EMC – Laboratory
Test Report No. 13 / 13024-2
VINCELL LT 4.3 Boxed S/N: 01338453
The results refer only to the tested equipment. Without written permission of the test laboratory it is not allowed to publish parts of this test report.
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Customer:
Garz & Fricke GmbH Tempowerkring 2 21079 Hamburg
Equipment under test:
VINCELL LT 4.3 Boxed, S/N: 01338453
Date of receipt:
Feb. 11, 2013
Date of test:
Feb. 11 and 12, 2013
Test site:
TÜV NORD CERT GmbH, Abteilung EMV Services, EMC-Laboratory
Test personnel:
Phone
Fax
e-mail
Dipl.-Ing. Zhaoqi Wang
040 / 76629-3433
040 / 76629-506
[email protected]
Participating customer:
Mr. Rickert
Applied standards: Emission: EN 61000-6-3 (2007) +A1 (2011): EN 55022 (2010): Immunity: EN 61000-6-2 (2005): EN 55024 (2010): • •
• • •
Generic emission standard; Part 1: Residential, commercial and light industry Information technology equipment – Radio disturbance characteristics – Limits and methods of measurement
Generic immunity standard; Part 2: Industrial environment; Information technology equipment – Immunity characteristics – Limits and methods of measurement: EN 61000-4-2 (2009): Electrostatic discharge immunity test EN 61000-4-3 (2006) +A1 (2008) +A2 (2010) : Radiated, radio-frequency electromagnetic field - immunity test EN 61000-4-4 (2004) +A1 (2010): Electrical fast transient/burst immunity test EN 61000-4-5 (2006): Surge immunity tests EN 61000-4-6 (2009): Immunity to conducted disturbances, induced by radio frequency fields
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Test results: The device complies with the limits for: • conducted emission (EN 61000-6-3 DC for disturbing voltage) • conducted emission (EN 55022 class B for disturbing current) • radiated emission (EN 61000-6-3, EN 55022 class B) The device complies with the immunity requirement of EN 61000-6-2 and EN 55024 to: • electrostatic discharge (EN 61000-4-2) • radiated, radio-frequency electromagnetic field (EN 61000-4-3) • electrical fast transient/burst (EN 61000-4-4) • surges (EN 61000-4-5) • conducted disturbances, induced by radio frequency fields (EN 61000-4-6)
The test results only apply to the Equipment under test.
Released:
Issued:
Dr. Thomas Weber
Dipl.-Ing. Zhaoqi Wang
Head of laboratory
Project manager
TÜV NORD CERT GmbH Abteilung EMV Services Harburger Schlossstraße 6-12 21079 Hamburg
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Table of contents 1
EQUIPMENT UNDER TEST AND OPERATING CONDITIONS .................................. 5
2
EMISSION .................................................................................................................... 6
2.1
Conducted emission (disturbing voltage) .................................................................. 6
2.2
Conducted emission (disturbing current)................................................................. 12
2.3
Disturbing field measurement ................................................................................. 16
3
IMMUNITY.................................................................................................................. 22
3.1
ESD Test................................................................................................................. 22
3.2
Immunity against electromagnetic fields ................................................................. 24
3.3
Burst........................................................................................................................ 27
3.4
Surge ...................................................................................................................... 29
3.5
Immunity to conducted disturbances, induced by radio frequency fields ................ 31
4
MEASURING INSTRUMENT LIST ............................................................................. 33
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1 Equipment under test and operating conditions Nominal voltage: Nominal current: Nominal power:
24 VDC 200 mA 4.5 W
Description:
The EUT (Equipment Under Test) is a mini PC with 4.5” touch panel and display. The EUT has 2x USB, Ethernet, RS232, RS485 and CAN-bus interfaces and a loud speaker.
Operating conditions:
All I/O ports were activated during the emission measurements. At the immunity tests the tested ports communicated with another PC (NESO-LT). During the tests the status of the ports were monitored with a test program.
Fig. 1-1: Test software Test conditions:
The function of the EUT is controlled by the test software. The period of the testing for all ports was about 2.5 s.
Remarks: • All cables except DC supply lines were screened. • The highest internal frequency is 50 MHz. • The cables of USB-OTG and USB-Host are shorter than 3 m.
