ABP-1000 BESEN Test Report Test Report.hwp ARAM Solution Co., Ltd.

ARAM Solution Co., Ltd. BESEN

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STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
TEST REPORT
1. Applicant
Brand Name
: ARAM Solution Co.,Ltd
: N/A
Address
FCC ID
: 2AAVTABP-1000
Name
Model No.
Variant Model No.
Manufacturer
Address
Name
2. Products
3. Test Standard
4.
5.
6.
7.
8.
Test Method
Test Result
Dates of Test
Date of Issue
Test Laboratory
Venture-dong #202, jeonbuk technopark,109, Ballyong-ro,
Deokjin-gu, Jeonju-si, Jeollabuk-do, Korea
BESEN
ABP-1000
N/A
ARAM Solution Co.,Ltd
Venture-dong #202, jeonbuk technopark,109, Ballyong-ro,
Deokjin-gu, Jeonju-si, Jeollabuk-do, Korea
: 47 CFR Part 15, Subpart C
: ANSI C63.10-2013
: PASS
: December 08, 2016 to December 14, 2016
: December 16, 2016
: Standard Engineering Co. Ltd.
FCC Designation Number : 624439
Tested by
Approved by
SoonHo, Kim / Test Engineer
SeongSeok, Seo / Compliance Engineer
This report may not be reproduced without the full written consent of
Standard Engineering Laboratory.
Standard Engineering Co. Ltd.
377-11, Sinjang-ri, Eumam-myeon, Seosan-si,
ChoongNam 356-844, South Korea
Tel.: +82-41-663-9436, Fax :+82-41-663-9434
www.stdeng.com
Page 1/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
1. Test Summary
Test
Antenna Requirement
AC Power Line
Conducted
Emission
Test Requirement
47 CFR Part 15, Subpart C
Section 15.203/15.247 (c)
47 CFR Part 15, Subpart C
Section 15.207
Conducted Peak Output 47 CFR Part 15, Subpart C
Test method
Result
ANSI C63.10 2013
PASS
ANSI C63.10 2013
PASS
KDB558074 D01
Power
Section 15.247 (b)(3)
v03r05
6dB Occupied
47 CFR Part 15, Subpart C
KDB558074 D01
Bandwidth
Section 15.247 (a)(2)
v03r05
47 CFR Part 15, Subpart C
KDB558074 D01
Section 15.247 (e)
v03r05
Band-edge for RF
47 CFR Part 15, Subpart C
KDB558074 D01
Conducted Emissions
Section 15.247(d)
v03r05
Power Spectral Density
RF Conducted Spurious 47 CFR Part 15, Subpart C
Emissions
Section 15.247(d)
Radiated Spurious
47 CFR Part 15, Subpart C
Emissions
Section 15.205/15.209
Band Edge (Radiated
47 CFR Part 15, Subpart C
Emission)
Section 15.205/15.209
Page 2/49
KDB558074 D01
v03r05
PASS
PASS
PASS
PASS
PASS
ANSI C63.10 2013
PASS
ANSI C63.10 2013
PASS
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
2. TABLE OF CONTENTS
1. Test Summary...........................................................................................................................................................2
2. Table of Contents....................................................................................................................................................3
3. General Information...............................................................................................................................................4
3.1 Client Information............................................................................................................................................4
3.2 General Description of E.U.T........................................................................................................................4
3.3 Details of E.U.T..................................................................................................................................................4
3.4 Operation Frequency each of channel.....................................................................................................5
3.5 Description of Support Units ......................................................................................................................5
3.6 Duty Cycle Of Test signal.............................................................................................................................6
3.7 Abnormalities from Standard Conditions...............................................................................................6
3.8 Other Information Requested by the Customer..................................................................................6
3.9 Test Location.....................................................................................................................................................6
4. Equipment Used during Test..............................................................................................................................7
5. Test Results and Measurement Data...............................................................................................................8
5.1 Antenna Requirement....................................................................................................................................8
5.2 Conducted Peak Output Power..................................................................................................................9
5.3 6dB Occupy Bandwidth...............................................................................................................................13
5.4 Power Spectral Density...............................................................................................................................16
5.5 Band-edge for RF Conducted Emissions..............................................................................................19
5.6 RF Conducted Spurious Emissions..........................................................................................................21
5.7 Radiated Spurious Emissions....................................................................................................................25
5.7.1Harmonic and other spurious emissions........................................................................................29
5.7.1.1 Test at Lowest Channel in transmitting status..........................................................................29
5.7.1.2 Test at middle Channel in transmitting status..........................................................................32
5.7.1.3 Test at Highest Channel in transmitting status........................................................................35
5.8 Band Edge (Radiated Emission)...............................................................................................................38
5.9 Conducted Emissions at Mains Terminals 150 kHz to 30 MHz....................................................43
5.9.1 Measurement Data................................................................................................................................45
5.10 Radio Frequency Exposure Procedures..............................................................................................47
** APPENDIX............................................................................................................................................................49
