System Verification
Appendix B. SAR Plots of SAR Measurement
Appendix C. Calibration Certificate for Probe and Dipole
Appendix D. Photographs of EUT and Setup
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Release Control Record
Report No.
SA170103W003
Report Format Version 5.0.0
Report No. : SA170103W003
Reason for Change
Date Issued
Initial release
Mar. 26, 2017
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FCC SAR Test Report
1. Summary of Maximum SAR Value
Highest Reported
Equipment
Class
Mode
Body SAR1g
DTS
2.4G WLAN
0.33
NII
5.2G WLAN
5.8G WLAN
0.61
0.90
DSS
Bluetooth
N/A
(0 cm Gap)
(W/kg)
Note:
1. The SAR limit (Head & Body: SAR1g 1.6 W/kg, Extremity: SAR10g 4.0 W/kg) for general population /
uncontrolled exposure is specified in FCC 47 CFR part 2 (2.1093) and ANSI/IEEE C95.1-1992.
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2. Description of Equipment Under Test
EUT Type
FCC ID
Brand Name
Model Name
HW Version
SW Version
Tx Frequency Bands
(Unit: MHz)
Uplink Modulations
Maximum Tune-up Conducted Power
(Unit: dBm)
Antenna Type
EUT Stage
Intel Euclid Developer Kit
2AK6WEUCLID1
INTEL
CCS-G003
9602C
4.4.0-9014-cs1p
WLAN : 2412 ~ 2462, 5180 ~ 5240, 5745 ~ 5805
Bluetooth : 2402 ~ 2480
802.11b : DSSS
802.11a/g/n : OFDM
Bluetooth : GFSK, π/4-DQPSK, 8-DPSK, LE
WLAN 2.4G : 14.5
WLAN 5.2G : 11.0
WLAN 5.8G : 10.5
Bluetooth : 5.9
Fixed Internal Antenna
Identical Prototype
Note:
1. The above EUT information is declared by manufacturer and for more detailed features description please refers
to the manufacturer's specifications or User's Manual.
List of Accessory:
Battery
Brand Name
Model Name
Power Rating
Type
Report Format Version 5.0.0
Report No. : SA170103W003
FH
BT-G012-H
3.8Vdc, 2200mAh
Li-polymer
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3. SAR Measurement System
3.1 Definition of Specific Absorption Rate (SAR)
SAR is related to the rate at which energy is absorbed per unit mass in an object exposed to a radio field. The SAR
distribution in a biological body is complicated and is usually carried out by experimental techniques or numerical
modeling. The standard recommends limits for two tiers of groups, occupational/controlled and general
population/uncontrolled, based on a person’s awareness and ability to exercise control over his or her exposure. In
general, occupational/controlled exposure limits are higher than the limits for general population/uncontrolled.
The SAR definition is the time derivative (rate) of the incremental energy (dW) absorbed by (dissipated in) an
incremental mass (dm) contained in a volume element (dv) of a given density (ρ). The equation description is as
below:
SAR is expressed in units of Watts per kilogram (W/kg)
SAR measurement can be related to the electrical field in the tissue by
Where: σ is the conductivity of the tissue, ρ is the mass density of the tissue and E is the RMS electrical field
strength.
3.2 SPEAG DASY System
DASY system consists of high precision robot, probe alignment sensor, phantom, robot controller, controlled
measurement server and near-field probe. The robot includes six axes that can move to the precision position of the
DASY5 software defined. The DASY software can define the area that is detected by the probe. The robot is
connected to controlled box. Controlled measurement server is connected to the controlled robot box. The DAE
includes amplifier, signal multiplexing, AD converter, offset measurement and surface detection. It is connected to
the Electro-optical coupler (ECO). The ECO performs the conversion form the optical into digital electric signal of the
DAE and transfers data to the PC.
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Fig-3.1 DASY System Setup
3.2.1
Robot
The DASY system uses the high precision robots from Stäubli SA (France). For the 6-axis controller system, the
robot controller version (DASY5: CS8c) from Stäubli is used. The Stäubli robot series have many features that are
important for our application:
‧ High precision (repeatability ±0.035 mm)
‧ High reliability (industrial design)
‧ Jerk-free straight movements
‧ Low ELF interference (the closed metallic construction shields against motor control fields)
Fig-3.2 DASY5
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3.2.2
Probes
The SAR measurement is conducted with the dosimetric probe. The probe is specially designed and calibrated for
use in liquid with high permittivity. The dosimetric probe has special calibration in liquid at different frequency.
Model
Construction
Frequency
Directivity
Dynamic Range
Dimensions
Model
Construction
Frequency
Directivity
Dynamic Range
Dimensions
3.2.3
EX3DV4
Symmetrical design with triangular core. Built-in shielding against
static charges. PEEK enclosure material (resistant to organic
solvents, e.g., DGBE).
10 MHz to 6 GHz
Linearity: ± 0.2 dB
± 0.3 dB in HSL (rotation around probe axis)
± 0.5 dB in tissue material (rotation normal to probe axis)
10 µW/g to 100 mW/g
Linearity: ± 0.2 dB (noise: typically < 1 µW/g)
Overall length: 337 mm (Tip: 20 mm)
Tip diameter: 2.5 mm (Body: 12 mm)
Typical distance from probe tip to dipole centers: 1 mm
ES3DV3
Symmetrical design with triangular core. Interleaved sensors.
Built-in shielding against static charges. PEEK enclosure material
(resistant to organic solvents, e.g., DGBE).
10 MHz to 4 GHz
Linearity: ± 0.2 dB
± 0.2 dB in HSL (rotation around probe axis)
± 0.3 dB in tissue material (rotation normal to probe axis)
5 µW/g to 100 mW/g
Linearity: ± 0.2 dB
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
Data Acquisition Electronics (DAE)
Model
Construction
Measurement
Range
Input Offset
Voltage
Input Bias Current
Dimensions
DAE3, DAE4
Signal amplifier, multiplexer, A/D converter and control logic.
Serial optical link for communication with DASY embedded
system (fully remote controlled). Two step probe touch detector
for mechanical surface detection and emergency robot stop.
-100 to +300 mV (16 bit resolution and two range settings: 4mV,
400mV)
< 5µV (with auto zero)
< 50 fA
60 x 60 x 68 mm
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3.2.4
Phantoms
Model
Construction
Material
Shell Thickness
Dimensions
Filling Volume
Model
Construction
Material
Shell Thickness
Dimensions
Filling Volume
Twin SAM
The shell corresponds to the specifications of the Specific
Anthropomorphic Mannequin (SAM) phantom defined in IEEE
1528 and IEC 62209-1. It enables the dosimetric evaluation of
left and right hand phone usage as well as body mounted usage
at the flat phantom region. A cover prevents evaporation of the
liquid. Reference markings on the phantom allow the complete
setup of all predefined phantom positions and measurement
grids by teaching three points with the robot.
