TTI-P-G 100/96-30 EMC Laboratory Test Report No. 05 / 5040-1-1 E4S-Box V1.0 S/N: 7 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.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 2 / 36 Customer: Stollmann Entwicklungs- + Vertriebs GmbH Mendelssohnstraße 15 D-22761 Hamburg Equipment under test: E4S-Box V1.0, SN: 7 Date of receipt: March 16, 2005 Date of test: March 16, 17, 2005 Test site: EMV Services GmbH & Co. KG Harburger Schlossstr. 6-12 D-21079 Hamburg Test personnel: Tel. Fax Email Dipl.-Ing. Oliver Schade 040 / 76629-1362 040 / 76629-506 schade@emv-services.de Dipl.-Ing. René Kyek 040 / 76629-1361 040 / 76629-506 kyek@emv-services.de Applied standards: EN 55022 (1998) + A1 (2000) + A2 (2003): Information technology equipment Radio disturbance characteristics Limits and methods of measurement EN 55024 (1998) + A1 (2001): Information technology equipment characteristics Limits and methods of measurement EN 61000-3-3 (1995)+ A1 (2001): Voltage fluctuation and flicker EN 61000-4-2 (2001): Electrostatic discharge immunity test EN 61000-4-3 (2001): Radiated, radio-frequency electromagnetic field - immunity test EN 61000-4-4 (2001): Electrical fast transient/burst immunity test EN 61000-4-5 (2001): Surge immunity tests EN 61000-4-6 (2001): to conducted disturbances, induced by radio frequency fields EN 61000-4-11 (2001): Voltage dips, short interruptions and voltage variations immunity test
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 3 / 36 Test results: The device complies with the limits for: conducted emission (class B, EN 55022), radiated emission (class B, EN 55022), voltage fluctuation and flicker (EN 61000-3-3). The device complies with the immunity requirement of EN 55024 against: electrostatic discharge (EN 61000-4-2) with the criterion A, radiated, radio-frequency electromagnetic field (EN 61000-4-3) with criterion A, electrical fast transient / burst (EN 61000-4-4) with criterion A, surges (EN 61000-4-5) with criterion A, conducted disturbances, induced by radio frequency fields (EN 61000-4-6) with criterion A, voltage dips, short interruptions and voltage variations (EN 61000-4-11) with demanded criteria. The test results only apply to the Equipment under test. Dr. Ernst Sauer Lab manager p.p. Dipl.-Ing. Oliver Schade EMV Services GmbH & Co. KG Ein Unternehmen der TÜV Nord Gruppe Harburger Schlossstraße 6-12 D-21079 Hamburg
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 4 / 36 Table of contents 1 DEVICE UNDER TEST AND OPERATING CONDITIONS 7 2 EMISSION 8 2.1 Conducted emission in accordance with EN 55022 class B disturbing voltage measurement 8 2.1.1 Test set-up 8 2.1.2 Operating conditions 8 2.1.3 Climatic conditions 8 2.1.4 Measuring equipment 8 2.1.5 Limit values 9 2.1.6 Uncertainty of measurements 9 2.1.7 Measuring procedure and results 9 2.2 Conducted emission in accordance with EN 55022 class B disturbing current measurement 12 2.2.1 Test set-up 12 2.2.2 Operating conditions 12 2.2.3 Climatic conditions 12 2.2.4 Measuring equipment 12 2.2.5 Limit values 13 2.2.6 Uncertainty of measurements 13 2.2.7 Measuring procedure and results 13 2.3 Disturbing field measurement in accordance with EN 55022 class B 16 2.3.1 Test set-up 16 2.3.2 Operating conditions 16 2.3.3 Climatic conditions 16 2.3.4 Measuring equipment 16 2.3.5 Limit values 17 2.3.6 Uncertainty of measurements 17 2.3.7 Measuring procedure and results 17 2.4 Voltage fluctuations and flicker measurement in accordance with EN 61000-3-3 20 2.4.1 Test set-up 20 2.4.2 Operating conditions 20 2.4.3 Climatic conditions 20 2.4.4 Measuring equipment 20 2.4.5 Uncertainty of measurements 20 2.4.6 Limit values 21 2.4.7 Measuring procedure and results 21 3 IMMUNITY IN ACCORDANCE WITH EN 55024 22
