EN 300 328 V1.8.1 TEST REPORT For

Report No.: HT2015430Ab-1

Shenzhen OES Testing technology co., Ltd. Page 1 of 24

EN 300 328 V1.8.1 TEST REPORT

For

Smart Device, Smart Finder

Model No. : S-1, S-2, S-3, S-4, S-5, S-6

Prepared for :

Address :

Prepared By : Shenzhen OES Testing technology co., Ltd.

Address : Room 401, 19, BaoKang Road, The Pine Community, Cross The Street,

Longgang District, Shenzhen City, Guangdong Province, China

Tel : (86) 755-66808335

Fax : (86) 755-61658456

Report No. : HT2015430Ab-1

Date of Test : April 22-30, 2015

Date of Rep. : April 30, 2015



TABLE OF CONTENT

Description Page

Test Report Declaration

1. GENERAL INFORMATION ................................................................................................4

1.1 Description of Device (EUT) ............................................................................................................. 4

1.2 Test Facility ....................................................................................................................................... 5

2. TEST INSTRUMENT USED .................................................................................................6

3. RF OUTPUR POWER (CONDUCTED MEASUREMENT) .............................................8

3.1. Limits. ........................................................................................................................................... 8

3.2. Test Result ..................................................................................................................................... 8

4. POWER SPECTRAL DENSITY ...........................................................................................9

4.1. Limits. ........................................................................................................................................... 9

4.2. Test Procedure ............................................................................................................................... 9

4.3. Test Result ................................................................................................................................... 10

5. OCCUPIED CHANNEL BANDWIDTH ............................................................................11

5.1. Limits. ......................................................................................................................................... 11

5.2. Test Procedure ............................................................................................................................. 11

5.3. Test Result ................................................................................................................................... 11

6. TRANSMITTER UNWANTED EMISSIONS IN THE OUT-OF-BAND DOMAIN ..... 13

6.1. Limits. ......................................................................................................................................... 13

6.2. Test Procedure ............................................................................................................................. 13

6.3. Test Result ................................................................................................................................... 16

7. TRANSMITTER UNWANTED EMISSIONS IN THE SPURIOUS DOMAIN .............18

7.1. Limits. ......................................................................................................................................... 18

7.2. Test Procedure ............................................................................................................................. 18

7.3. Test Result ................................................................................................................................... 21

8 RECEIVER PARAMETERS ............................................................................................... 22

8.1 Limits ............................................................................................................................................... 22

8.2 Test Procedure ................................................................................................................................. 22

8.3 Test Result ....................................................................................................................................... 24

APPENDIX I ---------------- Photographs of the EUT



TEST REPORT DECLARATION

Applicant :

Manufacturer :

EUT Description : Smart Device, Smart Finder

(A) Model No. : S-1, S-2, S-3, S-4, S-5, S-6

(B) Power Supply : DC 3.0V

Test Procedure Used:

EN 300 328 V1.8.1

[Electromagnetic compatibility and Radio spectrum Matters (ERM); Wideband transmission systems;

Data transmission equipment operating in the 2.4 GHz ISM band and using wide band modulation

techniques; Harmonized EN covering essential requirements under article 3.2 of the R&TTE Directive]

The device described above has been tested by Shenzhen OES Testing technology co., Ltd. to

determine the maximum emission levels emanating from the device, the severe levels that the

device can endure and EUT’S performance criterion. The test results are contained in this test

report. Shenzhen OES Testing technology co., Ltd. is assumed of full responsibility for the

accuracy and completeness of these tests. Also, this report shows that the EUT is technically

compliant with the EN 300 328 V1.8.1 requirements.

This report applies to above tested sample only and shall not be reproduced in part without

written approval of Shenzhen OES Testing technology co., Ltd.

Date of Test: April 22-30, 2015

Prepared by:

Huang hua, Baird

Engineer

Approved by:

Chi jun, Danny

Technical Director



1. GENERAL INFORMATION

1.1 Description of Device (EUT)

Description : Smart Device, Smart Finder

Trade Name : N.A.

Model Number : S-1, S-2, S-3, S-4, S-5, S-6

They are quite same in circuit design and PCB layout, so all tests of

this report are perform on model “S-1”.

Frequency Range : 2402M-2480M

Number of Channels : 40

Type of Antenna : PCB Antenna

Power supply : DC 3.0V

Test Conditions : NV (Normal Voltage): 3.0V, LV (Low Voltage):2.7V,

HV (High Voltage): 3.3V;

NT(Normal Temperature):23-25,

HT (High Temperature): 50,

LT (Low Temperature): -20 Relative Humidity: 46 to 56%

Applicant :

Address :

Manufacturer :

Address :



1.2 Test Facility

Site Description:

EMC Laboratory : Certificated by TUV Rheinland Shenzhen

May 10, 2004

Certificated by FCC

Registration Number: 253065

May 10, 2004

Certificated by Industry Canada

Registration Number: IC5077

May 18, 2004

Name of Firm : Accurate Technology Co., Ltd

Site Location : F1, Bldg. A, Changyuan New Material Port, Keyuan

Rd., Science & Industry Park, Nanshan, Shenzhen,

Guangdong, P.R. China



2. TEST INSTRUMENT USED

No.

Equipment

Manufacturer

Model No. S/N Cal. Date Next Cal.

Date

1 ESD TESTER HAEFELY PESD1610 H401552 2015.01.16 2016.01.16

2 MAGNETIC FIELD TESTER HAEFELY MAG100 150577 2015.01.15 2016.01.15

3

5kVA AC POWER SOURCE

CALIFORNIA

INSTRUMENTS

5001ix-400

55692

2015.01.15

2016.01.15

4

HARMONICS/FLICKER TEST

ANALYZER

CALIFORNIA

INSTRUMENTS

PACS-1

72254

2015.01.15

2016.01.15

5 50Ω COAXIAL SWITCH ANRITSU MP59B 6200283933 2015.01.15 2016.01.15

6 CONICAL HOUSING ATC N/A N/A N/A N/A

7 VOLTAGE PROBE SCHWARZBECK TK9416 N/A 2015.01.15 2016.01.15

8 RF CURRENT PROBE ROHDE& SCHWARZ EZ-17 100048 2015.01.15 2016.01.15

9 BILOG ANTENNA SCHWARZBECK VULB9163 194 2015.01.15 2016.01.15

10 SPECTRUM ANALYZER ANRITSU MS2651B N/A 2015.01.15 2016.01.15

11

PRE-AMPLIFIER

AGILENT

8447D

294A10619

2015.01.15

2016.01.15

12

RF COAXIAL CABLE(844

CHAMBER)

SCHWARZBECK

N-5m

NO.1

2015.01.15

2016.01.15

13 THERMO-HYGROMETER OREGON SCIENTIFIC JB913R GZ-WS004 2015.01.04 2016.01.04

14

1# SHIELDING ROOM

CHANGZHOU

ZHONGYU

843

N/A

N/A

N/A

15

2# SHIELDING ROOM

CHANGZHOU

ZHONGYU

843

N/A

N/A

N/A

16

3m Semi-ANECHOIC

CHAMBER

CHANGZHOU

ZHONGYU

844

N/A

N/A

N/A

17

ANTENNA/TURNTABLE

CONTROLLER

INNCO

CO2000

CO2000/077/7

301203/L

N/A

N/A

18 101 LCR METER YANGZHI YD2810B 20101170 2015.01.04 2016.01.04

19


CHAMBER)

NTGS8017

N-1m

NO.6

2015.01.15

2016.01.15

20


CHAMBER)

NTGS8017

N-1m

NO.7

2015.01.15

2016.01.15

21 AUDIO GENERATOR GW GAG-809 EG835424 N/A N/A




No.

Equipment 29

Manufacturer


Date

23

EMCPRO SYSTEM

(IMMUNITY TESTER)

THERMO

PRO-BASE

0403271

2015.01.15

2016.01.15

24

CAPACITIVE CLAMP

(EFT)

THERMO

PRO-CCL

0403272

2015.01.15

2016.01.15

25

COUPLER DECOUPLER

FOR TELECOM LINES

THERMO

CM-TEL-CD

0403273

2015.01.15

2016.01.15

26 L.I.S.N. ROHDE& SCHWARZ ESH3-Z5 100305 2015.01.15 2016.01.15

27 EMI TEST RECEIVER ROHDE& SCHWARZ ESPI-3 100396/003 2015.01.15 2016.01.15

28 SIGNAL GENERATOR ROHDE& SCHWARZ SML01 101161 2015.01.15 2016.01.15


30 SPECTRUM ANALYZER AGILENT E7405A MY45115511 2015.01.15 2016.01.15

31 L.I.S.N. SCHWARZBECK NSLK8126 8126431 2015.01.15 2016.01.15

32

PULSE LIMITER

(FOR ESPI3)

ROHDE& SCHWARZ

ESH3-Z2

100815

2015.01.15

2016.01.15

33 PRE-AMPLIFIER ROHDE& SCHWARZ CBLU1183540-01 3791 2015.01.15 2016.01.15


35 BILOG ANTENNA SCHWARZBECK VULB9163 9163-323 2015.01.15 2016.01.15

36 HORN ANTENNA SCHWARZBECK BBHA9120D 9120D-655 2015.01.15 2016.01.15

37 HORN ANTENNA SCHWARZBECK BBHA9170 9170-359 N/A N/A

38 LOOP ANTENNA SCHWARZBECK FMZB1516 1516131 2015.01.15 2016.01.15

39

ULTRA COMPACT

SIMULATOR

EM TEST

UCS 500 N5

V0928104968

2015.01.15

2016.01.15

40 CAPACITIVE CLAMP EM TEST HFK 0509-34 2015.01.15 2016.01.15

41 Transformer EM TEST V4780S2 0109-44 N/A N/A

42

Conducted Immunity Test

System

FRANKONIA

CIT-10

126B1121

2015.01.15

2016.01.15

43 CDN FRANKONIA CDN-M2/3 A3027020 2015.01.15 2016.01.15

44 EM Injection Clamp FCC F-203I-23mm 091824 2015.01.15 2016.01.15

45 LISN AFJ LS16C 16010946249 2015.01.15 2016.01.15

46 CLICK METER AFJ CL55C 55040947164 2015.01.15 2016.01.15



3. RF OUTPUR POWER (CONDUCTED MEASUREMENT)

3.1. Limits

The maximum RF output power shall be equal to or less than 20 dBm (100mW)

3.2. Test Result

Detailed information, Please refer to the following form.

Test Conditions

Measured power (mW/dBm) and variation (mW/dBm)

Channel 1

2402MHz

Channel 2

2440MHz

Channel 3

2480MHz

T nom (25) V nom (3.0V DC) 0.653/-1.85 0.618/-2.08 0.569/-2.45

T min (-20) V min (2.7V DC) 0.643/-1.92 0.605/-2.18 0.543/-2.65

V nom (3.3V DC) 0.666/-1.72 0.634/-1.98 0.533/-2.73

T max (+55) V min (2.7V DC) 0.673/-1.82 0.583/-2.34 0.498/-3.03

V nom (3.3V DC) 0.667/-1.76 0.564/-2.49 0.482/-3.17

Measurement Uncertainty ±1.5dB

Limit 20 dBm (100 mW)

Add the (stated) antenna assembly gain "G" in dBi of the individual antenna.

•If applicable, add the additional beamforming gain "Y" in dB.

•If more than one antenna assembly is intended for this power setting, the

maximum overall antenna gain (G orG + Y) shall be used.

•The RF Output Power (P) shall be calculated using the formula below:P = A + G

+ Y

•This value, which shall comply with the limit given in clauses 4.3.1.1.2 or

4.3.2.1.2, shall be recorded in the test report.

Result: PASS



4. POWER SPECTRAL DENSITY

4.1. Limits

For equipment using wide band modulations other than FHSS, the maximum Power

Spectral Density is limited to 10 dBm per MHz.

4.2. Test Procedure

The conducted measurement method was used in this report.

The transmitter was connected to the measuring equipment according to the above

setup.

Step 1:

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

•Start Frequency: 2 400 MHz

•Stop Frequency: 2 483,5 MHz

•Resolution BW: 10 kHz

•Video BW: 30 kHz

•Sweep Points: > 8 350

NOTE: For spectrum analysers not supporting this number of sweep points, the

frequency band may besegmented.

•Detector: RMS

•Trace Mode: Max Hold

•Sweep time: Auto

For non-continuous signals, wait for the trace to be completed. Save the (trace)

data set to a file.

Step 2:

For conducted measurements on smart antenna systems using either operating

mode 2 or 3 (see clause 5.1.3.2), repeatthe measurement for each of the transmit

ports. For each frequency point, add up the amplitude (power) values for

thedifferent transmit chains and use this as the new data set.

Step 3:

Add up the values for amplitude (power) for all the samples in the file.

Step 4:

Normalize the individual values for amplitude so that the sum is equal to the RF

Output Power (e.i.r.p.) measured inclause 5.3.2.

Step 5:

Starting from the first sample in the file (lowest frequency), add up the power of

the following samples representing a1 MHz segment and record the results for

power and position (i.e. sample #1 to #100). This is the Power SpectralDensity

(e.i.r.p.) for the first 1 MHz segment which shall be recorded.

Step 6:



Shift the start point of the samples added up in step 5 by 1 sample and repeat the

procedure in step 5 (i.e. sample #2 to#101).

Step 7:

Repeat step 6 until the end of the data set and record the radiated Power Spectral

Density values for each of the 1 MHzsegments.

From all the recorded results, the highest value is the maximum Power Spectral

Density for the UUT. This value, whichshall comply with the limit given in clause

4.3.2.2.2, shall be recorded in the test report.

4.3. Test Result

Measuring Parameter

Frequency Range

2400 MHz to 2483.5 MHz

RBW(MHz) 10 kHz

VBW(MHz) 30 kHz

Sweep points 8351

Detector mode RMS

Trace mode Max Hold

Sweep time Auto

Test Data

Limit 10dBm/MHz

Test Conditions

Temperature : 25C

Voltage: 3.3V

Power density (dBm)

2402MHz 2440MHz 2480MHz

Power

Spectral

density

Power

Spectral

density

Power

Spectral

density

-3.4 -3.2 -3.5

PASS



5. OCCUPIED CHANNEL BANDWIDTH

5.1. Limits

The Occupied Channel Bandwidth for each hopping frequency shall fall

completely within the band2400MHz to 2483.5MHz.

In addition, for non-adaptive systems using wide band modulations other than

FHSS and with e.i.r.p greater than10 dBm, the occupied channel bandwidth shall

be less than 20 MHz.

5.2. Test Procedure



setup.

Step 1:

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

•Centre Frequency: The centre frequency of the channel under test

•Resolution BW: ~ 1 % of the span without going below 1 %

•Video BW: 3 × RBW

•Frequency Span: 2 × Occupied Channel Bandwidth (e.g. 40 MHz for a 20 MHz

channel)

•Detector Mode: RMS


Step 2:

Wait until the trace is completed.

Find the peak value of the trace and place the analyser marker on this peak.

Step 3:

Use the 99 % bandwidth function of the spectrum analyser to measure the

Occupied Channel Bandwidth of the UUT.

This value shall be recorded.

NOTE: Make sure that the power envelope is sufficiently above the noise floor of

the analyser to avoid the noisesignals left and right from the power envelope being

taken into account by this measurement.