Vinylester, glass fiber reinforced (VE-GF)
2 ± 0.2 mm (6 ± 0.2 mm at ear point)
Length: 1000 mm
Width: 500 mm
Height: adjustable feet
approx. 25 liters
ELI
Phantom for compliance testing of handheld and body-mounted
wireless devices in the frequency range of 30 MHz to 6 GHz. ELI
is fully compatible with the IEC 62209-2 standard and all known
tissue simulating liquids. ELI has been optimized regarding its
performance and can be integrated into our standard phantom
tables. A cover prevents evaporation of the liquid. Reference
markings on the phantom allow installation of the complete setup,
including all predefined phantom positions and measurement
grids, by teaching three points. The phantom is compatible with
all SPEAG dosimetric probes and dipoles.
Vinylester, glass fiber reinforced (VE-GF)
2.0 ± 0.2 mm (bottom plate)
Major axis: 600 mm
Minor axis: 400 mm
approx. 30 liters
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3.2.5
Device Holder
Model
Construction
Material
Model
Construction
Material
3.2.6
Mounting Device
In combination with the Twin SAM Phantom or ELI4, the
Mounting Device enables the rotation of the mounted transmitter
device in spherical coordinates. Rotation point is the ear opening
point. Transmitter devices can be easily and accurately
positioned according to IEC, IEEE, FCC or other specifications.
The device holder can be locked for positioning at different
phantom sections (left head, right head, flat).
POM
Laptop Extensions Kit
Simple but effective and easy-to-use extension for Mounting
Device that facilitates the testing of larger devices according to
IEC 62209-2 (e.g., laptops, cameras, etc.). It is lightweight and
fits easily on the upper part of the Mounting Device in place of the
phone positioner.
POM, Acrylic glass, Foam
System Validation Dipoles
Model
Frequency
Return Loss
D-Serial
Symmetrical dipole with l/4 balun. Enables measurement of feed
point impedance with NWA. Matched for use near flat phantoms
filled with tissue simulating solutions.
750 MHz to 5800 MHz
> 20 dB
Power Capability
> 100 W (f < 1GHz), > 40 W (f > 1GHz)
Construction
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3.2.7
Tissue Simulating Liquids
For SAR measurement of the field distribution inside the phantom, the phantom must be filled with homogeneous
tissue simulating liquid to a depth of at least 15 cm. For head SAR testing, the liquid height from the ear reference
point (ERP) of the phantom to the liquid top surface is larger than 15 cm. For body SAR testing, the liquid height
from the center of the flat phantom to the liquid top surface is larger than 15 cm. The nominal dielectric values of the
tissue simulating liquids in the phantom and the tolerance of 5% are listed in Table-3.1.
Photo of Liquid Height for Head Position
Photo of Liquid Height for Body Position
The dielectric properties of the head tissue simulating liquids are defined in IEEE 1528, and KDB 865664 D01
Appendix A. For the body tissue simulating liquids, the dielectric properties are defined in KDB 865664 D01
Appendix A. The dielectric properties of the tissue simulating liquids were verified prior to the SAR evaluation using
a dielectric assessment kit and a network analyzer.
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Table-3.1 Targets of Tissue Simulating Liquid
Frequency
(MHz)
Target
Permittivity
750
835
900
1450
1640
1750
1800
1900
2000
2300
2450
2600
3500
5200
5300
5500
5600
5800
41.9
41.5
41.5
40.5
40.3
40.1
40.0
40.0
40.0
39.5
39.2
39.0
37.9
36.0
35.9
35.6
35.5
35.3
750
835
900
1450
1640
1750
1800
1900
2000
2300
2450
2600
3500
5200
5300
5500
5600
5800
55.5
55.2
55.0
54.0
53.8
53.4
53.3
53.3
53.3
52.9
52.7
52.5
51.3
49.0
48.9
48.6
48.5
48.2
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Range of
±5%
For Head
39.8 ~ 44.0
39.4 ~ 43.6
39.4 ~ 43.6
38.5 ~ 42.5
38.3 ~ 42.3
38.1 ~ 42.1
38.0 ~ 42.0
38.0 ~ 42.0
38.0 ~ 42.0
37.5 ~ 41.5
37.2 ~ 41.2
37.1 ~ 41.0
36.0 ~ 39.8
34.2 ~ 37.8
34.1 ~ 37.7
33.8 ~ 37.4
33.7 ~ 37.3
33.5 ~ 37.1
For Body
52.7 ~ 58.3
52.4 ~ 58.0
52.3 ~ 57.8
51.3 ~ 56.7
51.1 ~ 56.5
50.7 ~ 56.1
50.6 ~ 56.0
50.6 ~ 56.0
50.6 ~ 56.0
50.3 ~ 55.5
50.1 ~ 55.3
49.9 ~ 55.1
48.7 ~ 53.9
46.6 ~ 51.5
46.5 ~ 51.3
46.2 ~ 51.0
46.1 ~ 50.9
45.8 ~ 50.6
Target
Conductivity
Range of
±5%
0.89
0.90
0.97
1.20
1.29
1.37
1.40
1.40
1.40
1.67
1.80
1.96
2.91
4.66
4.76
4.96
5.07
5.27
0.85 ~ 0.93
0.86 ~ 0.95
0.92 ~ 1.02
1.14 ~ 1.26
1.23 ~ 1.35
1.30 ~ 1.44
1.33 ~ 1.47
1.33 ~ 1.47
1.33 ~ 1.47
1.59 ~ 1.75
1.71 ~ 1.89
1.86 ~ 2.06
2.76 ~ 3.06
4.43 ~ 4.89
4.52 ~ 5.00
4.71 ~ 5.21
4.82 ~ 5.32
5.01 ~ 5.53
0.96
0.97
1.05
1.30
1.40
1.49
1.52
1.52
1.52
1.81
1.95
2.16
3.31
5.30
5.42
5.65
5.77
6.00
0.91 ~ 1.01
0.92 ~ 1.02
1.00 ~ 1.10
1.24 ~ 1.37
1.33 ~ 1.47
1.42 ~ 1.56
1.44 ~ 1.60
1.44 ~ 1.60
1.44 ~ 1.60
1.72 ~ 1.90
1.85 ~ 2.05
2.05 ~ 2.27
3.14 ~ 3.48
5.04 ~ 5.57
5.15 ~ 5.69
5.37 ~ 5.93
5.48 ~ 6.06
5.70 ~ 6.30
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The following table gives the recipes for tissue simulating liquids.