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 5 / 36 3.1 ESD Test 22 3.1.1 Test set-up 22 3.1.2 Test equipment 22 3.1.3 Parameters 22 3.1.4 Operating conditions 23 3.1.5 Climatic conditions 23 3.1.6 Uncertainty of measurements 23 3.1.7 performance criteria 23 3.1.8 Test result 23 3.2 against electromagnetic fields 24 3.2.1 Test set-up 24 3.2.2 Test equipment 24 3.2.3 Parameters 24 3.2.4 Operating conditions 25 3.2.5 Climatic conditions 25 3.2.6 Uncertainty of measurements 25 3.2.7 performance criteria 25 3.2.8 Test result 25 3.3 Burst 26 3.3.1 Test set-up 26 3.3.2 Test equipment 26 3.3.3 Parameters 26 3.3.4 Operating conditions 27 3.3.5 Climatic conditions 27 3.3.6 Uncertainty of measurements 27 3.3.7 performance criteria 27 3.3.8 Test results 27 3.4 Surge 28 3.4.1 Test set-up 28 3.4.2 Test equipment 28 3.4.3 Parameters 28 3.4.4 Operating conditions 28 3.4.5 Climatic conditions 29 3.4.6 Uncertainty of measurements 29 3.4.7 performance criteria 29 3.4.8 Test result 29 3.5 to conducted disturbances, induced by radio frequency fields 30 3.5.1 Test set-up 30 3.5.2 Test equipment 30 3.5.3 Parameters 30 3.5.4 Operating conditions 31 3.5.5 Climatic conditions 31 3.5.6 Uncertainty of measurements 31 3.5.7 performance criteria 31 3.5.8 Test results 31
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 6 / 36 3.6 Voltage dips, short interruptions and voltage variations immunity tests 32 3.6.1 Test set-up 32 3.6.2 Test equipment 32 3.6.3 Parameters 32 3.6.4 Operating conditions 32 3.6.5 Climatic conditions 32 3.6.6 Uncertainty of measurements 33 3.6.7 performance criteria 33 3.6.8 Test results 33 4 MEASURING INSTRUMENT LIST 34
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 7 / 36 1 Device under test and operating conditions Nominal voltage: 12 V DC Description: The ES4 Box consists of 4 identical ISDN BRI S0 interfaces, 1 Ethernet 100BaseT interface, 1 RS232 control port for service and a 12V DC power supply. Operating conditions: During all tests call establishment was controlled via Ethernet. The calls were made from the E4S box S0 interface to an ISDN phone via an ISDN PBX. All voice data were mirrored in the E4S Box. The ISDN phone was used in the hands-free mode and stimulated with a metronome. The echo was supervised during all tests. The EUT was adapted to a mains adaptor as follows: Model: SA06L1113-V input: 100-240 V AC output: 12 V DC, 15 W The EUT was observed with the following equipment: telecommunications system: elmeg 8 (DSS1) 5960 108368.6 ISDN telephone: DeTeWe EuroMaster, SN: 0000090 Fig. 1-1 and 1-2: The EUT and its interfaces
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 8 / 36 2 Emission 2.1 Conducted emission in accordance with EN 55022 class B disturbing voltage measurement 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 Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 2.1.4 Measuring equipment Screened measuring room (small) Receiver: ESHS No. 102 Artif. mains network: HM6050-2 No. 414
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 9 / 36 2.1.5 Limit values Fig. 2-2 to 2-3 show the limit values according to EN 55022 class B for the quasipeak detector (QP) and the average detector (AV). 2.1.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 = ± 0.56 db. Measurement uncertainty which will be not exceeded with a probability of 95% is 2 x RSS: = ± 1.1 db. 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.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 10 / 36 80 Conducted emission (150 khz - 30 MHz): line L E4S-Box 70 Quasipeak-Limit (class B) Average-Limit (class B) 60 Interference voltage [dbµv] 50 40 30 20 10 0-10 2 3 4 5 6 7 8 910 6 2 3 4 5 6 7 8 910 7 2 3 Frequency [Hz] EMV Services 16.3.2005 Fig. 2-2: Conducted emission (150 khz - 30 MHz), conductor L Measuring information: EMI Receiver Software 2002 V2.0 EMI Receiver: ROHDE&SCHWARZ,ESHS10 Date: 16.03.2005, Time: 14:07 Start frequency: 1.50E+5Hz Stop frequency: 3.00E+7Hz Band width: 1.00E+4Hz Step width: 4.00E+3Hz Measure time of peak: 10ms Detector: QP & AV Ex-Attenuation: 10dB Transducer: 'Kab_kl' Transducer option: Line L E4S-Box / Stollmann Normal operation