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2 Emission 2.1 Conducted emission (disturbing voltage) 2.1.1 Test set-up The disturbing voltage of the EUT (equipment under test) was measured by a measuring receiver and an artificial mains network.
Fig. 2-1: Test set-up for the disturbing voltage measurement 2.1.2 Operating conditions Please refer to chapter 1. 2.1.3 Climatic conditions On Feb. 11, 2013 Ambient air temperature: 21 °C Humidity: 22 % Air pressure: 1012 hPa 2.1.4 Measuring equipment Screened measuring room (large) Receiver: ESS Artif. mains network: NSLK 8127 Pulse limiter: ESH3-Z2
No. 103 No. 419 No. 417
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2.1.5 Limit values Fig. 2-2 to 2-3 show the limit values according to EN 61000-6-3 for DC, for the quasipeak(QP) and average-detector (AV). 2.1.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 1.8 dB (9 kHz to 150 kHz), RSS = ± 1.5 dB (150 kHz to 30 MHz). The expanded measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 3.6 dB (9 kHz to 150 kHz), ∆ = ± 3.0 dB (150 kHz to 30 MHz). So the laboratory of EMV Services under-runs the maximum value of the expanded measurement uncertainty of EN 55016-4-2 (2004) for this measurement. Therefore the result of every measurement value at and below the limit is “pass”. 2.1.7 Measuring procedure and results The disturbing voltages on the power supply lines were measured by means of an artificial mains network in the frequency range 150 kHz to 30 MHz. The curves in Fig. 2-2 to 2-3 show the peak values of the conducted emission using a 10 ms measuring time. Quasipeak and average values were measured at local maximums using a 1 s measuring time. The results are marked by a "∗" (quasipeak values) and by a "x" (average values). No deviations with regard to the applied standard could be detected.
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Conducted emission (150 kHz - 30 MHz): 24 VDC supply line Minus VINCELL LT 4.3 Boxed
90
QP measurement AV measurement QP-Limit (EN 61000-6-3 for DC supply) AV-Limit (EN 61000-6-3 for DC supply) QP-Limit (EN 55022 class B) AV-Limit (EN 55022 class B)
80
Interference voltage [dBµV]
70 60 50 40 30 20 10 0
0.2
0.4
0.6
0.8
1
2
Frequency [MHz] TÜV NORD CERT | 11.2.2013
Fig. 2-2: Disturbing voltage on conductor Minus
Measuring information: Software: EMI Software 2012 07 EMI Receiver: ROHDE&SCHWARZ, ESS Date: 11.02.2013, Time: 13:30 BandWidth: 10 kHz Start frequency: 150.00 kHz Stop frequency: 30.01 MHz Scan step: 4.00 kHz Measure time of peak: 10 ms Detector: QP & AV Ex-Attenuation: 10dB Transducer: NSLK8127 Transducer option: Minus VINCELL LT 4.3 Boxed / Garz & Fricke GmbH
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Maximum of the disturbances with quasipeak detector Frequency[Hz] QP [dBµV] 1214000.000 45.730 1282000.000 45.330 1350000.000 44.590 1150000.000 43.150 16002000.000 42.900 1078000.000 42.390
QP-Limit [dBµV] Margin to limit [dB] 73.000 27.270 73.000 27.670 73.000 28.410 73.000 29.850 73.000 30.100 73.000 30.610
Maximum of the disturbances with average detector Frequency[Hz] AV [dBµV] 1214000.000 45.350 1282000.000 44.940 1350000.000 44.070 16002000.000 42.800 1150000.000 42.530 1078000.000 41.970
AV-Limit [dBµV] Margin to limit [dB] 60.000 14.650 60.000 15.060 60.000 15.930 60.000 17.200 60.000 17.470 60.000 18.030
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Conducted emission (150 kHz - 30 MHz): 24 VDC supply line Plus VINCELL LT 4.3 Boxed
90
QP measurement AV measurement QP-Limit (EN 61000-6-3 for DC supply) AV-Limit (EN 61000-6-3 for DC supply) QP-Limit (EN 55022 class B) AV-Limit (EN 55022 class B)
80
Interference voltage [dBµV]
70 60 50 40 30 20 10 0
0.2
0.4
0.6
0.8
1
2
Frequency [MHz] TÜV NORD CERT | 11.2.2013
Fig. 2-3: Disturbing voltage on conductor Plus
Measuring information: Software: EMI Software 2012 07 EMI Receiver: ROHDE&SCHWARZ, ESS Date: 11.02.2013, Time: 13:35 BandWidth: 10 kHz Start frequency: 150.00 kHz Stop frequency: 30.01 MHz Scan step: 4.00 kHz Measure time of peak: 10 ms Detector: QP & AV Ex-Attenuation: 10dB Transducer: NSLK8127 Transducer option: Plus VINCELL LT 4.3 Boxed / Garz & Fricke GmbH
