all you Need for emc testing The complete product range Innovative equipment for emc testing and measuring

all you Need for emc testing The complete product range Innovative equipment for emc testing and measuring

EMC Testing EMI Measuring THE FULL RANGE OF EM TEST: Solutions for all industrial sectors About EM TEST The EMC company pages 4 5 Operation concept and software pages 6 7 Simulators & EMC-equipment Automotive Renewable energy pages 8 15 pages 16 25 Telecom pages 26 39 Industry pages 40 53 Medical Residential Broadcast Components & safety pages 54 63 Military pages 64 69 Aircraft Accessories pages 70 77 Services > Service & support > Accredited calibration laboratory > Extended warranty > EMC-testing laboratory > EMC-Seminars and workshops > Rental service pages 78 83 Accredited Laboratories Confide nce for sure! 3

the emc company ELECTROMAGNETIC COMPATIBILITY Innovative technology for emc testing and measuring Any electronic or electrical device is part of a complex environment, heavily charged with conducted and radiated interference. Every electronic or electrical device is required to operate as intended in this environment without generating electromagnetic disturbances affecting other devices in its vicinity. A wide range of standards and directives regulate both the susceptibility as well as the maximum permissible emission level for each device. For you as a manufacturer both aspects need to be carefully examined and considered from the very early stages of development to obtain a high-quality product in terms of electromagnetic compatibility. EM TEST offers outstanding expertise in EMC. Our solutions and know-how in testing the susceptibility and measuring emissions are recognised worldwide. EM TEST is the leading manufacturer of high-class, fully compliance EMC testing and measurement equipment for the electronics industry in the automotive, telecom, medical, industrial electronics, avionics and military sectors. Company Specified in Standards Standards provide a driving force in the EMC business and form the framework for any manufacturer of electronic products and systems, protecting and safeguarding the environment from unnecessary electromagnetic interference. Standards are vital in this sector and test equipment manufacturers make a valuable contribution in highlighting technical aspects and practical applications for the equipment specified in the standards. This leads to more application-oriented standards, which directly benefit the user. EM TEST experts are members of national and international research groups and standards committees. In this way we contribute towards adaptive and practical standards. Consequently, we guarantee that the technical specifications are integrated in our products and testing procedures are interpreted according to the relevant standards. We thereby anticipate future developments of standards for the benefit of our customers. NOT ONLY DO WE MANUFACTURE AND SUPPLY TEST EQUIPMENT WE ALSO PROVIDE COMPLETE SOLUTIONS, e.g.: > Full compliance with current requirements and adaptability to future developments > ACCESSORIES FOR EASY AND COMPLIANT TEST SET-UP INSTALLATIONS > USER-FRIENDLY TEST ROUTINES, LIBRARIES OF STANDARDS AND TEST REPORT GENERATION 5

The Operation Concept The basis for versatile and multiple applications A closer Look at the Software Everything is there, everything is possible easy Selection of predefined norms and products Concept outstanding ease of operation The Function Keys Cursor keys and rotary knob ensure maximum user-friendly operation of the simulator. Parameters and complete test routines are selected via function keys. Comprehensive navigation makes operation as easy as possible. Service and self-check routines enable the user to verify the generator. presentation of the results as A well arranged test report Test Report iso.control Test Report iso.control test report Clear Display GPIB and USB Interfaces Fail1 and Fail2 Menus and parameters are clearly arranged in the LCD display for quick and accurate programming of tests. Every generator is equipped with both GPIB and USB interfaces for remote control. Fail1 and Fail2 inputs are implemented for DUT monitoring purposes. Page 2 of 3 6 7

automotive battery simulation The VDS 200N series is used to simulate the various battery supply waveforms recommended by international standards and car manufacturer standards. The wide range of manufacturer requirements make this an extremely important area, which is covered by the VDS 200N series. Additionally, the VDS 200N series serves as a powerful DC voltage supply for the DUT during tests with automotive transients. AutoWave is used for the following applications: > Generation of all kinds of voltage profiles via software > Replay of imported data or plot files, record & play > Recording voltage variations in the actual vehicle > replaying the measured data via a suitable DC source or amplifier > Analysis of recorded voltages and currents > Export of measured data to other software tools VDS 200N-SERIES Battery supply simulator and DC voltage source autowave Signal generator and recorder Automotive > Stand-alone, programmable DC source > 60 V/15 A up to 200 A (2,000 A inrush current) > Simulation + measuring + analysing > 16 bit resolution, 80 GByte hard disk memory > Simultaneous record & play function ISO 7637-2, ISO 16750, manufacturer specifications ISO 16750, vehicle manufacturer specifications Overview Application Products Battery Simulation VDS 200N-Series AutoWave Standards ISO 16750 Manufacturer Transients UCS 200N- Series LD 200N LD 200S-Series ISO 7637 Manufacturer Ford Specifications AMP 200N- Series RCB 200 RCB 200N1 CN 200N1 Power Fail PFS 200N- Series Transient Emission BS 200N80 BSM 200N40 AN 2050N- Series Manufacturer Manufacturer CISPR 25 ISO 7637 Manufacturer Conducted & Radiated immunity CWS 500N2 CWS 500N3 ISO 11452-X Manufacturer Electrostatic Discharge dito ESD 30N ISO 10605 Manufacturer Voltage range VDS 200N10 VDS 200N15 VDS 200N30 VDS 200N50 VDS 200N100 VDS 200N150 VDS 200N200 VDS 200N200.1 VDS 200N30.1 VDS 200N50.1 Frequency range Preprogrammed pulses Source impedance 0 V 60 V with 0.1 V steps I = 0 A 10 A cont., 15 A peak I = 0 A 15 A cont. I = 0 A 30 A cont., 70 A for 500 ms I = 0 A 50 A cont., 100 A for 500 ms I = 0 A 100 A cont., 150 A for 500 ms I = 0 A 150 A cont. I = 0 A 200 A cont. I = 0 A 200 A cont., 1,000 A for 500 ms Range I: -5 V ± 30 V I = 50 A cont., 150 A for 200 ms Range II: - 5 V ± 60 V I = 30 A cont., 90 A for 200 ms Range I: -5 V ± 30 V I = 85 A cont., 220 A for 200 ms Range II: - 5 V ± 60 V I = 50 A cont., 150 A for 200 ms DC up to 100 khz* * only for Ford EMC-CS-2009.1 2b, 4, sinewave, sinewave sweep, etc. Zq = < 10 mω Wave generator Output range Resolution Frequency range Sample rate Waveform segments Functions Wave recorder Input range 2 output channels standard 4 output channels optional ±10 V / 50 Ω 16 bit DC 50 khz up to 500 khz DC voltage, sine wave, sine wave sweep, Sine ramped, square wave, triangular wave, saw-tooth wave, ramp up/down, Exponential wave, damped oscillation, etc. Iteration of up to 9 parameters per level, up to 9 levels Pseudo-random distribution of parameters 2-channel measuring input ±5 V, 10 V, 20 V, 50 V, 100 V 9

transients transients The UCS 200N Ultra Compact Simulator for automotive transients unites the capabilities of an EFT/burst simulator, a micropulse simulator and the required coupling network in one box. The UCS 200N can be equipped to meet all international and car manufacturer specifications from around the globe. The coupling network can carry currents up to 200 A depending on the model. For non-standard tests the waveform parameters of the micropulse generator can be varied over a wide range. The built-in coupling network can be used and controlled by any unit of the LD 200N series and VDS 200N series. Load Dump pulses simulate the sudden disconnection (e.g. by corrosion) of the battery from the alternator while the alternator is generating current to load the battery. Such Load Dump pulses are high-energy pulses with a high destructive potential. The LD 200N simulates these high-energy pulses having a duration time in the range of hundreds of milliseconds. Load Dump pulses simulate the sudden disconnection (e.g. by corrosion) of the battery from the alternator while the alternator is generating current to load the battery. Such Load Dump pulses are high-energy pulses with a high destructive potential. The LD 200Sx simulates these high-energy pulses having a duration time in the range of hundreds of milliseconds. UCS 200N-Series Ultra Compact Simulator for automotive transients for pulses 1, 1a, 2a, 3a/3b and 6 LD 200N Automotive high-energy Load Dump generator for pulses 5 and 7 LD 200S-Series Automotive > Test pulses acc. to ISO, JASO, NISSAN, SAE > RC-Generator, test pulses 5a/5b as per ISO 7637-2 > Field decay and Load Dump as per Toyota > Spark gap test included > Freestyle pulse shape generation > Real source impedance, selectable ISO 7637-2, ISO 7637-3, SAE J1113, JASO D001, manufacturer specifications ISO 7637-2, SAE J1113, manufacturer specifications TSC 7001G Pulse 3a/3b as per ISO 7637-2 Open-circuit 25 V 1,000 V Rise time 5 ns Pulse duration 150 ns Ri 50 Ω 3a > negative, 3b > positive Micropulses as per ISO 7637-2 Open-circuit 20 V 600 V Pulses 1, 1a, 2a and 6 Ri 2, 4, 10, 20, 30, 50, 90 Ω Output coaxial connector 50 Ω Additional standard test routines SAE J1455 inductive & mutual NISSAN B2, C8, C50, C300 JASO A2, B2, D2 Freestyle Open-circuit 20 V 600 V Rise time tr 1 µs 10 µs Duration td 50 µs 10,000 µs Ri 2 450 Ω DUT supply 60 V Pulse 5a as per ISO 7637-2 Open-circuit Rise time Pulse duration Ri Pulse 5b as per ISO 7637-2 Clip voltage Manufacturer specifications Freestyle Rise time tr Pulse duration Internal resistor DUT supply 20 V 200 V 5 ms 10 ms 40 ms 400 ms selectable 0.5 38 Ω in 0.1 Ω steps Clipped Load Dump 15 V 99.5 V in 0.5 V steps SAE 1455, JASO, Chrysler, Ford Scania, Mercedes, Nissan, etc. < 1 μs 10 μs 90 μs with 10 μs steps 100 μs 900 μs with 100 μs steps 1 ms 10 ms with 1 ms steps 10 ms to 1,200 ms 0.5 38 Ω in 0.1 Ω steps 60 V Pulses as per Toyota TSC 7001G LD 200S18 Field decay LD 200S19 Load Dump Pulse 1 Load Dump Pulse 2 Load Dump Pulse 3 10 11

FORD EMC-CS-2009 Power Fail TRANSIENT EMISSION The AMP 200N series is a low-frequency signal source that generates sinusoidal signals used for simulating ripple noise and ground shift noise required by a variety of automotive standards industry e.g. Ford EMC-CS-2009.1, CI 210, CI 250 and RI 150. Additionally, the AMP 200N can be used to generate magnetic fields by means of a radiation loop or small Helmholtz coils as per RI 140 of Ford EMC-CS-2009.1. Controlled by the AutoWave a large number of different standard requirements can be covered. The RCB 200 series are transient pulse generators specifically designed as per Ford test requirements to simulate real-world fast transients, actually being generated by a specific type of relay switching selected components in a defined circuit. A variety of pulses is generated by using different arrangements of component layouts. A complete overview of EM TEST accessories for the various test applications is given on pages 68 74. The PFS 200N Power Fail Simulator generates fast voltage dips and drops (micro-interruptions) which enable mainly vehicle manufacturers to comply with standard requirements. Electronic switch technology in the PFS 200N ensures very fast rise and fall time (below 1 microsecond) requirements are met. The BS 200Nx is used to measure transient emissions to the wiring harness of parts and components installed in a vehicle. Additionally the required LISNs and the reference load CA BS200Nx are available. The LISNs and the switch can be operated independently as required for the measurements. AMP 200N-Series Low-frequency signal source for supply simulation and magnetic field testing RCB 200 / RCB 200N1 Transient generators for Ford test requirements PFS 200N-Series Power Fail Simulator BS 200Nx/BSM 200N40 Electronic switch for transient emission testing / Mechanical switch for transient emission testing Automotive > Built-in DDS to generate sinusoidal signals up to 250 khz > Ford CI-220, pulses A1, A2, B1, B2, C1, C2 > Voltage dropout, voltage dip, micro-interruption > 60 V / up to 100 A > Built-in LF amplifier, 250 W or 800 W > Ford CI-260, pulse F > 60 V/30 A up to 200 A > Electronic and mechanical switch > Output voltage max. 150 V p-p > Ford RI-130, pulses A2-1 and A2-2 (RCB 200N1) > Inverse-polarity protected Chrysler DC-10615, DC-11224, CS-11809, CS-11979, DaimlerChrysler DC-10614, DC-10615, DC-11224, Fiat 9.90110, Fiat 9.90111, Ford ES-XW7T-1A278-AC, Ford EMC CS-2009.1 GM 3097, ISO 11452-8, ISO 11452-10, IVECO 16-2119, Jaguar/ LandRover EMC-CS-2010JLR, Mitsubishi ES-X82114, ES-X82115, MBN 10284-2, NISSAN 28401 NDS02, PSA B21 7110, Renault 36.00.808/--G, --H, --J, --K, --L, SAE J1113-2, SAE J1113-22, TATA Motors TST/TS/WI/257, Volkswagen TL 825 66, Volvo STD 515-0003, Germanischer Lloyd GL VI 7-2, DO-160E/F/G, MIL-STD-461E/F Ford ES-XW7T-1A278-AC and Ford EMC-CS-2009.1 Chrysler PF 9326, Fiat 9.90110, Ford ES-XW7T-1A278-AB, Ford WDR 00.00 EA, JASO D001-94, Mitsubishi ES-X82010, Nissan 28401 NDS 02, PSA B21 7090, PSA B21 7110, Renault 36.00.808/--D, Renault 36.00.808/--E, Renault 36.00.808/--F, Toyota TSC3500G, Toyota TSC3590G, Toyota TSC7203G, BMW GS 95003-2, DaimlerChrysler DC-10615 Rev. A, Freightliner 49-00085, Hyundai ES 39110-00, Mack Trucks 606GS15, Volvo EMC requirements (1998), Volvo EMC requirements (2002), Renault 36.00.808/--G, DaimlerChrysler DC-10842, Toyota TSC6203G ISO 7637-2 (2011) Amplifier output characteristics Frequency range DC - 250 khz Signal power 250 W (nominal) or 800 W (nominal) Output voltage 50 V rms, max. 150 V p-p Output current Max. 5 A rms or max. 16 A rms Harmonic Distortion (THD) < 0.1 % Current protection Short circuit protected Overvoltage protection For voltages > 20 V fed back by the DUT Signal generator output characteristics Frequency range DC, 10 Hz 250 khz (sinusoidal) Output voltage +/-10 V DC offset 0-10 V, programmable, to control ext. DC amp. Measurement Frequency-selective voltage/current measurement (rms) Accessories Radiation Loop 120 mm radiation loop for magnetic field testing as per Ford EMC-CS-2009.1, RI 140 Loop Sensor To measure the magnetic field strength CN 200N1 Transformer assembly with built-in 0.5 Ω/250 W resistive load as per Ford EMC-CS-2009.1 CN 200N1 Audio transformer assembly for conducted immunity testing > Frequency range 30 Hz to 250 khz > 2 Audio transformers 2 x 200 Watt > Built-in low inductive load resistor 0.5 Ω, 250 W Ford EMC-CS-2009.1, SAE J1113-2, Germanischer Lloyd GL VI 7-2 PFS 200N30 Nominal current Inrush current PFS 200N50 Nominal current Inrush current PFS 200N100 Nominal current Inrush current PFS 200N150 Nominal current PFS 200N200 Nominal current Switching time (on/off) < 1 µs Max. battery supply voltage 60 V I = 0 A 30 A cont. Max. I = 70 A for 500 ms Max. battery supply voltage 60 V I = 0 A 50 A cont. Max. I = 100 A for 500 ms Max. battery supply voltage 60 V I = 0 A 100 A cont. Max. I = 150 A for 500 ms Max. battery supply voltage 60 V I = 0 A 150 A cont. Max. battery supply voltage 60 V I = 0 A 200 A cont. BS 200Nx Electronic switch Voltage Max. 60 V DC Current Max. 100 A Voltage drop < 1 V at 100 A Peak voltage Max. 1.000 V Peak current Max. 400 A for 200 ms Switching time 300 ns +/- 20 % into test load On/Off time Min. 10 ms to 500 ms AN 20100N Artificial Network Frequency range 0.1 to 150 MHz Operation voltage 1.000V DC / 250 V AC (up to 1 khz) Operation current 100 A continuous Impedance 50 Ω // 5uH +/-10 % Insertion loss < 3 db BSM 200N40 Mechanical switch Operation voltage Max. 16 V DC Operation current 40 A DC 12 13

