Simulation Studies for a Digital Hadron Calorimeter Arthur Maciel NIU / NICADD Saint Malo, April 12-15, 2002 Introduction to the DHCal Project Simulation.

Slides:

Advertisements

Similar presentations

CBM Calorimeter System CBM collaboration meeting, October 2008 I.Korolko(ITEP, Moscow)

Advertisements

LC Calorimeter Testbeam Requirements Sufficient data for Energy Flow algorithm development Provide data for calorimeter tracking algorithms  Help setting.

Quartz Plate Calorimeter Prototype Ugur Akgun The University of Iowa APS April 2006 Meeting Dallas, Texas.

Calorimetry Summary Dhiman Chakraborty, NIU Linear Collider Workshop UC Santa Cruz, 29-june-2002.

P. Gay Energy flow session1 Analytic Energy Flow F. Chandez P. Gay S. Monteil CALICE Coll.

A Study on Cluster Resolution Neighborhood hit density gradients are proposed as a means for -- identifying cluster boundaries -- implementing a cluster.

1 Study of the Tail Catcher Muon Tracker (TCMT) Scintillator Strips and Leakage with Simulated Coil Rick Salcido Northern Illinois University For CALICE.

Testbeam Requirements for LC Calorimetry S. R. Magill for the Calorimetry Working Group Physics/Detector Goals for LC Calorimetry E-flow implications for.

EF with simple multi-particle states Vishnu V. Zutshi NIU/NICADD.

Snowmass 25 AugustMark Thomson 1 PFA Progress and Priorities Mark Thomson (for Steve Magill, Felix Sefkow, Mark Thomson and Graham Wilson)  Progress at.

Off-axis Simulations Peter Litchfield, Minnesota  What has been simulated?  Will the experiment work?  Can we choose a technology based on simulations?

A first look at the digital approach Vishnu V. Zutshi NIU/NICADD.

Some early attempts at PFA Dhiman Chakraborty. LCWS05 Some early attempts at PFA Dhiman Chakraborty2 Introduction Primarily interested in exploring the.

GEM DHCAL Simulation Studies J. Yu* Univ. of Texas at Arlington ALCW, July 15, 2003 Cornell University (*on behalf of the UTA team; S. Habib, V. Kaushik,

 Track-First E-flow Algorithm  Analog vs. Digital Energy Resolution for Neutral Hadrons  Towards Track/Cal hit matching  Photon Finding  Plans E-flow.

 Performance Goals -> Motivation  Analog/Digital Comparisons  E-flow Algorithm Development  Readout R&D  Summary Optimization of the Hadron Calorimeter.

A preliminary analysis of the CALICE test beam data Dhiman Chakraborty, NIU for the CALICE Collaboration LCWS07, Hamburg, Germany May 29 - June 3, 2007.

Simulation of the DHCAL Prototype Lei Xia Argonne National Laboratory American Linear Collider Workshop: Ithaca, NY, July , 2003 Fe absorber Glass.

PFA Development – Definitions and Preparation 0) Generate some events w/G4 in proper format 1)Check Sampling Fractions ECAL, HCAL separately How? Photons,

Energy Flow Studies Steve Kuhlmann Argonne National Laboratory for Steve Magill, U.S. LC Calorimeter Group.

Jerry Blazey NIU/NICADD Towards A Scintillating (Semi)- Digital Hadron Calorimeter: Progress at NIU/NICADD Jerry Blazey Northern Illinois University.

Energy Flow Studies Steve Kuhlmann Argonne National Laboratory for Steve Magill, Brian Musgrave, Norman Graf, U.S. LC Calorimeter Group.

Scintillator (semi)DHCAL? Vishnu Zutshi for. Introduction Can a scintillator (semi)digital calorimeter work? Cell sizes are necessarily 6-12 cm 2 Can.

A Digital Hadron Calorimeter ? Vishnu V. Zutshi NIU/NICADD.

1/9/2003 UTA-GEM Simulation Report Venkatesh Kaushik 1 Simulation Study of Digital Hadron Calorimeter Using GEM Venkatesh Kaushik* University of Texas.

