/// are built from AliTrackReference for the hit in chamber (0..9) and from
/// kinematics (TreeK) for the vertex parameters.
///
-/// \author Jean-Pierre Cussonneau, Subatech
+/// \author Jean-Pierre Cussonneau, Philippe Pillot, Subatech
// ROOT includes
-#include "TClonesArray.h"
+#include <Riostream.h>
+#include "TMath.h"
+#include "TObjArray.h"
#include "TH1.h"
+#include "TH2.h"
+#include "TH3.h"
+#include "TGraphErrors.h"
+#include "TGraphAsymmErrors.h"
+#include "TF1.h"
#include "TFile.h"
-#include <TGeoManager.h>
+#include "TCanvas.h"
+#include "TLegend.h"
+#include "TGeoManager.h"
// STEER includes
-#include "AliRun.h"
-#include "AliHeader.h"
-#include "AliMC.h"
-#include "AliStack.h"
-#include "AliMagF.h"
-#include "AliTracker.h"
+#include "AliCDBManager.h"
+#include "AliGeomManager.h"
+#include "AliLog.h"
// MUON includes
+#include "AliMUONCDB.h"
#include "AliMUONConstants.h"
#include "AliMUONTrack.h"
#include "AliMUONRecoCheck.h"
#include "AliMUONTrackParam.h"
-#include "AliMUONTrackExtrap.h"
+#include "AliMUONRecoParam.h"
#include "AliMUONVTrackStore.h"
+#include "AliMUONVCluster.h"
+#include "AliMUONTrackExtrap.h"
+#include "AliMUONESDInterface.h"
+#include "AliMUONVTriggerTrackStore.h"
+#include "AliMUONTriggerTrack.h"
-Int_t TrackCheck( Bool_t *compTrack);
+Double_t langaufun(Double_t *x, Double_t *par);
+void FitGausResVsMom(TH2* h, Int_t nBins, const Double_t mean0, const Double_t sigma0, const char* fitting, TGraphAsymmErrors* gMean, TGraphAsymmErrors* gSigma);
+void FitPDCAVsMom(TH2* h, Int_t nBins, const char* fitting, TGraphAsymmErrors* gMean, TGraphAsymmErrors* gSigma);
+TCanvas* DrawVsAng(const char* name, const char* title, TH1* h1, TH2* h2);
+TCanvas* DrawVsPos(const char* name, const char* title, TH2* h1, TH2* h2, TH2* h3);
+TCanvas* DrawResMomVsMom(const char* name, const char* title, TH2* h, Int_t nBins, TF1* f2 = 0x0, const char* fitting = "");
-void MUONRecoCheck (Int_t nEvent = -1, char* geoFilename = "geometry.root",
- char * pathSim="./generated/", char * esdFileName="AliESDs.root")
+//------------------------------------------------------------------------------------
+void MUONRecoCheck(Int_t nEvent = -1, const char* pathSim="./generated/", const char* esdFileName="AliESDs.root",
+ const char* ocdbPath = "local://$ALICE_ROOT/OCDB", const Double_t pMin = 0., const Double_t pMax = 300.,
+ const Int_t pNBins = 30, Int_t absorberRegion = -1)
{
+ /// Associate the reconstructed tracks with the simulated ones and check the quality of the reconstruction
+ /// (tracking/trigger efficiency; momentum, slope,... resolutions at first cluster and at vertex; cluster resolution).
+ /// - You can choose the momentum range and number of bins used to study the track resolution versus momentum.
+ /// - You can limit the calculation of track resolution at vertex to the tracks crossing the absorber in a given region
+ /// with the flag "absorberRegion": -1=all, 1=[2,3]deg, 2=[3,10]deg.
- Bool_t compTrack[10];
- Bool_t compTrackOK[10];
- Int_t nClusterOk = 0;
- Int_t testTrack = 0;
- Int_t iTrack = 0;
- AliMUONTrack* trackOK(0x0);
- Int_t trackID = 0;
- Double_t sigmaCut = 4.; // 4 sigmas cut
- Double_t maxChi2 = 999.;
- AliMUONTrackParam *trackParam;
- Double_t x1,y1,z1,pX1,pY1,pZ1,p1;
- Double_t x2,y2,z2,pX2,pY2,pZ2,p2;
+ Double_t aAbsLimits[2];
+ if (absorberRegion > -1) {
+ if (absorberRegion == 1) {
+ aAbsLimits[0] = 2.;
+ aAbsLimits[1] = 3.;
+ } else if (absorberRegion == 2) {
+ aAbsLimits[0] = 3.;
+ aAbsLimits[1] = 10.;
+ } else {
+ cout<<"Unknown absorber region. Valid choices are: -1=all, 1=[2,3]deg, 2=[3,10]deg"<<endl;
+ return;
+ }
+ } else {
+ aAbsLimits[0] = 0.;
+ aAbsLimits[1] = 90.;
+ }
+
+ cout<<endl<<"Momentum range for track resolution studies: "<<pNBins<<" bins in ["<<pMin<<","<<pMax<<"] GeV/c"<<endl;
+ if (pMin >= pMax || pNBins <= 0) {
+ cout<<"--> incorrect momentum range"<<endl<<endl;
+ return;
+ } else cout<<endl;
+
+ AliLog::SetClassDebugLevel("AliMCEvent",-1);
+ // ###################################### define histograms ###################################### //
// File for histograms and histogram booking
TFile *histoFile = new TFile("MUONRecoCheck.root", "RECREATE");
- TH1F *hReconstructible = new TH1F("hReconstructible"," Nb of reconstructible tracks ",15,-0.5,14.5);
+ TH1F *hReconstructible = new TH1F("hReconstructible"," Nb of reconstructible tracks / evt",15,-0.5,14.5);
TH1F *hReco = new TH1F("hReco"," Nb of reconstructed tracks / evt",15,-0.5,14.5);
TH1F *hNClusterComp = new TH1F("hNClusterComp"," Nb of compatible clusters / track ",15,-0.5,14.5);
- TH1F *hTestTrack = new TH1F("hTestTrack"," Reconstruction requirement / track",15,-0.5,14.5);
TH1F *hTrackRefID = new TH1F("hTrackRefID"," track reference ID ",100,-0.5,99.5);
+ TH1F *hTriggerable = new TH1F("hTriggerable"," Nb of triggerable tracks / evt",15,-0.5,14.5);
+ TH1F *hTriggered = new TH1F("hTriggered"," Nb of triggered tracks / evt",15,-0.5,14.5);
- TH1F *hResMomVertex = new TH1F("hResMomVertex"," delta P vertex (GeV/c)",100,-10.,10);
- TH1F *hResMomFirstCluster = new TH1F("hResMomFirstCluster"," delta P first cluster (GeV/c)",100,-10.,10);
+ // momentum resolution at vertex
+ histoFile->mkdir("momentumAtVertex","momentumAtVertex");
+ histoFile->cd("momentumAtVertex");
- // Import TGeo geometry (needed by AliMUONTrackExtrap::ExtrapToVertex)
- if (!gGeoManager) {
- TGeoManager::Import(geoFilename);
- if (!gGeoManager) {
- Error("MUONmass_ESD", "getting geometry from file %s failed", geoFilename);
- return;
- }
- }
+ const Double_t pEdges[2] = {pMin, pMax};
+ const Int_t deltaPAtVtxNBins = 250;
+ Double_t deltaPAtVtxEdges[2];
+ if (pMax < 50.) { deltaPAtVtxEdges[0] = -20.; deltaPAtVtxEdges[1] = 5.; }
+ else { deltaPAtVtxEdges[0] = -35.; deltaPAtVtxEdges[1] = 15.; }
+
+ TH1F *hResMomVertex = new TH1F("hResMomVertex"," delta P at vertex;#Delta_{p} (GeV/c)",deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+
+ TH2D *hResMomVertexVsMom = new TH2D("hResMomVertexVsMom","#Delta_{p} at vertex versus p;p (GeV/c);#Delta_{p} (GeV/c)",2*pNBins,pEdges[0],pEdges[1],deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH2D *hResMomVertexVsMom_2_3_Deg = new TH2D("hResMomVertexVsMom_2_3_Deg","#Delta_{p} at vertex versus p for tracks between 2 and 3 degrees at absorber end;p (GeV/c);#Delta_{p} (GeV/c)",2*pNBins,pEdges[0],pEdges[1],deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH2D *hResMomVertexVsMom_3_10_Deg = new TH2D("hResMomVertexVsMom_3_10_Deg","#Delta_{p} at vertex versus p for tracks between 3 and 10 degrees at absorber end;p (GeV/c);#Delta_{p} (GeV/c)",2*pNBins,pEdges[0],pEdges[1],deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH2D *hResMomVertexVsMom_0_2_DegMC = new TH2D("hResMomVertexVsMom_0_2_DegMC","#Delta_{p} at vertex versus p for tracks with MC angle below 2 degrees;p (GeV/c);#Delta_{p} (GeV/c)",2*pNBins,pEdges[0],pEdges[1],deltaPAtVtxNBins/10,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+
+ TH2D *hResMomVertexVsPosAbsEnd_0_2_DegMC = new TH2D("hResMomVertexVsPosAbsEnd_0_2_DegMC","#Delta_{p} at vertex versus track position at absorber end for tracks with MC angle < 2 degrees;position (cm);#Delta_{p} (GeV/c)",1000,0.,100.,deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH2D *hResMomVertexVsPosAbsEnd_2_3_DegMC = new TH2D("hResMomVertexVsPosAbsEnd_2_3_DegMC","#Delta_{p} at vertex versus track position at absorber end for tracks with MC angle in [2,3[ degrees;position (cm);#Delta_{p} (GeV/c)",1000,0.,100.,deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH2D *hResMomVertexVsPosAbsEnd_3_10_DegMC = new TH2D("hResMomVertexVsPosAbsEnd_3_10_DegMC","#Delta_{p} at vertex versus track position at absorber end for tracks with MC angle in [3,10[ degrees;position (cm);#Delta_{p} (GeV/c)",1000,0.,100.,deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+
+ TH2D *hResMomVertexVsAngle = new TH2D("hResMomVertexVsAngle","#Delta_{p} at vertex versus track position at absorber end converted to degrees;angle (Deg);#Delta_{p} (GeV/c)",10,0.,10.,deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH2D *hResMomVertexVsMCAngle = new TH2D("hResMomVertexVsMCAngle","#Delta_{p} at vertex versus MC angle;MC angle (Deg);#Delta_{p} (GeV/c)",10,0.,10.,deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+ TH3D *hResMomVertexVsAngleVsMom = new TH3D("hResMomVertexVsAngleVsMom","#Delta_{p} at vertex versus track position at absorber end converted to degrees versus momentum;p (GeV/c);angle (Deg);#Delta_{p} (GeV/c)",2*pNBins,pEdges[0],pEdges[1],100,0.,10.,deltaPAtVtxNBins,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1]);
+
+ TGraphAsymmErrors* gMeanResMomVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResMomVertexVsMom->SetName("gMeanResMomVertexVsMom");
+ gMeanResMomVertexVsMom->SetTitle("<#Delta_{p}> at vertex versus p;p (GeV/c);<#Delta_{p}> (GeV/c)");
+ TGraphAsymmErrors* gMostProbResMomVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gMostProbResMomVertexVsMom->SetName("gMostProbResMomVertexVsMom");