5.3. Test Result



-10

-20

-30

-40

2400.999 2401.5 2402

Frequency in MHz

2402.5 2403.026

-10

-20

-30

-40

2478.999 2479.5 2480

Frequency in MHz

2480.5 2481.028

DUT

Frequency

(MHz)

Channel Center

Frequency

(MHz)

Occupied Channel

Bandwidth

(MHz)

Lower Band

Edge

(MHz)

Upper

Band Edge

(MHz)

Limit

(MHz)

2402 2402.012 1.012 2401.506 2402.519 Within The

Band

2400MHz to

2483.5MHz

2480 2480.013

1.014

2479.506

2480.520

Test Conditions

Temperature : 25C

Voltage: 3.3V

PASS

Plots of the lowest frequency

2.401506

GHz

2.402519

GHz

-20 d Bm

-21

dBm

Plots of the highest frequency

2.479506

GHz

-21 d Bm 2.480521

-22

GHz

dBm

Level in

dB

m

Le

ve

l in

dB

m



6. TRANSMITTER UNWANTED EMISSIONS IN THE

OUT-OF-BAND DOMAIN

6.1. Limits

The transmitter unwanted emissions in the out-of-band domain but outside the

allocated band, shall not exceed thevalues provided by the mask in figure 1.

NOTE: Within the 2 400 MHz to 2 483,5 MHz band, the Out-of-band emissions

are fulfilled by compliance withthe Occupied Channel Bandwidth requirement

in§2.4 in this report.

Figure 1: Transmit mask

6.2. Test Procedure



setup.

The applicable mask is defined by the measurement results from the tests

performed under clause 5.3.8 (OccupiedChannel Bandwidth).

The Out-of-band emissions within the different horizontal segments of the mask

provided in figures 1 and 3 shall bemeasured using the steps below. This method

assumes the spectrum analyser is equipped with the Time Domain Poweroption.

Step 1:



•Connect the UUT to the spectrum analyser and use the following settings:

- Centre Frequency: 2 484 MHz

- Span: 0 Hz

- Resolution BW: 1 MHz

- Filter mode: Channel filter

- Video BW: 3 MHz

- Detector Mode: RMS

- Trace Mode: Clear / Write

- Sweep Mode: Continuous

- Sweep Points: 5 000

- Trigger Mode: Video trigger

NOTE 1: In case video triggering is not possible, an external trigger source may

be used.

- Sweep Time: Suitable to capture one transmission burst

Step 2: (segment 2 483,5 MHz to 2 483,5 MHz + BW)

•Adjust the trigger level to select the transmissions with the highest power level.

•For frequency hopping equipment operating in a normal hopping mode, the

different hops will result in signalbursts with different power levels. In this case

the burst with the highest power level shall be selected.

•Set a window (start and stop lines) to match with the start and end of the burst

and in which the RMS powershall be measured using the Time Domain Power

function.

•Select RMS power to be measured within the selected window and note the result

which is the RMS powerwithin this 1 MHz segment (2 483,5 MHz to 2 484,5

MHz). Compare this value with the applicable limitprovided by the mask.

•Increase the centre frequency in steps of 1 MHz and repeat this measurement for

every 1 MHz segment withinthe range 2 483,5 MHz to 2 483,5 MHz + BW. The

centre frequency of the last 1 MHz segment shall be set to2 483,5 MHz + BW -

0,5 MHz (which means this may partly overlap with the previous 1 MHz

segment).

Step 3: (segment 2 483,5 MHz + BW to 2 483,5 MHz + 2BW)

•Change the centre frequency of the analyser to 2 484 MHz + BW and perform the

measurement for the first1 MHz segment within range 2 483,5 MHz + BW to 2

483,5 MHz + 2BW. Increase the centre frequency in1 MHz steps and repeat

themeasurements to cover this whole range. The centre frequency of the last 1

MHzsegment shall be set to 2 483,5 MHz + 2 BW - 0,5 MHz.

Step 4: (segment 2 400 MHz - BW to 2 400 MHz)

•Change the centre frequency of the analyser to 2 399,5 MHz and perform the

measurement for the first 1 MHzsegment within range 2 400 MHz - BW to 2 400

MHz Reduce the centre frequency in 1 MHz steps and repeatthe measurements to

cover this whole range. The centre frequency of the last 1 MHz segment shall be

set to2 400 MHz - 2BW + 0,5MHz.

Step 5: (segment 2 400 MHz - 2BW to 2 400 MHz - BW)

•Change the centre frequency of the analyser to 2 399,5 MHz - BW and perform

the measurement for the first1 MHz segment within range 2 400 MHz - 2BW to 2



400 MHz - BW. Reduce the centre frequency in 1 MHzsteps and repeat the

measurements to cover this whole range. The centre frequency of the last 1 MHz

segmentshall be set to 2 400 MHz - 2BW + 0,5MHz.

Step 6:

•In case of conducted measurements on equipment with a single transmit chain,

the declared antenna assemblygain "G" in dBi shall be added to the results for

each of the 1 MHz segments and compared with the limitsprovided by the mask

given in figures 1 or 3. If more than one antenna assembly is intended for this

powersetting, the antenna with the highest gain shall be considered.

•In case of conducted measurements on smart antenna systems (equipment with

multiple transmit chains), themeasurements need to be repeated for each of the

active transmit chains. The declared antenna assembly gain"G" in dBi for a single

antenna shall be added to these results. If more than one antenna assembly is

intendedfor this power setting, the antenna with the highest gain shall be

considered. Comparison with the applicablelimits shall be done using any of the

options given below:

- Option 1: the results for each of the transmit chains for the corresponding 1 MHz

segments shall beadded. The additional beamforming gain "Y" in dB shall be

added as well and the resulting valuescompared with the limits provided by the

mask given in figures 1 or 3.

- Option 2: the limits provided by the mask given in figures 1 or 3 shall be

reduced by 10 x log10(Ach) andthe additional beamforming gain "Y" in dB. The

results for each of the transmit chains shall beindividually compared with these

reduced limits.

NOTE 2: Ach refers to the number of active transmit chains.It shall be recorded

whether the equipment complies with the mask provided in figures 1 or 3.



6.3. Test Result

Plot of the low frequency

0

-5

-10

-15

-20

-25

-30

-35

-40

-45

-50

-55

-60

-65

-70

-75

2397.974 2398.5 2399 2399.5 2400

Frequency in MHz

Lim

it in

dB

m



Plot of the high frequency

0

-5

-10

-15

-20

-25

-30

-35

-40

-45

-50

-55

-60

-65

-70

-75

2483.5 2484 2484.5 2485 2485.529

Frequency in MHz

Lim

it in

dB

m



7. TRANSMITTER UNWANTED EMISSIONS IN THE SPURIOUS

DOMAIN

7.1. Limits

Frequency range Maximum power,

e.r.p. (≤ 1 GHz)

e.i.r.p. (> 1 GHz)

(dBm)

Bandwidth

30MHz to 47MHz -36 100kHz


74MHz to 87.5MHz -36 100kHz

87.5MHz to 118MHz -54 100kHz





862MHz to 1GHz -36 100kHz

1GHz to 12.75GHz -30 1MHz

7.2. Test Procedure

In case of conducted measurements, the radio equipment shall be connected to the

measuring equipment via a suitableattenuator.

The spectrum in the spurious domain (see figures 1 or 3) shall be searched for

emissions that exceed the limit valuesgiven in tables 1 or 4 or that come to within

6 dB below these limits. Each occurrence shall be recorded.

The measurement procedure shall be as follows.

7.2.1 Pre-scan

The test procedure below shall be used to identify potential unwanted emissions

of the UUT.

Step 1:

The sensitivity of the spectrum analyser should be such that the noise floor is at

least 12 dB below the limits given intables 1 or 4.



Step 2:

The emissions over the range 30 MHz to 1 000 MHz shall be identified.Spectrum

analyser settings:

•Resolution bandwidth: 100 kHz

•Video bandwidth: 300 kHz

•Detector mode: Peak •Trace Mode: Max Hold

•Sweep Points: ≥ 9 970

NOTE 1: For spectrum analysers not supporting this high number of sweep points,

the frequency band may need tobe segmented.

•Sweep time: For non-continuous transmissions (duty cycle less than 100 %), the

sweep timeshall be sufficiently long, such that for each 100 kHz frequency step,

themeasurement time is greater than two transmissions of the UUT.

For Frequency Hopping equipment operating in a normal operating (hopping

notdisabled) mode, the sweep time shall be further increased to capture

multipletransmissions on the same hopping frequency in different hopping

sequences.

Allow the trace to stabilize. Any emissions identified during the sweeps above and

that fall within the 6 dB range belowthe applicable limit or above, shall be

individually measured using the procedure in clause 5.3.10.2.1.2 and compared

tothe limits given in tables 1 or 4.

Step 3:

The emissions over the range 1 GHz to 12,75 GHz shall be identified.

Spectrum analyser settings:

•Resolution bandwidth: 1 MHz

•Video bandwidth: 3 MHz



NOTE 2: For spectrum analysers not supporting this high number of sweep points,

the frequency band may need tobe segmented.

•Sweep time: For non-continuous transmissions (duty cycle less than 100 %), the

sweep timeshall be sufficiently long, such that for each 1 MHz frequency step, the

measurementtime is greater than two transmissions of the UUT.

For Frequency Hopping equipment operating in a normal operating (hopping

notdisabled) mode, the sweep time shall be further increased to capture

multipletransmissions on the same hopping frequency in different hopping

sequences.

Allow the trace to stabilize. Any emissions identified during the sweeps above

that fall within the 6 dB range below theapplicable limit or above, shall be

individually measured using the procedure in clause 5.3.10.2.1.2 and compared to

thelimits given in tables 1 or 4.

Frequency Hopping equipment may generate a block (or several blocks) of

spurious emissions anywhere within thespurious domain. If this is the case, only

the highest peak of each block of emissions shall be measured using theprocedure

in clause 5.3.10.2.1.2.

Step 4:




multiple transmit chains), thesteps 2 and 3 need to be repeated for each of the

active transmit chains (Ach).The limits used toidentifyemissions during this

pre-scan need to be reduced with 10 × log10 (Ach) (number of active

transmitchains)

7.2.2 Measurement of the emissions identified during the pre-scan

The steps below shall be used to accurately measure the individual unwanted

emissions identified during the pre-scanmeasurements above.

Step 1:

The level of the emissions shall be measured using the following spectrum

analyser settings:

•Centre Frequency: Frequency of emission identified during the pre-scan

•Resolution Bandwidth: 100 kHz (< 1 GHz) / 1 MHz (> 1 GHz)

•Video Bandwidth: 300 kHz (< 1 GHz) / 3 MHz (> 1 GHz)

•Frequency Span: Wide enough to capture each individual emission indentified

during the pre-scan

•Sweep mode: Continuous

•Sweep time: Auto

•Trigger: Free run

•Detector: RMS


Step 2:

In case of conducted measurements on smart antenna systems (equipment with

multiple transmit chains), the step 1needs to be repeated for each of the active

transmit chains (Ach).The trace data for each transmit chain has to be

recorded.Sum the power in each of the traces for each individual frequency bin.

Step 3:

Use the marker function to find the highest peak within the measurement trace and

record its value and its frequency.

Step 4:

The measured values shall be compared to the limits defined in tables 1 and 4.



7.3. Test Result

No. Frequency(MHz) ERP Level (dBm) Limit (dBm) Margin(dB)

Transmitter Operating Mode

Tx: Low Channel

1 4799.71 -60.74 -30 30.74

2 7204.23 -57.51 -30 27.51

3 9611.91 -58.58 -30 28.58

4 12008.23 -58.41 -30 28.41

5 12494.00 -57.67 -30 27.67

Tx: High Channel

1 4957.43 -61.14 -30 31.14

2 7432.56 -57.57 -30 27.57

3 9914.82 -58.62 -30 28.62

4 12397.01 -57.63 -30 27.63

5 12493.00 -58.13 -30 28.13

Test Condition: Temperature NT, Voltage NV



8 RECEIVER PARAMETERS

8.1 Limits

Receiver spurious emissions are emissions at any frequency when the equipment

is in receive mode.

The spurious emissions of the transmitter shall not exceed the values in following

tables for the EUT in this report.

Frequency range Maximum power(dBm)

e.r.p. (≤ 1 GHz)

e.i.r.p. (> 1 GHz)

Bandwidth

30MHz to 1GHz -57 100KHz

1GHz to 12.75GHz -47 1MHz

8.2 Test Procedure

In case of conducted measurements, the radio equipment shall be connected to the

measuring equipment via a suitableattenuator.

The spectrum in the spurious domain (see figures 1 or 3) shall be searched for

emissions that exceed the limit valuesgiven in tables 2 or 5 or that come to within

6 dB below these limits. Each occurrence shall be recorded.

The measurement procedure shall be as follows.

8.2.1 Pre-scan

The test procedure below shall be used to identify potential unwanted emissions

of the UUT.

Step 1:

The sensitivity of the spectrum analyser should be such that the noise floor is at

least 12 dB below the limits given intables 2 or 5.

Step 2:

The emissions over the range 30 MHz to 1 000 MHz shall be identified. Spectrum

analyser settings:

•Resolution bandwidth: 100 kHz

•Video bandwidth: 300 kHz





•Sweep time: Auto

Allow the trace to stabilize. Any emissions identified during the sweeps above and

that fall within the 6 dB range belowthe applicable limit or above, shall be

individually measured using the procedure in clause 5.3.11.2.1.2 and compared

tothe limits given in tables 2 or 5.

Step 3:

The emissions over the range 1 GHz to 12,75 GHz shall be identified.Spectrum

analyser settings:

•Resolution bandwidth: 1 MHz

•Video bandwidth: 3 MHz



•Sweep time: Auto

Allow the trace to stabilize. Any emissions identified during the sweeps above

that fall within the 6 dB range below theapplicable limit or above, shall be

individually measured using the procedure in clause 5.3.11.2.1.2 and compared to

thelimits given in tables 2 or 5.Frequency Hopping equipment may generate a

block (or several blocks) of spurious emissions anywhere within thespurious

domain. If this is the case, only the highest peak of each block of emissions shall

be measured using theprocedure in clause 5.3.11.2.1.2.

Step 4:


multiple receive chains), thesteps 2 and 3 need to be repeated for each of the

active receive chains (Ach).The limits used to identifyemissions during this

pre-scan need to be reduced with 10 × log10 (Ach) (number of active receive

chains).

8.2.2 Measurement of the emissions identified during the pre-scan

The steps below shall be used to accurately measure the individual unwanted

emissions identified during the pre-scanmeasurements above.

Step 1:

The level of the emissions shall be measured using the following spectrum

analyser settings:

•Centre Frequency: Frequency of emission identified during the pre-scan

•Resolution Bandwidth: 100 kHz (< 1 GHz) / 1 MHz (> 1 GHz)

•Video Bandwidth: 300 kHz (< 1 GHz) / 3 MHz (> 1 GHz)

•Frequency Span: Wide enough to capture each individual emission indentified

during the pre-scan

•Sweep mode: Continuous

•Sweep time: Auto

•Trigger: Free run

•Detector: RMS




Step 2:

In case of conducted measurements on smart antenna systems (equipment with

multiple receive chains), the step 1needs to be repeated for each of the active

receive chains (Ach).The trace data for each receive chain has to be recorded.Sum

the power in each of the traces for each individual frequency bin.