Track Extrapolation/Shower Reconstruction in a Digital HCAL – ANL Approach Steve Magill ANL 1 st step - Track extrapolation thru Cal – substitute for Cal.

Andy White U.Texas at Arlington (for J.Yu, C.Han, J.Li, D.Jenkins, J.Smith, K.Parmer, A.Nozawa, V.Kaushik) 10/18/04 IEEE/NSS Digital Hadron Calorimetry.

Progress with the Development of Energy Flow Algorithms at Argonne José Repond for Steve Kuhlmann and Steve Magill Argonne National Laboratory Linear Collider.

Development of Particle Flow Calorimetry José Repond Argonne National Laboratory DPF meeting, Providence, RI August 8 – 13, 2011.

The CALICE Si-W ECAL - physics prototype 2012/Apr/25 Tamaki Yoshioka (Kyushu University) Roman Poschl (LAL Orsay)

Introduction Multi-jets final states are of major interest for the LC Physics EFlow : An essential test to design the foreseen detector Software (Algorithms)

Simulation Studies for a Digital Hadron Calorimeter Arthur Maciel NIU / NICADD Saint Malo, April 12-15, 2002 Introduction to the DHCal Project Simulation.

Event Reconstruction in SiD02 with a Dual Readout Calorimeter Detector Geometry EM Calibration Cerenkov/Scintillator Correction Jet Reconstruction Performance.

26 Apr 2009Paul Dauncey1 Digital ECAL: Lecture 1 Paul Dauncey Imperial College London.

CALICE Digital Hadron Calorimeter: Calibration and Response to Pions and Positrons International Workshop on Future Linear Colliders LCWS 2013 November.

Development of a Particle Flow Algorithms (PFA) at Argonne Presented by Lei Xia ANL - HEP.

Two Density-based Clustering Algorithms L. Xia (ANL) V. Zutshi (NIU)

1 Calorimetry Simulations Norman A. Graf for the SLAC Group January 10, 2003.

UTA GEM DHCAL Simulation Jae Yu * UTA DoE Site Visit Nov. 13, 2003 (*On behalf of the UTA team; A. Brandt, K. De, S. Habib, V. Kaushik, J. Li, M. Sosebee,

Development of Digital Hadron Calorimeter Using GEM Shahnoor Habib For HEP Group, UT Arlington Oct. 12, 2002 TSAPS Fall ’02, UT Brownsville Simulation.

Simulation & Algorithms Update Development of Simulation Tools Development of Simulation Tools Calorimetry E-Flow Algorithms Calorimetry E-Flow Algorithms.

1 D.Chakraborty – VLCW'06 – 2006/07/21 PFA reconstruction with directed tree clustering Dhiman Chakraborty for the NICADD/NIU software group Vancouver.

Particle-flow Algorithms in America Dhiman Chakraborty N. I. Center for Accelerator & Detector Development for the International Conference.

1 Hadronic calorimeter simulation S.Itoh, T.Takeshita ( Shinshu Univ.) GLC calorimeter group Contents - Comparison between Scintillator and Gas - Digital.

1 1 - To test the performance 2 - To optimise the detector 3 – To use the relevant variable Software and jet energy measurement On the importance to understand.

Individual Particle Reconstruction The PFA Approach to Detector Development for the ILC Steve Magill (ANL) Norman Graf, Ron Cassell (SLAC)

Digital Hadron Calorimetry for the International Linear Collider Using Gas Electron Multiplier Technology Andy White University of Texas at Arlington (for.

Test Beam: Calorimetric Wishes… Steve Magill, Jose Repond, Andre Turcot, Jae Yu* Jan. 10, 2003 Goals for calorimeter test beam What’s needed for EFA? Requirements.

7/13/2005The 8th ACFA Daegu, Korea 1 T.Yoshioka (ICEPP), M-C.Chang(Tohoku), K.Fujii (KEK), T.Fujikawa (Tohoku), A.Miyamoto (KEK), S.Yamashita.

