Jetmax JM-RC-DR1 RF Remote Control User Guide

The RF Remote Control has been evaluated to meet general RF exposure requirements. It can be used in portable exposure conditions without restrictions.

Battery Use Reminders:

Always purchase the correct size and grade of battery suitable for the intended use.

Replace all batteries of a set at the same time.
Clean the battery contacts and those of the device before battery installation.

Ensure correct installation of batteries with regard to\ polarity (+ and -).
Remove batteries from equipment not in use for an extended period.

Promptly remove used batteries.

Frequently Asked Questions

Q: Can I use rechargeable batteries with the RF Remote Control?
- A: It is recommended to use standard disposable batteries for optimal performance. Rechargeable batteries may not provide the same level of power output.
Q: How far is the effective range of the RF Remote Control?
- A: The effective range can vary depending on environmental factors, but typically ranges up to 30 meters in an open area.

Product Information

Guangdong Global Testing Technology Co., Ltd. Room 101-105, 203-210, Building 1, No.2, Keji 8 Road, Songshan Lake Park, Dongguan city, Guangdong, People’s Republic of China, 523808 This report is based on a single evaluation of the submitted sample(s) of the above mentioned \Product, it does not imply an assessment of the production of the products. This report shall not be reproduced, except in full, without the written approval of Guangdong Global Testing Technology Co., Ltd.

Revision History

Rev.		Issue Date		Revisions		Revised By
V0		September 23, 2024		Initial Issue

Summary of Test Results

Test Item	Limit/Requirement	Result
Antenna Requirement	FCC Part 15.203	Pass
AC Power Line Conducted Emission	FCC Part 15.207	Pass
20dB Bandwidth	FCC Part 15.231(c)	Pass
Transmission Time	FCC Part 15.231(a)	Pass
Radiated Emission	FCC Part 15.205/15.209 FCC Part 15.231(b)	Pass

This test report is only published to and used by the applicant, and it is not for evidence purposes in China.
*The measurement result for the sample received is <Pass> according to <CFR 47 FCC PART 15 SUBPART C> when <Accuracy Method> decision rule is applied.

ATTESTATION OF TEST RESULTS

Applicant Information

Company Name: Jetmax Lighting Co., Ltd

Address: No.3, Golden 2nd Road, Baima, Nancheng District, Dongguan City, Guangdong Province

Manufacturer Information

Company Name: Jetmax Lighting Co., Ltd
Address: No.3, Golden 2nd Road, Baima, Nancheng District, Dongguan City, Guangdong Province

EUT Information

Product Description: RF Remote Control

Model: JM-RC-DR1
Brand: N/A
Sample Received Date: September 12, 2024
Sample Status: Normal
Sample ID: A24081243 001
Date of Tested: September 12, 2024 to September 20, 2024

APPLICABLE STANDARDS
STANDARD	TEST RESULTS
CFR 47 FCC PART 15 SUBPART C	Pass

TEST METHODOLOGY

All tests were performed in accordance with the standard CFR 47 FCC PART 15 SUBPART C

FACILITIES AND ACCREDITATION

Accreditation Certificate

A2LA (Certificate No.: 6947.01)

Guangdong Global Testing Technology Co., Ltd.

has been assessed and proved to be in compliance with A2LA.

FCC (FCC Designation No.: CN1343)

Guangdong Global Testing Technology Co., Ltd.

has been recognized to perform compliance testing on equipment subject to Supplier’s Declaration of Conformity (SDoC) and Certification rules

ISED (Company No.: 30714)

Guangdong Global Testing Technology Co., Ltd.

has been registered and fully described in a report filed with ISED.

The Company Number is 30714 and the test lab Conformity Assessment Body Identifier (CABID) is CN0148.