Page 3/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
3. General Information
3.1. Client Information
Applicant
: ARAM Solution Co.,Ltd
Address of Applicant : Venture-dong #202, jeonbuk technopark,109, Ballyong-ro,
Deokjin-gu, Jeonju-si, Jeollabuk-do, Korea
3.2. General Description of E.U.T.
Product Name
BESEN
Model No.
ABP-1000
3.3. Details of E.U.T.
Operation Frequency : 2402 MHz to 2480 MHz
Wireless Type
: Bluetooth
Channel Numbers
: 40 Channels
Channel Spacing
: 2MHz
Type of Modulation
: GFSK
Antenna Type
: Pattern Antenna
Antenna Gain
: -0.68 dBi
Test Software
: nrfgostudio_win-64_1.21.2_installer
Power Supply
: DC 5.0 V
Test Voltage
: DC 5.0 V
Page 4/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
3.4. Operation Frequency each of channel
Channel Frequency Channel Frequency Channel Frequency Channel Frequency
2402MHz
11
2422MHz
21
2442MHz
31
2462MHz
2404MHz
12
2424MHz
22
2444MHz
32
2464MHz
2406MHz
13
2426MHz
23
2446MHz
33
2466MHz
2408MHz
14
2428MHz
24
2448MHz
34
2468MHz
2410MHz
15
2430MHz
25
2450MHz
35
2470MHz
2412MHz
16
2432MHz
26
2452MHz
36
2472MHz
2414MHz
17
2434MHz
27
2454MHz
37
2474MHz
2416MHz
18
2436MHz
28
2456MHz
38
2476MHz
2418MHz
19
2438MHz
29
2458MHz
39
2478MHz
10
2420MHz
20
2440MHz
30
2460MHz
40
2480MHz
Note:
In section 15.31(m), regards to the operating frequency range over 10 MHz, the Lowest
frequency, the middle frequency, and the highest frequency of channel were selected to
perform the test, and the selected channel see below:
Channel
Frequency
Lowest channel
2402MHz
Middle channel
2440MHz
Highest channel
2480MHz
3.5. Description of Support Units
The EUT has been tested with corresponding accessories as below:
Supplied by Standard Engineering Laboratory.:
Description
Manufacturer
Model No.
Serial No.
NoteBook
LG
SD550
308QCZP556717
USB Cable
JVE-M2
E232940
PWS-5005D
205050
Jig
Power Supply
NORDIC
SEMICONDUCTOR
Provice
Page 5/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
3.6. Duty Cycle Of Test signal
Duty cycle is <93%, duty factor shall be considered. Duty cycle=Tx on/(Tx on+Tx off),
Duty factor=10*log(1/duty cycle)
Band
2.4 GHz band
Rate
1 Byte
Duty cycle
0.206
Duty Cycle Factor
6.86
3.7. Abnormalities from Standard Conditions
None.
3.8. Other Information Requested by the Customer
None.
3.9. Test Location
377-11, Sinjang-ri, Eumam-myeon, Seosan-si, ChoongNam 356-844, South Korea
(FCC Designation Number : 624439)
This test site is in compliance with ISO/IEC 17025 for general requirements for the competence
of testing and calibration laboratories.
Page 6/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
4. Equipment Used during Test
No.
Test Equipment
Manufacturer
Model No.
Serial No.
