Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mapping separation power Klaus Götzen GSI Darmstadt PID TAG Meeting 15. Feb. 2007.

Published byAmanda Wade Modified over 9 years ago

Similar presentations

Presentation on theme: "Mapping separation power Klaus Götzen GSI Darmstadt PID TAG Meeting 15. Feb. 2007."— Presentation transcript:

1 Mapping separation power Klaus Götzen GSI Darmstadt PID TAG Meeting 15. Feb. 2007

2 2 K. Götzen PID TAG Meeting – EVO – 15.02.08 Central Problem Problem: –What is necessary PID quality for PANDA, i.e. what minimal set of PID detectors is needed?... or to be more exact: –How much separation power do we need in which phase space region to reach our physics goals? Answering implies: 1.How good is separation over phase space? 2.Where is significant kinematic signal/background overlap?

3 3 K. Götzen PID TAG Meeting – EVO – 15.02.08 PID information Attempt to answer question No 1. At the moment: almost no reco‘d PID info from Full Sim Consider parametrized PID info in Fast Sim from det‘s –Barrel DIRC (  C )tcb –Endcap DIRC (  C )tcd –Forward RICH (  C )tcr –Straw Tube Tracker (dE/dx)des –Micro Vertex Detector (dE/dx)dem –Barrel TOF (m 2 )mt Dataset: 200k isotropic ( ,p) single track events of every particle type (e, , , K, p) 0° <  < 180° 0.15 GeV/c < p < 8 GeV/c

4 4 K. Götzen PID TAG Meeting – EVO – 15.02.08 Quality check barrel DIRC endcap DIRC forward RICH STT MVD TOF p [GeV/c 2 ] CC CC CC dE/dx m2m2

5 5 K. Götzen PID TAG Meeting – EVO – 15.02.08 Method Divide 2-D p,  region into bins for every bin & every 2 PID hypothesis (only ‚neighbours‘, i.e.: e-  /  -  /  -K / K-p) –plot the 2 distributions –determine mean values  i and RMS r i for both hypothesis (e.g.  and K) –separation power (number sigmas) is estimated as –colorize a 2-D map according to n 

6 6 K. Götzen PID TAG Meeting – EVO – 15.02.08 Example 1 CC CC K K    K = 0.7955 r K = 0.00288   = 0.8218 r  = 0.00239 (not really gauss‘sch)  K = 0.7071 r K = 0.01436   = 0.8147 r  = 0.00238 Barrel DIRC |p-2.0|<0.1 [GeV] |  -2|<0.2 |p-1.0|<0.1 [GeV] |  -2|<0.2

7 7 K. Götzen PID TAG Meeting – EVO – 15.02.08 Example 2 Barrel DIRC STT CC dE/dx K K    K = 0.817 r K = 0.00243   = 0.823 r  = 0.00239  K = 12.94 r K = 6.015   = 4.02 r  = 0.976 |p-4.0|<0.1 [GeV] |  -2|<0.2 |p-0.3|<0.1 [GeV] |  -2|<0.2

8 8 K. Götzen PID TAG Meeting – EVO – 15.02.08 Separation e - mu p [GeV]  [deg] p [GeV]  [deg] 0 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5

9 9 K. Götzen PID TAG Meeting – EVO – 15.02.08 Separation mu - pi p [GeV]  [deg] p [GeV]  [deg] 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5

10 10 K. Götzen PID TAG Meeting – EVO – 15.02.08 Separation pi - K p [GeV]  [deg] p [GeV]  [deg] 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5

11 11 K. Götzen PID TAG Meeting – EVO – 15.02.08 Separation K - p p [GeV]  [deg] p [GeV]  [deg] 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5 0 3 6 1 2 4 5

12 12 K. Götzen PID TAG Meeting – EVO – 15.02.08 Overall performance Combined n  given by expression Of course, there are still some flaws, but this is the preliminary separation power map!