+ gMostProbResMomVertexVsMom->SetTitle("Most probable #Delta_{p} at vertex versus p;p (GeV/c);Most prob. #Delta_{p} (GeV/c)");
+ TGraphAsymmErrors* gSigmaResMomVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResMomVertexVsMom->SetName("gSigmaResMomVertexVsMom");
+ gSigmaResMomVertexVsMom->SetTitle("#sigma_{p}/p at vertex versus p;p (GeV/c);#sigma_{p}/p (%)");
+
+ // momentum resolution at first cluster
+ histoFile->mkdir("momentumAtFirstCluster","momentumAtFirstCluster");
+ histoFile->cd("momentumAtFirstCluster");
+
+ const Int_t deltaPAtFirstClNBins = 500;
+ Double_t deltaPAtFirstClEdges[2];
+ if (pMax < 25.) { deltaPAtFirstClEdges[0] = -5.; deltaPAtFirstClEdges[1] = 5.; }
+ else if (pMax < 50.) { deltaPAtFirstClEdges[0] = -10.; deltaPAtFirstClEdges[1] = 10.; }
+ else { deltaPAtFirstClEdges[0] = -25.; deltaPAtFirstClEdges[1] = 25.; }
+
+ TH1F *hResMomFirstCluster = new TH1F("hResMomFirstCluster"," delta P at first cluster;#Delta_{p} (GeV/c)",deltaPAtFirstClNBins,deltaPAtFirstClEdges[0],deltaPAtFirstClEdges[1]);
+ TH2D *hResMomFirstClusterVsMom = new TH2D("hResMomFirstClusterVsMom","#Delta_{p} at first cluster versus p;p (GeV/c);#Delta_{p} (GeV/c)",2*pNBins,pEdges[0],pEdges[1],deltaPAtFirstClNBins,deltaPAtFirstClEdges[0],deltaPAtFirstClEdges[1]);
+
+ TGraphAsymmErrors* gMeanResMomFirstClusterVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResMomFirstClusterVsMom->SetName("gMeanResMomFirstClusterVsMom");
+ gMeanResMomFirstClusterVsMom->SetTitle("<#Delta_{p}> at first cluster versus p;p (GeV/c);<#Delta_{p}> (GeV/c)");
+ TGraphAsymmErrors* gSigmaResMomFirstClusterVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResMomFirstClusterVsMom->SetName("gSigmaResMomFirstClusterVsMom");
+ gSigmaResMomFirstClusterVsMom->SetTitle("#sigma_{p}/p at first cluster versus p;p (GeV/c);#sigma_{p}/p (%)");
+
+ // angular resolution at vertex
+ histoFile->mkdir("slopesAtVertex","slopesAtVertex");
+ histoFile->cd("slopesAtVertex");
+
+ const Int_t deltaSlopeAtVtxNBins = 500;
+ const Double_t deltaSlopeAtVtxEdges[2] = {-0.05, 0.05};
+
+ TH1F *hResSlopeXVertex = new TH1F("hResSlopeXVertex","#Delta_{slope_{X}} at vertex;#Delta_{slope_{X}}", deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH1F *hResSlopeYVertex = new TH1F("hResSlopeYVertex","#Delta_{slope_{Y}} at vertex;#Delta_{slope_{Y}}", deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeXVertexVsMom = new TH2D("hResSlopeXVertexVsMom","#Delta_{slope_{X}} at vertex versus p;p (GeV/c);#Delta_{slope_{X}}",2*pNBins,pEdges[0],pEdges[1], deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeYVertexVsMom = new TH2D("hResSlopeYVertexVsMom","#Delta_{slope_{Y}} at vertex versus p;p (GeV/c);#Delta_{slope_{Y}}",2*pNBins,pEdges[0],pEdges[1], deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+
+ TH2D *hResSlopeXVertexVsPosAbsEnd_0_2_DegMC = new TH2D("hResSlopeXVertexVsPosAbsEnd_0_2_DegMC","#Delta_{slope_{X}} at vertex versus track position at absorber end for tracks with MC angle < 2 degrees;position (cm);#Delta_{slope_{X}}",1000,0.,100.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeYVertexVsPosAbsEnd_0_2_DegMC = new TH2D("hResSlopeYVertexVsPosAbsEnd_0_2_DegMC","#Delta_{slope_{Y}} at vertex versus track position at absorber end for tracks with MC angle < 2 degrees;position (cm);#Delta_{slope_{Y}}",1000,0.,100.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeXVertexVsPosAbsEnd_2_3_DegMC = new TH2D("hResSlopeXVertexVsPosAbsEnd_2_3_DegMC","#Delta_{slope_{X}} at vertex versus track position at absorber end for tracks with MC angle in [2,3[ degrees;position (cm);#Delta_{slope_{X}}",1000,0.,100.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeYVertexVsPosAbsEnd_2_3_DegMC = new TH2D("hResSlopeYVertexVsPosAbsEnd_2_3_DegMC","#Delta_{slope_{Y}} at vertex versus track position at absorber end for tracks with MC angle in [2,3[ degrees;position (cm);#Delta_{slope_{Y}}",1000,0.,100.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeXVertexVsPosAbsEnd_3_10_DegMC = new TH2D("hResSlopeXVertexVsPosAbsEnd_3_10_DegMC","#Delta_{slope_{X}} at vertex versus track position at absorber end for tracks with MC angle in [3,10[ degrees;position (cm);#Delta_{slope_{X}}",1000,0.,100.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeYVertexVsPosAbsEnd_3_10_DegMC = new TH2D("hResSlopeYVertexVsPosAbsEnd_3_10_DegMC","#Delta_{slope_{Y}} at vertex versus track position at absorber end for tracks with MC angle in [3,10[ degrees;position (cm);#Delta_{slope_{Y}}",1000,0.,100.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+
+ TH2D *hResSlopeXVertexVsAngle = new TH2D("hResSlopeXVertexVsAngle","#Delta_{slope_{X}} at vertex versus track position at absorber end converted to degrees;angle (Deg);#Delta_{slope_{X}}",10,0.,10.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeYVertexVsAngle = new TH2D("hResSlopeYVertexVsAngle","#Delta_{slope_{Y}} at vertex versus track position at absorber end converted to degrees;angle (Deg);#Delta_{slope_{Y}}",10,0.,10.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeXVertexVsMCAngle = new TH2D("hResSlopeXVertexVsMCAngle","#Delta_{slope_{X}} at vertex versus MC angle;MC angle (Deg);#Delta_{slope_{X}}",10,0.,10.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+ TH2D *hResSlopeYVertexVsMCAngle = new TH2D("hResSlopeYVertexVsMCAngle","#Delta_{slope_{Y}} at vertex versus MC angle;MC angle (Deg);#Delta_{slope_{Y}}",10,0.,10.,deltaSlopeAtVtxNBins, deltaSlopeAtVtxEdges[0], deltaSlopeAtVtxEdges[1]);
+
+ TGraphAsymmErrors* gMeanResSlopeXVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResSlopeXVertexVsMom->SetName("gMeanResSlopeXVertexVsMom");
+ gMeanResSlopeXVertexVsMom->SetTitle("<#Delta_{slope_{X}}> at vertex versus p;p (GeV/c);<#Delta_{slope_{X}}>");
+ TGraphAsymmErrors* gSigmaResSlopeXVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResSlopeXVertexVsMom->SetName("gSigmaResSlopeXVertexVsMom");
+ gSigmaResSlopeXVertexVsMom->SetTitle("#sigma_{slope_{X}} at vertex versus p;p (GeV/c);#sigma_{slope_{X}}");
+ TGraphAsymmErrors* gMeanResSlopeYVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResSlopeYVertexVsMom->SetName("gMeanResSlopeYVertexVsMom");
+ gMeanResSlopeYVertexVsMom->SetTitle("<#Delta_{slope_{Y}}> at vertex versus p;p (GeV/c);<#Delta_{slope_{Y}}>");
+ TGraphAsymmErrors* gSigmaResSlopeYVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResSlopeYVertexVsMom->SetName("gSigmaResSlopeYVertexVsMom");
+ gSigmaResSlopeYVertexVsMom->SetTitle("#sigma_{slope_{Y}} at vertex versus p;p (GeV/c);#sigma_{slope_{Y}}");
+
+ // angular resolution at first cluster
+ histoFile->mkdir("slopesAtFirstCluster","slopesAtFirstCluster");
+ histoFile->cd("slopesAtFirstCluster");
+
+ const Int_t deltaSlopeAtFirstClNBins = 500;
+ const Double_t deltaSlopeAtFirstClEdges[2] = {-0.01, 0.01};
+
+ TH1F *hResSlopeXFirstCluster = new TH1F("hResSlopeXFirstCluster","#Delta_{slope_{X}} at first cluster;#Delta_{slope_{X}}", deltaSlopeAtFirstClNBins, deltaSlopeAtFirstClEdges[0], deltaSlopeAtFirstClEdges[1]);
+ TH2D *hResSlopeXFirstClusterVsMom = new TH2D("hResSlopeXFirstClusterVsMom","#Delta_{slope_{X}} at first cluster versus p;p (GeV/c);#Delta_{slope_{X}}",2*pNBins,pEdges[0],pEdges[1], deltaSlopeAtFirstClNBins, deltaSlopeAtFirstClEdges[0], deltaSlopeAtFirstClEdges[1]);
+ TH1F *hResSlopeYFirstCluster = new TH1F("hResSlopeYFirstCluster","#Delta_{slope_{Y}} at first cluster;#Delta_{slope_{Y}}", deltaSlopeAtFirstClNBins, deltaSlopeAtFirstClEdges[0], deltaSlopeAtFirstClEdges[1]);
+ TH2D *hResSlopeYFirstClusterVsMom = new TH2D("hResSlopeYFirstClusterVsMom","#Delta_{slope_{Y}} at first cluster versus p;p (GeV/c);#Delta_{slope_{Y}}",2*pNBins,pEdges[0],pEdges[1], deltaSlopeAtFirstClNBins, deltaSlopeAtFirstClEdges[0], deltaSlopeAtFirstClEdges[1]);
+
+ TGraphAsymmErrors* gMeanResSlopeXFirstClusterVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResSlopeXFirstClusterVsMom->SetName("gMeanResSlopeXFirstClusterVsMom");
+ gMeanResSlopeXFirstClusterVsMom->SetTitle("<#Delta_{slope_{X}}> at first cluster versus p;p (GeV/c);<#Delta_{slope_{X}}>");
+ TGraphAsymmErrors* gSigmaResSlopeXFirstClusterVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResSlopeXFirstClusterVsMom->SetName("gSigmaResSlopeXFirstClusterVsMom");
+ gSigmaResSlopeXFirstClusterVsMom->SetTitle("#sigma_{slope_{X}} at first cluster versus p;p (GeV/c);#sigma_{slope_{X}}");
+ TGraphAsymmErrors* gMeanResSlopeYFirstClusterVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResSlopeYFirstClusterVsMom->SetName("gMeanResSlopeYFirstClusterVsMom");
+ gMeanResSlopeYFirstClusterVsMom->SetTitle("<#Delta_{slope_{Y}}> at first cluster versus p;p (GeV/c);<#Delta_{slope_{Y}}>");
+ TGraphAsymmErrors* gSigmaResSlopeYFirstClusterVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResSlopeYFirstClusterVsMom->SetName("gSigmaResSlopeYFirstClusterVsMom");
+ gSigmaResSlopeYFirstClusterVsMom->SetTitle("#sigma_{slope_{Y}} at first cluster versus p;p (GeV/c);#sigma_{slope_{Y}}");
+
+ // DCA resolution and MCS angular dispersion