Cal. Date
Next
Cal. Data
Used
equipment
EMI Test Receiver
LIG
LSA-265
L07098033
03/08/2016 03/08/2017
■
EMI Test Receiver
Rhode & Schwarz
ESIB7
3311
02/11/2016 02/11/2017
■
Bi-log Antenna
Schwarzbeck
VULB9163
164
09/15/2014 09/30/2017
■
Loop Antenna
EMCO
6502
9206-2769
01/28/2016 01/28/2018
■
Spectrum Analyzer
Agilent
E4440A
US45303130 01/26/2016 01/26/2017
■
Frequency Counter
HP
5347A
3009A02742 01/26/2016 01/26/2017
□
Attenuator
Agilent
8495B
3308A22485 01/26/2016 01/26/2017
□
Power Meter
Agilent
E4418B
MY405111655 01/26/2016 01/26/2017
□
Power Sensor
HP
8485A
2347A02746 01/26/2016 01/26/2017
□
10
RF Cable
11
Signal Generator
HP
83630A
3420A00728 01/26/2016 01/26/2017
□
12
Oscilloscope
HP
54815A
US38380122 01/26/2016 01/26/2017
□
13
Pre Amplifier
Agilent
8449B
3008A02105 01/26/2016 01/26/2017
■
14
Signal Generator
Rhode & Schwarz
SML03
102330
01/26/2016 01/26/2017
□
15
Power Divider
Agilent
11636B
50309
01/26/2016 01/26/2017
□
16
Power Sensor
Seoksan Tech
SE-CT-02
S7400JD53406
01/26/2016 01/26/2017
18
□
17
DC Power Supply
HP
6032A
US35420383 01/26/2016 01/26/2017
■
18
Slidacs
Sunchang Electrics
5KV
N/A
01/26/2016 01/26/2017
□
19
Bandreject Filter
K&L Microwave
50140
555
01/26/2016 01/26/2017
□
20
Horn Antenna
Schwarzbeck
BBHA9120A
346
02/05/2016 02/05/2018
■
21
Horn Antenna
A.H. SYSTEMS
SAS-572
269
09/03/2015 09/03/2017
■
22
DC Power Supply
Provice
PWS-5005D
205050
01/26/2016 01/26/2017
■
23
Pulse Limiter
Rhode & Schwarz
ESH3-Z2
100137
11/10/2016 11/10/2017
■
24
LISN
Rhode & Schwarz
ESH3-Z5
11/10/2016 11/10/2017
■
Gigalane
SMS102-MF1
41-SMS102-1.0 PB1252301285
Page 7/49
100204
N/A
N/A
■
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5. Test Results and Measurement Data
5.1. Antenna Requirement
Standard requirement: 47 CFR Part 15C Section 15.203 /247(c)
15.203 requirement:
An intentional radiator shall be designed to ensure that no antenna other than that
furnished by the responsible party shall be used with the device. The use of a permanently
attached antenna or of an antenna that uses a unique coupling to the intentional radiator,
the manufacturer may design the unit so that a broken antenna can be replaced by the
user, but the use of a standard antenna jack or electrical connector is prohibited.
15.247(b) (4) requirement:
The conducted output power limit specified in paragraph (b) of this section is based on the
use of antennas with directional gains that do not exceed 6 dBi. Except as shown in
paragraph (c) of this section, if transmitting antennas of directional gain greater than 6 dBi
are used, the conducted output power from the intentional radiator shall be reduced
below the stated values in paragraphs (b)(1), (b)(2), and (b)(3) of this section, as
appropriate, by the amount in dB that the directional gain of the antenna exceeds 6 dBi.
EUT Antenna
PASS
The transmitter has an Internal Pattern antenna. The directional gain of the antenna is
-0.68 dBi. please refer to the EUT Internal photos and Antenna gain.
Page 8/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.2. Conducted Peak Output Power
Test Requirement:
47 CFR Part 15C Section 15.247 (b)(3)
Test Method:
KDB558074 D01 v03r05
Test Configuration:
Test Instruments:
Refer to section 4.10 for details
Exploratory Test
Transmitting mode
Mode:
Final Test Mode:
Non-hopping transmitting with GFSK modulation
Limit:
30dBm
Test Results:
Pass
Measurement Data
Peak Power
Test channel
Lowest
Middle
Highest
Peak Output Power (dBm)
3.25
2.11
0.38
Test channel
Conducted
Power
(dBm)
Lowest
Middle
Highest
-4.19
-6.10
-6.94
Limit (dBm)
30.00
30.00
30.00
Average Power
Final
Duty Cycle
Conducted
Factor
Power
(dBm)
6.86
2.67
6.86
0.76
6.86
-0.08
Page 9/49
Result
Pass
Pass
Pass
Limit (dBm)
Result
30.00
30.00
30.00
Pass
Pass
Pass
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Result plot as follows:
Test mode: Peak Power
Lowest Channel:
Middle Channel:
Page 10/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Highest Channel:
Result plot as follows:
Test mode: Average Power
Lowest Channel:
Page 11/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Middle Channel:
Highest Channel:
Page 12/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.3. 6dB Occupy Bandwidth
Test Requirement:
47 CFR Part 15C Section 15.247 (a)(2)
Test Method:
KDB558074 D01 v03r05
Test Configuration:
Instruments Used:
Refer to section 4.10 for details
Exploratory Test Mode:
Transmitting mode
Final Test Mode:
