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Fast sampling for Picosecond timing

Fast sampling for Picosecond timing. Jean-François Genat. EFI Chicago, Dec 17-18 th 2007. Outline. Time picking strategies Timing using MCPs Fast Sampling chip Technologies Conclusions. J ean -F rancois Genat, EFI, Dec 17-18 th 2007, Chicago.

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Fast sampling for Picosecond timing

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  1. Fast sampling for Picosecond timing Jean-François Genat EFI Chicago, Dec 17-18th 2007

  2. Outline • Time picking strategies • Timing using MCPs • Fast Sampling chip • Technologies • Conclusions Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  3. Time picking techniques • Discriminators can be: • - Single Threshold • Derivative’s Zero-crossing • - Multiple Thresholds • CFDs (many flavours) • All make assumptions on the signal waveform • depending upon detector + front end processing • Fast samplingand digitization • Extract most of the pulse information if sampling is • fast enough to resolve the signal rise-time • Digital processing allows any kind of time (and amplitude) extraction • Time accuracy depends on the sampling rate and amplitude ranges Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  4. 10-100 GHz sampling • Fast sampling: • High rate sampling and pulse reconstruction knowing the waveform allows to get accurately: • - Amplitude • Time • using for instance least squares algorithms (Cleland & Stern) • On-chip digital oscilloscopes, integrated in multi-channel analog memory chips: Labrador (Hawaii), SAM (Saclay) • Digital signal processing can also be integrated Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  5. Outline • Time picking strategies • Timing using MCPs • Fast Sampling chip • Technologies • Conclusions Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  6. MCPs timing performance Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  7. Fast signals 0 1 2 3 4 5 ns Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  8. Fast Sampling with Si detectors Input signal 30ns peaking time (detector + noise) S/N = 30 Peaking time = 50ns Noise spectrum Serial, 1/f Amplitude and time spreads sigma(a) =2%, sigma(t)= 1.2 ns A few nanoseconds measured (M. Friedl, M. Pernicka, Vienna) Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  9. Fast sampling simulations Simulated waveforms: White noise added to randomly delayed pulses Peaking time = 200ps 256 samples S/N=50 Peaking time = 160ps 128 samples S/N=60 2ns 1ns Sigma(time) = 6ps Sigma(time) = 8.3ps Residual (no noise) : 3ps No sensitivity to amplitude distribution Infinite dynamic range assumed Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  10. Outline • Time picking strategies • Timing using MCPs • Fast Sampling chip • Technologies • Conclusions Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  11. Counter and picosecond Vernier timer Triggering discriminators 500 MHz Clock Wilkinson AD Read Cntrl Inputs Analog storage Output Time stamps Write and Read control Figure 1 Fast sampler block diagram 10-100 GHz sampling Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  12. Blocks Capacitor bank (SCA): - number of channels - depth - dynamic range - droop, crosstalk Timing generator - time step - clock frequency - use Vernier to increase sampling frequency Triggering Discriminators - threshold - speed - delay ADC (Wilkinson) - number of channels - number of bits - clock speed Control and processing Overall: - input to SCA bandwidth - temperature sensitivity - calibration - power Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  13. N taps main DLL Clock input th tv M taps Vernier DLLs th = Tclock/N, tv = Tclock/M N and M relatively primes LSB = th-tv N x M delayed outputs Timing generator Increasing delays Use as much as possible clock locked looped delays Routing of delays to SCA critical Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  14. Clock Digital Delay Lines: DLL Delay locked loop: Interpolate delays within a clock period N delay elementst Delays control Time arbiter Clock feeds the digital delay line Phase arbiter locks delays on clock period M. Bazes IBM, Proc. IEEE JSSC 1985 p 75 Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  15. Phase lock Clock DLL output Phase arbiter Delay control Lag Lag Lead OK Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  16. Delay elements Active RC element: R resistance of a switched on transistor C total capacitance at the connecting node Typically RC = 1-100 using current IC technologies N delay elementst sis technology dependent: the fastest, the best ! Within a chip s ~ 1 % a wafer s ~ 5-10% a lot s ~ 10-20% [Mantyniemi et al. IEEE JSSC 28-8 pp 887-894] Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  17. Time controlled delay Vdd Delay control thru Vdd Delay controls thru gates voltages PMOS PMOS B=A NMOS NMOS Spread=12 ps Propagation delay t ~ 10-100 ps CMOS Technology 90nm: t ~ 20-40 ps 65nm in production today 100ps TDC 0.6mm CMOS (1992) Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  18. write read reset Switched Capacitors Array Flavours: - Sampling Cap switched in the loop of an opamp - Differential implementation Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  19. Discriminators Do not need the ps accuracy (reference is the main clock) Stops the sampling after a (programmable) delay Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  20. ADC Wilkinson preferred in terms of power and Silicon area since heavily parallel See Eric Delagnes slide: Fast Wilkinson: Clock interpolated using a DLL 100 ps counter 10 times faster Same 12 bit accuracy Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  21. ILC 130nm Silicon strips chip Channel n+1 Sparsifier Can be used for fast decision S aiVi > th (includes auto-zero) Time tag Single ramp 10 bits ADC Channel n-1 reset reset Analog samplers Strip Ch # Preamp + Shapers Waveforms Counter CMOS 130nm ADC Clock 3-96 MHz Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  22. Outline • Time picking strategies • Timing using MCPs • Fast Sampling chip • Technologies • Conclusions Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  23. Technologies SiGe - Not many benefits compared to Deep Sub-Micron CMOS - In addition CMOS from BiCMOS not as fast as pure DSM CMOS 2006 Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  24. CMOS Present designs in CMOS: CERN HPTDC IBM .25 mm 25ps timing generator development .13 mm 6ps timing generator Hawaii BLAB 1 TSMC .25 mm 6 GHz 10b sampling dev 2 TSMC .25 mm 10 GHz Saclay SAM AMS .35 mm 2 GHz 12b sampling 90nm CMOS available from MOSIS, Europractice Drawbacks - Reduced voltage supply - Leaks Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  25. Outline • Time picking strategies • Timing using MCPs • Fast Sampling chip • Technologies • Conclusions Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

  26. Backup J-F Genat, RP220/420 Paris Workshop, Sept 12th 2007

  27. Multi-threshold performance Multi-threshold: sampling times instead of amplitudes : - Number of thresholds 4-8 - Thresholds values equally spaced - Order of the fit: 2d order optimum Extrapolated time

  28. MCP PMT single photon signals Actual MCPs signals K. Inami Univ. Nagoya Tr = 500ps tts= 30ps MCPs segmented anode signals simulation 20 photoelectrons tts = 860 fs H. Frisch, Univ. Chicago + Argonne BUT N photo-electrons improves as Jean-Francois Genat, EFI, Dec 17-18th 2007, Chicago

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