2000 IEEE NSS Lyon,France Oct 2000 1 Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade DØ Calorimeter Electronics Upgrade for Tevatron Run II.

Slides:

Advertisements

Similar presentations

ATLAS Tile Calorimeter Performance Henric Wilkens (CERN), on behalf of the ATLAS collaboration.

Advertisements

6 Mar 2002Readout electronics1 Back to the drawing board Paul Dauncey Imperial College Outline: Real system New VFE chip A simple system Some questions.

An SiPM Based Readout for the sPHENIX Calorimeters Eric J. Mannel IEEE NSS/MIC October 30, 2013.

TileCal Electronics A Status Report J. Pilcher 17-Sept-1998.

Status of Eric Kajfasz CPPM/Fermilab GDR-Susy, Lyon - 26 novembre 2001.

How to Build a Neutrino Oscillations Detector - Why MINOS is like it is! Alfons Weber March 2005.

28 August 2002Paul Dauncey1 Readout electronics for the CALICE ECAL and tile HCAL Paul Dauncey Imperial College, University of London, UK For the CALICE-UK.

Ionization. Measuring Ions A beam of charged particles will ionize gas. –Particle energy E –Chamber area A An applied field will cause ions and electrons.

Large Area, High Speed Photo-detectors Readout Jean-Francois Genat + On behalf and with the help of Herve Grabas +, Samuel Meehan +, Eric Oberla +, Fukun.

Mainz: Contributions to the LArg-Calorimeter Purity monitoring of the liquid argon and temperature measurement in the three cryostats - Old electronics.

DØ L1Cal Trigger 10-th INTERNATIONAL CONFERENCE ON INSTRUMENTATION FOR COLLIDING BEAM PHYSICS Budker Institute of Nuclear Physics Siberian Branch of Russian.

Preliminary Design of Calorimeter Electronics Shudi Gu June 2002.

Oct, 2000CMS Tracker Electronics1 APV25s1 STATUS Testing started beginning September 1 wafer cut, others left for probing 10 chips mounted on test boards.

Performance test of STS demonstrators Anton Lymanets 15 th CBM collaboration meeting, April 12 th, 2010.

L.Royer– Calice DESY – July 2010 Laurent ROYER, Samuel MANEN, Pascal GAY LPC Clermont-Ferrand R&D LPC Clermont-Fd dedicated to the.

Digital Signal Processing and Generation for a DC Current Transformer for Particle Accelerators Silvia Zorzetti.

Preliminary measurements for the 8 channel prototype of SPD discriminator ASIC I.The 8 channel prototype. II.Status of the test. III.Noise. IV.Gain. V.Test.

Figure 1: ICD Single Channel Block Diagram Schematic PMT High Voltage Supply (see Figure 4 & 4a) LED Pulser PMT Calibration (see Figure 6) ICD Scintillator.

Mark Raymond /12/051 Trip-t & TFB Trip-t schematics signals and registers operation SiPM connection TFB block diagram functionality.

1 Online Calibration of Calorimeter Mrinmoy Bhattacharjee SUNY, Stony Brook Thanks to: D. Schamberger, L. Groer, U. Bassler, B. Olivier, M. Thioye Institutions:

Figure 2 gives an overview of the hardware components of the upgraded Main Injector BPM system. The figure shows 2 signal channels which produce one position.

CALOR2000 Conference Annecy,France Oct Leslie Groer Columbia UniversityDØ Calorimeter Electronics Upgrade Columbia University New York DØ Calorimeter.

ATLAS Liquid Argon Calorimeter Monitoring & Data Quality Jessica Levêque Centre de Physique des Particules de Marseille ATLAS Liquid Argon Calorimeter.

A. Gibson, Toronto; Villa Olmo 2009; ATLAS LAr Commissioning October 5, 2009 Commissioning of the ATLAS Liquid Argon Calorimeter Adam Gibson University.

Dec.11, 2008 ECL parallel session, Super B1 Results of the run with the new electronics A.Kuzmin, Yu.Usov, V.Shebalin, B.Shwartz 1.New electronics configuration.

January 31, MICE DAQ MICE and ISIS Introduction MICE Detector Front End Electronics Software and MICE DAQ Architecture MICE Triggers Status and Schedule.

March 9, 2005 HBD CDR Review 1 HBD Electronics Preamp/cable driver on the detector. –Specification –Schematics –Test result Rest of the electronics chain.

Update on final LAV front-end M. Raggi, T. Spadaro, P. Valente & G. Corradi, C. Paglia, D. Tagnani.