Conducted and radiated immunity ELECTROSTATIC DISCHaRGE Bulk Current Injection (BCI) is a test procedure to test immunity to electrical disturbances caused by narrowband electromagnetic energy. The test signal is injected by means of a current injection probe. In physical terms the current injection probe is a current transformer laid around the wiring harness. Immunity tests are performed varying the level and the frequency of the injected test signal. The BCI test method is widely known in the automotive industry as well as in the military/aircraft industry to test single components of a complex system. The CWS 500N3 is a state-of-the-art solution in a compact one-box design to test immunity to conducted audio frequency disturbances and low-frequency magnetic fields. The CWS 500N3 includes signal generator, LF amplifier, coupling transformer, frequency selective current and voltage monitor, software and GPIB interface. The icd.control-software supports test routines, controls external measuring devices and automatically generates test reports with all test data included. Electrostatic discharges between objects can cause persistent disturbances or even destruction of sensitive electronics or controls. Dito is the most advanced ESD tester for accurate simulation of ESD pulses according to the latest standards. Its efficient battery power concept allows users to generate up to 50,000 pulses at maximum test voltage from a single battery. Standard and pre-programmed user test routines make ESD testing an easy and comfortable procedure. The ESD 30N is the state-of-the art ESD tester for all test requirements demanding more than 15 kv. Powered by the mains it also offers a built-in battery for testing without mains. Benefits like bleed-off function, sensor for temperature and rel. humidity and automatic polarity change-over are only a few to make the ESD 30N an outstanding tester. cws 500N2 Bulk Current Injection (BCI) testing CWS 500N3 Audio frequency and magnetic field testing dito The ultimate ESD tester ESD 30N ESD tester up to 30 kv Automotive > Compact simulator as per ISO 11452-4; EN 61000-4-6 > Conducted & radiated immunity up to 250 khz > Ergonomic design > Up to 30 kv contact & air discharge > 9 khz to 400 MHz, 100 W (expandable up to 1 GHz) > Built-in voltage/current measurement > Modular concept > Interchangeable discharge networks > System solution is fully designed and supported by EM TEST > Built-in coupling transformer 1 : 2 > Easy to handle > For automotive, industrial and military applications ISO 11452-4, ISO 11452-5, vehicle manufacturer specifications ISO 11452-8, ISO 11452-10, vehicle manufacturer specifications, SAE J1113, MIL-STD 461 Bellcore GR-1089-Core, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, IEC 61000-4-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, ISO 10605, JASO D001-94, Chrysler PF 9326, DaimlerChrysler PF-10540, Fiat 9.90110, Ford WDR 00.00EA, Renault 36.00.400/B, Renault 36.00.400/C, Toyota TSC3500G, Toyota TSC3590G, Volvo EMC requirements (1998), EN 300329 IEC 61000-4-2, ISO 10605, SAE J1113-13, SAE J1455, BMW 600 13.0 (Part 2), BMW GS 5002 (1999), DaimlerChrysler DC-10613, DaimlerChrysler DC-10614, Mercedes AV EMV, Ford ES-XW7T-1A278-AB, GMW 3097, GMW 3097 (2001), GMW 3100, GMW 3100 (2001), Mazda MES PW 67600, Mitsubishi ES-X82010, Nissan 28401 NDS 02, Porsche, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-E, Renault 36.00.808/-F, Smart DE1005B, VW TL 824 66, MBN 10284-2:2002, Renault 36.00.808/-G BCI method ISO 11452-4 Output power 100 W (nominal) Output impedance 50 Ω Max. VSWR 1 : 2.0 Output level -13 dbm 50 dbm Frequency range 9 khz 400 MHz (1,000 MHz) Modulation AM 1 3,000 Hz, 1 99 % depth PM 1 3,000 Hz Duty cycle 10% 80 % Harmonic distortion > 20 dbc Output N-connector Built-in power meter Channel 1 forward power Channel 2 reverse power Channel 3 injected current Built-in coupler Max 200 W/1 GHz Built-in RF switch Automatic commutation to an external amplifier Conducted immunity ISO 11452-10, MIL STD 461 Output level 0.001 V max. 6.5 Vrms Output current Max. 15 A Frequency range 10 Hz to 250 khz Output power nominal 100 W Output power peak 400 W Output impedance < 0.5 Ω Harmonic distortion < 20 dbc at max. power Coupling Audio transformer included Measurements Freq. selective voltage/current meter Verification load 0.5 Ω & 4 Ω included Radiated immunity ISO 11452-8, MIL STD 461 Magnetic field Max. 1,000 A/m up to 1 khz Radiation loop As per MIL STD 461 Magnetic Loop sensor As per MIL STD 461 Current sensor Included ESD as per IEC 61000-4-2 Test voltage 0.5 16.5 kv Discharge Air/contact discharge Hold-on time > 5 s R/C parameter 150 pf/330 Ω Specification contact discharge 500 V to 10 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV ESD as per ISO 10605 Test voltage 0.5 16.5 kv Discharge Air/contact discharge R/C parameters 100 pf/1,500 Ω 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω ESD as per IEC 61000-4-2 Ed.2 and ISO 10605 Test voltage Max. 30 kv Discharge Air/contact discharge Hold-on time > 5 s Specification contact discharge 0.2 30 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV R/C parameters 150pF/330 Ω 330pF/330 Ω 150pF/2,000 Ω 330pF/2,000 Ω 100pF/1,500 Ω customized Special technical highlights - RC network values indicated on the LCD - AD or CD discharge mode indicated on the LCD - Bleed-off function to discharge the EUT - Temperature and humidity sensor included - USB or optical interface included - esd.control software - AC or DC power supply (battery mode included) - Power supply: AC (88 250 V), DC (11 16 V) - Battery Mode included for several hours 14 15

Renewable Energy Transients The UCS 500N5/UCS 500N7 Ultra Compact Simulators are the most versatile testers for covering transient and power-fail requirements according to international (basic and generic) and product family standards with voltage capability of up to 7 kv. In addition to the IEC 61000-4-5 standard for surge testing they also comply to ANSI/IEEE C62.41 requirements for surge and ring wave testing. The UCS 500N7 is the most economical test solution for fully compliant immunity tests and CE marking. A built-in CDN is used for testing single-phase EUTs up to 400 V/16 A, while tests on three-phase EUTs can be performed by adding an automatically controlled external coupling network up to 690 V with max. 100 A. EM TEST supplies a large range of accessories for various applications. UCS 500N5.2 Compact tester for EFT/burst, surge and power fail UCS 500N7.2 Compact tester for EFT/burst, surge, ring wave and power fail Renewable E. > Small and compact all-in-one tester > IEC 61000-4-4/-5/-8/-9/-11/-29 > Built-in single-phase CDN > Testing beyond the limits, 5.5 kv EFT & 7 kv surge > Optional RWG module as per 61000-4-12 IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, EN 55024, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, ITU-T K.20, ITU-T K.41, ITU-T K.45, EN 300329 IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-12, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, Bellcore GR-1089-Core, ANSI/IEEE C62.41, EN 61543, IEC 61008-1, IEC 61009-1, IEEE 1547, UL 1741 Overview Application Transients Damped oscillatory and Ringwave Products UCS 500Nx CNI 501/503- Series Standards IEC 61000-4-4 IEC 61000-4-5 OCS 500N- Series DOW Module IEC 61000-4-12 IEC 61000-4-18 Conducted and radiated immunity CWS 500N1- Series CWS 500N2 Voltage Surge and safety VSS 500N10.3 Power Quality PFS 503N- Series UCS 500Nx Harmonics & Flicker DPA 500N DPA 503N AIF 503N- Series ACS 503N- Series IEC 61000-4-6 IEC 61730-2 IEC 610004-11 IEC 61000-3-2 IEC 61000-3-3 IEC 61000-3-11 IEC 61000-3-12 AC/DC Supply Anomaly Simulation NetWave-Series Single Phase NetWave-Series Three Phase IEC 61000-4-13 IEC 61000-4-14 IEC 61000-4-17 IEC 61000-4-27 IEC 61000-4-28 Electrostatic Discharge dito ESD 30N IEC 61000-4-2 EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 160 V 5,000 V 8/20 µs 80 A 2,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 400 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 160 V 5,000 V 4/300 µs 4 A 125 A Technical Data EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 250 V 7,000 V 8/20 µs 125 A 3,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 400 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Ring wave as per IEC 61000-4-12 0.5 µs/100 khz 6,000 V with 12 Ω and 30 Ω source impedance Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 250 V 7,000 V 4/300 µs 6 A 175 A 17

The single and three-phase coupling/decoupling networks of the CNI 501/503 x series, are used for coupling EFT/Burst and Surge pulses on DC-lines or three-phase (4-wire or 5-wire supply lines) mains supply systems for voltages up to 1,000 VDC/ 3 x 690 VAC. A particularly interesting series due to the increasing demand for testing inverters used in the area of renewable energies (e.g. photovoltaic systems, wind power stations, electric cars). Damped Oscillatory and ringwave The OCS 500N6 is used for ring wave testing up to 6 kv, slow damped oscillatory wave testing (100 khz and 1 MHz) up to 3 kv, and optional fast damped oscillatory wave at 3, 10, and 30 MHz. A ring wave is a non-repetitive damped oscillatory transient occurring in low-voltage power, control and signal lines supplied by public and non-public networks. Damped oscillatory waves are repetitive transients occurring mainly in power, control and signal cables installed in high-voltage and medium-voltage stations. The OCS 500N6 can also be used to perform magnetic field tests as required in IEC 61000-4-10 using a magnetic field coil such as the MS 100. CNI 50x-SERIES Combined coupling/decoupling networks for burst and surge OCS 500N-Series Compact tester for ring wave and damped oscillatory waves DOW Module Fast damped oscillatory wave option for OCS 500N6-Series Renewable E. also available as 1 or 3-Phase Version up to 32 A > Surge as per ANSI/IEEE C62.41 in combination with UCS 500N7 > 100 khz ring wave & 100 khz/1 MHz damped oscillatory > Fast Damped Oscillatory Wave 3/10/30 MHz > Automatic selection of Surge impedance > Conducted immunity and magnetic field test > Fully remote controlled by EM TEST generators > Built-in coupling network ANSI/IEEE C62.41, EN 61000-6-1, EN 61000-6-2, EN 61543, IEC 60601-1-2, IEC 61000-4-12, IEC 61000-4-4, IEC 61000-4-5, IEC 61008-1, IEC 61009-1, IEC 61326, IEC 61850-3, ITU-T K.20, ITU-T K.21, ITU-T K.45 ANSI/IEEE C37.90, ANSI/IEEE C62.41, IEC 60255-1, IEC 61000-4-10, IEC 61000-4-12, IEC 61000-4-18, IEEE 1547 IEC 61000-4-18 TECHNICAL DATA (OVERVIEW) CNI for UCS 500N5 (5,5 kv) CNI 503A.1 CNI 503A.2 CNI 503A2.1 CNI 503A3.1 CNI 503A3.2 CNI 503A4.2 CNI 503A4.4 CNI for UCS 500N7 (7 kv) CNI 503B S1 CNI 503B S2 CNI 503B S3 CNI 503B S4 CNI 503B 7.4 CNI 503B 9.3 Other models and configurations on request 3 x 690 V (AC), 16 A 3 x 690 V (AC), 1000V (DC), 16 A 3 x 690 V (AC), 32 A 3 x 690 V (AC), 1000V (DC), 63 A 3 x 690 V (AC), 63 A 3 x 690 V (AC), 100 A 3 x 690 V (AC), 1000V (DC), 100 A 3 x 690 V (AC), 16 A 3 x 690 V (AC), 32 A 3 x 690 V (AC), 63 A 3 x 690 V (AC), 100 A 3 x 690 V (AC), 1000 V (DC), 32 A 3 x 690 V (AC), 1000V (DC), 100 A CNI for UCS 500N7 (+ / - / PE) CNI 501B S2 CNI 501B S3 CNI 501B S4 Other models and configurations on request 7 kv, 1,000 V (DC), 16 A 7 kv, 1,000 V (DC), 32 A 7 kv, 1,000 V (DC), 63 A Damped oscillatory as per IEC 61000-4-18 Output voltage open-circuit 250 V 3,000 V +/- 10 % Rise time/oscillation frequency 1/T 75 ns/100 khz and 1 MHz Decaying Peak 5 must be > 50 % of peak 1 value Peak 10 must be < 50 % of peak 1 value Source impedance 200 Ω Repetition rate 40/s for 100 khz and 400/s for 1 MHz Direct output at the front panel For ext CDN & magn. field antenna Coupling network 1-phase or 3-phase Damped oscillatory magnetic field as per IEC 61000-4-10 MS 100 (square 1 m 1 m) antenna Ring wave as per IEC 61000-4-12 Output voltage open-circuit 250 V 6,000 V Rise time first peak T1/Oscillation frequency 0.5 µs/100 khz Decaying of Pk1 to Pk2 40 % 110 % Decaying of Pk2 to Pk3 & decaying of Pk3 to Pk4 40 % 80 % Output impedance 12 Ω, 30 Ω (200 Ω external) Wave shape short-circuit Rise time first peak tr T1 < 1 µs Oscillation frequency 1/T 100 khz Fast Damped oscillatory IEC 61000-4-18 Output voltage open-circuit 450 V 4,400 V +/- 10 % Rise time voltage waveform 5 ns +/- 30 % Oscillation frequency 3 MHz, 10 MHz, 30 MHz, +/- 10 % Decaying voltage waveform Peak 5 must be > 50 % of peak 1 Source impedance 50 Ω +/- 20 % Peak 10 must be < 50 % of peak 1 Repetition rate Max. 5000/s +/- 10 % Burst duration 50ms +/- 20 %, at 3 MHz 15ms +/- 20 %, at 10 MHz 5ms +/- 20 %, at 30 MHz Burst period 300 ms +/- 20 % Short circuit current 9A 88A +/- 20 % Rise time current waveform At 3 MHz: <330 ns At 10 MHz: <100 ns At 30 MHz: <33 ns Decaying current waveform Peak 5 must be >25 % of peak 1 Peak 10 must be <25 % of peak 1 18 19

Conducted and radiated immunity voltage surge and Safety Power Quality The CWS 500N1 is the most compact single-box test equipment for conducted RF immunity testing as per IEC 61000-4-6 and related standards. As well as 1 khz 80 % AM the CWS 500N1 also generates 2 Hz 80 % AM for testing medical appliances and 1 Hz PM with 50 % duty cycle required for testing safety equipment such as fire alarms. EM TEST supplies a large range of CDNs, EM clamps, current injection clamps and calibration accessories. Bulk Current Injection (BCI) is a test procedure for testing the immunity to electrical disturbances from narrowband electromagnetic energy. The test signal is injected by means of a current injection probe. In physical terms the current injection probe is a current transformer laid around the wiring harness. Immunity tests are performed varying the level and the frequency of the injected test signal. The BCI test method is widely known in the automotive industry as well as in the military/ aircraft industry for testing single components of a complex system. The voltage surge simulators VSS 500N generate high-voltage transients as required by several IEC standards. The voltage surge pulses are used to test the isolation (voltage withstand) capability of components, sockets, connectors, cables and many other items. As per safety test requirements the insulation between accessible parts or parts connected to them and hazardous live parts must be able to withstand surges due to transients caused, e.g. by thunderstorms and entering the apparatus through the antenna terminal. Electronic and electrical equipment may be affected by voltage dips, short interruptions and voltage variations of the power supply. Dips and interruptions are caused by faults in the network or installations or by sudden large changes of load. Testing for such a phenomena is required in order to ensure that electronic and electrical equipment does not fall into unsafe operation conditions. CWS 500N1-Series The single-box solution for RF-conducted immunity testing cws 500N2 The single-box solution for RF-conducted immunity testing VSS 500N10.3 Surge tester 10 kv for solar panel testing PFS 503N-Series Simulator for dips, short interruptions and voltage variations Renewable E. Solution for NAMUR NE 21 > RF-conducted immunity testing as per IEC 61000-4-6 > Compact simulator as per ISO 11452-4; EN 61000-4-6 > 7 load ranges from 10nF to 180nF > True 3-phase voltage dip generator as per IEC 61000-4-11 / -34 > Up to 300 MHz test frequency > 9 khz to 400 MHz, 100 W (expandable up to 1 GHz) > Dip mode, line(s) to neutral or line to line > Self-calibration procedures for CDNs and coupling clamps > System solution is fully designed and supported by EM TEST > External variac for STAR and DELTA power mains systems IEC 61000-4-6, IEC 60601-1-2:2002, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, EN 50130-4, EN 61000-6-1, EN 61000-6-2, EN 300329, NAMUR NE21 IEC 61000-4-6, EN 61000-6-1, EN 61000-6-2, IEC 60601-1-2:2002, ISO 11452-4, ISO 11452-5, DaimlerChrysler DC-10614, Ford ES-XW7T-1A278-AB, Ford ESXW7T- 1A278-AC, GMW 3097 (2001), GMW 3097 (2004), MBN 10284-2:2002, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-G, MIL STD 461D/CS 114, MIL STD 461E/CS 114, RTCA/DO 160 Section 20, Fiat 9.90110 IEC 61730-1, IEC 61730-2, IEC 60060, UL 1703 IEC 61000-4-11, IEC 61000-4-29, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, IEC 61000-4-34 Output power 80 W Output impedance 50 Ω max. VSWR 1 : 1.2 at all phase angles and at max. power (without destruction) Frequency range 9 khz 1 GHz (internal signal generator) Frequency range with built-in 100 khz 300MHz amplifier Modulation AM 1 3,000 Hz, 0 95 % depth PM 1 3,000 Hz Duty cycle 10 % 80 % Harmonic distortion > 20 dbc Preprogrammed modulations Amplitude modulation 80 % ±5 %, 1 khz ±10 % 80 % ±5 %, 2 Hz, 1 khz Pulse modulation 1 Hz, 50 % duty cycle acc. to EN 50130-4 Other models: CWS 500N1.1 Output power, frequency range 25 W, 100 khz 250 MHz CWS 500N1.2 Output power, frequency range 50 W, 10 khz 230 MHz Output power 100 W (nominal) Output impedance 50 Ω Max. VSWR 1 : 2.0 Output level -13 dbm 50 dbm Frequency range 9 khz 400 MHz (1,000 MHz) Modulation AM 1 3,000 Hz, 1 99 % depth PM 1 3,000 Hz Duty cycle 10 % 80 % Harmonic distortion > 20 dbc Output N-connector Built-in power meter Channel 1 forward power Channel 2 reverse power Channel 3 injected current Built-in coupler Max. 200 W/1 GHz Built-in RF switch Automatic commutation to an external amplifier Surge as per IEC 60255-5 500 V 10,000 V Wave shape Front time tr 1.2 µs Time to half value 50 µs Load capacitance ranges 30 nf 40 nf 40 nf 50 nf 50 nf 65 nf 65 nf 85 nf 85 nf 110 nf 110 nf 140 nf 140 nf 180 nf /alternating Output direct HV-banana connector AC voltage L-L Max. 3 440 V AC current Max. 3 32/63/100 A Frequency 50/60 Hz DC voltage Max. 250 V DC current Max. 32, 63, 100 A Inrush current > 500 A (PFS 503N32) > 1.000 A (PFS 503N63 / PFS 503N100) Short-circuit protected Dip mode Line to line Line to neutral Lines to neutral Other Models: PFS 503N32.1 3 x 690 V, 32 A PFS 503 N63.1 3 x 690 V, 63 A PFS 503N100.1 3 x 690 V, 100 A 20 21