Step 3:

Use the marker function to find the highest peak within the measurement trace and

record its value and its frequency.

Step 4:

The measured values shall be compared to the limits defined in tables 2 and 5.

8.3 Test Result

No. Frequency(MHz) ERP Level (dBm) Limit (dBm) Margin(dB)

Receiver Operating Mode

Tx: Low Channel

1 4802.78 -63.24 -47 10.48

2 7201.43 -58.97 -47 12.35

3 9605.64 -55.24 -47 10.82

4 12008.65 -54.86 -47 8.87

5 12398.67 -54.96 -47 8.83

Tx: High Channel

1 4959.00 -63.05 -47 16.05

2 7434.22 -58.77 -47 11.77

3 9912.32 -55.05 -47 8.05

4 12392.68 -54.54 -47 7.54

5 12396.75 -54.73 -47 7.73

Test Condition: Temperature NT, Voltage NV


APPENDIX I

Photograph of the EUT


Front View of EUT (M/N: S-1)

Rear View of EUT (M/N: S-1)


Antenna

Inside View of EUT (M/N: S-1)

Inside View of EUT (M/N: S-1)

APPLICATION FOR LVD TEST REPORT

On Behalf of


Model No.: S-1, S-2, S-3, S-4, S-5, S-6

Prepared for :


Room 401, 19, BaoKang Road, The Pine Community, Cross The Street,



Date of Report: April 30, 2015

Report Number: HT2015430Ab-4

Report No. HT2015430Ab-4


TEST REPORT

IEC/EN 60950-1

Information technology equipment – Safety –

Part 1: General requirements

Report Number.....................................: HT2015430Ab-4

Tested by (name + signature) .................: Baird ..........................................................

Approved by (name + signature)............: Danny ..........................................................

Date of issue...........................................: April 30, 2015

Total number of pages .................................. 46

Testing Laboratory ..............................: Shenzhen OES Testing technology co., Ltd.

Address...................................................: Room 401, 19, BaoKang Road, The Pine Community, Cross The Street,


Applicant’s name..................................:

Address...................................................:

Manufacturer’s name……………….:

Address...................................................:

Test specification:

Standard .................................................: IEC 60950-1:2005 (2nd

Edition) + A1:2009

EN 60950-1:2006 + A11:2009 + A1:2010 + A12:2011+ A2:2013

Test procedure........................................: LVD

Non-standard test method…………..: N/A

Test Report Form No. ..........................: IEC60950_1B

Test Report Form(s) Originator..............: SGS Fimko Ltd

Master TRF ............................................: Dated 2010-04

Copyright © 2010 Worldwide System for Conformity Testing and Certification of Electrotechnical Equipment

and Components (IECEE), Geneva, Switzerland. All rights reserved.

This publication may be reproduced in whole or in part for non-commercial purposes as long as the IECEE is acknowledged as copyright owner

and source of the material. IECEE takes no responsibility for and will not assume liability for damages resulting from the reader's interpretation of the reproduced material due to its placement and context.

If this Test Report Form is used by non-IECEE members, the IECEE/IEC logo and the reference to the CB Scheme

procedure shall be removed.

This report is not valid as a CB Test Report unless signed by an approved CB Testing Laboratory and appended

to a CB Test Certificate issued by an NCB in accordance with IECEE 02.

Test item description........................... : Smart Device, Smart Finder

Trade Mark.............................................: N.A.

Model/Type reference .............................. : S-1, S-2, S-3, S-4, S-5, S-6

Model difference.....................................: N/A

Ratings ...................................................: 3.0V (supplied by battery);



Copy of marking plate (The artwork below may be only a draft.)

Smart Device, Smart Finder Model No.: S-1

Shenzhen Yijiu Technology Co., Ltd.

Test item particulars........................................................... :

Equipment mobility........................................................... :

Connection to the mains .................................................... :

Operating condition........................................................... :

[] movable [×] hand-held [] transportable

[] stationary [] for building-in [] direct plug-in

[] pluggable equipment [] type A [] type B

[] permanent connection

[] detachable power supply cord [] non-detachable power supply cord

[×] not directly connected to the mains

[×] continuous

[] rated operating / resting time:

Access location ................................................................ :

Over voltage category (OVC) ......................................... :

Mains supply tolerance (%) or absolute mains supply

values .............................................................................. :

Tested for IT power systems ........................................... :

[×] operator accessible

[] restricted access location

[] OVC I [] OVC II [] OVC III [] OVC IV [] other:

N/A

[] Yes [×] No

IT testing, phase-phase voltage (V) ................................. :

Class of equipment .......................................................... :

Considered current rating of protective device as part of

the building installlation (A) ........................................... :

Pollution degree (PD) ...................................................... :

IP protection class ........................................................... :

Altitude during operation (m) .......................................... :

Altitude of test laboratory (m) ......................................... :

Mass of equipment (kg) ................................................... :

[] Class I [] Class II [×] Class III [] Not classified

N/A

[] PD 1 [×] PD 2 [] PD 3

IPX0

<2000m

<2000m

0. 032.5kg

Possible test case verdicts:

- test case does not apply to the test object............................: N/A (or N)

- test object does meet the requirement .................................: P (Pass)

- test object does not meet the requirement...........................: F (Fail)

Testing ...................................................................................:

Date of receipt of test item.....................................................: April 22, 2015

Date(s) of performance of tests..............................................: April 22-30, 2015



General remarks:

The test results presented in this report relate only to the object tested.

This report shall not be reproduced, except in full, without the written approval of the Issuing testing laboratory.

"(see Enclosure #)" refers to additional information appended to the report.

"(see appended table)" refers to a table appended to the report.

Throughout this report a comma / point is used as the decimal separator.

General product information:

Brief description of the test sample:

-The equipment is supplied by a rechargeable lithium secondary battery pack of 3.0V, therefore, its circuits are

considered as SELV of class III equipment.

-The testing operating ambient temperature to testing sample is considered as 25°C without declaration from

manufacturer.

Abbreviations used in the report:

- Normal conditions N.C. - single fault conditions

S.F.C

- functional insulation OP - basic insulation BI - double insulation DI - supplementary insulation SI

- between parts of opposite polarity BOP - reinforced insulation RI

Indicate used abbreviations (if any):



IEC/EN 60950-1

Clause Requirement + Test Result - Remark Verdict

1 GENERAL P

1.5 Components P

1.5.1 General (see appended table 1.5.1) P

Comply with IEC 60950-1 or relevant component

standard

Components that were found to

affect safety aspects comply with

the requirements of this standard

or within the safety aspects of

the relevant IEC component

standards.

P

1.5.2 Evaluation and testing of components Components that are certified to

IEC and /or national standards

are used correctly within their

ratings. Components not covered

by IEC standards are tested

under the conditions present in

the equipment.

P

1.5.3 Thermal controls No thermal controls provided. N

1.5.4 Transformers No transformers N

1.5.5 Interconnecting cables P

1.5.6 Capacitors bridging insulation No such capacitor N

1.5.7 Resistors bridging insulation No such resistor N

1.5.7.1 Resistors bridging functional, basic or supplementary

insulation

N

1.5.7.2 Resistors bridging double or reinforced insulation

between a.c. mains and other circuits

N

1.5.7.3 Resistors bridging double or reinforced insulation

between a.c. mains and antenna or coaxial cable

N

1.5.8 Components in equipment for IT power systems No connection to the AC mains supply.

N

1.5.9 Surge suppressors No surge suppressors N

1.5.9.1 General N

1.5.9.2 Protection of VDRs N

1.5.9.3 Bridging of functional insulation by a VDR N

1.5.9.4 Bridging of basic insulation by a VDR N

1.5.9.5 Bridging of supplementary, double or reinforced

insulation by a VDR

N

1.6 Power interface P

1.6.1 AC power distribution systems N



IEC/EN 60950-1


1.6.2 Input current N

1.6.3 Voltage limit of hand-held equipment P

1.6.4 Neutral conductor N

1.7 Marking and instructions P

1.7.1 Power rating and identification markings P

1.7.1.1 Power rating marking Unit is not provided with a

means for direct connection to a

mains supply, it need not be

marked with any electrical rating

N

Multiple mains supply connections..........................: N

Rated voltage(s) or voltage range(s) (V) ...................... : N

Symbol for nature of supply, for d.c. only ..................... : N

Rated frequency or rated frequency range (Hz) ............ : N

Rated current (mA or A) ............................................... : N

1.7.1.2 Identification markings P

Manufacturer’s name or trade-mark or identification

mark ............................................................................. :

(See the second pages.) P

Model identification or type reference ......................... : (See the marking plate.) P

Symbol for Class II equipment only ............................ : Class III eqiupment N

Other markings and symbols ....................................... : Additional symbols or marking

does not give rise to

misunderstanding.

P

1.7.2 Safety instructions and marking Safety instruction provided. P

1.7.2.1 General P

1.7.2.2 Disconnect devices No connection to the mains

supply

N

1.7.2.3 Overcurrent protective device Not such equipments N

1.7.2.4 IT power distribution systems N

1.7.2.5 Operator access with a tool No such operator access area N

1.7.2.6 Ozone No ozone produced. N

1.7.3 Short duty cycles Continuous operation. N

1.7.4 Supply voltage adjustment ..........................................: No adjustment used N

Methods and means of adjustment; reference to

installation instructions ...............................................:

N

1.7.5 Power outlets on the equipment ..................................: No such outlet N

1.7.6 Fuse identification (marking, special fusing

characteristics, cross-reference) ..................................:

No such fuse N



IEC/EN 60950-1


1.7.7 Wiring terminals See below N

1.7.7.1 Protective earthing and bonding terminals ..................: No protective earthing terminals N

1.7.7.2 Terminals for a.c. mains supply conductors No such terminals N

1.7.7.3 Terminals for d.c. mains supply conductors N

1.7.8 Controls and indicators See below P

1.7.8.1 Identification, location and marking ............................: Switch and indicators were not

safety involved

N

1.7.8.2 Colours .......................................................................: N

1.7.8.3 Symbols according to IEC 60417 ................................ : N

1.7.8.4 Markings using figures ............................................. : N

1.7.9 Isolation of multiple power sources ............................ : N

1.7.10 Thermostats and other regulating devices .................. : Not used. N

1.7.11 Durability After rubbing test there was no

damage to the label. The

marking on the label did not

fade. There was neither curling

nor lifting of the label edge.

P

1.7.12 Removable parts No removable parts provided. N

1.7.13 Replaceable batteries ................................................. : P

Language(s) ............................................................... : Instructions and markings are in

English. Versions in other

languages will be provided when

national certificate approval

1.7.14 Equipment for restricted access locations.................... : Not limited for use in restricted

access locations.

N

2 PROTECTION FROM HAZARDS P

2.1 Protection from electric shock and energy hazards P

2.1.1 Protection in operator access areas Only SELV circuits involved and

no energized parts.

P

2.1.1.1 Access to energized parts P

Test by inspection ........................................................: N

Test with test finger (Figure 2A) ..................................: N

Test with test pin (Figure 2B) ......................................: N

Test with test probe (Figure 2C) ..................................: N

2.1.1.2 Battery compartments No TNV circuits N

2.1.1.3 Access to ELV wiring No ELV wiring in operator

accessible area.

N



IEC/EN 60950-1


Working voltage (Vpeak or Vrms); minimum distance

through insulation (mm)

(see appended tables 2.10.2 and

2.10.5)

2.1.1.4 Access to hazardous voltage circuit wiring No hazardous voltage wiring in

operator accessible area.

N

2.1.1.5 Energy hazards .............................................................: No hazardous energy level in

operator accessible area.

P

2.1.1.6 Manual controls No conductive shafts of

operating knobs and handles.

N

2.1.1.7 Discharge of capacitors in equipment No connetion to the mains N

Measured voltage (V); time-constant (s)........................:

2.1.1.8 Energy hazards – d.c. mains supply Equipment is not connected to

d.c. mains supply.

N

a) Capacitor connected to the d.c. mains supply ..........: N

b) Internal battery connected to the d.c. mains supply .: N

2.1.1.9 Audio amplifiers ..........................................................: See cl. 2.1.1.1

See separate test report IEC/EN

60065

N

2.1.2 Protection in service access areas No maintenance work in

operation mode necessary.

N

2.1.3 Protection in restricted access locations The unit is not limited to be used

in restricted access locations.

N

2.2 SELV circuits P

2.2.1 General requirements SELV circuits are safe during normal operation and under single fault, checked by inspection

P

2.2.2 Voltages under normal conditions (V) .........................: All accessible voltages are less than 42.4 Vpk or 60 Vdc and are classified as SELV.

P

2.2.3 Voltages under fault conditions (V) .............................: P

2.2.4 Connection of SELV circuits to other circuits ...........: SELV circuits P

2.3 TNV circuits

No TNV circuits.

N

2.3.1 Limits N

Type of TNV circuits .....................................................:

2.3.2 Separation from other circuits and from accessible parts N

2.3.2.1 General requirements N

2.3.2.2 Protection by basic insulation N



IEC/EN 60950-1


2.3.2.3 Protection by earthing N

2.3.2.4 Protection by other constructions .................................: N

2.3.3 Separation from hazardous voltages N

Insulation employed.......................................................:

2.3.4 Connection of TNV circuits to other circuits N

Insulation employed.......................................................:

2.3.5 Test for operating voltages generated externally N

2.4 Limited current circuits

No Limited current circuits

N

2.4.1 General requirements N

2.4.2 Limit values N

Frequency (Hz) ..............................................................:

Measured current (mA)..................................................:

Measured voltage (V) ....................................................:

Measured circuit capacitance (nF or µF) .......................:

2.4.3 Connection of limited current circuits to other circuits N

2.5 Limited power sources P

a) Inherently limited output N

b) Impedance limited output N

c) Regulating network limited output under normal

operating and single fault condition

P

d) Overcurrent protective device limited output N

Max. output voltage (V), max. output current (A), max.

apparent power (VA) .....................................................:

(see appended table 2.5)

Current rating of overcurrent protective device (A) .:

Use of integrated circuit (IC) current limiters (See Annex CC) N

2.6 Provisions for earthing and bonding

Class III equipment, no earthing and bonding parts.

N

2.6.1 Protective earthing N

2.6.2 Functional earthing N

2.6.3 Protective earthing and protective bonding conductors N

2.6.3.1 General N

2.6.3.2 Size of protective earthing conductors N



IEC/EN 60950-1


Rated current (A), cross-sectional area (mm2), AWG....:

2.6.3.3 Size of protective bonding conductors N

Rated current (A), cross-sectional area (mm2), AWG....:

Protective current rating (A), cross-sectional area (mm2),

AWG..............................................................................:

2.6.3.4 Resistance of earthing conductors and their terminations;

resistance (), voltage drop (V), test current (A),

duration (min) ................................................................:

N

2.6.3.5 Colour of insulation .......................................................: N

2.6.4 Terminals N

2.6.4.1 General N

2.6.4.2 Protective earthing and bonding terminals N

Rated current (A), type, nominal thread diameter (mm) :

2.6.4.3 Separation of the protective earthing conductor from

protective bonding conductors

N

2.6.5 Integrity of protective earthing N

2.6.5.1 Interconnection of equipment N

2.6.5.2 Components in protective earthing conductors and

protective bonding conductors

N

2.6.5.3 Disconnection of protective earth N

2.6.5.4 Parts that can be removed by an operator N

2.6.5.5 Parts removed during servicing N

2.6.5.6 Corrosion resistance N

2.6.5.7 Screws for protective bonding N

2.6.5.8 Reliance on telecommunication network or cable

distribution system

N

2.7 Overcurrent and earth fault protection in primary circuits

No connection to the mains supply.