Table-3.2 Recipes of Tissue Simulating Liquid
Tissue
Type
Bactericide
DGBE
HEC
NaCl
H750
H835
H900
H1450
H1640
H1750
H1800
H1900
H2000
H2300
H2450
H2600
H3500
H5G
B750
B835
B900
B1450
B1640
B1750
B1800
B1900
B2000
B2300
B2450
B2600
B3500
B5G
0.2
0.2
0.2
0.2
0.2
0.2
43.3
45.8
47.0
44.5
44.5
44.5
44.9
45.0
45.1
8.0
34.0
32.5
31.0
29.5
29.5
30.0
31.0
31.4
31.8
28.8
0.2
0.2
0.2
0.2
0.2
0.2
1.5
1.5
1.4
0.6
0.5
0.4
0.3
0.2
0.1
0.1
0.1
0.1
0.2
0.8
0.9
0.9
0.3
0.3
0.2
0.4
0.3
0.2
0.1
0.1
0.1
0.1
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Sucrose
Triton
X-100
Water
Diethylene
Glycol
Monohexylether
56.0
57.0
58.0
48.8
48.5
48.2
20.0
17.2
10.7
42.1
41.1
40.2
56.1
53.7
52.6
55.2
55.3
55.4
55.0
54.9
54.8
71.8
65.5
50.0
50.2
50.5
65.7
67.2
68.8
70.1
70.2
69.8
68.9
68.5
68.1
71.1
78.6
17.3
10.7
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3.3 SAR System Verification
The system check verifies that the system operates within its specifications. It is performed daily or before every
SAR measurement. The system check uses normal SAR measurements in the flat section of the phantom with a
matched dipole at a specified distance. The system verification setup is shown as below.
Fig-3.4 System Verification Setup
The validation dipole is placed beneath the flat phantom with the specific spacer in place. The distance spacer is
touch the phantom surface with a light pressure at the reference marking and be oriented parallel to the long side of
the phantom. The spectrum analyzer measures the forward power at the location of the system check dipole
connector. The signal generator is adjusted for the desired forward power (250 mW is used for 700 MHz to 3 GHz,
100 mW is used for 3.5 GHz to 6 GHz) at the dipole connector and the power meter is read at that level. After
connecting the cable to the dipole, the signal generator is readjusted for the same reading at power meter.
After system check testing, the SAR result will be normalized to 1W forward input power and compared with the
reference SAR value derived from validation dipole certificate report. The deviation of system check should be within
10 %.
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3.4 SAR Measurement Procedure
According to the SAR test standard, the recommended procedure for assessing the peak spatial-average SAR value
consists of the following steps:
(a) Power reference measurement
(b) Area scan
(c) Zoom scan
(d) Power drift measurement
The SAR measurement procedures for each of test conditions are as follows:
(a) Make EUT to transmit maximum output power
(b) Measure conducted output power through RF cable
(c) Place the EUT in the specific position of phantom
(d) Perform SAR testing steps on the DASY system
(e) Record the SAR value
3.4.1
Area & Zoom Scan Procedure
First Area Scan is used to locate the approximate location(s) of the local peak SAR value(s). The measurement grid
within an Area Scan is defined by the grid extent, grid step size and grid offset. Next, in order to determine the EM
field distribution in a three-dimensional spatial extension, Zoom Scan is required. The Zoom Scan is performed
around the highest E-field value to determine the averaged SAR-distribution over 10 g. According to KDB 865664
D01, the resolution for Area and Zoom scan is specified in the table below.
Items
Area Scan
(∆x, ∆y)
Zoom Scan
(∆x, ∆y)
Zoom Scan
(∆z)
Zoom Scan
Volume
<= 2 GHz
2-3 GHz
3-4 GHz
4-5 GHz
5-6 GHz
<= 15 mm
<= 12 mm
<= 12 mm
<= 10 mm
<= 10 mm
<= 8 mm
<= 5 mm
<= 5 mm
<= 4 mm
<= 4 mm
<= 5 mm
<= 5 mm
<= 4 mm
<= 3 mm
<= 2 mm
>= 30 mm
>= 30 mm
>= 28 mm
>= 25 mm
>= 22 mm
Note:
When zoom scan is required and report SAR is <= 1.4 W/kg, the zoom scan resolution of ∆x / ∆y (2-3GHz: <= 8 mm,
3-4GHz: <= 7 mm, 4-6GHz: <= 5 mm) may be applied.
3.4.2
Volume Scan Procedure
The volume scan is used for assess overlapping SAR distributions for antennas transmitting in different frequency
bands. It is equivalent to an oversized zoom scan used in standalone measurements. The measurement volume will
be used to enclose all the simultaneous transmitting antennas. For antennas transmitting simultaneously in different
frequency bands, the volume scan is measured separately in each frequency band. In order to sum correctly to
compute the 1g aggregate SAR, the EUT remain in the same test position for all measurements and all volume scan
use the same spatial resolution and grid spacing. When all volume scan were completed, the software, SEMCAD
postprocessor can combine and subsequently superpose these measurement data to calculating the multiband
SAR.
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3.4.3
Power Drift Monitoring
All SAR testing is under the EUT install full charged battery and transmit maximum output power. In DASY
measurement software, the power reference measurement and power drift measurement procedures are used for
monitoring the power drift of EUT during SAR test. Both these procedures measure the field at a specified reference
position before and after the SAR testing. The software will calculate the field difference in dB. If the power drift more
than 5%, the SAR will be retested.
3.4.4
Spatial Peak SAR Evaluation
The procedure for spatial peak SAR evaluation has been implemented according to the test standard. It can be
conducted for 1g and 10g, as well as for user-specific masses. The DASY software includes all numerical
procedures necessary to evaluate the spatial peak SAR value.
The base for the evaluation is a "cube" measurement. The measured volume must include the 1g and 10g cubes
with the highest averaged SAR values. For that purpose, the center of the measured volume is aligned to the
interpolated peak SAR value of a previously performed area scan.
The entire evaluation of the spatial peak values is performed within the post-processing engine (SEMCAD). The
system always gives the maximum values for the 1g and 10g cubes. The algorithm to find the cube with highest
averaged SAR is divided into the following stages:
(a) Extraction of the measured data (grid and values) from the Zoom Scan
(b) Calculation of the SAR value at every measurement point based on all stored data (A/D values and
measurement parameters)
(c) Generation of a high-resolution mesh within the measured volume
(d) Interpolation of all measured values form the measurement grid to the high-resolution grid
(e) Extrapolation of the entire 3-D field distribution to the phantom surface over the distance from sensor to surface
(f)
Calculation of the averaged SAR within masses of 1g and 10g
3.4.5
SAR Averaged Methods
In DASY, the interpolation and extrapolation are both based on the modified Quadratic Shepard’s method. The
interpolation scheme combines a least-square fitted function method and a weighted average method which are the
two basic types of computational interpolation and approximation.
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. The uncertainty increases with the extrapolation distance. To keep the uncertainty within 1% for the 1 g and
10 g cubes, the extrapolation distance should not be larger than 5 mm.