+ histoFile->mkdir("DCA","DCA");
+ histoFile->cd("DCA");
+
+ const Int_t deltaPDCANBins = 500;
+ const Double_t deltaPDCAEdges[2] = {0., 1000.};
+ const Double_t deltaPMCSAngEdges[2] = {-1.5, 1.5};
+
+ TH1F *hPDCA = new TH1F("hPDCA","p #times DCA at vertex;p #times DCA (GeV #times cm)", deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+ TH2D *hPDCAVsMom_2_3_Deg = new TH2D("hPDCAVsMom_2_3_Deg","p #times DCA versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);p #times DCA (GeV #times cm)",2*pNBins,pEdges[0],pEdges[1], deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+ TH2D *hPDCAVsMom_3_10_Deg = new TH2D("hPDCAVsMom_3_10_Deg","p #times DCA versus p for tracks within [3,10[ degrees at absorber end;p (GeV/c);p #times DCA (GeV #times cm)",2*pNBins,pEdges[0],pEdges[1], deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+ TH2D *hPMCSAngVsMom_2_3_Deg = new TH2D("hPMCSAngVsMom_2_3_Deg","p #times #Delta#theta_{MCS} versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);p #times #Delta#theta_{MCS} (GeV)",2*pNBins,pEdges[0],pEdges[1], deltaPDCANBins, deltaPMCSAngEdges[0], deltaPMCSAngEdges[1]);
+ TH2D *hPMCSAngVsMom_3_10_Deg = new TH2D("hPMCSAngVsMom_3_10_Deg","p #times #Delta#theta_{MCS} versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);p #times #Delta#theta_{MCS} (GeV)",2*pNBins,pEdges[0],pEdges[1], deltaPDCANBins, deltaPMCSAngEdges[0], deltaPMCSAngEdges[1]);
+
+ TH2D *hPDCAVsPosAbsEnd_0_2_DegMC = new TH2D("hPDCAVsPosAbsEnd_0_2_DegMC","p #times DCA versus track position at absorber end for tracks with MC angle < 2 degrees;position (cm);p #times DCA (GeV #times cm)",1000,0.,100.,deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+ TH2D *hPDCAVsPosAbsEnd_2_3_DegMC = new TH2D("hPDCAVsPosAbsEnd_2_3_DegMC","p #times DCA}versus track position at absorber end for tracks with MC angle in [2,3[ degrees;position (cm);p #times DCA (GeV #times cm)",1000,0.,100.,deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+ TH2D *hPDCAVsPosAbsEnd_3_10_DegMC = new TH2D("hPDCAVsPosAbsEnd_3_10_DegMC","p #times DCA versus track position at absorber end for tracks with MC angle in [3,10[ degrees;position (cm);p #times DCA (GeV #times cm)",1000,0.,100.,deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+
+ TH2D *hPDCAVsAngle = new TH2D("hPDCAVsAngle","p #times DCA versus track position at absorber end converted to degrees;angle (Deg);p #times DCA (GeV #times cm)",10,0.,10.,deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+ TH2D *hPDCAVsMCAngle = new TH2D("hPDCAVsMCAngle","p #times DCA versus MC angle;MC angle (Deg);p #times DCA (GeV #times cm)",10,0.,10.,deltaPDCANBins, deltaPDCAEdges[0], deltaPDCAEdges[1]);
+
+ TGraphAsymmErrors* gMeanPDCAVsMom_2_3_Deg = new TGraphAsymmErrors(pNBins);
+ gMeanPDCAVsMom_2_3_Deg->SetName("gMeanPDCAVsMom_2_3_Deg");
+ gMeanPDCAVsMom_2_3_Deg->SetTitle("<p #times DCA> versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);<p #times DCA> (GeV #times cm)");
+ TGraphAsymmErrors* gSigmaPDCAVsMom_2_3_Deg = new TGraphAsymmErrors(pNBins);
+ gSigmaPDCAVsMom_2_3_Deg->SetName("gSigmaPDCAVsMom_2_3_Deg");
+ gSigmaPDCAVsMom_2_3_Deg->SetTitle("#sigma_{p #times DCA} versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);#sigma_{p #times DCA} (GeV #times cm)");
+ TGraphAsymmErrors* gMeanPDCAVsMom_3_10_Deg = new TGraphAsymmErrors(pNBins);
+ gMeanPDCAVsMom_3_10_Deg->SetName("gMeanPDCAVsMom_3_10_Deg");
+ gMeanPDCAVsMom_3_10_Deg->SetTitle("<p #times DCA> versus p for tracks within [3,10[ degrees at absorber end;p (GeV/c);<p #times DCA> (GeV #times cm)");
+ TGraphAsymmErrors* gSigmaPDCAVsMom_3_10_Deg = new TGraphAsymmErrors(pNBins);
+ gSigmaPDCAVsMom_3_10_Deg->SetName("gSigmaPDCAVsMom_3_10_Deg");
+ gSigmaPDCAVsMom_3_10_Deg->SetTitle("#sigma_{p #times DCA} versus p for tracks within [3,10[ degrees at absorber end;p (GeV/c);#sigma_{p #times DCA} (GeV #times cm)");
+ TGraphAsymmErrors* gMeanPMCSAngVsMom_2_3_Deg = new TGraphAsymmErrors(pNBins);
+ gMeanPMCSAngVsMom_2_3_Deg->SetName("gMeanPMCSAngVsMom_2_3_Deg");
+ gMeanPMCSAngVsMom_2_3_Deg->SetTitle("<p #times #Delta#theta_{MCS}> versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);<p #times #Delta#theta_{MCS}> (GeV)");
+ TGraphAsymmErrors* gSigmaPMCSAngVsMom_2_3_Deg = new TGraphAsymmErrors(pNBins);
+ gSigmaPMCSAngVsMom_2_3_Deg->SetName("gSigmaPMCSAngVsMom_2_3_Deg");
+ gSigmaPMCSAngVsMom_2_3_Deg->SetTitle("#sigma_{p #times #Delta#theta_{MCS}} versus p for tracks within [2,3[ degrees at absorber end;p (GeV/c);#sigma_{p #times #Delta#theta_{MCS}} (GeV)");
+ TGraphAsymmErrors* gMeanPMCSAngVsMom_3_10_Deg = new TGraphAsymmErrors(pNBins);
+ gMeanPMCSAngVsMom_3_10_Deg->SetName("gMeanPMCSAngVsMom_3_10_Deg");
+ gMeanPMCSAngVsMom_3_10_Deg->SetTitle("<p #times #Delta#theta_{MCS}> versus p for tracks within [3,10[ degrees at absorber end;p (GeV/c);<p #times #Delta#theta_{MCS}> (GeV)");
+ TGraphAsymmErrors* gSigmaPMCSAngVsMom_3_10_Deg = new TGraphAsymmErrors(pNBins);
+ gSigmaPMCSAngVsMom_3_10_Deg->SetName("gSigmaPMCSAngVsMom_3_10_Deg");
+ gSigmaPMCSAngVsMom_3_10_Deg->SetTitle("#sigma_{p #times #Delta#theta_{MCS}} versus p for tracks within [3,10[ degrees at absorber end;p (GeV/c);#sigma_{p #times #Delta#theta_{MCS}} (GeV)");
+
+ // eta resolution at vertex
+ histoFile->mkdir("etaAtVertex","etaAtVertex");
+ histoFile->cd("etaAtVertex");
+
+ const Int_t deltaEtaAtVtxNBins = 500;
+ const Double_t deltaEtaAtVtxEdges[2] = {-0.5, 0.5};
+
+ TH1F *hResEtaVertex = new TH1F("hResEtaVertex","#Delta_{eta} at vertex;#Delta_{eta}", deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
+ TH2D *hResEtaVertexVsMom = new TH2D("hResEtaVertexVsMom","#Delta_{eta} at vertex versus p;p (GeV/c);#Delta_{eta}",2*pNBins,pEdges[0],pEdges[1], deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
- // set mag field
- // waiting for mag field in CDB
- if (!TGeoGlobalMagField::Instance()->GetField()) {
- printf("Loading field map...\n");
- AliMagF* field = new AliMagF("Maps","Maps",2,1.,1., 10.,AliMagF::k5kG);
- TGeoGlobalMagField::Instance()->SetField(field);
+ TH2D *hResEtaVertexVsPosAbsEnd_0_2_DegMC = new TH2D("hResEtaVertexVsPosAbsEnd_0_2_DegMC","#Delta_{eta} at vertex versus track position at absorber end for tracks with MC angle < 2 degrees;position (cm);#Delta_{eta}",1000,0.,100.,deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
+ TH2D *hResEtaVertexVsPosAbsEnd_2_3_DegMC = new TH2D("hResEtaVertexVsPosAbsEnd_2_3_DegMC","#Delta_{eta} at vertex versus track position at absorber end for tracks with MC angle in [2,3[ degrees;position (cm);#Delta_{eta}",1000,0.,100.,deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
+ TH2D *hResEtaVertexVsPosAbsEnd_3_10_DegMC = new TH2D("hResEtaVertexVsPosAbsEnd_3_10_DegMC","#Delta_{eta} at vertex versus track position at absorber end for tracks with MC angle in [3,10[ degrees;position (cm);#Delta_{eta}",1000,0.,100.,deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
+
+ TH2D *hResEtaVertexVsAngle = new TH2D("hResEtaVertexVsAngle","#Delta_{eta} at vertex versus track position at absorber end converted to degrees;angle (Deg);#Delta_{eta}",10,0.,10.,deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
+ TH2D *hResEtaVertexVsMCAngle = new TH2D("hResEtaVertexVsMCAngle","#Delta_{eta} at vertex versus MC angle;MC angle (Deg);#Delta_{eta}",10,0.,10.,deltaEtaAtVtxNBins, deltaEtaAtVtxEdges[0], deltaEtaAtVtxEdges[1]);
+
+ TGraphAsymmErrors* gMeanResEtaVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResEtaVertexVsMom->SetName("gMeanResEtaVertexVsMom");
+ gMeanResEtaVertexVsMom->SetTitle("<#Delta_{eta}> at vertex versus p;p (GeV/c);<#Delta_{eta}>");
+ TGraphAsymmErrors* gSigmaResEtaVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResEtaVertexVsMom->SetName("gSigmaResEtaVertexVsMom");
+ gSigmaResEtaVertexVsMom->SetTitle("#sigma_{eta} at vertex versus p;p (GeV/c);#sigma_{eta}");
+
+ // phi resolution at vertex
+ histoFile->mkdir("phiAtVertex","phiAtVertex");
+ histoFile->cd("phiAtVertex");
+
+ const Int_t deltaPhiAtVtxNBins = 500;
+ const Double_t deltaPhiAtVtxEdges[2] = {-0.5, 0.5};
+
+ TH1F *hResPhiVertex = new TH1F("hResPhiVertex","#Delta_{phi} at vertex;#Delta_{phi}", deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+ TH2D *hResPhiVertexVsMom = new TH2D("hResPhiVertexVsMom","#Delta_{phi} at vertex versus p;p (GeV/c);#Delta_{phi}",2*pNBins,pEdges[0],pEdges[1], deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+
+ TH2D *hResPhiVertexVsPosAbsEnd_0_2_DegMC = new TH2D("hResPhiVertexVsPosAbsEnd_0_2_DegMC","#Delta_{phi} at vertex versus track position at absorber end for tracks with MC angle < 2 degrees;position (cm);#Delta_{phi}",1000,0.,100.,deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+ TH2D *hResPhiVertexVsPosAbsEnd_2_3_DegMC = new TH2D("hResPhiVertexVsPosAbsEnd_2_3_DegMC","#Delta_{phi} at vertex versus track position at absorber end for tracks with MC angle in [2,3[ degrees;position (cm);#Delta_{phi}",1000,0.,100.,deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+ TH2D *hResPhiVertexVsPosAbsEnd_3_10_DegMC = new TH2D("hResPhiVertexVsPosAbsEnd_3_10_DegMC","#Delta_{phi} at vertex versus track position at absorber end for tracks with MC angle in [3,10[ degrees;position (cm);#Delta_{phi}",1000,0.,100.,deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+