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 11 / 36 80 Conducted emission (150 khz - 30 MHz): line N E4S-Box 70 Quasipeak-Limit (class B) Average-Limit (class B) 60 Interference voltage [dbµv] 50 40 30 20 10 0-10 2 3 4 5 6 7 8 910 6 2 3 4 5 6 7 8 910 7 2 3 EMV Services 16.3.2005 Frequency [Hz] Fig. 2-3: Conducted emission (150 khz - 30 MHz), conductor N Measuring information: EMI Receiver Software 2002 V2.0 EMI Receiver: ROHDE&SCHWARZ,ESHS10 Date: 16.03.2005, Time: 14:14 Start frequency: 1.50E+5Hz Stop frequency: 3.00E+7Hz Band width: 1.00E+4Hz Step width: 4.00E+3Hz Measure time of peak: 10ms Detector: QP & AV Ex-Attenuation: 10dB Transducer: 'Kab_kl' Transducer option: Line N E4S-Box / Stollmann Normal operation
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 12 / 36 2.2 Conducted emission in accordance with EN 55022 class B disturbing current measurement 2.2.1 Test set-up The disturbing current was measured on the ethernet and S0 cable with a measuring receiver and a current clamp. Fig. 2-4 and 2-5: Test set-up for the disturbing current measurement 2.2.2 Operating conditions Please refer to chapter 1. 2.2.3 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 2.2.4 Measuring equipment Screened measuring room (small) Receiver: ESHS No. 102 Current clamp: 6741-1 No. 405
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 13 / 36 2.2.5 Limit values Fig. 2-6 and 2-7 show the limit values according to EN 55022 class B for the quasipeak detector (QP) and the average detector (AV). 2.2.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 = ± 0.56 db. Measurement uncertainty which will be not exceeded with a probability of 95% is 2 x RSS: = ± 1.1 db. 2.2.7 Measuring procedure and results The disturbing current on the signal lines were measured by means of an artificial mains network in the frequency range 150 khz to 30 MHz. The curves in Fig. 2-6 and 2-7 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.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 14 / 36 80 70 60 Conducted emission (150 khz - 30 MHz): RJ 45 cable E4S-Box QP-Limit (EN 61000-6-3) AV-Limit (EN 61000-6-3) QP measurement AV measurement Interference current [dbµa] 50 40 30 20 10 0-10 -20 2 3 4 5 6 7 8 910 6 2 3 4 5 6 7 8 910 7 2 3 Frequency [Hz] EMV Services GmbH 16.3.2005 Fig. 2-6: Interference current (150 khz - 30 MHz), ethernet cable Measuring information: EMI Receiver Software 2002 V2.0 EMI Receiver: ROHDE&SCHWARZ,ESHS10 Date: 16.03.2005, Time: 14:38 Start frequency: 150.00E+3Hz Stop frequency: 30.00E+6Hz Band width: 10.00E+3Hz Step width: 4.00E+3Hz Measure time of peak: 10ms Detector: QP & AV Ex-Attenuation: 0dB Transducer: '6741-1' Transducer option: E4S-Box / Stollmann Normal operation
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 15 / 36 80 70 60 Conducted emission (150 khz - 30 MHz): ISDN cable E4S-Box QP-Limit (EN 61000-6-3) AV-Limit (EN 61000-6-3) QP measurement AV measurement Interference current [dbµa] 50 40 30 20 10 0-10 -20 2 3 4 EMV Services GmbH 16.3.2005 5 6 7 8 910 6 2 3 Frequency [Hz] 4 5 6 7 8 910 7 2 3 Fig. 2-7: Interference current (150 khz - 30 MHz), S0 cable Measuring information: EMI Receiver Software 2002 V2.0 EMI Receiver: ROHDE&SCHWARZ,ESHS10 Date: 16.03.2005, Time: 14:46 Start frequency: 150.00E+3Hz Stop frequency: 30.00E+6Hz Band width: 10.00E+3Hz Step width: 4.00E+3Hz Measure time of peak: 10ms Detector: QP & AV Ex-Attenuation: 0dB Transducer: '6741-1' Transducer option: E4S-Box / Stollmann Normal operation