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4. SAR Measurement Evaluation
4.1 EUT Configuration and Setting

In general, various vendor specific external test software and chipset based internal test modes are typically used
for SAR measurement. These chipset based test mode utilities are generally hardware and manufacturer dependent,
and often include substantial flexibility to reconfigure or reprogram a device. A Wi-Fi device must be configured to
transmit continuously at the required data rate, channel bandwidth and signal modulation, using the highest
transmission duty factor supported by the test mode tools for SAR measurement. The test frequencies established
using test mode must correspond to the actual channel frequencies. When 802.11 frame gaps are accounted for in
the transmission, a maximum transmission duty factor of 92 - 96% is typically achievable in most test mode
configurations. A minimum transmission duty factor of 85% is required to avoid certain hardware and device
implementation issues related to wide range SAR scaling. In addition, a periodic transmission duty factor is required
for current generation SAR systems to measure SAR correctly. The reported SAR must be scaled to 100%
transmission duty factor to determine compliance at the maximum tune-up tolerance limit.
According to KDB 248227 D01, this device has installed WLAN engineering testing software which can provide
continuous transmitting RF signal. During WLAN SAR testing, this device was operated to transmit continuously at
the maximum transmission duty with specified transmission mode, operating frequency, lowest data rate, and
maximum output power.
Initial Test Configuration
An initial test configuration is determined for OFDM transmission modes in 2.4 GHz and 5 GHz bands according to
the channel bandwidth, modulation and data rate combination(s) with the highest maximum output power specified
for production units in each standalone and aggregated frequency band. When the same maximum power is
specified for multiple transmission modes in a frequency band, the largest channel bandwidth, lowest order
modulation, lowest data rate and lowest order 802.11a/g/n/ac mode is used for SAR measurement, on the highest
measured output power channel in the initial test configuration, for each frequency band.
Subsequent Test Configuration
SAR measurement requirements for the remaining 802.11 transmission mode configurations that have not been
tested in the initial test configuration are determined separately for each standalone and aggregated frequency band,
in each exposure condition, according to the maximum output power specified for production units. Additional power
measurements may be required to determine if SAR measurements are required for subsequent highest output
power channels in a subsequent test configuration. When the highest reported SAR for the initial test configuration
according to the initial test position or fixed exposure position requirements, is adjusted by the ratio of the
subsequent test configuration to initial test configuration specified maximum output power and the adjusted SAR is ≤
1.2 W/kg, SAR is not required for that subsequent test configuration.
SAR Test Configuration and Channel Selection
When multiple channel bandwidth configurations in a frequency band have the same specified maximum output
power, the initial test configuration is using largest channel bandwidth, lowest order modulation, lowest data rate,
and lowest order 802.11 mode (i.e., 802.11a is chosen over 802.11n then 802.11ac or 802.11g is chosen over
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802.11n). After an initial test configuration is determined, if multiple test channels have the same measured
maximum output power, the channel chosen for SAR measurement is determined according to the following.
1) The channel closest to mid-band frequency is selected for SAR measurement.
2) For channels with equal separation from mid-band frequency; for example, high and low channels or two
mid-band channels, the higher frequency (number) channel is selected for SAR measurement.
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4.2 EUT Testing Position
This EUT was tested for all six surfaces of the EUT as Front Face, Rear Face, Left Side, Right Side, Top Side and
Bottom Side. The separation distance between this EUT and phantom is 0 cm.
4.2.1
SAR Test Exclusion Evaluations
According to KDB 447498 D01, the SAR test exclusion condition is based on source-based time-averaged
maximum conducted output power, adjusted for tune-up tolerance, and the minimum test separation distance
required for the exposure conditions. The SAR exclusion threshold is determined by the following formula.
≤ 3.0 for SAR-1g, ≤ 7.5 for SAR-10g
When the minimum test separation distance is < 5 mm, a distance of 5 mm is applied to determine SAR test
exclusion.
Mode
Max.
Tune-up
Power
(dBm)
Max.
Tune-up
Power
(mW)
BT
5.9
3.89
Body
Ant. to Surface
(mm)
Calculated
Result
Require
SAR
Testing?
1.2
No
Note:
1. When separation distance <= 50 mm and the calculated result shown in above table is <= 3.0 for SAR-1g
exposure condition, or <= 7.5 for SAR-10g exposure condition, the SAR testing exclusion is applied.
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4.3 Tissue Verification
The measuring results for tissue simulating liquid are shown as below.
Test
Date
Tissue
Type
Frequency
(MHz)
Liquid
Temp.
(℃)
Measured
Conductivity
(σ)
Measured
Permittivity
(εr)
Target
Conductivity
(σ)
Target
Permittivity
(εr)
Conductivity
Deviation
(%)
Permittivity
Deviation
(%)
Mar. 26, 2017
Mar. 25, 2017
Mar. 25, 2017
Body
Body
Body
2450
5250
5800
21.1
21.2
21.2
1.906
5.547
6.287
51.411
48.253
47.348
1.95
5.36
6.00
52.70
48.90
48.20
-2.26
3.49
4.78
-2.45
-1.32
-1.77
Note:
The dielectric properties of the tissue simulating liquid must be measured within 24 hours before the SAR testing
and within ±5% of the target values. Liquid temperature during the SAR testing must be within ±2 ℃.
4.4 System Validation
The SAR measurement system was validated according to procedures in KDB 865664 D01. The validation status in
tabulated summary is as below.
Test
Date
Probe
S/N
Calibration Point
Mar. 26, 2017
Mar. 25, 2017
Mar. 25, 2017
3873
3873
3873
Body
Body
Body
2450
5250
5800
Measured
Measured
Conductivity
Permittivity
(σ)
1.906
5.547
6.287
Validation for CW
Validation for Modulation
(εr)
Sensitivity
Range
Probe
Linearity
Probe
Isotropy
51.411
48.253
47.348
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Modulation
Duty Factor
Type
OFDM
OFDM
OFDM
N/A
N/A
N/A
PAR
Pass
Pass
Pass
4.5 System Verification
The measuring result for system verification is tabulated as below.
Test
Date
Mar. 26, 2017
Mar. 25, 2017
Mar. 25, 2017
Mode
Frequency
(MHz)
1W Target
SAR-1g
(W/kg)
Measured
SAR-1g
(W/kg)
Normalized
to 1W
SAR-1g
(W/kg)
Deviation
(%)
Dipole
S/N
Probe
S/N
DAE
S/N
Body
Body
Body
2450
5250
5800
52.70
77.70
77.00
12.70
7.68
7.73
50.80
76.80
77.30
-3.61
-1.16
0.39
893
1133
1133
3873
3873
3873
1341
1341
1341
Note:
Comparing to the reference SAR value provided by SPEAG, the validation data should be within its specification of
10 %. The result indicates the system check can meet the variation criterion and the plots can be referred to
Appendix A of this report.