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Maximum of the disturbances with quasipeak detector Frequency[Hz] 478000 486000 6874000 7126000 958000 20750000
QP [dBµV] 69 62.26 51.56 50.79 50.53 49.76
QP-Limit [dBµV] Margin to limit [dB] 79 10 79 16.74 73 21.44 73 22.21 73 22.47 73 23.24
Maximum of the disturbances with average detector Frequency[Hz] 6874000 7126000 6622000 20750000 21250000 20502000
AV [dBµV] 51.31 50.55 45.74 44.7 44.53 44.44
AV-Limit [dBµV] Margin to limit [dB] 60 8.69 60 9.45 60 14.26 60 15.3 60 15.47 60 15.56
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2.2 Conducted emission (disturbing current) 2.2.1 Test set-up The disturbing current of the EUT (equipment under test) was measured by a measuring receiver and a current clamp.
Fig. 2-4: Test set-up for the disturbing current measurement
2.2.2 Operating conditions Please refer to chapter 1. 2.2.3 Climatic conditions On Feb. 11, 2013 Ambient air temperature: 21 °C Humidity: 22 % Air pressure: 1012 hPa 2.2.4 Measuring equipment Screened measuring room (large) Receiver: ESS Current clamp: 6741-1
No. 103 No. 405
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2.2.5 Limit values Fig. 2-6 shows the limit values according to EN 55022 class B for the quasipeak- (QP) and average-detector (AV). 2.2.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 1.37 dB (9 kHz to 150 kHz). The expanded measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 2.7 dB So the laboratory of EMV Services under-runs the maximum value of the expanded measurement uncertainty of EN 55016-4-2 (2004) for this measurement. Therefore the result of every measurement value at and below the limit is “passed”. 2.2.7 Measuring procedure and results The disturbing current on the signal interfaces were measured by means of a current clamp in the frequency range 150 kHz to 30 MHz. The curve in Fig. 2-6 shows the peak values of the conducted emission using a 10 ms measuring time. Quasipeak and average values were measured at local maximums using a 1 s measuring time. The results are marked by a "∗" (quasipeak values) and by a "x" (average values). No deviations with regard to the applied standard could be detected.
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Interference current (150 kHz - 30 MHz): Data cable of Ethernet VINCELL LT 4.3 Boxed
50
QP-Limit (EN 55022 class B) AV-Limit (EN 55022 class B) QP-Measurement AV-Measurement
40
Current [dBµA]
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20
10
0
-10
-20
0.2
0.4
0.6
0.8
1
2
Frequency [MHz] TÜV NORD CERT | 11.2.2013
Fig. 2-5: Disturbing current on signal interface
Measuring information: Software: EMI Software 2012 07 EMI Receiver: ROHDE&SCHWARZ, ESS Date: 11.02.2013, Time: 13:47 BandWidth: 10 kHz Start frequency: 150.00 kHz Stop frequency: 6.55 MHz Scan step: 4.00 kHz Measure time of peak: 10 ms Ex-Attenuation: 10dB Transducer: 6741-1 Transducer option: Ethernet VINCELL LT 4.3 Boxed / Garz & Fricke GmbH
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Maximum of the disturbances with quasipeak detector Frequency[Hz] QP [dBµA] 23126000.000 9.050 26486000.000 8.270 29234000.000 7.460 1282000.000 7.180 28686000.000 7.060 1350000.000 6.960
QP-Limit [dBµA] Margin to limit [dB] 30.000 20.950 30.000 21.730 30.000 22.540 30.000 22.820 30.000 22.940 30.000 23.040
Maximum of the disturbances with average detector Frequency[Hz] AV [dBµA] 1282000.000 6.740 1214000.000 6.520 1350000.000 6.300 23126000.000 6.050 1418000.000 5.110 26486000.000 4.890
AV-Limit [dBµA] Margin to limit [dB] 20.000 13.260 20.000 13.480 20.000 13.700 20.000 13.950 20.000 14.890 20.000 15.110
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2.3 Disturbing field measurement 2.3.1 Test set-up The disturbing electromagnetic field of the EUT was measured in an anechoic chamber, in a 10-m-distance. The anechoic chamber fulfils the requirements of the standard EN 55016.