12/20/2006ILC-Sousei Annual KEK1 Particle Flow Algorithm for Full Simulation Study ILC-Sousei Annual KEK Dec. 20 th -22 nd, 2006 Tamaki.

Imaging Hadron Calorimeters for Future Lepton Colliders José Repond Argonne National Laboratory 13 th Vienna Conference on Instrumentation Vienna University.

1 Plannar Active Absorber Calorimeter Adam Para, Niki Saoulidou, Hans Wenzel, Shin-Shan Yu Fermialb Tianchi Zhao University of Washington ACFA Meeting.

Summary from NIU Workshop and Prague Summary from NIU Workshop and Prague S. R. Magill Physics and Detectors for a 90 to 800 GeV Linear Collider: Third.

Geant4-based detector simulation activities at NICADD Guilherme Lima for the NICADD simulations group December 2003.

HCAL Leakage Studies CLIC Physics & Detector Meeting 10. November 2008 Christian Grefe CERN.

CEPC 数字强子量能器读出电子学预研进展

SiD Calorimeter R&D Collaboration

slicPandora: slic + pandoraPFANew

State-of-the-art in Hadronic Calorimetry for the Lepton Collider

   Calorimetry et al.    SUMMARY 12 contributions Tile HCAL

EFA/DHCal development at NIU

Linear Collider Simulation Tools

Preliminary Results on Non-Projective HCal Simulations

Rick Salcido Northern Illinois University For CALICE Collaboration

Argonne National Laboratory

Detector Optimization using Particle Flow Algorithm

Status of CEPC HCAL Optimization Study in Simulation LIU Bing On behalf the CEPC Calorimeter working group.

Linear Collider Simulation Tools

Steve Magill Steve Kuhlmann ANL/SLAC Motivation

LC Calorimeter Testbeam Requirements

Presentation transcript:

Simulation Studies for a Digital Hadron Calorimeter Arthur Maciel NIU / NICADD Saint Malo, April 12-15, 2002 Introduction to the DHCal Project Simulation Tools and Models From Analog to Digital Towards an E-Flow Algorithm A Proposed Clustering Strategy Current Status, Future Plans

 A joint proposal for the development of digital hadron calorimetry technology for the Linear Collider  NIU investigates a scintillator based design  UTA investigates a gas based (GEM) design  ANL investigates an RPC based design  For hardware project details see talk by J. Repond Introduction Northern Illinois University ( NIU / NICADD ) University of Texas at Arlington ( UTA ) Argonne National Laboratory ( ANL ) October 2001 A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Main Goals of the Software Effort To assist in the design of a Digital Hadron Calorimeter (DHCAL)  Parameter Optimization e.g; transverse segmentation, cell depth and absorber density, detector depth, layer geometry, stack geometry, TRK-EM-HAD matching Feasibility and Resolution Reach of an Energy Flow Strategy  Identify energy deposition patterns (clusters) arising from individual particles  Efficient cluster resolution and reconstruction, with central track matching capability under expected Liner Collider (~TeV) conditions  Ability to discriminate charged.vs. neutral particle generated clusters Develop a solid notion of the Physics Reach (versus cost) A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Simulation Tools and Detector Model Linear Collider Detector Simulation Package Using the “SD” Detector Model (Snowmass 2001), as described in; EMHAD Inner Rad127 cm154 cm Outer Rad142 cm256 cm N.of layers3034 Z – max210 cm312 cm Segm.(θ x φ)840 x x 1200 Transv. cell size0.5 x 0.5 cm1 x 1 cm active layerSi, 0.4 mmPolyst 1cm passive layerW, 2.5mmS.Steel 2cm Rad-Int lengths20 – – 4 The SD Calorimeter Projective towers, inside a 5 Tesla B-field The NICADD “sioserver” A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Single Particle Resolution ( by V. Zutshi, NIU) Analog S = from sampling fractions Digital S = from cell counts σ/E Charged Pions, “SD” detector Analog vs Digital E (GeV) A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