Valerio Re, Massimo Manghisoni Università di Bergamo and INFN, Pavia, Italy Jim Hoff, Abderrezak Mekkaoui, Raymond Yarema Fermi National Accelerator Laboratory.

Ursula Bassler, LPNHE Paris1Collaboration Meeting - 13 Sept Calorimeter: Status & Plans Preamp/ Driver Trig. sum Filter/ Shaper x1 x8 SCA (48 deep)

All Experimenters MeetingDmitri Denisov Week of July 7 to July 15 Summary  Delivered luminosity and operating efficiency u Delivered: 1.4pb -1 u Recorded:

Nirmalya Parua March 17, 2003 The RunII Calorimeter Nirmalya Parua (For the Calorimeter Group) Shifter’s Tutorial March 17, 2003  Overview Of the D0 Calorimeter.

DØ Calorimeter Software Meeting April 26, Leslie Groer Columbia UniversityCalorimeter Online Software Status + Needs 1  Examines  Crate Unpacking.

BeamCal Electronics Status FCAL Collaboration Meeting LAL-Orsay, October 5 th, 2007 Gunther Haller, Dietrich Freytag, Martin Breidenbach and Angel Abusleme.

DØ Algorithms Meeting April 6, Leslie Groer, Columbia Univ Ursula Bassler, LPNHE, ParisCalorimeter Online Software Status 1  Examines  Crate Unpacking.

Fermilab Silicon Strip Readout Chip for BTEV

Nirmalya Parua March 25-29, 2002 The RunII D0 Calorimeter Electronics Upgrade & Its Performance Nirmalya Parua State University of New York Stony Brook.

11 October 2002Paul Dauncey - CDR Introduction1 CDR Introduction and Overview Paul Dauncey Imperial College London.

A Silicon Photomultiplier (SiPM) Based Readout for the sPHENIX Upgrade S. Boose, J. Haggerty, E. Mannel, A. Sukhanov For the PHENIX Collaboration Introduction:

Susan Burke DØ/University of Arizona DPF 2006 Measurement of the top pair production cross section at DØ using dilepton and lepton + track events Susan.

Status of the PSD upgrade - Status of the PSD cooling and temperature stabilization system - MAPD gain monitoring system - PSD readout upgrade F.Guber,

DØ Collaboration Workshop NIU, DeKalb, IL June Leslie Groer Columbia UniversityCalorimeter Electronics Upgrade Columbia University New York Calorimeter.

Robert R. Wilson Prize Talk John Peoples April APS Meeting: February 14,

Calibration Workshop 8 Sept Calorimeter Calibration: Calibration procedure and Database Definition Ursula Bassler, Mrinmoy Bhattacharjee, Leslie.

R&D status of the very front end ASIC Tilecal week (7 October 2011) François Vazeille Jacques Lecoq, Nicolas Pillet, Laurent Royer and Irakli Minashvili.

1 Timing of the calorimeter monitoring signals 1.Introduction 2.LED trigger signal timing * propagation delay of the broadcast calibration command * calibration.

Front-end Electronic for the CALICE ECAL Physic Prototype Christophe de La Taille Julien Fleury Gisèle Martin-Chassard Front-end Electronic for the CALICE.

Krisztian PetersPrecision Calibration of the DØ HCAL in Run II1 Krisztian Peters University of Manchester For the DØ Calorimeter Algorithm Group June.

Calorimeter Task Force Workshop February 10, 2003 Leslie Groer, Columbia UniversityCalorimeter Software Status 1 Past Calorimeter Software Improvements.

10/3/2003Andreas Jansson - Tevatron IPM review1 Tevatron IPM Proposed design.

PP December 7, 2004 The RunII Calorimeter Pierre Pétroff and Norm Buchanan (For the Calorimeter Group) (taken largely from N. Parua’s tutorial) Cal-Muo.

