Presentation is loading. Please wait.

Presentation is loading. Please wait.

Background understanding and detector inefficiency

Published byHerman Suparman Tanuwidjaja Modified over 5 years ago

Similar presentations

Presentation on theme: "Background understanding and detector inefficiency"— Presentation transcript:

1 Background understanding and detector inefficiency
Can we understand the remaining events from a view of photon inefficiency ? ( if possible, subtract them as backgrounds.) An Idea : Special trigger Kp2 but one photon is missed. (2) Event reconstruction Missing photon kinematics (3) Photon inefficiency as a function of its energy and direction ? NOTE : Different type of critical backgrounds.         Geometrical dependence : Detector hole, dead material Energy dependence   : Photonuclear interaction …

2 Phase space correction factors
Polar angle distribution Correction factors Monte Carlo simulation Real data

3 Daughter Table Method w/ Binominal error Convoluted inefficiency
Daughter tables produced by random number generator 300 daughter tables

4 p0  gg background subtraction

5

6 p0  gg background subtraction

7 Improvement by the subtraction
Upper limit on Improvement (Before/After) Before subtraction After subtraction

8

9

10

11 Convoluted p0 rejection
Results Dip angle dependence Next Slide … p0 rejection from 1gamma inefficiency tables. p0 rejection from real data (from pnn1 analysis.) p0 rejection from 1gamma inefficiency tables. p0 rejection from real data (from pnn1 analysis.)

12 Stretch functions

13 Kinematical Fitting Before/After
Performance checks with MC sample

14 c2 Probability from Kin Fitting
Kp2(1) for denominator map 1gamma for numerator map

15 Self-vetoing effect due to split photon
MC simulation Missing photon kinematics

16 Single Photon Inefficiency

17 Single Photon Inefficiency

18 p0  gg detection inefficiency
(1) Photon kinematics (2) Single photon inefficiency from MC simulation

19 Daughter Table Method w/ Binominal error Convoluted inefficiency
Daughter tables produced by random number generator 300 daughter tables

20 Polar angle distribution Correction factors
Monte Carlo simulation Real data

21 p0  gg background subtraction

22

23 p0  gg background subtraction

24 Improvement by the subtraction
Upper limit on Improvement (Before/After) Before subtraction After subtraction

25

26

27

28 Abs(sin(theta)) < 0.45 Energy leakage Einner > 10 MeV

29 Fiducial Constraints

30 Performance of the clustering Method
MC sample theta

31 p0 gg backgrounds Photon inefficiency 20<Eg[MeV]<225
Low energy g : sampling fluctuation High energy g: photonuclear interaction ( hard to simulate reliably.) Detector photon inefficiency (measured with real data) 20~40MeV 40~60MeV 60~80MeV 80~100MeV 100~120MeV 120~140MeV 140~160MeV

Download ppt "Background understanding and detector inefficiency"

Similar presentations

XXXX eme Rencontres de Moriond Pierre COLIN March 2005 Pierre Colin Dmitry Naumov Patrick Nedelec RECONSTRUCTION OF EXTENSIVE AIR SHOWERS FROM SPACE Stand.

XXXX eme Rencontres de Moriond Pierre COLIN March 2005 Pierre Colin Dmitry Naumov Patrick Nedelec RECONSTRUCTION OF EXTENSIVE AIR SHOWERS FROM SPACE Stand.
Hadron production in hard scattering Event GeneratorGEANT.

Hadron production in hard scattering Event GeneratorGEANT.
Barbara Sciascia – LNF 1 K  semileptonic BR measurement B. Sciascia 4 may 2006 KpmKSL joint meeting.

Barbara Sciascia – LNF 1 K  semileptonic BR measurement B. Sciascia 4 may 2006 KpmKSL joint meeting.
Multiplicity analysis and dN/d  reconstruction with the silicon pixel detector Terzo Convegno Nazionale sulla Fisica di ALICE Frascati (Italy) – November.

Multiplicity analysis and dN/d  reconstruction with the silicon pixel detector Terzo Convegno Nazionale sulla Fisica di ALICE Frascati (Italy) – November.
Study of the e + e   η  process at √s = 1 GeV (main systematic error in the e + e   e + e  η analysis) 09-02-2010.