+ TH2D *hResPhiVertexVsAngle = new TH2D("hResPhiVertexVsAngle","#Delta_{phi} at vertex versus track position at absorber end converted to degrees;angle (Deg);#Delta_{phi}",10,0.,10.,deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+ TH2D *hResPhiVertexVsMCAngle = new TH2D("hResPhiVertexVsMCAngle","#Delta_{phi} at vertex versus MC angle;MC angle (Deg);#Delta_{phi}",10,0.,10.,deltaPhiAtVtxNBins, deltaPhiAtVtxEdges[0], deltaPhiAtVtxEdges[1]);
+
+ TGraphAsymmErrors* gMeanResPhiVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gMeanResPhiVertexVsMom->SetName("gMeanResPhiVertexVsMom");
+ gMeanResPhiVertexVsMom->SetTitle("<#Delta_{phi}> at vertex versus p;p (GeV/c);<#Delta_{phi}>");
+ TGraphAsymmErrors* gSigmaResPhiVertexVsMom = new TGraphAsymmErrors(pNBins);
+ gSigmaResPhiVertexVsMom->SetName("gSigmaResPhiVertexVsMom");
+ gSigmaResPhiVertexVsMom->SetTitle("#sigma_{phi} at vertex versus p;p (GeV/c);#sigma_{phi}");
+
+ // cluster resolution
+ histoFile->mkdir("clusters","clusters");
+ histoFile->cd("clusters");
+
+ TH1F* hResidualXInCh[AliMUONConstants::NTrackingCh()];
+ TH1F* hResidualYInCh[AliMUONConstants::NTrackingCh()];
+ for (Int_t i = 0; i < AliMUONConstants::NTrackingCh(); i++) {
+ hResidualXInCh[i] = new TH1F(Form("hResidualXInCh%d",i+1), Form("cluster-track residual-X distribution in chamber %d;#Delta_{X} (cm)",i+1), 1000, -1., 1.);
+ hResidualYInCh[i] = new TH1F(Form("hResidualYInCh%d",i+1), Form("cluster-track residual-Y distribution in chamber %d;#Delta_{Y} (cm)",i+1), 1000, -0.5, 0.5);
}
- // set the magnetic field for track extrapolations
- AliMUONTrackExtrap::SetField();
+
+ TGraphErrors* gResidualXPerChMean = new TGraphErrors(AliMUONConstants::NTrackingCh());
+ gResidualXPerChMean->SetName("gResidualXPerChMean");
+ gResidualXPerChMean->SetTitle("cluster-trackRef residual-X per Ch: mean;chamber ID;<#Delta_{X}> (cm)");
+ gResidualXPerChMean->SetMarkerStyle(kFullDotLarge);
+ TGraphErrors* gResidualYPerChMean = new TGraphErrors(AliMUONConstants::NTrackingCh());
+ gResidualYPerChMean->SetName("gResidualYPerChMean");
+ gResidualYPerChMean->SetTitle("cluster-trackRef residual-Y per Ch: mean;chamber ID;<#Delta_{Y}> (cm)");
+ gResidualYPerChMean->SetMarkerStyle(kFullDotLarge);
+ TGraphErrors* gResidualXPerChSigma = new TGraphErrors(AliMUONConstants::NTrackingCh());
+ gResidualXPerChSigma->SetName("gResidualXPerChSigma");
+ gResidualXPerChSigma->SetTitle("cluster-trackRef residual-X per Ch: sigma;chamber ID;#sigma_{X} (cm)");
+ gResidualXPerChSigma->SetMarkerStyle(kFullDotLarge);
+ TGraphErrors* gResidualYPerChSigma = new TGraphErrors(AliMUONConstants::NTrackingCh());
+ gResidualYPerChSigma->SetName("gResidualYPerChSigma");
+ gResidualYPerChSigma->SetTitle("cluster-trackRef residual-Y per Ch: sigma;chamber ID;#sigma_{Y} (cm)");
+ gResidualYPerChSigma->SetMarkerStyle(kFullDotLarge);
+ histoFile->mkdir("trigger");
+ histoFile->cd("trigger");
+ TH1F* hResidualTrigX11 = new TH1F("hResiudalTrigX11", "Residual X11", 100, -10., 10.);
+ TH1F* hResidualTrigY11 = new TH1F("hResiudalTrigY11", "Residual Y11", 100, -10., 10.);
+ TH1F* hResidualTrigSlopeY = new TH1F("hResiudalTrigSlopeY", "Residual Y slope", 100, -0.1, 0.1);
+ TH1F* hTriggerableMatchFailed = new TH1F("hTriggerableMatchFailed", "Triggerable multiplicity for events with no match", 15, -0.5, 14.5);
+
+
+ // ###################################### initialize ###################################### //
AliMUONRecoCheck rc(esdFileName, pathSim);
+ // load necessary data from OCDB
+ AliCDBManager::Instance()->SetDefaultStorage(ocdbPath);
+ AliCDBManager::Instance()->SetRun(rc.GetRunNumber());
+ if (!AliMUONCDB::LoadField()) return;
+ AliMUONTrackExtrap::SetField();
+ AliGeomManager::LoadGeometry();
+ if (!AliGeomManager::GetGeometry()) return;
+ AliMUONRecoParam* recoParam = AliMUONCDB::LoadRecoParam();
+ if (!recoParam) return;
+ AliMUONESDInterface::ResetTracker(recoParam);
+
+ // get sigma cut from recoParam to associate clusters with TrackRefs in case the label are not used
+ Double_t sigmaCut = (recoParam->ImproveTracks()) ? recoParam->GetSigmaCutForImprovement() : recoParam->GetSigmaCutForTracking();
+ // compute the mask of requested stations from recoParam
+ UInt_t requestedStationMask = 0;
+ for (Int_t i = 0; i < 5; i++) if (recoParam->RequestStation(i)) requestedStationMask |= ( 1 << i );
+ // get from recoParam whether a track need 2 chambers hit in the same station (4 or 5) or not to be reconstructible
+ Bool_t request2ChInSameSt45 = !recoParam->MakeMoreTrackCandidates();
+
Int_t nevents = rc.NumberOfEvents();
if (nevents < nEvent || nEvent < 0) nEvent = nevents;
Int_t nReconstructibleTracks = 0;
Int_t nReconstructedTracks = 0;
Int_t nReconstructibleTracksCheck = 0;
+ AliMUONTrackParam *trackParam;
+ Double_t x1,y1,z1,slopex1,slopey1,pX1,pY1,pZ1,p1,pT1,eta1,phi1;
+ Double_t x2,y2,z2,slopex2,slopey2,pX2,pY2,pZ2,p2,pT2,eta2,phi2;
+ Double_t dPhi;
+ Double_t xAbs,yAbs,dAbs,aAbs,aMCS,aMC;
+ Double_t xDCA,yDCA,dca,pU;
+ Double_t aMCSMoy = 0., aMCS2Moy = 0., dMCSMoy = 0., dMCS2Moy = 0., adMCSMoy = 0.;
+ Int_t nMCS = 0;
+ // ###################################### fill histograms ###################################### //
for (ievent=0; ievent<nEvent; ievent++)
{
- if (!(ievent%10)) printf(" **** event # %d \n",ievent);
+ if ((ievent+1)%100 == 0) cout<<"\rEvent processing... "<<ievent+1<<flush;
- AliMUONVTrackStore* trackStore = rc.ReconstructedTracks(ievent);
- AliMUONVTrackStore* trackRefStore = rc.ReconstructibleTracks(ievent);
+ AliMUONVTrackStore* trackStore = rc.ReconstructedTracks(ievent, kFALSE);
+ AliMUONVTrackStore* trackRefStore = rc.ReconstructibleTracks(ievent, requestedStationMask, request2ChInSameSt45);
hReconstructible->Fill(trackRefStore->GetSize());
hReco->Fill(trackStore->GetSize());
nReconstructibleTracks += trackRefStore->GetSize();
nReconstructedTracks += trackStore->GetSize();
+
+ AliMUONVTriggerTrackStore* triggerTrackRefStore = rc.TriggerableTracks(ievent);
+ AliMUONVTriggerTrackStore* triggerTrackStore = rc.TriggeredTracks(ievent);
+
+ hTriggerable->Fill(triggerTrackRefStore->GetSize());
+ hTriggered->Fill(triggerTrackStore->GetSize());
+
+ // loop over trigger trackRef
+ TIter nextTrig(triggerTrackRefStore->CreateIterator());
+ AliMUONTriggerTrack* triggerTrackRef;
+ Int_t nTriggerMatches = 0;
+ while ( ( triggerTrackRef = static_cast<AliMUONTriggerTrack*>(nextTrig()) ) )
+ {
+
+ AliMUONTriggerTrack* triggerTrackMatched = 0x0;
+
+ // loop over trackReco and look for compatible track
+ TIter nextTrig2(triggerTrackStore->CreateIterator());
+ AliMUONTriggerTrack* triggerTrackReco;
+ while ( ( triggerTrackReco = static_cast<AliMUONTriggerTrack*>(nextTrig2()) ) )
+ {
+
+ // check if trackReco is compatible with trackRef
+ if (triggerTrackReco->Match(*triggerTrackRef, sigmaCut)) {
+ triggerTrackMatched = triggerTrackReco;
+ nTriggerMatches++;
+ break;
+ }
+ }
+
+ if (triggerTrackMatched) { // tracking requirements verified, track is found
+ hResidualTrigX11->Fill( triggerTrackMatched->GetX11() - triggerTrackRef->GetX11() );
+ hResidualTrigY11->Fill( triggerTrackMatched->GetY11() - triggerTrackRef->GetY11() );
+ hResidualTrigSlopeY->Fill( triggerTrackMatched->GetSlopeY() - triggerTrackRef->GetSlopeY() );
+ }
+ } // loop on trigger track ref
+ if ( nTriggerMatches != triggerTrackStore->GetSize() )
+ hTriggerableMatchFailed->Fill(triggerTrackRefStore->GetSize());
+
+ // loop over trackRef
TIter next(trackRefStore->CreateIterator());
AliMUONTrack* trackRef;
-
while ( ( trackRef = static_cast<AliMUONTrack*>(next()) ) )
{
- maxChi2 = 999.;
- testTrack = 0;
- trackOK = 0x0;
- for (Int_t ch = 0; ch < AliMUONConstants::NTrackingCh(); ch++)
- {
- compTrackOK[ch] = kFALSE;
- }
+ hTrackRefID->Fill(trackRef->GetUniqueID());
+
+ AliMUONTrack* trackMatched = 0x0;
+ Int_t nMatchClusters = 0;
+
+ // loop over trackReco and look for compatible track
TIter next2(trackStore->CreateIterator());
AliMUONTrack* trackReco;
-
while ( ( trackReco = static_cast<AliMUONTrack*>(next2()) ) )
{
- // check if trackRef is compatible with trackReco
- if (trackReco->GetNClusters() > 1) {
-
- // check cluster by cluster if trackReco contain info at each cluster
- trackRef->CompatibleTrack(trackReco,sigmaCut,compTrack);
-
- iTrack = TrackCheck(compTrack);
-
- if (iTrack > testTrack)
- {
- nClusterOk = 0;
- for (Int_t ch = 0; ch < AliMUONConstants::NTrackingCh(); ch++)
- {
- if (compTrack[ch]) nClusterOk++;
- compTrackOK[ch] = compTrack[ch];
- }
- testTrack = iTrack;
- trackOK = trackReco;
- }
-
- } else {
-
- // check only parameters at the z position of the first trackRef
- AliMUONTrackParam *refParam = (AliMUONTrackParam*) trackRef->GetTrackParamAtCluster()->First();
- AliMUONTrackParam recoParam(*((AliMUONTrackParam*) trackReco->GetTrackParamAtCluster()->First()));
