Presentation is loading. Please wait.

Presentation is loading. Please wait.

Requirements to RICH FEE Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 10 March 2005.

Published byHoward Jordan Modified over 9 years ago

Similar presentations

Presentation on theme: "Requirements to RICH FEE Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 10 March 2005."— Presentation transcript:

1 Requirements to RICH FEE Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 10 March 2005

2 B M C Parameters of the PMT FEU-Hive External PMT diameter is 6 mm Photo-cathode diameter is 5 mm Photo-detector element diameter 7 mm PMT length is 60-70 mm Photo-cathode: K 2 CsSb Quantum efficiency at 410 nm is 25% Effective number of dynodes is 12 Nominal HV is less than 2 kV Amplification is 10 6 Dynamical charge range is 0.25-2.5 pC Noise current is 3000 e/sec Capacitance is 15 pF Power dissipations is 40 mW

3 B M C Inputs for RICH Front End Electronics on the base of the PMT FEU-Hive: Negative polarity of the output signals Total charge in a pulse – from 0.25 to 25 pC Noise -- 3000 e/sec Pulse lenght -- several ns Output capasitance -- 15 pF ADC bit number -- 8-9 bits Channel density -- 2.5 channels /cm2 Total number of channels – 100000- 200000

4 B M C HV regulation Classical scheme of the HV regulation with ballast resistor and PMT dividing sercuit The ballast resistor has 6 bit regulation in the region 1.6-2 kV, i.e. with 6V step Avaliable space, we have only 0.4 cm2/channel, due to this we have, probably, no possibility for the HV regulation

5 B M C Summary Nominal HV for the PMT is 2 kV No HV regulation, but pre-selection of the PMTs with different gains Power consumption 40 mW/PMT due to HV divider 8-9 bit ADC The width of the PMT signal is several ns Shaper time depends on requirements to the time resolution, it should be at least 3 time samples for any PMT pulse, thus τ ~ 3/F clock The main problem is the electronics density, i.e. 0.4 cm2/channel

Download ppt "Requirements to RICH FEE Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 10 March 2005."

Similar presentations

Electronics for large LAr TPC’s F. Pietropaolo (ICARUS Collaboration) CRYODET Workshop LNGS, 13-14 March 2006.

Electronics for large LAr TPC’s F. Pietropaolo (ICARUS Collaboration) CRYODET Workshop LNGS, March 2006.
INSTITUT MAX VON LAUE - PAUL LANGEVIN Fast Real-time SANS Detectors Charge Division in Individual, 1-D Position- sensitive Gas Detectors Patrick Van Esch.

INSTITUT MAX VON LAUE - PAUL LANGEVIN Fast Real-time SANS Detectors Charge Division in Individual, 1-D Position- sensitive Gas Detectors Patrick Van Esch.
E. Atkin, E. Malankin, V. Shumikhin NRNU MEPhI, Moscow 1.

E. Atkin, E. Malankin, V. Shumikhin NRNU MEPhI, Moscow 1.
Tagger Electronics Part 1: tagger focal plane microscope Part 2: tagger fixed array Part 3: trigger and digitization Richard Jones, University of Connecticut.

Tagger Electronics Part 1: tagger focal plane microscope Part 2: tagger fixed array Part 3: trigger and digitization Richard Jones, University of Connecticut.
Calibration of the 10inch PMT for IceCube Experiment 03UM1106 Kazuhiro Fujimoto A thesis submitted in partial fulfillment of the requirements of the degree.

Calibration of the 10inch PMT for IceCube Experiment 03UM1106 Kazuhiro Fujimoto A thesis submitted in partial fulfillment of the requirements of the degree.
Update on Electronics Activities Jim Pilcher University of Chicago 20-Jan-2006.

Update on Electronics Activities Jim Pilcher University of Chicago 20-Jan-2006.
Large Area, High Speed Photo-detectors Readout Jean-Francois Genat + On behalf and with the help of Herve Grabas +, Samuel Meehan +, Eric Oberla +, Fukun.

Large Area, High Speed Photo-detectors Readout Jean-Francois Genat + On behalf and with the help of Herve Grabas +, Samuel Meehan +, Eric Oberla +, Fukun.
Development of novel R/O electronics for LAr detectors 6.10.2006 Max Hess Controller ADC Data Reduction Ethernet 10/100Mbit Host Detector typical block.

Development of novel R/O electronics for LAr detectors Max Hess Controller ADC Data Reduction Ethernet 10/100Mbit Host Detector typical block.
Veto Wall Test Hyupwoo Lee MINERvA/Jupiter Group Meeting Apr, 16, 2008.

Veto Wall Test Hyupwoo Lee MINERvA/Jupiter Group Meeting Apr, 16, 2008.
Time Projection Chamber for the R 3 B set-up Combination of detectors upstream (target) & downstream of the magnet  Improvement of A, Z & E * balances.

Time Projection Chamber for the R 3 B set-up Combination of detectors upstream (target) & downstream of the magnet  Improvement of A, Z & E * balances.
Time over Threshold Electronics for Neutrino Telescopy George Bourlis + multiplicity.

Time over Threshold Electronics for Neutrino Telescopy George Bourlis + multiplicity.
CBM Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 12 February 2004.

CBM Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 12 February 2004.
ECAL electronics Guido Haefeli, Lausanne PEBS meeting 10.Jan. 2011 1.

ECAL electronics Guido Haefeli, Lausanne PEBS meeting 10.Jan
Photon detection Visible or near-visible wavelengths

Photon detection Visible or near-visible wavelengths
T. Sumiyoshi (TMU) 30, Nov. 2004 del Carmen 1 Development of HPD (HAP D) Photon-detector for the Aerogel RICH Photon-detector for the Aerogel.

T. Sumiyoshi (TMU) 30, Nov del Carmen 1 Development of HPD (HAP D) Photon-detector for the Aerogel RICH Photon-detector for the Aerogel.
Preliminary LumiCAL FEE Specification Presented by Alexander Solin NC PHEP FCAL collaboration meeting, February 12-13, 2006, Krakow (INP PAS),

Preliminary LumiCAL FEE Specification Presented by Alexander Solin NC PHEP FCAL collaboration meeting, February 12-13, 2006, Krakow (INP PAS),
Chamber parameters that we can modify and that affect the rising time Number of ionisation clusters produced in the drift gap: Poisson Distribution Probability.

Chamber parameters that we can modify and that affect the rising time Number of ionisation clusters produced in the drift gap: Poisson Distribution Probability.
RICH Development Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 9 March 2005.

RICH Development Serguei Sadovsky IHEP, Protvino CBM meeting GSI, 9 March 2005.
MR (7/7/05) T2K electronics Beam structure ~ 8 (9?) bunches / spill bunch width ~ 60 nsec bunch separation ~ 600 nsec spill duration ~ 5  sec Time between.

MR (7/7/05) T2K electronics Beam structure ~ 8 (9?) bunches / spill bunch width ~ 60 nsec bunch separation ~ 600 nsec spill duration ~ 5  sec Time between.
1 Max-Planck-Institut fuer Physik, Muenchen, Germany, 2 Humboldt-Universituet Berlin, Germany, 3 Univ. Complutense, Madrid, Spain, 4 ETH, Zurich, Switzerland,

1 Max-Planck-Institut fuer Physik, Muenchen, Germany, 2 Humboldt-Universituet Berlin, Germany, 3 Univ. Complutense, Madrid, Spain, 4 ETH, Zurich, Switzerland,

Similar presentations

Ads by Google