N

2.7.1 Basic requirements N

Instructions when protection relies on building

installation

N

2.7.2 Faults not simulated in 5.3.7 N

2.7.3 Short-circuit backup protection N

2.7.4 Number and location of protective devices ...................: N

2.7.5 Protection by several devices N

2.7.6 Warning to service personnel.........................................: N



IEC/EN 60950-1


2.8 Safety interlocks

No safety interlock.

N

2.8.1 General principles N

2.8.2 Protection requirements N

2.8.3 Inadvertent reactivation N

2.8.4 Fail-safe operation N

Protection against extreme hazard N

2.8.5 Moving parts N

2.8.6 Overriding N

2.8.7 Switches, relays and their related circuits N

2.8.7.1 Separation distances for contact gaps and their related

circuits (mm) ................................................................ :

N

2.8.7.2 Overload test N

2.8.7.3 Endurance test N

2.8.7.4 Electric strength test (see appended table 5.2) N

2.8.8 Mechanical actuators N

2.9 Electrical insulation

2.9.1 Properties of insulating materials Natural rubber, asbestos or

hygroscopic materials are not

used.

P

2.9.2 Humidity conditioning Not required N

Relative humidity (%), temperature (°C) .....................:

2.9.3 Grade of insulation Class III unit, insulation is not

relied upon for safety

P

2.9.4 Separation from hazardous voltages N

Method(s) used ............................................................:

2.10 Clearances, creepage distances and distances through insulation

SELV circuits only, functional indulation required. See clause 5.3.4

N

2.10.1 General N

2.10.1.1 Frequency .....................................................................: N

2.10.1.2 Pollution degrees ..........................................................: N

2.10.1.3 Reduced values for functional insualtion N

2.10.1.4 Intervening unconnected conductive parts N



IEC/EN 60950-1


2.10.1.5 Insulation with varying dimensions N

2.10.1.6 Special separation requirements N

2.10.1.7 Insulation in circuits generating starting pulses N

2.10.2 Determination of working voltage N

2.10.2.1 General N

2.10.2.2 RMS working voltage N

2.10.2.3 Peak working voltage N

2.10.3 Clearances N

2.10.3.1 General N

2.10.3.2 Mains transient voltages N

a) AC mains supply ......................................................: N

b) Earthed d.c. mains supplies .....................................: N

c) Unearthed d.c. mains supplies ..................................: N

d) Battery operation .....................................................: N

2.10.3.3 Clearances in primary circuits N

2.10.3.4 Clearances in secondary circuits N

2.10.3.5 Clearances in circuits having starting pulses N

2.10.3.6 Transients from a.c. mains supply ................................: N

2.10.3.7 Transients from d.c. mains supply ...............................: N

2.10.3.8 Transients from telecommunication networks and cable

distribution systems .....................................................:

N

2.10.3.9 Measurement of transient voltage levels N

a) Transients from a mains suplply N

For an a.c. mains supply ...............................................: N

For a d.c. mains supply ................................................: N

b) Transients from a telecommunication network : N

2.10.4 Creepage distances N

2.10.4.1 General N

2.10.4.2 Material group and caomparative tracking index N

CTI tests.........................................................................:

2.10.4.3 Minimum creepage distances N

2.10.5 Solid insulation N

2.10.5.1 General N

2.10.5.2 Distances through insulation (see appended table 2.10.5) N

2.10.5.3 Insulating compound as solid insulation N



IEC/EN 60950-1


2.10.5.4 Semiconductor devices N

2.10.5.5. Cemented joints N

2.10.5.6 Thin sheet material – General N

2.10.5.7 Separable thin sheet material N

Number of layers (pcs)...................................................:

2.10.5.8 Non-separable thin sheet material N

2.10.5.9 Thin sheet material – standard test procedure N

Electric strength test

2.10.5.10 Thin sheet material – alternative test procedure N


2.10.5.11 Insulation in wound components N

2.10.5.12 Wire in wound components N

Working voltage ...........................................................: N

a) Basic insulation not under stress ..............................: N

b) Basic, supplemetary, reinforced insulation ..............: N

c) Compliance with Annex U .......................................: N

Two wires in contact inside wound component; angle

between 45 and 90 ....................................................:

N

2.10.5.13 Wire with solvent-based enamel in wound components N


Routine test N

2.10.5.14 Additional insulation in wound components N

Working voltage ...........................................................: N

- Basic insulation not under stress ................................: N

- Supplemetary, reinforced insulation ..........................: N

2.10.6 Construction of printed boards N

2.10.6.1 Uncoated printed boards N

2.10.6.2 Coated printed boards N

2.10.6.3 Insulation between conductors on the same inner surface

of a printed board

N

2.10.6.4 Insulation between conductors on different layers of a

printed board

N

Distance through insulation N

Number of insulation layers (pcs) ..................................: N

2.10.7 Component external terminations N

2.10.8 Tests on coated printed boards and coated components N



IEC/EN 60950-1


2.10.8.1 Sample preparation and preliminary inspection N

2.10.8.2 Thermal conditioning N

2.10.8.3 Electric strength test N

2.10.8.4 Abrasion resistance test N

2.10.9 Thermal cycling N

2.10.10 Test for Pollution Degree 1 environment and insulating

compound

N

2.10.11 Tests for semiconductor devices and cemented joints N

2.10.12 Enclosed and sealed parts N

3 WIRING, CONNECTIONS AND SUPPLY P

3.1 General P

3.1.1 Current rating and overcurrent protection P

3.1.2 Protection against mechanical damage Wires do not touch sharp edges

which could damage the

insulation and cause hazards.

P

3.1.3 Securing of internal wiring Internal wires secured P

3.1.4 Insulation of conductors No such cords N

3.1.5 Beads and ceramic insulators Not used N

3.1.6 Screws for electrical contact pressure No screw used for electrical

connection.

N

3.1.7 Insulating materials in electrical connections N

3.1.8 Self-tapping and spaced thread screws N

3.1.9 Termination of conductors All conductors are reliable

secured.

P

10 N pull test Complied. P

3.1.10 Sleeving on wiring Not used. N

3.2 Connection to a mains supply

No connection to the mains supply

N

3.2.1 Means of connection N

3.2.1.1 Connection to an a.c. mains supply N

3.2.1.2 Connection to a d.c. mains supply N

3.2.2 Multiple supply connections N

3.2.3 Permanently connected equipment N

Number of conductors, diameter of cable and conduits

(mm) ............................................................................:



IEC/EN 60950-1


3.2.4 Appliance inlets N

3.2.5 Power supply cords N

3.2.5.1 AC power supply cords N

Type .............................................................................:

Rated current (A), cross-sectional area (mm2), AWG :

3.2.5.2 DC power supply cords N

3.2.6 Cord anchorages and strain relief N

Mass of equipment (kg), pull (N) ...............................:

Longitudinal displacement (mm) .................................:

3.2.7 Protection against mechanical damage N

3.2.8 Cord guards N

Diameter or minor dimension D (mm); test mass (g) ..:

Radius of curvature of cord (mm)..................................:

3.2.9 Supply wiring space N

3.3 Wiring terminals for connection of external conductors

No wiring terminals for supply connection.

N

3.3.1 Wiring terminals N

3.3.2 Connection of non-detachable power supply cords N

3.3.3 Screw terminals N

3.3.4 Conductor sizes to be connected N

Rated current (A), cord/cable type, cross-sectional area

(mm2) .............................................................................:

3.3.5 Wiring terminal sizes N

Rated current (A), type, nominal thread diameter (mm)

.......................................................................................:

3.3.6 Wiring terminal design N

3.3.7 Grouping of wiring terminals N

3.3.8 Stranded wire N

3.4 Disconnection from the mains supply

No connections to the mains supply

N

3.4.1 General requirement N

3.4.2 Disconnect devices N

3.4.3 Permanently connected equipment N

3.4.4 Parts which remain energized N



IEC/EN 60950-1


3.4.5 Switches in flexible cords N

3.4.6 Number of poles - single-phase and d.c. equipment N

3.4.7 Number of poles - three-phase equipment N

3.4.8 Switches as disconnect devices N

3.4.9 Plugs as disconnect devices N

3.4.10 Interconnected equipment N

3.4.11 Multiple power sources N

3.5 Interconnection of equipment P

3.5.1 General requirements P

3.5.2 Types of interconnection circuits .................................: SELV P

3.5.3 ELV circuits as interconnection circuits N

3.5.4 Data ports for additional equipment P

4 PHYSICAL REQUIREMENTS P

4.1 Stability N

Angle of 10 Hand-held appliance N

Test force (N) ...............................................................: Not floor-standing unit N

4.2 Mechanical strength P

4.2.1 General See below. After tests, unit

complies with the requirements

of sub-clauses 2.1.1

P

Rack-mounted equipment. (see Annex DD) N

4.2.2 Steady force test, 10 N P

4.2.3 Steady force test, 30 N N

4.2.4 Steady force test, 250 N 250 N applied to external

enclosure. No energy or other

hazards.

P

4.2.5 Impact test N

Fall test N

Swing test N

4.2.6 Drop test; height (mm) .................................................: The product was subjected to

three drops from the height of

1m onto hardwood at 13mm

thick.

P



IEC/EN 60950-1


4.2.7 Stress relief test Enclosure of thermal plastic test

at 70°C for 7h, no hazard

P

4.2.8 Cathode ray tubes No CRT provided. N

Picture tube separately certified ...................................: N

4.2.9 High pressure lamps No high pressure lamps

provided.

N

4.2.10 Wall or ceiling mounted equipment; force (N) ............: N

4.2.11 Rotating solid media N

Test to cover on the door…………………………….: N

4.3 Design and construction P

4.3.1 Edges and corners Edges or corners are rounded. P

4.3.2 Handles and manual controls; force (N) .................... : No handles or manual controls

provided.

N

4.3.3 Adjustable controls No adjustable controls provided. N

4.3.4 Securing of parts Mechanical fixings in such a way

designed that they will withstand

mechanical stress occurring in

normal use.

P

4.3.5 Connection by plugs and sockets N

4.3.6 Direct plug-in equipment Not direct plug-in equipment N

Torque .........................................................................:

Compliance with the relevant mains plug standard .....: N

4.3.7 Heating elements in earthed equipment No heating elements provided. N

4.3.8 Batteries See appended table 4.3.8 P

- Overcharging of a rechargeable battery P

- Unintentional charging of a non-rechargeable battery N

- Reverse charging of a rechargeable battery P

- Excessive discharging rate for any battery P

4.3.9 Oil and grease No oil or grease provided. N

4.3.10 Dust, powders, liquids and gases N

4.3.11 Containers for liquids or gases No container for liquids or gases

provided.

N

4.3.12 Flammable liquids .......................................................: No flammable liquids provided. N

Quantity of liquid (l) ...................................................: N

Flash point (C) ...........................................................: N

4.3.13 Radiation No radiation. P



IEC/EN 60950-1


4.3.13.1 General N

4.3.13.2 Ionizing radiation N

Measured radiation (pA/kg) ........................................:

Measured high-voltage (kV) ........................................:

Measured focus voltage (kV) .......................................:

CRT markings ..............................................................:

4.3.13.3 Effect of ultraviolet (UV) radiation on materials N

Part, property, retention after test, flammability

classification ...............................................................:

N

4.3.13.4 Human exposure to ultraviolet (UV) radiation ...........: N

4.3.13.5 Lasers (including laser diodes) and LEDs N

4.3.13.5.1 Lasers (including laser laser diodes) (see separate test report of

IEC/EN 60825-1 /

IEC/EN 60825-2)

N

Laser class ...................................................................:

4.3.13.5.2 Light emitting diodes (LEDs) N

4.3.13.6 Other types ..................................................................: N

4.4 Protection against hazardous moving parts

No hazardous moving parts.

N

4.4.1 General N

4.4.2 Protection in operator access areas .............................: N

Household and home/office document/media shredders (see Annex EE) N

4.4.3 Protection in restricted access locations ......................: N

4.4.4 Protection in service access areas N

4.4.5 Protection against moving fan blades N

4.4.5.1 General N

Not considered to cause pain or injury. a)………….: N

Is considered to cause pain, not injury. b) …………: N

Considered to cause injury.

c) …………:

N

4.4.5.2 Protection for users N

Use of symbol or warning ……………………………: N

4.4.5.3 Protection for service persons N

Use of symbol or warning ……………………………: N



IEC/EN 60950-1


4.5 Thermal requirements P

4.5.1 General P

4.5.2 Temperature tests P

Normal load condition per Annex L ...........................:

4.5.3 Temperature limits for materials (see appended table 4.5) P

4.5.4 Touch temperature limits (see appended table 4.5) P

4.5.5 Resistance to abnormal heat ........................................: No thermoplastic material at

hazardous voltages.

N

4.6 Openings in enclosures N

4.6.1 Top and side openings N

Dimensions (mm) ........................................................:

4.6.2 Bottoms of fire enclosures No need of fire enclosure (See

cl. 4.7.2.2).

N

Construction of the bottomm, dimensions (mm) ........:

4.6.3 Doors or covers in fire enclosures N

4.6.4 Openings in transportable equipment N

4.6.4.1 Constructional design measures N

Dimensions (mm) ........................................................:

4.6.4.2 Evaluation measures for larger openings N

4.6.4.3 Use of metallized parts N

4.6.5 Adhesives for constructional purposes N

Conditioning temperature (C), time (weeks) ...............:

4.7 Resistance to fire P

4.7.1 Reducing the risk of ignition and spread of flame P

Method 1, selection and application of components

wiring and materials

(see appended table 4.7) P

Method 2, application of all of simulated fault condition

tests

(see appended table 5.3) N

4.7.2 Conditions for a fire enclosure P

4.7.2.1 Parts requiring a fire enclosure Lithium battery is not in

conformity with the LPS power

units

P

4.7.2.2 Parts not requiring a fire enclosure N

4.7.3 Materials P

4.7.3.1 General P



IEC/EN 60950-1


4.7.3.2 Materials for fire enclosures V-1 or better P

4.7.3.3 Materials for components and other parts outside fire

enclosures

N

4.7.3.4 Materials for components and other parts inside fire

enclosures V-2, HF-2 or better P

4.7.3.5 Materials for air filter assemblies No air filters assemblies. N

4.7.3.6 Materials used in high-voltage components No high voltage component. N

5 ELECTRICAL REQUIREMENTS AND SIMULATED ABNORMAL CONDITIONS P

5.1 Touch current and protective conductor current

No connection to the mains supply, SELV circuits only.