Fig. 2-6: Test set-up for the disturbing field measurement
2.3.2 Operating conditions Please refer to chapter 1. 2.3.3 Climatic conditions On Feb. 11, 2013 Ambient air temperature: 21 °C Humidity: 22 % Air pressure: 1012 hPa 2.3.4 Measuring equipment Semi-anechoic-chamber Receiver ESU8 Antenna: CBL 6112
No. 118 No. 305
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2.3.5 Limit values Fig. 2-7 to 2-8 show the limit values according to EN 61000-6-3 and EN 55022 class B for the quasipeak detector (QP), for a 10-m-distance. 2.3.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 2.34 dB. The expanded measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 4.68 dB. So the laboratory of EMV Services under-runs the maximum value of the expanded measurement uncertainty of EN 55016-4-2 (2004) for this measurement. Therefore the result of every measurement value at and below the limit is “passed”. 2.3.7 Measuring procedure and results The peak values of the disturbing field in the frequency range 30 MHz to 1 GHz were measured in horizontal and vertical antenna polarisations at three antenna heights. The maximum radiated emission was determined by turning the EUT 360° around and by the variation of the antenna height. The curves in Fig. 2-7 to 2-8 show the peak values of the radiated emission using a 10 ms measuring time. Quasipeak values were measured at local maximums using a 1 s measuring time. The results are marked by a „∗“. No deviations with regard to the applied standard could be detected.
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Radiated emission, maxhold in allround direction with three antenna heights, hor. polarization VINCELL LT 4.3, Ferrite on USB-OTG cable
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Peak measurement QP measurement QP-Limit (EN 61000-6-3, EN 55022 class B)
Fieldstrength [dBµV/m]
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TÜV NORD CERT | 11.2.2013
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Frequency [MHz]
Fig. 2-7: Radiated emission (30 MHz to 1 GHz), horizontal antenna polarisation
Measuring information: Software: RE Max ESU v.2012.08 EMI Receiver: Rohde&Schwarz, ESU-8 Date: 11.02.2013, Time: 10:03 Start frequency: 30.00 MHz Stop frequency: 1.00 GHz Step width: 32.33 kHz PreScan bandwidth: 100.00 kHz Search detector: QP Search bandwidth: 120 kHz Ex-Attent.: 0dB Transducer: CBL6112.KOR Transducer option: hor. VINCELL LT 4.3 Boxed / Garz & Fricke GmbH
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Maximum of the disturbances with quasipeak detector: Frequency [Hz] 480047680.000 960068352.000 911018688.000 893461696.000 833418688.000 784854016.000
QP valus [dBµV/m] 30.530 27.970 24.090 24.020 23.430 23.240
QP-limit [dBµV/m] 37.000 37.000 37.000 37.000 37.000 37.000
Distance to limit [dB] 6.470 9.030 12.910 12.980 13.570 13.760
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Radiated emission, maxhold in allround direction with three antenna heights, vert. polarization VINCELL LT 4.3, Ferrite on USB-OTG cable
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Peak measurement QP measurement QP-Limit (EN 61000-6-3, EN 55022 class B)
Fieldstrength [dBµV/m]
40
30
20
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TÜV NORD CERT | 11.2.2013
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1000
Frequency [MHz]
Fig. 2-8: Radiated emission (30 MHz to 1 GHz), vertical antenna polarisation
Measuring information: Software: RE Max ESU v.2012.08 EMI Receiver: Rohde&Schwarz, ESU-8 Date: 11.02.2013, Time: 09:53 Start frequency: 30.00 MHz Stop frequency: 1.00 GHz Step width: 32.33 kHz PreScan bandwidth: 100.00 kHz Search detector: QP Search bandwidth: 120 kHz Ex-Attent.: 0dB Transducer: CBL6112.KOR Transducer option: vert. VINCELL LT 4.3 Boxed / Garz & Fricke GmbH
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Maximum of the disturbances with quasipeak detector: Frequency [Hz] 480047680.000 975555968.000 903840640.000 887835648.000 30226334.000 791611648.000
QP valus [dBµV/m] 31.770 25.100 24.020 23.960 16.490 23.180
QP-limit [dBµV/m] 37.000 37.000 37.000 37.000 30.000 37.000
Distance to limit [dB] 5.230 11.900 12.980 13.040 13.510 13.820
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3 Immunity 3.1 ESD Test 3.1.1 Test set-up The test set-up for the ESD testing shows Fig. 3-1.
