TEST REPORT

Report Overview

Remarks: The results shown in this test report refer only to the sample(s) tested. This test report cannot be reproduced, except in full, without prior written permission of Waltek Testing Group (Shenzhen) Co., Ltd. The report would be invalid without specific stamp of test institute and the signatures of compiler and approver.

Prepared By:

Waltek Testing Group (Shenzhen) Co., Ltd.
Address: 1/F., Room 101, Building 1, Hongwei Industrial Park, Liuxian 2nd Road, Block 70 Bao'an District, Shenzhen, Guangdong, China
Tel.: +86-755-33663308
Fax.: +86-755-33663309

Waltek Testing Group (Shenzhen) Co., Ltd. http://www.semtest.com.cn

Report Version

1. GENERAL INFORMATION

1.1 Product Description for Equipment Under Test (EUT)

Client Information

General Description of EUT

Note: The test data is gathered from a production sample, provided by the manufacturer. The appearance of other models listed in the report is different from main-test model SM-824D2, but the circuit and the electronic construction do not change, declared by the manufacturer.

Technical Characteristics of EUT

1.2 Test Standards

The tests were performed according to following standards:

• FCC Rules Part 15.247: Frequency Hopping, Direct Spread Spectrum and Hybrid Systems that are in operation within the bands of 902-928 MHz, 2400-2483.5 MHz, and 5725-5850 MHz.
• 558074 D01 15.247 Meas Guidance v05r02: Guidance for Compliance Measurements on Digital Transmission System, Frequency Hopping Spread Spectrum System, and Hybrid System Devices Operating under section 15.247 of the FCC rules.
• ANSI C63.10-2013: American National Standard for Testing Unlicensed Wireless Devices.

Maintenance of compliance is the responsibility of the manufacturer. Any modification of the product, which result in lowering the emission, should be checked to ensure compliance has been maintained.

1.3 Test Methodology

All measurements contained in this report were conducted with ANSI C63.10-2013, KDB 558074 D01 15.247 Meas Guidance v05r02.

The equipment under test (EUT) was configured to measure its highest possible emission level. The test modes were adapted accordingly in reference to the Operating Instructions.

1.4 Test Facility

Address of the test laboratory

Laboratory: Waltek Testing Group (Shenzhen) Co., Ltd.
Address: 1/F., Room 101, Building 1, Hongwei Industrial Park, Liuxian 2nd Road, Block 70 Bao'an District, Shenzhen, Guangdong, China

FCC - Registration No.: 125990

Waltek Testing Group (Shenzhen) Co., Ltd. EMC Laboratory has been registered and fully described in a report filed with the FCC (Federal Communications Commission). The acceptance letter from the FCC is maintained in their files. The Designation Number is CN5010, and Test Firm Registration Number is 125990.

Industry Canada (IC) Registration No.: 11464A

The 3m Semi-anechoic chamber of Waltek Testing Group (Shenzhen) Co., Ltd. has been registered by Certification and Engineering Bureau of Industry Canada for radio equipment testing with Registration No.: 11464A.

1.5 EUT Setup and Test Mode

The EUT was operated in the engineering mode to fix the Tx frequency that was for the purpose of the measurements. All testing shall be performed under maximum output power condition, with a duty cycle equal to 100%, and to measure its highest possible emissions level, more detailed description as follows:

Test Mode List

Test Conditions

EUT Cable List and Details

Special Cable List and Details

Auxiliary Equipment List and Details

1.6 Measurement Uncertainty

1.7 Test Equipment List and Details

Software List

*Remark: indicates software version used in the compliance certification testing

2. SUMMARY OF TEST RESULTS

N/A: Not applicable

3. Antenna Requirement

3.1 Standard Applicable

According to FCC Part 15.203, 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 shall be considered sufficient to comply with the provisions of this section.

3.2 Evaluation Information

This product has a PIFA antenna, fulfilling the requirement of this section.

4. Power Spectral Density

4.1 Standard Applicable

According to 15.247(a)(1)(iii), for digitally modulated systems, the power spectral density conducted from the intentional radiator to the antenna shall not be greater than 8 dBm in any 3 kHz band during any time interval of continuous transmission.