Non-hopping transmitting with GFSK modulation
Limit:
≥ 500 kHz
Test Results:
Pass
Measurement Data
Lowest
6dB Occupy Bandwidth
(kHz)
752
Middle
714
≥ 500
Pass
Highest
731
≥ 500
Pass
Test channel
Page 13/49
Limit (kHz)
Result
≥ 500
Pass
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Result plot as follows:
Test mode: GFSK
Lowest Channel:
Middle Channel:
Page 14/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Highest Channel:
Page 15/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.4. Power Spectral Density
Test Requirement:
47 CFR Part 15C Section 15.247 (e)
Test Method:
KDB558074 D01 v03r05
Test Configuration:
Test Instruments:
Refer to section 4.10 for details
Exploratory Test
Transmitting mode
Mode:
Final Test Mode:
Non-hopping transmitting with GFSK modulation
Limit:
≤8dBm/3kHz
Test Results:
Pass
Measurement Data
Test channel
Lowest
Middle
Highest
GFSK mode
Power Spectral Density
Limit
(dBm/3kHz)
(dBm/3kHz)
-10.39
≤8 dBm/3kHz
-11.01
≤8 dBm/3kHz
-12.51
≤8 dBm/3kHz
Page 16/49
Result
Pass
Pass
Pass
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Result plot as follows:
Test mode: GFSK
Lowest Channel:
Middle Channel:
Page 17/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Highest Channel:
Page 18/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.5. Band-edge for RF Conducted Emissions
Test Requirement:
FCC Part15 C section 15.247 (d)
Test Method:
KDB558074 D01 v03r05
Test Configuration:
Exploratory Test Mode:
Transmitting mode
Final Test Mode:
Non-hopping transmitting with GFSK modulation
Limit:
In any 100 kHz bandwidth outside the frequency band in which
the spread spectrum intentional radiator is operating, the radio
frequency power that is produced by the intentional radiator
shall be at least 20 dB below that in the 100 kHz bandwidth
within the band that contains the highest level of the desired
power, based on either an RF conducted or a radiated
measurement.
Instruments Used:
Refer to section 4.10 for details
Test Results:
Pass
Page 19/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Result plot as follows:
Test mode: GFSK
Lowest Channel:
Highest Channel:
Page 20/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.6. RF Conducted Spurious Emissions
Test Requirement:
47 CFR Part 15C Section 15.247 (d)
Test Method:
KDB558074 D01 v03r05
Test Configuration:
Exploratory Test Mode:
Transmitting mode
Final Test Mode:
Non-hopping transmitting with GFSK modulation
Limit:
In any 100 kHz bandwidth outside the frequency band in which
the spread spectrum intentional radiator is operating, the radio
frequency power that is produced by the intentional radiator
shall be at least 20 dB below that in the 100 kHz bandwidth
within the band that contains the highest level of the desired
power, based on either an RF conducted or a radiated
measurement.
Instruments Used:
Refer to section 4.10 for details
Test Results:
Pass
Page 21/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Result plot as follows:
Test mode: GFSK
Lowest Channel:
Page 22/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Middle Channel:
Page 23/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Highest Channel:
Page 24/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.7. Radiated Spurious Emissions
Test equirement:
47 CFR Part 15C Section 15.209 and 15.205
Test Method:
ANSI C63.10 2013
Test Site:
Measurement Distance: 3m
Receiver Setup:
Frequency
Detector
RBW
VBW
Remark
0.009MHz-0.090MHz
Peak
10kHz
30kHz
Peak
0.009MHz-0.090MHz
Average
10kHz
30kHz
Average
0.090MHz-0.110MHz
Quasi-peak
10kHz
30kHz
Quasi-peak
0.110MHz-0.490MHz
Peak
10kHz
30kHz
Peak
0.110MHz-0.490MHz
Average
10kHz
30kHz
Average
0.490MHz -30MHz
Quasi-peak
10kHz
30kHz
Quasi-peak
30MHz-1GHz
Quasi-peak
100kHz
300kHz
Quasi-peak
Peak
1MHz
3MHz
Peak
Peak
1MHz
10Hz
Average
Field strength
Limit
(microvolt/meter)
(dBuV/m)
0.009MHz-0.490MHz
2400/F(kHz)
300
0.490MHz-1.705MHz
24000/F(kHz)
30
1.705MHz-30MHz
30
30
30MHz-88MHz
100
40.0
Quasi-peak
88MHz-216MHz
150
43.5
Quasi-peak
216MHz-960MHz
200
46.0
Quasi-peak
960MHz-1GHz
500
54.0
Quasi-peak
Above 1GHz
500
54.0
Average
Above 1GHz
Frequency
Limit:
Remark
Measurement
distance (m)
Note:
15.35(b), Unless otherwise specified, the limit on peak radio frequency emissions is
20dB above the maximum permitted average emission limit applicable to the
equipment under test. This peak limit applies to the total peak emission level radiated
by the device.