Note: All tests measurement facilities use to collect the measurement data are located at Room 101-105, 203-210, Building 1, No.2, Keji 8 Road, Songshan Lake Park, Dongguan city, Guangdong, People’s Republic of China, 523808

CALIBRATION AND UNCERTAINTY

MEASURING INSTRUMENT CALIBRATION
The measuring equipment utilized to perform the tests documented in this report has been calibrated in accordance with the manufacturer’s recommendations and is traceable to recognized national standards.
MEASUREMENT UNCERTAINTY
Where relevant, the following measurement uncertainty levels have been estimated for tests performed on the apparatus:

Test Items	k	Uncertainty
20dB Emission Bandwidth	1.96	±9.2 PPM
Conducted Output Power	1.96	±1.5 dB
Power Spectral Density Level	1.96	±1.9 dB
Conducted Spurious Emission	1.96	9 kHz-30 MHz: ± 0.95 dB 30 MHz-1 GHz: ± 1.5 dB 1GHz-12.75GHz: ± 1.8 dB 12.75 GHz-26.5 GHz: ± 2.1dB
Note: This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=1.96.

Test Item	Measurement Frequency Range	K	U(dB)
Conducted emissions from the AC mains power ports (AMN)	150 kHz ~ 30 MHz	2	3.37
Radiated emissions	9 kHz ~ 30 MHz	2	4.16
Radiated emissions	30 MHz ~ 1 GHz	2	3.79
Radiated emissions	1 GHz ~ 18 GHz	2	5.62
Radiated emissions	18 GHz ~ 40 GHz	2	5.54
Note: This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k=2.

EQUIPMENT UNDER TEST

DESCRIPTION OF EUT

CHANNEL LIST

Channel List
Channel	Frequency (MHz)	Channel	Frequency (MHz)	Channel	Frequency (MHz)	Channel	Frequency (MHz)
1	433.92	/	/	/	/	/	/

MAX FIELD STRENGTH

Frequency (MHz)	Channel Number	Max field strength (dBµV/m)
433.92	1	71.61

TEST CHANNEL CONFIGURATION

Test Channel Number	Frequency
CH 1	433.92 MHz

THE WORSE CASE POWER SETTING PARAMETER

The Worse Case Power Setting Parameter
Test Software		/
Modulation Mode	Transmit Antenna Number	Test Channel
		CH 1
ASK/OOK	1	Default

DESCRIPTION OF AVAILABLE ANTENNAS

Antenna	Frequency (MHz)	Antenna Type	MAX Antenna Gain (dBi)
1	433.92	Internal antenna	0

Test Mode	Transmit and Receive Mode	Description
ASK/OOK	1TX	ANT 1 can be used as transmitting antenna.

Note: The value of the antenna gain was declared by the customer.

SUPPORT UNITS FOR SYSTEM TEST

Equipment	Manufacturer	Model No.
/	/	/

SETUP DIAGRAM

Radiated Emission:

EUT

RF conducted:

EUT

MEASURING EQUIPMENT AND SOFTWARE USED

Test Equipment of Conducted RF
Equipment	Manufacturer	Model No.	Serial No.	Last Cal.	Due Date
Spectrum Analyzer	Rohde & Schwarz	FSV40	102257	2023/09/18	2024/09/17
Spectrum Analyzer	KEYSIGHT	N9020A	MY51285127	2023/09/18	2024/09/17
EXG Analog Signal Generator	KEYSIGHT	N5173B	MY61253075	2023/09/18	2024/09/17
Vector Signal Generator	Rohde & Schwarz	SMM100A	101899	2023/09/18	2024/09/17
RF Control box	MWRF-test	MW100-RFCB	MW220926GTG	2023/09/18	2024/09/17
Wideband Radio Communication Tester	Rohde & Schwarz	CMW270	102792	2023/09/18	2024/09/17
Wideband Radio Communication Tester	Rohde & Schwarz	CMW500	103235	2023/09/18	2024/09/17
temperature humidity chamber	Espec	SH-241	SH-241-2014	2023/09/18	2024/09/17
RF Test Software	MWRF-test	MTS8310E (Ver. V2/0)	N/A	N/A	N/A