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 16 / 36 2.3 Disturbing field measurement in accordance with EN 55022 class B 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 fulfills the requirements of the standard EN 50147 (1996). Fig. 2-8: Test set-up 2.3.2 Operating conditions Please refer to chapter 1. 2.3.3 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 2.3.4 Measuring equipment Semi-anechoic-chamber Receiver ESS No. 103 Antennas: CBL 6112 No. 305
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 17 / 36 2.3.5 Limit values Fig. 2-9 and 2-10 show the limit values according to 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 experimentally statistical calculated measurement uncertainty. The momentary highest calculated standard deviation is ± 0.68 db (RSS=Root-Sum-of-the-Squares deviation). This corresponds to an measurement uncertainty which will be not exceeded with a probability of 68%. Measurement uncertainty which will be not exceeded with a probability of 95% (factor 2.16, t-distribution): = ± 1.5 db. 2.3.7 Measuring procedure and results The peak values of the disturbing field in the frequency range 30 MHz to 1000 MHz were measured in vertical and horizontal antenna polarisations. The curves in Fig. 2-9 and 2-10 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. The test passed because the value of the resistor R26 was increased from 10 to 75 Ω.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 18 / 36 50 45 Radiated emission (30-1000 MHz), hor. polarisation E4S-Box Quasipeak-Limit (class B) 40 Fieldstrength [dbµv/m] 35 30 25 20 15 10 5 0 3 4 5 6 7 8 9 10 8 2 3 4 5 6 7 8 9 10 9 Frequency [Hz] EMV Services 16.3.2005 Fig. 2-9: Radiated emission (30 MHz - 1000 MHz), horizontal antenna polarisation Measuring information: EMI Receiver Software 2002 V2.0 EMI Receiver: ROHDE&SCHWARZ,ESS Date: 16.03.05, Time: 11:02 Start frequency: 3.00E+7Hz Stop frequency: 1.00E+9Hz Band width: 1.20E+5Hz Step width: 4.00E+4Hz Measure time of peak: 10ms Detector: QP Ex-Attenuation: 0dB Transducer: 'cbl6112k' Transducer option: Hor. antenna polarisation ES4-Box / Stollmann
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 19 / 36 50 45 Radiated emission (30-1000 MHz), vert. polarisation E4S-Box Quasipeak-Limit (class B) 40 Fieldstrength [dbµv/m] 35 30 25 20 15 10 5 0 3 4 5 6 7 8 9 10 8 2 3 4 5 6 7 8 9 10 9 Frequency [Hz] EMV Services 16.3.2005 Fig. 2-10: Radiated emission (30 MHz - 1000 MHz), vertical antenna polarisation Measuring information: EMI Receiver Software 2002 V2.0 EMI Receiver: ROHDE&SCHWARZ,ESS Date: 16.03.05, Time: 10:47 Start frequency: 3.00E+7Hz Stop frequency: 1.00E+9Hz Band width: 1.20E+5Hz Step width: 4.00E+4Hz Measure time of peak: 10ms Detector: QP Ex-Attenuation: 0dB Transducer: 'cbl6112k' Transducer option: Vert. antenna polarisation ES4-Box / Stollmann