Page 25/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Test Configuration:
1) 9 kHz to 30 MHz emissions:
2) 30 MHz to 1 GHz emissions:
Page 26/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
3) 1 GHz to 25 GHz emissions:
a. For below 1GHz, the EUT was placed on the top of a rotating table 0.8
meters above the ground at a 3 meter OATS. The table was rotated 360
degrees to determine the position of the highest radiation.
b. For above 1GHz, the EUT was placed on the top of a rotating table 1.5
meters above the ground at a 3 meter anechoic chamber. The table was
rotated 360 degrees to determine the position of the highest radiation.
c. The EUT was set 3 meters away from the interference-receiving
antenna, which was mounted on the top of a variable-height antenna
Test Procedure:
tower.
d. The antenna height is varied from one meter to four meters above the
ground to determine the maximum value of the field strength. Both
horizontal and vertical polarizations of the antenna are set to make the
measurement.
d. The antenna height is varied from one meter to four meters above the
ground to determine the maximum value of the field strength. Both
horizontal and vertical polarizations of the antenna are set to make the
measurement.
Page 27/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
e. For each suspected emission, the EUT was arranged to its worst case
and then the antenna was tuned to heights from 1 meter to 4 meters (for
the test frequency of below 30MHz, the antenna was tuned to heights 1
meter) and the rotatable table was turned from 0 degrees to 360
degrees to find the maximum reading.
f. The test-receiver system was set to Peak Detect Function and Specified
Bandwidth with Maximum Hold Mode.
g. If the emission level of the EUT in peak mode was 10dB lower than the
Test Procedure:
limit specified, then testing could be stopped and the peak values of the
EUT would be reported. Otherwise the emissions that did not have 10dB
margin would be re-tested one by one using peak, quasi-peak or
average method as specified and then reported in a data sheet.
h. Test the EUT in the lowest channel (2402MHz),the middle channel
(2440MHz),the Highest channel (2480MHz)
i. The radiation measurements are performed in X, Y, Z axis positioning
for Transmitting mode, and found the X axis positioning which it is the
worst case.
j. Repeat above procedures until all frequencies measured was complete.
Test Mode:
Transmitting mode.
Test Results:
Pass
Page 28/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.7.1. Harmonic and other spurious emissions
5.7.1.1. Test at Lowest Channel in transmitting status
9 kHz~30 MHz Field Strength of Unwanted Emissions. Quasi-Peak Measurement
The measurements with active loop antenna were greater than 20dB below the limit, so
the test data were not recorded in the test report.
30 MHz~1 GHz Spurious Emissions. Quasi-Peak Measurement
Test Mode: GFSK
Test channel: Lowest
Vertical:
Level (dBμV/m)
Quasi-peak measurement
Frequency
(MHz)
Detect
Mode
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
56.70
QP
33.31
6.18
27.13
40.0
61.80
QP
34.39
5.65
28.74
40.0
152.28
QP
32.81
11.88
20.93
43.5
342.68
QP
29.37
16.62
12.75
46.0
481.45
QP
37.47
20.38
17.09
46.0
609.31
QP
37.79
23.03
14.76
46.0
719.27
QP
42.14
24.40
17.74
46.0
Page 29/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Horizontal:
Level (dBμV/m)
Quasi-peak measurement
Frequency
(MHz)
Detect
Mode
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
58.18
QP
33.12
5.82
27.30
40.0
63.97
QP
34.14
5.97
28.17
40.0
113.81
QP
28.88
11.68
17.20
43.5
166.08
QP
37.92
11.12
26.80
46.0
236.71
QP
37.01
13.33
23.68
46.0
480.73
QP
39.66
20.36
19.30
46.0
719.97
QP
44.97
24.41
20.56
46.0
899.99
QP
44.30
26.65
17.65
46.0
Page 30/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
1~25 GHz Harmonics & Spurious Emissions. Peak & Average Measurement
Peak / Average Measurement:
Frequency
(MHz)
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Amplifier
Gain
(dB)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
The amplitude of spurious emissions that are attenuated by more
than 20 dB below the permissible value has no need to be reported.
Page 31/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.7.1.2. Test at middle Channel in transmitting status
9 kHz~30 MHz Field Strength of Unwanted Emissions. Quasi-Peak Measurement
The measurements with active loop antenna were greater than 20dB below the limit, so
the test data were not recorded in the test report.