Harmonics & Flicker Harmonics and interharmonics are caused by modern electronic power conditioning modules used to control loads and reduce power consumption. Such most commonly non-linear modules are the source of voltage at unwanted frequencies superimposed on the supply voltage. Voltage fluctuations caused by varying load currents may influence luminance or spectral distribution of lighting systems. The impression of unsteadiness of visual sensation induced by this light stimulus is called flicker. Flicker also needs to be limited to a minimum. The DPA 500N is used for single-phase applications and the DPA 503N supports both single and 3-phase applications. ACS 500N is a single-phase and the ACS 503N a 3-phase AC source, specially designed for harmonics and flicker testing. It meets the corresponding specifications as per IEC/EN 61000-3-2 and IEC/EN 61000-3-3. It provides the perfect sinusoidal and stable voltage signal specified to give fully compliant harmonics and flicker analyses irrespective of the mains supply frequency and steadiness of the voltage. The AIF 503N-Series three-phase flicker impedances offer two different impedance values. Z ref is used as the flicker impedance as per EN/IEC 61000-3-3 and specified by IEC 60725. Z test is used for equipment intended for connection to a public low-voltage distribution system having a service current supply capability of more than 100 A specified in EN/IEC 61000-3-11. The ACS 503N-Series are three-phase AC sources, specifically designed for harmonics and flicker testing. It meets the corresponding specifications as per EN/IEC 61000-3-2, EN/IEC 61000-3-3 and JIS C 61000-3-2 as well as per EN/IEC 61000-3-11 and EN/IEC 61000-3-12 for measuring DUTs having a nominal current up to 75 A per phase. The ACS 503N-Series provides the perfect sinusoidal and stable voltage signal specified to perform fully compliant harmonics and flicker analysis despite of the mains supply frequency and steadyness of the voltage. DPA 500N Single-phase power analyser, H&F analyser DPA 503N 3-phase power analyser, H&F analyser AIF 503N-Series 3-phase flicker impedance up to 75 A ACS 503N-Series Three-phase AC voltage sources Renewable E. > Single-phase harmonics/flicker analyser > Three-phase harmonics/flicker analyser > Flicker impedance as per IEC 60725 > AC power sources for three-phase up to 90 kva > Built-in single-phase flicker impedance > External three-phase flicker impedance AIF 503 > For flicker analysis as per IEC 61000-3-3 > Large inrush current capability > Real-time analysis using internal computer and DSP > Real-time analysis using internal computer and DSP > Built-in Zref and Ztest > Controlled by DPA 503N and dpa.control software IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, IEC 61000-4-7, IEC 61000-4-15, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 300386-2, EN 61000-3-2, EN 61000-3-3, EN 61000-3-11, EN 61000-3-12, EN 61000-4-7, EN 61000-4-15, JIS C 61000-3-2 IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, IEC 61000-4-7, IEC 61000-4-15, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 300386-2, EN 61000-3-2, EN 61000-3-3, EN 61000-4-7, EN 61000-4-15, EN 61000-3-11, EN 61000-3-12 JIS C 61000-3-2 IEC 61000-3-3, IEC 61000-3-11, EN 61000-3-3, EN 61000-3-11, IEC 60725 IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, EN 61000-3-2, EN 61000-3-3, EN 61000-3-11, EN 61000-3-12, JIS C 61000-3-2 Input channels 2 (1 current & voltage) EUT connection 1-phase A/D converter 16 bit Class of instrument Class A as per IEC/EN 61000-4-7, ed. 2 Voltage input 10 530 Vrms Overload 4,000 V peak Input range internal 50 A peak 16 A continuous Input range external Standard delivered model max. 140 A (factory setting 2 turns 70 A) Harmonic analysis IEC/EN 61000-3-2 and IEC/EN 61000-3-12, according to IEC/EN 61000-4-7, JIS C 61000-3-2 Harmonic range 1 50 th harmonic Grouping Interharmonics acc. to IEC/EN 61000-4-7, ed. 2 Display Urms, Irms, Ipeak, Upeak, P, Q, S, power factor, THD (U), THD (I), crest factor (U), crest factor (I) Flicker analysis IEC/EN 61000-3-3 and IEC/EN 61000-3-11, according to IEC/EN 61000-4-15 Flicker data P st and P lt, Vrms, dmax, dc, dt, P 50 % S, P 10 % S, P 3 % S, P 1 % S, P 0.1 % Flicker impedance: Phase Neutral 0.24 Ω + j 0.15 Ω 0.16 Ω + j 0.10 Ω Input channels 6 (3 current & voltage) EUT connection 3-phase A/D converter 16 bit Class of instrument Class A as per IEC/EN 61000-4-7 ed.2 Voltage input 10 530 Vrms Overload 4,000 V peak Current input Depends on CT model used Input range Standard delivered model max. 140 A (factory setting 2 turns 70 A) Harmonic analysis IEC/EN 61000-3-2 and IEC/EN 61000-3-12, according to IEC/EN 61000-4-7, JIS C 61000-3-2 Harmonic range 1 50 th harmonic Grouping Interharmonics acc. to IEC/EN 61000-4-7, ed. 2 Display Urms, Irms, Upeak, Ipeak, P, Q, S, power factor, THD (U), THD (I), crest factor (U), crest factor (I) Flicker analysis IEC/EN 61000-3-3 and IEC/EN 61000-3-11, according to IEC/EN 61000-4-15 Flicker data P st and P lt, Vrms, dmax, dc, dt, P50%S, P 10 % S, P 3 % S, P 1 % S, P 0.1 % Phase 3-phase Z ref R A = 0.24 Ω X A = 0.15 Ω R N = 0.16 Ω X N = 0.10 Ω Z test R A = 0.15 Ω X A = 0.15 Ω R N = 0.10 Ω X N = 0.10 Ω Accuracy Z ref, Z test < 3 % EUT power supply Line voltage 3 400 V Line frequency 47 63 Hz Other models AIF 503N32 Line current: max. 32 A per line AIF 503N63 Line current: max. 63 A per line AIF 503N75 Line current: max. 75 A per line Voltage range 0 to 300 V Voltage resolution 0.025 % Output frequency 40 Hz to 80 Hz Output connector 3-phase CEE-connector Frequency resolution 0.02 Hz Frequency accuracy, stability 100 ppm Total harmonics distortion THD Less than 0.1 % Output voltage stability Better than 0.1 % Output voltage accuracy Better than 0.5 % Other models: ACS 503N16 3 x 300 V (p-n), 16,000 VA ACS 503N30 3 x 300 V (p-n), 30,000 VA ACS 503N60 3 x 300 V (p-n), 60,000 VA ACS 503N90 3 x 300 V (p-n), 90,000 VA 22 23

SIMULATION OF AC AND DC SUPPLY ANOMALIES ELECTROSTATIC DISCHaRGE NetWave is an AC/DC power source, specifically designed to meet the requirements as per IEC/EN 61000-4-13, IEC/EN 61000-4-14, IEC/EN 61000-4-17, IEC/EN 61000-4-28. Its output power with low distortion and high stability, even if supplying dynamic loads, guarantees full compliant measure- ments for harmonics and flicker as per IEC/EN 61000-3-2, JIS C 61000-3-2 and IEC/EN 61000-3-3 as well as per IEC/EN 61000-3-11 and IEC/EN 61000-3-12. The three-phase Netwave models additionally support testing as per IEC/EN 61000-4-27. Electrostatic discharges between objects can cause persistent disturbances or even destruction of sensitive electronics or controls. Dito is the most advanced ESD tester for accurate simulation of ESD pulses according to the latest standards. It's efficient battery power concept allows users to generate up to 50,000 pulses at maximum test voltage from a single battery. While standard and pre-programmed user test routines make ESD testing an easy and comfortable procedure. The ESD 30N is the state-of-the art ESD tester for all test requirements demanding more than 15 kv. Powered by the mains it also offers a built-in battery for testing without mains. Benefits like bleed-off function, sensor for temperature and rel. humidity and automatic polarity change-over are only a few to make the ESD 30N an outstanding tester. NETWAVE-Series SINGLE Phase Multifunction AC/DC Power Source NETWAVE-Series Three Phase Multifunction AC/DC Power Source dito The ultimate ESD tester ESD 30N ESD tester up to 30 kv Renewable E. > Wide power bandwidth; DC 5 khz > Wide power bandwidth; DC 5 khz > Ergonomic design > Up to 30 kv contact & air discharge > High inrush current capability > High inrush current capability > Modular concept > Interchangeable discharge networks > Built-in arbitrary waveform generator, 16 Bit > Built-in arbitrary waveform generator, 16 Bit > Easy to handle > For automotive, industrial and military applications IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing Bellcore GR-1089-Core, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, IEC 61000-4-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, ISO 10605, JASO D001-94, Chrysler PF 9326, DaimlerChrysler PF-10540, Fiat 9.90110, Ford WDR 00.00EA, Renault 36.00.400/B, Renault 36.00.400/C, Toyota TSC3500G, Toyota TSC3590G, Volvo EMC requirements (1998), EN 300329 IEC 61000-4-2, ISO 10605, SAE J1113-13, SAE J1455, BMW 600 13.0 (Part 2), BMW GS 5002 (1999), DaimlerChrysler DC-10613, DaimlerChrysler DC-10614, Mercedes AV EMV, Ford ES-XW7T-1A278-AC, GMW 3097, GMW 3097 (2001), GMW 3100, GMW 3100 (2001), Mazda MES PW 67600, Mitsubishi ES-X82010, Nissan 28401 NDS 02, Porsche, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-E, Renault 36.00.808/-F, Smart DE1005B, VW TL 824 66, MBN 10284-2:2002, Renault 36.00.808/-G Technical Data - SINGLE Phase Technical Data - Three Phase Output voltage Netwave 3, Netwave 7 0 V 300 VAC (p-n); 0 V ± 425 VDC Netwave 7.2 0 V 360 VAC (p-n); 0 V ± 500 VDC Output power Netwave 3 AC mode: 3,500 VA, DC mode: 4,500 W Netwave 7, Netwave 7.2 AC mode: 7,500 VA, DC mode: 9,000 W Output current Netwave 3 12 A (RMS) continuous 21 A (RMS) short-term (max. 3 s) 100 A repetitive peak Netwave 7, Netwave 7.2 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak Output frequency DC 5,000 Hz Frequency accuracy, stability 100 ppm Output voltage stability Better than 0.1 % Output voltage accuracy Better than 0.5 % Total harmonic distortion (THD) Less than 0.5 % DC offset in AC mode < 20 mv with linear load Slew rate 8 V / µs Output voltage Netwave 20, Netwave 30, Netwave 60 Netwave 20.1, Netwave 30.1, Netwave 60.1 Output power Netwave 20.x Netwave 30.x Netwave 60.x Output current Netwave 20.x Netwave 30.x Netwave 60.x 0 V 3*300 VAC (p-n); 0 V ± 425 VDC 0 V 3*360 VAC (p-n); 0 V ± 500 VDC 22,500 VA AC, 27,000 W DC 30,000 VA AC, 36,000 W DC 60,000 VA AC, 72,000 W DC 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak 33 A (RMS) continuous 66 A (RMS) short-term (max. 3 s) 250 A repetitive peak 66 A (RMS) continuous 100 A (RMS) short-term (max. 3 s) 400 A repetitive peak ESD as per IEC 61000-4-2 Test voltage 0.5 16.5 kv Discharge Air/contact discharge Hold-on time > 5 s R/C parameter 150 pf/330 Ω Specification contact discharge 500 V to 10 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV ESD as per ISO 10605 Test voltage 0.5 16.5 kv Discharge Air/contact discharge R/C parameters 100 pf/1,500 Ω 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω ESD as per IEC 61000-4-2 and ISO 10605 Test voltage Max. 30 kv Discharge Air/contact discharge Hold-on time > 5 s Specification contact discharge 0.2 30 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV R/C parameters 150pF/330 Ω 330pF/330 Ω 150pF/2,000 Ω 330pF/2,000 Ω 100pF/1,500 Ω customized Special technical highlights - RC network values indicated on the LCD - AD or CD discharge mode indicated on the LCD - Bleed-off function to discharge the EUT - Temperature and humidity sensor included - USB or optical interface included - esd.control software - Power supply: AC (88 250 V), DC (11 16 V) - Battery mode included for several hours 24 25

telecom TRANSIENTS, RADIATED IMMUNITY AND POWER MAINS SIMULATION The UCS 500N5/UCS 500N7 Ultra Compact Simulators are the most versatile testers for covering transient and power-fail requirements according to international (basic and generic) and product family standards with voltage capability of up to 7 kv. In addition to the IEC 61000-4-5 standard for surge testing, they also complies to ANSI/IEEE C62.41 requirements for surge and ring wave testing. The UCS 500N7 is the most economical test solution for fully compliant immunity tests and CE marking. A built-in CDN is used for testing single-phase EUTs up to 400 V/16 A, while tests on three-phase EUTs can be performed by adding an automatically controlled external coupling network up to 690 V with max. 100 A. EM TEST supplies a large range of accessories for various applications. UCS 500N5 Compact tester for EFT/burst, surge and power fail UCS 500N7 Compact tester for EFT/burst, surge, ring wave and power fail Telecom > Small and compact all-in-one tester > Testing beyond the limits, 5.5 kv EFT & 7 kv surge > IEC 61000-4-4/-5/-8/-9/-11/-29 > Optional RWG module as per 61000-4-12 > Built-in single-phase CDN IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, EN 55024, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, ITU-T K.20, ITU-T K.41, ITU-T K.45, EN 300329 IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-12, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, Bellcore GR-1089-Core, ANSI/IEEE C62.41, EN 61543, IEC 61008-1, IEC 61009-1, IEEE 1547, UL 1741 Overview Technical Data Application Products Standards Power Mains Simulation UCS 500Nx PFS 503N-Series VDS 200N-Series ITU K ETSI Transients UCS 500Nx VCS 500Nx TSS 500Nx EFT 500N-Series UCS 200N VSS 500N10 ITU K ETSI BELLCORE FCC part 68 Conducted Immunity CWS 500N1-Series CWS 500N2 ITU K ETSI Radiated Immunity UCS 500Nx ITU K ETSI Harmonics & Flicker DPA 500N ACS 500N NetWave-Series Single Phase NetWave-Series Three Phase ITU K ETSI Electrostatic Discharge dito ESD 30N ITU K ETSI BELLCORE EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 160 V 5,000 V 8/20 µs 80 A 2,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 300 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 160 V 5,000 V 4/300 µs 4 A 125 A EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 250 V 7,000 V 8/20 µs 125 A 3,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 300 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Ring wave as per IEC 61000-4-12 0.5 µs/100 khz 6,000 V with 12 Ω and 30 Ω source impedance Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 250 V 7,000 V 4/300 µs 6 A 175 A 27

transients Surge pulses occur due to direct or indirect lightning strikes to an external (outdoor) circuit. This leads to currents or electromagnetic fields causing high-voltage or current transients. Another source of surge pulses is switching transients originating from switching disturbances and system faults. Due to the characteristic of the phenomenon almost every electrical and electronic device is affected by such lightning events. Surge tests should therefore be widely performed. Surge voltages can reach several thousands of volts while surge currents reach levels of several thousands of amps. UCS 500N5V Surge tester 5.0 kv VCS 500N8 Surge tester 8 kv VCS 500N10 Surge tester up to 10 kv VCS 500N7T Surge & telecom tester 7 kv Also available as VCS 500N12 with 12 kv also available as VCS 500N10T with 10 kv Telecom > 5.0 kv/2.5 ka surge, IEC 61000-4-5/-9 > Testing beyond the limits, 8 kv/4 ka, IEC 61000-4-5/-9 > Still compact in size but up to 10 kv/5 ka, IEC 61000-4-5/-9 > IEC 61000-4-5, ITU > Preprogrammed standard test routines included > 7.0 kv/3.5 ka surge & 7.0 kv telecom surge 10 µs/700 µs > Built-in single-phase CDN > Built-in single or 3-phase CDN > External CDNs for power mains and I/O line applications > Built-in single-phase CDN IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.41, ITU-T K.45 IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 Surge as per IEC 61000-4-5 Surge as per IEC 61000-4-5 Surge as per IEC 61000-4-5 Surge as per IEC 61000-4-5 160 V 5,000 V 250 V 8,000 V 250 V 10,000 V 250 V 7,000 V Wave shape As per IEC 60469-1 Wave shape As per IEC 60469-1 Wave shape As per IEC 60469-1 Wave shape As per IEC 60469-1 Rise time tr 1.0 µs Rise time tr 1.0 µs Rise time tr 1.0 µs Rise time tr 1,0 µs Pulse duration 50 µs Pulse duration 50 µs Pulse duration 50 µs Pulse duration 50 µs 80 A 2,500 A 125 A 4,000 A 125 A 5,000 A 125 A 3,500 A Wave shape As per IEC 60469-1 Wave shape As per IEC 60469-1 Wave shape As per IEC 60469-1 Wave shape As per IEC 60469-1 Rise time tr 6.4 µs Rise time tr 6.4 µs Rise time tr 6.4 µs Rise time tr 6.4 µs Pulse duration 16 µs Pulse duration 16 µs Pulse duration 16 µs Pulse duration 16 µs /alternating /alternating /alternating /alternating Output direct HV-banana connector Output direct HV-banana connector Output direct HV-banana connector Output direct HV-banana connector Coupling network L N with Z = 2 Ω Coupling network L N with Z = 2 Ω Coupling network External option Coupling network L N with Z = 2 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω Em.safe Current limiter function VCS 500N12 500 V 12,000 V / 6,000 A Telecom surge 250 V 7,000 V Front time 10 µs Pulse duration 700 µs 6.0 175 A Rise time tr 4 µs Pulse duration 300 µs VCS 500N10T 500 V 10.000 V 28 29

transients Telecommunication networks are exposed to lightning events. Therefore telecommunication equipment connected to the outside world needs to have appropriate protection that demonstrates an acceptable level of immunity to surge transients. This would prevent failure during lightning events. Telecom surge simulators of the TSS 500 series are used to test the immunity of telecommunication equipment. TSS 500N4 Telecom surge tester 4 kv TSS 500N10 Telecom surge tester 10 kv TSS 500N4b Telecom surge tester TSS 500N6b Telecom surge tester Telecom > Compact telecom surge generator as per ITU > Extra-high voltage telecom surge generator as per ITU > High-power telecom surge generator as per GR 1089 > Compact telecom surge generator as per GR 1089 > Built-in 1.2/50 µs & 10/700 µs transients > Up to 10 kv peak voltage > 10/250 µs for open-circuit voltage and short-circuit current > All 10/360 µs, 10/1,000 µs and 2/10 µs included > Built-in coupling network; 4 100 Ω and 2 25 Ω > Built-in coupling network; 4 100 Ω and 2 25 Ω > Up to 4 kv peak voltage and 2 ka peak current > Built-in resistors and coupling network FCC 97-270 (part 68), IEC 61000-4-5, ITU-T K.17, ITU-T K.20, ITU-T K.21, ITU-T K.28, ITU-T K.45, IEC 60950-1 FCC 97-270 (part 68), IEC 61000-4-5, ITU-T K.17, ITU-T K.20, ITU-T K.21, ITU-T K.28, ITU-T K.45, EN 60950-1 Bellcore GR-1089-Core Bellcore GR-1089-Core, ITU-T K.12, ITU-T K.28, ITU-T K.45 160 V 4,000 V Telecom surge as per ITU K Wave shape Front time tf 1.2 µs Duration td 50 µs Wave shape open-circuit Front time tf 10 µs Duration td 700 µs Wave shape short-circuit current 4 100 A Rise time tr 4 µs Duration td 300 µs Surge B as per FCC part 68 Wave shape open-circuit Front time tf 9 µs Duration td 720 µs Wave shape short-circuit current 4 100 A Rise time tr 5 µs Duration td 320 µs 500 V 10,000 V Telecom surge as per ITU K Wave shape Front time tf 1.2 µs Duration td 50 µs Wave shape open-circuit Front time tf 10 µs Duration td 700 µs Wave shape short-circuit current 12.5 250 A Rise time tr 4 µs Duration td 300 µs Surge B as per FCC part 68 Wave shape open-circuit Front time tf 9 µs Duration td 720 µs Wave shape short-circuit current 12.5 250 A Rise time tr 5 µs Duration td 320 µs First level lightning 2,000 V/1,000 A Rise time tr 10 µs Duration td 250 µs Second level lightning 4,000 V/2,000 A Rise time tr 10 µs Duration td 250 µs First level lightning surge 3,000 V/2,000 A Rise time tr 10 µs Duration td 250 µs High exposure premises 4,000 V/4 500 A Rise time tr 10 µs Duration td 250 µs 4 wire application 4 500 A for T, R, T1, R1 First-level lightning Pulse 10/1,000 µs with 6 Ω 1,000 V & 167 A per conductor Rise time tr/pulse duration td 10 µs/1,000 µs Pulse 10/360 µs with 10 Ω 1,000 V & 100 A per conductor Rise time tr/pulse duration td 10 µs/360 µs Pulse 10/1,000 µs with 10 Ω 1,000 V & 100 A per conductor Rise time tr/pulse duration td 10 µs/1,000 µs Pulse 2/10 µs with 5 Ω 2,500 V & 500 A per conductor Rise time tr/pulse duration td 2 µs/10 µs Pulse 10/360 µs with 40 Ω 1,000 V & 25 A per conductor Rise time tr/pulse duration td 10 µs/360 µs Intra-building lightning Pulse 2/10 µs with 8 Ω 2,500 V & 312 A per conductor Rise time tr/pulse duration td 2 µs/10 µs Pulse 2/10 µs with 15 Ω 2,500 V & 167 A per conductor Rise time tr/pulse duration td 2 µs/10 µs Second-level lightning Pulse 2/10 µs with 10 Ω 5,000 V & 500 A per conductor Rise time tr/pulse duration td 2 µs/10 µs CNB 500 Optional coupler for 12 pairs 30 31