Fig. 3-1: Test set-up for ESD testing ESD (air and conducted discharges) were performed at several points of the EUT (arrows). 3.1.2 Test equipment Screened measuring room (large) Generator: dito
No. 229
3.1.3 Parameters The ESD was characterized by the following parameters: Amplitude:
2, 4, 8 kV (air discharge) 2, 4 kV (contact discharge) Polarity: +, Pulse/s: 1 Ten discharges of each polarity were performed at each test point.
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3.1.4 Operating conditions Please refer to chapter 1. 3.1.5 Climatic conditions On Feb. 12, 2013 Ambient air temperature: 22 °C Humidity: 32 % Air pressure: 1015 hPa 3.1.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 7.1%. Measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 14.2%. 3.1.7 Immunity performance criteria Criterion B. 3.1.8 Test result No malfunctions or influences were detected. The device fulfils criterion A.
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3.2 Immunity against electromagnetic fields 3.2.1 Test set-up The EUT was influenced by electromagnetic fields in the frequency range 80 MHz to 1 GHz and 1.4 GHz to 2.7 GHz. The testing took place in a semi-anechoic-chamber.
Fig. 3-2: Test set-up for radiated susceptibility test The electromagnetic field was generated in an anechoic chamber using the reference field method according to EN 61000-4-3. The transmitting antenna was driven by a defined power at each frequency in order to generate the desired field strength without the EUT at the position, where the EUT has been placed (uniform area). The distance between antenna and EUT was 3 m. Between antenna and EUT absorbers (anechoic cones) were placed. EUT positions: front side, refer to the Fig. 3-2 also. 3.2.2 Test equipment Semi-anechoic-chamber Field strength meas. system: Field probe: Signal generator: Power sensor: Amplifier: Antenna: Software:
FM 5004 HI-6005 No. 113 SMB100A No. 607 NAP-Z6 No. 115 NRT-Z44 No. 116 CBA G-500, Teseq AP32SW150, Prâna Biconical antenna 9983, EMCO Horn antenna, Model 3115 ETS ImmunityRS 2012 01
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3.2.3 Parameters Amplitude: Frequency range: Amplitude: Frequency range: Modulation: Frequency step: Duration / step: Polarization:
10 V/m 80 MHz to 1 GHz 3 V/m 1.4 GHz to 2.7 GHz 80 % AM, 1 kHz 1% 3s horizontal and vertical
3.2.4 Operating conditions Please refer to chapter 1. 3.2.5 Climatic conditions On Feb. 11, 2013 Ambient air temperature: 21 °C Humidity: 22 % Air pressure: 1012 hPa 3.2.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%. Plus the tolerance from the field homogeneity): RSS = ± 1.1 dB. Measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 2.2 dB. 3.2.7 Immunity performance criteria Criterion A.
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3.2.8 Test result Frequency (MHz) 80 - 1000 1400 - 2700 80 - 1000 1400 - 2700
Polarisation
Test result
horizontal horizontal vertical vertical
A A A A
No malfunctions or influences were detected. The device fulfils criterion A.
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3.3 Burst 3.3.1 Test set-up The test pulses were coupled into the power leads using a coupling network and into the data lines via coupling clamp.
