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Beam Secondary Shower Acquisition System: Cables Measurements Student Meeting Jose Luis Sirvent PhD. Student 22/07/2013
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1. Cable measurements campaign. 1 st Experiment layout: – Frequency Response (Bode Plot ‘Magnitude’) – Phase displacement (Bode Plot ‘Angle’) LeCroy Scope Adapters BNC-N BNC Ch1 50 ohm Splitter N-2xBNC 50 ohm Loop (double Female) N-Connector 10 ns 8 ns Func. Generator BNC Ch2 50 ohm CK50 2 x 88 m = 176m
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1. Cable measurements campaign. 1 st Experiment : – Frequency Response (Bode Plot ‘Magnitude’) Measuring the ratio V2rms/V1rms at different frequencies
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1. Cable measurements campaign. Very good agreement Pspice model: Fits well with 176m!! Analitical functions: Where : C(l), L(l) and Rac(l,f), Gac(l,f) Values of Rac and Gac have been calculated from: http://issues.cern.ch/browse/BIWS-422
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1. Cable measurements campaign. 2 nd Experiment layout: – Pulse distortion (Integrator effect) – Step response (Low-pass filter) LeCroy Scope Adapters SMA-N SMA-BNC Ch1 50 ohm Splitter SMA-2xSMA 50 ohm Loop (double Female) N-Connector 4 ns 8 ns Pulse Generator SMA-BNC Ch2 50 ohm CK50 2 x 125 m
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1. Cable measurements campaign. 2 nd Experiment (lab testing): Equipment works well, only delay of 8ns 4 ns 8 ns CK 50 Cable Connection -PicoSecond 2600C: Pulse generator 1 - 100ns Selectionable delay Repetition Rate 1-100KHz Vo 45V (-70dB) Zo 50 ohm -LeCroy Scope: Sampling Freq 5Gsps Scale 2ns/div Zin 50 ohm -Testing pulses characteristics: Rise time 419ps Fall time 837ps Pulse width 700ps System delay 8ns
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1. Cable measurements campaign. 2 nd Experiment (Pulse distortion with Square pulse): Square pulse ~4ns: Rise: 407ps 596ps Falling: 876ps 3.436ns Width: 2.464ns 3.298ns Whole Pulse: 3.747ns 7.330ns (Δ195%) Attenuation: 3V 1.75V (-4.68dB) *Yellow: Input *Pink: Output
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1. Cable measurements campaign. 2 nd Experiment (Pulse distortion with ~1.5ns pulse): Square pulse ~1.5ns: Rise: 378ps 606ps Falling: 860ps 4.375ns Width: 763ns 1.369ns Whole Pulse: 2.001ns 6.350ns (Δ317%) Attenuation: 2.75V 1V (-8.7dB) *Yellow: Input *Pink: Output Beware the long tails!! 25ns
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1. Cable measurements campaign. 2 nd Experiment (Step Response & System Identification): Matlab System Identification Toolbox Arxqs model fits 94.64%!! Delay = 759ns – 8ns (probe) = 751ns
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1. Cable measurements campaign. Comparison of the Matlab model TF(f)
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1. Cable measurements campaign. Comparison of the Matlab model TF(f) Matlab model (arxqs) Pspice model (Tlossy)
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1. Cable measurements campaign. 3 rd Experiment layout: – A) Cable noise measurement (Noise normal distribution & Noise Frequency Spectrum) Usage of 2 sets of data at different sampling frequency: 500Mhz & 5Ghz LeCroy Scope Adapter BNC-N BNC Ch1 50 ohm Loop (double Female) N-Connector 10 ns BNC Ch2 50 ohm Load 50 ohm CK50 2 x 88 m = 176m
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1. Cable measurements campaign. A) Cable noise measurement (Noise Frequency Spectrum Fs= 500Mhz) Set 1: 10 Segments of 5ms recorded at 500Mhz with only scope loaded Set 2: 10 Segments of 5ms recorded at 500Mhz with cable loaded Extraction of FFT 1 – 250Mhz for each segment measured in set 1 and averages of FFT Extraction of FFT 1 – 250Mhz for each segment measured in set 2 and averages of FFT FM Radio Stations & TV AM Radio Stations & Others A B
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1. Cable measurements campaign. A) Cable noise measurement (Noise Frequency Spectrum Fs= 5Ghz) Set 1: 10 Segments of 500us recorded at 5Ghz with only scope loaded Set 2: 10 Segments of 500us recorded at 5Ghz with cable loaded Extraction of FFT 1 – 2.5Ghz for each segment measured in set 1 and averages of FFT Extraction of FFT 1 – 2.5Ghz for each segment measured in set 2 and averages of FFT TV StationsGSM-900 GSM-1800 WI-FI C D
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1. Cable measurements campaign. A) Cable noise measurement (Noise Frequency Spectrum Fs= 500Mhz & 5Ghz ) A look in detail (Most important contribution 330KHz!!) 300KHz 1.67GHz 750MHz 167MHz A B C D
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1. Cable measurements campaign. A) Cable noise measurement (Noise Frequency Spectrum Fs= 500Mhz & 5Ghz ) A look in semi-logaritmic scale (Easier to see that the most important contribution is at 330KHz!!)
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1. Cable measurements campaign. A) Cable noise measurement (Noise Frequency Spectrum Fs= 500Mhz) 1.23Khz 19.6Khz 330Khz
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1. Cable measurements campaign. A) Cable noise measurement (Amplitude distribution at Fs= 500Mhz)
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1. Cable measurements campaign. A) Cable noise measurement (Amplitude distribution at Fs= 5Ghz)
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