4.2 Test Setup Block Diagram

The test setup for Power Spectral Density measurement consists of the EUT connected via an RF cable and attenuator to a spectrum analyzer. This arrangement allows for direct measurement of the conducted power spectral density.

4.3 Test Procedure

According to the KDB 558074 D01 v05r02 Subclause 8.4 and ANSI C63.10-2013 Subclause 11.10.2, the test method of power spectral density is as follows:

1. Set analyzer center frequency to DTS channel center frequency.
2. Set the span to 1.5 times the DTS bandwidth.
3. Set the RBW to: 3 kHz < RBW ≤ 100 kHz.
4. Set the VBW ≥ 3 × RBW.
5. Detector = peak.
6. Sweep time = auto couple.
7. Trace mode = max hold.
8. Allow trace to fully stabilize.
9. Use the peak marker function to determine the maximum amplitude level within the RBW.
10. If measured value exceeds limit, reduce RBW (no less than 3 kHz) and repeat.

4.4 Summary of Test Results/Plots

Please refer to Appendix A for detailed test results and plots.

5. DTS Bandwidth

5.1 Standard Applicable

According to 15.247(a)(2), systems using digital modulation techniques may operate in the 902–928 MHz, 2400–2483.5 MHz, and 5725–5850 MHz bands. The minimum 6 dB bandwidth shall be at least 500 kHz.

5.2 Test Setup Block Diagram

The test setup for DTS Bandwidth measurement is similar to Power Spectral Density, with the EUT connected via an RF cable and attenuator to a spectrum analyzer.

5.3 Test Procedure

According to the KDB 558074 D01 v05r02 Subclause 8.2 and ANSI C63.10-2013 Subclause 11.8.1, the test method of DTS Bandwidth is as below:

1. Set RBW = 100 kHz.
2. Set the video bandwidth (VBW) ≥ 3 × RBW.
3. Detector = Peak.
4. Trace mode = max hold.
5. Sweep = auto couple.
6. Allow the trace to stabilize.
7. Measure the maximum width of the emission that is constrained by the frequencies associated with the two outermost amplitude points (upper and lower frequencies) that are attenuated by 6 dB relative to the maximum level measured in the fundamental emission.

5.4 Summary of Test Results/Plots

Please refer to Appendix B for detailed test results and plots.

6. RF Output Power

6.1 Standard Applicable

According to 15.247(b)(3), for systems using digital modulation in the 902–928 MHz, 2400–2483.5 MHz, and 5725–5850 MHz bands: 1 Watt.

6.2 Test Setup Block Diagram

The test setup for RF Output Power measurement involves the EUT connected via an RF cable and attenuator to a spectrum analyzer.

6.3 Test Procedure

According to the KDB-558074 D01 v05r02 Subclause 8.3.1.1 and ANSI C63.10-2013 Subclause 11.9.1.1, this procedure shall be used when the measurement instrument has available a resolution bandwidth that is greater than the DTS bandwidth.

1. Set the RBW ≥ DTS bandwidth.
2. Set VBW ≥ 3 × RBW.
3. Set span ≥ 3xRBW
4. Sweep time = auto couple.
5. Detector = peak.
6. Trace mode = max hold.
7. Allow trace to fully stabilize.
8. Use peak marker function to determine the peak amplitude level.

6.4 Summary of Test Results/Plots

Please refer to Appendix C for detailed test results and plots.

7. Field Strength of Spurious Emissions

7.1 Standard Applicable

According to §15.247(d), in any 100 kHz bandwidth outside the frequency band in which the spread spectrum or digitally modulated 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, provided the transmitter demonstrates compliance with the peak conducted power limits. If the transmitter complies with the conducted power limits based on the use of RMS averaging over a time interval, as permitted under paragraph (b)(3) of this section, the attenuation required under this paragraph shall be 30 dB instead of 20 dB. Attenuation below the general limits specified in §15.209(a) is not required. In addition, radiated emissions which fall in the restricted bands, as defined in §15.205(a), must also comply with the radiated emission limits specified in §15.209(a).

The emission limit in this paragraph is based on measurement instrumentation employing an average detector. The provisions in §15.35 for limiting peak emissions apply. Spurious Radiated Emissions measurements starting below or at the lowest crystal frequency.