ELECTROSTATIC DISCHaRGE Electrostatic discharges between objects can cause persistent disturbances or even destruction of sensitive electronics or controls. Dito is the most advanced ESD tester for accurate simulation of ESD pulses according to the latest standards. Its efficient battery power concept allows users to generate up to 50,000 pulses at maximum test voltage from a single battery, while standard and pre-programmed user test routines make ESD testing an easy and comfortable procedure. The ESD 30N is the state-of-the art ESD tester for all test requirements demanding more than 15 kv. Powered by the mains it also offers a built-in battery for testing without mains. Benefits like bleed-off function, sensor for temperature and rel. humidity and automatic polarity change-over are only a few to make the ESD 30N an outstanding tester. TSS 500N2B TSS 500N2F Telecom surge tester Telecom surge generator for surge A pulses as per FCC part 68 dito The ultimate ESD tester ESD 30N ESD tester up to 30 kv Telecom > High-power telecom surge generator as per GR 1089 > Compact telecom surge generator as per FCC part 68 > Ergonomic design > Up to 30 kv contact & air discharge > 10/1,000 µs for open-circuit voltage and short-circuit current > Built-in 10/160 µs & 10/560 µs transients > Modular concept > Interchangeable discharge networks > Up to 2 kv peak voltage and 200 A per wire peak current > Built-in resistors and coupling network > Easy to handle > For automotive, industrial and military applications Bellcore GR-1089-Core FCC 97-270 (part 68) Bellcore GR-1089-Core, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, IEC 61000-4-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, ISO 10605, JASO D001-94, Chrysler PF 9326, DaimlerChrysler PF-10540, Fiat 9.90110, Ford WDR 00.00EA, Renault 36.00.400/B, Renault 36.00.400/C, Toyota TSC3500G, Toyota TSC3590G, Volvo EMC requirements (1998), EN 300329 IEC 61000-4-2, ISO 10605, SAE J1113-13, SAE J1455, BMW 600 13.0 (Part 2), BMW GS 5002 (1999), DaimlerChrysler DC-10613, DaimlerChrysler DC-10614, Mercedes AV EMV, Ford ES-XW7T-1A278-AB, GMW 3097, GMW 3097 (2001), GMW 3100, GMW 3100 (2001), Mazda MES PW 67600, Mitsubishi ES-X82010, Nissan 28401 NDS 02, Porsche, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-E, Renault 36.00.808/-F, Smart DE1005B, VW TL 824 66, MBN 10284-2:2002, Renault 36.00.808/-G Pulse 10/1,000 µs with 10 Ω 2,000 V & 200 A per conductor Rise time tr/pulse duration td 10 µs/1,000 µs 4 wire application T, R, T1, R1 AC power port surge 160 V 2,500 V Rise time tr < 2.0 µs Pulse duration > 10 µs > 1,000 A Rise time tr < 2.0 µs Pulse duration > 10 µs Coupling network L to N, L to PE, N to PE; Zi = 2.5 Ω Metallic surge Max. 1,000 V Rise time tr < 10 µs Pulse duration > 560 µs Min. 100 A per conductor Rise time tr < 10 µs Pulse duration > 560 µs Longitudinal surge Max. 1,500 V Rise time tr < 10 µs Pulse duration > 160 µs Min. 200 A per conductor Rise time tr < 10 µs Pulse duration > 160 µs ESD as per IEC 61000-4-2 Test voltage 0.5 16.5 kv Discharge Air/contact discharge Hold-on time > 5 s R/C parameter 150 pf/330 Ω Specification contact discharge 500 V to 10 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV ESD as per ISO 10605 Test voltage 0.5 16.5 kv Discharge Air/contact discharge R/C parameters 100 pf/1,500 Ω 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω ESD as per IEC 61000-4-2 and ISO 10605 Test voltage Max. 30 kv Discharge Air/contact discharge Hold-on time > 5 s Specification contact discharge 0.2 30 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV R/C parameters 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω 100 pf/1,500 Ω customized Special technical highlights - RC network values indicated on the LCD - AD or CD discharge mode indicated on the LCD - Bleed-off function to discharge the EUT - Temperature and humidity sensor included - USB or optical interface included - esd.control software - Power supply: AC (88 250 V), DC (11 16 V) - Battery mode included for several hours 32 33

Conducted and radiated immunity Harmonics & Flicker The CWS 500N1 is the most compact single-box test equipment for conducted RF immunity testing as per IEC 61000-4-6 and related standards. As well as 1 khz 80 % AM, the CWS 500N1 also generates 2 Hz 80 % AM to test medical appliances, and 1 Hz PM with 50 % duty cycle required to test safety equipment such as fire alarms. EM TEST supplies a large range of CDNs, EM clamps, current injection clamps and calibration accessories. Bulk Current Injection (BCI) is a test procedure to test the immunity to electrical disturbances from narrowband electromagnetic energy. The test signal is injected by means of a current injection probe. In physical terms the current injection probe is a current transformer laid around the wiring harness. Immunity tests are performed varying the level and the frequency of the injected test signal. The BCI test method is widely known in the automotive industry as well as in the military/aircraft industry to test single components of a complex system. Harmonics and interharmonics are caused by modern electronic power conditioning modules used to control loads and reduce power consumption. Such most commonly non-linear modules are the source of voltage at unwanted frequencies superimposed on the supply voltage. Voltage fluctuations caused by varying load currents may influence luminance or spectral distribution of lighting systems. The impression of unsteadiness of visual sensation induced by this light stimulus is called flicker. Flicker also needs to be limited to a minimum. The DPA 500N is used for single-phase applications and the DPA 503N supports both single and 3-phase applications. ACS 500N is a single-phase and the ACS 503N a 3-phase AC source, specially designed for harmonics and flicker testing. It meets the corresponding specifications as per IEC/EN 61000-3-2 and IEC/EN 61000-3-3. It provides the perfect sinusoidal and stable voltage signal specified to give fully compliant harmonics and flicker analyses irrespective of the mains supply frequency and steadiness of the voltage. CWS 500N1-Series The single-box solution for RF-conducted immunity testing cws 500N2 The single-box solution for RF-conducted immunity testing DPA 500N Single-phase power analyser, H&F analyser ACS 500N6 Single-phase AC voltage source up to 6 kva Solution for NAMUR NE 21 also available as ACS 500N3 3,000 VA Telecom > RF-conducted immunity testing as per IEC 61000-4-6 > Compact simulator as per ISO 11452-4; EN 61000-4-6 > Single-phase harmonics/flicker analyser > AC power source up to 300 V/20 A single phase > Up to 300 MHz test frequency > 9 khz to 400 MHz, 100 W (expandable up to 1 GHz) > Built-in single-phase flicker impedance > Large inrush current capability > Self-calibration procedures for CDNs and coupling clamps > System solution is fully designed and supported by EM TEST > Real-time analysis using internal computer and DSP > Controlled by DPA 500N and dpa.control software IEC 61000-4-6, IEC 60601-1-2:2002, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, EN 50130-4, EN 61000-6-1, EN 61000-6-2, EN 300329, NAMUR NE21 IEC 61000-4-6, EN 61000-6-1, EN 61000-6-2, IEC 60601-1-2:2002, ISO 11452-4, ISO 11452-5, DaimlerChrysler DC-10614, Ford ES-XW7T-1A278-AB, Ford ESXW7T- 1A278-AC, GMW 3097 (2001), GMW 3097 (2004), MBN 10284-2:2002, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-G, MIL STD 461D/CS 114, MIL STD 461E/CS 114, RTCA/DO 160 Section 20, Fiat 9.90110 IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, IEC 61000-4-7, IEC 61000-4-15, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 300386-2, EN 61000-3-2, EN 61000-3-3, EN 61000-3-11, EN 61000-3-12, EN 61000-4-7, EN 61000-4-15, JIS C 61000-3-2 IEC 61000-3-2, IEC 61000-3-3, EN 61000-3-2, EN 61000-3-3, JIS C 61000-3-2 Output power 80 W (nominal) Output impedance 50 Ω max. VSWR 1 : 1.2 at all phase angles and at max. power (without destruction) Frequency range 9 khz 1 GHz (internal signal generator) Frequency range with built-in 100 khz 300MHz amplifier Modulation AM 1 3,000 Hz, 0 95 % depth PM 1 3,000 Hz Duty cycle 10 % 80 % Harmonic distortion > 20 dbc Preprogrammed modulations Amplitude modulation 80 % ±5 %, 1 khz ±10 % 80 % ±5 %, 2 Hz, 1 khz Pulse modulation 1 Hz, 50% duty cycle acc. to EN 50130-4 Other models: CWS 500N1.1 Output power, frequency range 25 W, 100 khz 250 MHz CWS 500N1.2 Output power, frequency range 50 W, 10 khz 230 MHz Output power 100 W (nominal) Output impedance 50 Ω Max. VSWR 1 : 2.0 Output level -13 dbm 50 dbm Frequency range 9 khz 400 MHz (1,000 MHz) Modulation AM 1-3,000 Hz, 1-99 % depth PM 1 3,000 Hz Duty cycle 10 % 80 % Harmonic distortion > 20 dbc Output N-connector Built-in power meter Channel 1 forward power Channel 2 reverse power Channel 3 injected current Built-in coupler Max. 200 W/1 GHz Built-in RF switch Automatic commutation to an external amplifier Input channels 2 (1 current & voltage) EUT connection 1-phase A/D converter 16 bit Class of instrument Class A as per IEC/EN 61000-4-7, ed. 2 Voltage input 10 530 Vrms Overload 4,000 V peak Input range internal 50 A peak 16 A continuous Input range external Standard delivered model max. 140 A (factory setting 2 turns 70 A) Harmonic analysis IEC/EN 61000-3-2 and IEC/EN 61000-3-12, according to IEC/EN 61000-4-7, JIS C 61000-3-2 Harmonic range 1 50th harmonic Grouping Interharmonics acc. to IEC/EN 61000-4-7, ed. 2 Display Urms, Irms, Ipeak, Upeak, P, Q, S, power factor, THD (U), THD (I), crest factor (U), crest factor (I) Flicker analysis IEC/EN 61000-3-3 and IEC/EN 61000-3-11, according to IEC/EN 61000-4-15 Flicker data P st and P lt, Vrms, dmax, dc, dt, P50 %S, P10 %S, P3 %S, P1 %S, P0.1 % Flicker impedance: Phase Neutral 0.24 Ω + j 0.15 Ω 0.16 Ω + j 0.10 Ω ACS 500N6 Voltage range 0 to 300 V Voltage resolution 0.025 % Output frequency 10 Hz to 80 Hz Output power 6,000 VA Output Safety banana-connector ACS 500N3 Voltage range 0 to 300 V Voltage resolution 0.025 % Output frequency 10 Hz to 80 Hz Output power 3,000 VA Output Safety banana-connector 34 35

SIMULATION OF AC AND DC SUPPLY ANOMALIES Power Mains Simulation voltage surge and Safety NetWave is an AC/DC power source, specifically designed to meet the requirements as per IEC/EN 61000-4-13, IEC/EN 61000-4-14, IEC/EN 61000-4-17, IEC/EN 61000-4-28. Its output power with low distortion and high stability, even if supplying dynamic loads, guarantees full compliant measurements for harmonics and flicker as per IEC/EN 61000-3-2, JIS C 61000-3-2 and IEC/EN 61000-3-3 as well as per IEC/EN 61000-3-11 and IEC/EN 61000-3-12. The three-phase Netwave models additionally support testing as per IEC/EN 61000-4-27. Electronic and electrical equipment may be affected by voltage dips, short interruptions and voltage variations of the power supply. Dips and interruptions are caused by faults in the network or installations or by sudden large changes of load. Testing for such a phenomena is required in order to ensure that electronic and electrical equipment does not fall into unsafe operation conditions. The voltage surge simulator VSS 500N10 generates high-voltage transients as required by IEC 60065 and UL 6500 standards for safety tests on audio, video and similar electronic apparatus. NETWAVE-Series SINGLE Phase Multifunction AC/DC Power Source NETWAVE-Series Three Phase Multifunction AC/DC Power Source PFS 503N-Series Simulator for dips, short interruptions and voltage variations VSS 500N10 Voltage surge simulation Telecom > Wide power bandwidth; DC 5 khz > Wide power bandwidth; DC 5 khz > True 3-phase voltage dip generator as per IEC 61000-4-11 > Testing equipment safety up to 10 kv > High inrush current capability > High inrush current capability > Dip mode, line(s) to neutral or line to line > Special pulse-shaping network > Built-in arbitrary waveform generator, 16 Bit > Built-in arbitrary waveform generator, 16 Bit > External variac for STAR and DELTA power mains systems IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing IEC 61000-4-11, IEC 61000-4-29, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, IEC 61000-4-34 IEC 60065, UL 6500, IEC 60950 Technical Data - SINGLE Phase Technical Data - Three Phase Output voltage Netwave 3, Netwave 7 0 V 300 VAC (p-n); 0 V ± 425 VDC Netwave 7.2 0 V 360 VAC (p-n); 0 V ± 500 VDC Output power Netwave 3 AC mode: 3,500 VA, DC mode: 4,500 W Netwave 7, Netwave 7.2 AC mode: 7,500 VA, DC mode: 9,000 W Output current Netwave 3 12 A (RMS) continuous 21 A (RMS) short-term (max. 3 s) 100 A repetitive peak Netwave 7, Netwave 7.2 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak Output frequency DC 5,000 Hz Frequency accuracy, stability 100 ppm Output voltage stability Better than 0.1 % Output voltage accuracy Better than 0.5 % Total harmonic distortion (THD) Less than 0.5 % DC offset in AC mode < 20 mv with linear load Slew rate 8 V/µs Output voltage Netwave 20, Netwave 30, Netwave 60 Netwave 20.1, Netwave 30.1, Netwave 60.1 Output power Netwave 20.x Netwave 30.x Netwave 60.x Output current Netwave 20.x Netwave 30.x Netwave 60.x 0 V 3*300 VAC (p-n); 0 V ± 425 VDC 0 V 3*360 VAC (p-n); 0 V ± 500 VDC 22,500 VA AC, 27,000 W DC 30,000 VA AC, 36,000 W DC 60,000 VA AC, 72,000 W DC 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak 33 A (RMS) continuous 66 A (RMS) short-term (max. 3s ) 250 A repetitive peak 66 A (RMS) continuous 100 A (RMS) short-term (max. 3 s) 400 A repetitive peak AC voltage L-L Max. 3 440 V AC current Max. 3 32/63/100 A Frequency 50/60 Hz AC voltage L-N Max. 250 V AC current Max. 32, 63, 100 A Frequency 50/60 Hz DC voltage Max. 250 V DC current Max. 32, 63, 100 A Inrush current > 500 A (PFS 503N32) > 1.000 A (PFS 503N63 / PFS 503N100) Short-circuit protected Dip mode Line to line Line to neutral Lines to neutral Other Models: PFS 503N32 3 x 440 V, 32 A PFS 503N63 3 x 440 V, 63 A PFS 503N100 3 x 440 V, 100 A Rise time tr Pulse duration Internal resistor 500 V 10,000 V < 100 ns > 2 ms 1,000 Ω Positive 36 37

transients transients battery simulation UCS 500N5E/EFT 500N5 an EFT/burst generator is an intelligent solution offering exactly what you need for full-compliance immunity tests for electrical/fast transient phenomena. The distinct operation features, convenient DUT connection facilities, a clearly arranged menu structure and display concept as well as the preprogrammed standard test routines make testing easy, reliable and safe. Extendable with a variety of test accessories the EFT 500Nx is a universal device for a broad range of tests, including three-phase applications up to 100 A. The UCS 200N Ultra Compact Simulator for automotive transients unites the capabilities of an EFT/burst simulator, a micropulse simulator and the required coupling network in one box. The UCS 200N can be equipped to meet all international and car manufacturer specifications from around the globe. The coupling network can carry currents up to 200 A depending on the model. For non-standard tests the waveform parameters of the micropulse generator can be varied over a wide range. The built-in coupling network can be used and controlled by any unit of the LD 200N series, VDS 200N series and PFS 200N series. The VDS 200N series is used to simulate the various battery supply waveforms recommended by international standards and car manufacturer standards. The wide range of manufacturer requirements make this an extremely important area, which is covered by the VDS 200N series. Additionally, the VDS 200N series serves as a powerful DC voltage supply for the DUT during tests with automotive transients. EFT 500N5-SERIES/UCS500N5E Electronic-fast-transient simulator EFT 500N8 Electronic-fast-transient simulator UCS 200N-SERIES Ultra Compact Simulator for automotive transients for pulses 1, 1a, 2a, 3a/3b and 6 VDS 200N-SERIES Battery supply simulator and DC voltage source Also available as EFT 500N8.1 3 x 440 V AC/32 A Telecom > Fast-transient simulator as per IEC 61000-4-4, ed. 2 > Fast-transient simulator as per IEC 61000-4-4, ed. 2 > Test pulses acc. to ISO, JASO, NISSAN, SAE > Stand-alone, programmable DC source > Output voltage 5,5 kv, spike frequency up to 1 MHz > Output voltage 7 kv, spike frequency up to 1 MHz > Built-in single-phase CDN > Freestyle pulse shape generation > 60 V/15 A up to 200 A (2,000 A inrush current) IEC 61000-4-4 Ed.2 (2004), IEC 61000-4-4 Amd.1 Ed.2 (2010), EN 61000-4-4:2005-07 IEC 61000-4-4 Ed.2 (2004), IEC 61000-4-4 Amd.1 Ed.2 (2010), EN 61000-4-4:2005-07 ISO 7637-2, ISO 7637-3, SAE J1113, JASO D001, manufacturer specifications ISO 7637-2, ISO 16750, manufacturer specifications UCS 500N5E EFT as per IEC 61000-4-4, ed. 2 Pulse 3a/3b as per ISO 7637-2 Voltage range 0 V 60 V with 0.1 V steps Open-circuit 200 V 5,500 V Open-circuit 1,000 V 7,000 V Open-circuit 25 V 1,000 V VDS 200N10 I = 0 A 10 A cont., 15 A peak Wave shape into a 50 Ω load 100 V 2,750 V Wave shape into a 50 Ω load 500 V 3,500 V Rise time 5 ns VDS 200N15 I = 0 A 15 A cont. Rise time tr 5 ns Rise time tr 5 ns Pulse duration 150 ns VDS 200N30 I = 0 A 30 A cont., 70 A for 500 ms Pulse duration td 50 ns Pulse duration td 50 ns Ri 50 Ω VDS 200N50 I = 0 A 50 A cont., 100 A for 500 ms Wave shape into a 1,000 Ω load 200 V 4,800 V Wave shape into a 1,000 Ω load 1,000 V 7,000 V 3a > negative, 3b > positive VDS 200N100 I = 0 A 100 A cont., 150 A for 500 ms Rise time tr 5 ns Rise time tr 5 ns Micropulses as per ISO 7637-2 VDS 200N150 I = 0 A 150 A cont. Pulse duration td 35 ns 150 ns Pulse duration td 35 ns 150 ns Open-circuit 20 V 600 V VDS 200N200 I = 0 A 200 A cont. Source impedance Zq = 50 Ω Source impedance Zq = 50 Ω Pulses 1, 1a, 2a and 6 VDS 200N200.1 I = 0 A 200 A cont., 1,000 A for 500 ms Ri 2, 4, 10, 20, 30, 50, 90 Ω Output 50 Ω coaxial connector To connect external coupler Output 50 Ω coaxial connector To connect external coupler Output coaxial connector 50 Ω VDS 200N30.1 Range I: -5 V ± 30 V Coupling network To L, N, PE all combinations Coupling network To L, N, PE all combinations Additional standard test routines SAE J1455 inductive & mutual I = 50 A cont., 150 A for 200 ms Verification Verification NISSAN B2, C8, C50, C300 Range II: - 5 V ± 60 V Coaxial output Wave shape on 50 Ω and 1,000 Ω Coaxial output Wave shape on 50 Ω and 1,000 Ω JASO A2, B2, D2 I = 30 A cont., 90 A for 200 ms CDN output Wave shape 5/50 ns on 50 Ω during common CDN output Wave shape 5/50 ns on 50 Ω during common Freestyle VDS 200N50.1 Range I: -5 V ± 30 V mode coupling mode coupling Open-circuit 20 V 600 V I = 85 A cont., 220 A for 200 ms DUT power mains supply AC 250 V/16 A, 50/60 Hz; DC 250 V/10 A DUT power mains supply AC 250 V/16 A, 50/60 Hz; DC 250 V/10 A Rise time tr 1 µs 10 µs Range II: - 5 V ± 60 V Other Models: Duration td 50 µs 10,000 µs I = 50 A cont., 150 A for 200 ms EFT 500N5.1 3-Phase Couplingnetwork, 3 x 440 V AC/32 A EFT 500N8.1 3-Phase Couplingnetwork, 3 x 440 V AC/32 A Ri 2 450 Ω EFT 500N5.2 3-Phase Couplingnetwork, 3 x 440 V AC/50 A DUT supply voltage 60 V Preprogrammed pulses 2b, 4, sinewave, sinewave sweep, etc. EFT 500N5.5 1-Phase Couplingnetwork, 1 x 250 V AC/32 A DUT current (nominal) 50 A, 100 A, 150 A and 200 A Source impedance Zq = < 10 mω 38 39