- AliMUONTrackExtrap::ExtrapToZCov(&recoParam, refParam->GetZ());
- Double_t chi2;
- if (refParam->CompatibleTrackParam(recoParam, sigmaCut, chi2)) {
-
- if (chi2 < maxChi2) {
- maxChi2 = chi2;
- trackOK = trackReco;
- }
-
- }
-
+
+ // check if trackReco is compatible with trackRef
+ if (trackReco->Match(*trackRef, sigmaCut, nMatchClusters)) {
+ trackMatched = trackReco;
+ break;
}
-
+
}
- hTestTrack->Fill(testTrack);
- trackID = trackRef->GetMCLabel();
- hTrackRefID->Fill(trackID);
-
- if (testTrack == 4 || maxChi2 < 5.*sigmaCut*sigmaCut) { // tracking requirements verified, track is found
+ if (trackMatched) { // tracking requirements verified, track is found
nReconstructibleTracksCheck++;
- hNClusterComp->Fill(nClusterOk);
+ hNClusterComp->Fill(nMatchClusters);
+
+ // compute track position at the end of the absorber
+ AliMUONTrackParam trackParamAtAbsEnd(*((AliMUONTrackParam*)trackMatched->GetTrackParamAtCluster()->First()));
+ AliMUONTrackExtrap::ExtrapToZ(&trackParamAtAbsEnd, AliMUONConstants::AbsZEnd());
+ xAbs = trackParamAtAbsEnd.GetNonBendingCoor();
+ yAbs = trackParamAtAbsEnd.GetBendingCoor();
+ dAbs = TMath::Sqrt(xAbs*xAbs + yAbs*yAbs);
+ aAbs = TMath::ATan(-dAbs/AliMUONConstants::AbsZEnd()) * TMath::RadToDeg();
+ pX2 = trackParamAtAbsEnd.Px();
+ pY2 = trackParamAtAbsEnd.Py();
+ pZ2 = trackParamAtAbsEnd.Pz();
+ pT2 = TMath::Sqrt(pX2*pX2 + pY2*pY2);
+ aMCS = TMath::ATan(-pT2/pZ2) * TMath::RadToDeg();
+
trackParam = trackRef->GetTrackParamAtVertex();
x1 = trackParam->GetNonBendingCoor();
y1 = trackParam->GetBendingCoor();
z1 = trackParam->GetZ();
+ slopex1 = trackParam->GetNonBendingSlope();
+ slopey1 = trackParam->GetBendingSlope();
pX1 = trackParam->Px();
pY1 = trackParam->Py();
pZ1 = trackParam->Pz();
p1 = trackParam->P();
-
- // printf(" Ref. track at vertex: x,y,z: %f %f %f px,py,pz,p: %f %f %f %f \n",x1,y1,z1,pX1,pY1,pZ1,p1);
- trackReco = trackOK;
- trackParam = new AliMUONTrackParam(*((AliMUONTrackParam*)(trackReco->GetTrackParamAtVertex())));
+ pT1 = TMath::Sqrt(pX1*pX1 + pY1*pY1);
+ aMC = TMath::ATan(-pT1/pZ1) * TMath::RadToDeg();
+ eta1 = TMath::Log(TMath::Tan(0.5*TMath::ATan(-pT1/pZ1)));
+ phi1 = TMath::Pi()+TMath::ATan2(-pY1, -pX1);
+
+ trackParam = trackMatched->GetTrackParamAtVertex();
x2 = trackParam->GetNonBendingCoor();
y2 = trackParam->GetBendingCoor();
z2 = trackParam->GetZ();
+ slopex2 = trackParam->GetNonBendingSlope();
+ slopey2 = trackParam->GetBendingSlope();
pX2 = trackParam->Px();
pY2 = trackParam->Py();
pZ2 = trackParam->Pz();
p2 = trackParam->P();
- delete trackParam;
- // printf(" Reconst. track at vertex: x,y,z: %f %f %f px,py,pz: %f %f %f %f \n",x2,y2,z2,pX2,pY2,pZ2,p2);
+ pT2 = TMath::Sqrt(pX2*pX2 + pY2*pY2);
+ eta2 = TMath::Log(TMath::Tan(0.5*TMath::ATan(-pT2/pZ2)));
+ phi2 = TMath::Pi()+TMath::ATan2(-pY2, -pX2);
+ dPhi = phi2-phi1;
+ if (dPhi < -TMath::Pi()) dPhi += 2.*TMath::Pi();
+ else if (dPhi > TMath::Pi()) dPhi -= 2.*TMath::Pi();
+
+ AliMUONTrackParam trackParamAtDCA(*((AliMUONTrackParam*) trackMatched->GetTrackParamAtCluster()->First()));
+ pU = trackParamAtDCA.P();
+ AliMUONTrackExtrap::ExtrapToVertexWithoutBranson(&trackParamAtDCA, z2);
+ xDCA = trackParamAtDCA.GetNonBendingCoor();
+ yDCA = trackParamAtDCA.GetBendingCoor();
+ dca = TMath::Sqrt(xDCA*xDCA + yDCA*yDCA);
+
hResMomVertex->Fill(p2-p1);
-
+ hResSlopeXVertex->Fill(slopex2-slopex1);
+ hResSlopeYVertex->Fill(slopey2-slopey1);
+ hPDCA->Fill(0.5*(p2+pU)*dca);
+ hResEtaVertex->Fill(eta2-eta1);
+ hResPhiVertex->Fill(dPhi);
+ if (aMC >= aAbsLimits[0] && aMC <= aAbsLimits[1]) {
+ hResMomVertexVsMom->Fill(p1,p2-p1);
+ hResSlopeXVertexVsMom->Fill(p1,slopex2-slopex1);
+ hResSlopeYVertexVsMom->Fill(p1,slopey2-slopey1);
+ hResEtaVertexVsMom->Fill(p1,eta2-eta1);
+ hResPhiVertexVsMom->Fill(p1,dPhi);
+ }
+ hResMomVertexVsAngleVsMom->Fill(p1,aAbs,p2-p1);
+ if (aAbs > 2. && aAbs < 3.) {
+ hResMomVertexVsMom_2_3_Deg->Fill(p1,p2-p1);
+ hPDCAVsMom_2_3_Deg->Fill(p1,0.5*(p2+pU)*dca);
+ hPMCSAngVsMom_2_3_Deg->Fill(p1,0.5*(p2+pU)*(aMCS-aMC)*TMath::DegToRad());
+ }
+ else if (aAbs >= 3. && aAbs < 10.) {
+ hResMomVertexVsMom_3_10_Deg->Fill(p1,p2-p1);
+ hPDCAVsMom_3_10_Deg->Fill(p1,0.5*(p2+pU)*dca);
+ hPMCSAngVsMom_3_10_Deg->Fill(p1,0.5*(p2+pU)*(aMCS-aMC)*TMath::DegToRad());
+ aMCSMoy += 0.5*(p2+pU)*(aMCS-aMC)*TMath::DegToRad();
+ aMCS2Moy += (0.5*(p2+pU)*(aMCS-aMC)*TMath::DegToRad()) * (0.5*(p2+pU)*(aMCS-aMC)*TMath::DegToRad());
+ dMCSMoy += 0.5*(p2+pU)*(dAbs-pT1/pZ1*AliMUONConstants::AbsZEnd());
+ dMCS2Moy += (0.5*(p2+pU)*(dAbs-pT1/pZ1*AliMUONConstants::AbsZEnd())) * (0.5*(p2+pU)*(dAbs-pT1/pZ1*AliMUONConstants::AbsZEnd()));
+ adMCSMoy += (0.5*(p2+pU)*(aMCS-aMC)*TMath::DegToRad()) * (0.5*(p2+pU)*(dAbs-pT1/pZ1*AliMUONConstants::AbsZEnd()));
+ nMCS++;
+ }
+ if (aMC < 2.) {
+ hResMomVertexVsMom_0_2_DegMC->Fill(p1,p2-p1);
+ hResMomVertexVsPosAbsEnd_0_2_DegMC->Fill(dAbs,p2-p1);
+ hResSlopeXVertexVsPosAbsEnd_0_2_DegMC->Fill(dAbs,slopex2-slopex1);
+ hResSlopeYVertexVsPosAbsEnd_0_2_DegMC->Fill(dAbs,slopey2-slopey1);
+ hPDCAVsPosAbsEnd_0_2_DegMC->Fill(dAbs,0.5*(p2+pU)*dca);
+ hResEtaVertexVsPosAbsEnd_0_2_DegMC->Fill(dAbs,eta2-eta1);
+ hResPhiVertexVsPosAbsEnd_0_2_DegMC->Fill(dAbs,dPhi);
+ }
+ else if (aMC >= 2. && aMC < 3) {
+ hResMomVertexVsPosAbsEnd_2_3_DegMC->Fill(dAbs,p2-p1);
+ hResSlopeXVertexVsPosAbsEnd_2_3_DegMC->Fill(dAbs,slopex2-slopex1);
+ hResSlopeYVertexVsPosAbsEnd_2_3_DegMC->Fill(dAbs,slopey2-slopey1);
+ hPDCAVsPosAbsEnd_2_3_DegMC->Fill(dAbs,0.5*(p2+pU)*dca);
+ hResEtaVertexVsPosAbsEnd_2_3_DegMC->Fill(dAbs,eta2-eta1);
+ hResPhiVertexVsPosAbsEnd_2_3_DegMC->Fill(dAbs,dPhi);
+ }
+ else if (aMC >= 3. && aMC < 10.) {
+ hResMomVertexVsPosAbsEnd_3_10_DegMC->Fill(dAbs,p2-p1);
+ hResSlopeXVertexVsPosAbsEnd_3_10_DegMC->Fill(dAbs,slopex2-slopex1);
+ hResSlopeYVertexVsPosAbsEnd_3_10_DegMC->Fill(dAbs,slopey2-slopey1);
+ hPDCAVsPosAbsEnd_3_10_DegMC->Fill(dAbs,0.5*(p2+pU)*dca);
+ hResEtaVertexVsPosAbsEnd_3_10_DegMC->Fill(dAbs,eta2-eta1);
+ hResPhiVertexVsPosAbsEnd_3_10_DegMC->Fill(dAbs,dPhi);
+ }
+ hResMomVertexVsAngle->Fill(aAbs,p2-p1);
+ hResSlopeXVertexVsAngle->Fill(aAbs,slopex2-slopex1);
+ hResSlopeYVertexVsAngle->Fill(aAbs,slopey2-slopey1);
+ hPDCAVsAngle->Fill(aAbs,0.5*(p2+pU)*dca);
+ hResEtaVertexVsAngle->Fill(aAbs,eta2-eta1);
+ hResPhiVertexVsAngle->Fill(aAbs,dPhi);
+ hResMomVertexVsMCAngle->Fill(aMC,p2-p1);
+ hResSlopeXVertexVsMCAngle->Fill(aMC,slopex2-slopex1);
+ hResSlopeYVertexVsMCAngle->Fill(aMC,slopey2-slopey1);
+ hPDCAVsMCAngle->Fill(aMC,0.5*(p2+pU)*dca);
+ hResEtaVertexVsMCAngle->Fill(aMC,eta2-eta1);
+ hResPhiVertexVsMCAngle->Fill(aMC,dPhi);
+
trackParam = (AliMUONTrackParam*) trackRef->GetTrackParamAtCluster()->First();
x1 = trackParam->GetNonBendingCoor();
y1 = trackParam->GetBendingCoor();
z1 = trackParam->GetZ();
+ slopex1 = trackParam->GetNonBendingSlope();
+ slopey1 = trackParam->GetBendingSlope();
pX1 = trackParam->Px();
pY1 = trackParam->Py();
pZ1 = trackParam->Pz();
p1 = trackParam->P();
- // printf(" Ref. track at 1st cluster: x,y,z: %f %f %f px,py,pz: %f %f %f \n",x1,y1,z1,pX1,pY1,pZ1);
- trackParam = (AliMUONTrackParam*) trackOK->GetTrackParamAtCluster()->First();
+ pT1 = TMath::Sqrt(pX1*pX1 + pY1*pY1);
+
+ trackParam = (AliMUONTrackParam*) trackMatched->GetTrackParamAtCluster()->First();
x2 = trackParam->GetNonBendingCoor();
y2 = trackParam->GetBendingCoor();
z2 = trackParam->GetZ();
+ slopex2 = trackParam->GetNonBendingSlope();
+ slopey2 = trackParam->GetBendingSlope();
pX2 = trackParam->Px();
pY2 = trackParam->Py();
pZ2 = trackParam->Pz();
p2 = trackParam->P();
- // printf(" Reconst. track at 1st cluster: x,y,z: %f %f %f px,py,pz: %f %f %f \n",x2,y2,z2,pX2,pY2,pZ2);
+ pT2 = TMath::Sqrt(pX2*pX2 + pY2*pY2);
hResMomFirstCluster->Fill(p2-p1);
-
+ hResMomFirstClusterVsMom->Fill(p1,p2-p1);
+
+ hResSlopeXFirstCluster->Fill(slopex2-slopex1);
+ hResSlopeYFirstCluster->Fill(slopey2-slopey1);
+ hResSlopeXFirstClusterVsMom->Fill(p1,slopex2-slopex1);
+ hResSlopeYFirstClusterVsMom->Fill(p1,slopey2-slopey1);
+
+ // Fill residuals
+ // Loop over clusters of first track
+ AliMUONTrackParam* trackParamAtCluster1 = (AliMUONTrackParam*) trackMatched->GetTrackParamAtCluster()->First();
+ while (trackParamAtCluster1) {
+ AliMUONVCluster* cluster1 = trackParamAtCluster1->GetClusterPtr();
+ AliMUONTrackParam* trackParamAtCluster2 = (AliMUONTrackParam*) trackRef->GetTrackParamAtCluster()->First();
+ while (trackParamAtCluster2) {
+ AliMUONVCluster* cluster2 = trackParamAtCluster2->GetClusterPtr();
+ if (cluster1->GetDetElemId() == cluster2->GetDetElemId()) {
+ hResidualXInCh[cluster1->GetChamberId()]->Fill(cluster1->GetX() - cluster2->GetX());
+ hResidualYInCh[cluster1->GetChamberId()]->Fill(cluster1->GetY() - cluster2->GetY());
+ break;
+ }
+ trackParamAtCluster2 = (AliMUONTrackParam*) trackRef->GetTrackParamAtCluster()->After(trackParamAtCluster2);
+ }
+ trackParamAtCluster1 = (AliMUONTrackParam*) trackMatched->GetTrackParamAtCluster()->After(trackParamAtCluster1);
+ }
+
}
+
} // end loop track ref.