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4.6 Maximum Output Power
4.6.1
Maximum Conducted Power
The maximum conducted average power (Unit: dBm) including tune-up tolerance is shown as below.
Mode
802.11b
802.11g
802.11a
802.11n HT20
2.4G WLAN
14.5
13.5
N/A
12.5
Mode
GFSK
π/4-DQPSK
8-DPSK
LE
4.6.2
5.2G WLAN
N/A
N/A
11.0
10.0
5.8G WLAN
N/A
N/A
10.5
9.5
2.4G Bluetooth
5.9
2.5
2.5
4.5
Measured Conducted Power Result
The measuring conducted average power (Unit: dBm) is shown as below.

Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
1 (2412)
13.37
1 (2412)
12.63
1 (2412)
11.90
802.11b
6 (2437)
13.47
802.11g
6 (2437)
13.15
802.11n (HT20)
6 (2437)
12.11
11 (2462)
13.94
11 (2462)
12.88
11 (2462)
11.71

Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
36 (5180)
10.15
36 (5180)
9.77
802.11a
40 (5200)
44 (5220)
10.65
10.38
802.11n (HT20)
40 (5200)
44 (5220)
9.94
9.40
48 (5240)
10.24
48 (5240)
9.42

Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
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149 (5745)
10.42
149 (5745)
9.33
802.11a
153 (5765)
157 (5785)
9.38
9.83
802.11n (HT20)
153 (5765)
157 (5785)
9.01
9.20
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9.69
161 (5805)
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Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
Mode
Channel / Frequency (MHz)
Average Power
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0 (2402)
4.70
0 (2402)
1.06
0 (2402)
1.15
0 (2402)
4.42
Bluetooth GFSK
39 (2441)
5.81
Bluetooth π/4-DQPSK
39 (2441)
1.96
Bluetooth 8-DPSK
39 (2441)
2.11
Bluetooth LE
19 (2440)
4.23
78 (2480)
5.70
78 (2480)
1.50
78 (2480)
1.68
39 (2480)
4.26
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4.7 SAR Testing Results
4.7.1
SAR Test Reduction Considerations

Testing of other required channels within the operating mode of a frequency band is not required when the reported
SAR for the mid-band or highest output power channel is:
(1) ≤ 0.8 W/kg or 2.0 W/kg, for 1-g or 10-g respectively, when the transmission band is ≤ 100 MHz
(2) ≤ 0.6 W/kg or 1.5 W/kg, for 1-g or 10-g respectively, when the transmission band is between 100 MHz and 200
MHz
(3) ≤ 0.4 W/kg or 1.0 W/kg, for 1-g or 10-g respectively, when the transmission band is ≥ 200 MHz

(1) For handsets operating next to ear, hotspot mode or mini-tablet configurations, the initial test position
procedures were applied. The test position with the highest extrapolated peak SAR will be used as the initial
test position. When the reported SAR of initial test position is <= 0.4 W/kg, SAR testing for remaining test
positions is not required. Otherwise, SAR is evaluated at the subsequent highest peak SAR positions until the
reported SAR result is <= 0.8 W/kg or all test positions are measured.
(2) For WLAN 2.4 GHz, the highest measured maximum output power channel for DSSS was selected for SAR
measurement. When the reported SAR is <= 0.8 W/kg, no further SAR testing is required. Otherwise, SAR is
evaluated at the next highest measured output power channel. When any reported SAR is > 1.2 W/kg, SAR is
required for the third channel. For OFDM modes (802.11g/n), SAR is not required when the highest reported
SAR for DSSS is adjusted by the ratio of OFDM to DSSS specified maximum output power and it is <= 1.2
W/kg.
(3) For WLAN 5 GHz, the initial test configuration was selected according to the transmission mode with the
highest maximum output power. When the reported SAR of initial test configuration is > 0.8 W/kg, SAR is
required for the subsequent highest measured output power channel until the reported SAR result is <= 1.2
W/kg or all required channels are measured. For other transmission modes, SAR is not required when the
highest reported SAR for initial test configuration is adjusted by the ratio of subsequent test configuration to
initial test configuration specified maximum output power and it is <= 1.2 W/kg.
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4.7.2
Plot
No.
SAR Results for Body Exposure Condition (Separation Distance is 0 cm Gap)
Band
Mode
Test
Position
Ch.
Max.
Tune-up
Power
(dBm)
Measured
Conducted
Power
(dBm)
Power
Drift
(dB)
Measured
SAR-1g
(W/kg)
Scaling
Factor
Scaled
SAR-1g
(W/kg)
802.11b
802.11b
802.11b
802.11b
802.11b
802.11b
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
802.11a
Front Face
Rear Face
Left Side
Right Side
Top Side
Bottom Side
Front Face
Rear Face
Left Side
Right Side
Top Side
Bottom Side
Front Face
Rear Face
Left Side
Right Side
Top Side
Bottom Side
Front Face
Front Face
11
11
11
11
11
11
40
40
40
40
40
40
149
149
149
149
149
149
157
149
14.5
14.5
14.5
14.5
14.5
14.5
11.0
11.0
11.0
11.0
11.0
11.0
10.5
10.5
10.5
10.5
10.5
10.5
10.5
10.5
13.94
13.94
13.94
13.94
13.94
13.94
10.65
10.65
10.65
10.65
10.65
10.65
10.42
10.42
10.42
10.42
10.42
10.42
9.83
10.42
-0.02
0.02
0.05
0.06
0.01
-0.03
0.00
0.02
0.02
0.02
0.00
0.00
0.07
0.02
0.07
0.02
0.00
0.00
0.07
0.07
0.286
0.04
0.174
0.047
0.561
0.042
0.11
0.05
0.882
0.116
0.117
0.08
0.752
0.871
1.14
1.14
1.14
1.14
1.14
1.14
1.08
1.08
1.08
1.08
1.08
1.08
1.02
1.02
1.02
1.02
1.02
1.02
1.17
1.02
0.33
0.05
0.20
0.05
0.00
0.00
0.61
0.05
0.12
0.05
0.00
0.00
0.90
0.12
0.12
0.08
0.00
0.00
0.88
0.89
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4.7.3
SAR Measurement Variability
According to KDB 865664 D01, SAR measurement variability was assessed for each frequency band, which is
determined by the SAR probe calibration point and tissue-equivalent medium used for the device measurements.