N

5.1.1 General (see appended Table 5.1) N

5.1.2 Configuration of equipment under test (EUT) N

5.1.2.1 Single connection to an a.c. mains supply N

5.1.2.2 Redundant multiple connections to an a.c. mains supply N

5.1.2.3 Simultaneous multiple connections to an a.c. mains

supply

N

5.1.3 Test circuit N

5.1.4 Application of measuring instrument N

5.1.5 Test procedure N

5.1.6 Test measurements N

Supply voltage (V) ......................................................:

Measured touch current (mA) .....................................:

Max. allowed touch current (mA) ...............................:

Measured protective conductor current (mA) .............:

Max. allowed protective conductor current (mA).........:

5.1.7 Equipment with touch current exceeding 3,5 mA N

5.1.7.1 General ........................................................................: N

5.1.7.2 Simultaneous multiple connections to the supply N

5.1.8 Touch currents to telecommunication networks and

cable distribution systems and from telecommunication

networks

N

5.1.8.1 Limitation of the touch current to a telecommunication

network or to a cable distribution system

N

Supply voltage (V) ......................................................:

Measured touch current (mA) .....................................:

Max. allowed touch current (mA) ...............................:



IEC/EN 60950-1


5.1.8.2 Summation of touch currents from telecommunication

networks

N

a) EUT with earthed telecommunication ports ...........: N

b) EUT whose telecommunication ports have no

reference to protective earth

N

5.2 Electric strength N

5.2.1 General (see appended table 5.2) N

5.2.2 Test procedure N

5.3 Abnormal operating and fault conditions P

5.3.1 Protection against overload and abnormal operation P

5.3.2 Motors N

5.3.3 Transformers No transformers N

5.3.4 Functional insulation.....................................................: Method c, (see appended table

5.3)

P

5.3.5 Electromechanical components No electromechanical

component

N

5.3.6 Audio amplifiers in ITE ..............................................: N

5.3.7 Simulation of faults (see appended table 5.3) P

5.3.8 Unattended equipment None of them are used. N

5.3.9 Compliance criteria for abnormal operating and fault

conditions No fire propagated beyond the

equipment. No molten metal was

emitted.

P

5.3.9.1 During the tests Ditto P

5.3.9.2 After the tests Ditto P

6 CONNECTION TO TELECOMMUNICATION NETWORKS

No connection to telecommunication networks

N

6.1 Protection of telecommunication network service persons, and users of other equipment

connected to the network, from hazards in the equipment

N

6.1.1 Protection from hazardous voltages N

6.1.2 Separation of the telecommunication network from earth N

6.1.2.1 Requirements (see appended table 5.2) N

Supply voltage (V) ......................................................:

Current in the test circuit (mA) .............................:

6.1.2.2 Exclusions ...................................................................: N



IEC/EN 60950-1


6.2 Protection of equipment users from overvoltages on telecommunication networks N

6.2.1 Separation requirements N

6.2.2 Electric strength test procedure N

6.2.2.1 Impulse test (see appended table 5.2) N

6.2.2.2 Steady-state test (see appended table 5.2) N

6.2.2.3 Compliance criteria N

6.3 Protection of the telecommunication wiring system from overheating N

Max. output current (A) ..............................................:

Current limiting method ..............................................:

7 CONNECTION TO CABLE DISTRIBUTION SYSTEMS

No connection to cable distribution systems

N

7.1 General N

7.2 Protection of cable distribution system service persons,

and users of other equipment connected to the system,

from hazardous voltages in the equipment

N

7.3 Protection of equipment users from overvoltages on the

cable distribution system

N

7.4 Insulation between primary circuits and cable

distribution systems

N

7.4.1 General N

7.4.2 Voltage surge test (see appended table 5.2) N

7.4.3 Impulse test (see appended table 5.2) N

A ANNEX A, TESTS FOR RESISTANCE TO HEAT AND FIRE N

A.1 Flammability test for fire enclosures of movable

equipment having a total mass exceeding 18 kg, and of

stationary equipment (see 4.7.3.2)

N

A.1.1 Samples ........................................................................ :

Wall thickness (mm) .................................................... :

A.1.2 Conditioning of samples; temperature (C) ................ : N

A.1.3 Mounting of samples .................................................. : N

A.1.4 Test flame (see IEC 60695-11-3) N

Flame A, B, C or D ..................................................... :

A.1.5 Test procedure N



IEC/EN 60950-1


A.1.6 Compliance criteria N

Sample 1 burning time (s) ............................................ :



A.2 Flammability test for fire enclosures of movable equipment having a total mass not

exceeding 18 kg, and for material and components located inside fire enclosures (see 4.7.3.2

and 4.7.3.4)

N

A.2.1 Samples, material ......................................................... :

Wall thickness (mm) .................................................... :

A.2.2 Conditioning of samples; temperature (°C) ................ : N

A.2.3 Mounting of samples .................................................. : N

A.2.4 Test flame (see IEC 60695-11-4) N

Flame A, B or C ......................................................... :

A.2.5 Test procedure N

A.2.6 Compliance criteria N




A.2.7 Alternative test acc. to IEC 60695-11-5, cl. 5 and 9 N




A.3 Hot flaming oil test (see 4.6.2) N

A.3.1 Mounting of samples N

A.3.2 Test procedure

A.3.3 Compliance criterion N

B ANNEX B, MOTOR TESTS UNDER ABNORMAL CONDITIONS (see 4.7.2.2 and

5.3.2)

N

B.1 General requirements N

Position ....................................................................... :

Manufacturer .............................................................. :

Type ............................................................................ :

Rated values ............................................................. :

B.2 Test conditions N



IEC/EN 60950-1


B.3 Maximum temperatures (see appended table 5.3) N

B.4 Running overload test (see appended table 5.3) N

B.5 Locked-rotor overload test N

Test duration (days) .................................................... :

Electric strength test: test voltage (V) ........................ :

B.6 Running overload test for d.c. motors in secondary

circuits

N

B.6.1 General N

B.6.2 Test procedure N

B.6.3 Alternative test procedure N

B.6.4 Electric strength test; test voltage (V) ........................ : N

B.7 Locked-rotor overload test for d.c. motors in secondary

circuits

N

B.7.1 General N

B.7.2 Test procedure N

B.7.3 Alternative test procedure N

B.7.4 Electric strength test; test voltage (V) ....................... : N

B.8 Test for motors with capacitors (see appended table 5.3) N

B.9 Test for three-phase motors (see appended table 5.3) N

B.10 Test for series motors N

Operating voltage (V) ................................................. :

C ANNEX C, TRANSFORMERS (see 1.5.4 and 5.3.3) N

Position ....................................................................... :

Manufacturer .............................................................. :

Type ............................................................................ :

Rated values ............................................................. :

Method of protection .................................................... :

C.1 Overload test (see appended table 5.3) N

C.2 Insulation (see appended tables 5.2 and C2) N

Protection from displacement of windings................... : N

D ANNEX D, MEASURING INSTRUMENTS FOR TOUCH-CURRENT TESTS

(see 5.1.4)

N

D.1 Measuring instrument Figure D.1 used N

D.2 Alternative measuring instrument N



IEC/EN 60950-1


E ANNEX E, TEMPERATURE RISE OF A WINDING (see 1.4.13) N

F ANNEX F, MEASUREMENT OF CLEARANCES AND CREEPAGE DISTANCES

(see 2.10 and Annex G)

N

G ANNEX G, ALTERNATIVE METHOD FOR DETERMINING MINIMUM

CLEARANCES

N

G.1 Clearances N

G.1.1 General N

G.1.2 Summary of the procedure for determining minimum

clearances

N

G.2 Determination of mains transient voltage (V) N

G.2.1 AC mains supply ........................................................ : N

G.2.2 Earthed d.c. mains supplies ........................................ : N

G.2.3 Unearthed d.c. mains supplies .................................... : N

G.2.4 Battery operation ........................................................ : N

G.3 Determination of telecommunication network transient

voltage (V) .................................................................. :

N

G.4 Determination of required withstand voltage (V) N

G.4.1 Mains transients and internal repetitive peaks ............ : N

G.4.2 Transients from telecommunication networks ............ : N

G.4.3 Combination of transients N

G.4.4 Transients from cable distribution systems N

G.5 Measurement of transient voltages (V) N

a) Transients from a mains supply N

For an a.c. mains supply N

For a d.c. mains supply N

b) Transients from a telecommunication network N

G.6 Determination of minimum clearances ....................... : N

H ANNEX H, IONIZING RADIATION (see 4.3.13) N

J ANNEX J, TABLE OF ELECTROCHEMICAL POTENTIALS (see 2.6.5.6) N

Metal(s) used ............................................................... :



IEC/EN 60950-1


K ANNEX K, THERMAL CONTROLS (see 1.5.3 and 5.3.8) N

K.1 Making and breaking capacity N

K.2 Thermostat reliability; operating voltage (V) ..............: N

K.3 Thermostat endurance test; operating voltage (V) ......: N

K.4 Temperature limiter endurance; operating voltage (V) : N

K.5 Thermal cut-out reliability N

K.6 Stability of operation (see appended table 5.3) N

L ANNEX L, NORMAL LOAD CONDITIONS FOR SOME TYPES OF ELECTRICAL

BUSINESS EQUIPMENT (see 1.2.2.1 and 4.5.2)

P

L.1 Typewriters N

L.2 Adding machines and cash registers N

L.3 Erasers N

L.4 Pencil sharpeners N

L.5 Duplicators and copy machines N

L.6 Motor-operated files N

L.7 Other business equipment P

M ANNEX M, CRITERIA FOR TELEPHONE RINGING SIGNALS (see 2.3.1) N

M.1 Introduction N

M.2 Method A N

M.3 Method B N

M.3.1 Ringing signal N

M.3.1.1 Frequency (Hz) ........................................................... :

M.3.1.2 Voltage (V) ................................................................. :

M.3.1.3 Cadence; time (s), voltage (V) .................................... :

M.3.1.4 Single fault current (mA) ........................................... :

M.3.2 Tripping device and monitoring voltage .................... : N

M.3.2.1 Conditions for use of a tripping device or a monitoring

voltage

N

M.3.2.2 Tripping device N

M.3.2.3 Monitoring voltage (V) .............................................. : N

N ANNEX N, IMPULSE TEST GENERATORS (see 1.5.7.2, 1.5.7.3, 2.10.3.9, 6.2.2.1,

7.3.2, 7.4.3 and Clause G.5)

N

N.1 ITU-T impulse test generators N



IEC/EN 60950-1


N.2 IEC 60065 impulse test generator N

P ANNEX P, NORMATIVE REFERENCES

Q ANNEX Q, Voltage dependent resistors (VDRs) (see 1.5.9.1) N

a) Preferred climatic categories .................................. : N

b) Maximum continuous voltage ................................ : N

c) Pulse current ........................................................... : N

R ANNEX R, EXAMPLES OF REQUIREMENTS FOR QUALITY CONTROL

PROGRAMMES

N

R.1 Minimum separation distances for unpopulated coated

printed boards (see 2.10.6.2)

N

R.2 Reduced clearances (see 2.10.3) N

S ANNEX S, PROCEDURE FOR IMPULSE TESTING (see 6.2.2.3) N

S.1 Test equipment N

S.2 Test procedure N

S.3 Examples of waveforms during impulse testing N

T ANNEX T, GUIDANCE ON PROTECTION AGAINST INGRESS OF WATER

(see 1.1.2)

N

See separate test report

U ANNEX U, INSULATED WINDING WIRES FOR USE WITHOUT INTERLEAVED

INSULATION (see 2.10.5.4)

N

See separate test report

V ANNEX V, AC POWER DISTRIBUTION SYSTEMS (see 1.6.1) N

V.1 Introduction N

V.2 TN power distribution systems N

W ANNEX W, SUMMATION OF TOUCH CURRENTS N

W.1 Touch current from electronic circuits N

W.1.1 Floating circuits N

W.1.2 Earthed circuits N



IEC/EN 60950-1


W.2 Interconnection of several equipments N

W.2.1 Isolation N

W.2.2 Common return, isolated from earth N

W.2.3 Common return, connected to protective earth N

X ANNEX X, MAXIMUM HEATING EFFECT IN TRANSFORMER TESTS

(see clause C.1)

N

X.1 Determination of maximum input current N

X.2 Overload test procedure N

Y ANNEX Y, ULTRAVIOLET LIGHT CONDITIONING TEST (see 4.3.13.3) N

Y.1 Test apparatus ............................................................. : N

Y.2 Mounting of test samples ............................................ : N

Y.3 Carbon-arc light-exposure apparatus .......................... : N

Y.4 Xenon-arc light exposure apparatus ............................ : N

Z ANNEX Z, OVERVOLTAGE CATEGORIES (see 2.10.3.2 and Clause G.2) N

AA ANNEX AA, MANDREL TEST (see 2.10.5.8) N

BB ANNEX BB, CHANGES IN THE SECOND EDITION

CC ANNEX CC, Evaluation of integrated circuit (IC) current limiters N

CC.1 General N

CC.2 Test program 1……………………………………….: N

CC.3 Test program 2……………………………………….: N

DD ANNEX DD, Requirements for the mounting means of rack-mounted equipment N

DD.1 General N

DD.2 Mechanical strength test, variable N………………..: N

DD.3 Mechanical strength test, 250N, including end

stops……………………………………………………:

N

DD.4 Compliance……………………………………………: N

EE ANNEX EE, Household and home/office document/media shredders N

EE.1 General N

EE.2 Markings and instructions N



IEC/EN 60950-1


Use of markings or symbols…………………………: N

Information of user instructions, maintenance and/or

servicing instructions…………………………:

N

EE.3 Inadvertent reactivation test…………………………: N

EE.4 Disconnection of power to hazardous moving parts: N

Use of markings or symbols…………………………: N

EE.5 Protection against hazardous moving parts N

Test with test finger (Figure 2A) ……………………: N

Test with wedge probe (Figure EE1 and EE2) ……: N



IEC/EN 60950-1


EN 60950-1:2006 – COMMON MODIFICATIONS

Contents Add the following annexes:

Annex ZA (normative) Normative references to international publications

with their corresponding European publications

Annex ZB (normative) Special national conditions

Annex ZC (informative) A-deviations

P

General Delete all the “country” notes in the reference document according to the following list:

1.4.8 Note 2 1.5.1 Note 2 & 3 1.5.7.1 Note

1.5.8 Note 2 1.5.9.4 Note 1.7.2.1 Note 4, 5 & 6 2.2.3 Note 2.2.4 Note 2.3.2 Note

2.3.2.1 Note 2 2.3.4 Note 2 2.6.3.3 Note 2 & 3

2.7.1 Note 2.10.3.2 Note 2 2.10.5.13 Note 3

3.2.1.1 Note 3.2.4 Note 3. 2.5.1 Note 2

4.3.6 Note 1 & 2 4.7 Note 4 4.7.2.2 Note

4.7.3.1 Note 2 5.1.7.1 Note 3 & 4 5.3.7 Note 1

6 Note 2 & 5 6.1.2.1 Note 2 6.1.2.2 Note

6.2.2 Note 6. 2.2.1 Note 2 6.2.2.2 Note 7.1 Note 3 7.2 Note 7.3 Note 1 & 2

G.2.1 Note 2 Annex H Note 2

P

1.3.Z1 Add the following subclause:

1.3.Z1 Exposure to excessive sound pressure

The apparatus shall be so designed and constructed as to present no danger when used for

its intended purpose, either in normal operating conditions or under fault conditions,

particularly providing protection against exposure to excessive sound pressures from

headphones or earphones.

