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TIME-DOMAIN MEASUREMENT SYSTEM FOR IMPULSE NOISE CHARACTERIZATION Salvador Verdaguer Ferran Silva Electromagnetic Compatibility Group (GCEM). Technical.

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Presentation on theme: "TIME-DOMAIN MEASUREMENT SYSTEM FOR IMPULSE NOISE CHARACTERIZATION Salvador Verdaguer Ferran Silva Electromagnetic Compatibility Group (GCEM). Technical."— Presentation transcript:

1 TIME-DOMAIN MEASUREMENT SYSTEM FOR IMPULSE NOISE CHARACTERIZATION Salvador Verdaguer Ferran Silva Electromagnetic Compatibility Group (GCEM). Technical University of Catalonia (UPC) Campus Nord, Edifici C4. c/ Jordi Girona 1-3. 08034 Barcelona SPAIN salva@eel.upc.essalva@eel.upc.es

2 1.-Transient phenomena: measurement challenge 2.-First option: spectrum analyzers and EMI receivers 4.-Second option: wideband digital oscilloscopes 5.-Proposed solution: a hybrid architecture 6.-Signal path in frequency domain 9.-Real-transient measurements 10.-Conclusions Index

3 Transient phenomena Transient measurement and characterization is necessary to determine the effect of impulsive interferences on new electronic systems

4 High frequency Short duration Low level Transient characteristics Which is the most suitable equipment to measure them ?

5 ● Broad frequency range ● High sensitivity ● Wide dynamic range Spectrum Analyzers and EMI Receivers Frequency sweep operation: Too slow Does not provide time information Trigger system usually asynchronous Zero-span operation: # Samples limited to # points on screen e.g.: RBW = 1 MHz  f S = 2 MHz 250 μs on a 500-point screen Real spectrum Measured spectrum

6 ● Frequency range > 3 GHz ● Sample memory > 32 MB ● Versatile trigger ● Measurement accurate in amplitude and phase Wideband Digital Oscilloscopes Large bandwidth used in measurement process  higher noise level 8-bit ADC  narrow dynamic range A/D f High sampling frequencies  €€€ e.g.: f S = 5 GHz needed for 2,4 GHz ISM band

7 Spectrum analyzer or EMI receiver Proposed solution Acquisition System (digitizer board) Frequency-domain stage  High frequency  High sensitivity Time-domain stage  Large dynamic range > 10 bit  Deep sample memory > 32 MB

8 Proposed solution: general architecture 9 kHz – 3 GHz RBW  1 MHz ADC 14 bit 32 MB 64 MS/s Trigger stage IF OUTPUT R&S ESPI3 in Zero span mode NI PXI 5620

9 Signal path in frequency domain f f f f CF RBW = 1 MHz Zero span output IF output Digitizer system output 250 μs on-screen IF = 20,4 MHz >1 second captured

10 Real-transient measurement 2 m CF = 50 MHz RBW = 1 MHz Relay spark

11 Real-transient measurement 1 MHz BW centered at 100 MHz FM radio broadcast waveforms 82 dBuV/m 86 dBuV/m 4.4 kV ESD Transient in time domain

12 Real-transient measurement Clean RF band, no waveforms present 88 dBuV/m 4.4 kV ESD 1 MHz BW centered at 130 MHz Transient in time domain

13 Real-transient measurement 4.4 kV ESD Quiet GSM channel 34 dBuV/m 54 dBuV/m 1 MHz BW centered at 1803 MHz Transient in time domain

14 Real-transient measurement GSM Incoming call Signal seek in frequency domain: 100 MHz Span, MAX Hold 1803 MHz GSM channel

15 Real-transient measurement GSM Incoming call Time-domain 100 ms capture Time-domain 1,2 ms capture 48 dBuV/m 52 dBuV/m 1803 MHz GSM channel

16 Electronics production plant measurement Component insertion machines Rolling line: 30 m x 5 m

17 Electronics production plant measurement 3 frequency bands were considered: 150 MHz 433 MHz 2,4 GHz

18 Electronics production plant measurement 150 MHz band Frequency measurement 1 minute MAX hold step 1

19 Electronics production plant measurement 150 MHz band Time measurement 26 transients/minute 78 dBuV/m step 2

20 Electronics production plant measurement 433 MHz band Frequency measurement 1 min MAX hold step 1

21 Electronics production plant measurement 433 MHz band Time measurement 29 transients/minute 82 dBuV/m step 2

22 Electronics production plant measurement 2,4 GHz band Frequency measurement 1 min MAX hold step 1

23 Electronics production plant measurement 2,4 GHz band Time measurement 30 dBuV/m step 2

24 Measurement system based on external digitizing of spectrum analyzer or EMI receiver IF output Conclusions Allows time-domain measurement of signals Provide new uses to instruments already available in a typical EMC lab Can be used as a tool to study transient noise environments High frequency Non-periodic Low level

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