DHCal Transverse Segmentation and Response Linearity DHCal Longitudinal Segmentation (absorber depth halved) Resolution 600 x x x 300 / Single Pions “SD” Detector ( by V. Zutshi, NIU) Segmentation Studies Analog vs Digital Analog vs Digital Analog vs Digital Conclusion; Conclusion; - No apparent penalty in energy resolution energy resolution - Obvious gains in spacial resolution (granularity) resolution (granularity) A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002 E (GeV)

K 0 L Analysis by S.Magill (ANL) – Analog Readout Compare to digital  e + e -  ZZ (500 GeV CM) Clustering from “MC-truth”  /mean ~ 26% Analog vs Digital “SD” Detector A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

ECAL behavior for K 0 L showers rms/mean ~ 30%rms/mean ~ 33% HCAL behavior for K 0 L showers A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Studies Towards an Energy Flow Algorithm Two distinct cell-clustering approaches currently being pursued; (1)A layer by layer search for local maxima (seeds) Nearest Neighbours cluster building Longitudinal matching (stacking) of layer clusters (2)Variable size 3D-Domain(θ, φ, ρ) search for local maxima Longitudinal matching (stacking) of such cell domains The plan is to; -investigate performances independently -understand strong/weak points -study a possible synergy between both approaches (i.e. collect best aspects into one hybrid method) A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Clustering by Domain Inspection A domain is a box ( n θ x m φ x l ρ ), all three variable and self adjusting after being given initial values ( in plots). Searches run in (n x m ) with slower-l acting as a test parameter. Search produces a set of (, ) centroids for layer matching. EM-Cal searches start around shower-max, proceed to edges. HAD-Cal searches start around the entry layer. Centroids are determined from local maxima (Energy / N.Hits). Domain “methods” investigate neighbourhood gradients for the resolution of nearby clusters. A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Transverse Profile Longitudinal Profile Cluster Energy Profiles for 10 GeV π ’s Transverse Profile Longitudinal Profile cell # layer # A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Cluster N.of Hits Profiles for 10 GeV π ’s Transverse Profile Longitudinal Profile Transverse Profile Longitudinal Profile cell # layer # A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Analog 10 GeV π’ s Digital Clustering by Domain Inspection A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Clustering by Domain Inspection Single Layer Matching Resolution for 10 GeV π ’s A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Clustering by Domain Inspection A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002 Analog 50 GeV π’ s Digital

Clustering by Domain Inspection Single Layer Matching Resolution for 50 GeV π ’s A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Preliminary Tests Using mono energetic single tracks Internal checks&consistency / debug Parameter selection, initial values Parameter stability, finding eff. Energy resolution, stacking resolution Analog.vs. Digital Results encouraging (still trivial) Next Steps Space resolution Develop domain methods to; - determine the transverse bounds of a cluster - resolve nearby clusters - implement a split-merge strategy - generate pattern recognition discriminators (isolation, neighbourhood gradients...) A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002

Centroid Determination Domain Energy Density Domain Energy Density 1 st Differential Centroid Isolation Example Domain Methods A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002 (Arbitrary units, similar w/ N.hits) Domain Energy Density 2 nd Differential 5k. 10GeV π ’s

Centroid Determination Domain Energy Density Domain Energy Density 1 st Differential Centroid Isolation Example Domain Methods A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002 Domain Energy Density 2 nd Differential Single 10GeV π (Arbitrary units, similar w/ N.hits)

Centroid Determination Domain Energy Density Domain Energy Density 1 st Differential Centroid Isolation Example Domain Methods A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002 (Arbitrary units, similar w/ N.hits) Domain Energy Density 2 nd Differential Single 20GeV π

A. Maciel, 2 nd ECFA-DESY Workshop, St. Malo, April 19, 2002 Summary, Prospects Work recently started on two E-Flow driven fronts. Now at the preliminary tests and tool development stage. Proceed soon to more detailed simulations ( GEANT4 ). Implement the NIU+UTA+ANL specific prototypes. Integrate E-Flow algorithm development into Linear Collider physics studies. Pursue a sharing of tools, models and methods with the L.C.Detector community, towards establishing common grounds for detector performance development.