industry medical residential broadcast Transients The UCS 500N5/UCS 500N7 Ultra Compact Simulators are the most versatile testers for covering transient and power-fail requirements according to international (basic and generic) and product family standards, with voltage capability of up to 7 kv. In addition to the IEC 61000-4-5 standard for surge testing, they also comply to ANSI/IEEE C62.41 requirements for surge and ring wave testing. UCS 500N5 Compact tester for EFT/burst, surge and power fail The UCS 500N7 is the most economical test solution for fully compliant immunity tests and CE marking. A built-in CDN is used for testing single-phase EUTs up to 400 V/16 A, while tests on three-phase EUTs can be performed by adding an automatically controlled external coupling network up to 690 V with max. 100 A. EM TEST supplies a large range of accessories for various applications. UCS 500N7 Compact tester for EFT/burst, surge, ring wave and power fail > Small and compact all-in-one tester > IEC 61000-4-4/-5/-8/-9/-11/-29 > Built-in single-phase CDN IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, EN 55024, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, ITU-T K.20, ITU-T K.41, ITU-T K.45, EN 300329 > Testing beyond the limits, 5.5 kv EFT & 7 kv surge > Optional RWG module as per 61000-4-12 IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-12, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, Bellcore GR-1089-Core, ANSI/IEEE C62.41, EN 61543, IEC 61008-1, IEC 61009-1, IEEE 1547, UL 1741 Industry Medical Residential Broadcast Overview Technical Data Application Transients Conducted Immunity Products UCS 500Nx EFT 500N-Series VCS 500Nx OCS 500N-Series TSS 500Nx Standards IEC 61000-4-4 IEC 61000-4-5 IEC 61000-4-12 IEC 61000-4-18 CWS 500N1-Series CWS 500N2 CWS 500N4 IEC 60601-1-2 IEC 61000-4-6 IEC 61000-4-16 Radiated Immunity UCS 500Nx OCS 500N-Series IEC 61000-4-8 IEC 61000-4-9 IEC 61000-4-10 Power Mains Simulation PFS 503N-Series UCS 500Nx NetWave-Series Single Phase NetWave Series Three Phase IEC 61000-4-11 IEC 61000-4-13 IEC 61000-4-14 IEC 61000-4-27 IEC 61000-4-28 IEC 61000-4-29 Electrostatic Discharge dito ESD 30N Harmonics & Flicker DPA 500N ACS 500N DPA 503N ACS 503N-Series AIF 503N-Series IEC 61000-4-2 IEC 61000-3-2 IEC 61000-3-3 IEC 61000-3-11 IEC 61000-3-12 JIS C 61000-3-2 EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 160 V 5,000 V 8/20 µs 80 A 2,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 300 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 160 V 5,000 V 4/300 µs 4 A 125 A EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 250 V 7,000 V 8/20 µs 125 A 3,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 300 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Ring wave as per IEC 61000-4-12 0.5 µs/100 khz 6,000 V with 12 Ω and 30 Ω source impedance Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 250 V 7,000 V 4/300 µs 6 A 175 A 41

transients transients UCS 500N5E /EFT 500N5 an EFT/burst generator is an intelligent solution offering exactly what you need for full-compliance immunity tests for electrical/fast transient phenomena. The distinct operation features, convenient DUT connection facilities, a clearly arranged menu structure and display concept as well as the preprogrammed standard test routines make testing easy, reliable and safe. Extendable with a variety of test accessories the EFT 500Nx is a universal device for a broad range of tests, including three-phase applications up to 100 A. Surge pulses occur due to direct or indirect lightning strikes to an external (outdoor) circuit. This leads to currents or electromagnetic fields causing high-voltage or current transients. Another source of surge pulses is switching transients originating from switching disturbances and system faults. Due to the characteristic of the phenomenon almost every electrical and electronic device is affected by such lightning events. Surge tests should therefore be widely performed. Surge voltages can reach several thousands of volts while surge currents reach levels of several thousands of amps. EFT 500N5-SERIES/UCS500N5E Electronic-fast-transient simulator EFT 500N8 Electronic-fast-transient simulator UCS 500N5V Surge tester 5.0 kv VCS 500N8 Surge tester 8 kv > Fast-transient simulator as per IEC 61000-4-4, ed. 2 > Output voltage 5,5 kv, spike frequency up to 1 MHz IEC 61000-4-4 Ed.2 (2004), IEC 61000-4-4 Amd.1 Ed.2 (2010), EN 61000-4-4:2005-07 Also available as EFT 500N8.1 3 x 440 V AC/32 A > Fast-transient simulator as per IEC 61000-4-4, ed. 2 > Output voltage 7 kv, spike frequency up to 1 MHz > Built-in single-phase CDN IEC 61000-4-4 Ed.2 (2004), IEC 61000-4-4 Amd.1 Ed.2 (2010), EN 61000-4-4:2005-07 > 5.0 kv/2.5 ka surge, IEC 61000-4-5/-9 > Preprogrammed standard test routines included > Built-in single-phase CDN IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.41, ITU-T K.45 > Testing beyond the limits, 8 kv/4 ka, IEC 61000-4-5/-9 > Built-in single or 3-phase CDN IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 Industry Medical Residential Broadcast UCS 500N5E Open-circuit Wave shape into a 50 Ω load Rise time tr Pulse duration td Wave shape into a 1,000 Ω load Rise time tr Pulse duration td Source impedance Output 50 Ω coaxial connector Coupling network Verification Coaxial output CDN output DUT power mains supply Other Models: EFT 500N5.1 EFT 500N5.2 EFT 500N5.5 200 V 5,500 V 100 V 2,750 V 5 ns 50 ns 200 V 4,800 V 5 ns 35 ns 150 ns Zq = 50 Ω To connect external coupler To L, N, PE all combinations Wave shape on 50 Ω and 1,000 Ω Wave shape 5/50 ns on 50 Ω during common mode coupling AC 250 V/16 A, 50/60 Hz; DC 250 V/10 A 3-Phase Couplingnetwork, 3 x 440 V AC/32 A 3-Phase Couplingnetwork, 3 x 440 V AC/50 A 1-Phase Couplingnetwork, 1 x 250 V AC/32 A EFT as per IEC 61000-4-4, ed. 2 Open-circuit Wave shape into a 50 Ω load Rise time tr Pulse duration td Wave shape into a 1,000 Ω load Rise time tr Pulse duration td Source impedance Output 50 Ω coaxial connector Coupling network Verification Coaxial output CDN output DUT power mains supply EFT 500N8.1 1,000 V 7,000 V 500 V 3,500 V 5 ns 50 ns 1,000 V 7,000 V 5 ns 35 ns 150 ns Zq = 50 Ω To connect external coupler To L, N, PE all combinations Wave shape on 50 Ω and 1,000 Ω Wave shape 5/50 ns on 50 Ω during common mode coupling AC 250 V/16 A, 50/60 Hz; DC 250 V/10 A 3-Phase Couplingnetwork, 3 x 440 V AC/32 A Surge as per IEC 61000-4-5 160 V 5,000 V Wave shape as per IEC 469-1 Rise time tr 1.0 µs Pulse duration 50 µs 80 A 2,500 A Wave shape as per IEC 469-1 Rise time tr 6.4 µs Pulse duration 16 µs /alternating Output direct HV-banana connector Coupling network L N with Z = 2 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω Em.safe Current limiter function Surge as per IEC 61000-4-5 250 V 8,000 V Wave shape as per IEC 469-1 Rise time tr 1.0 µs Pulse duration 50 µs 125 A 4,000 A Wave shape as per IEC 469-1 Rise time tr 6.4 µs Pulse duration 16 µs /alternating Output direct HV-banana connector Coupling network L N with Z = 2 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω 42 43

transients transients Surge pulses occur due to direct or indirect lightning strikes to an external (outdoor) circuit. This leads to currents or electromagnetic fields causing high-voltage or current transients. Another source of surge pulses is switching transients originating from switching disturbances and system faults. Due to the characteristic of the phenomenon almost every electrical and electronic device is affected by such lightning events. Surge tests should therefore be widely performed. Surge voltages can reach several thousands of volts while surge currents reach levels of several thousands of amps. Telecommunication networks are exposed to lightning events. Therefore telecommunication equipment connected to the outside world need to have appropriate protection that demonstrates an acceptable level of immunity to surge transients. This would prevent failure during lightning events. Telecom surge simulators of the TSS 500 series are used to test the immunity of telecommunication equipment. VCS 500N10 Surge tester up to 10 kv VCS 500N7T Surge & telecom tester 7 kv TSS 500N4 Telecom surge tester 4 kv TSS 500N10 Telecom surge tester 10 kv > Still compact in size but up to 10 kv/5 ka, IEC 61000-4-5/-9 also available as VCS 500N12 with 12 kv > External CDNs for power mains and I/O line applications IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 > IEC 61000-4-5, ITU > 7.0 kv/3.5 ka surge & 7.0 kv telecom surge 10 µs/700 µs > Built-in single-phase CDN also available as VCS 500N10T with 10 kv IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 > Compact telecom surge generator as per ITU > Built-in 1.2/50 µs & 10/700 µs transients > Built-in coupling network; 4 100 Ω and 2 25 Ω FCC 97-270 (part 68), IEC 61000-4-5, ITU-T K.17, ITU-T K.20, ITU-T K.21, ITU-T K.28, ITU-T K.45, IEC 60950-1 > Extra-high voltage telecom surge generator as per ITU > Up to 10 kv peak voltage > Built-in coupling network; 4 100 Ω and 2 25 Ω FCC 97-270 (part 68), IEC 61000-4-5, ITU-T K.17, ITU-T K.20, ITU-T K.21, ITU-T K.28, ITU-T K.45, EN 60950-1 Industry Medical Residential Broadcast Surge as per IEC 61000-4-5 Surge as per IEC 61000-4-5 160 V 4,000 V 500 V 10,000 V 250 V 10,000 V 250 V 7,000 V Telecom surge as per ITU K Telecom surge as per ITU K Wave shape Wave shape Wave shape Wave shape Rise time tr 1.0 µs Rise time tr 1,0 µs Front time tf 1.2 µs Front time tf 1.2 µs Pulse duration 50 µs Pulse duration 50 µs Duration td 50 µs Duration td 50 µs 125 A 5,000 A 125 A 3,500 A Wave shape Wave shape Wave shape open-circuit Wave shape open-circuit Rise time tr 6.4 µs Rise time tr 6.4 µs Front time tf 10 µs Front time tf 10 µs Pulse duration 16 µs Pulse duration 16 µs Duration td 700 µs Duration td 700 µs /alternating /alternating Wave shape short-circuit current 4 100 A Wave shape short-circuit current 12.5 250 A Output direct HV-banana connector Output direct HV-banana connector Rise time tr 4 µs Rise time tr 4 µs Coupling network External option Coupling network L N with Z = 2 Ω Duration td 300 µs Duration td 300 µs L-PE, N-PE, L+N-PE; Z = 12 Ω VCS 500N12 500 V 12,000 V / 6,000 A Telecom surge 250 V 7,000 V Surge B as per FCC part 68 Surge B as per FCC part 68 Front time 10 µs Wave shape open-circuit Wave shape open-circuit Pulse duration 700 µs Front time tf 9 µs Front time tf 9 µs 6.0 175 A Duration td 720 µs Duration td 720 µs Rise time tr 4 µs Wave shape short-circuit current 4 100 A Wave shape short-circuit current 12.5 250 A Pulse duration 300 µs Rise time tr 5 µs Rise time tr 5 µs Duration td 320 µs Duration td 320 µs VCS 500N10T 500 V 10,000 V / 5,000 A 44 45

transients Conducted and radiated immunity The OCS 500N6 is used for ring wave testing up to 6 kv, slow damped oscillatory wave testing (100 khz and 1 MHz) up to 3 kv, and optional fast damped oscillatory wave at 3, 10, and 30 MHz. A ring wave is a non-repetitive damped oscillatory transient occurring in low-voltage power, control and signal lines supplied by public and non-public networks. Damped oscillatory waves are repetitive transients occurring mainly in power, control and signal cables installed in high-voltage and medium-voltage stations. The OCS 500N6 can also be used to perform magnetic field tests as required in IEC 61000-4-10 using a magnetic field coil such as the MS 100. The CWS 500N1 is the most compact single-box test equipment for conducted RF immunity testing as per IEC 61000-4-6 and related standards. As well as 1 khz 80 % AM, the CWS 500N1 also generates 2 Hz 80 % AM for testing medical appliances, and 1 Hz PM with 50 % duty cycle required for testing safety equipment such as fire alarms. EM TEST supplies a large range of CDNs, EM clamps, current injection clamps and calibration accessories. Bulk Current Injection (BCI) is a test procedure for testing the immunity to electrical disturbances caused by narrowband electromagnetic energy. The test signal is injected by means of a current injection probe. In physical terms the current injection probe is a current transformer laid around the wiring harness. Immunity tests are performed varying the level and the frequency of the injected test signal. The BCI test method is widely known in the automotive industry as well as in the military/aircraft industry for testing single components of a complex system. OCS 500N-Series Compact tester for ring wave and damped oscillatory waves DOW Module Fast damped oscillatory wave option for OCS 500N6 CWS 500N1-Series The single-box solution for RF-conducted immunity testing cws 500N2 The single-box solution for RF-conducted immunity testing > 100 khz ring wave & 100 khz/1 MHz damped oscillatory > Conducted immunity and magnetic field test > Built-in coupling network also available as 1 or 3-Phase Version up to 32 A ANSI/IEEE C37.90, ANSI/IEEE C62.41, IEC 60255-1, IEC 61000-4-10, IEC 61000-4-12, IEC 61000-4-18, IEEE 1547 > Fast Damped Oscillatory Wave 3/10/30 MHz IEC 61000-4-18 Solution for NAMUR NE 21 > RF-conducted immunity testing as per IEC 61000-4-6 > Up to 300 MHz test frequency > Self-calibration procedures for CDNs and coupling clamps IEC 61000-4-6, IEC 60601-1-2:2002, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, EN 50130-4, EN 61000-6-1, EN 61000-6-2, EN 300329, NAMUR NE21 > Compact simulator as per ISO 11452-4; EN 61000-4-6 > 9 khz to 400 MHz, 100 W (expandable up to 1 GHz) > System solution is fully designed and supported by EM TEST IEC 61000-4-6, EN 61000-6-1, EN 61000-6-2, IEC 60601-1-2:2002, ISO 11452-4, ISO 11452-5, DaimlerChrysler DC-10614, Ford ES-XW7T-1A278-AB, Ford ESXW7T- 1A278-AC, GMW 3097 (2001), GMW 3097 (2004), MBN 10284-2:2002, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-G, MIL STD 461D/CS 114, MIL STD 461E/CS 114, RTCA/DO 160 Section 20, Fiat 9.90110 Industry Medical Residential Broadcast TECHNICAL DATA (OVERVIEW) Damped oscillatory as per IEC 61000-4-18 Output voltage open-circuit 250 V 3,000 V +/- 10 % Rise time/oscillation frequency 1/T 75 ns/100 khz and 1 MHz Decaying Peak 5 must be > 50 % of peak 1 value Peak 10 must be < 50 % of peak 1 value Source impedance 200 Ω Repetition rate 40/s for 100 khz and 400/s for 1 MHz Direct output at the front panel For ext CDN & magn. field antenna Coupling network 1-phase or 3-phase Damped oscillatory magnetic field as per IEC 61000-4-10 MS 100 (square 1 m 1 m) antenna Ring wave as per IEC 61000-4-12 Output voltage open-circuit 250 V 6,000 V Rise time first peak T1/Oscillation frequency 0.5 µs/100 khz Decaying of Pk1 to Pk2 40 % 110 % Decaying of Pk2 to Pk3 & decaying of Pk3 to Pk4 40 % 80 % Output impedance 12 Ω, 30 Ω (200 Ω external) Wave shape short-circuit Rise time first peak tr T1 < 1 µs Oscillation frequency 1/T 100 khz Fast Damped oscillatory IEC 61000-4-18 Output voltage open-circuit 450 V 4,400 V +/- 10 % Rise time voltage waveform 5 ns +/- 30 % Oscillation frequency 3 MHz, 10 MHz, 30 MHz, +/- 10 % Decaying voltage waveform Peak 5 must be > 50 % of peak 1 Source impedance 50 Ω +/- 20 % Peak 10 must be < 50 % of peak 1 Repetition rate Max. 5000/s +/- 10 % Burst duration 50 ms +/- 20 %, at 3 MHz 15 ms +/- 20 %, at 10 MHz 5 ms +/- 20 %, at 30 MHz Burst period 300 ms +/- 20 % Short circuit current 9A 88 A +/- 20 % Rise time current waveform Decaying current waveform At 3 MHz: < 330 ns At 10 MHz: < 100 ns At 30 MHz: < 33 ns Peak 5 must be > 25 % of peak 1 Peak 10 must be < 25 % of peak 1 Output power 80 W (nominal) Output impedance 50 Ω Frequency range 9 khz 1 GHz (internal signal generator) max. VSWR 1 : 1.2 at all phase angles and at max. power (without destruction) Frequency range with build-in 100 khz 300 MHz amplifier Modulation AM 1 3,000 Hz, 0 95 % depth PM 1 3,000 Hz Duty cycle 10 % 90 % Harmonic distortion > 20 dbc Preprogrammed modulations Amplitude modulation 80 % < ± 5 %, 1 khz < ± 10 % 80 % < ± 5 %, 2 Hz, 1 khz Pulse modulation 1 Hz, 50 % duty cycle acc. to EN 50130-4 Other models CWS 500N1.1 Output power, frequency range 25 W, 100 khz 250 MHz CWS 500N1.2 Output power, freuqency range 50 W, 10 khz 230 MHz Output power 100 W (nominal) Output impedance 50 Ω Max. VSWR 1 : 2.0 Output level -13 dbm 50 dbm Frequency range 9 khz 400 MHz (1,000 MHz) Modulation AM 1 3,000 Hz, 1 99 % depth PM 1 3,000 Hz Duty cycle 10 % 80 % Harmonic distortion > 20 dbc Output N-connector Built-in power meter Channel 1 forward power Channel 2 reverse power Channel 3 injected current Built-in coupler Max 200 W/1 GHz Built-in RF switch Automatic commutation to an external amplifier 46 47