When both head and body tissue-equivalent media are required for SAR measurements in a frequency band, the
variability measurement procedures should be applied to the tissue medium with the highest measured SAR, using
the highest measured SAR configuration for that tissue-equivalent medium. Alternatively, if the highest measured
SAR for both head and body tissue-equivalent media are ≤ 1.45 W/kg and the ratio of these highest SAR values, i.e.,
largest divided by smallest value, is ≤ 1.10, the highest SAR configuration for either head or body tissue-equivalent
medium may be used to perform the repeated measurement. These additional measurements are repeated after the
completion of all measurements requiring the same head or body tissue-equivalent medium in a frequency band.
The test device should be returned to ambient conditions (normal room temperature) with the battery fully charged
before it is re-mounted on the device holder for the repeated measurement(s) to minimize any unexpected variations
in the repeated results.
SAR repeated measurement procedure:
1. When the highest measured SAR is < 0.80 W/kg, repeated measurement is not required.
2. When the highest measured SAR is >= 0.80 W/kg, repeat that measurement once.
3. If the ratio of largest to smallest SAR for the original and first repeated measurements is > 1.20, or when the
original or repeated measurement is >= 1.45 W/kg, perform a second repeated measurement.
4. If the ratio of largest to smallest SAR for the original, first and second repeated measurements is > 1.20, and the
original, first or second repeated measurement is >= 1.5 W/kg, perform a third repeated measurement.
Band
Mode
Test
Position
Ch.
Original
Measured
SAR-1g
(W/kg)
1st
Repeated
SAR-1g
(W/kg)
L/S
Ratio
2nd
Repeated
SAR-1g
(W/kg)
L/S
Ratio
3rd
Repeated
SAR-1g
(W/kg)
L/S
Ratio
802.11a
Front Face
149
0.882
0.871
1.01
N/A
N/A
N/A
N/A
Test Engineer:Yihu Xiong
Report Format Version 5.0.0
Report No. : SA170103W003
Page No.
Issued Date
: 25 of 29
: Mar. 26, 2017
FCC SAR Test Report
5. Calibration of Test Equipment
Equipment
System Validation Dipole
System Validation Dipole
Dosimetric E-Field Probe
Data Acquisition Electronics
ENA Series Network Analyzer
Spectrum Analyzer
MXG Analog Signal Generator
Power Meter
Power Sensor
Temp. & Humi. Recorder
Electronic Thermometer
Coupler
Report Format Version 5.0.0
Report No. : SA170103W003
Manufacturer
SPEAG
SPEAG
SPEAG
SPEAG
Agilent
KEYSIGHT
KEYSIGHT
Agilent
Agilent
CLOCK
YONGFA
Woken
Model
D2450V2
D5GHzV2
EX3DV4
DAE4
E5071C
N9010A
N5183A
ML2495A
MA2411B
HTC-1
YF-160A
0110A056020-10
SN
893
1133
3873
1341
MY46214638
MY54510355
MY50143024
1506002
1339353
157248
120100323
COM27RW1A3
Cal. Date
Aug. 26, 2016
Sep. 01, 2016
Sep. 01, 2016
Aug. 29, 2016
Jul. 27, 2016
Jun. 29, 2016
Mar. 01, 2017
Mar. 01, 2017
Mar. 01, 2017
Jul. 29, 2016
Sep. 28, 2016
Sep. 28, 2016
Page No.
Issued Date
Cal. Interval
1 Year
1 Year
1 Year
1 Year
1 Year
1Year
1 Year
1Year
1 Year
1 Year
1 Year
1 Year
: 26 of 29
: Mar. 26, 2017
FCC SAR Test Report
6. Measurement Uncertainty
Source of Uncertainty
Tolerance
Probability
(± %)
Distribution
6.0
Normal
Divisor
Ci
Ci
(1g)
(10g)
Standard
Standard
Uncertainty
Uncertainty
(± %, 1g)
(± %, 10g)
6.0
6.0
Vi
Measurement System
Probe Calibration
∞
Axial Isotropy
4.7
Rectangular
√3
0.707
0.707
1.9
1.9
∞
Hemispherical Isotropy
9.6
Rectangular
√3
0.707
0.707
3.9
3.9
∞
Boundary Effect
1.0
Rectangular
√3
0.6
0.6
∞
Linearity
4.7
Rectangular
√3
2.7
2.7
∞
System Detection Limits
0.25
Rectangular
√3
0.14
0.14
∞
Readout Electronics
0.3
Normal
0.3
0.3
∞
Response Time
0.0
Rectangular
√3
0.0
0.0
∞
Integration Time
1.7
Rectangular
√3
1.0
1.0
∞
RF Ambient Conditions - Noise
3.0
Rectangular
√3
1.7
1.7
∞
RF Ambient Conditions - Reflections
3.0
Rectangular
√3
1.7
1.7
∞
Probe Positioner Mechanical Tolerance
0.4
Rectangular
√3
0.2
0.2
∞
Probe Positioning with Respect to Phantom Shell
2.9
Rectangular
√3
1.7
1.7
∞
2.0
Rectangular
√3
1.2
1.2
∞
Test Sample Positioning
1.5 / 0.7
Normal
1.5
0.7
32
Device Holder Uncertainty
4.2 / 1.8
Normal
4.2
1.8
32
5.0
Rectangular
√3
2.9
2.9
∞
7.2
Rectangular
√3
4.2
4.2
∞
Liquid Conductivity - Deviation from Target Values
5.0
Rectangular
√3
0.64
0.43
1.8
1.2
∞
Liquid Conductivity - Measurement Uncertainty
1.0
Normal
0.64
0.43
0.6
0.4
25
Liquid Permittivity - Deviation from Target Values
5.0
Rectangular
√3
0.60
0.49
1.7
1.4
∞
Liquid Permittivity - Measurement Uncertainty
0.5
Normal
0.60
0.49
25
Extrapolation, interpolation, and integration
algorithms for max. SAR evaluation
Test Sample Related
Output Power Variation - SAR Drift Measurement
Phantom and Tissue Parameters
Phantom Uncertainty (Shape and Thickness
Tolerances)
0.3
0.2
Combined Standard Uncertainty
± 11.2 %
± 10.4 %
Expanded Uncertainty (K=2)
± 22.4 %
± 20.8 %
Uncertainty budget for frequency range 300 MHz to 3 GHz
Report Format Version 5.0.0
Report No. : SA170103W003
Page No.