 13 Readout Electronics A First Look 28-Jan-2004.

Tuesday, 20 May 2003OPERA Collaboration Meeting - Gran Sasso1 Status of front-end electronics for the OPERA Target Tracker LAL Orsay S.BONDIL, J. BOUCROT,

Status of front-end electronics for the OPERA Target Tracker

Rainer Stamen, Norman Gee

Calorimeter Status Electronics Installation and Commissioning

The DØ Calorimeter Upgrade

Jinfan Chang Experimental Physics Center , IHEP Feb 18 , 2011

Calorimeter Mu2e Development electronics Front-end Review

DØ Upgrade Run II Introduction Physics Goals Tevatron Upgrade

EMC Electronics and Trigger Review and Trigger Plan

A First Look J. Pilcher 12-Mar-2004

LHCb calorimeter main features

Example of DAQ Trigger issues for the SoLID experiment

BESIII EMC electronics

RPC Front End Electronics

- Calorimeter Calibration

PHENIX forward trigger review

The Ohio State University USCMS EMU Meeting, FNAL, Oct. 29, 2004

Calorimeter Upgrade The Tevatron and Dzero Upgrades

Presentation transcript:

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade DØ Calorimeter Electronics Upgrade for Tevatron Run II DØ Collaboration October IEEE NUCLEAR SCIENCE SYMPOSIUM and MEDICAL IMAGING CONFERENCE Lyon, France October 15-20, 2000

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 2 Fermilab Accelerator Upgrade  Two new machines at FNAL for Run II:  Main Injector  150 GeV conventional proton accelerator  Supports luminosity upgrade for the collider, future 120 GeV fixed-target program, and neutrino production for NUMI  Recycler  8 GeV permanent magnet (monoenergetic) storage ring  permits antiproton recycling from the collider  Tevatron Status and Schedule  DØ and CDF roll in – January 2001  Run II start – March 2001  1.8 Tev  2 TeV  Goal:  L dt = 2 fb -1 by fb -1 + by 2006?  Very first p-pbar collisions seen (August 2000)

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 3 Run II Parameters 0% 10% 20% 30% 40% ns 132 ns Run II Bunch Spacing # of Ints. / Crossing % Crossings

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 4 Timing 3.56us 4.36us 2.64us superbunchgap 396ns gap used to form trigger and sample baselines this gap is too small to form trigger and sample baseline  Bunch structure Run I 6x6 Run II 36x36  Design all the electronics, triggers and DAQ to handle bunch structure with a minimum of 132ns between bunches and higher luminosity  Maintain detector performance

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 5 Calorimeter Readout Electronics  Objectives  Accommodate reduced minimum bunch spacing from 3.5  s to 396 ns or 132 ns and L ~ 2 x cm -2 s -1  Storage of analog signal for 4  s for L1 trigger formation  Generate trigger signals for calorimeter L1 trigger  Maintain present level of noise performance and pile-up performance  Methods  Replace preamplifiers  Replace shapers  Add analog storage  Replace calibration system  Replace timing and control system  Keep Run I ADCs, crates and most cabling to minimize cost and time LAr det. preamp shaper + BLS ADC analog buffer storage L1+L2 trigger

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 6 Calorimeter Electronics Upgrade 55K readout channels  Replace signal cables from cryostat to preamps (110   30  for impedance match)  Replacement of preamps, shapers, baseline subtraction circuitry (BLS)  Addition of analog storage (48-element deep Switched Capacitor Array (SCA))  New Timing and Control  New calibration pulser + current cables Preamp/ Driver Trig. sum Filter/ Shaper x1 x8 SCA (48 deep) BLS Output Buffer Detc. Bank 0 Bank 1 Replace cables for impedence match new low noise preamp & driver Shorter shaping ~400ns SCA analog storage >4  sec, alternate Additional buffering for L2 & L3 SCA new calibrated pulse injection BLS Card

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 7 Preamplifier 2” FET driverpreamp similar to Run 1 version except Dual FET frontend Compensation for detector capacitance Faster recovery time New output driver for terminated signal transmission out in Preamplifier New calorimeter preamp  Hybrid on ceramic  48 preamps on a motherboard  New low-noise switching power supplies in steel box

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 8 Preamp Species  14+1 (ICD) species of preamp  Feedback provide compensation for RC from detector capacitance and cable impedance  Readout in towers of up to 12 layers  0:EM1, 1:EM2, 2-5:EM3, 6:EM4, 7-10:FH, 11:CH  4 towers per preamp motherboard provides trigger tower (EM+ HAD) of  x  0.2 x 0.2 Preamp species Avg. Detector cap. (nF) Layer readout Feedback cap (pF) RC (ns) Total preamps A EM1,2, HAD B HAD C HAD D HAD E CC EM F EC EM3, G CC EM4, EC EM3, Ha-Hg2- 4 EC EM3, I— ICD