Test Equipment of Radiated emissions below 1GHz
Equipment	Manufacturer	Model No.	Serial No.	Last Cal.	Due Date
3m Semi-anechoic Chamber	ETS	9m6m6m	Q2146	2022/08/30	2025/08/29
EMI Test Receiver	Rohde & Schwarz	ESCI3	101409	2023/09/18	2024/09/17
Spectrum Analyzer	KEYSIGHT	N9020A	MY51283932	2023/09/18	2024/09/17
Pre-Amplifier	HzEMC	HPA-9K0130	HYPA21001	2023/09/18	2024/09/17
Biconilog Antenna	Schwarzbeck	VULB 9168	01315	2022/10/10	2025/10/09
Biconilog Antenna	ETS	3142E	00243646	2022/03/23	2025/03/22
Loop Antenna	ETS	6502	243668	2022/03/30	2025/03/29
Test Software	Farad	EZ-EMC (Ver.FA-03A2 RE)	N/A	N/A	N/A

Test Equipment of Radiated emissions above 1GHz
Equipment	Manufacturer	Model No.	Serial No.	Last Cal.	Due Date
3m Semi-anechoic Chamber	ETS	9m6m6m	Q2149	2022/08/30	2025/08/29
Spectrum Analyzer	Rohde & Schwarz	FSV40	101413	2023/09/18	2024/09/17
Spectrum Analyzer	KEYSIGHT	N9020A	MY51283932	2023/09/18	2024/09/17
Pre-Amplifier	A-INFO	HPA-1G1850	HYPA21003	2023/09/18	2024/09/17
Horn antenna	A-INFO	3117	246069	2022/03/11	2025/03/10

Pre-Amplifier	ZKJC	HPA-184057	HYPA21004	2023/09/18	2024/09/17
Horn antenna	ZKJC	3116C	246265	2022/03/29	2025/03/28
Test Software	Farad	EZ-EMC (Ver.FA-03A2 RE+)	N/A	N/A	N/A

Test Equipment of Conducted emissions
Equipment	Manufacturer	Model No.	Serial No.	Last Cal.	Due Date
Shielded Room	CHENG YU	8m5m4m	N/A	2022/10/29	2025/10/28
EMI Test Receiver	Rohde & Schwarz	ESR3	102647	2023/09/18	2024/09/17
LISN/AMN	Rohde & Schwarz	ENV216	102843	2023/09/18	2024/09/17
NNLK 8129 RC	Schwarzbeck	NNLK 8129 RC	5046	2023/09/18	2024/09/17
Test Software	Farad	EZ-EMC (Ver. EMC-con-3A1 1+)	N/A	N/A	N/A

ANTENNA PORT TEST RESULTS

ON-TIME AND DUTY CYCLE

LIMITS

None; for reporting purposes only.

TEST PROCEDURE

Refer to ANSI C63.10-2013 Zero–Span Spectrum Analyzer method.

TEST SETUP

TEST ENVIRONMENT

Temperature	23.2℃	Relative Humidity	52%
Atmosphere Pressure	101kPa

TEST RESULTS

433.92MHz

On Time (msec)	Period (msec)	Duty Cycle x (Linear)	Duty Cycle (%)	Duty Cycle Correction Factor (db)	1/T Minimum VBW (kHz)	Final setting For VBW (kHz)
21.9	100	0.219	21.9	-13.19	0.05	1

Note:

Duty Cycle Correction Factor=20log(x).

Where: x is Duty Cycle (Linear)
Where: T is On Time (transmitting duration)

If that calculated VBW is not available on the analyzer then the next higher value should be used

20DB BANDWIDTH

LIMITS

CFR 47 FCC Part15 (15.231) Subpart C
Section	Test Item	Limit	Frequency Range (MHz)
CFR 47 FCC 15.231(a)(2)	20 dB Bandwidth	≤ 1084.8 kHz	433.92

TEST PROCEDURE

Connect the EUT to the spectrum analyser and use the following settings

Center Frequency	The center frequency of the channel under test
Frequency Span	Approximately 2 to 3 times the 20dB bandwidth
Detector	Peak
RBW	1 % to 5 % of the 20 dB bandwidth
VBW	approximately 3×RBW
Trace	Max hold
Sweep	Auto couple

a) Use the occupied bandwidth function of the instrument, allow the trace to stabilize and report the measured 20 dB Bandwidth.

