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Published byBarry Leslie Strickland Modified over 9 years ago
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Front-end readout study for SuperKEKB IGARASHI Youichi
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Requirements of Front-end from DAQ Trigger decision time (3 sec ~ 6 sec) –Buffer size of L1 Trigger : 6 sec Rapid trigger communication –Trigger/Busy handshake –Event Tag.(ID?) receiving Dead-time must be less than a few sec Data transport to DAQ system (Trigger pattern information transport to GDL)
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Unification idea by DAQ group Unification point –Behind L1 FIFO and data link unification –The Link(RocketIO) for Data transfer is chosen. –RX/TX on COPPER board. TX/RX FINESSE Unified TX/RX TT-SW New timing Distributor Detector FE, A/D L1FIFO TT-RX Detector FE, A/D Detector FE, A/D TRIGGER COPPER Xilinx RocketI O Control FPGA FE board
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Detectors and readout methods Read-out device planlocation SVDAPV-25 + Repeater + VME FADCNear detector + electronics hut CDCASB/TDC/FADC or High speed FADCNear detector PID ARICHASIC (SA, … )Near detector PID TOP(high precision time measurement : ~10ps) - ECLWaveform DigitizerSide of detector + ? KLMDisc.+FPGANear detector PXLApplication of PANDA readout board
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SVD front-end APV-25 readout baseline design works already. SVD group will progress to w/o FADC crate design to reduce module space and power consumption. Now
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PID front-end Aerogel RICH –HAPD + SA system works. –The hit-pattern digital transfer by UNIFIED interface is checked up. TOP ? FPGA DAQ UNIFIED interface SA (ASIC) HAPD SA (ASIC) HAPD SA (ASIC) HAPD SA (ASIC) HAPD
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ECL front-end COPPER based Waveform digitizer was tested. VME U9 Shaper ADC Waveform Analyzer is planed.
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KLM front-end RPC : –time-multiplex COPPER TDC system works. –The hit-pattern digital transfer by UNIFIED interface is checked up. New Scintillator : –The hit-pattern digital transfer by UNIFIED interface ?
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G.S.Varner ’ s Proposal Waveform sampling for all detectors TARGET : –1GHz, 9bit digitizer BLAB2 : –10GHz digitizer which can be used high-resolution time measurements
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CDC Readout study with DAQ UNIFIED interface CDC FE prototype card –A study about CDAQ/Front-end data transport. –A study about GDL/Front-end data transport –A study of the CDC readout scheme Charge measurements by (slow) FADC Drift time measurements by FPGA based TDC –A study of common mode noise from the front-end readout board to CDC –A confirmation of front-end specification G.V. ’ s proposal FE will be tested in parallel.
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CDC FE Prototype card Under 20cm ASB + Discriminator ASB + Discriminator ASB + Discriminator ASB + Discriminator FADC 16ch/board BJT -ASB/Discriminator FADC: over 20MHz / 10bit FPGA : Vertex-5 LXT –TDC: 1 nsec counting –FADC reading –Control FPGA: Spertan3A –SiTCP for CDC study Connectors –RJ-45 for SiTCP –RJ-45 for DAQ timing signals –RJ-45 for DAQ data line –SFP for DAQ data line –Optical TX/RX for GDL –LEMO input x 3, output x1 Shielded substrate FPGA (CONTROL, TDC) RJ45 SFP Optical Transceiver FADC FPGA (SiTCP) Optical Transceiver RJ45
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Front-end (for system test) ASB –Amp. Shaper Buffer –4ch/chip –Peaking time ~ 40 nsec –Gain : -360mV/pC ~ -1400mV/pC (4 step variable) ASB protection Disc. Fe source D-out A-out
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TDC in FPGA To use 4 different phase 250MHz Clock in the aim of 1 nsec counting 4ns Latch each clock timings 0 1 1 Encode latched pattern 0 RMS=0.51n s Input : Hoshin 16bit TDC tester
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LOGIC part diagram FADC Ti ADS5287 ASB Discriminator SFP (Optical connector) RJ-45 LVDS 8 pairs CONTROL 3x4 Vertex-5 LXT (XC5VLX50T, IO:360pin) LVDS 2 pairs LVDS 4 pairs RJ-45 15 TIMING LVDS 4x4 pairs LEMO RocketIO GFP 100base PHY Spertan3A SiTCP TDC (with FIFO) 3 FIFO 4 LED DIP-SW 8 16 TEST PIN 16 CONTROL CLK 125MHz Sampling CLK 20~40 MHz CLK 42.33MHz ASB Discriminator FADC Ti ADS5287 ASB Discriminator ASB Discriminator De-serializer 5 LVDS 8 pairs 5 48 DIP-SW TEST PIN 8 32 CLK 50MHz LVDS CLKs LVDS CLKs PUSH SW DAC (Vth) 8 RocketIO GFP Optical connector LVDS 2 pairs CLK For GFP RocketIO GFP RJ-45 LVDS 2 pairs
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Scheduled plan 2008/11Study preliminary specification 2008/11,12 design circuit schematics –ASD part (T.Taniguchi-san) –Digital part (M.Saito-san) 2008/12 endorder printed circuit board design 2009/2 Final check of the PC board design and start production –M.Ikeno-san etc … 2009/3Start the practical study
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Summary Each detector groups are progressing to design the detector Front-end. G.V. offer good two high speed waveform samplers to unified FE. –The unification by the waveform sampler should be discussed. –Those prototype is available. UNIFIED interface R&D has been started in collaboration with CDC group. Issues –Treatments about over 20 MB/sec/link speed data flow COPPER can treat up to 40MB/sec data flow w/o network. Will detector groups request more faster single link data flow ? –Discussion with the groups which thinking COPPER-less option.
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Backups
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SVD front-end
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