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INO prototype detector

Status report on electronics, trigger and data acquisition system for the proposed INO prototype detector. B.Satyanarayana Department of High Energy Physics Tata Institute of Fundamental Research Homi Bhabha Road, Colaba, Mumbai, 400 005 E-mail: bsn@tifr.res.in. INO prototype detector.

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INO prototype detector

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  1. Status report on electronics, trigger and data acquisition system for the proposed INO prototype detector B.SatyanarayanaDepartment of High Energy PhysicsTata Institute of Fundamental ResearchHomi Bhabha Road, Colaba, Mumbai, 400 005E-mail: bsn@tifr.res.in

  2. INO prototype detector • Detector and signal specifications • Detector dimensions: 1m X 1m X 1m • 14 layers of RPCs with 6cm iron plates interleaved. • Two signal planes orthogonal to each other and each having 32 pick-up strips • Total channels = 32 X 14 X 2 = 896 • Pulse height = 100 to 300mV; Rise time = < 1 ns • Pulse width = ~50ns; Rate ~ 1KHz • Trigger information • Expected trigger rate is few Hz • Required Trigger logic is m X n fold, where • m = 1 to 4; no. of consecutive channels in a layer • n = 5 to 1; no. of consecutive layers with m fold in each layer • ie m x n = (1 x 5) OR (2 x 4) OR (3 x 3) OR (4 x 2) • Information to be recorded on a trigger • Absolute arrival time of the trigger • Track identification (XYZ points in RPC layers) • Direction of track ( TDC information) • Miscellaneous information and calibration data • Monitoring health of the detector B.Satyanarayana VECC, Kolkata December 24, 2005

  3. Readout scheme for prototype B.Satyanarayana VECC, Kolkata December 24, 2005

  4. Fast preamplifier • Provided by Electronic Division, BARC • Currently being used with avalanche mode operation • Fixed gain (10), single channel, single polarity, with discrete components (availability issues) B.Satyanarayana VECC, Kolkata December 24, 2005

  5. Preamp hybrid • Bipolar operation tested • To be packaged into a hybrid (BEL) • Possible to mount on the RPC pickup strips • Will improve signal to noise • Fabrication procedure • Circuit schematic by BARC • Layout preparation by BEL (2-3 weeks) • Pilot production by BEL and validation (1 month) • Final production (4-6 weeks) B.Satyanarayana VECC, Kolkata December 24, 2005

  6. 16-channel analog front-end • Based on Analog Devices’ Quad-device • Fast comparator with ECL outputs • Wire ORed pre-trigger outputs • Production board tested with RPC strip signals • Works as good as commercial units • Components being procured • Ready for production (2-3 months) B.Satyanarayana VECC, Kolkata December 24, 2005

  7. 32-channel digital front-end B.Satyanarayana VECC, Kolkata December 24, 2005

  8. Digital front-end status • Logic fused into a CPLD XC 95288 -HQ708 • Code tested on a simulator and hardware using a pattern generator • Jig fabricated to test the logic on RPC signals • Work in progress (2 weeks) • PCB layout is also in progress • Production estimate about 3 months B.Satyanarayana VECC, Kolkata December 24, 2005

  9. Prototype detector trigger logic B.Satyanarayana VECC, Kolkata December 24, 2005

  10. FRC 60 5 Fold coincidence of consecutive F1 signals from 1 to 14 layers 4 Fold coincidence of consecutive F2 signals from 1 to 14 layers OR FRC 60 2 Fold coincidence of consecutive F4 signals from 1 to 14 layers 3 Fold coincidence of consecutive F3 signals from 1 to 14 layers FRC 60 Similar coincidence logic from Y Plane signals ( 1F to 4F) OR FRC 60 CAMAC based trigger module m-Fold LVDS signals (X-Plane) m-Fold LVDS signals (Y-Plane) Final trigger B.Satyanarayana VECC, Kolkata December 24, 2005

  11. Trigger module status • Being developed by Electronics Division, BARC • Implemented using a FPGA • Major part of logic coded; scalers to be done • Module given for fabrication • Expected to be ready in two months • Testing and debugging (1 month) B.Satyanarayana VECC, Kolkata December 24, 2005

  12. CAMAC based control module Generates three sets of control and hand shake signals for selection of DFE board, readout of event data and monitoring of pickup signals in the selected board B.Satyanarayana VECC, Kolkata December 24, 2005

  13. CAMAC based readout module • Four serial event data read out channels • Eight monitor data inputs • Serial to parallel conversion of event data • Data written into FIFO buffer • FIFO buffers readout through CAMAC backplane in the event routine • Eight selected monitor channels translated into ECL logic signals • Rates monitored through ECL input CAMAC scaler modules B.Satyanarayana VECC, Kolkata December 24, 2005

  14. Other items • High voltage supplies (CAEN, SINP) • Low voltage supplies (Local) • Components, cables etc • Commercial/available modules • TDCs • Scalers • CAMAC crates and controllers • DAQ software on Linux platform B.Satyanarayana VECC, Kolkata December 24, 2005

  15. Thoughts for final detector • Expertise from TIFR, BARC, SINP, VECC, IITB, IGCAR, NSC etc • Industry ready and active • Front-end and timing ASICs • Low rates; high degree of multiplexing possible • ASIC design process must begin now • Comparator ASIC work by SINP • Tools and training of personnel • Discussion meeting at national level B.Satyanarayana VECC, Kolkata December 24, 2005

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