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A scalable DAQ system using the DRS4 sampling chip H.Friederich 1, G.Davatz 1, U.Hartmann 2, A.Howard 1, H.Meyer 1, D.Murer 1, S.Ritt 2, N.Schlumpf 2 1.

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Presentation on theme: "A scalable DAQ system using the DRS4 sampling chip H.Friederich 1, G.Davatz 1, U.Hartmann 2, A.Howard 1, H.Meyer 1, D.Murer 1, S.Ritt 2, N.Schlumpf 2 1."— Presentation transcript:

1 A scalable DAQ system using the DRS4 sampling chip H.Friederich 1, G.Davatz 1, U.Hartmann 2, A.Howard 1, H.Meyer 1, D.Murer 1, S.Ritt 2, N.Schlumpf 2 1 ETH Zurich, Switzerland 2 Paul Scherrer Institute, Switzerland

2 Slide 2 Hannes Friederich – May 2010 Outline 1. Introduction  WaveDREAM Project  DRS4 Chip 2. Realization  Analog Frontend  Continuous Digitization  Digital Backend 3. Results  System Bandwidth  Noise Power Spectrum  System Nonlinearity

3 Slide 3 Hannes Friederich – May 2010 WaveDREAM Project  Motivation: 1 GSPS, 8-bit, low cost, multichannel system for pulse shape discrimination and photon counting  Development of a flexible DAQ system  Based on the DRS4 chip  Active amplification  20 dB gain  ≥ 500 MHz bandwidth  Scalable no. of channels  Optimized for small amplitude (~10 mV), high frequency signals (~1 GHz), e.g. PMT  Capability for 1 ns global event timestamps  Digital Trigger (FPGA)  General purpose board

4 Slide 4 Hannes Friederich – May 2010 DRS4 Chip (Developed at PSI)  Large Switched Capacitor Array (SCA)  Stores the analog waveform  up to 5 GSPS  11.5 bit SNR  Slower SCA readout  Less expensive ADC electronics  Region of interest readout  NumberOfBins x 30 ns  8+1 channels  Individual Channel depth 1024 bins  Channel cascading  Parallel or serial channel readout

5 Slide 5 Hannes Friederich – May 2010 DRS4 Transparent Mode  Input directly accessible at output while recording  50 MHz Bandwidth  Continuous sampling of the input  Same ADC as DRS readout  Digital trigger  Arbitrary event record length  Eliminates the need for splitting the signal at the frontend  Reduces PCB complexity SCA MUX LP Transparent Mode gain: ½ of SCA gain

6 Slide 6 Hannes Friederich – May 2010 Design Realization Analog Frontend DRS4 ADC FPGA Gigabit Ethernet UDP connection to backend Board-to-board communication Board-to-board communication Readout of all 8 pipelines in parallel Minimizes DRS4 dead time Digital Trigger in the FPGA (e.g. Threshold, CFD)

7 Slide 7 Hannes Friederich – May 2010 Analog Frontend  AC coupled input  Fixed gain 20 dB  Adjustable baseline  Accommodates all signal polarities  Input remains in linear range of DRS4  Frontend-only bandwidth > 1 GHz 50 + 14 dB+ 6 dB DRS4 THS 4302 THS 4508 50 baseline DC offset DAC Input span: 1 V p-p Input levels between 0.1 and 1.5 V

8 Slide 8 Hannes Friederich – May 2010 Continuous Digitization  AD9212: 8 Channel, 10 bit ADC, 65 MSPS  Transparent Mode: 50 MHz bandwidth  Sampling theorem: ≥ 100 MSPS or additional low-pass filtering  More bandwidth increases SNR for high-frequency pulses  Solution: 2 AD9212 with 180 degrees clock phase shift, 120 MSPS DRS4 AD9212 FPGA CLK Trigger Sample Modes: - Continuous sampling (120 MSPS) - DRS Readout (30 MSPS)

9 Slide 9 Hannes Friederich – May 2010 Global Timestamps  Global Clock & Reference signal distributed to all boards  Avoids clock skew  Use clock conditioner chips to reduce clock jitter  Sample the reference signal in the DRS4 to extract fine-grain timestamps  Calibrate propagation delays  Not tested – No numbers DRS4 FPGA LP

10 Slide 10 Hannes Friederich – May 2010 Prototype Implementation  Mezzanine Card  Analog electronics, DRS4 chip, ADCs  Carrier Card  Slots for 2 mezzanine cards  2 FPGAs (Xilinx Spartan 3A)  Communication Layer  Gigabit Ethernet  UDP / IP / MAC layer in VHDL  Board-to-board communication  960 Mbit/s  USB 2.0  RS-485  VME form factor (6U)  Provides mechanical support, power supply & cooling  No support for VME bus

11 Slide 11 Hannes Friederich – May 2010 Results: System Bandwidth  Input capacitance of DRS limits bandwidth  500 MHz Bandwidth  Nonlinear amplification around 300 MHz

12 Slide 12 Hannes Friederich – May 2010 Transparent Mode Bandwidth Bandwidth [-3dB]: 60 MHz

13 Slide 13 Hannes Friederich – May 2010 Noise Power Spectral Density  ENOB 8 – 8.5 bit DRS Readout (1.024 GSPS)

14 Slide 14 Hannes Friederich – May 2010 Baseline Adjustment  Baseline can be adjusted  Linear adjustment circuit ADC range [0 1024]

15 Slide 15 Hannes Friederich – May 2010 Amplitude Nonlinearity  Amplitude Nonlinearity less than 1 ADC value

16 Slide 16 Hannes Friederich – May 2010 Applications  A performant system has been demonstrated  Possible applications include  Pulse shape discrimination  Photon counting from PMTs  Oscilloscope functionality  Arbitrarily flexible trigger logic in the digital domain  Window coincidence already implemented  If you’re interested in using the WaveDREAM board, please contact me afterwards

17 Slide 17 Hannes Friederich – May 2010 PMT Signals First part of transparent mode signal equals DRS readout signal

18 Slide 18 Hannes Friederich – May 2010 Conclusion  A challenging design realized  Good bandwidth achieved (500 MHz)  Region of interest sampling up to 5 GSPS  120 MSPS continuous sampling  Digital Trigger logic  ENOB 8 - 8.5 bit  Gigabit Ethernet  Cost Effective  Flexible design for multiple applications  Thanks to Arktis Radiation Detectors Ltd & CTI for financial support

19 Slide 19 Hannes Friederich – May 2010

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