13 13 K. Götzen PID TAG Meeting – EVO – 15.02.08 Signal / Background overlap How does this now apply to our physics cases? Compare the following: EvtGen: Kaon p-  distributions of benchmark channel, e.g. at different pbar momenta (1.432, 5.0, 10.0, 15.0 GeV/c) DPM Gen: Pion p-  distribution at same energies Determine kinematic overlap regions and look how good separation power is there

14 14 K. Götzen PID TAG Meeting – EVO – 15.02.08 p pbar = 1.432 / 5.0 GeV/c  bkg K, signalproduct of histo‘s (overlap) p = 1.432 GeV/c p = 5.0 GeV/c  bkg K, signalproduct of histo‘s (overlap)

15 15 K. Götzen PID TAG Meeting – EVO – 15.02.08 p pbar = 10.0 / 15.0 GeV/c  bkg K, signalproduct of histo‘s (overlap) p = 10.0 GeV/c p = 15.0 GeV/c  bkg K, signalproduct of histo‘s (overlap)

16 16 K. Götzen PID TAG Meeting – EVO – 15.02.08 Combining information

17 17 K. Götzen PID TAG Meeting – EVO – 15.02.08 Combining information @ 1.432 GeV/c

18 18 K. Götzen PID TAG Meeting – EVO – 15.02.08 Combining information @ 15.0 GeV/c

19 19 K. Götzen PID TAG Meeting – EVO – 15.02.08 Combining information @ 15.0 GeV/c problem here?

20 20 K. Götzen PID TAG Meeting – EVO – 15.02.08 Summary Task: Recommendation for minimum set of PID detectors Attempt to determine –Separation power p-  dependent –Regions, where it‘s acctually needed Limitations –Information based on parametrizations only –No EMC informations so far –Dsitributions are not gaussian  does our definition of sep. power make sense here –Due to finite granularity (bin width)  artifacts in the map –Is the estimate for the total n ,tot correct?

Download ppt "Mapping separation power Klaus Götzen GSI Darmstadt PID TAG Meeting 15. Feb. 2007."

Similar presentations

Development of the Partical IDentification in the PANDA – Experiment Report in the Technical Board Georg Schepers for the PID TAG PANDA – meeting 18. September.

Development of the Partical IDentification in the PANDA – Experiment Report in the Technical Board Georg Schepers for the PID TAG PANDA – meeting 18. September.
CBM Calorimeter System CBM collaboration meeting, October 2008 I.Korolko(ITEP, Moscow)

CBM Calorimeter System CBM collaboration meeting, October 2008 I.Korolko(ITEP, Moscow)
Application of Straw Tube Detectors to Hyperon Studies Sedigheh Jowzaee Symposium on Applied Nuclear Physics and Innovative Technologies 24-27 Sep. 2014,

Application of Straw Tube Detectors to Hyperon Studies Sedigheh Jowzaee Symposium on Applied Nuclear Physics and Innovative Technologies Sep. 2014,
Fast simulator for Super-Belle Christoph Schwanda HEPHY, Austrian Academy of Sciences BNM 2008, 3rd Int. Workshop on B Factories and New Measurements Atami,

Fast simulator for Super-Belle Christoph Schwanda HEPHY, Austrian Academy of Sciences BNM 2008, 3rd Int. Workshop on B Factories and New Measurements Atami,
14 Sept 2004 D.Dedovich Tau041 Measurement of Tau hadronic branching ratios in DELPHI experiment at LEP Dima Dedovich (Dubna) DELPHI Collaboration E.Phys.J.

14 Sept 2004 D.Dedovich Tau041 Measurement of Tau hadronic branching ratios in DELPHI experiment at LEP Dima Dedovich (Dubna) DELPHI Collaboration E.Phys.J.
Concept of the PANDA Detector for pp&pA at GSI Physical motivation for hadron physics with pbars The antiproton facility Detector concept Selected simulation.

Concept of the PANDA Detector for pp&pA at GSI Physical motivation for hadron physics with pbars The antiproton facility Detector concept Selected simulation.
Status Analysis pp -> D s D s0 (2317) Overview Reconstruction Some QA plots Figure of merit First approach/strategy.