7.2 Test Procedure

The setup of EUT is according with per ANSI C63.10-2013 measurement procedure. The specification used was with the FCC Part 15.205 15.247(a) and FCC Part 15.209 Limit.

The external I/O cables were draped along the test table and formed a bundle 30 to 40 cm long in the middle. The spacing between the peripherals was 10 cm.

Test setup for emission measurement below 30MHz:

A semi-anechoic 3m chamber is used. The EUT is placed on a turn table at 0.8m height. An antenna is positioned 3m away from the EUT. The turn table rotates from 0° to 360°. The EUT is connected to a PC System, which is connected to a Spectrum Analyzer, Amplifier, and Combining Network.

Test setup for emission measurement from 30 MHz to 1 GHz:

A semi-anechoic 3m chamber is used. The EUT is placed on a turn table at 0.8m height. An antenna is positioned 3m away from the EUT, with antenna elevation varying from 1 to 4m. The turn table rotates from 0° to 360°. The EUT is connected to a PC System, which is connected to a Spectrum Analyzer, Amplifier, and Combining Network.

Test setup for emission measurement above 1 GHz:

An anechoic 3m chamber is used. The EUT is placed on a turn table at 1.5m height. An antenna is positioned 3m away from the EUT, with antenna elevation varying from 1 to 4m. The turn table rotates from 0° to 360°. Absorbers are placed within the chamber. The EUT is connected to a PC System, which is connected to a Spectrum Analyzer, Amplifier, and Combining Network.

• Frequency: 9kHz-30MHz: RBW=10KHz, VBW=30KHz, Sweep time= Auto, Trace = max hold, Detector function = peak.
• Frequency: 30MHz-1GHz: RBW=120KHz, VBW=300KHz, Sweep time= Auto, Trace = max hold, Detector function = peak, QP.
• Frequency: Above 1GHz: RBW=1MHz, VBW=3MHz(Peak), 10Hz(AV), Sweep time= Auto, Trace = max hold, Detector function = peak, AV.

7.3 Corrected Amplitude & Margin Calculation

The Corrected Amplitude is calculated by adding the Antenna Factor and the Cable Factor, and subtracting the Amplifier Gain from the Amplitude reading. The basic equation is as follows:

Corr. Ampl. = Indicated Reading + Ant. Factor + Cable Loss – Ampl. Gain

The "Margin" column of the following data tables indicates the degree of compliance with the applicable limit. For example, a margin of -6dBμV means the emission is 6dBμV below the maximum limit. The equation for margin calculation is as follows:

Margin = Corr. Ampl. – FCC Part 15 Limit

7.4 Summary of Test Results/Plots

Note: this EUT was tested in 3 orthogonal positions and the worst case position data was reported.

Spurious Emissions Below 1GHz - Low Channel (Horizontal Polarity)

A plot shows the spurious emissions from 30 MHz to 1000 MHz with peaks observed at various frequencies, all remaining below the Limit1 line. The detailed measurements are provided in the table below.

Spurious Emissions Below 1GHz - Low Channel (Vertical Polarity)

A plot shows the spurious emissions from 30 MHz to 1000 MHz with peaks observed at various frequencies, all remaining below the Limit1 line. The detailed measurements are provided in the table below.

Spurious Emissions Below 1GHz - Middle Channel (Horizontal Polarity)

A plot shows the spurious emissions from 30 MHz to 1000 MHz with peaks observed at various frequencies, all remaining below the Limit1 line. The detailed measurements are provided in the table below.

Spurious Emissions Below 1GHz - Middle Channel (Vertical Polarity)

A plot shows the spurious emissions from 30 MHz to 1000 MHz with peaks observed at various frequencies, all remaining below the Limit1 line. The detailed measurements are provided in the table below.

Spurious Emissions Below 1GHz - High Channel (Horizontal Polarity)

A plot shows the spurious emissions from 30 MHz to 1000 MHz with peaks observed at various frequencies, all remaining below the Limit1 line. The detailed measurements are provided in the table below.