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 20 / 36 2.4 Voltage fluctuations and flicker measurement in accordance with EN 61000-3-3 2.4.1 Test set-up Fig. 2-11: Test set-up for the flicker measurement 2.4.2 Operating conditions Please refer to chapter 1. 2.4.3 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 2.4.4 Measuring equipment Power analyzer: PM 3000A No.: 111 AC Power Source 4500 L (California Instruments) 2.4.5 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly but not inevitable normally distributed.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 21 / 36 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 = ± 0.51%. Measurement uncertainty which will be not exceeded with a probability of 95% is 2 x RSS: = ± 1.02%. 2.4.6 Limit values Short time flicker value: P st = 1 Relative constant voltage deviation: dc[%] = 3.3 Maximum relative voltage deviation: dmax[%] = 4 Maximum temporal voltage variation: d(t)[ms] = 500 2.4.7 Measuring procedure and results Limit Measurement values P st = 1.00 0.114 dc[%] = 3.3 0.015 dmax[%] = 4 0.044 d(t)[ms ] = 500 0 No deviations with regard to the applied standard could be detected.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 22 / 36 3 in accordance with EN 55024 3.1 ESD Test 3.1.1 Test set-up The test set-up for the ESD testing show Fig. 3-1 to 3-3. Fig. 3-1 to 3-3: Test set-up for ESD testing 3.1.2 Test equipment Screened measuring room (small) Generator: MZ TPC-2 No. 223 3.1.3 Parameters The ESD was characterized by the following parameters: Amplitude: 4 kv (contact discharge) 8 kv (air discharge)
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 23 / 36 Polarity: +, - Pulse/s: 1 Ten discharges of each polarity were performed at each test point. 3.1.4 Operating conditions Please refer to chapter 1. 3.1.5 Climatic conditions Feb. 17, 2005 Ambient air temperature: 23 C Humidity: 27 % Air pressure: 1027 hpa 3.1.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 performance criteria Criterion B. 3.1.8 Test result No malfunctions or influences were detected. The device fulfills criterion A.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 24 / 36 3.2 against electromagnetic fields 3.2.1 Test set-up The EUT was influenced by electromagnetic fields in the frequency range 80 MHz to 1000 MHz (amplitude modulation). Fig. 3-4 and 3-5: 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. 3.2.2 Test equipment Semi-anechoic-chamber Field strength meas. system: FM 2004 No. 107 Field probe: HI-4421G No. 113 Signal generator: 2032 No. 603 Amplifier: Antennas: PST, 500-1000 W, Pötschke Biconical antenna 9983, EMCO Log. per. antenna 10013, EMCO 3.2.3 Parameters Amplitude: 3 V/m Frequency range: 80-1000 MHz Modulation: 80 % AM, 1 khz Frequency steps: < 1% Average wobble rate: < 1.5 10-3 Decades/s Polarisation: horizontal and vertical
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 25 / 36 3.2.4 Operating conditions Please refer to chapter 1. 3.2.5 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 3.2.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 performance criteria Criterion A. 3.2.8 Test result No malfunctions or influences were detected. The device fulfills criterion A.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 26 / 36 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 (ethernet and S0) via coupling clamp. Fig. 3-6: Test set-up for Burst test 3.3.2 Test equipment Screened measuring room (small) Burst Generator: PEFT Junior No. 205 Coupling clamp: MEB 3.3.3 Parameters The pulses were characterized by the following parameters: Single pulse rise time/duration: 5ns/50ns Amplitude: 1 kv on power lines 0,5 kv on data lines Polarity: +, - Repetition rate: 5 khz Burst duration: 15 ms Burst frequency: 3 Hz Test duration: 60 s (each)