Power Mains Simulation SIMULATION OF AC AND DC SUPPLY ANOMALIES The CWS 500N4 is the state-of-the-art solution in a compact one-box design to test for immunity to conducted, common mode disturbances in the frequency range 0 Hz (DC) to 150 khz. Such test requirements are specified in IEC 61000-4-16 and cover continuous mode testing as well as short term testing with DC, 16 2/3 Hz, 50 Hz and 60 Hz plus a sweep mode from 15 Hz to 150 khz. Complemented by an AC voltage source or a motor variac, the CWS 500N4 forms a complete test system allowing the coupling of the disturbance signals onto the various types of lines by means of specified coupling networks. Electronic and electrical equipment may be affected by voltage dips, short interruptions and voltage variations of the power supply. Dips and interruptions are caused by faults in the network or installations or by sudden large changes of load. Testing for such a phenomena is required in order to ensure that electronic and electrical equipment does not fall into unsafe operation conditions. NetWave is an AC/DC power source, specifically designed to meet the requirements as per IEC/EN 61000-4-13, IEC/EN 61000-4-14, IEC/EN 61000-4-17, IEC/EN 61000-4-28. Its output power with low distortion and high stability, even if supplying dynamic loads, guarantees full compliant measure- ments for harmonics and flicker as per IEC/EN 61000-3-2, JIS C 61000-3-2 and IEC/EN 61000-3-3 as well as per IEC/EN 61000-3-11 and IEC/EN 61000-3-12. The three-phase Netwave models additionally support testing as per IEC/EN 61000-4-27. cws 500N4 Compact simulator for conducted common-mode immunity testing PFS 503N-Series Simulator for dips, short interruptions and voltage variations NETWAVE-Series SINGLE Phase Multifunction AC/DC Power Source NETWAVE-Series Three Phase Multifunction AC/DC Power Source > Compact simulator as per IEC 61000-4-16 > DC to 150 KHz > System solution is fully designed and supported by EM TEST IEC 60533, IEC 61000-4-16, IEC 61326, IEC 61543, IEC 61850-3, IEC 60255-22-7, IEC/EN 60870-5, EN 50121-4 > True 3-phase voltage dip generator as per IEC 61000-4-11/-34 > Dip mode, line(s) to neutral or line to line > External variac for STAR and DELTA power mains systems IEC 61000-4-11, IEC 61000-4-29, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, IEC 61000-4-34 > Wide power bandwidth; DC 5 khz > High inrush current capability > Built-in arbitrary waveform generator, 16 Bit IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing > Wide power bandwidth; DC 5 khz > High inrush current capability > Built-in arbitrary waveform generator, 16 Bit IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing Industry Medical Residential Broadcast Technical Data - SINGLE Phase Technical Data - Three Phase Signal level continuous 0.1 35 V rms or DC Test levels short-term 1 330 V rms or DC Test frequencies DC, 16 2/3 Hz, 50 Hz and 60 Hz Frequency range 15 Hz - 165 khz (sweep mode) Generator impedance 50 Ω, guaranteed also under short-circuit conditions Build-in voltmeter RMS measurement Build-in rectifier For DC testing with MV 2606N2.2 Build-in semi conductor fall/rise time between 1 µs 5 µs power switch AC voltage L-L Max. 3 440 V AC current Max. 3 32/63/100 A Frequency 50/60 Hz AC voltage L-N Max. 250 V AC current Max. 32, 63, 100 A Frequency 50/60 Hz DC voltage Max. 250 V DC current Max. 32, 63, 100 A Inrush current > 500A (PFS 503N32) > 1.000A (PFS 503N63 / PFS 503N100) Short-circuit protected Dip mode Line to line Line to neutral Lines to neutral Other Models: PFS 503N32.1 3 x 690 V, 32 A PFS 503N63.1 3 x 690 V, 63 A PFS 503N100.1 3 x 690 V, 100 A Output voltage Netwave 3, Netwave 7 0 V 300 VAC (p-n); 0 V ± 425 VDC Netwave 7.2 0 V 360 VAC (p-n); 0 V ± 500 VDC Output power Netwave 3 AC mode: 3,500 VA, DC mode: 4,500 W Netwave 7, Netwave 7.2 AC mode: 7,500 VA, DC mode: 9,000 W Output current Netwave 3 12 A (RMS) continuous 21 A (RMS) short-term (max. 3 s) 100 A repetitive peak Netwave 7, Netwave 7.2 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak Output frequency DC 5,000 Hz Frequency accuracy, stability 100 ppm Output voltage stability Better than 0.1 % Output voltage accuracy Better than 0.5 % Total harmonic distortion (THD) Less than 0.5 % DC offset in AC mode < 20 mv with linear load Slew rate 8 V/µs Output voltage Netwave 20, Netwave 30, Netwave 60 Netwave 20.1, Netwave 30.1, Netwave 60.1 Output power Netwave 20.x Netwave 30.x Netwave 60.x Output current Netwave 20.x Netwave 30.x Netwave 60.x 0 V 3*300 VAC (p-n); 0 V ± 425 VDC 0 V 3*360 VAC (p-n); 0 V ± 500 VDC 22,500 VA AC, 27,000 W DC 30,000 VA AC, 36,000W DC 60,000 VA AC, 72,000 W DC 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak 33 A (RMS) continuous 66 A (RMS) short-term (max. 3 s) 250 A repetitive peak 66 A (RMS) continuous 100 A (RMS) short-term (max. 3 s) 400 A repetitive peak 48 49

ELECTROSTATIC DISCHaRGE Harmonics & Flicker Electrostatic discharges between objects can cause persistent disturbances or even destruction of sensitive electronics or controls. Dito is the most advanced ESD tester for accurate simulation of ESD pulses according to the latest standards. Its efficient battery power concept allows users to generate up to 50,000 pulses at maximum test voltage from a single battery, while standard and preprogrammed user test routines make ESD testing an easy and comfortable procedure. The ESD 30N is the state-of-the art ESD tester for all test requirements demanding more than 15 kv. Powered by the mains it also offers a built-in battery for testing without mains. Benefits like bleed-off function, sensor for temperature and rel. humidity and automatic polarity change-over are only a few to make the ESD 30N an outstanding tester. Harmonics and interharmonics are caused by modern electronic power conditioning modules used to control loads and reduce power consumption. Such most commonly non-linear modules are the source of voltage at unwanted frequencies superimposed on the supply voltage. Voltage fluctuations caused by varying load currents may influence luminance or spectral distribution of lighting systems. The impression of unsteadiness of visual sensation induced by this light stimulus is called flicker. Flicker also needs to be limited to a minimum. The DPA 500N is used for single-phase applications and the DPA 503N supports both single and 3-phase applications. ACS 500N is a single-phase and the ACS 503N a 3-phase AC source, specially designed for harmonics and flicker testing. It meets the corresponding specifications as per IEC/EN 61000-3-2 and IEC/EN 61000-3-3. It provides the perfect sinusoidal and stable voltage signal specified to give fully compliant harmonics and flicker analyses irrespective of the mains supply frequency and steadiness of the voltage. dito The ultimate ESD tester ESD 30N ESD tester up to 30 kv DPA 500N Single-phase power analyser, H&F analyser ACS 500N6 Single-phase AC voltage source up to 6 kva > Ergonomic design > Modular concept > Easy to handle Bellcore GR-1089-Core, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, IEC 61000-4-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, ISO 10605, JASO D001-94, Chrysler PF 9326, DaimlerChrysler PF-10540, Fiat 9.90110, Ford WDR 00.00EA, Renault 36.00.400/B, Renault 36.00.400/C, Toyota TSC3500G, Toyota TSC3590G, Volvo EMC requirements (1998), EN 300329 > Up to 30 kv contact & air discharge > Interchangeable discharge networks > For automotive, industrial and military applications IEC 61000-4-2, ISO 10605, SAE J1113-13, SAE J1455, BMW 600 13.0 (Part 2), BMW GS 5002 (1999), DaimlerChrysler DC-10613, DaimlerChrysler DC-10614, Mercedes AV EMV, Ford ES-XW7T-1A278-AC, GMW 3097, GMW 3097 (2001), GMW 3100, GMW 3100 (2001), Mazda MES PW 67600, Mitsubishi ES-X82010, Nissan 28401 NDS 02, Porsche, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-E, Renault 36.00.808/-F, Smart DE1005B, VW TL 824 66, MBN 10284-2:2002, Renault 36.00.808/-G > Single-phase harmonics/flicker analyser > Built-in single-phase flicker impedance > Real-time analysis using internal computer and DSP IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, IEC 61000-4-7, IEC 61000-4-15, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 300386-2, EN 61000-3-2, EN 61000-3-3, EN 61000-3-11, EN 61000-3-12, EN 61000-4-7, EN 61000-4-15, JIS C 61000-3-2 also available as ACS 500N3 3,000 VA > AC power source up to 300 V/20 A single phase > Large inrush current capability > Controlled by DPA 500N and dpa.control software IEC 61000-3-2, IEC 61000-3-3, EN 61000-3-2, EN 61000-3-3, JIS C 61000-3-2 Industry Medical Residential Broadcast ESD as per IEC 61000-4-2 Test voltage 0.5 16.5 kv Discharge Air/contact discharge Hold-on time > 5 s R/C parameter 150 pf/330 Ω Specification contact discharge 500 V to 10 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV ESD as per ISO 10605 Test voltage 0.5 16.5 kv Discharge Air/contact discharge R/C parameters 100 pf/1,500 Ω 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω ESD as per IEC 61000-4-2 and ISO 10605 Test voltage Max. 30 kv Discharge Air/contact discharge Hold-on time > 5 s Specification contact discharge 0.2 30 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV R/C parameters 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω 100 pf/1,500 Ω customized Special technical highlights - RC network values indicated on the LCD - AD or CD discharge mode indicated on the LCD - Bleed-off function to discharge the EUT - Temperature and humidity sensor included - USB or optical interface included - esd.control software - Power supply: AC (88 250 V), DC (11 16 V) - Battery mode included for several hours Input channels 2 (1 current & voltage) EUT connection 1-phase A/D converter 16 bit Class of instrument Class A as per IEC/EN 61000-4-7, ed. 2 Voltage input 10 530 Vrms Overload 4,000 V peak Input range internal 50 A peak 16 A continuous Input range external Standard delivered model max. 140 A (factory setting 2 turns 70 A) Harmonic analysis IEC/EN 61000-3-2 and IEC/EN 61000-3-12, according to IEC/EN 61000-4-7, JIS C 61000-3-2 Harmonic range 1 50th harmonic Grouping Interharmonics acc. to IEC/EN 61000-4-7, ed. 2 Display Urms, Irms, Ipeak, Upeak, P, Q, S, power factor, THD(U), THD(I), crest factor(u), crest factor(i) Flicker analysis IEC/EN 61000-3-3 and IEC/EN 61000-3-11, according to IEC/EN 61000-4-15 Flicker data P st and P lt, Vrms, dmax, dc, dt, P 50 % S, P10%S, % P3%S, P 3 % S, P1 P % 1 % S, S, P 0.1 P 0.1 %% Flicker impedance: Phase Neutral 0.24 Ω + j 0.15 Ω 0.16 Ω + j 0.10 Ω ACS 500N6 Voltage range 0 to 300 V Voltage resolution 0.025 % Output frequency 10 Hz to 80 Hz Output power 6,000 VA Output connector Safety banana-plug ACS 500N3 Voltage range 0 to 300 V Voltage resolution 0.025 % Output frequency 10 Hz to 80 Hz Output power 3,000 VA Output connector Safety banana-plug 50 51

DPA 503N 3-phase power analyser, H&F analyser ACS 503N-Series Three-phase AC voltage sources AIF 503N16 3-phase flicker impedance 16 A AIF 503N-Series 3-phase flicker impedance up to 75 A > Three-phase harmonics/flicker analyser > External three-phase flicker impedance AIF 503 > Real-time analysis using internal computer and DSP IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, IEC 61000-4-7, IEC 61000-4-15, IEC 60601-1-2:2002, EN 61000-6-1, EN 61000-6-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 300386-2, EN 61000-3-2, EN 61000-3-3, EN 61000-4-7, EN 61000-4-15, EN 61000-3-11, EN 61000-3-12 JIS C 61000-3-2 > AC power sources for three-phase up to 90 kva > Large inrush current capability > Controlled by DPA 503N and dpa.control software IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, EN 61000-3-2, EN 61000-3-3, EN 61000-3-11, EN 61000-3-12, JIS C 61000-3-2 > Flicker impedance as per IEC 60725 > For flicker analysis as per IEC 61000-3-3 > For 3-phase EUTs up to 16 A nominal current IEC 61000-3-3, IEC 61000-3-11, EN 61000-3-3, EN 61000-3-11, IEC 60725 > Flicker impedance as per IEC 60725 > For flicker analysis as per IEC 61000-3-3/-11 > Built-in Zref and Ztest IEC 61000-3-3, IEC 61000-3-11, EN 61000-3-3, EN 61000-3-11, IEC 60725 Industry Medical Residential Broadcast Input channels 6 (3 current & voltage) EUT connection 3-phase A/D converter 16 bit Class of instrument Class A as per IEC/EN 61000-4-7 ed.2 Voltage input 10 530 Vrms Overload 4,000 V peak Current input Depends on CT model used Input range Standard delivered model max. 140 A (factory setting 2 turns 70 A) Harmonic analysis IEC/EN 61000-3-2 and IEC/EN 61000-3-12, according to IEC/EN 61000-4-7, JIS C 61000-3-2 Harmonic range 1 50 th harmonic Grouping Interharmonics acc. to IEC/EN 61000-4-7, ed. 2 Display Urms, Irms, Upeak, Ipeak, P, Q, S, power factor, THD (U), THD (I), crest factor (U), crest factor (I) Flicker analysis IEC/EN 61000-3-3 and IEC/EN 61000-3-11, according to IEC/EN 61000-4-15 Flicker data P st and P lt, Vrms, dmax, dc, dt, P 50 % S, P 10 % S, P 3 % S, P 1 % S, P 0.1 % Voltage range 0 to 300 V Voltage resolution 0.025 % Output frequency 40 Hz to 80 Hz Output connector 3-phase CEE-connector Frequency resolution 0.02 Hz Frequency accuracy, stability 100 ppm Total harmonics distortion THD Less than 0.1 % Output voltage stability Better than 0.1 % Output voltage accuracy Better than 0.5 % Other models: ACS 503N16 3 x 300 V (p-n), 16,000 VA ACS 503N30 3 x 300 V (p-n), 30,000 VA ACS 503N60 3 x 300 V (p-n), 60,000 VA ACS 503N90 3 x 300 V (p-n), 90,000 VA Phase 3-phase Z ref R A = 0.24 Ω X A = 0.15 Ω R N = 0.16 Ω X N = 0.10 Ω Z test Not available Accuracy Zref, Ztest < 3 % EUT power supply Line voltage 3 400 V Line current 16 A per phase max. Line frequency 47 63 Hz Phase 3-phase Z ref R A = 0.24 Ω X A = 0.15 Ω R N = 0.16 Ω X N = 0.10 Ω Z test R A = 0.15 Ω X A = 0.15 Ω R N = 0.10 Ω X N = 0.10 Ω Accuracy Z ref, Z test < 3 % EUT power supply Line voltage 3 400 V Line frequency 47 63 Hz Other models AIF 503N32 Line current: max. 32 A per line AIF 503N63 Line current: max. 63 A per line AIF 503N75 Line current: max. 75 A per line 52 53