TEST SETUP

TEST ENVIRONMENT

Temperature	23.2℃	Relative Humidity	52%
Atmosphere Pressure	101kPa

TEST RESULTS

Frequency (MHz)	20dB bandwidth (kHz)	Limit (kHz)	Result
433.92	18.36	≤1084.8	Pass

TRANSMISSION TIME

LIMITS

CFR 47 FCC Part15 (15.231) Subpart C
Section	Test Item	Limit
CFR 47 FCC §15.247 (a)	Transmission Time	A manually operated transmitter shall employ a switch that will automatically deactivate the transmitter within not more than 5 seconds of being released.

TEST PROCEDURE

Connect the EUT to the spectrum analyser and use the following settings:

Center Frequency	The center frequency of the channel under test
Detector	PEAK
RBW	8MHz
VBW	8MHz
Span	0Hz
Sweep time	Auto couple

Allow trace to fully stabilize and record value.

TEST SETUP

TEST ENVIRONMENT

Temperature	23.4℃	Relative Humidity	55%
Atmosphere Pressure	101kPa

TEST RESULTS

Frequency (MHz)	TRANSMISSION TIME (s)	Limit (s)	Result
433.92	0.344	≤5	Pass

RADIATED TEST RESULTS

LIMITS

Please refer to CFR 47 FCC §15.231(b)

Fundamental frequency (MHz)	Field strength of fundamental (microvolts/meter)	Field strength of spurious emission (microvolts/meter)
40.66-40.70	2,250	225
70-130	1,250	125
130-174	¹1,250 to 3,750	¹125 to 375
174-260	3,750	375
260-470	¹3,750 to 12,500	¹375 to 1,250
Above 470	12,500	1,250

Note: 1. Linear interpolations.
Please refer to CFR 47 FCC §15.205 and §15.209.
Radiation Disturbance Test Limit for FCC (Class B) (9 kHz ~ 1 GHz)

Emissions radiated outside of the specified frequency bands above 30 MHz
Frequency Range (MHz)	Field Strength Limit (uV/m) at 3 m	Field Strength Limit
		(dBuV/m) at 3 m
		Quasi-Peak
30 – 88	100	40
88 – 216	150	43.5
216 – 960	200	46
Above 960	500	54
Above 1000	500	Peak	Average
		74	54

FCC Emissions radiated outside of the specified frequency bands below 30 MHz
Frequency (MHz)	Field strength (microvolts/meter)	Measurement distance (meters)
0.009-0.490	2400/F(kHz)	300
0.490-1.705	24000/F(kHz)	30
1.705-30.0	30	30

TEST PROCEDURE

Below 30 MHz

The setting of the spectrum analyser

RBW	200 Hz (From 9 kHz to 0.15 MHz)/ 9 kHz (From 0.15 MHz to 30 MHz)
VBW	200 Hz (From 9 kHz to 0.15 MHz)/ 9 kHz (From 0.15 MHz to 30 MHz)
Sweep	Auto

The testing follows the guidelines in ANSI C63.10-2013 clause 6.4.
The EUT was arranged to its worst case and then turntable (from 0 degree to 360 degrees) to find the maximum reading. A pre-amp and a high pass filter are used for the test in order to get better signal level. Both Horizontal, Face-on and Face-off polarizations of the antenna are set to make the measurement.
The EUT was placed on a turntable with 80 cm above ground.