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 27 / 36 3.3.4 Operating conditions Please refer to chapter 1. 3.3.5 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 3.3.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 performance criteria Criterion B. 3.3.8 Test results Amplitude Conductor Coupling Result ± 1 kv L CN1 o.k. ± 1 kv N CN1 o.k. ± 1 kv PE CN1 o.k. ± 1 kv L, N, PE CN1 o.k. ± 0,5 kv ethernet cable clamp o.k. ± 0,5 kv S0 cable clamp o.k. No malfunctions or influences were detected. The device fulfills criterion A.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 28 / 36 3.4 Surge 3.4.1 Test set-up The test pulses were coupled into the power leads using a coupling network. Fig. 3-7: Test set-up for Surge test 3.4.2 Test equipment Screened measuring room (small) Surge Generator: VCS 500 No. 202 3.4.3 Parameters The pulses were characterized by the following parameters: Amplitude: 1 kv (common mode) 2 kv (differential mode) Polarity: +, - Rise time: 1.2 µs Virtual time to half value: 50 µs Pulses/polarity: 10 Pulse/min: 1 Synchronization: 0, 90, 270 3.4.4 Operating conditions Please refer to chapter 1.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 29 / 36 3.4.5 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa 3.4.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 performance criteria Criterion B. 3.4.8 Test result Coupling Amplitude +0,5 kv -0,5 kv +1 kv -1 kv +2 kv -2 kv Phase 0 90 0 270 0 90 0 270 0 90 0 270 L - N 1x 1x 1x 1x 1x 2x 1x 2x --- --- --- --- L - PE 1x 1x 1x 1x 1x 1x 1x 1x 1x 2x 1x 2x N - PE 1x 1x 1x 1x 1x 1x 1x 1x 1x 2x 1x 2x No malfunctions or influences were detected. The device fulfills criterion A.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 30 / 36 3.5 to conducted disturbances, induced by radio frequency fields 3.5.1 Test set-up The coupling was performed with the coupling networks M3 into the power leads and T400 into the data lines (ethernet and S0). Fig. 3-8: Test set-up 3.5.2 Test equipment Screened measuring room (large) Coupling network: M3 No. 502 T400 No. 518 Signal generator: SMY 01 No. 604 Amplifier: 6000N (PMM) 3.5.3 Parameters Amplitude: 3 V (power leads and data lines) Modulation: 80 % AM, 1 khz Frequency range: 150 khz to 80 MHz Steps: < 1% Average wobbel rate: 1,5 10-3 Decades/s
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 31 / 36 3.5.4 Operating conditions Please refer to chapter 1. 3.5.5 Climatic conditions Feb. 17, 2005 Ambient air temperature: 23 C Humidity: 27 % Air pressure: 1027 hpa 3.5.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 performance criteria Criterion A. 3.5.8 Test results No malfunctions or influences were detected. The device fulfills criterion A.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 32 / 36 3.6 Voltage dips, short interruptions and voltage variations immunity tests 3.6.1 Test set-up The coupling was performed with the programmable power source. 3.6.2 Test equipment Fig. 3-9: Test set-up Power analyzer: PM 3000A No.: 111 AC Power Source 4500 L (California Instruments) 3.6.3 Parameters Reduction [%] Time [ms] 100 10 30 500 100 5000 3.6.4 Operating conditions Please refer to chapter 1. 3.6.5 Climatic conditions Feb. 16, 2005 Ambient air temperature: 22 C Humidity: 35 % Air pressure: 1025 hpa
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 33 / 36 3.6.6 Uncertainty of measurements The total uncertainty of measurement is the result of the mathematical statistic distribution of the individual measurement uncertainty of the used measurement equipment. It is supposed that all individual deviations accidentaly 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 = ± 1.3%. Measurement uncertainty which will be not exceeded with a probability of 95% is 2 x RSS: = ± 2.6%. 3.6.7 performance criteria Reduction [%] Time [ms] demanded criterion 100 10 B 30 500 C 100 5000 C 3.6.8 Test results Reduction [%] Voltage [V] Time [ms] Result 100 0 10 A 30 161 500 A 100 0 5000 C The device fulfills the demanded criteria.