Components & Safety Transients The UCS 500N5/UCS 500N7 Ultra Compact Simulators are the most versatile testers for covering transient and power-fail requirements according to international (basic and generic) and product family standards, with voltage capability of up to 7 kv. In addition to the IEC 61000-4-5 standard for surge testing, they also comply to ANSI/IEEE C62.41 requirements for surge and ring wave testing. The UCS 500N7 is the most economical test solution for fully compliant immunity tests and CE marking. A built-in CDN is used for testing single-phase EUTs up to 400 V/16 A, while tests on three-phase EUTs can be performed by adding an automatically controlled external coupling network up to 690 V with max. 100 A. EM TEST supplies a large range of accessories for various applications. UCS 500N5 Compact tester for EFT/burst, surge and power fail UCS 500N7 Compact tester for EFT/burst, surge, ring wave and power fail > Small and compact all-in-one tester > IEC 61000-4-4/-5/-8/-9/-11/-29 > Built-in single-phase CDN > Testing beyond the limits, 5.5 kv EFT & 7 kv surge > Optional RWG module as per 61000-4-12 IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, EN 55024, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, ITU-T K.20, ITU-T K.41, ITU-T K.45, EN 300329 IEC 61000-4-4, IEC 61000-4-5, IEC 61000-4-8, IEC 61000-4-9, IEC 61000-4-11, IEC 61000-4-12, IEC 61000-4-29, EN 61000-6-1, EN 61000-6-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, Bellcore GR-1089-Core, ANSI/IEEE C62.41, EN 61543, IEC 61008-1, IEC 61009-1, IEEE 1547, UL 1741 Components Overview Technical Data Application Surge Telecom Surge Products UCS 500Nx VCS 500Nx VSS 500Nx TSS 500Nx TSS 500N6B Standards IEC 61000-4-5 ITU K Bellcore IEC 60950 Oscillatory OCS 500N-Series DOW Module IEC 61000-4-18 IEC 60255 Current Surge CSS 500N2 CSS 500N10 Protection devices Voltage Surge VSS 500N10.2 VSS 500N12-Series VSS 500N6 VSS 500N15.1 Solar panels, Relays and Switches Safety VSS 500N10 IEC 60065 UL 6500 IEC 60950 EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 160 V 5,000 V 8/20 µs 80 A 2,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 300 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 160 V 5,000 V 4/300 µs 4 A 125 A EFT as per IEC 61000-4-4, ed. 2 Open-circuit 200 V 5,500 V Rise time tr 5 ns Pulse duration td 50 ns Source impedance Zq = 50 Ω Surge as per IEC 61000-4-5 1.2/50 µs 250 V 7,000 V 8/20 µs 125 A 3,500 A /alternating Mag. field as per IEC 61000-4-9 100, 300, 1,000 A/m Dips as per IEC 61000-4-11 AC voltage/current Max. 300 V/16 A (P N) Inrush current More than 500 A Mag. field as per IEC 61000-4-8 1, 3, 10 and 30 A/m with MC 2630 100, 300 and 1,000 A/m with MC26100 Ring wave as per IEC 61000-4-12 0.5 µs/100 khz 6,000 V with 12 Ω and 30 Ω source impedance Telecom surge as per IEC 61000-4-5 Open-circuit 10/700 µs 250 V 7,000 V 4/300 µs 6 A 175 A 55

transients Surge pulses occur due to direct or indirect lightning strikes to an external (outdoor) circuit. This leads to currents or electromagnetic fields causing high-voltage or current transients. Another source of surge pulses is switching transients originating from switching disturbances and system faults. Due to the characteristic of the phenomenon almost every electrical and electronic device is affected by such lightning events. Surge tests should therefore be widely performed. Surge voltages can reach several thousands of volts while surge currents reach levels of several thousands of amps. UCS 500N5V Surge tester 5.0 kv VCS 500N8 Surge tester 8 kv VCS 500N10 Surge tester 10 kv VCS 500N12 Surge tester 12 kv > 5.0 kv/2.5 ka surge, IEC 61000-4-5/-9 > Testing beyond the limits, 8 kv/4 ka, IEC 61000-4-5/-9 > Still compact in size but up to 10 kv/5 ka, IEC 61000-4-5/-9 > Still compact in size but up to 12 kv/6 ka, IEC 61000-4-5/-9 > Preprogrammed standard test routines included > Built-in single-phase CDN > Built-in single or 3-phase CDN > External CDNs for power mains and I/O line applications > External CDNs for power mains and I/O line applications IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.41, ITU-T K.45 IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 Components Surge as per IEC 61000-4-5 160 V 5,000 V Wave shape as per IEC 469-1 Rise time tr 1.0 µs Pulse duration 50 µs 80 A 2,500 A Wave shape as per IEC 469-1 Rise time tr 6.4 µs Pulse duration 16 µs /alternating Output direct HV-banana connector Coupling network L N with Z = 2 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω Surge as per IEC 61000-4-5 250 V 8,000 V Wave shape as per IEC 469-1 Rise time tr 1.0 µs Pulse duration 50 µs 125 A 4,000 A Wave shape as per IEC 469-1 Rise time tr 6.4 µs Pulse duration 16 µs /alternating Output direct HV-banana connector Coupling network L N with Z = 2 Ω L-PE, N-PE, L+N-PE; Z = 12 Ω Surge as per IEC 61000-4-5 250 V 10,000 V Wave shape as per IEC 469-1 Rise time tr 1.0 µs Pulse duration 50 µs 125 A 5,000 A Wave shape as per IEC 469-1 Rise time tr 6.4 µs Pulse duration 16 µs /alternating Output direct HV-banana connector Coupling network External option Surge as per IEC 61000-4-5 500 V 12,000 V Wave shape as per IEC 469-1 Rise time tr 1.0 µs Pulse duration 50 µs 250 A 6,000 A Wave shape as per IEC 469-1 Rise time tr 6.4 µs Pulse duration 16 µs /alternating Output direct HV-banana connector Coupling network External option Em.safe Current limiter function 56 57

transients Telecommunication networks are exposed to lightning events. Therefore telecommunication equipment connected to the outside world need to have appropriate protection that demonstrates an acceptable level of immunity to surge transients. This would prevent failure during lightning events. Telecom surge simulators of the TSS 500 series are used to test the immunity of telecommunication equipment. VCS 500N7T Surge & telecom tester 7 kv TSS 500N4 Telecom surge tester 4 kv TSS 500N10 Telecom surge tester 10 kv TSS 500N6b Telecom surge tester also available as VCS 500N10T with 10 kv > IEC 61000-4-5, ITU > Compact telecom surge generator as per ITU > Extra-high voltage telecom surge generator as per ITU > Compact telecom surge generator as per GR 1089 > 7.0 kv/3.5 ka surge & 7.0 kv telecom surge 10 µs/700 µs > Built-in 1.2/50 µs & 10/700 µs transients > Up to 10 kv peak voltage > All 10/360 µs, 10/1,000 µs and 2/10 µs included > Built-in single-phase CDN > Built-in coupling network; 4 100 Ω and 2 25 Ω > Built-in coupling network; 4 100 Ω and 2 25 Ω > Built-in resistive coupling network IEC 61000-4-5, IEC 61000-4-9, EN 300329, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 300386-2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, ITU-T K.20, ITU-T K.21, ITU-T K.41, ITU-T K.45 FCC 97-270 (part 68), IEC 61000-4-5, ITU-T K.17, ITU-T K.20, ITU-T K.21, ITU-T K.28, ITU-T K.45, IEC 60950-1 FCC 97-270 (part 68), IEC 61000-4-5, ITU-T K.17, ITU-T K.20, ITU-T K.21, ITU-T K.28, ITU-T K.45, IEC 60950-1 Bellcore GR-1089-Core, ITU-T K.12, ITU-T K.28, ITU-T K.45 Components Surge as per IEC 61000-4-5 160 V 4,000 V 500 V 10,000 V First-level lightning 250 V 7,000 V Telecom surge as per ITU K Telecom surge as per ITU K Pulse 10/1,000 µs with 6 Ω > 1,000 V & 167 A per conductor Wave shape Wave shape Wave shape Rise time tr/pulse duration td < 10 µs/> 1,000 µs Rise time tr 1,0 µs Front time tf 1.2 µs Front time tf 1.2 µs Pulse 10/360 µs with 10 Ω > 1,000 V & 100 A per conductor Pulse duration 50 µs Duration td 50 µs Duration td 50 µs Rise time tr/pulse duration td < 10 µs/> 360 µs 125 A 3,500 A Pulse 10/1,000 µs with 10 Ω > 1,000 V & 100 A per conductor Wave shape Wave shape open-circuit Wave shape open-circuit Rise time tr/pulse duration td < 10 µs/> 1,000 µs Rise time tr 6.4 µs Front time tf 10 µs Front time tf 10 µs Pulse 2/10 µs with 5 Ω > 2,500 V & 500 A per conductor Pulse duration 16 µs Duration td 700 µs Duration td 700 µs Rise time tr/pulse duration td < 2 µs/> 10 µs /alternate Wave shape short-circuit current 4 100 A Wave shape short-circuit current 12.5 250 A Pulse 10/360 µs with 40 Ω > 1,000 V & 25 A per conductor Output direct HV-banana connector Rise time tr 4 µs Rise time tr 4 µs Rise time tr/pulse duration td < 10 µs/> 360 µs Coupling network L N with Z = 2 Ω Duration td 300 µs Duration td 300 µs Intra-building lightning L-PE, N-PE, L+N-PE; Z = 12 Ω Pulse 2/10 µs with 8 Ω > 2,500 V & 312 A per conductor Telecom surge 250 V 7,000 V Surge B as per FCC part 68 Surge B as per FCC part 68 Rise time tr/pulse duration td < 2 µs/> 10 µs Front time 10 µs Wave shape open-circuit Wave shape open-circuit Pulse 2/10 µs with 15 Ω > 2,500 V & 167 A per conductor Pulse duration 700 µs Front time tf 9 µs Front time tf 9 µs Rise time tr/pulse duration td < 2 µs/> 10 µs 6.0 175 A Duration td 720 µs Duration td 720 µs Second-level lightning Rise time tr 4 µs Wave shape short-circuit current 4 100 A Wave shape short-circuit current 12.5 250 A Pulse 2/10 µs with 10 Ω > 5,000 V & 500 A per conductor Pulse duration 300 µs Rise time tr 5 µs Rise time tr 5 µs Rise time tr/pulse duration td < 2 µs/> 10 µs Duration td 320 µs Duration td 320 µs DUT supply 60 V/50 A 1 µs 10 µs VCS 500N10T 500 V 10,000 V 58 59

transients Current Surge The OCS 500N6 is used for ring wave testing up to 6 kv, slow damped oscillatory wave testing (100 khz and 1 MHz) up to 3 kv, and optional fast damped oscillatory wave at 3, 10, and 30 MHz. A ring wave is a non-repetitive damped oscillatory transient occurring in low-voltage power, control and signal lines supplied by public and non-public networks. Damped oscillatory waves are repetitive transients occurring mainly in power, control and signal cables installed in high-voltage and medium-voltage stations. The OCS 500N6 can also be used to perform magnetic field tests as required in IEC 61000-4-10 using a magnetic field coil such as the MS 100. Surge pulses occur due to direct or indirect lightning strikes to an external (outdoor) circuit. This leads to currents or electromagnetic fields causing high-voltage or current transients. Another source of surge pulses is switching transients originating from switching disturbances and system faults. Due to the characteristic of the phenomenon almost every electrical and electronic device is affected by such lightning events. Surge tests should therefore be widely performed also on component level. OCS 500N-series Compact tester for ring wave and damped oscillatory waves DOW Module Fast damped oscillatory wave option for OCS 500N6-Series CSS 500N2 Current surge tester CSS 500N10 Current surge tester also available as 1 or 3-Phase Version up to 32 A also available as CSS 500N10.1 4 ka 10/350 μs > 100 khz ring wave & 100 khz/1 MHz damped oscillatory > Fast Damped Oscillatory Wave 3/10/30 MHz > Current surge generator 8/20 µs > Current surge generator 8/20 µs > Conducted immunity and magnetic field test > Low current ranges to test SMD protection devices > High current capability up to 10 ka (4 ka 10/350 µs) > Built-in coupling network > EUT test box available > Voltage/current measurement included ANSI/IEEE C37.90, ANSI/IEEE C62.41, IEC 60255-1, IEC 61000-4-10, IEC 61000-4-12, IEC 61000-4-18, IEEE 1547 IEC 61000-4-18 Components TECHNICAL DATA (OVERVIEW) Damped oscillatory as per IEC 61000-4-18 Output voltage open-circuit 250 V 3,000 V +/- 10 % Rise time/oscillation frequency 1/T 75 ns/100 khz and 1 MHz Decaying Peak 5 must be > 50 % of peak 1 value Peak 10 must be < 50 % of peak 1 value Source impedance 200 Ω Repetition rate 40/s for 100 khz and 400/s for 1 MHz Direct output at the front panel For ext CDN & magn. field antenna Coupling network 1-phase or 3-phase Damped oscillatory magnetic field as per IEC 61000-4-10 MS 100 (square 1 m 1 m) antenna Ring wave as per IEC 61000-4-12 Output voltage open-circuit 250 V 6,000 V Rise time first peak T1/Oscillation frequency 0.5 µs/100 khz Decaying of Pk1 to Pk2 40 % 110 % Decaying of Pk2 to Pk3 & decaying of Pk3 to Pk4 40 % 80 % Output impedance 12 Ω, 30 Ω (200 Ω external) Wave shape short-circuit Rise time first peak tr T1 < 1 µs Oscillation frequency 1/T 100 khz Fast Damped oscillatory IEC 61000-4-18 Output voltage open-circuit 450 V 4,400 V +/- 10 % Rise time voltage waveform 5 ns +/- 30 % Oscillation frequency 3 MHz, 10 MHz, 30 MHz, +/- 10 % Decaying voltage waveform Peak 5 must be > 50 % of peak 1 Source impedance 50 Ω +/- 20 % Peak 10 must be < 50 % of peak 1 Repetition rate Max. 5000/s +/- 10 % Burst duration 50 ms +/- 20 %, at 3 MHz 15 ms +/- 20 %, at 10 MHz 5 ms +/- 20 %, at 30 MHz Burst period 300 ms +/- 20 % Short circuit current 9A 88 A +/- 20 % Rise time current waveform At 3 MHz: < 330 ns At 10 MHz: < 100 ns At 30 MHz: < 33 ns Decaying current waveform Peak 5 must be > 25 % of peak 1 Peak 10 must be < 25 % of peak 1 Charging voltage 100 2,500 V 1,200 A Range I 1 18 A Range II 6 140 A Range III 40 1,200 A Wave shape Rise time tr 8.0 µs Pulse duration 20 µs /alternating Output direct HV-connector HV test clamp EUT test box Other waveforms on request Model CSS 500N10 Charging voltage 250 6,000 V 10,000 A Wave shape Rise time tr 8.0 µs Pulse duration 20 µs /alternating Output direct HV-banana connector EUT test box Model CSS 500N10.1 Charging voltage 300 5,000 V 4,000 A Wave shape Rise time tr 10 µs Pulse duration 350 µs /alternating Output direct HV-banana connector EUT test box Other waveforms on request 60 61

voltage surge and Safety The voltage surge simulators VSS 500N generate high-voltage transients as required by several IEC standards. The voltage surge pulses are used to test the isolation (voltage withstand) capability of components, sockets, connectors, cables and many other items. As per safety test requirements the insulation between accessible parts or parts connected to them and hazardous live parts must be able to withstand surges due to transients caused, e.g. by thunderstorms and entering the apparatus through the antenna terminal. The voltage surge simulator VSS 500N10 generates high-voltage transients as required by IEC 60065 and UL 6500 standards for safety tests on audio, video and similar electronic apparatus. VSS 500N12-Series Voltage surge simulation VSS 500N10 VSS 500N6 VSS 500N10.3 Voltage surge simulation Surge tester 6 kv for safety testing of Protection Relays Surge tester 10 kv for solar panel testing also available as VSS 500N6.2 with reduced voltage also available as VSS 500N15.1 with 15 kv > Testing equipment for safety testing up to 12 kv > Testing equipment safety up to 10 kv > Compact in size > 7 load ranges from 10 nf to 180 nf > Internal 40 Ω or 500 Ω resistor for current limiting > Special pulse-shaping network > Constant energy IEC 60060, IEC 384-14, IEC 664, IEC 60335 IEC 60065, UL 6500, IEC 60950 IEC 60255-5 IEC 61730-1, IEC 61730-2, IEC 60060, UL 1703 Components VSS 500N12 500 V 12,000 V Rise time tr 1.2 µs Pulse duration 50 µs Internal resistor 500 Ω /alternating VSS 500N12.1 500 V 12,000 V Rise time tr 1.2 µs Pulse duration 50 µs Internal resistor 40 Ω /alternating VSS 500N6.2 500 V 6,000 V Rise time tr 1.2 µs Pulse duration 50 µs Internal resistor 500 Ω /alternating Rise time tr Pulse duration Internal resistor 500 V 10,000 V < 100 ns > 2 ms 1,000 Ω Positive Surge as per IEC 60255-5 500 V 6,600 V Wave shape Rise time tr 1.2 µs Pulse duration 50 µs Internal impedance 500 Ω Energy 0.5 J at each test level Test level 0.55 kv 0.9 kv 3.0 kv 5.0 kv 6.6 kv /alternate Output direct HV-banana connector VSS 500N15.1 500 V 15,000 V Testlevel 0.55 kv 0.9 kv 3.0 kv 5.0 kv 6.6 kv 9.3 kv 14 kv Surge as per IEC 60255-5 500 V 10,000 V Wave shape Front time tr 1.2 µs Time to half value 50 µs Load capacitance ranges 30 nf 40 nf 40 nf 50 nf 50 nf 65 nf 65 nf 85 nf 85 nf 110 nf 110 nf 140 nf 140 nf 180 nf /alternating Output direct HV-banana connector 62 63

Aircraft Military SIMULATION OF AC AND DC SUPPLY ANOMALIES NetWave is an AC/DC power source, specifically designed to meet the requirements as per IEC/EN 61000-4-13, IEC/EN 61000-4-14, IEC/EN 61000-4-17, IEC/EN 61000-4-28. Its output power with low distortion and high stability, even if supplying dynamic loads, guarantees full compliant measurements for harmonics and flicker as per IEC/EN 61000-3-2, JIS C 61000-3-2 and IEC/EN 61000-3-3 as well as per IEC/EN 61000-3-11 and IEC/EN 61000-3-12. The three-phase Netwave models additionally support testing as per IEC/EN 61000-4-27. NETWAVE-Series SINGLE Phase Multifunction AC/DC Power Source NETWAVE-Series Three Phase Multifunction AC/DC Power Source > Wide power bandwidth; DC 5 khz > High inrush current capability > Built-in arbitrary waveform generator, 16 Bit > Wide power bandwidth; DC 5 khz > High inrush current capability > Built-in arbitrary waveform generator, 16 Bit IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing IEC 61000-4-13, IEC 61000-4-14, IEC 61000-4-17, IEC 61000-4-27, IEC 61000-4-28, IEC 61000-4-29, IEC 61000-3-2, IEC 61000-3-3, IEC 61000-3-11, IEC 61000-3-12, JIS C 61000-3-2, MIL-STD 704, RTCA/DO 160 Section 16, Airbus, Boeing Overview Technical Data - SINGLE Phase Technical Data - Three Phase Application Power Mains Supply Simulation Conducted Immunity Radiated Immunity Electrostatic Discharge Output voltage Netwave 3, Netwave 7 Netwave 7.2 Output power 0 V 300 VAC (p-n); 0 V ± 425 VDC 0 V 360 VAC (p-n); 0 V ± 500 VDC Output voltage Netwave 20, Netwave 30, Netwave 60 Netwave 20.1, Netwave 30.1, 0 V 3*300 VAC (p-n); 0 V ± 425 VDC 0 V 3*360 VAC (p-n); 0 V ± 500 VDC Military Aircraft Products NetWave-Series Single Phase Netwave-Series Three Phase AutoWave VDS 200N-Series CWS 500N3 CWS 500N2 CWS 500N3 CWS 500N2 dito ESD 30N Netwave 3 Netwave 7, Netwave 7.2 Output current Netwave 3 AC mode: 3,500 VA, DC mode: 4,500 W AC mode: 7,500 VA, DC mode: 9,000 W 12 A (RMS) continuous 21 A (RMS) short-term (max. 3 s) 100 A repetitive peak Netwave 60.1 Output power Netwave 20.x Netwave 30.x Netwave 60.x Output current 22,500 VA AC, 27,000 W DC 30,000 VA AC, 36,000 W DC 60,000 VA AC, 72,000 W DC Standards DO 160, Sec. 16 MIL-STD-704 Boeing Airbus MIL STD 461 DO 160 MIL STD 461 DO 160 MIL STD 461 DO 160 Netwave 7, Netwave 7.2 Output frequency Frequency accuracy, stability 26 A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak DC 5,000 Hz 100 ppm Netwave 20.x Netwave 30.x 26A (RMS) continuous 47 A (RMS) short-term (max. 3 s) 200 A repetitive peak 33 A (RMS) continuous 66 A (RMS) short-term (max. 3s) Output voltage stability Better than 0.1 % 250 A repetitive peak Output voltage accuracy Better than 0.5 % Netwave 60.x 66 A (RMS) continuous Total harmonic distortion (THD) Less than 0.5 % 100 A (RMS) short-term (max. 3 s) DC offset in AC mode < 20 mv with linear load 400 A repetitive peak Slew rate 8 V/µs 65