The EUT was set 3 meters from the interference receiving antenna, which was mounted on the top of a 1 m height antenna tower.
The radiated emission limits are based on measurements employing a CISPR quasi-peak detector except for the frequency bands 9-90 kHz, 110-490 kHz and above 1000 MHz Radiated emission limits in these three bands are based on measurements employing an average detector.
For measurement below 1 GHz, the initial step in collecting conducted emission data is a spectrum analyzer peak detector mode pre-scanning the measurement frequency range. Significant peaks are then marked and then Quasi Peak and average detector modes re-measured. If the emission level of the EUT measured by the peak detector is 3 dB lower than the applicable limit, the peak emission level will be reported. Otherwise, the emission measurement will be repeated using the quasi-peak and average detector and reported.

Although these tests were performed other than open field site, adequate comparison measurements were confirmed against 30m open field site. Therefore sufficient tests were made to demonstrate that the alternative site produces results that correlate with the ones of tests made in an open field site based on KDB 414788.
The limits in CFR 47, Part 15, Subpart C, paragraph 15.209 (a), are identical to those in RSS-GEN Section 8.9, Table 6, since the measurements are performed in terms of magnetic field strength and converted to electric field strength levels (as reported in the table) using the free space impedance of 377Ω. For example, the measurement frequency X KHz resulted in a level of Y dBuV/m, which is equivalent to Y-51.5 = Z dBuA/m, which has the same margin, W dB, to the corresponding RSS-GEN Table 6 limit as it has to be 15.209(a) limit.

Below 1 GHz and above 30 MHz

The setting of the spectrum analyzer

RBW	120 kHz
VBW	300 kHz
Sweep	Auto
Detector	Peak/QP
Trace	Max hold

The testing follows the guidelines in ANSI C63.10-2013 clause 6.5.
The EUT was arranged to its worst case and then tune the antenna tower (from 1 m to 4 m) and turntable (from 0 degree to 360 degrees) to find the maximum reading. A pre-amp and a high pass filter are used for the test in order to get better signal level. Both horizontal and vertical polarizations of the antenna are set to make the measurement.

The EUT was placed on a turntable with 80 cm above ground.
The EUT was set 3 meters from the interference receiving antenna, which was mounted on the top of a variable-height antenna tower.
For measurement below 1 GHz, the initial step in collecting conducted emission data is a spectrum analyzer peak detector mode pre-scanning the measurement frequency range. Significant peaks are then marked and then Quasi Peak detector mode re-measured. If the emission level of the EUT measured by the peak detector is 3 dB lower than the applicable limit, the peak emission level will be reported. Otherwise, the emission measurement will be repeated using the quasi-peak detector and reported.

Above 1G

The setting of the spectrum analyzer

RBW	1 MHz
VBW	PEAK: 3 MHz AVG: see note 6
Sweep	Auto
Detector	Peak
Trace	Max hold

The testing follows the guidelines in ANSI C63.10-2013 clause 6.6.

The EUT was arranged to its worst case and then tune the antenna tower (from 1 m to 4 m) and turntable (from 0 degree to 360 degrees) to find the maximum reading. A pre-amp and a high pass filter are used for the test in order to get better signal level. Both horizontal and vertical polarizations of the antenna are set to make the measurement.
The EUT was placed on a turntable with 1.5 m above ground.
The EUT was set 3 meters from the interference receiving antenna, which was mounted on the top of a variable height antenna tower.

For measurements above 1 GHz, the emission measurement will be measured by the peak detector. This peak level, once corrected, must comply with the limit specified in Section 15.209.
For measurements above 1 GHz the resolution bandwidth is set to 1 MHz, then the video bandwidth is set to 3 MHz for peak measurements and 1 MHz resolution bandwidth with 1/T video bandwidth with peak detector for average measurements. For the Duty Cycle please refer to clause 7.1.ON TIME AND DUTY CYCLE.

X-axis, Y-axis, and Z-axis positions:

Note 1: For all radiated test, EUT in each of three orthogonal axis emissions had been tested, but only the worst case (X-axis) data was recorded in the report.