Spurious Emissions Below 1GHz - High Channel (Vertical Polarity)

A plot shows the spurious emissions from 30 MHz to 1000 MHz with peaks observed at various frequencies, all remaining below the Limit1 line. The detailed measurements are provided in the table below.

Remark: '-' Means ' the test Degree and Height are not recorded by the test software and only show the worst case in the test report.

Spurious Emissions Above 1GHz - Radiated Test Results

Note: Testing is carried out with frequency range 9kHz to the tenth harmonics, other than listed in the table above are attenuated more than 20dB below the permissible limits or the field strength is too small to be measured.

Low Channel-2406MHz

Middle Channel-2440MHz

High Channel-2472MHz

8. Out of Band Emissions

8.1 Standard Applicable

According to §15.247(d), in any 100 kHz bandwidth outside the frequency band in which the spread spectrum or digitally modulated 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, provided the transmitter demonstrates compliance with the peak conducted power limits. If the transmitter complies with the conducted power limits based on the use of RMS averaging over a time interval, as permitted under paragraph (b)(3) of this section, the attenuation required under this paragraph shall be 30 dB instead of 20 dB. Attenuation below the general limits specified in §15.209(a) is not required. In addition, radiated emissions which fall in the restricted bands, as defined in §15.205(a), must also comply with the radiated emission limits specified in §15.209(a).

8.2 Test Procedure

According to the KDB 558074 D01 v05r02 Subclause 8.4 and ANSI C63.10-2013 Subclause 11.11, the Emissions in nonrestricted frequency bands test method is as follows:

1. Set the center frequency and span to encompass frequency range to be measured.
2. Set the RBW = 100 kHz.
3. Set the VBW ≥ [3 × RBW].
4. Detector = peak.
5. Sweep time = auto couple.
6. Trace mode = max hold.
7. Allow trace to fully stabilize.
8. Use the peak marker function to determine the maximum amplitude level.

According to the KDB 558074 D01 v05r02 Subclause 8.5 and ANSI C63.10-2013 Subclause 11.12, the Emissions in restricted frequency bands test method is as follows:

A. Radiated emission measurements:

Set span = wide enough to capture the peak level of the emission operating on the channel closest to the bandedge, as well as any modulation products which fall outside of the authorized band of operation (2310MHz to 2420MHz for low bandedge, 2460MHz to 2500MHz for the high bandedge)

• RBW = 1MHz, VBW = 1MHz for peak value measured
• RBW = 1MHz, VBW = 10Hz for average value measured
• Sweep = auto; Detector function = peak/average; Trace = max hold

All the trace to stabilize, set the marker on the emission at the bandedge, or on the highest modulation product outside of the band, if this level is greater than that at the bandedge. Enable the marker-delta function, then use the marker-to-peak function to move the marker to the peak of the in-band emission. Those emission must comply with the 15.209 limit for fall in the restricted bands listed in section 15.205. Note that the method of measurement KDB publication number: 913591 may be used for the radiated bandedge measurements.

B. Antenna-port conducted measurements

Peak emission levels are measured by setting the instrument as follows:

1. RBW = as specified in Table 9.
2. VBW ≥ [3 × RBW].
3. Detector = peak.
4. Sweep time = auto.
5. Trace mode = max hold.
6. Allow sweeps to continue until the trace stabilizes. (Note that the required measurement time may be lengthened for low-duty-cycle applications.)

RBW as a function of frequency

If the peak-detected amplitude can be shown to comply with the average limit, then it is not necessary to perform a separate average measurement.

Ensure that the amplitude of all unwanted emissions outside of the authorized frequency band (excluding restricted frequency bands) are attenuated by at least the minimum requirements specified in section 8.1. Report the three highest emissions relative to the limit.

8.3 Summary of Test Results/Plots

Radiated Test Plots - Low Channel

A plot shows the radiated emission measurements for the low channel in horizontal (worst case) polarity, indicating peaks at various frequencies, including the fundamental frequency and spurious emissions. The detailed numerical results are provided in the table below.

Radiated Test Plots - High Channel

A plot shows the radiated emission measurements for the high channel in horizontal (worst case) polarity, indicating peaks at various frequencies, including the fundamental frequency and spurious emissions. The detailed numerical results are provided in the table below.

Conducted test

Please refer to Appendix D for detailed test results and plots.