Issued Date
: 27 of 29
: Mar. 26, 2017
FCC SAR Test Report
Source of Uncertainty
Tolerance
Probability
(± %)
Distribution
6.55
Normal
Divisor
Ci
Ci
(1g)
(10g)
Standard
Standard
Uncertainty
Uncertainty
(± %, 1g)
(± %, 10g)
6.55
6.55
Vi
Measurement System
Probe Calibration
∞
Axial Isotropy
4.7
Rectangular
√3
0.707
0.707
1.9
1.9
∞
Hemispherical Isotropy
9.6
Rectangular
√3
0.707
0.707
3.9
3.9
∞
Boundary Effect
2.0
Rectangular
√3
1.2
1.2
∞
Linearity
4.7
Rectangular
√3
2.7
2.7
∞
System Detection Limits
0.25
Rectangular
√3
0.14
0.14
∞
Readout Electronics
0.3
Normal
0.3
0.3
∞
Response Time
0.0
Rectangular
√3
0.0
0.0
∞
Integration Time
1.7
Rectangular
√3
1.0
1.0
∞
RF Ambient Conditions - Noise
3.0
Rectangular
√3
1.7
1.7
∞
RF Ambient Conditions - Reflections
3.0
Rectangular
√3
1.7
1.7
∞
Probe Positioner Mechanical Tolerance
0.4
Rectangular
√3
0.2
0.2
∞
Probe Positioning with Respect to Phantom Shell
6.7
Rectangular
√3
3.9
3.9
∞
4.0
Rectangular
√3
2.3
2.3
∞
Test Sample Positioning
1.5 / 0.7
Normal
1.5
0.7
32
Device Holder Uncertainty
4.2 / 1.8
Normal
4.2
1.8
32
5.0
Rectangular
√3
2.9
2.9
∞
7.6
Rectangular
√3
4.4
4.4
∞
Liquid Conductivity - Deviation from Target Values
5.0
Rectangular
√3
0.64
0.43
1.8
1.2
∞
Liquid Conductivity - Measurement Uncertainty
1.0
Normal
0.64
0.43
0.6
0.4
25
Liquid Permittivity - Deviation from Target Values
5.0
Rectangular
√3
0.60
0.49
1.7
1.4
∞
Liquid Permittivity - Measurement Uncertainty
0.5
Normal
0.60
0.49
0.3
0.2
25
Combined Standard Uncertainty
± 12.3 %
± 11.5 %
Expanded Uncertainty (K=2)
± 24.6 %
± 23.0 %
Extrapolation, interpolation, and integration
algorithms for max. SAR evaluation
Test Sample Related
Output Power Variation - SAR Drift Measurement
Phantom and Tissue Parameters
Phantom Uncertainty (Shape and Thickness
Tolerances)
Uncertainty budget for frequency range 3 GHz to 6 GHz
Report Format Version 5.0.0
Report No. : SA170103W003
Page No.
Issued Date
: 28 of 29
: Mar. 26, 2017
FCC SAR Test Report
7. Information on the Testing Laboratories
We, Bureau Veritas Shenzhen Co., Ltd. Dongguan Branch, were founded in 2002 to provide our best service in EMC,
Radio, Telecom and Safety consultation. Our laboratories are accredited and approved according to ISO/IEC 17025.
If you have any comments, please feel free to contact us at the following:
China Dongguan Lab:
No. 34, Chenwulu Section, Guantai Rd., Houjie Town, Dongguan City, Guangdong 523942, China
Tel: 86-769-8593-5656
Fax: 86-769-8599-1080
Email: service.dg@cn.bureauveritas.com
Web Site: www.adt.com.tw
The road map of all our labs can be found in our web site also.
---END---
Report Format Version 5.0.0
Report No. : SA170103W003
Page No.
Issued Date
: 29 of 29
: Mar. 26, 2017
FCC SAR Test Report
Appendix A. SAR Plots of System Verification
The plots for system verification with largest deviation for each SAR system combination are shown as follows.
Report Format Version 5.0.0
Report No. : SA170103W003
Issued Date
: Mar. 26, 2017
Test Laboratory: Bureau Veritas ADT SAR/HAC Testing Lab
Date: 2017/03/26
System Check_B2450_170326
DUT: Dipole 2450 MHz; Type:D2450V2; SN:893
Communication System: CW; Frequency: 2450 MHz;Duty Cycle: 1:1
Medium: B2450_0326 Medium parameters used: f = 2450 MHz; σ = 1.906 S/m; εr = 51.411; ρ =
1000 kg/m3
Ambient Temperature:22.1 ℃; Liquid Temperature:21.1 ℃
DASY5 Configuration:
- Probe: EX3DV4 - SN3873; ConvF(7.46, 7.46, 7.46); Calibrated: 2016/09/01;
- Sensor-Surface: 2mm (Mechanical Surface Detection)
- Electronics: DAE4 Sn1341; Calibrated: 2016/08/29
- Phantom: ELI v5.0; Type: QDOVA002AA; Serial: TP:1205
- Measurement SW: DASY52, Version 52.8 (8); SEMCAD X Version 14.6.10 (7331)
Pin=250mW/Area Scan (71x81x1): Interpolated grid: dx=1.200 mm, dy=1.200 mm
Maximum value of SAR (interpolated) = 20.0 W/kg
Pin=250mW/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm
Reference Value = 100.7 V/m; Power Drift = 0.06 dB
Peak SAR (extrapolated) = 26.8 W/kg
SAR(1 g) = 12.7 W/kg; SAR(10 g) = 5.75 W/kg
Maximum value of SAR (measured) = 19.3 W/kg
Test Laboratory: Bureau Veritas ADT SAR/HAC Testing Lab
Date: 2017/03/25
System Check_B5250_170325
DUT: Dipole D5GHzV2; Type:D5GHzV2; SN:1133
Communication System: CW; Frequency: 5250 MHz;Duty Cycle: 1:1
Medium: B5G_0325 Medium parameters used: f = 5250 MHz; σ = 5.547 S/m; εr = 48.253; ρ =
1000 kg/m3
Ambient Temperature:22.3 ℃; Liquid Temperature:21.2 ℃
DASY5 Configuration:
- Probe: EX3DV4 - SN3873; ConvF(4.39, 4.39, 4.39); Calibrated: 2016/09/01;
- Sensor-Surface: 1.4mm (Mechanical Surface Detection)
- Electronics: DAE4 Sn1341; Calibrated: 2016/08/29
- Phantom: Left Phantom with CRP v5.0; Type: QD000P40CD; Serial: TP:1722
- Measurement SW: DASY52, Version 52.8 (8); SEMCAD X Version 14.6.10 (7331)
Pin=100mW/Area Scan (91x91x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm
Maximum value of SAR (interpolated) = 16.6 W/kg
Pin=100mW/Zoom Scan (7x7x12)/Cube 0: Measurement grid: dx=4mm, dy=4mm, dz=2mm
Reference Value = 46.25 V/m; Power Drift = 0.05 dB
Peak SAR (extrapolated) = 28.0 W/kg
SAR(1 g) = 7.68 W/kg; SAR(10 g) = 2.16 W/kg
Maximum value of SAR (measured) = 17.4 W/kg
Test Laboratory: Bureau Veritas ADT SAR/HAC Testing Lab
Date: 2017/03/25
System Check_B5800_170325
DUT: Dipole D5GHzV2; Type:D5GHzV2; SN:1133
Communication System: CW; Frequency: 5800 MHz;Duty Cycle: 1:1
Medium: B5G_0325 Medium parameters used: f = 5800 MHz; σ = 6.287 S/m; εr = 47.348; ρ =
1000 kg/m3
Ambient Temperature:22.3 ℃; Liquid Temperature:21.2 ℃
DASY5 Configuration:
- Probe: EX3DV4 - SN3873; ConvF(3.97, 3.97, 3.97); Calibrated: 2016/09/01;
- Sensor-Surface: 1.4mm (Mechanical Surface Detection)
- Electronics: DAE4 Sn1341; Calibrated: 2016/08/29
- Phantom: Left Phantom with CRP v5.0; Type: QD000P40CD; Serial: TP:1722
- Measurement SW: DASY52, Version 52.8 (8); SEMCAD X Version 14.6.10 (7331)
Pin=100mW/Area Scan (91x91x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm
Maximum value of SAR (interpolated) = 16.5 W/kg
Pin=100mW/Zoom Scan (7x7x12)/Cube 0: Measurement grid: dx=4mm, dy=4mm, dz=2mm
Reference Value = 48.11 V/m; Power Drift = 0.04 dB
Peak SAR (extrapolated) = 28.8 W/kg
SAR(1 g) = 7.73 W/kg; SAR(10 g) = 2.16 W/kg
Maximum value of SAR (measured) = 18.0 W/kg
FCC SAR Test Report
Appendix B. SAR Plots of SAR Measurement
The SAR plots for highest measured SAR in each exposure configuration, wireless mode and frequency band
combination, and measured SAR > 1.5 W/kg are shown as follows.