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 34 / 36 4 Measuring instrument list State: Mar 04, 2005 1 Measuring Instruments Marking Manufacturer Type Serial-No. last Cal. next Cal. No. (+/- 3 Month) Spectrumanalyzer Advantest R3271 55050076 Jan 03 Jan 05 101 EMI-Test Receiver Rohde & Schwarz ESHS 10 826865/012 Jul 04 Jul 06 102 EMI-Test Receiver Rohde & Schwarz ESS 827478/004 Oct 04 Oct 06 103 EMI-Test Receiver Rohde & Schwarz ESS 836769/010 Jan 04 Jan 06 104 DMM Hewlett Packard 34401A 3146 A 05639 Jan 03 Jan 05 105 Oszilloscope Tektronix TDS 684A B 010356 Jan 04 Jan 06 106 Fieldstrength Monitor Amplifier Research FM 2004 12407 May 01 May 05 107 Power Analyzer Voltech PM3000A 9246 Nov 04 Nov 06 111 EMI-Test Receiver Rohde & Schwarz ESMI 838335/009 Jul 04 Jul 06 112 Fieldstrength Probe Holaday HI-4421G 85032 May 01 May 05 113 2 Generators Marking Manufacturer Type Serial-No. last Cal. next Cal. (+/- 3 Month) No. Surge Generator EM-Test VCS-500 0395-20 Jan 03 Jan 05 202 Burst-Generator Haefely PEFT Junior 083 180-29 Dec 02 Dec 04 205 ESD-Test System Schaffner NSG 435 1571 Feb 04 Feb 06 206 Burst-Generator Haefely PEFT Junior 083 485-36 Dec 02 Dec 04 207 Pulse-Generator California Instr. 4500L-1HGA- 4710 51758, 71009, 71027, 71042 Nov 03 Nov 05 208 Surge-Generator EM-Test TSS-500 0794-09 Jan 03 Jan 05 213 Burst-Generator EM-Test EFT-500 0795-44 Dec 02 Dec 04 214 Surge-Generator EM-Test VCS-500 0795-12 Jan 03 Jan 05 216 Pulse-Generator EM-Test LD 200 0095-01 Oct 03 Oct 05 217 Pulse-Generator EM-Test EFT-200 0494-08 Oct 03 Oct 05 218 Pulse-Generator EM-Test VDS-200 0195-01 Oct 03 Oct 05 219 ESD-Generator Keytek MZ-15/EC 9409234 Feb 04 Feb 06 222 ESD-Test tip Keytek MZ TPC-2 9409257 Feb 04 Feb 06 223 Pulse-Generator EM-Test MPG-200 0195-03 Oct 03 Oct 05 224 Power Fail Simulator EM-Test PFS-503 0101-01 Dec 02 Dec 04 225 ESD-Generator EM-Test dito 0303/33 Sep 04 Sep 06 226 Pulse-Generator EM-Test OCS-500 M6 1003-02 Feb 05 Feb 07 227
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 35 / 36 3 Antennas Marking Manufacturer Type Serial-No. last Cal. next Cal. No. (+/- 3 Month) Biconical Antenna Schwarzbeck VHA 9103 9007 Sep 04 Sep 08 301 Log.-Per. Antenna Schwarzbeck UHALP 9108 9003 Sep 04 Sep 08 302 active Loop Antenna Rohde & Schwarz HFH2-Z2 832609/012 Feb 05 Feb 07 303 3 Loop Antenna Rohde & Schwarz HM 020 839610/001 Nov 00 Nov 04 304 Bilog Antenna CHASE Electronics CBL6112 2082 Sep 04 Sep 08 305 Bilog Antenna CHASE Electronics CBL6111 1568 Sep 04 Sep 08 306 Biconical Antenna Rohde & Schwarz HK 116 831931/015 Sep 04 Sep 08 307 Log.