9. Conducted Emissions

9.1 Test Procedure

The setup of EUT is according with per ANSI C63.10-2013 measurement procedure. The specification used was with the FCC Part 15.207 Limit.

The external I/O cables were draped along the test table and formed a bundle 30 to 40 cm long in the middle. The spacing between the peripherals was 10 cm.

9.2 Basic Test Setup Block Diagram

The conducted emissions test setup shows the EUT connected to a LISN (Line Impedance Stabilization Network) at 0.8m height from the ground plane. The LISN is connected to a Receiver and PC System. The EUT is placed 0.4m from the vertical wall.

9.3 Test Receiver Setup

During the conducted emission test, the test receiver was set with the following configurations:

• Start Frequency: 150 kHz
• Stop Frequency: 30 MHz
• Sweep Speed: Auto
• IF Bandwidth: 10 kHz
• Quasi-Peak Adapter Bandwidth: 9 kHz
• Quasi-Peak Adapter Mode: Normal

9.4 Summary of Test Results/Plots

Conducted Emissions - AC120V 60Hz (Line Polarity)

A plot shows the conducted emissions from 0.150 MHz to 30.0 MHz for the Line polarity, indicating various peaks relative to Limit1 (QP) and Limit2 (AVG). The detailed numerical results are provided in the table below.

Conducted Emissions - AC120V 60Hz (Neutral Polarity)

A plot shows the conducted emissions from 0.150 MHz to 30.0 MHz for the Neutral polarity, indicating various peaks relative to Limit1 (QP) and Limit2 (AVG). The detailed numerical results are provided in the table below.

APPENDIX SUMMARY

APPENDIX A: Power Spectral Density

This appendix presents the detailed Power Spectral Density test results for the GFSK(2.4G) modulation, across Low, Middle, and High channels. Each result is compared against the 8 dBm/3kHz limit.

Plots are provided for each channel (Low, Middle, High) showing the spectrum analyzer trace with the peak marker indicating the measured power spectral density. These plots confirm that the measured values are well within the specified limit of 8 dBm/3kHz.

APPENDIX B: DTS Bandwidth

This appendix presents the detailed DTS Bandwidth test results for the GFSK(2.4G) modulation, across Low, Middle, and High channels. The minimum 6 dB bandwidth is required to be at least 500 kHz.

Plots are provided for each channel (Low, Middle, High) showing the spectrum analyzer trace with the occupied bandwidth and 6 dB bandwidth measurements. These plots confirm that the measured 6 dB bandwidth values exceed the minimum requirement of 500 kHz.

APPENDIX C: RF Output Power

This appendix presents the detailed RF Output Power test results for the GFSK(2.4G) modulation, across Low, Middle, and High channels. The limit for RF Output Power is 30.00 dBm (1 Watt).

Plots are provided for each channel (Low, Middle, High) showing the spectrum analyzer trace with the peak marker indicating the measured RF output power. These plots confirm that the measured values are well within the specified limit of 30.00 dBm.

APPENDIX D: Conducted Out of Band Emissions

This appendix presents the detailed Conducted Out of Band Emissions test results for the GFSK(2.4G) modulation, across Low, Middle, and High channels. The measurements demonstrate compliance with the required attenuation levels.

Low Channel

Plots are provided showing the conducted out-of-band emissions for the Low channel. The first plot focuses on the band edge (2.398 GHz center frequency) showing the fundamental emission and the attenuated emissions outside the band. The second plot shows the full frequency range from 30 MHz to 26 GHz, confirming that all spurious emissions are well below the limits.

Middle Channel

A plot is provided showing the conducted out-of-band emissions for the Middle channel, focusing on the band edge (2.44 GHz center frequency). This plot confirms compliance with the required attenuation levels.

High Channel

Plots are provided showing the conducted out-of-band emissions for the High channel. The first plot focuses on the band edge (2.48 GHz center frequency) showing the fundamental emission and the attenuated emissions outside the band. The second plot shows the full frequency range from 30 MHz to 26 GHz, confirming that all spurious emissions are well below the limits.

APPENDIX PHOTOGRAPHS

Please refer to "ANNEX" for product and test setup photographs.