Fig. 3-3: Test set-up for Burst test 3.3.2 Test equipment Screened measuring room (large) Burst Generator: PEFT Junior Coupling clamp: MEB
No. 205
3.3.3 Parameters The pulses were characterized by the following parameters: Single pulse rise time/duration: 5ns/50ns Amplitude: 2 kV on power lines 1 kV on data lines Polarity: +, Repetition rate: 5 kHz Burst duration: 15 ms Burst frequency: 3 Hz Test duration: 60 s (each) 3.3.4 Operating conditions Please refer to chapter 1.
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3.3.5 Climatic conditions On Feb. 12, 2013 Ambient air temperature: 22 °C Humidity: 25 % Air pressure: 1015 hPa 3.3.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 6.46%. Measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 12.9%. 3.3.7 Immunity performance criteria Criterion B. 3.3.8 Test results Amplitude ± 2 kV ± 1 kV ± 1 kV ± 1 kV ± 1 kV
Conductor DC supply lines and box Cable of RS232 Cable of RS485 Cable of CAN-bus Cable of Ethernet
Coupling PEFT Clamp Clamp Clamp Clamp
Test result B1 A A B2 B3
1: During the test message displayed error: “COM2 is failed”. 2: During the test message displayed error: “Network is failed”. 1: During the test message displayed error: “Network is failed”. No malfunctions or influences were detected. The device fulfils criterion B.
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3.4 Surge 3.4.1 Test set-up The test pulses were coupled into the power leads using a coupling network.
Fig. 3-4: Test set-up for Surge test
3.4.2 Test equipment Screened measuring room (large) Surge Generator: UCS-500 M4
No. 228
3.4.3 Parameters The pulses were characterized by the following parameters: Amplitude: Polarity: Rise time: Virtual time to half value: Pulses/polarity: Pulse/min: Synchronisation:
0.5 kV (line to line) +, 1.2 µs 50 µs 10 1 0°
3.4.4 Operating conditions Please refer to chapter 1.
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3.4.5 Climatic conditions On Feb. 12, 2013 Ambient air temperature: 22 °C Humidity: 25 % Air pressure: 1015 hPa 3.4.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 6.33%. Measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 12.7%. 3.4.7 Immunity performance criteria Criterion B. 3.4.8 Test result No malfunctions or influences were detected. The device fulfils criterion A.
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3.5 Immunity to conducted disturbances, induced by radio frequency fields 3.5.1 Test set-up The coupling was performed with the coupling network into the power leads and with the coupling clamp into the data lines.
Fig. 3-5: Test set-up for the immunity test against induced radio frequency fields 3.5.2 Test equipment Screened measuring room (large) Coupling network: M3 ISN ST08 USB/p Injection Clamp: F-2031 Decoupling Clamp: F-2031-DCN SML03 Amplifier: SCCX100 (IFI) Software: Immunity 2012 01 3.5.3 Parameters Amplitude: Modulation: Modulation depth: Modulation frequency: Frequency range: Frequency step: Duration / step:
10 V amplitude modulation 80 % 1 kHz 150 kHz to 80 MHz 1% 3s
No. 502 No. 521 No. 520 No. 509 No. 510 No. 606
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3.5.4 Operating conditions Please refer to chapter 1. 3.5.5 Climatic conditions On Feb. 12, 2013 Ambient air temperature: 22 °C Humidity: 25 % Air pressure: 1015 hPa 3.5.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematically-statistically distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentally but not inevitable normally distributed. The total deviation is supposed to be normally distributed (RSS=Root-Sum-of-the-Squares deviation corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%): RSS = ± 7.2%. Measurement uncertainty ∆ which will be not exceeded with a probability of 95% is 2 x RSS: ∆ = ± 14.5%. 3.5.7 Immunity performance criteria Criterion A. 3.5.8 Test results Amplitude 10 V 10 V 10 V 10 V 10 V
Conductor DC – power line RS232 RS485 CAN Ethernet
Coupling M3 clamp clamp clamp ISN ST08
Test result
No malfunctions or influences were detected. The device fulfils criterion A.
EMV Services Emission / Immunity
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4 Measuring instrument list State Jan 18, 2013 1 Marking
Measuring Instruments Manufacturer
Type
Serial-No.
last Cal.
Spectrumanalyzer
Advantest
R3271
55050076
May 12
next Cal. (+/- 3 Month) May 14
No.