Report Format Version 5.0.0
Report No. : SA170103W003
Issued Date
: Mar. 26, 2017
Test Laboratory: Bureau Veritas ADT SAR/HAC Testing Lab
Date: 2017/03/26
P01 802.11b_Front Face_0cm_Ch11
DUT: 170103W003
Communication System: 802.11b; Frequency: 2462 MHz;Duty Cycle: 1:1
Medium: B2450_0326 Medium parameters used: f = 2462 MHz; σ = 1.921 S/m; εr = 51.373; ρ =
1000 kg/m3
Ambient Temperature:22.1 ℃; Liquid Temperature:21.1 ℃
DASY5 Configuration:
- Probe: EX3DV4 - SN3873; ConvF(7.46, 7.46, 7.46); Calibrated: 2016/09/01;
- Sensor-Surface: 1.4mm (Mechanical Surface Detection)
- Electronics: DAE4 Sn1341; Calibrated: 2016/08/29
- Phantom: ELI v5.0; Type: QDOVA002AA; Serial: TP:1205
- Measurement SW: DASY52, Version 52.8 (8); SEMCAD X Version 14.6.10 (7331)
- Area Scan (81x131x1): Interpolated grid: dx=1.200 mm, dy=1.200 mm
Maximum value of SAR (interpolated) = 0.649 W/kg
- Zoom Scan (5x5x7)/Cube 0: Measurement grid: dx=8mm, dy=8mm, dz=5mm
Reference Value = 6.459 V/m; Power Drift = -0.02 dB
Peak SAR (extrapolated) = 1.00 W/kg
SAR(1 g) = 0.286 W/kg; SAR(10 g) = 0.125 W/kg
Maximum value of SAR (measured) = 0.575 W/kg
Test Laboratory: Bureau Veritas ADT SAR/HAC Testing Lab
Date: 2017/03/25
P02 802.11a_Front Face_0cm_Ch40
DUT: 170103W003
Communication System: 802.11a; Frequency: 5200 MHz;Duty Cycle: 1:1
Medium: B5G_0325 Medium parameters used: f = 5200 MHz; σ = 5.48 S/m; εr = 48.358; ρ =
1000 kg/m3
Ambient Temperature:22.3 ℃; Liquid Temperature:21.2 ℃
DASY5 Configuration:
- Probe: EX3DV4 - SN3873; ConvF(4.39, 4.39, 4.39); Calibrated: 2016/09/01;
- Sensor-Surface: 1.4mm (Mechanical Surface Detection)
- Electronics: DAE4 Sn1341; Calibrated: 2016/08/29
- Phantom: Left Phantom with CRP v5.0; Type: QD000P40CD; Serial: TP:1722
- Measurement SW: DASY52, Version 52.8 (8); SEMCAD X Version 14.6.10 (7331)
- Area Scan (81x141x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm
Maximum value of SAR (interpolated) = 1.11 W/kg
- Zoom Scan (7x7x12)/Cube 0: Measurement grid: dx=4mm, dy=4mm, dz=2mm
Reference Value = 4.748 V/m; Power Drift = -0.00 dB
Peak SAR (extrapolated) = 4.23 W/kg
SAR(1 g) = 0.561 W/kg; SAR(10 g) = 0.184 W/kg
Maximum value of SAR (measured) = 1.52 W/kg
Test Laboratory: Bureau Veritas ADT SAR/HAC Testing Lab
Date: 2017/03/25
P03 802.11a_Front Face_0cm_Ch149
DUT: 170103W003
Communication System: 802.11a; Frequency: 5745 MHz;Duty Cycle: 1:1
Medium: H5G_0325 Medium parameters used: f = 5745 MHz; σ = 6.214 S/m; εr = 47.444; ρ =
1000 kg/m3
Ambient Temperature:22.3 ℃; Liquid Temperature:21.2 ℃
DASY5 Configuration:
- Probe: EX3DV4 - SN3873; ConvF(3.97, 3.97, 3.97); Calibrated: 2016/09/01;
- Sensor-Surface: 1.4mm (Mechanical Surface Detection)
- Electronics: DAE4 Sn1341; Calibrated: 2016/08/29
- Phantom: Left Phantom with CRP v5.0; Type: QD000P40CD; Serial: TP:1722
- Measurement SW: DASY52, Version 52.8 (8); SEMCAD X Version 14.6.10 (7331)
- Area Scan (81x141x1): Interpolated grid: dx=1.000 mm, dy=1.000 mm
Maximum value of SAR (interpolated) = 3.09 W/kg
- Zoom Scan (7x7x12)/Cube 0: Measurement grid: dx=4mm, dy=4mm, dz=2mm
Reference Value = 4.521 V/m; Power Drift = 0.07 dB
Peak SAR (extrapolated) = 7.51 W/kg
SAR(1 g) = 0.882 W/kg; SAR(10 g) = 0.254 W/kg
Maximum value of SAR (measured) = 3.08 W/kg
FCC SAR Test Report
Appendix C. Calibration Certificate for Probe and Dipole
The SPEAG calibration certificates are shown as follows.
Report Format Version 5.0.0
Report No. : SA170103W003
Issued Date
: Mar. 26, 2017

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