TEST SETUP

TEST ENVIRONMENT

Temperature	22.1℃	Relative Humidity	51%
Atmosphere Pressure	101kPa

TEST RESULTS

Please refer to section 8.1

RADIATED EMISSION

Field Strength of Fundamental Frequency

Mode: 433.92MHz
Power: Battery 3V
TE: Berny

Date 2024/08/19
T/A/P 22.1℃/51%/101Kpa

Critical_Freqs

No.	Freq. (MHz)	Reading (dBµV)	Corr. (dB)	Meas. (dBµV/m)	Limit (dBµV/m)	Margin (dB)	Det.	Pol.
1	433.940	85.81	-14.2	71.61	80.83	9.22	PK+	H

Note：[Margin=Limit-Meas.]; [Meas.=Reading+Corr. ]

Mode: 433.92MHz Power:

Battery 3V TE: Berny
Date 2024/08/19
T/A/P 22.1℃/51%/101Kpa

Critical_Freqs

No.	Freq. (MHz)	Reading (dBµV)	Corr. (dB)	Meas. (dBµV/m)	Limit (dBµV/m)	Margin (dB)	Det.	Pol.
1	433.940	78.05	-14.2	63.85	80.83	16.98	PK+	V

Note：[Margin=Limit-Meas.]; [Meas.=Reading+Corr. ]

Note:

Only the worst data was recorded, if it complies with the limit, the other emissions were deemed to comply with the limit.

Radiated Spurious Emission

Mode: 433.92MHz

Power: Battery 3V
TE: Berny
Date 2024/08/19

T/A/P 22.1℃/51%/101Kpa

Critical_Freqs

No.	Freq. (MHz)	Reading (dBµV)	Corr. (dB)	Meas. (dBµV/m)	Limit (dBµV/m)	Margin (dB)	Det.	Pol.
1	30.000	46.01	-14.27	31.74	40.00	8.26	PK+	V
2	210.420	36.99	-21.26	15.73	43.50	27.77	PK+	V
3	720.640	32.64	-6.94	25.70	46.00	20.30	PK+	V
4	792.420	34.86	-6.62	28.24	46.00	17.76	PK+	V
5	868.080	32.80	-5.49	27.31	46.00	18.69	PK+	V
6	946.650	30.90	-3.34	27.56	46.00	18.44	PK+	V

Note：[Margin=Limit-Meas.]; [Meas.=Reading+Corr. ]

Mode: 433.92MHz Power:
Battery 3V
TE: Berny

Date 2024/08/19
T/A/P 22.1℃/51%/101Kpa

Critical_Freqs

No.	Freq. (MHz)	Reading (dBµV)	Corr. (dB)	Meas. (dBµV/m)	Limit (dBµV/m)	Margin (dB)	Det.	Pol.
1	30.970	29.62	-14.8	14.82	40.00	25.18	PK+	H
2	335.550	40.97	-17.11	23.86	46.00	22.14	PK+	H
3	623.640	41.01	-9.2	31.81	46.00	14.19	PK+	H
4	672.140	39.56	-7.98	31.58	46.00	14.42	PK+	H
5	792.420	39.87	-6.62	33.25	46.00	12.75	PK+	H
6	868.080	44.49	-5.49	39.00	46.00	7.00	PK+	H

Note：[Margin=Limit-Meas.]; [Meas.=Reading+Corr. ]

Mode:	433.92MHz
Power:	Battery 3V
TE:	Berny
Date	2024/08/19
T/A/P	22.1℃/51%/101Kpa

Critical_Freqs

No.	Freq. (MHz)	Reading (dBµV)	Corr. (dB)	Meas. (dBµV/m)	Limit (dBµV/m)	Margin (dB)	Det.	Pol.
1	1302.000	69.06	-22.83	46.23	74.00	27.77	PK+	V
2	1864.000	66.83	-19.57	47.26	74.00	26.74	PK+	V
3	2148.000	65.60	-17.99	47.61	74.00	26.39	PK+	V
4	2412.000	63.93	-17.4	46.53	74.00	27.47	PK+	V
5	5764.500	59.90	-9.25	50.65	74.00	23.35	PK+	V
6	17686.500	47.36	0.25	47.61	74.00	26.39	PK+	V