EMI-Test Receiver
Rohde & Schwarz
ESHS 10
826865/012
Mar 11
Mar 13
102
EMI-Test Receiver
Rohde & Schwarz
ESS
827478/004
Oct 12
Oct 14
103
EMI-Test Receiver
Rohde & Schwarz
ESS
836769/010
Feb 11
Feb 13
104
101
DMM
Hewlett Packard
34401A
US36059532
May 12
May 14
105
Oszilloscope
Tektronix
TDS 684A
B 010356
Mar 11
Mar 13
106
Fieldstrength Probe
Holaday
HI-6005
52608
Nov 12
Nov 16
113
Signal amplifier
Hewlett Packard
8447F
2805A03113
Apr 12
Apr 14
114
Power sensor
Rohde & Schwarz
NAP-Z6
830262/014
Jan 12
Jan 14
115
Power sensor
Rohde & Schwarz
NRT-Z44
101718
Jan 12
Jan 14
116
Digital Power Analyzer
EM-Test
DPA 500
V0711102307
Mar 12
Mar 14
117
EMI-Test Receiver
Rohde & Schwarz
ESU8
100172
Jan 11
Jan 13
118
Spectrumanalyzer
Rohde & Schwarz
FSP3
100247
Apr 11
Apr 13
119
Field measurement system DMM
Symann & Trebbau
EM 200
100.03.015
Apr 11
Apr 13
120
Agilent
34401A
MY47051047
Oct 11
Oct 13
121
next Cal. (+/- 3 Month) Mar 14
No.
2
Generators
Marking
Manufacturer
Type
Serial-No.
last Cal.
Surge Generator
HILO-Test
CWG 4-104
921446
Mar 12
Surge Generator
EM-Test
VCS-500
0395-20
Mar 12
Mar 14
202
Burst-Generator
Haefely
PEFT Junior
083 180 - 29
Mar 12
Mar 14
205
Burst-Generator
Haefely
PEFT Junior
083 485 - 36
Mar 12
Mar 14
207
Surge-Generator
EM-Test
TSS-500
0794-09
Mar 12
Mar 14
213
Pulse-Generator
EM-Test
LD-200
0196-06
Jul 11
Jul 13
217
Pulse-Generator
EM-Test
EFT-200
0494-08
Jun 12
Jun 14
218
Pulse-Generator
EM-Test
VDS-200
0195-01
Dec 10
Dec 12
219
ESD-Generator
Keytek
MZ-15/EC
9409234
Feb 11
Feb 13
222
ESD-Test tip
Keytek
MZ TPC-2
9409257
Feb 11
Feb 13
223
201
Pulse-Generator
EM-Test
MPG-200
0195-03
Dec 10
Dec 12
224
Power Fail Simulator
EM-Test
PFS-503
0101-01
Aug 12
Aug 14
225
ESD-Generator
EM-Test
dito
0303/33
Feb 11
Feb 13
226
Pulse-Generator
EM-Test
OCS-500 M6
1003-02
Feb 12
Feb 14
227
Pulse-Generator
EM-Test
UCS-500 M4
V0726102639
Sep 12
Sep 14
228
ESD-Generator
EM-Test
dito
V0902104550
Feb 11
Feb 13
229
Electronic switch
EM-Test
BS 200 N
V1037107353
Nov 12
Nov 14
230
EMV Services Emission / Immunity
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Feb. 13, 2013
34 / 35
3
Antennas
Marking
Manufacturer
Type
Serial-No.
last Cal.
Biconical Antenna
Schwarzbeck
VHA 9103
9007
Mar 12
next Cal. (+/- 3 Month) Mar 16
Log.-per. Antenna
Schwarzbeck
UHALP 9108
9003
Mar 12
Mar 16
302
active Loop Antenna
Rohde & Schwarz
HFH2-Z2
836077/012
Oct 11
Oct 13
303
No. 301
3 Loop Antenna
Rohde & Schwarz
HM 020
839610/001
Sep 09
Sep 13
304
Bilog Antenna
CHASE Electronics
CBL6112
2082
Nov 09
Nov 13
305
Bilog Antenna
CHASE Electronics
CBL6111
1568
Nov 09
Nov 13
306
active Rod Antenna
Rohde & Schwarz
HFH2-Z1
872343/007
Oct 11
Oct 13
309
Double-Ridged Waveguide
ETS Lindgren
ETS3115
6413
Dec 12
Dec 18
311
4
Facilities
Marking
Manufacturer
Type
Serial-No.
last Cal.