NOTE Z1 A new method of measurement is described in EN 50332-1, Sound system equipment:

Headphones and earphones associated with portable audio equipment – Maximum sound pressure

level measurement methodology and limit considerations – Part 1: General method for “one package

equipment”, and in EN 50332-2, Sound system equipment: Headphones and earphones associated

with portable audio equipment – Maximum sound pressure level measurement methodology and limit

considerations – Part 2: Guidelines to associate sets with headphones coming from different

manufacturers.

P

1.5.1 Add the following NOTE:

NOTE Z1 The use of certain substances in electrical and electronic equipment is restricted within the

EU: see Directive 2002/95/EC

P

1.7.2.1 Add the following NOTE:

NOTE Z1 In addition, the instructions shall include, as far as applicable, a warning that excessive

sound pressure from earphones and headphones can cause hearing loss

N

2.7.1 Replace the subclause as follows:

Basic requirements

To protect against excessive current, short-circuits and earth faults in PRIMARY

CIRCUITS, protective devices shall be included either as integral parts of the equipment or

as parts of the building installation, subject to the following, a), b) and c):

a) except as detailed in b) and c), protective devices necessary to comply with the

requirements of 5.3 shall be included as parts of the equipment;

b) for components in series with the mains input to the equipment such as the supply cord,

appliance coupler, r.f.i. filter and switch, short-circuit and earth fault protection may be

provided by protective devices in the building installation;

N



IEC/EN 60950-1


c) it is permitted for PLUGGABLE EQUIPMENT TYPE B or PERMANENTLY

CONNECTED EQUIPMENT, to rely on dedicated overcurrent and short-circuit protection

in the building installation, provided that the means of protection, e.g. fuses or circuit

breakers, is fully specified in the installation instructions.

If reliance is placed on protection in the building installation, the installation instructions

shall so state, except that for PLUGGABLE EQUIPMENT TYPE A the building

installation shall be regarded as providing protection in accordance with the rating of the

wall socket outlet.

2.7.2 This subclause has been declared ‘void’. P

3.2.3 Delete the NOTE in Table 3A, and delete also in this table the conduit sizes in parentheses. N

3.2.5.1 Replace “60245 IEC 53” by “H05 RR-F”; “60227 IEC 52” by “H03 VV-F or H03 VVH2-F”;

“60227 IEC 53” by “H05 VV-F or H05 VVH2-F2”.

In Table 3B, replace the first four lines by the following:

| Up to and including 6 | 0,75 a)

|

| Over 6 up to and including 10 | (0,75) b)

1,0 |

| Over 10 up to and including 16 | (1,0) c)

1,5 |

In the conditions applicable to Table 3B delete the words “in some countries” in condition

a).

In NOTE 1, applicable to Table 3B, delete the second sentence.

N

3.3.4 In Table 3D, delete the fourth line: conductor sizes for 10 to 13 A, and replace with the

following:

| Over 10 up to and including 16 | 1,5 to 2,5 | 1,5 to 4 |

Delete the fifth line: conductor sizes for 13 to 16 A.

N

4.3.13.6 Add the following NOTE:

NOTE Z1 Attention is drawn to 1999/519/EC: Council Recommendation on the limitation of

exposure of the general public to electromagnetic fields 0 Hz to 300 GHz. Standards taking into

account this Recommendation which demonstrate compliance with the applicable EU Directive are

indicated in the OJEC.

N

Annex H Replace the last paragraph of this annex by:

At any point 10 cm from the surface of the OPERATOR ACCESS AREA, the dose rate

shall not exceed 1 μSv/h (0,1 Mr/h) (see NOTE). Account is taken of the background level.

Replace the notes as follows:

NOTE These values appear in Directive 96/29/Euratom.

Delete NOTE 2.

N

Biblio-

graphy

Additional EN standards.

ZA NORMATIVE REFERENCES TO INTERNATIONAL PUBLICATIONS WITH THEIR

CORRESPONDING EUROPEAN PUBLICATIONS

ZB SPECIAL NATIONAL CONDITIONS N

1.2.4.1 In Denmark, certain types of Class I appliances (see 3.2.1.1) may be provided with a plug

not establishing earthing conditions when inserted into Danish socket-outlets.

N



IEC/EN 60950-1


1.5.7.1 In Finland, Norway and Sweden, resistors bridging BASIC INSULATION in CLASS I

PLUGGABLE EQUIPMENT TYPE A must comply with the requirements in 1.5.7.2.

N

1.5.8 In Norway, due to the IT power system used (see annex V, Figure V.7), capacitors are

required to be rated for the applicable line-to-line voltage (230 V).

N

1.5.9.4 In Finland, Norway and Sweden, the third dashed sentence is applicable only to equipment

as defined in 6.1.2.2 of this annex.

N

1.7.2.1 In Finland, Norway and Sweden, CLASS I PLUGGABLE EQUIPMENT TYPE A

intended for connection to other equipment or a network shall, if safety relies on connection

to protective earth or if surge suppressors are connected between the network terminals and

accessible parts, have a marking stating that the equipment must be connected to an earthed

mains socket-outlet.

The marking text in the applicable countries shall be as follows:

In Finland : « Laite on liitettävä suojamaadoituskoskettimilla varustettuun pistorasiaan »

In Norway: “Apparatet må tilkoples jordet stikkontakt”

In Sweden: “Apparaten skall anslutas till jordat uttag”

N

1.7.5 In Denmark, socket-outlets for providing power to other equipment shall be in accordance

with the Heavy Current Regulations, Section 107-2-D1, Standard Sheet DK 1-3a, DK 1-5a

or DK 1-7a, when used on Class I equipment. For STATIONARY EQUIPMENT the

socket-outlet shall be in accordance with Standard Sheet DK 1-1b or DK 1-5a.

N

2.2.4 In Norway, for requirements see 1.7.2.1, 6.1.2.1 and 6.1.2.2 of this annex. N

2.3.2 In Finland, Norway and Sweden there are additional requirements for the insulation. See

6.1.2.1 and 6.1.2.2 of this annex.

N

2.3.4 In Norway, for requirements see 1.7.2.1, 6.1.2.1 and 6.1.2.2 of this annex. N

2.6.3.3 In the United Kingdom, the current rating of the circuit shall be taken as 13 A, not 16 A. N

2.7.1 In the United Kingdom, to protect against excessive currents and short-circuits in the

PRIMARY CIRCUIT of DIRECT PLUG-IN EQUIPMENT, tests according to 5.3 shall be

conducted, using an external protective device rated 30 A or 32 A. If these tests fail,

suitable protective devices shall be included as integral parts of the DIRECT PLUG-IN

EQUIPMENT, so that the requirements of 5.3 are met.

N

2.10.5.13 In Finland, Norway and Sweden, there are additional requirements for the insulation, see

6.1.2.1 and 6.1.2.2 of this annex.

N

3.2.1.1 In Switzerland, supply cords of equipment having a RATED CURRENT not exceeding 10

A shall be provided with a plug complying with SEV 1011 or IEC 60884-1 and one of the

following dimension sheets:

SEV 6532-2.1991 Plug Type 15 3P+N+PE 250/400 V, 10 A

SEV 6533-2.1991 Plug Type 11 L+N 250 V, 10 A

SEV 6534-2.1991 Plug Type 12 L+N+PE 250 V, 10 A

In general, EN 60309 applies for plugs for currents exceeding 10 A. However, a 16 A plug

and socket-outlet system is being introduced in Switzerland, the plugs of which are

according to the following dimension sheets, published in February 1998:

SEV 5932-2.1998 Plug Type 25 3L+N+PE 230/400 V, 16 A

SEV 5933-2.1998 Plug Type 21 L+N 250 V, 16 A

SEV 5934-2.1998 Plug Type 23 L+N+PE 250 V, 16 A

N



IEC/EN 60950-1


3.2.1.1 In Denmark, supply cords of single-phase equipment having a rated current not

exceeding13 A shall be provided with a plug according to the Heavy Current Regulations,

Section 107-2-D1.

CLASS I EQUIPMENT provided with socket-outlets with earth contacts or which are

intended to be used in locations where protection against indirect contact is required

according to the wiring rules shall be provided with a plug in accordance with standard

sheet DK 2-1a or DK 2-5a.

If poly-phase equipment and single-phase equipment having a RATED CURRENT

exceeding 13 A is provided with a supply cord with a plug, this plug shall be in accordance

with the Heavy Current Regulations, Section 107-2-D1 or EN 60309-2.

N

3.2.1.1 In Spain, supply cords of single-phase equipment having a rated current not exceeding 10

A shall be provided with a plug according to UNE 20315:1994.

Supply cords of single-phase equipment having a rated current not exceeding 2,5 A shall be

provided with a plug according to UNE-EN 50075:1993.

CLASS I EQUIPMENT provided with socket-outlets with earth contacts or which are

intended to be used in locations where protection against indirect contact is required

according to the wiring rules, shall be provided with a plug in accordance with standard

UNE 20315:1994.

If poly-phase equipment is provided with a supply cord with a plug, this plug shall be in

accordance with UNE-EN 60309-2.

N

3.2.1.1 In the United Kingdom, apparatus which is fitted with a flexible cable or cord and is

designed to be connected to a mains socket conforming to BS 1363 by means of that

flexible cable or cord and plug, shall be fitted with a ‘standard plug’ in accordance with

Statutory Instrument 1768:1994 – The Plugs and Sockets etc. (Safety) Regulations 1994,

unless exempted by those regulations.

NOTE ‘Standard plug’ is defined in SI 1768:1994 and essentially means an approved plug

conforming to BS 1363 or an approved conversion plug.

N

3.2.1.1 In Ireland, apparatus which is fitted with a flexible cable or cord and is designed to be

connected to a mains socket conforming to I.S. 411 by means of that flexible cable or cord

and plug, shall be fitted with a 13 A plug in accordance with Statutory Instrument 525:1997

– National Standards Authority of Ireland (section 28) (13 A Plugs and Conversion

Adaptors for Domestic Use) Regulations 1997.

N

3.2.4 In Switzerland, for requirements see 3.2.1.1 of this annex. N

3.2.5.1 In the United Kingdom, a power supply cord with conductor of 1,25 mm2 is allowed for

equipment with a rated current over 10 A and up to and including 13 A.

N

3.3.4 In the United Kingdom, the range of conductor sizes of flexible cords to be accepted by

terminals for equipment with a RATED CURRENT of over 10 A up to and including 13 A

is:

• 1,25 mm2 to 1,5 mm

2 nominal cross-sectional area.

N

4.3.6 In the United Kingdom, the torque test is performed using a socket outlet complying with

BS 1363 part 1:1995, including Amendment 1:1997 and Amendment 2:2003 and the plug

part of DIRECT PLUG-IN EQUIPMENT shall be assessed to BS 1363: Part 1, 12.1, 12.2,

12.3, 12.9, 12.11, 12.12, 12.13, 12.16 and 12.17, except that the test of 12.17 is performed

at not less than 125 °C. Where the metal earth pin is replaced by an Insulated Shutter

Opening Device (ISOD), the requirements of clauses 22.2 and 23 also apply.

N



IEC/EN 60950-1


4.3.6 In Ireland, DIRECT PLUG-IN EQUIPMENT is known as plug similar devices. Such

devices shall comply with Statutory Instrument 526:1997 – National Standards Authority of

Ireland (Section 28) (Electrical plugs, plug similar devices and sockets for domestic use)

Regulations, 1997.

N

5.1.7.1 In Finland, Norway and Sweden TOUCH CURRENT measurement results exceeding 3,5

Ma r.m.s. are permitted only for the following equipment:

• STATIONARY PLUGGABLE EQUIPMENT TYPE A that

is intended to be used in a RESTRICTED ACCESS LOCATION where

equipotential bonding has been applied, for example, in a

telecommunication centre; and

has provision for a permanently connected PROTECTIVE EARTHING

CONDUCTOR; and

is provided with instructions for the installation of that conductor by a

SERVICE PERSON;

• STATIONARY PLUGGABLE EQUIPMENT TYPE B;

• STATIONARY PERMANENTLY CONNECTED EQUIPMENT.

N

6.1.2.1 In Finland, Norway and Sweden, add the following text between the first and second

paragraph of the compliance clause:

If this insulation is solid, including insulation forming part of a component, it shall at least

consist of either

- two layers of thin sheet material, each of which shall pass the electric

strength test below, or

- one layer having a distance through insulation of at least 0,4 mm, which shall

pass the electric strength test below.

If this insulation forms part of a semiconductor component (e.g. an optocoupler), there is no

distance through insulation requirement for the insulation consisting of an insulating

compound completely filling the casing, so that CLEARANCES and CREEPAGE

DISTANCES do not exist, if the component passes the electric strength test in accordance

with the compliance clause below and in addition

- passes the tests and inspection criteria of 2.10.11 with an electric strength

test of 1,5 Kv multiplied by 1,6 (the electric strength test of 2.10.10 shall be

performed using 1,5 Kv), and

- is subject to ROUTINE TESTING for electric strength during manufacturing,

using a test voltage of 1,5 Kv.

It is permitted to bridge this insulation with a capacitor complying with EN 132400:1994,

subclass Y2.

A capacitor classified Y3 according to EN 132400:1994, may bridge this insulation under

the following conditions:

- the insulation requirements are satisfied by having a capacitor classified Y3

as defined by EN 132400, which in addition to the Y3 testing, is tested with

an impulse test of 2,5 Kv defined in EN 60950-1:2006, 6.2.2.1;

- the additional testing shall be performed on all the test specimens as

described in EN 132400;

- the impulse test of 2,5 Kv is to be performed before the endurance test in

EN 132400, in the sequence of tests as described in EN 132400.

N



IEC/EN 60950-1


6.1.2.2 In Finland, Norway and Sweden, the exclusions are applicable for PERMANENTLY

CONNECTED EQUIPMENT, PLUGGABLE EQUIPMENT TYPE B and equipment

intended to be used in a RESTRICTED ACCESS LOCATION where equipotential bonding

has been applied, e.g. in a telecommunication centre, and which has provision for a

permanently connected PROTECTIVE EARTHING CONDUCTOR and is provided with

instructions for the installation of that conductor by a SERVICE PERSON.

N

7.2 In Finland, Norway and Sweden, for requirements see 6.1.2.1 and 6.1.2.2 of this annex.

The term TELECOMMUNICATION NETWORK in 6.1.2 being replaced by the term

CABLE DISTRIBUTION SYSTEM.

N

7.3 In Norway and Sweden, there are many buildings where the screen of the coaxial cable is

normally not connected to the earth in the building installation.

N

7.3 In Norway, for installation conditions see EN 60728-11:2005. N

ZC A-DEVIATIONS (informative) (EN 60950-1/A11) N

1.5.1 Switzerland (Ordinance on environmentally hazardous substances SR 814.081, Annex 1.7, Mercury - Annex 1.7 of SR 814.81 applies for mercury.)

Add the following:

NOTE In Switzerland, switches containing mercury such as thermostats, relays and level controllers

are not allowed.

N

1.7.2.1 Germany (Gesetz über technische Arbeitsmittel und Verbraucherprodukte (Geräte- und Produktsicherheitsgesetz – GPSG) [Law on technical labour equipment and consumer products], of 6th January 2004, Section 2, Article 4, Clause (4), Item 2).