-Per. Antenna Rohde & Schwarz HL 223 835556/002 Sep 04 Sep 08 308 active Rod Antenna Rohde & Schwarz HFH2-Z1 872343/007 Feb 05 Feb 07 309 Log.-Per. Antenna Rohde & Schwarz HL 025 352069/001 Nov 00 Nov 04 310 4 Facilities Marking Manufacturer Type Serial-No. last Cal. next Cal. No. (+/- 3 Month) Clamp MEB AMZ 11 2 Mar 05 Mar 09 401 V-LISN Schwarzbeck NSLK 8128 - Jan 05 Jan 09 402 T-LISN 10 khz - 30 MHz Schwarzbeck NTFM 8132 - Jan 05 Jan 09 403 T-LISN 30 MHz - 150 MHz Schwarzbeck NTFM 8133 - Jan 05 Jan 09 404 Current clamp Solar 6741-1 922657 Apr 03 Apr 07 405 Current clamp Rohde & Schwarz EZ-17 835989/002 Apr 03 Apr 07 406 V-LISN Rolf Heine NNB 4/63 TL 4/63-96004 Jan 05 Jan 09 407 LISN Rohde & Schwarz ESH3-Z6 835273/015 Jan 05 Jan 09 408 LISN Rohde & Schwarz ESH3-Z6 840522/006 Jan 05 Jan 09 409 Voltage Probe Rohde & Schwarz ESH2-Z3 Nr 1 Nov 02 Nov 06 410 Voltage Probe Rohde & Schwarz ESH2-Z3 Nr 2 Nov 02 Nov 06 411 V-LISN Rohde & Schwarz ESH2-Z5 835490 / 006 Jan 05 Jan 09 412 4-Line T-LISN Schwarzbeck NTFM 8136 111 Jan 05 Jan 09 413 LISN HAMEG HM6050-2 025880032 Sep 04 Sep 08 414
No. 05/5040-1-1 EMV-05/5040-1-1 March 22, 05 36 / 36 5 CDN Marking Manufacturer Type Serial-No. last Cal. next Cal. No. (+/- 3 Month) CDN MEB T4 10840 Jul 04 Jul 08 501 CDN MEB M3 11181 Jul 04 Jul 08 502 CDN MEB T2 11398 Jul 04 Jul 08 503 CDN FCC M5 103 Jul 04 Jul 08 504 CDN FCC C1 35 Jul 04 Jul 08 505 CDN FCC M2 57 Jul 04 Jul 08 506 CDN FCC AF2 40 Jul 04 Jul 08 507 CDN FCC AF8 17 Jul 04 Jul 08 508 EM Injection Clamp FCC F-203I 107 Jul 04 Jul 08 509 CDN FCC F-203I-DCN 40 Jul 04 Jul 08 510 CDN MEB S9 12341 Jul 04 Jul 08 511 CDN MEB S15 11300 Jul 04 Jul 08 512 CDN MEB S25 11342 Jul 04 Jul 08 513 CDN MEB M3 12192 Jul 04 Jul 08 514 CDN MEB M1 12028 Jul 04 Jul 08 515 CDN MEB M5 12245 Jul 04 Jul 08 516 EM Injection Clamp FCC F-203I 364 Jul 04 Jul 08 517 CDN MEB T400 16914 Jul 04 Jul 08 518 6 Signal Generators Marking Manufacturer Type Serial-No. last Cal. next Cal. (+/- 3 Month) No. Signal Generator Rohde & Schwarz SMP 22 831022/0007 Dec 02 Dec 04 601 Signal Generator Marconi 2022 D 119160/046 Jul 04 Jul 06 602 Signal Generator Marconi 2032 119580/009 Jan 05 Jan 07 603 Signal Generator Rohde & Schwarz SMY 01 840703/016 Jan 05 Jan 07 604 Signal Generator Marconi 2031 119748/007 Jan 05 Jan 07 605 End of the Test Report