Study of the e + e   η  process at √s = 1 GeV (main systematic error in the e + e   e + e  η analysis)
July 2001 Snowmass A New Measurement of  from KTeV Introduction The KTeV Detector  Analysis of 1997 Data Update of Previous Result Conclusions.

July 2001 Snowmass A New Measurement of  from KTeV Introduction The KTeV Detector  Analysis of 1997 Data Update of Previous Result Conclusions.
QCD Meeting July 23, 2004 Is it due to the hard collision? Is it due to fragmentation? Strong polarization seen in fixed-target experiments where jet NOT.

QCD Meeting July 23, 2004 Is it due to the hard collision? Is it due to fragmentation? Strong polarization seen in fixed-target experiments where jet NOT.
W Mass & Width Measurement at LEP II BEACH 04, IIT Chicago, 08/03/04 Ambreesh Gupta, University of Chicago.

W Mass & Width Measurement at LEP II BEACH 04, IIT Chicago, 08/03/04 Ambreesh Gupta, University of Chicago.
A Search for Point Sources of High Energy Neutrinos with AMANDA-B10 Scott Young, for the AMANDA collaboration UC-Irvine PhD Thesis:

A Search for Point Sources of High Energy Neutrinos with AMANDA-B10 Scott Young, for the AMANDA collaboration UC-Irvine PhD Thesis:
Study of e + e  collisions with a hard initial state photon at BaBar Michel Davier (LAL-Orsay) for the BaBar collaboration TM.

Study of e + e  collisions with a hard initial state photon at BaBar Michel Davier (LAL-Orsay) for the BaBar collaboration TM.
Computational Lab in Physics: Final Project Monte Carlo Nuclear Collisions: Glauber Model.

Computational Lab in Physics: Final Project Monte Carlo Nuclear Collisions: Glauber Model.
Crossed Channel Compton Scattering Michael Düren and George Serbanut, II. Phys. Institut, - some remarks on cross sections and background processes  

Crossed Channel Compton Scattering Michael Düren and George Serbanut, II. Phys. Institut, - some remarks on cross sections and background processes  
Spasimir Balev /CERN/ 14.12.2010. 2 20 mrad 3 LKr simulation: – very slow, so only events with interesting topology are fully simulated: –  + with.

Spasimir Balev /CERN/ mrad 3 LKr simulation: – very slow, so only events with interesting topology are fully simulated: –  + with.
Rare B  baryon decays Jana Thayer University of Rochester CLEO Collaboration EPS 2003 July 19, 2003 Motivation Baryon production in B decays Semileptonic.

Rare B  baryon decays Jana Thayer University of Rochester CLEO Collaboration EPS 2003 July 19, 2003 Motivation Baryon production in B decays Semileptonic.
PoGO_G4_2004-02-03.ppt1 Study on Key Properties of PoGO by Geant4 Simulator January 28, 2004 Tsunefumi Mizuno History of changes:

PoGO_G4_ ppt1 Study on Key Properties of PoGO by Geant4 Simulator January 28, 2004 Tsunefumi Mizuno History of changes:
Gus Sinnis Asilomar Meeting 11/16/2003 The Next Generation All-Sky VHE Gamma-Ray Telescope.

Gus Sinnis Asilomar Meeting 11/16/2003 The Next Generation All-Sky VHE Gamma-Ray Telescope.
Review of GlueX FCAL Design Richard Jones, University of Connecticut GlueX collaboration meetingSept 9-11 2004, Newport News as presented by Scott Teige,

Review of GlueX FCAL Design Richard Jones, University of Connecticut GlueX collaboration meetingSept , Newport News as presented by Scott Teige,
Detection of electromagnetic showers along muon tracks Salvatore Mangano (IFIC)

Detection of electromagnetic showers along muon tracks Salvatore Mangano (IFIC)
 0  5  Outline Event selection & analysis Background rejection Efficiencies Mass spectrum Comparison data-MC Branching ratio evaluation Systematics.

 0  5  Outline Event selection & analysis Background rejection Efficiencies Mass spectrum Comparison data-MC Branching ratio evaluation Systematics.
Experimental Search for the Decay K. Mizouchi (Kyoto University) (1) Physics Motivation (2) Detector (3) Selection Criteria (4) Branching Ratio (5) Background.

Experimental Search for the Decay K. Mizouchi (Kyoto University) (1) Physics Motivation (2) Detector (3) Selection Criteria (4) Branching Ratio (5) Background.

Similar presentations

Ads by Google