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DCH FEE 28 chs DCH prototype FEE &

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Presentation on theme: "DCH FEE 28 chs DCH prototype FEE &"— Presentation transcript:

1 DCH FEE 28 chs DCH prototype FEE &
DCH readout chain development status G. Felici G. Felici LNF - SuperB Workshop - April 2011

2 LNF - SuperB Workshop - April 2011
Outline DCH prototype front-end and HV distribution Requirements Feedthrough lock board Field wires GND boards HV distribution board Signal extraction (decoupling & protection) board Preamplifier board Cluster Counting update Cluster Counting scenarios Cluster Counting based on FADC Cluster Counting based on derivative circuit Derivative circuit – Simulation result examples Readout chain update Readout chain including derivative circuit ADC data readout example Conclusions G. Felici LNF - SuperB Workshop - April 2011

3 LNF - SuperB Workshop - April 2011
DCH prototype front-end G. Felici LNF - SuperB Workshop - April 2011

4 LNF - SuperB Workshop - April 2011
28 chs DCH prototype FEE Signal amplification requirements BW ≥ 250 MHz Amplification ≥ 5 mV/fC Noise < 2000 erms On Detector FEE boards Feedthrough lock board (2 boards required) Field wires GND boards (2 boards required) HV distribution board (1 board required) Signal extraction (decoupling & protection) board (1 board required) Preamplifier board (1 board required) G. Felici LNF - SuperB Workshop - April 2011

5 28 chs DCH prototype FEE – Feedthrough lock board
The board is used to lock feed-throughs, in order to avoid stressing (or breaking) wires while working on ground or front‐end boards. The lock boards must be anchored on each end-plate. NB: A similar architecture must be foreseen for the DCH, to avoid accidental damages to the wires when working on FEE boards. G. Felici LNF - SuperB Workshop - April 2011

6 28 chs DCH prototype FEE – Ground board
GND connectors The board is used To connect field wires to GND by means of female connectors soldered on the PCB itself. Holes in the board allow for signal extraction and HV distribution by means of appropriate boards. NB: the same approach can be used for DCH. Dedicated connections will be required for some field wires if we plan to measure wire tension from time to time. G. Felici LNF - SuperB Workshop - April 2011

7 28 chs DCH prototype FEE – HV distribution board
Guard wires Sense wires The board provides HV filtering and distribution to sense and guard wires G. Felici LNF - SuperB Workshop - April 2011

8 28 chs DCH prototype FEE – Signal extraction board
The board is plugged into sense wire feedthrough and GROUND board GND connectors. It includes HV decoupling and spark protection circuit G. Felici LNF - SuperB Workshop - April 2011

9 28 chs DCH prototype FEE – Preamplifier board
Input signal connector It is plugged into the signal extraction board and provide amplification to the wire signals Unipolar Out Unipolar output connector Differential output connector Power supply connector Test input connector Diff Out Cin Decoupling Pre Ampli G. Felici LNF - SuperB Workshop - April 2011

10 LNF - SuperB Workshop - April 2011
Cluster counting G. Felici LNF - SuperB Workshop - April 2011

11 Cluster counting scenarios
Cluster Counting based on FAST (1 GS) sampling device Pro Flexible data analysis (software/firmware implementation) Con Huge data throughput Cluster Counting based on derivative method Pro Easy to integrate in a readout chain (requires a multi-hit TDC) Con Sensitive to channel noise Low flexiblity G. Felici LNF - SuperB Workshop - April 2011

12 Cluster counting based on FADC
Data throughput (1 1 GS) 8 bits (FADC resolution) x 1000 (samples) x (channels) x 0.1 (occupancy) x 150 kHz (average trigger rate) = 1.2 x 1012 bits/s ( Gbits/s)  FPGA implementation of a fast algorithm required for cluster detecting ( loss of accuracy in peak detecting) G. Felici LNF - SuperB Workshop - April 2011

13 Cluster Counting based on derivative method
Studies to verify Cluster Counting capability by means derivative circuit are going on. The method will be extensively tested by means of the 28 chs DCH prototype G. Felici LNF - SuperB Workshop - April 2011

14 How the circuit works (I)
Pspice simulation Signal acquired with DRS digitizer (1 GS) 1μs 1μs 1μs 1μs G. Felici LNF - SuperB Workshop - April 2011

15 How the circuit works (II)
G. Felici LNF - SuperB Workshop - April 2011

16 Derivative circuit - Simulation result examples
Vth Counts -10mV 33 -20mV 27 -30mV 21 -40mV 14 -50mV 16 -60mV -80mV 15 -90mV -100m mV ns mV Vth Counts -10mV 28 -20mV 24 -30mV 20 -40mV 17 -50mV 15 -60mV 14 -80mV -90mV 12 -100m 11 ns G. Felici LNF - SuperB Workshop - April 2011

17 Readout chain implementation based on
Charge ADC, TDC & derivative circuit G. Felici LNF - SuperB Workshop - April 2011

18 Readout chain including derivative circuit
DISTRIBUTED RAM 16 bits – 4 events (128 words) BLOCK RAM 8 bits – 1024 words ADC : 32 – 8 bits words TDC : words (cluster arrival time) Trigger Latency Time + n samples (Dual-port memory) RO buffer ADC n 2 1 DATA RO SM (FEX) Pushing mode Ev4 Ev3 Ev2 Ev1 Triggered Data Bus OL Analog signal Possible event structure 1 (or 2) status word 1 ADC data word (charge) 20-30 TDC data word (cluster arrival time) Derivative Circuit TDC n5 n1 15 11 05 1 5 = max number of cluster in a ADC sampling period Fine Address (counter L1) - Latency Read ADDR ADDR Sampling clock COUNTER (0 – n) ADDR DISTRIBUTED RAM 10 bits – 16 words FiFO Empty L1 FIFO L1 (synchronized by sampling clock) FiFO Read Data (counter L1) G. Felici LNF - SuperB Workshop - April 2011

19 ADC data readout example
SAMPLING CLK L1 SAMPLED DATA READOUT CLK READOUT ADC DATA G. Felici LNF - SuperB Workshop - April 2011

20 LNF - SuperB Workshop - April 2011
Conclusions DCH prototype front-end and HV distribution boards have been already designed. Boards production will start within one week. DCH prototype will be used to verify cluster counting implementation both using fast digitizer and derivative circuit. A new version of derivative circuit has been designed and simulated using (as stimulus file) data acquired by means of DRS digitizer. Simulation with Garfield data are going on to tune circuit parameters. Readout chain requires large use of programmable logic (FPGA), then both accurate study of background radiation and radiation tolerant design are required (in our design off-detector readout chain is located near the detector) Up to now we focused our attention on off-detector front-end electronics, nevertheless we need also preamplifiers to amplify wire signals … G. Felici LNF - SuperB Workshop - April 2011

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