battery simulation Conducted and radiated immunity AutoWave is used for the following applications: > Generation of all kinds of voltage profiles via software > Replay of imported data or plot files, record & play > Recording voltage variations in the actual vehicle > replaying the measured data via a suitable DC source or amplifier > Analysis of recorded voltages and currents > Export of measured data to other software tools The AMP 200N series is a low-frequency signal source that generates sinusoidal signals used for simulating ripple noise and ground shift noise required by a variety of automotive standards, e.g. Ford EMC-CS-2009.1, CI 210, CI 250 and RI 150. Additionally, the AMP 200N can be used to generate magnetic fields by means of a radiation loop or small Helmholtz coils as per RI 140 of Ford EMC-CS-2009.1 Contolled by the AutoWave a large number of different standard requirements can be covered. Bulk Current Injection (BCI) is a test procedure to test immunity to electrical disturbances caused by narrowband electromagnetic energy. The test signal is injected by means of a current injection probe. In physical terms the current injection probe is a current transformer laid around the wiring harness. Immunity tests are performed varying the level and the frequency of the injected test signal. The BCI test method is widely known in the automotive industry as well as in the military/aircraft industry to test single components of a complex system. The CWS 500N3 is a state-of-the-art solution in a compact one-box design to test immunity to conducted audio frequency disturbances and low-frequency magnetic fields. The CWS 500N3 includes signal generator, LF amplifier, coupling transformer, frequency selective current and voltage monitor, software and GPIB interface. The icd.control-software supports the test routines, controls external measuring devices and automatically generates test reports with all test data included. autowave Signal generator and recorder AMP 200N-Series Low-frequency signal source for supply simulation and magnetic field testing cws 500N2 Bulk Current Injection (BCI) testing CWS 500N3 Audio frequency and magnetic field testing > Simulation + measuring + analysing > Built-in DDS to generate sinusoidal signals up to 250 khz > Bulk current injection as per MIL 461E > Conducted & radiated immunity up to 250 khz > 16 bit resolution, 80 GByte hard disk memory > Built-in LF amplifier, 250 W or 800 W > 9 khz to 400 MHz, 100 W (expandable up to 1 GHz) > Built-in voltage/current measurement > Simultaneous record & play function > Output voltage max. 150 V p-p > System solution is fully designed and supported by EM TEST > Built-in coupling transformer 1 : 2 DO 160 section 16 requirements Chrysler DC-10615, DC-11224, CS-11809, CS-11979, DaimlerChrysler DC-10614, DC-10615, DC-11224, Fiat 9.90110, Fiat 9.90111, Ford ES-XW7T-1A278-AC, Ford EMC CS-2009.1 GM 3097, ISO 11452-8, ISO 11452-10, IVECO 16-2119, Jaguar/ LandRover EMC-CS-2010JLR, Mitsubishi ES-X82114, ES-X82115, MBN 10284-2, NISSAN 28401 NDS02, PSA B21 7110, Renault 36.00.808/--G, --H, --J, --K, --L, SAE J1113-2, SAE J1113-22, TATA Motors TST/TS/WI/257, Volkswagen TL 825 66, Volvo STD 515-0003, Germanischer Lloyd GL VI 7-2, DO-160E/F/G, MIL-STD-461E/F IEC 61000-4-6, EN 61000-6-1, EN 61000-6-2, IEC 60601-1-2:2002, ISO 11452-4, ISO 11452-5, DaimlerChrysler DC-10614, Ford ES-XW7T-1A278-AB, Ford ESXW7T-1A278-AC, GMW 3097 (2001), GMW 3097 (2004), MBN 10284-2:2002, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-G, MIL STD 461D/CS 114, MIL STD 461E/CS 114, RTCA/DO 160 Section 20, Fiat 9.90110 ISO 11452-8, ISO 11452-10, vehicle manufacturer specifications, SAE J1113, MIL-STD 461 Wave generation 2 output channels standard 4 output channels optional Output range ±10 V/50 Resolution 16 bit Frequency range DC 50 khz Sample rate up to 500 khz Waveform segments DC voltage, sine wave, sine wave sweep, Sine ramped, square wave, triangular Wave, saw-tooth wave, ramp up/down, Exponential wave, etc. Functions Iteration of up to 12 parameters per level, up to 9 levels Rseudo-random distribution of parameters Wave recorder 2-channel measuring input Input range ±5 V, 10 V, 20 V, 50 V, 100 V Amplifier output characteristics Frequency range DC 250 khz Signal power 250 W (nominal) or 800 W (nominal) Output voltage 50 V rms, max. 150 V p-p Output current Max. 5 A rms or max. 16 A rms Harmonic Distortion (THD) < 0.1 % Current protection Short circuit protected Overvoltage protection For voltages > 20 V fed back by the DUT Signal generator output characteristics Frequency range DC, 10 Hz 250 khz (sinusoidal) Output voltage ± 10 V DC offset 0-10 V, programmable, to control ext. DC amp. Measurement Frequency-selective voltage current measurement (rms) Accessories Radiation Loop 120 mm radiation loop for magnetic field testing as per Ford EMC-CS-2009.1, RI 140 Loop Sensor To measure the magnetic field strength CN 200N1 Transformer assembly with built-in 0.5 Ω / 250 W resistive load as per Ford EMC-CS-2009.1 BCI method MIL 461E, CS114 Output power 100 W (nominal) Output impedance 50 Ω Max. VSWR 1 : 2.0 Output level -13 dbm 50 dbm Frequency range 9 khz 400 MHz (1,000 MHz) Modulation AM 1 3,000 Hz, 1 99 % depth PM 1 3,000 Hz Duty cycle 10 % 80 % Harmonic distortion > 20 dbc Output N-connector Built-in power meter Channel 1 forward power Channel 2 reverse power Channel 3 injected current Built-in coupler Max 200 W/1 GHz Test method Closed loop Built-in RF switch Automatic commutation to an external amplifier Conducted immunity MIL STD 461 Output level 0.001 V max. 6.5 Vrms Output current Max. 15 A Frequency range 10 Hz to 250 khz Output power nominal 100 W Output power peak 400 W Output impedance < 0.5 Ω Harmonic distortion > 20 dbc at max. power Coupling Audio transformer included Measurements Freq. selective voltage/current meter Verification load 0.5 Ω & 4 Ω included Radiated immunity MIL STD 461 Magnetic field Max. 1,000 A/m up to 1 khz Frequency range 15 Hz to 150 khz Radiating loop As per MIL STD 461 Magnetic field sensor As per MIL STD 461 Current sensor Included Military Aircraft 66 67

ELECTROSTATIC DISCHaRGE Electrostatic discharges between objects can cause persistent disturbances or even destruction of sensitive electronics or controls. Dito is the most advanced ESD tester for accurate simulation of ESD pulses according to the latest standards. Its efficient battery power concept allows users to generate up to 50,000 pulses at maximum test voltage from a single battery. while standard and pre-programmed user test routines make ESD testing an easy and comfortable procedure. dito The ultimate ESD tester The ESD 30N is the state-of-the art ESD tester for all test requirements demanding more than 15 kv. Powered by the mains it also offers a built-in battery for testing without mains. Benefits like bleed-off function, sensor for temperature and rel. humidity and automatic polarity change-over are only a few to make the ESD 30N an outstanding tester. ESD 30N ESD tester up to 30 kv download the complete technical data: > Ergonomic design > Modular concept > Easy to handle Bellcore GR-1089-Core, EN 300340, EN 300342-1, EN 300386 V1.3.2, EN 301489-1, EN 301489-7, EN 301489-17, EN 301489-24, EN 55024, IEC 61000-4-2, ITU-T K.20, ITU-T K.21, ITU-T K.45, ISO 10605, JASO D001-94, Chrysler PF 9326, DaimlerChrysler PF-10540, Fiat 9.90110, Ford WDR 00.00EA, Renault 36.00.400/B, Renault 36.00.400/C, Toyota TSC3500G, Toyota TSC3590G, Volvo EMC requirements (1998), EN 300329 > Up to 30 kv contact & air discharge > Interchangeable discharge networks > For automotive, industrial and military applications IEC 61000-4-2, ISO 10605, SAE J1113-13, SAE J1455, BMW 600 13.0 (Part 2), BMW GS 5002 (1999), DaimlerChrysler DC-10613, DaimlerChrysler DC-10614, Mercedes AV EMV, Ford ES-XW7T-1A278-AB, GMW 3097, GMW 3097 (2001), GMW 3100, GMW 3100 (2001), Mazda MES PW 67600, Mitsubishi ES-X82010, Nissan 28401 NDS 02, Porsche, PSA B21 7110, Renault 36.00.808/-D, Renault 36.00.808/-E, Renault 36.00.808/-F, Smart DE1005B, VW TL 824 66, MBN 10284-2:2002, Renault 36.00.808/-G www.emtest.com ESD as per IEC 61000-4-2 Test voltage 0.5 16.5 kv Discharge Air/contact discharge Hold-on time > 5 s R/C parameter 150 pf/330 Ω Specification contact discharge 500 V to 10 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV ESD as per ISO 10605 Test voltage 0.5 16.5 kv Discharge Air/contact discharge R/C parameters 100 pf/1,500 Ω 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω ESD as per IEC 61000-4-2 and ISO 10605 Test voltage Max. 30 kv Discharge Air/contact discharge Hold-on time > 5 s Specification contact discharge 0.2 30 kv Rise time tr 0.8 ns ± 25 % Peak of discharge currents 3.75 A/kV R/C parameters 150 pf/330 Ω 330 pf/330 Ω 150 pf/2,000 Ω 330 pf/2,000 Ω 100 pf/1,500 Ω customized Special technical highlights - RC network values indicated on the LCD - AD or CD discharge mode indicated on the LCD - Bleed-off function to discharge the EUT - Temperature and humidity sensor included - USB or optical interface included - esd.control software - Power supply: AC (88 250 V), DC (11 16 V) - Battery mode included for several hours Military Aircraft 68

Accessories CNI 501/503 Combined coupling/decoupling networks for burst and surge CNI 501/CNI 503 CNI 508N1 ASSEMBLY Coupling/decoupling assembly for unshielded and shielded high-speed communication lines up to 1 GBIT/s > Connection to: UCS 500 Nx, EFT 500 Nx, VCS 500 Nx The coupling network is the central connection point in a fully automatic test set-up. With the coupling networks type CNI 501/503, burst and surge pulses as well as voltage dips and voltage variations are coupled onto the selected supply lines. > Connection to: UCS 500 Nx, VCS 500 Nx CDN for coupling surge onto unshielded and shielded high speed communication lines for data rates up to 1,000 Mbit/s. Protection equipment limits residual voltage at the AE side. Surge, ring wave and Burst pulses can also be applied on shielded lines. CNV 504/8N.X / CNV 504/8S1 Coupling/decoupling networks for signal/data and telecom lines CNV 501/503 Coupling/decoupling networks CNV 501/CNV 503 for surge Accessories > Connection to: UCS 500 Nx, VCS 500 Nx The coupling networks CNV 504/508 are used to superimpose the surge pulse onto signal and data lines as well as onto telecommunication lines. > Connection to: UCS 500 Nx, VCS 500 Nx The coupling network is the central connection point in a fully automatic test set-up. With the coupling networks type CNV 501/503, surge pulses are coupled onto the selected supply lines. 71

MV3P40xxDS 3-phase motor variac for Delta-Star tests. For tests according to IEC/EN 61000-4-11 and IEC/EN 61000-4-34 MV26xx Motor variac type MV26xx for tests according to IEC/EN 61000-4-11 V4780/V4780S2 Tap-off transformer type V4780 for tests according to IEC/EN 61000-4-11 RDS 200/RDS 200S1 Ford ES-XW7T.../EMC-CS-2009, CI 230 > Connection to: PFS 503 Nx > Connection to: UCS 500 Nx, PFS 503 Nx > Connection to: UCS 500 Nx > Connection to: PFS 200 Nx, AutoWave The motor variac is used for adjusting the required dip voltage and voltage variation continuously. For 3-phase applications the variac can be used for STAR and DELTA powered EUTs as well. The motor variac is used for adjusting the required dip voltage and voltage variation continuously. The V4780 is a tap-off transformer to achieve the fixed 40 %, 70 % and 80 % dip levels. This unit is also available as a remote-controlled model V4780S2. RDS 200 is a remote-controlled DC voltage source with a built-in current sink and is used to generate battery supply variations. It is controlled via the 0 10 V DC analogue signal from the PFS 200N for voltage dips or by an arbitrary generator to generate signals, e.g. as required by Ford s CI 230 specification. MS 100N Magnetic field test antenna according to IEC/EN 61000-4-8 Ed. 2:2009 and IEC/EN 61000-9 MV2606N2.2 Motor variac for tests according to IEC/EN 61000-4-16 galvanically isolated ACS 500N2.3 Single-phase AC/DC voltage source 2 kva for tests according to IEC/EN 61000-4-16 galvanically isolated CDN 16-T2 / CN 16-L2/L3/L4/L8 360 degrees rotatable coil Accessories > Connection to: UCS 500 Nx, PFS 503 Nx, VCS 500 Nx OCS 500N > Connection to: CWS 500 N4 > Connection to: CWS 500N4 > Connection to: CWS 500N4 Type MS 100N: > 4 cm 2 cross-section as per IEC 61000-4-8 Ed.2:2009 > 100 A/m continuous, 1,000 A/m short term > Pulses up to 3,200 A/m > On request also available with wheels The motor variac is specifically designed for conducted lowfrequency tests according to IEC/EN 61000-4-16. Supports tests at present supply frequency. ACS 500N2.3 is an electronic AC source, specifically designed for conducted low-frequency tests according IEC/EN 61000-4-16. Supports tests at various supply frequencies. Coupling/decoupling networks for communication ports and signal/datalines as well as AC/DC power supply lines according to IEC 61000-4-16 72 73

CDNs AND clamps Coupling/decoupling networks according IEC 61000-4-6 Injection and monitoring probes F-130A-1, F-140, F-120-6A, F-120-9A, F-33-2, F-55, F-65 CTR2 CTR2-AD > Connection to: CWS 500N1, CWS 500 N2 > Connection to: CWS 500N1, CWS 500 N2 > Connection to: ESD 30 N, dito > Connection to: ESD 30 N, dito > Suitable calibration adapters for all available CDNs > Coupling clamp (EM clamp) > Current injection > T-50, 50 Ώ termination resistor > R-100N, 150 Ώ to 50 Ώ adapter > Current injection probes > Calibration jigs > Matching impedance and termination resistors The CTR2 is a coaxial current target designed to monitor electro-static discharges as required in IEC 61000-4-2. The CTR2-AD is a conical adapter to connect the CTR2 into a 50 Ω measuring system for verification. Radiating Loop Loop Sensor CA PFS Verification kit for power fail simulators acc. to IEC 61000-4-11 CA ISO Accessories > Connection to: CWS 500 N3 > Connection to: CWS 500 N3 > Connection to: UCS 500 Nx, PFS 503 Nx > Connection to: UCS 200 N, LD 200 Nx, LD 200 Sx Radiating loop as per MIL-STD 461 to generate magnetic fields. Loop sensor as per MIL 461 to measure magnetic fields. > Built-in 1,700 μf capacitor and discharge resistor > Built-in current probe 10 mv/a > Monitor output to measure residual capacitor voltage A different set of resistors is used for the verification of transient generators as per ISO 7637-2. The generator output is measured under matched load conditions which means R I = RL. 74 75

HFK Coupling clamp according to IEC/EN 61000-4-4 ACC EAS 30 Capacitive coupling clamp according to ISO 7637-3 Earth grounding resistor acc. to IEC 61000-4-2 > Connection to: UCS 500 Nx, EFT 500 Nx > Connection to: UCS 200N > Connection to: ESD 30 N, dito The capacitive coupling clamp is used to couple the burst pulses onto control and data lines. The capacitive coupling clamp is used to couple pulses 1, 2 and 3a + 3b onto control and data lines. The EAS 30 is necessary for the test set-up according to the relevant standard to connect the HCP and the VCP to the Ground Reference Plane. ITP, ITP/H Immunity test probes for pre-compliance tests acc. to IEC 61000-4-3 VCP Vertical coupling plane acc. to IEC 61000-4-2 ca eft Calibration set acc. to IEC/EN 61000-4-4, ed. 2 Accessories > Connection to: UCS 200 N, UCS 500 Nx, EFT 500 Nx > Connection to: ESD 30N, dito > Connection to: UCS 200 N, UCS 500 Nx, EFT 500 Nx Generates electrical and magnetic fields. Set includes different test probes. The test probes can be connected to the above-listed generators for burst application. These test probes allow preliminary testing acc. to IEC 61000-4-3 during development. The VCP is used to subject the DUT to discharge indirectly. The 10 cm clearing distance to the DUT is obtained by the wooden support. The pulse shape of EFT/burst generators designed as per IEC 61000-4-4 has to be verified at 50 Ω as well at 1,000 Ω load. Both matching resistors additionally include a voltage divider to measure the wave form. 76 77

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EM TEST SERVICES: CUSTOMIZED SOLUTIONS FOR EVERY NEED. Service & Support: ALWAYS AVAILABLE COMPREHENSIVE SERVICE PORTFOLIO Our comprehensive professional service and support solutions leave nothing to be desired. Commissioning, briefings, updates, maintenance, and repair work are given high priority at EM TEST. Thanks to the outstanding infrastructure, an optimum service project management, and especially thanks to our highly qualified and motivated employees, we literally achieve the highest level of EM TEST service quality. EMC TEST LAB: YOUR PRODUCT SUCCESS IS OUR MISSION PROFESSIONAL SUPPORT RIGHT FROM THE Beginning EM TEST assists you already on the development phase of your products with technical coaching and tangible measures such as layout optimization, design of devices and power supplys, grounding and shielding, microprocessor board design, and much more. Not only do we determine the interference potentials but we also simultaneously develop suitable interference suppression and elimination measures in cooperation with you, our customer. ACCREDITED CALIBRATION LABS: ABSOLUTE COMPLIANCE REPRODUCIBLE, FAST & COMPETENT Accredited Laboratories The accredited EM TEST calibration laboratories in Reinach (CH) and Kamen (D) perform competent, independent and reasonably priced calibrations according to DIN EN ISO/IEC 17025 as well as national and international standards. And not just for EM TEST products, but also for equipment from other manufacturers. And if you like also on site. C onfid ence for sure! EMC SEMINARS & WORKSHOPS: success Can be learned EMC-knowledge for beginners und professionals Our EMC seminars and workshops are geared to our customer s requirements in the fields of research, development and production. All EM TEST lecturers come exclusively from the practice and impart their knowlegde vividly and up close and personal manner to the participants. Maximum know-how transfer and learning success are guaranteed. Extended warranty: Quasi for free More warranty? With pleasure. Calibrations of EM TEST offer more. Your EM TEST product will be checked on request and if necessary adjusted immediately. We are so convinced of the quality of your products that the warranty time can be extended to 3 years by having calibrated the equipment at any of the accredited calibration laboratories of EM TEST during the 2-year warranty period. Hence, you ll get 1 year warranty almost for free. RENTAL EQUIPMENT: READY FOR EVERY TESTING DEMAND ALWAYS THE RIGHT TESTING INSTRUMENT Bridge long-term planned investments by renting the equipment you need for as long as you need it at EM TEST. We have a large pool of rental equipment, which is not only state of the art, but moreover fully compliant with all EMC testing requirements. With rental equipment from EM TEST, you can respond promptly and flexibly to unexpected testing demands. Quickly and economically! EM TEST Services 80 81

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