Note：[Margin=Limit-Meas.]; [Meas.=Reading+Corr. ]

Mode:	433.92MHz
Power:	Battery 3V
TE:	Berny
Date	2024/08/19
T/A/P	22.1℃/51%/101Kpa

Critical_Freqs

No.	Freq. (MHz)	Reading (dBµV)	Corr. (dB)	Meas. (dBµV/m)	Limit (dBµV/m)	Margin (dB)	Det.	Pol.
1	1302.000	72.66	-22.83	49.83	74.00	24.17	PK+	H
2	1942.000	66.74	-18.85	47.89	74.00	26.11	PK+	H
3	2604.000	63.81	-16.98	46.83	74.00	27.17	PK+	H
4	3037.500	59.77	-15.03	44.74	74.00	29.26	PK+	H
5	5781.000	59.47	-9.08	50.39	74.00	23.61	PK+	H
6	16741.500	47.46	-1.01	46.45	74.00	27.55	PK+	H

Note：[Margin=Limit-Meas.]; [Meas.=Reading+Corr. ]

Note:

Measurement = Reading Level + Correct Factor.
If Peak Result complies with AV limit, AV Result is deemed to comply with AV limit.
Peak: Peak detector.
Only the worst data was recorded, if it complies with the limit, the other emissions deemed to comply with the limit.

ANTENNA REQUIREMENT

REQUIREMENT

Please refer to FCC §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. 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.

DESCRIPTION

Pass

AC POWER LINE CONDUCTED EMISSION

LIMITS

Please refer to CFR 47 FCC §15.207 (a)

FREQUENCY (MHz)	Quasi-peak	Average
0.15 -0.5	66 – 56 *	56 – 46 *
0.50 -5.0	56.00	46.00
5.0 -30.0	60.00	50.00

TEST PROCEDURE

The EUT is put on a table of non-conducting material that is 80 cm high. The vertical conducting wall of shielding is located 40 cm to the rear of the EUT. The power line of the EUT is connected to the AC mains through a Artificial Mains Network (A.M.N.). A EMI Measurement Receiver (R&S Test Receiver ESR3) is used to test the emissions from both sides of AC line. According to the requirements in Section 6.2 of ANSI C63.10-2013.Conducted emissions from the EUT measured in the frequency range between 0.15 MHz and 30 MHz using CISPR Quasi-Peak and average detector mode. The bandwidth of EMI test receiver is set at 9 kHz.
The arrangement of the equipment is installed to meet the standards and operating in a manner, which tends to maximize its emission characteristics in a normal application.

TEST SETUP

TEST ENVIRONMENT

Temperature	/	Relative Humidity	/
Atmosphere Pressure	/

TEST RESULTS

Not Applicable

APPENDIX: PHOTOGRAPHS OF TEST CONFIGURATION

Radiated Emission

APPENDIX: PHOTOGRAPHS OF THE EUT

External

Documents / Resources

Jetmax JM-RC-DR1 RF Remote Control [pdf] User Guide
2AZA6JM-RC-DR1, JM-RC-DR1 RF Remote Control, JM-RC-DR1, RF Remote Control, Remote Control, Control

References

User Manual

Jetmax JM-RC-DR1 RF Remote Control

Product Information

Product Usage Instructions

Frequently Asked Questions

Product Information

TEST METHODOLOGY

CALIBRATION AND UNCERTAINTY

EQUIPMENT UNDER TEST

MEASURING EQUIPMENT AND SOFTWARE USED

ANTENNA PORT TEST RESULTS

RADIATED TEST RESULTS

TEST PROCEDURE

TEST SETUP

RADIATED EMISSION

ANTENNA REQUIREMENT

AC POWER LINE CONDUCTED EMISSION

APPENDIX: PHOTOGRAPHS OF TEST CONFIGURATION

Documents / Resources

References

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