} // end loop on event
+ cout<<"\rEvent processing... "<<nevents<<" done"<<endl;
+
+ // ###################################### compute stuff ###################################### //
+ cout<<"\nWhen not specified, resolution at vertex is computed for ";
+ if (absorberRegion == 1) cout<<"tracks in the absorber region [2,3] deg."<<endl;
+ else if (absorberRegion == 2) cout<<"tracks in the absorber region [3,10] deg."<<endl;
+ else cout<<"all tracks"<<endl;
+
+ // compute momentum resolution at vertex versus p
+ TF1 *f2 = new TF1("f2",langaufun,deltaPAtVtxEdges[0],deltaPAtVtxEdges[1],4);
+ Int_t rebinFactorX = TMath::Max(hResMomVertexVsMom->GetNbinsX()/pNBins, 1);
+ for (Int_t i = rebinFactorX; i <= hResMomVertexVsMom->GetNbinsX(); i+=rebinFactorX) {
+ cout<<"\rFitting momentum residuals at vertex... "<<i/rebinFactorX<<"/"<<pNBins<<flush;
+ TH1D *tmp = hResMomVertexVsMom->ProjectionY("tmp",i-rebinFactorX+1,i,"e");
+ f2->SetParameters(0.2,0.,(Double_t)tmp->GetEntries(),1.);
+ tmp->Fit("f2","WWNQ");
+ Double_t fwhm = f2->GetParameter(0);
+ Double_t sigma = f2->GetParameter(3);
+ Double_t sigmaP = TMath::Sqrt(sigma*sigma + fwhm*fwhm/(8.*log(2.)));
+ Int_t rebin = TMath::Max(Int_t(0.5*sigmaP/tmp->GetBinWidth(1)),1);
+ while (deltaPAtVtxNBins%rebin!=0) rebin--;
+ tmp->Rebin(rebin);
+ tmp->Fit("f2","NQ");
+ fwhm = f2->GetParameter(0);
+ sigma = f2->GetParameter(3);
+ sigmaP = TMath::Sqrt(sigma*sigma + fwhm*fwhm/(8.*log(2.)));
+ Double_t fwhmErr = f2->GetParError(0);
+ Double_t sigmaErr = f2->GetParError(3);
+ Double_t sigmaPErr = TMath::Sqrt(sigma*sigma*sigmaErr*sigmaErr + fwhm*fwhm*fwhmErr*fwhmErr/(64.*log(2.)*log(2.))) / sigmaP;
+ hResMomVertexVsMom->GetXaxis()->SetRange(i-rebinFactorX+1,i);
+ Double_t p = (tmp->GetEntries() > 0) ? hResMomVertexVsMom->GetMean() : 0.5 * (hResMomVertexVsMom->GetBinLowEdge(i-rebinFactorX+1) + hResMomVertexVsMom->GetBinLowEdge(i+1));
+ hResMomVertexVsMom->GetXaxis()->SetRange();
+ Double_t pErr[2] = {p-hResMomVertexVsMom->GetBinLowEdge(i-rebinFactorX+1), hResMomVertexVsMom->GetBinLowEdge(i+1)-p};
+ gMeanResMomVertexVsMom->SetPoint(i/rebinFactorX-1, p, tmp->GetMean());
+ gMeanResMomVertexVsMom->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], tmp->GetMeanError(), tmp->GetMeanError());
+ gMostProbResMomVertexVsMom->SetPoint(i/rebinFactorX-1, p, -f2->GetParameter(1));
+ gMostProbResMomVertexVsMom->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], f2->GetParError(1), f2->GetParError(1));
+ gSigmaResMomVertexVsMom->SetPoint(i/rebinFactorX-1, p, 100.*sigmaP/p);
+ gSigmaResMomVertexVsMom->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], 100.*sigmaPErr/p, 100.*sigmaPErr/p);
+ delete tmp;
+ }
+ cout<<"\rFitting momentum residuals at vertex... "<<pNBins<<"/"<<pNBins<<endl;
+
+ // compute momentum relative resolution at first cluster versus p
+ FitGausResVsMom(hResMomFirstClusterVsMom, pNBins, 0., 1., "momentum residuals at first cluster", gMeanResMomFirstClusterVsMom, gSigmaResMomFirstClusterVsMom);
+ rebinFactorX = TMath::Max(hResMomFirstClusterVsMom->GetNbinsX()/pNBins, 1);
+ for (Int_t i = rebinFactorX; i <= hResMomFirstClusterVsMom->GetNbinsX(); i+=rebinFactorX) {
+ Double_t x,y;
+ gSigmaResMomFirstClusterVsMom->GetPoint(i/rebinFactorX-1, x, y);
+ gSigmaResMomFirstClusterVsMom->SetPoint(i/rebinFactorX-1, x, 100.*y/x);
+ gSigmaResMomFirstClusterVsMom->SetPointEYlow(i/rebinFactorX-1, 100.*gSigmaResMomFirstClusterVsMom->GetErrorYlow(i/rebinFactorX-1)/x);
+ gSigmaResMomFirstClusterVsMom->SetPointEYhigh(i/rebinFactorX-1, 100.*gSigmaResMomFirstClusterVsMom->GetErrorYhigh(i/rebinFactorX-1)/x);
+ }
+
+ // compute slopeX resolution at vertex versus p
+ FitGausResVsMom(hResSlopeXVertexVsMom, pNBins, 0., 2.e-3, "slopeX residuals at vertex", gMeanResSlopeXVertexVsMom, gSigmaResSlopeXVertexVsMom);
- printf(" nb of reconstructible tracks: %d \n", nReconstructibleTracks);
- printf(" nb of reconstructed tracks: %d \n", nReconstructedTracks);
- printf(" nb of reconstructible tracks which are reconstructed: %d \n", nReconstructibleTracksCheck);
+ // compute slopeY resolution at vertex versus p
+ FitGausResVsMom(hResSlopeYVertexVsMom, pNBins, 0., 2.e-3, "slopeY residuals at vertex", gMeanResSlopeYVertexVsMom, gSigmaResSlopeYVertexVsMom);
+ // compute slopeX resolution at first cluster versus p
+ FitGausResVsMom(hResSlopeXFirstClusterVsMom, pNBins, 0., 3.e-4, "slopeX residuals at first cluster", gMeanResSlopeXFirstClusterVsMom, gSigmaResSlopeXFirstClusterVsMom);
+
+ // compute slopeY resolution at first cluster versus p
+ FitGausResVsMom(hResSlopeYFirstClusterVsMom, pNBins, 0., 2.e-4, "slopeY residuals at first cluster", gMeanResSlopeYFirstClusterVsMom, gSigmaResSlopeYFirstClusterVsMom);
+
+ // compute p*DCA resolution in the region [2,3] deg at absorber end
+ FitPDCAVsMom(hPDCAVsMom_2_3_Deg, pNBins, "p*DCA (tracks in [2,3] deg.)", gMeanPDCAVsMom_2_3_Deg, gSigmaPDCAVsMom_2_3_Deg);
+
+ // compute p*DCA resolution in the region [3,10] deg at absorber end
+ FitPDCAVsMom(hPDCAVsMom_3_10_Deg, pNBins, "p*DCA (tracks in [3,10] deg.)", gMeanPDCAVsMom_3_10_Deg, gSigmaPDCAVsMom_3_10_Deg);
+
+ // compute MCS angular dispersion in the region [2,3] deg at absorber end
+ FitGausResVsMom(hPMCSAngVsMom_2_3_Deg, pNBins, 0., 2.e-3, "p*MCSAngle (tracks in [2,3] deg.)", gMeanPMCSAngVsMom_2_3_Deg, gSigmaPMCSAngVsMom_2_3_Deg);
+
+ // compute MCS angular dispersion in the region [3,10] deg at absorber end
+ FitGausResVsMom(hPMCSAngVsMom_3_10_Deg, pNBins, 0., 2.e-3, "p*MCSAngle (tracks in [3,10] deg.)", gMeanPMCSAngVsMom_3_10_Deg, gSigmaPMCSAngVsMom_3_10_Deg);
+
+ // compute eta resolution at vertex versus p
+ FitGausResVsMom(hResEtaVertexVsMom, pNBins, 0., 0.1, "eta residuals at vertex", gMeanResEtaVertexVsMom, gSigmaResEtaVertexVsMom);
+
+ // compute phi resolution at vertex versus p
+ FitGausResVsMom(hResPhiVertexVsMom, pNBins, 0., 0.01, "phi residuals at vertex", gMeanResPhiVertexVsMom, gSigmaResPhiVertexVsMom);
+
+ // compute cluster-track residual mean and dispersion
+ for (Int_t i = 0; i < AliMUONConstants::NTrackingCh(); i++) {
+ hResidualXInCh[i]->GetXaxis()->SetRangeUser(-3.*hResidualXInCh[i]->GetRMS(), 3.*hResidualXInCh[i]->GetRMS());
+ gResidualXPerChMean->SetPoint(i, i+1, hResidualXInCh[i]->GetMean());
+ gResidualXPerChMean->SetPointError(i, 0., hResidualXInCh[i]->GetMeanError());
+ gResidualXPerChSigma->SetPoint(i, i+1, hResidualXInCh[i]->GetRMS());
+ gResidualXPerChSigma->SetPointError(i, 0., hResidualXInCh[i]->GetRMSError());
+ hResidualXInCh[i]->GetXaxis()->SetRange(0,0);
+ hResidualYInCh[i]->GetXaxis()->SetRangeUser(-3.*hResidualYInCh[i]->GetRMS(), 3.*hResidualYInCh[i]->GetRMS());
+ gResidualYPerChMean->SetPoint(i, i+1, hResidualYInCh[i]->GetMean());
+ gResidualYPerChMean->SetPointError(i, 0., hResidualYInCh[i]->GetMeanError());
+ gResidualYPerChSigma->SetPoint(i, i+1, hResidualYInCh[i]->GetRMS());
+ gResidualYPerChSigma->SetPointError(i, 0., hResidualYInCh[i]->GetRMSError());
+ hResidualYInCh[i]->GetXaxis()->SetRange(0,0);
+ }
+
+ // ###################################### display histograms ###################################### //
+ // diplay momentum residuals
+ TCanvas* cResMom = DrawVsAng("cResMom", "momentum residual at vertex in 3 angular regions", hResMomVertex, hResMomVertexVsAngle);
+ TCanvas* cResMomMC = DrawVsAng("cResMomMC", "momentum residual at vertex in 3 MC angular regions", hResMomVertex, hResMomVertexVsMCAngle);
+ TCanvas* cResMomVsPos = DrawVsPos("cResMomVsPos", "momentum residual at vertex versus position at absorber end in 3 MC angular regions",
+ hResMomVertexVsPosAbsEnd_0_2_DegMC, hResMomVertexVsPosAbsEnd_2_3_DegMC, hResMomVertexVsPosAbsEnd_3_10_DegMC);