30 MHz~1 GHz Spurious Emissions. Quasi-Peak Measurement
Test Mode: GFSK
Test channel: Middle
Vertical:
Level (dBμV/m)
Quasi-peak measurement
Frequency
(MHz)
Detect
Mode
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
57.07
QP
33.47
6.09
27.38
40.0
64.71
QP
32.16
6.07
26.09
40.0
152.34
QP
33.63
11.87
21.76
43.5
228.45
QP
32.84
12.63
20.21
46.0
478.18
QP
37.17
20.29
16.88
46.0
609.30
QP
39.37
23.03
16.34
46.0
718.20
QP
44.14
24.38
19.76
46.0
Page 32/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Horizontal:
Level (dBμV/m)
Quasi-peak measurement
Frequency
(MHz)
Detect
Mode
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
58.54
QP
29.12
5.74
23.38
40.0
64.69
QP
32.62
6.07
26.55
40.0
151.84
QP
34.99
11.90
23.09
43.5
237.07
QP
35.55
13.36
22.19
46.0
480.71
QP
36.67
20.36
16.31
46.0
719.61
QP
42.37
24.40
17.97
46.0
900.03
QP
42.64
26.65
15.99
46.0
Page 33/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
1~25 GHz Harmonics & Spurious Emissions. Peak & Average Measurement
Peak / Average Measurement:
Frequency
(MHz)
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Amplifier
Gain
(dB)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
The amplitude of spurious emissions that are attenuated by more
than 20 dB below the permissible value has no need to be reported.
Page 34/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.7.1.3. Test at Highest Channel in transmitting status
9 kHz~30 MHz Field Strength of Unwanted Emissions. Quasi-Peak Measurement
The measurements with active loop antenna were greater than 20dB below the limit, so
the test data were not recorded in the test report.
30 MHz~1 GHz Spurious Emissions. Quasi-Peak Measurement
Test Mode: GFSK
Test channel: Highest
Vertical:
Level (dBμV/m)
Quasi-peak measurement
Frequency
(MHz)
Detect
Mode
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
57.08
QP
33.19
6.09
27.10
40.0
63.66
QP
33.28
5.92
27.36
40.0
152.33
QP
33.03
11.87
21.16
43.5
228.49
QP
31.49
12.63
18.86
46.0
380.76
QP
32.23
17.68
14.55
46.0
480.72
QP
37.37
20.36
17.01
46.0
609.27
QP
37.55
23.03
14.52
46.0
720.00
QP
42.26
24.41
17.85
46.0
Page 35/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Horizontal:
Level (dBμV/m)
Quasi-peak measurement
Frequency
(MHz)
Detect
Mode
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
57.84
QP
29.66
5.91
23.75
40.0
63.97
QP
31.28
5.97
25.31
40.0
151.72
QP
36.76
11.91
24.85
43.5
238.89
QP
33.19
13.52
19.67
46.0
479.99
QP
40.07
20.34
19.73
46.0
719.25
QP
42.13
24.40
17.73
46.0
899.99
QP
42.62
26.65
15.97
46.0
Page 36/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
1~25 GHz Harmonics & Spurious Emissions. Peak & Average Measurement
Peak / Average Measurement:
Frequency
(MHz)
Polarization
(V/H)
Measured
Value
(dB㎶)
Antenna Factor
Cable Loss
(dB/m)
Amplifier
Gain
(dB)
Emission
Level
(dB㎶/m)
Limit
(dB㎶/m)
The amplitude of spurious emissions that are attenuated by more
than 20 dB below the permissible value has no need to be reported.
Remark:
1). The field strength is calculated by adding the Antenna Factor. Cable Factor & Preamplifier.
The basic equation with a sample calculation is as follows:
Emission = Measured Value + Antenna Factor + Cable Loss –Amplifier Gain.
2). As shown in Section, for frequencies above 1000 MHz. the above field strength limits are
based on average limits. However, the peak field strength of any emission shall not exceed the
maximum permitted average limits specified above by more than 20 dB under any condition
of modulation.
3). The test only perform the EUT in transmitting status since the test frequencies were over
1GHz only required transmitting status.
Page 37/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.8. Band Edge (Radiated Emission)
Test
Requirement:
FCC Part15 C Section 15.247
(d) In addition, radiated emissions which fall in the restricted bands. as
defined in Section 15.205(a), must also comply with the radiated
emission limits specified in Section 15.209(a) (see Section 15.205(c)).