No.
Clamp
MEB
AMZ 11
2
Sep 09
next Cal. (+/- 3 Month) Sep 13
401
V-LISN
Schwarzbeck
NSLK 8128
-
Jun 11
Jun 15
402
Current clamp
Solar
6741-1
922657
Dez 11
Dez 15
405
Current clamp
Rohde & Schwarz
EZ-17
835989/002
Dez 11
Dez 15
406
Voltage Probe
Schwarzbeck
TK 9421
9421-127
Apr 11
Apr 15
410
Voltage Probe
Rohde & Schwarz
ESH2-Z3
No. 2
Apr 11
Apr 15
411
V-LISN
Rohde & Schwarz
ESH2-Z5
835490 / 006
Jul 11
Jul 15
412
V-LISN
Schwarzbeck
NSLK 8127
8127-463
Jul 11
Jul 15
414
LISN
Schwarzbeck
NNBM 8125 BCI
8125-1200
Nov 10
Nov 14
415
LISN
Schwarzbeck
NNBM 8125 BCI
8125-1201
Nov 10
Nov 14
416
Pulse limiter
Rohde & Schwarz
ESH3-Z2
without
Jul 11
Jul 15
417
Pulse limiter
Rohde & Schwarz
ESH3-Z2
without
Jul 11
Jul 15
418
V-LISN
Schwarzbeck
NSLK 8127
8127-603
Jul 11
Jul 15
419
Pulse limiter
Rohde & Schwarz
ESH3-Z2
without
Jul 11
Jul 15
420
EMV Services Emission / Immunity
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Feb. 13, 2013
35 / 35
5
CDN
Marking
Manufacturer
CDN
MEB
T4
10840
CDN
MEB
M3
11181
CDN
MEB
T2
11398
CDN
FCC
M5
103
Aug 12
Aug 16
504
CDN
FCC
C1
35
Aug 12
Aug 16
505
CDN
FCC
M2
57
Aug 12
Aug 16
506
Type
Serial-No.
last Cal. Aug 12
next Cal. (+/- 3 Month) Aug 16
No. 501
Aug 12
Aug 16
502
Aug 12
Aug 16
503
CDN
FCC
AF8
17
Aug 12
Aug 16
508
EM Injection Clamp
FCC
F-203I
107
Aug 12
Aug 16
509
CDN
FCC
F-203I-DCN
40
Aug 12
Aug 16
510
CDN
MEB
S9
12341
Aug 12
Aug 16
511
CDN
MEB
S15
11300
Aug 12
Aug 16
512
CDN
MEB
S25
11342
Aug 12
Aug 16
513
CDN
MEB
M3
12192
Aug 12
Aug 16
514
CDN
MEB
M1
12028
Aug 12
Aug 16
515
CDN
MEB
M5
12245
Aug 12
Aug 16
516
EM Injection Clamp
FCC
F-203I
364
Aug 12
Aug 16
517
CDN
MEB / Schaffner
T400
16914
Aug 12
Aug 16
518
CDN
Teseq
S751
26559
Aug 12
Aug 16
519
CDN
Teseq
USB/p
27032
Aug 12
Aug 16
520
CDN
Teseq
ISN ST08
26574
Aug 12
Aug 16
521
CDN
Teseq
M116
29876
Aug 12
Aug 16
522
CDN
Teseq
M216
30289
Aug 12
Aug 16
523
CDN
Teseq
M416
28045
Aug 12
Aug 16
524
6
Signal Generators
Marking
Manufacturer
Type
Serial-No.
last Cal.
next Cal. (+/- 3 Month)
No.
Signal Generator
Rohde & Schwarz
SMP 22
831022/0007
Dec 12
Dec 14
601
Signal Generator
Marconi
2022 D
119160/046
Apr 11
Apr 13
602
Signal Generator
Marconi
2031
119748/007
Feb 12
Feb 14
605
Signal Generator
Rohde & Schwarz
SML 203
103132
Dec 12
Dec 14
606
Signal Generator
Rohde & Schwarz
SMB100A
103875
Jul 11
Jul 13
607
End of the Test Report