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 9 L1 SCAs (2+2) L2 SCA Array of 48 capacitors to pipeline calorimeter signals BLS Card BLS motherboard v2.2 BLS daughterboard Shapers (12)  Use 2 L1 SCA chips for each x1/x8 gain - alternate read/write for each superbunch  Readout time ~ 6  s (< length SCA buffer)  L2 SCA buffers readout for transfer to ADC after L2 trigger decision  No dead time for 10KHz L1 trigger rate  Trigger tower formation (0.2 x 0.2) for L1  Rework existing power supplies  New T&C signals to handle SCA requirements and interface to L1/L2 trigger system( use FPGAs and FIFOs) Output circuit Trigger pickoff/summers ~ 1 inch shaper

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 10 SCA  Designed by LBL, FNAL, SUNY Stony Brook (25k in system)  Not designed for simultaneous read and write operations  two SCA banks alternate reading and writing  12 bit dynamic range (1/4000)  low and high gain path for each readout channel (X8/X1)  maintain 15 bit dynamic range cap ref input 1” 12 channels 48 deep packaged

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 11 Preamp signal shape  return to zero by about 1.2  s  Sample at 320ns  Mostly insensitive to 396 ns or 132 ns running  BLS-Finite time difference is measured  Uses three samples earlier  Pile-up  Preamp output is integral of detector signal  rise time > 430ns  recovery time 15  s  To minimize the effects of pileup, only use 2/3 of the charge in the detector  Shaped signal sampled every seven RF buckets (132ns)  peak at about 300ns After shaper Signal from preamp ns amplitude 320 ns Detector signal

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 12 Noise Contributions  Design for  400ns shaping  lower noise – 2 FET input  luminosity of 2x10 32 cm –2 s -1  Re-optimized three contributions  Electronics noise:  x 1.6   shaping time (2  s  400ns) (~  t)   lower noise preamp (2 FET) (~ 1/  2)  Uranium noise:  x 2.3   shorter shaping time (~  t)  Pile-up noise:  x 1.3   luminosity (~  L)   shorter shaping times (~  t)  Comparable noise performance at with new electronics as with old electronics at  Simulations of the W mass “bench- mark” confirm that pile-up will not limit our W mass at Run II.

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 13 Cell Capacitance Electronic noise Total 3.5 MeV U noise Estimates of Noise Contributions EM3 layer per cell  nF GeV

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 14 Electronics Calibration Goals  Calibrate electronics to better than 1%  Measure pedestals due to electronics and Ur noise  Determine zero suppression limits  Determine gains (x1,x8) from pulsed channels  Study channel-to-channel response; linearity  Commissioning  Bad channels  Trigger verification  Check channel mapping  Monitoring tool  Oracle Database for storage  Database used to download pedestals and zero-suppression limits to ADC boards

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 15 Preamp Box 2 Fanouts (2x3x16 switches ) switch Electronics Calibration System Pulser Trigger Power Supply PIB 6 commands (3x2) 96 currents Pulser Interface Board: VME interface automated calibration procedure Active Fanout with Switches: pulse shaping and distribution Open switch when receive command signal Pulser: DC current and command generator: DC current set by 18-bit DAC 96 enable registers 6-programmable 8-bit delays for command signals with 2ns step size LPNHE-Paris LAL-Orsay

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 16 Calibration Pulser Response  Linear response for DAC pulse height (0-65k)  Fully saturate ADC (at DAC= 90k)  Linearity of calibration and calorimeter electronics better than 0.2% (for DAC < 65k)  Cross-talk in neighboring channels < 1.5%  Uniformity of pulser modules better than 1%  No significant noise added from the calibration system  Correction factors need to be determined  mean Deviation from linearity Single channel (ADC vs. DAC) better than 0.2%

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 17 Pulser Signal Shapes Calorimeter Signal at Preamp Input Calibration Signal at Preamp Input Calorimeter Signal after Preamp and Shaper Calibration Signal after Preamp and Shaper 400ns  Response of calorimeter signal w.r.t. calibration signal <1% at max. signal for variation of different parameters (cable length, Z preamp, Z cable,…)  No test beam running  absolute energy scale will have to be established from the data  Maximum response time for EM and hadronic channels differ due to different preamp types. Use delays and modeling to accommodate these  Correct pulser response for different timings and shape  Use initial “guess” based on Monte-Carlo sampling weights and Spice models of the electronics. Signal reflection

2000 IEEE NSS Lyon,France Oct Hervé Lebbolo LPNHE ParisDØ Calorimeter Electronics Upgrade 18 Conclusions  Dzero is upgrading its detector  L.Argon calorimeter untouched  Harder machine conditions and new environment (solenoid) –New Calorimeter Electronics –Improved ICD –New Central and Forward Preshower  Similar performance with 20x more data  Run II start in 6 months