+ TCanvas* cResMom_2_3_Deg = DrawResMomVsMom("cResMom_2_3_Deg", "momentum residual for tracks between 2 and 3 degrees",
+ hResMomVertexVsMom_2_3_Deg, 10, f2, "momentum residuals at vertex (tracks in [2,3] deg.)");
+ TCanvas* cResMom_3_10_Deg = DrawResMomVsMom("cResMom_3_10_Deg", "momentum residual for tracks between 3 and 10 degrees",
+ hResMomVertexVsMom_3_10_Deg, 10, f2, "momentum residuals at vertex (tracks in [3,10] deg.)");
+ TCanvas* cResMom_0_2_DegMC = DrawResMomVsMom("cResMom_0_2_DegMC", "momentum residuals for tracks with MC angle < 2 degrees", hResMomVertexVsMom_0_2_DegMC, 5);
+
+ // diplay slopeX residuals
+ TCanvas* cResSlopeX = DrawVsAng("cResSlopeX", "slope_{X} residual at vertex in 3 angular regions", hResSlopeXVertex, hResSlopeXVertexVsAngle);
+ TCanvas* cResSlopeXMC = DrawVsAng("cResSlopeXMC", "slope_{X} residual at vertex in 3 MC angular regions", hResSlopeXVertex, hResSlopeXVertexVsMCAngle);
+ TCanvas* cResSlopeXVsPos = DrawVsPos("cResSlopeXVsPos", "slope_{X} residual at vertex versus position at absorber end in 3 MC angular regions",
+ hResSlopeXVertexVsPosAbsEnd_0_2_DegMC, hResSlopeXVertexVsPosAbsEnd_2_3_DegMC, hResSlopeXVertexVsPosAbsEnd_3_10_DegMC);
+
+ // diplay slopeY residuals
+ TCanvas* cResSlopeY = DrawVsAng("cResSlopeY", "slope_{Y} residual at vertex in 3 angular regions", hResSlopeYVertex, hResSlopeYVertexVsAngle);
+ TCanvas* cResSlopeYMC = DrawVsAng("cResSlopeYMC", "slope_{Y} residual at vertex in 3 MC angular regions", hResSlopeYVertex, hResSlopeYVertexVsMCAngle);
+ TCanvas* cResSlopeYVsPos = DrawVsPos("cResSlopeYVsPos", "slope_{Y} residual at vertex versus position at absorber end in 3 MC angular regions",
+ hResSlopeYVertexVsPosAbsEnd_0_2_DegMC, hResSlopeYVertexVsPosAbsEnd_2_3_DegMC, hResSlopeYVertexVsPosAbsEnd_3_10_DegMC);
+
+ // diplay P*DCA
+ TCanvas* cPDCA = DrawVsAng("cPDCA", "p #times DCA in 3 angular regions", hPDCA, hPDCAVsAngle);
+ TCanvas* cPDCAMC = DrawVsAng("cPDCAMC", "p #times DCA in 3 MC angular regions", hPDCA, hPDCAVsMCAngle);
+ TCanvas* cPDCAVsPos = DrawVsPos("cPDCAVsPos", "p #times DCA versus position at absorber end in 3 MC angular regions",
+ hPDCAVsPosAbsEnd_0_2_DegMC, hPDCAVsPosAbsEnd_2_3_DegMC, hPDCAVsPosAbsEnd_3_10_DegMC);
+
+ // diplay eta residuals
+ TCanvas* cResEta = DrawVsAng("cResEta", "eta residual at vertex in 3 angular regions", hResEtaVertex, hResEtaVertexVsAngle);
+ TCanvas* cResEtaMC = DrawVsAng("cResEtaMC", "eta residual at vertex in 3 MC angular regions", hResEtaVertex, hResEtaVertexVsMCAngle);
+ TCanvas* cResEtaVsPos = DrawVsPos("cResEtaVsPos", "eta residual at vertex versus position at absorber end in 3 MC angular regions",
+ hResEtaVertexVsPosAbsEnd_0_2_DegMC, hResEtaVertexVsPosAbsEnd_2_3_DegMC, hResEtaVertexVsPosAbsEnd_3_10_DegMC);
+
+ // diplay phi residuals
+ TCanvas* cResPhi = DrawVsAng("cResPhi", "phi residual at vertex in 3 angular regions", hResPhiVertex, hResPhiVertexVsAngle);
+ TCanvas* cResPhiMC = DrawVsAng("cResPhiMC", "phi residual at vertex in 3 MC angular regions", hResPhiVertex, hResPhiVertexVsMCAngle);
+ TCanvas* cResPhiVsPos = DrawVsPos("cResPhiVsPos", "phi residual at vertex versus position at absorber end in 3 MC angular regions",
+ hResPhiVertexVsPosAbsEnd_0_2_DegMC, hResPhiVertexVsPosAbsEnd_2_3_DegMC, hResPhiVertexVsPosAbsEnd_3_10_DegMC);
+
+ // ###################################### save histogram ###################################### //
histoFile->Write();
+
+ histoFile->cd("momentumAtVertex");
+ gMeanResMomVertexVsMom->Write();
+ gMostProbResMomVertexVsMom->Write();
+ gSigmaResMomVertexVsMom->Write();
+ cResMom->Write();
+ cResMomMC->Write();
+ cResMomVsPos->Write();
+ cResMom_2_3_Deg->Write();
+ cResMom_3_10_Deg->Write();
+ cResMom_0_2_DegMC->Write();
+
+ histoFile->cd("slopesAtVertex");
+ gMeanResSlopeXVertexVsMom->Write();
+ gMeanResSlopeYVertexVsMom->Write();
+ gSigmaResSlopeXVertexVsMom->Write();
+ gSigmaResSlopeYVertexVsMom->Write();
+ cResSlopeX->Write();
+ cResSlopeY->Write();
+ cResSlopeXMC->Write();
+ cResSlopeYMC->Write();
+ cResSlopeXVsPos->Write();
+ cResSlopeYVsPos->Write();
+
+ histoFile->cd("DCA");
+ gMeanPDCAVsMom_2_3_Deg->Write();
+ gSigmaPDCAVsMom_2_3_Deg->Write();
+ gMeanPDCAVsMom_3_10_Deg->Write();
+ gSigmaPDCAVsMom_3_10_Deg->Write();
+ gMeanPMCSAngVsMom_2_3_Deg->Write();
+ gSigmaPMCSAngVsMom_2_3_Deg->Write();
+ gMeanPMCSAngVsMom_3_10_Deg->Write();
+ gSigmaPMCSAngVsMom_3_10_Deg->Write();
+ cPDCA->Write();
+ cPDCAMC->Write();
+ cPDCAVsPos->Write();
+
+ histoFile->cd("etaAtVertex");
+ gMeanResEtaVertexVsMom->Write();
+ gSigmaResEtaVertexVsMom->Write();
+ cResEta->Write();
+ cResEtaMC->Write();
+ cResEtaVsPos->Write();
+
+ histoFile->cd("phiAtVertex");
+ gMeanResPhiVertexVsMom->Write();
+ gSigmaResPhiVertexVsMom->Write();
+ cResPhi->Write();
+ cResPhiMC->Write();
+ cResPhiVsPos->Write();
+
+ histoFile->cd("momentumAtFirstCluster");
+ gMeanResMomFirstClusterVsMom->Write();
+ gSigmaResMomFirstClusterVsMom->Write();
+
+ histoFile->cd("slopesAtFirstCluster");
+ gMeanResSlopeXFirstClusterVsMom->Write();
+ gMeanResSlopeYFirstClusterVsMom->Write();
+ gSigmaResSlopeXFirstClusterVsMom->Write();
+ gSigmaResSlopeYFirstClusterVsMom->Write();
+
+ histoFile->cd("clusters");
+ gResidualXPerChMean->Write();
+ gResidualXPerChSigma->Write();
+ gResidualYPerChMean->Write();
+ gResidualYPerChSigma->Write();
+
histoFile->Close();
+
+ // ###################################### clean memory ###################################### //
+ delete cResMom;
+ delete cResMomMC;
+ delete cResMomVsPos;
+ delete cResMom_2_3_Deg;
+ delete cResMom_3_10_Deg;
+ delete cResMom_0_2_DegMC;
+ delete cResSlopeX;
+ delete cResSlopeY;
+ delete cResSlopeXMC;
+ delete cResSlopeYMC;
+ delete cResSlopeXVsPos;
+ delete cResSlopeYVsPos;
+ delete cPDCA;
+ delete cPDCAMC;
+ delete cPDCAVsPos;
+ delete cResEta;
+ delete cResEtaMC;
+ delete cResEtaVsPos;
+ delete cResPhi;
+ delete cResPhiMC;
+ delete cResPhiVsPos;
+
+ // ###################################### print statistics ###################################### //
+ printf("\n");
+ printf("nb of reconstructible tracks: %d \n", nReconstructibleTracks);
+ printf("nb of reconstructed tracks: %d \n", nReconstructedTracks);
+ printf("nb of reconstructible tracks which are reconstructed: %d \n", nReconstructibleTracksCheck);
+
+ aMCSMoy /= (Double_t) nMCS;
+ aMCS2Moy /= (Double_t) nMCS;
+ dMCSMoy /= (Double_t) nMCS;
+ dMCS2Moy /= (Double_t) nMCS;
+ adMCSMoy /= (Double_t) nMCS;
+ Double_t sigma2_ThetaMCS = aMCS2Moy - aMCSMoy*aMCSMoy;
+ Double_t sigma2_PosMCS = dMCS2Moy - dMCSMoy*dMCSMoy;
+ Double_t cov_ThetaPosMCS = - (adMCSMoy - aMCSMoy*dMCSMoy);
+ printf("\nmultiple scattering of tracks between 3 and 10 deg. at absorber end:\n");
+ printf(" sigma_ThetaMCS = %f\n", TMath::Sqrt(sigma2_ThetaMCS));
+ printf(" sigma_PosMCS = %f\n", TMath::Sqrt(sigma2_PosMCS));
+ printf(" cov_ThetaPosMCS = %f\n", cov_ThetaPosMCS);
+ printf(" --> sigma_DCA = %f\n", TMath::Sqrt(AliMUONConstants::AbsZEnd()*AliMUONConstants::AbsZEnd()*sigma2_ThetaMCS
+ - 2.*AliMUONConstants::AbsZEnd()*cov_ThetaPosMCS + sigma2_PosMCS));
+ printf("\n");
}
+//------------------------------------------------------------------------------------
+Double_t langaufun(Double_t *x, Double_t *par) {
+
+ //Fit parameters:
+ //par[0]=Width (scale) parameter of Landau density
+ //par[1]=Most Probable (MP, location) parameter of Landau density
+ //par[2]=Total area (integral -inf to inf, normalization constant)
+ //par[3]=Width (sigma) of convoluted Gaussian function
+ //
+ //In the Landau distribution (represented by the CERNLIB approximation),
+ //the maximum is located at x=-0.22278298 with the location parameter=0.