Test Method:
ANSI C63.10: 2013
Measurement
3m
Limit:
Section 15.209(a)
40.0 dBμV/m between 30MHz & 88MHz; Quasi-peak Value
43.5 dBμV/m between 88MHz & 216MHz; Quasi-peak Value
46.0 dBμV/m between 216MHz & 960MHz; Quasi-peak Value
54.0 dBμV/m between 960MHz.& 1GHz; Quasi-peak Value
54.0 dBμV/m Above 1GHz; Average Value
74.0 dBμV/m Above 1GHz; Peak Value
Test Procedure:
a. The EUT was placed on the top of a rotating table 0.8 meters above
the ground at a 3 meter semi-anechoic camber. The table was rotated
360 degrees to determine the position of the highest radiation.
b. The EUT was set 3 meters away from the interference-receiving
antenna, which was mounted on the top of a variable-height antenna
tower.
c. The antenna height is varied from one meter to four meters above the
ground to determine the maximum value of the field strength. Both
horizontal and vertical polarizations of the antenna are set to make the
measurement.
d. For each suspected emission, the EUT was arranged to its worst case
and then the antenna was tuned to heights from 1 meter to 4 meters
and the rotatable table was turned from 0 degrees to 360 degrees to
find the maximum reading.
e. The test-receiver system was set to Peak Detect Function and
Specified Bandwidth with Maximum Hold Mode.
f. Place a marker at the end of the restricted band closest to the transmit
frequency to show compliance. Also measure any emissions in the
restricted bands. Save the spectrum analyzer plot. Repeat for each
power and modulation for lowest and highest channel
g. Test the EUT in the lowest channel , the Highest channel
h. The radiation measurements are performed in X, Y, Z axis positioning.
And found the X axis positioning which it is worse case, only the test
worst case mode is recorded in the report.
i. Repeat above procedures until all frequencies measured was complete.
Page 38/49
STANDARD
ENGINEERING
Exploratory Test
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Transmitting mode
Mode:
Final Test Mode:
Non-hopping transmitting with GFSK modulation
Instruments Used:
Refer to section 4.10 for details
Test Results:
Pass
Page 39/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Measurement Result:
Lowest Channel , Horizontal , Peak/Average Detector
High Channel , Horizontal , Peak/Average Detector
Page 40/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Low Channel , Vertical , Peak/Average Detector
High Channel , Vertical , Peak/Average Detector
Page 41/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Section 15.205 Restricted bands of operation.
(a) Except as shown in paragraph (d) of this section. only spurious emissions are permitted in
any of the frequency bands listed below:
Page 42/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.9. Conducted Emissions at Mains Terminals 150 kHz to 30 MHz
Test Requirement:
FCC Part 15 C section 15.207
Test Method: ANSI C63.10:
ANSI C63.10: 2013
Frequency Range:
150 kHz to 30 MHz
Detector:
Peak for pre-scan (9 kHz Resolution Bandwidth)
Test Limit
EUT Operation:
Test in normal operating mode. For intentional radiators,
measurements of the variation of the input power or the radiated
signal level of the fundamental frequency component of the emission,
as appropriate, shall be performed with the supply voltage varied
between 85% and 115% of the nominal rated supply voltage.
Pre-Scan has been conducted to determine the worst-case mode
from all possible combinations between available modulations, data
rates and antenna ports (if EUT with antenna diversity architecture).
Page 43/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Test Configuration:
Test procedure:
1. The mains terminal disturbance voltage test was conducted in a shielded room.
2. The EUT was connected to AC power source through a LISN 1 (Line Impedance Stabilization
Network) which provides a 50/50μH + 5linear impedance. The power cables of all other units
of the EUT were connected to a second LISN 2, which was bonded to the ground reference
plane in the same way as the LISN 1 for the unit being measured. A multiple socket outlet strip
was used to connect multiple power cables to a single LISN provided the rating of the LISN was
not exceeded.
3. The tabletop EUT was placed upon a non-metallic table 0.8m above the ground reference
plane. And for floor-standing arrangement, the EUT was placed on the horizontal ground
reference plane, but separated from metallic contact with the ground reference plane by 0.1m
of insulation.
4. The test was performed with a vertical ground reference plane. The rear of the EUT shall be
0,4 m from the vertical ground reference plane. The vertical ground reference plane was
bonded to the horizontal ground reference plane. The LISN 1 was placed 0,8 m from the
boundary of the unit under test and bonded to a ground reference plane for LISNs mounted
on top of the ground reference plane. This distance was between the closest points of the LISN
1 and the EUT. All other units of the EUT and associated equipment was at least 0,8 m from the
LISN 2.
5) In order to find the maximum emission, the relative positions of equipment and all of the
interface cables must be changed according to ANSI C63.10: 2009 on conducted
measurement.
