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A Faster Digitizer System for the Hadron Blind Detector in the PHENIX Experiment

A Faster Digitizer System for the Hadron Blind Detector in the PHENIX Experiment.

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A Faster Digitizer System for the Hadron Blind Detector in the PHENIX Experiment

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  1. A Faster Digitizer System for the Hadron Blind Detector in the PHENIX Experiment Cheng-Yi ChiNevis Lab Physics Dept. Columbia University for the PHENIX experiment N35-6 IEEE NSS & MIC 2007 by C. Y. Chi

  2. HBD Team • Weizmann Institute of Science • A.Dubey, Z. Fraenkel, A. Kozlov, M. Naglis, I. Ravinovich, D.Sharma, I.Tserruya* • Stony Brook University • W.Anderson, Z.Citron, J.M.Durham, T.Hemmick, J.Kamin • Brookhaven National Lab • B.Azmoun, A.Milov, R.Pisani, T.Sakaguchi, A.Sickles, S.Stoll, C.Woody (Physics) • J.Harder, P.O’Connor, V.Radeka, B.Yu (Instrumentation Division) • Columbia University (Nevis Labs) • C-Y. Chi, F.W. Sippach * Project Leader

  3. Mesh HV panel g Triple GEM module with mesh grid Primary ionization HV e- CsI layer Pad readout plane Triple GEM Readout Pads Mylar entrance window Honeycomb panels HV panel HADRON BLIND DETECTOR • Proximity focus Cherenkov counter. • Use CsI to convert photon to electron. • GEM is used for amplify the electron from CsI. • Measure time and charge • Installed in 2006 N05-1 HBD I.Tserruya N15-295 HBD Gas S.Stoll MP5-3 Gain J.S.Kamin N15-239, GAS B. Azmoun MP4-2 Foil B. Azmoun IEEE NSS & MIC 2007 by C. Y. Chi

  4. 15 mm 19 mm Preamp (BNL IO-1195) 2304 channels total Charge Preamp with On-Board Cable Driver(IO1195-1-REVA) • Features: • +/- 5V power supply. • 165 mW power dissipation. • Bipolar operation (Q_input = +/- ) • Differential outputs for driving 100 ohm twisted pair cable. • Large output voltage swing -- +/- 1.5V (cable terminated at both ends) • (+/- 3V at driver output) • Low noise: Q_noise = 345e (C_external = 5pF, shaping = .25us) • (Cf = 1pF, Rf = 1meg) • Size = 15mm x 19mm • Preamp output (internal) will operate +/- 2.5V to handle large pile-up. IEEE NSS & MIC 2007 by C. Y. Chi

  5. Use 2MM Hard Metric cable to move signals between preamp/FEM 2mm HM connector has 5 pins per row and 2mm spacing between pins and rows There are two types of cable configuration: *100 ohms parallel shielded cable 50 ohms coaxial cable Signal arrangement S- S+ G S- S+ MERITEC Our choice is This gives us signal density 2mm x 10mm for every 2 signals. Same type of cables will be used for L1 trigger data. IEEE NSS & MIC 2007 by C. Y. Chi

  6. FEM receiver + ADC Preamp Cable driver Differential Receiver ADC FPGA TI ADS5272 Based on AD8138 receiver Unity gain 8 CHANNEL 65 MHz 12 bits ADC (80 TQFP) The +/- input can swing from 1V to 2V, Vcm=1.5V + side 2V, - side 1V -> highest count - side 2V, + side 1V -> lowest count Our +/- input will swing from 1.5 to 2V/ 1.5 to 1V we will only get 11 bits out of 12 bits 16fc will be roughly sitting at 200 count We will run the ADC at 6X beam crossing clock 6X9.4 MHz = 56.4 MHz or ~17.7ns per samples ADC data are serialized LVDS at 12*56.4 MHz= 678 MHz IEEE NSS & MIC 2007 by C. Y. Chi

  7. HBD ADC board We use ALTERA STRATIX II 60 FPGA to receive the 6 ADC’s data It has 8 SERDES blocks. ALTERA provides de-serializer Mega function block. 6XADC clock  SERDES clock  data de-serialized as 6 bit 120 MHZ Regroup to 12 bits at 60 MHz , 45 degree phase adjustment step. Timing Margin  270 degree. • The FPGA also provides • L1 delay (up to 240 samples) • 8 events buffer • ADC setting download • Offline slow readback • 7 threshold levels for L1 trigger primitives per channel. ALTERA FPGA ADC Differential receiver 48 channels per board 6U X160 mm size Signals from Preamp IEEE NSS & MIC 2007 by C. Y. Chi

  8. FEM Crate Block Diagram FEM: Digitize the detector pulse Clock Fanout -> distribut the ADC + system clocks XMIT: send the digitize data to DAQ Pulse: send the test pulse to the preamp Clock Master: Interface with PHENIX timing system for L1, clock etc. DCM: PHENIX Data Collection Module FEM CRATE Token passing dataway 60MHz ADC clock 20MHz system clock 60MW/sec Clock fanout FEM (ADC) FEM (ADC) XMIT Pulser 80MW/sec Optical link Clock Master Preamp GTM + Ethernet DCM IEEE NSS & MIC 2007 by C. Y. Chi

  9. 16MV test pulse on all the channels on FEM number 2 The test is done by moving test jigs cables (6 outputs) 8 times. 60Mhz noise kicks back from ADC Preamp output Output of FEM receiver 10mv, 100ns per division Digital sum 20mv/division IEEE NSS & MIC 2007 by C. Y. Chi

  10. ADC test result -2 Average over 40 events Preamp + ADC system performance ADC Sample # Preamp on Preamp off Sigma on the baseline ADC distribution for 192 channel ADC distribution for sample 15 TEST Pulse Injection at preamp input IEEE NSS & MIC 2007 by C. Y. Chi

  11. ADC test result -3 ADC The result after doing Pulse (n+2) – Pulse (n) Sample Number ADC ADC Distribution Sample Number 100 events histogram from test pulse injection. < problem with the low drop regulators> ADC Distribution IEEE NSS & MIC 2007 by C. Y. Chi

  12. CONCLUSION • The electronics has been installed and run successfully in 2007 run. • We have ~2300 channel installed. • The FEM board power consumption is about 20W for 48 channel. • The whole system fit into 4 crates, including the enough space of adding L1 trigger boards. • We read out 12 samples of ADC data per channel. The channel has ADC (peak – baseline) < threshold (channel) get dropped in the data acquisition system. • Both TI and Analog Device now have multiple channels 14 bits ADC. • We will develop a new system for 14 bits application with slightly higher packing density. IEEE NSS & MIC 2007 by C. Y. Chi

  13. IEEE NSS & MIC 2007 by C. Y. Chi

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