+ //This shift is corrected within this function, so that the actual
+ //maximum is identical to the MP parameter.
+
+ // Numeric constants
+ Double_t invsq2pi = 0.3989422804014; // (2 pi)^(-1/2)
+ Double_t mpshift = -0.22278298; // Landau maximum location
+
+ // Control constants
+ Double_t np = 100.0; // number of convolution steps
+ Double_t sc = 5.0; // convolution extends to +-sc Gaussian sigmas
+
+ // Variables
+ Double_t xx;
+ Double_t mpc;
+ Double_t fland;
+ Double_t sum = 0.0;
+ Double_t xlow,xupp;
+ Double_t step;
+ Double_t i;
+
+
+ // MP shift correction
+ mpc = par[1] - mpshift * par[0];
+
+ // Range of convolution integral
+ xlow = x[0] - sc * par[3];
+ xupp = x[0] + sc * par[3];
+
+ step = (xupp-xlow) / np;
+
+ // Convolution integral of Landau and Gaussian by sum
+ for(i=1.0; i<=np/2; i++) {
+ xx = xlow + (i-.5) * step;
+ //change x -> -x because the tail of the Landau is at the left here...
+ fland = TMath::Landau(-xx,mpc,par[0]) / par[0];
+ sum += fland * TMath::Gaus(x[0],xx,par[3]);
+
+ //change x -> -x because the tail of the Landau is at the left here...
+ xx = xupp - (i-.5) * step;
+ fland = TMath::Landau(-xx,mpc,par[0]) / par[0];
+ sum += fland * TMath::Gaus(x[0],xx,par[3]);
+ }
+
+ return (par[2] * step * sum * invsq2pi / par[3]);
+}
-Int_t TrackCheck( Bool_t *compTrack)
+//------------------------------------------------------------------------------------
+void FitGausResVsMom(TH2* h, Int_t nBins, const Double_t mean0, const Double_t sigma0,
+ const char* fitting, TGraphAsymmErrors* gMean, TGraphAsymmErrors* gSigma)
{
- // Apply reconstruction requirements
- // Return number of validated conditions
- // If all the tests are verified then TrackCheck = 4 (good track)
- Int_t iTrack = 0;
- Int_t nCompClustersInLastStations = 0;
-
- // apply reconstruction requirements
- if (compTrack[0] || compTrack[1]) iTrack++; // at least one compatible cluster in st. 0
- if (compTrack[2] || compTrack[3]) iTrack++; // at least one compatible cluster in st. 1
- if (compTrack[4] || compTrack[5]) iTrack++; // at least one compatible cluster in st. 2
- for (Int_t ch = 6; ch < AliMUONConstants::NTrackingCh(); ch++) {
- if (compTrack[ch]) nCompClustersInLastStations++;
- }
- if (nCompClustersInLastStations > 2) iTrack++; // at least 3 compatible clusters in st. 3 & 4
+ /// generic function to fit residuals versus momentum with a gaussian
+ static TF1* fGaus = 0x0;
+ if (!fGaus) fGaus = new TF1("fGaus","gaus");
- return iTrack;
+ Int_t rebinFactorX = TMath::Max(h->GetNbinsX()/nBins, 1);
+ for (Int_t i = rebinFactorX; i <= h->GetNbinsX(); i+=rebinFactorX) {
+ cout<<Form("\rFitting %s... %d/%d",fitting,i/rebinFactorX,nBins)<<flush;
+ TH1D *tmp = h->ProjectionY("tmp",i-rebinFactorX+1,i,"e");
+ fGaus->SetParameters(tmp->GetEntries(), mean0, sigma0);
+ tmp->Fit("fGaus","WWNQ");
+ Int_t rebin = TMath::Max(Int_t(0.5*fGaus->GetParameter(2)/tmp->GetBinWidth(1)),1);
+ while (tmp->GetNbinsX()%rebin!=0) rebin--;
+ tmp->Rebin(rebin);
+ tmp->Fit("fGaus","NQ");
+ h->GetXaxis()->SetRange(i-rebinFactorX+1,i);
+ Double_t p = (tmp->GetEntries() > 0) ? h->GetMean() : 0.5 * (h->GetBinLowEdge(i-rebinFactorX+1) + h->GetBinLowEdge(i+1));
+ h->GetXaxis()->SetRange();
+ Double_t pErr[2] = {p-h->GetBinLowEdge(i-rebinFactorX+1), h->GetBinLowEdge(i+1)-p};
+ gMean->SetPoint(i/rebinFactorX-1, p, fGaus->GetParameter(1));
+ gMean->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], fGaus->GetParError(1), fGaus->GetParError(1));
+ gSigma->SetPoint(i/rebinFactorX-1, p, fGaus->GetParameter(2));
+ gSigma->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], fGaus->GetParError(2), fGaus->GetParError(2));
+ delete tmp;
+ }
+ cout<<Form("\rFitting %s... %d/%d",fitting,nBins,nBins)<<endl;
+}
+
+//------------------------------------------------------------------------------------
+void FitPDCAVsMom(TH2* h, Int_t nBins, const char* fitting, TGraphAsymmErrors* gMean, TGraphAsymmErrors* gSigma)
+{
+ /// generic function to fit p*DCA distributions
+ static TF1* fPGaus = 0x0;
+ if (!fPGaus) fPGaus = new TF1("fPGaus","x*gaus");
+ Int_t rebinFactorX = TMath::Max(h->GetNbinsX()/nBins, 1);
+ for (Int_t i = rebinFactorX; i <= h->GetNbinsX(); i+=rebinFactorX) {
+ cout<<Form("\rFitting %s... %d/%d",fitting,i/rebinFactorX,nBins)<<flush;
+ TH1D *tmp = h->ProjectionY("tmp",i-rebinFactorX+1,i,"e");
+ fPGaus->SetParameters(1.,0.,80.);
+ Int_t rebin = 25.*(tmp->GetNbinsX()/(tmp->GetBinLowEdge(tmp->GetNbinsX()+1)-tmp->GetBinLowEdge(1)));
+ while (tmp->GetNbinsX()%rebin!=0) rebin--;
+ tmp->Rebin(rebin);
+ tmp->Fit("fPGaus","NQ");
+ h->GetXaxis()->SetRange(i-rebinFactorX+1,i);
+ Double_t p = (tmp->GetEntries() > 0) ? h->GetMean() : 0.5 * (h->GetBinLowEdge(i-rebinFactorX+1) + h->GetBinLowEdge(i+1));
+ h->GetXaxis()->SetRange();
+ Double_t pErr[2] = {p-h->GetBinLowEdge(i-rebinFactorX+1), h->GetBinLowEdge(i+1)-p};
+ gMean->SetPoint(i/rebinFactorX-1, p, fPGaus->GetParameter(1));
+ gMean->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], fPGaus->GetParError(1), fPGaus->GetParError(1));
+ gSigma->SetPoint(i/rebinFactorX-1, p, fPGaus->GetParameter(2));
+ gSigma->SetPointError(i/rebinFactorX-1, pErr[0], pErr[1], fPGaus->GetParError(2), fPGaus->GetParError(2));
+ delete tmp;
+ }
+ cout<<Form("\rFitting %s... %d/%d",fitting,nBins,nBins)<<endl;
+}
+
+//------------------------------------------------------------------------------------
+TCanvas* DrawVsAng(const char* name, const char* title, TH1* h1, TH2* h2)
+{
+ /// generic function to draw histograms versus absorber angular region
+ TCanvas* c = new TCanvas(name, title);
+ c->cd();
+ h1->Draw();
+ TH1D *proj1 = h2->ProjectionY(Form("%s_proj_0_2",h2->GetName()),1,2);
+ proj1->Draw("sames");
+ proj1->SetLineColor(2);
+ TH1D *proj2 = h2->ProjectionY(Form("%s_proj_2_3",h2->GetName()),3,3);
+ proj2->Draw("sames");
+ proj2->SetLineColor(4);
+ TH1D *proj3 = h2->ProjectionY(Form("%s__proj_3_10",h2->GetName()),4,10);
+ proj3->Draw("sames");
+ proj3->SetLineColor(3);
+ return c;
+}
+
+//------------------------------------------------------------------------------------
+TCanvas* DrawVsPos(const char* name, const char* title, TH2* h1, TH2* h2, TH2* h3)
+{
+ /// generic function to draw histograms versus position at absorber end
+ TCanvas* c = new TCanvas(name, title);
+ c->cd();
+ h1->Draw();
+ h1->SetMarkerColor(2);
+ h2->Draw("sames");
+ h2->SetMarkerColor(4);
+ h3->Draw("sames");
+ h3->SetMarkerColor(3);
+ return c;
+}
+
+//------------------------------------------------------------------------------------
+TCanvas* DrawResMomVsMom(const char* name, const char* title, TH2* h, Int_t nBins, TF1* f2, const char* fitting)
+{
+ /// generic function to draw and eventually fit momentum residuals versus momentum
+ TLegend* l = new TLegend(0.15,0.25,0.3,0.85);
+ TCanvas* c = new TCanvas(name, title);
+ c->cd();
+ TH1D* proj = 0x0;
+ h->Sumw2();
+ Int_t rebinFactorX = TMath::Max(h->GetNbinsX()/nBins, 1);
+ for (Int_t i = rebinFactorX; i <= h->GetNbinsX(); i+=rebinFactorX) {
+ if (f2) cout<<Form("\rFitting %s... %d/%d",fitting,i/rebinFactorX,nBins)<<flush;
+ proj = h->ProjectionY(Form("%s_%d",h->GetName(),i/rebinFactorX),i-rebinFactorX+1,i);
+ if (proj->GetEntries() > 0) proj->Scale(1./proj->GetEntries());
+ proj->Draw((i==rebinFactorX)?"hist":"histsames");
+ proj->SetLineColor(i/rebinFactorX);
+ if (f2) {
+ f2->SetParameters(0.2,0.,1.,1.);
+ f2->SetLineColor(i/rebinFactorX);
+ proj->Fit("f2","WWNQ","sames");
+ Double_t fwhm = f2->GetParameter(0);
+ Double_t sigma = f2->GetParameter(3);
+ Double_t sigmaP = TMath::Sqrt(sigma*sigma + fwhm*fwhm/(8.*log(2.)));
+ Int_t rebin = TMath::Max(Int_t(0.5*sigmaP/proj->GetBinWidth(1)),1);
+ while (proj->GetNbinsX()%rebin!=0) rebin--;
+ proj->Rebin(rebin);
+ proj->Scale(1./rebin);
+ proj->Fit("f2","Q","sames");
+ } else proj->SetLineWidth(2);
+ Double_t p = 0.5 * (h->GetBinLowEdge(i-rebinFactorX+1) + h->GetBinLowEdge(i+1));
+ l->AddEntry(proj,Form("%5.1f GeV",p));
+ }
+ if (f2) cout<<Form("\rFitting %s... %d/%d",fitting,nBins,nBins)<<endl;
+ l->Draw("same");
+ return c;
}