Page 44/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.9.1. Measurement Data
Pre-scan was performed with peak detected on all ports, Quasi-peak & average
measurements were performed at the frequencies at which maximum peak emission level
were detected. Please see the attached Quasi-peak and Average test results.
Line - PE(QusiPeak and Average detector used)
REDUCTION TABLE
No
Freq
Level
Corr
Limit
Margin
State
Reference
10
11
12
13
14
(MHz)
0.180
0.273
0.378
0.473
2.000
16.527
27.468
0.180
0.273
0.378
0.473
2.000
16.527
27.468
(dBuV)
47.90
37.79
33.59
29.91
28.19
30.19
31.24
27.71
20.51
21.07
20.53
19.16
19.71
23.31
(dB)
10.06
9.96
10.94
9.98
10.12
10.92
11.31
10.06
9.96
10.94
9.98
10.12
10.92
11.31
(dBuV)
64.49
61.03
58.33
56.46
56.00
60.00
60.00
54.49
51.03
48.33
46.46
46.00
50.00
50.00
(dB)
16.59
23.24
24.74
26.55
27.81
29.81
28.76
26.78
30.52
27.26
25.93
26.84
30.29
26.69
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
QP
QP
QP
QP
QP
QP
QP
AV
AV
AV
AV
AV
AV
AV
Page 45/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Neutral – PE(QusiPeak and Average detector used)
REDUCTION TABLE
No
Freq
Level
Corr
Limit
Margin
State
Reference
10
11
12
13
14
(MHz)
0.163
0.715
1.232
3.547
4.793
17.476
26.340
0.163
0.715
1.232
3.547
4.793
17.476
26.340
(dBuV)
48.89
23.94
27.98
29.45
26.75
28.72
32.00
27.47
17.28
21.57
20.18
16.60
17.94
25.04
(dB)
10.15
9.99
10.04
10.18
10.25
10.80
11.05
10.15
9.99
10.04
10.18
10.25
10.80
11.05
(dBuV)
65.31
56.00
56.00
56.00
56.00
60.00
60.00
55.31
46.00
46.00
46.00
46.00
50.00
50.00
(dB)
16.42
32.06
28.02
26.55
29.25
31.28
28.00
27.84
28.72
24.43
25.82
29.40
32.06
24.96
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
Pass
QP
QP
QP
QP
QP
QP
QP
AV
AV
AV
AV
AV
AV
AV
Measurement data:
* Detector function was set into Quasi-peak & Average mode.
* Corr = LISN Factor + Cable loss + Pulse Limiter
Page 46/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
5.10. Radio Frequency Exposure Procedures
Regulation
According to §2.1091, §2.1093 and §1.1307(b), systems operating under the provisions of
this section shall be operated in a manner that ensures that the public is not exposed to
radio frequency energy level in excess of the Commission’'s guidelines.
Note 1 to Table 1: Occupational/controlled limits apply in situations in which persons are
exposed as a consequence of their employment provided those persons are fully aware of the
potential for exposure and can exercise control over their exposure. Limits for
occupational/controlled exposure also apply in situations when an individual is transient
through a location where occupational/controlled limits apply provided he or she is made
aware of the potential for exposure.
The S = PG / (4πR²)
Where S = power density in mW/cm²
P = transmit power in mW
G = numeric gain of transmit antenna (numeric gain=Log-1(dB antenna gain/10))
R = distance (cm)
The calculations in the table below use the highest gain of antenna for client EUT. These
calculations represent worst case in terms of the exposure levels.
Page 47/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
Measurement Data
Channel
Frequency
Power
Antenna
Gain
Numeric
antenna
gain
Limits
(MHz)
(dBm)
(mW)
(dBi)
(mW)
(cm)
(mW/cm2)
(mW/cm2)
2402
2440
2480
3.25
2.11
0.38
2.113
1.626
1.091
-0.68
-0.68
-0.68
0.855
0.855
0.855
20
20
20
0.00035
0.00027
0.00018
1.0
1.0
1.0
Note: 1.0 mW/cm² from 1.310 §Table 1
The worst MPE = 0.00035 mW/cm² < 1.0 mW/cm².
Conclusion : The SAR measurement is exempt.
Page 48/49
STANDARD
ENGINEERING
FCC ID : 2AAVTABP-1000
Report Number : STD-FCC-16080
APPENDIX
1. EUT photo
Page 49/49
Download: ABP-1000 BESEN Test Report Test Report.hwp ARAM Solution Co., Ltd.
Mirror Download [FCC.gov]ABP-1000 BESEN Test Report Test Report.hwp ARAM Solution Co., Ltd.
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