Status Analysis pp -> D s D s0 (2317) Overview Reconstruction Some QA plots Figure of merit First approach/strategy.
Emily Thompson May 5 – UMass HEP Exp Group Meeting 1 Tag-probe method: Fitting Z → μ + μ - mass peaks Motivation: 1. Want to use long p T tail of muon.

Emily Thompson May 5 – UMass HEP Exp Group Meeting 1 Tag-probe method: Fitting Z → μ + μ - mass peaks Motivation: 1. Want to use long p T tail of muon.
James Ritman Univ. Giessen PANDA: Experiments to Study the Properties of Charm in Dense Hadronic Matter Overview of the PANDA Pbar-A Program The Pbar Facility.

James Ritman Univ. Giessen PANDA: Experiments to Study the Properties of Charm in Dense Hadronic Matter Overview of the PANDA Pbar-A Program The Pbar Facility.
16 April 2005 APS 2005 Search for exclusive two body decays of B→D s * h at Belle Luminda Kulasiri University of Cincinnati Outline Motivation Results.

16 April 2005 APS 2005 Search for exclusive two body decays of B→D s * h at Belle Luminda Kulasiri University of Cincinnati Outline Motivation Results.
Topological D-meson Reconstruction with STAR Using the Silicon Vertex Tracker (SVT) Sarah LaPointe Wayne State University SVT review, BNL, July 7 th /8.

Topological D-meson Reconstruction with STAR Using the Silicon Vertex Tracker (SVT) Sarah LaPointe Wayne State University SVT review, BNL, July 7 th /8.
1 BaBar Collaboration Randall Sobie Institute for Particle Physics University of Victoria.

1 BaBar Collaboration Randall Sobie Institute for Particle Physics University of Victoria.
Oct. 5 th 2011 8 th International Workshop on Heavy Quarkonium 2011 Jim Ritman Mitglied der Helmholtz-Gemeinschaft Status of PANDA.

Oct. 5 th th International Workshop on Heavy Quarkonium 2011 Jim Ritman Mitglied der Helmholtz-Gemeinschaft Status of PANDA.
Count rate estimates from TDR Assuming beam intenisties from previous slide and acc *rec from SIM LH2 case [counts/24h] p [GeV/c] beam momentum Solid.

Count rate estimates from TDR Assuming beam intenisties from previous slide and acc *rec from SIM LH2 case [counts/24h] p [GeV/c] beam momentum Solid.
1 Physics Impact of Detector Performance Tim Barklow SLAC March 18, 2005.

1 Physics Impact of Detector Performance Tim Barklow SLAC March 18, 2005.
TOF (and Global) PID F. Pierella for the TOF-Offline Group INFN & Bologna University PPR Meeting, January 2003.

TOF (and Global) PID F. Pierella for the TOF-Offline Group INFN & Bologna University PPR Meeting, January 2003.
PPR meeting - January 23, 2003 Andrea Dainese 1 TPC tracking parameterization: a useful tool for simulation studies with large statistics Motivation Implementation.

PPR meeting - January 23, 2003 Andrea Dainese 1 TPC tracking parameterization: a useful tool for simulation studies with large statistics Motivation Implementation.
GlueX Particle Identification Ryan Mitchell Indiana University Detector Review, October 2004.

GlueX Particle Identification Ryan Mitchell Indiana University Detector Review, October 2004.
Current Status of Hadron Analysis Introduction Hadron PID by PHENIX-TOF  Current status of charged hadron PID  CGL and track projection point on TOF.

Current Status of Hadron Analysis Introduction Hadron PID by PHENIX-TOF  Current status of charged hadron PID  CGL and track projection point on TOF.
D 0 Measurement in Cu+Cu Collisions at √s=200GeV at STAR using the Silicon Inner Tracker (SVT+SSD) Sarah LaPointe Wayne State University For the STAR Collaboration.

D 0 Measurement in Cu+Cu Collisions at √s=200GeV at STAR using the Silicon Inner Tracker (SVT+SSD) Sarah LaPointe Wayne State University For the STAR Collaboration.

Similar presentations

Ads by Google