If for the assurance of safety and health certain rules during use, amending or maintenance of a technical labour equipment or readymade consumer product are to be followed, a manual in German language has to be delivered when placing the product on the market.

Of this requirement, rules for use even only by SERVICE PERSONS are not exempted.

N

1.7.13 Switzerland (Ordinance on chemical hazardous risk reduction SR 814.81, Annex 2.15 Batteries)

Annex 2.15 of SR 814.81 applies for batteries.

N

ZD A-DEVIATIONS (informative) (EN 60950-1/A12) P

1.3.Z1 Delete the addition of 1.3.Z1 P

1.2.3 Delete the definition 1.2.3.Z1 P

1.7.2.1 Delete NOTE Z1 and the addition for Portable Sound System P

Zx Protection against excessive sound pressure from personal music players

See seprated test report in accordance with EN 50332-1 or EN 50332-2 as applicable. P

Zx.1 General P

A personal music player is a portable equipment for personal use, that:

− is designed to allow the user to listen to recorded or broadcast sound or video; and

− primarily uses headphones or earphones that can be worn in or on or around the ears; and

− allows the user to walk around while in use.

P

The requirements in this sub-clause are valid for music or video mode only. P



IEC/EN 60950-1


The requirements do not apply:

− while the personal music player is connected to an external amplifier; or

− while the headphones or earphones are not used. NOTE 2 An external amplifier is an amplifier which is not part of the personal music player or the listening

device, but which is intended to play the music as a standalone music player.

The requirements do not apply to:

− hearing aid equipment and professional equipment; NOTE 3 Professional equipment is equipment sold through special sales channels. All products sold through

normal electronics stores are considered not to be professional equipment.

N

Zx.2 Equipment requirements P

Zx.3 Warning P

The warning shall be placed on the equipment, or on the packaging, or in the instruction

manual and shall consist of the following:

— the symbol of Figure 1 with a minimum height of 5 mm; and

— the following wording, or similar:

To prevent possible hearing damage, do not listen at high volume levels for long periods.

P

Alternatively, the entire warning may be given through the equipment display during use,

when the user is asked to acknowledge activation of the higher level. N

Zx.4 Requirements for listening devices (headphones and earphones) P

Zx.5 Measurement methods P



IEC/EN 60950-1


1.5.1 TABLE: List of critical components P

Object/part No. Manufacturer/

trademark

Type/model Technical data Standard Mark(s) of

conformity1)

PCB Various Various V-0 UL 94 UL

Magnet Wire Various Various 130C UL 1446 UL

Batteries Various Various 3.7V 650mAh -- Test with

appliance

Batteries cell Various Various 4.2V 650mAh UL 1642 UL

Enclosure Various Various V-1 UL 94 UL

Supplementary information: 1)

Provided evidence ensures the agreed level of compliance.

1.5.1 TABLE: Opto Electronic Devices N

Manufacturer ...................................................... :

Type ................................................................... :

Separately tested................................................. :

Bridging insulation............................................. :

External creepage distance ................................. :

Internal creepage distance .................................. :

Distance through insulation................................ :

Tested under the following conditions ............... :

Input ................................................................... :

Output ................................................................ :

supplementary information

1.6.2 TABLE: Electrical data (in normal conditions) --

U (V) I (A) Irated (A) P (W) Fuse # Ifuse

(A)

Condition/status

DC5V

(Connected to the

computer USB port)

0.025 -- 0.125 -- -- Charged with empty battery

DC 3.7V 0.026 -- 0.096 -- -- Work with the largest load

Supplementary information: no rated current marked, test data just for reference



IEC/EN 60950-1


2.1.1.5 c)

1)

TABLE: max. V, A, VA test P

Voltage (rated)

(V)

Current (rated)

(A)

Voltage (max.)

(V)

Current (max.)

(A)

VA (max.)

(VA)

Battery output: 3.7 -- 4.21 2.1 8.84

Note:

2.1.1.5 c) 2) TABLE: stored energy N

Capacitance C (µF) Voltage U (V) Energy E (J)

-- -- --

supplementary information:

2.2.2 TABLE: Hazardous voltage measurement N

Transformer Location max. Voltage Voltage Limitation

Component V peak V d.c.

-- -- -- -- --

Note:

2.2.3 TABLE: SELV voltage measurement N

Location Voltage measured (V) Comments

-- -- --

Note:

2.4.2 TABLE: limited current circuit measurement N

Location Voltage

(V)

Current

(mA)

Freq.

(kHz)

Limit

(mA)

Comments

-- -- -- -- -- --

Notes:

2.5 TABLE: limited power sources P

Measured Uoc (V) with all load circuits 4.21V(battery)

disconnected:

Isc (A) VA

Meas. Limit Meas. Limit

Normal condition 2.1 8 8.84 100

Abnormal condition(B- P- s-c) 5.9 8 17.7 100



IEC/EN 60950-1


2.10.2 Table: working voltage measurement N

Location RMS voltage (V) Peak voltage (V) Comments

-- -- -- --

Note:

2.10.3 and

2.10.4

TABLE: Clearance and creepage distance measurements N

Clearance (cl) and creepage

distance (cr) at/of/between:

U peak

(V)

U r.m.s.

(V)

Required cl

(mm)

cl

(mm)

Required cr

(mm)

cr

(mm)

-- -- -- -- -- -- --

Supplementary information:

2.10.5 TABLE: Distance through insulation measurements N

Distance through insulation (DTI) at/of: U peak

(V)

U rms

(V)

Test voltage

(V)

Required DTI

(mm)

DTI

(mm)

-- -- -- -- -- --


4.3.8 TABLE: Batteries P

The tests of 4.3.8 are applicable only when appropriate battery data is

not available

--

Is it possible to install the battery in a reverse polarity position? No possible --

Non-rechargeable batteries Rechargeable batteries

Discharging Un-

intentional

charging

Charging Discharging Reversed charging

Meas.

current

Manuf.

Specs.

Meas.

current

Manuf.

Specs.

Meas.

current

Manuf.

Specs.

Meas.

current

Manuf.

Specs.

Max.

current

during

normal

condition

-- -- -- 24A -- 31A -- -- --

Max.

current

during

fault

condition

-- -- -- 25A -- 32A -- -- --

Test results: Verdict

- Chemical leaks P

- Explosion of the battery P



IEC/EN 60950-1


- Emission of flame or expulsion of molten metal P

- Electric strength tests of equipment after completion of tests N


4.5 TABLE: Thermal requirements P

Supply voltage (V)............................... : a) charged with empty battery

b)discharge by full-charged battery

Ambient T1(C) ................................... : See below.

Ambient T2 (C) .................................. : See below.

Maximum measured temperature T of part/at: T (C) Tmax (C)

PCB near U1 35.5 33.7 130

Battery 33.6 32.3 --

Enclosure 29.8 28.8 95

Button 26.9 26.2 95

Ambient 25.0 25.0 --


1.Nomral condition see clause 1.2.1 & annex L.

Temperature T of winding: t1 (°C) R1 () t2 (°C) R2

()

T (C) Allowed

Tmax (C)

Insulation

class


4.5.2 TABLE: ball pressure test of thermoplastic parts N

allowed impression diameter (mm) : 2 mm

Part Test temperature

(C)

Impression diameter

(mm)

-- -- --

Note:

4.7 TABLE: Resistance to fire N

Part under test Test temperature (C) Result

-- -- --



IEC/EN 60950-1


5.1 TABLE: touch current measurement N

Condition L terminal A

(mA)

N terminal A

(mA)

Limit

(mA)

Comments

-- -- -- -- --

Notes:

5.2 TABLE: Electric strength tests, impulse tests and voltage surge tests N

Test voltage applied between: Test voltage (V) Breakdown

-- -- --

Note: Test voltage a.c. / d.c.

5.3 TABLE: Fault condition tests P

ambient temperature (C) ............................................ : 25.0C

model/type of power supply ........................................ : --

manufacturer of power supply .................................... : --

rated markings of power supply .................................. : --

No. Component

no.

Fault Test voltage

(V)

Test time Fuse

no.

Fuse current

(A)

Result

1 Battery Over

charge

DC5.3V 7hr -- -- Unit Normal Operation.

No hazards,

Battery body = 33.9 ºC

PWB = 32.3 ºC.

2 Battery

Output s-c -- 7hr -- -- Battery over discharges tests,

no hazard.

3 Battery

control

board (B- to

P-)

s-c

charge DC5V 7hr -- -- Unit Normal Operation.

No hazards,


PWB = 32.1 ºC.

4 Battery

control

board (B- to

P-)

s-c

discharg

e

-- 7hr -- -- Unit Normal Operation.

No hazards,


PWB = 31.9ºC.

Supplementary information

s-c = short-circuited. o-c = open-circuited. o-l=overloaded.




Appendix 1

Equipment List

No.

Equipment

Manufacturer

Model No.

Serial No. Calibratio

n date

Calibrati

o n due

date

01 Hybrid Recorder Yokogawa DR130 27D216293 2015.1.4 2016.1.3

02 Hybrid Recorder Yokogawa DR130 27D216294 2015.1.4 2016.1.3

03 Data Acquisition / Switch Unit Agilent 34970A MY41027365 2015.1.4 2016.1.3


05 Temp. & Humid. Chamber Gongwen HSD-500 0109 2015.1.4 2016.1.3

06 Oven Chamber Rongfeng 101A-3 900875 2015.1.4 2016.1.3

14 Oscilloscope Tektronix TDS3012B B035855 2015.1.4 2016.1.3

15 Digital Power Meter Qingzhi 8716C 870307119 2015.1.4 2016.1.3

16 Digital Power Meter Ainuo 8715B 038710069 2015.1.4 2016.1.3

17 Digital Power Meter Everfine YF9901 405075 2015.1.4 2016.1.3

18 Ohm Meter Yang Zi YD2511 794 2015.1.4 2016.1.3

19 Multi Meter Fluke 111 85150263 2015.1.4 2016.1.3

20 Multi Meter Fluke 111 85150223 2015.1.4 2016.1.3

21 Desktop Multi Meter Good Will GDM-8245 E900535 2015.1.4 2016.1.3

22 Desktop Multi Meter Fluke 45 8392015 2015.1.4 2016.1.3



25 Hi-Pot Tester Ainuo 9604 039609405 2015.1.4 2016.1.3

26 Grounding Bond Meter Ainuo 9613B 039606212 2015.1.4 2016.1.3

27 Leakage Current Meter EXTECH 7611 1330308 2015.1.4 2016.1.3

28 Touch Current Meter EPRE 400C 0402A05 2015.1.4 2016.1.3

29 Insulation Resistance Tester Yang Zhi YD2683 030 2015.1.4 2016.1.3


31 Electronic Scale Heng Tong J3S5 18514 2015.1.4 2016.1.3

32 Push-Pull Scale Japan

Instrumentation NK-300 49779 2015.1.4 2016.1.3

33 Test hook Zhilitong TH-1 W8L180T1 2015.1.4 2016.1.3

34 Digital Caliper Guang Lu (0~150mm)/0.0

1mm 27452 2015.1.4 2016.1.3

35 Digital Caliper Guang Lu (0~150mm)/0.0

1mm 27460 2015.1.4 2016.1.3

36 Electronic Thermo-Hygrometer Oregon JB913R 06A03-4101 2015.1.4 2016.1.3

39 Goniometer Wenzhou JZC-B2 15032 2015.1.4 2016.1.3

40 Tumbling Barrel Zhilitong GT-1 G010104 2015.1.4 2016.1.3

41 Audio Generator Good Will GAG-810 D913311 2015.1.4 2016.1.3

42 Noise Generator DM DM8898 D826715 2015.1.4 2016.1.3

43 Plug Torque Tester Zhilitong LJ-1 LJ010104 2015.1.4 2016.1.3

44 Shot Test Pin Probe Zhilitong ZP-1 44/ATCS-44 2015.1.4 2016.1.3

45 Test Probe 41 Zhilitiong ZT-1 D30L80/ATCS-45 2015.1.4 2016.1.3

46 Finger Nail Probe Zhilitong ZJ-1 D14N30/ATCS-46 2015.1.4 2016.1.3

47 Test Finger Probe Zhilitong ZF-1 X010106/ATCS-47 2015.1.4 2016.1.3

48 Accessibility Probe Zhilitong ZA-1 A010102/ATCS-48 2015.1.4 2016.1.3

49 UL Finger Probe America ULP-01 A01/ATCS-49 2015.1.4 2016.1.3

50 Rigid Finger Probe Zhilitong TZ-1 L010304 2015.1.4 2016.1.3

51 Test Probe Zhilitong TZ-11 D4L100/ATCS-51 2015.1.4 2016.1.3



54 Test Probe Zhilitong TZ-14 D40/ATCS-54 2015.1.4 2016.1.3

55 Steel Ball Zhilitong ZB-1 D5W500 2015.1.4 2016.1.3

58 DC Power Supply All Power IP50-20D 401024 —— ——

59 DC Power Supply Chuang Hong CPS-5030D 04021101 —— ——

60 Isolating Transformer Kong Tel 5KVA 002 —— ——

61 Hammer Guangdong Zhijian CJ-2 24003 2015.1.4 2016.1.3

62 Hammer Zhilitong CJ-2 C021204 2015.1.4 2016.1.3

63 Hammer Guangdong Zhijian CJ-2 24004 2015.1.4 2016.1.3



No.

Equipment

Manufacturer

Model No.


n date

Calibrati

o n due

date 64 Hammer Zhilitong CJ-2 C021104 2015.1.4 2016.1.3

65 Torque Driver kanon 30LTDK 04C175 2015.1.4 2016.1.3

66 Torque Driver kanon 12LTDK 04A037 2015.1.4 2016.1.3

67 AC Voltage Stabilizer Sanke Electrical SVC-30KVA 31208433081 —— ——

68 AC Voltage Stabilizer Sanke Electrical SVC-30KVA 31208455481 —— ——

69 Frequency Converter Power Supply All Power AFC-220 890411 —— ——

70 Frequency Converter Power Supply NewG Power Ng-3120a 04454 —— ——

72 High-voltage Digital Voltage Meter Yang Zi YD1940 101 2015.1.4 2016.1.3

73 High-voltage Passive Probe TEXAS HVP3011 ATCS-73 2015.1.4 2016.1.3

74 Switching Mode Power Supply Manson SIM-9106 350400004 2015.1.4 2016.1.3

75 Tape line Great Wall GW-589E 18955 2015.1.4 2016.1.3

76 Platform Scale Shanghai TGT-100 ATCS-76 2015.1.4 2016.1.3

77 Timer Tian Fu PC396 AT24H 2015.1.4 2016.1.3



80 Digital Power Meter Everfine PF9805 301020 2015.1.4 2016.1.3

81 Digital Power Meter iDRC CP-280 280887 2015.1.4 2016.1.3


83 Glow Wire Test Set Zhilitong GTR-B R024007 2015.1.4 2016.1.3

84 Needle Flame Test Set Zhilitong ZY-2 Y021507 2015.1.4 2016.1.3

85 Hi-Pot Tester Changsheng CS5051 200609812 2015.1.4 2016.1.3

86 DC Electronic Load Techred TR-868 ATE868205164 2015.1.4 2016.1.3

87 Switching Mode Power Supply Manson SIM-9303 G290700126 —— ——

88 Ball Pressure Tester Zhilitong QY-1 Q013408/ATCS-88 2015.1.4 2016.1.3

89 Ball Pressure Tester Zhilitong QY-1 Q013508/ATCS-89 2015.1.4 2016.1.3

90 Oscilloscope voltage probe (100X) Tektronix P5100 23489-6 2015.1.4 2016.1.3

91 K type thermocouple OMEGA TT-K-30-1000 ATCS-91 2015.1.4 2016.1.3

92 J type thermocouple OMEGA TT-J-30-1000 ATCS-92 2015.1.4 2016.1.3

93 Small finger probe (Φ8.6) HUANAN EX-A02 ATCS-93 2015.1.4 2016.1.3

94 Small finger probe (Φ5.6) HUANAN EX-A02 ATCS-94 2015.1.4 2016.1.3

95 Draught-proof enclosure Shanghai Jingtian DMS-B12 DAMS2009110136 2015.1.4 2016.1.3

96 Proof tracking Test Apparatus Shenzhen

Demaisheng LD-H TI09101201 2015.1.4 2016.1.3

97 228 meter SIMPSON 228 10-866030 2015.1.4 2016.1.3

98 Digital Caliper Guang Lu (0-150mm)/

0.01mm 090074695 2015.1.4 2016.1.3

99 Torque Driver Kanon 10DPSK 0907005 2015.1.4 2016.1.3

100 Digital Power Meter Yokogawa WT110 12VC26618M 2015.1.4 2016.1.3

101 Desktop Multi Meter Fluke 45 7664009 2015.1.4 2016.1.3

102 Steel Ball XINNA YD2810B 11051101 2015.1.4 2016.1.3



106 K type thermocouple OMEGA TT-K-30 ATCS-106 2015.1.4 2016.1.3

107 E27 Cap "GO" Gauge Guangzhou Gerui 7006-27B-1 GRT110727002 2015.1.4 2016.1.3

108 E27 Cap "NOT GO" Gauge Guangzhou Gerui 7006-28A-1 110711012 2015.1.4 2016.1.3

109 E27 Cap "GO" Gauge for dimension

S1 Guangzhou Gerui 7006-27C-1 110720005 2015.1.4 2016.1.3

110 E27 Cap Gauge for testing contact

making Guangzhou Gerui 7006-50-1 110711013 2015.1.4 2016.1.3

111 E27 Cap Gauge for testing contact

making Guangzhou Gerui 7006-51-2 110711005 2015.1.4 2016.1.3

112 E27 Cap Gauge for testing

protection against accidental contact

during insertion

Guangzhou Gerui

7006-51A-2

110720008

2015.1.4

2016.1.3

113 E14 Cap "GO" Gauge Guangzhou Gerui 7006-27F-1 110711046 2015.1.4 2016.1.3

114 E14 Cap "NOT GO" Gauge Guangzhou Gerui 7006-28B-1 110711044 2015.1.4 2016.1.3

115 E14 Cap "GO" Gauge for dimension

S1 Guangzhou Gerui 7006-27G-1 110711050 2015.1.4 2016.1.3

116 E14 Cap Gauge for testing contact Guangzhou Gerui 7006-54-2 110711040 2015.1.4 2016.1.3



No.

Equipment

Manufacturer

Model No.


n date

Calibrati

o n due

date

making

117 E14 Cap Gauge for testing

protection against accidental contact Guangzhou Gerui 7006-55-2 110711037 2015.1.4 2016.1.3

118 G13 "GO" Gauge Guangzhou Gerui 7006-45-4 GRT11092730 2015.1.4 2016.1.3

119 G13 "GO" and "NOT GO" Gauge Guangzhou Gerui 7006-44-4 GRT11092731 2015.1.4 2016.1.3

120 Power cord flexing and swivel tester DEMAISHENG DMS-801H 2011DMS-801H0902 2015.1.4 2016.1.3

121 10 kV surge tester CEPREI 1065A 1108AG41 2015.1.4 2016.1.3

122 Cylindrical contact plane(Φ12.7) Zhilitong Φ12.7mm ATCS-122 2015.1.4 2016.1.3

123 Cylindrical contact plane(Φ30) Zhilitong Φ30mm ATCS-123 2015.1.4 2016.1.3

124 0.1Ω constant resistance Zhilitong 0.1Ω ATCS-124 2015.1.4 2016.1.3

125 30A Current Shunt Agilent 34330A 0418 2015.1.4 2016.1.3

126 Test Probe Zhilitong ZLT-I23 I231201 2015.1.4 2016.1.3

127 Test A Probe Zhilitong ZLT-I01 I011201 2015.1.4 2016.1.3

128 Test C Probe Zhilitong ZLT-I03 I031201 2015.1.4 2016.1.3

129 Test D Probe Zhilitong ZLT-I04 I041203 2015.1.4 2016.1.3

130 Test 31 Probe Zhilitong ZLT-I14 I141201 2015.1.4 2016.1.3

131 Wedge-shaped test probe Zhilitong ZLT-U14 U141202 2015.1.4 2016.1.3

132 Hammer Zhilitong ZLT-CJ1 C011208 2015.1.4 2016.1.3

133 Steel Ball(Φ12.5) Zhilitong ZLT-I06 I061201 2015.1.4 2016.1.3

134 Tumbling Barrel Zhilitong ZLT-GT2 G021202 2015.1.4 2016.1.3

135 Oscilloscope voltage probe (10X,

1X) KENWOOD PC-54 ATCS-135 2015.1.4 2016.1.3

136 Transformer bump testing appliance SHENZHEN

GANGWEI ATCS-136 ATCS-136 2015.1.4 2016.1.3

137 HOT WIRE ANEMOMETER Lutron AM-4204 Q619466 2015.1.4 2016.1.3

138 Magnifier ZHONGXUN ATCS-138 3001003939 2015.1.4 2016.1.3

139 Digital Protractor GUANGZHOU

XINHE 82201B-00 ATCS-139 2015.1.4 2016.1.3

140 Test chain GUANGZHOU

XINHE SH3306 50612 2015.1.4 2016.1.3

141 G13 lamp holder test fixture SHENZHEN

GANGWEI ATCS-141 ATCS-141 —— ——

142 Digital Power Meter YOKOGAWA WT210 91F603491 2015.1.4 2016.1.3

143 Leakage Current Meter CHANGSHENG CS5520E 1109203-002 2015.1.4 2016.1.3

E30 LCR bridge YANGZHI YD2810B 272 2015.1.4 2016.1.3

E53 Exposure level tester NARDA 2304/03 B-0138 2015.1.4 2016.1.3

E54 Magnetic field probe 100cm2 NARDA 2300/90.10 B-0137 2015.1.4 2016.1.3



Appendix 2

Photo documentation

Photo 1

View:

[ ] front

[ ] rear

[ ] right side

[ ] left side

[√ ] top

[ ] bottom

[ ] internal

Photo 2

View:

[ ] front

[ ] rear

[ ]right side

[ ] left side

[ ] top

[√ ] bottom

[ ] internal



Photo documentation

Photo 3

View:

[ ] front

[ ] rear

[ ] right side

[ ] left side

[ ] top

[ ] bottom

[√ ] internal

Photo 4

View:

[ ] front

[ ] rear

[ ]right side

[ ] left side

[ ] top

[ ] bottom

[√ ] internal



EN 62479 TEST REPORT

For


Model No. : S-1, S-2, S-3, S-4, S-5, S-6

Prepared for :

Address :


Address : Room 401, 19, BaoKang Road, The Pine Community, Cross The

Street, Longgang District, Shenzhen City, Guangdong Province,

China

Tel : (86) 755-66808335

Fax : (86) 755-61658456

Report No. : HT2015430Ab-3

Date of Test : April 22-30, 2015

Date of Rep. : April 30, 2015



TABLE OF CONTENT

Description Page

Test Report Declaration

1. GENERAL INFORMATION .....................................................................................................4

1.1 Description of Device (EUT) ................................................................................................................. 4

1.2 Test Facility ........................................................................................................................................... 5

2. TEST INSTRUMENT USED ......................................................................................................6

3. TEST RESULT ............................................................................................................................. 8



TEST REPORT DECLARATION

Applicant :

Manufacturer :

EUT Description : Smart Device, Smart Finder

(A) Model No. : S-1, S-2, S-3, S-4, S-5, S-6

(B) Power Supply : DC 3.0V

Test Procedure Used:

EN 62479: 2010

[Assessment of the compliance of low power electronic and electrical equipment with the basic

restrictions related to human exposure to electromagnetic fields (10MHz-300GHz)]

The device described above has been tested by Shenzhen OES Testing technology co., Ltd. to

determine the maximum emission levels emanating from the device, the severe levels that the

device can endure and EUT’S performance criterion. The test results are contained in this test

report. Shenzhen OES Testing technology co., Ltd. is assumed of full responsibility for the

accuracy and completeness of these tests. Also, this report shows that the EUT is technically

compliant with the EN 62479: 2010 requirements.

This report applies to above tested sample only and shall not be reproduced in part without

written approval of Shenzhen OES Testing technology co., Ltd.


Prepared by:

Huang hua, Baird

Engineer

Approved by:

Chi jun, Danny

Technical Director



1. GENERAL INFORMATION

1.1 Description of Device (EUT)

Description : Smart Device, Smart Finder

Trade Name : N.A.

Model Number : S-1, S-2, S-3, S-4, S-5, S-6

They are quite same in circuit design and PCB layout, so all tests of

this report are perform on model “S-1”.

Frequency Range : 2402-2480MHz

Number of Channels : 40

Type of Antenna : PCB Antenna

Power supply : DC 3.0V

Applicant :

Address :

Manufacturer :

Address :



1.2 Test Facility

Site Description:

EMC Laboratory : Certificated by TUV Rheinland Shenzhen

May 10, 2004

Certificated by FCC

Registration Number: 253065

May 10, 2004

Certificated by Industry Canada

Registration Number: IC5077

May 18, 2004

Name of Firm : Accurate Technology Co., Ltd

Site Location : F1, Bldg. A, Changyuan New Material Port, Keyuan

Rd., Science & Industry Park, Nanshan, Shenzhen,

Guangdong, P.R. China



2. TEST INSTRUMENT USED

No.

Equipment

Manufacturer


Date

1 ESD TESTER HAEFELY PESD1610 H401552 2015.01.16 2016.01.16

2 MAGNETIC FIELD TESTER HAEFELY MAG100 150577 2015.01.15 2016.01.15

3

5kVA AC POWER SOURCE

CALIFORNIA

INSTRUMENTS

5001ix-400

55692

2015.01.15

2016.01.15

4

HARMONICS/FLICKER TEST

ANALYZER

CALIFORNIA

INSTRUMENTS

PACS-1

72254

2015.01.15

2016.01.15


6 CONICAL HOUSING ATC N/A N/A N/A N/A

7 VOLTAGE PROBE SCHWARZBECK TK9416 N/A 2015.01.15 2016.01.15

8 RF CURRENT PROBE ROHDE& SCHWARZ EZ-17 100048 2015.01.15 2016.01.15

9 BILOG ANTENNA SCHWARZBECK VULB9163 194 2015.01.15 2016.01.15

10 SPECTRUM ANALYZER ANRITSU MS2651B N/A 2015.01.15 2016.01.15

11

PRE-AMPLIFIER

AGILENT

8447D

294A10619

2015.01.15

2016.01.15

12


CHAMBER)

SCHWARZBECK

N-5m

NO.1

2015.01.15

2016.01.15


14

1# SHIELDING ROOM

CHANGZHOU

ZHONGYU

843

N/A

N/A

N/A

15

2# SHIELDING ROOM

CHANGZHOU

ZHONGYU

843

N/A

N/A

N/A

16

3m Semi-ANECHOIC

CHAMBER

CHANGZHOU

ZHONGYU

844

N/A

N/A

N/A

17

ANTENNA/TURNTABLE

CONTROLLER

INNCO

CO2000

CO2000/077/7

301203/L

N/A

N/A

18 101 LCR METER YANGZHI YD2810B 20101170 2015.01.04 2016.01.04

19


CHAMBER)

NTGS8017

N-1m

NO.6

2015.01.15

2016.01.15

20


CHAMBER)

NTGS8017

N-1m

NO.7

2015.01.15

2016.01.15

21 AUDIO GENERATOR GW GAG-809 EG835424 N/A N/A




No.

Equipment 29

Manufacturer


Date

23

EMCPRO SYSTEM

(IMMUNITY TESTER)

THERMO

PRO-BASE

0403271

2015.01.15

2016.01.15

24

CAPACITIVE CLAMP

(EFT)

THERMO

PRO-CCL

0403272

2015.01.15

2016.01.15

25

COUPLER DECOUPLER

FOR TELECOM LINES

THERMO

CM-TEL-CD

0403273

2015.01.15

2016.01.15

26 L.I.S.N. ROHDE& SCHWARZ ESH3-Z5 100305 2015.01.15 2016.01.15


28 SIGNAL GENERATOR ROHDE& SCHWARZ SML01 101161 2015.01.15 2016.01.15


30 SPECTRUM ANALYZER AGILENT E7405A MY45115511 2015.01.15 2016.01.15

31 L.I.S.N. SCHWARZBECK NSLK8126 8126431 2015.01.15 2016.01.15

32

PULSE LIMITER

(FOR ESPI3)

ROHDE& SCHWARZ

ESH3-Z2

100815

2015.01.15

2016.01.15

33 PRE-AMPLIFIER ROHDE& SCHWARZ CBLU1183540-01 3791 2015.01.15 2016.01.15


35 BILOG ANTENNA SCHWARZBECK VULB9163 9163-323 2015.01.15 2016.01.15

36 HORN ANTENNA SCHWARZBECK BBHA9120D 9120D-655 2015.01.15 2016.01.15

37 HORN ANTENNA SCHWARZBECK BBHA9170 9170-359 N/A N/A

38 LOOP ANTENNA SCHWARZBECK FMZB1516 1516131 2015.01.15 2016.01.15

39

ULTRA COMPACT

SIMULATOR

EM TEST

UCS 500 N5

V0928104968

2015.01.15

2016.01.15

40 CAPACITIVE CLAMP EM TEST HFK 0509-34 2015.01.15 2016.01.15

41 Transformer EM TEST V4780S2 0109-44 N/A N/A

42

Conducted Immunity Test

System

FRANKONIA

CIT-10

126B1121

2015.01.15

2016.01.15

43 CDN FRANKONIA CDN-M2/3 A3027020 2015.01.15 2016.01.15

44 EM Injection Clamp FCC F-203I-23mm 091824 2015.01.15 2016.01.15

45 LISN AFJ LS16C 16010946249 2015.01.15 2016.01.15

46 CLICK METER AFJ CL55C 55040947164 2015.01.15 2016.01.15



3. TEST RESULT

From results of report HT2015430Aa-1 can be assumed that the compliance criteria is fulfilled

(max. radiated power is less than 20mW(13dbm)). The assumption is made with an uncertainty of

30%.

*EN 62479: 2010 “4.1(D) & 4.2

Measurements or calculations show that the available antenna power and/or the average total

radiated power are below the low-power exclusion level defined in 4.2(Pmax: .”

20mW(13dBm))

Result: PASS

Documents

EN 300 328 V1.8.1 TEST REPORT For