#ifndef ALITRDTRACK_H
-#define ALITRDTRACK_H
+#define ALITRDTRACK_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
- * See cxx source for full Copyright notice */
+ * See cxx source for full Copyright notice */
#include <AliKalmanTrack.h>
-#include <TMath.h>
+#include <TMath.h>
+
+#include "AliBarrelTrack.h"
+#include "AliTRDgeometry.h"
+#include "TVector2.h"
class AliTRDcluster;
-class AliTPCtrack;
+class AliTPCtrack;
+class AliESDtrack;
const unsigned kMAX_CLUSTERS_PER_TRACK=210;
public:
- AliTRDtrack():AliKalmanTrack(){}
+ AliTRDtrack():AliKalmanTrack(){fBackupTrack=0;}
AliTRDtrack(const AliTRDcluster *c, UInt_t index, const Double_t xx[5],
const Double_t cc[15], Double_t xr, Double_t alpha);
AliTRDtrack(const AliTRDtrack& t);
AliTRDtrack(const AliKalmanTrack& t, Double_t alpha);
-
+ AliTRDtrack(const AliESDtrack& t);
+ ~AliTRDtrack();
Int_t Compare(const TObject *o) const;
void CookdEdx(Double_t low=0.05, Double_t up=0.70);
Double_t GetAlpha() const {return fAlpha;}
+ Int_t GetSector() const {
+ //if (fabs(fAlpha) < AliTRDgeometry::GetAlpha()/2) return 0;
+ return Int_t(TVector2::Phi_0_2pi(fAlpha)/AliTRDgeometry::GetAlpha())%AliTRDgeometry::kNsect;}
+
Double_t GetC() const {return fC;}
Int_t GetClusterIndex(Int_t i) const {return fIndex[i];}
Float_t GetClusterdQdl(Int_t i) const {return fdQdl[i];}
void GetCovariance(Double_t cov[15]) const;
- Float_t GetdEdx() const {return fdEdx;}
+ Double_t GetdEdx() const {return fdEdx;}
+ Double_t GetPIDsignal() const {return GetdEdx();}
Double_t GetEta() const {return fE;}
void GetExternalCovariance(Double_t cov[15]) const ;
Double_t GetLikelihoodElectron() const { return fLhElectron; };
- Double_t Get1Pt() const {return TMath::Abs(fC*GetConvConst());}
+ Double_t Get1Pt() const {return (1e-9*TMath::Abs(fC)/fC + fC)*GetConvConst(); }
Double_t GetP() const {
return TMath::Abs(GetPt())*sqrt(1.+GetTgl()*GetTgl());
}
- Double_t GetPredictedChi2(const AliTRDcluster*) const ;
+ Double_t GetPredictedChi2(const AliTRDcluster*, Double_t h01) const ;
Double_t GetPt() const {return 1./Get1Pt();}
void GetPxPyPz(Double_t &px, Double_t &py, Double_t &pz) const ;
void GetGlobalXYZ(Double_t &x, Double_t &y, Double_t &z) const ;
Double_t GetX() const {return fX;}
Double_t GetY() const {return fY;}
Double_t GetZ() const {return fZ;}
+ UInt_t * GetBackupIndexes() {return fIndexBackup;}
+ UInt_t * GetIndexes() {return fIndex;}
+
+
+ Double_t GetYat(Double_t xk) const {
+//-----------------------------------------------------------------
+// This function calculates the Y-coordinate of a track at the plane x=xk.
+// Needed for matching with the TOF (I.Belikov)
+//-----------------------------------------------------------------
+ Double_t c1=fC*fX - fE, r1=TMath::Sqrt(1.- c1*c1);
+ Double_t c2=fC*xk - fE, r2=TMath::Sqrt(1.- c2*c2);
+ return fY + (xk-fX)*(c1+c2)/(r1+r2);
+ }
+ void SetStop(Bool_t stop) {fStopped=stop;}
+ Bool_t GetStop() const {return fStopped;}
- Int_t PropagateTo(Double_t xr,
- Double_t x0=8.72,Double_t rho=5.86e-3,Double_t pm=0.139);
+ Int_t PropagateTo(Double_t xr, Double_t x0=8.72, Double_t rho=5.86e-3);
void ResetCovariance();
+ void ResetCovariance(Float_t mult);
+ void ResetClusters() { SetChi2(0.); SetNumberOfClusters(0); }
Int_t Rotate(Double_t angle);
void SetdEdx(Float_t dedx) {fdEdx=dedx;}
void SetSeedLabel(Int_t lab) { fSeedLab=lab; }
- Int_t Update(const AliTRDcluster* c, Double_t chi2, UInt_t i);
+ Int_t Update(const AliTRDcluster* c, Double_t chi2, UInt_t i,
+ Double_t h01);
+ Int_t UpdateMI(const AliTRDcluster* c, Double_t chi2, UInt_t i,
+ Double_t h01, Int_t plane);
+ //
+ void GetBarrelTrack(AliBarrelTrack *track);
+ void AddNWrong() {fNWrong++;}
+
+ Int_t GetNWrong() const {return fNWrong;}
+ Int_t GetNRotate() const {return fNRotate;}
+ Int_t GetNCross() const {return fNCross;}
+ void IncCross() {fNCross++;}
+ AliTRDtrack * GetBackupTrack(){return fBackupTrack;}
+ void MakeBackupTrack();
+ //
protected:
Double_t fAlpha; // rotation angle
Double_t fX; // running local X-coordinate of the track (time bin)
+ Bool_t fStopped; // track stop indication
- Double_t fY; // Y-coordinate of the track
- Double_t fZ; // Z-coordinate of the track
- Double_t fC; // track curvature
- Double_t fE; // C*x0
- Double_t fT; // tangent of the track dip angle
+ Double_t fY; // Y-coordinate of the track
+ Double_t fZ; // Z-coordinate of the track
+ Double_t fE; // C*x0
+ Double_t fT; // tangent of the track momentum dip angle
+ Double_t fC; // track curvature
Double_t fCyy; // covariance
Double_t fCzy, fCzz; // matrix
- Double_t fCcy, fCcz, fCcc; // of the
- Double_t fCey, fCez, fCec, fCee; // track
- Double_t fCty, fCtz, fCtc, fCte, fCtt; // parameters
-
+ Double_t fCey, fCez, fCee; // of the
+ Double_t fCty, fCtz, fCte, fCtt; // track
+ Double_t fCcy, fCcz, fCce, fCct, fCcc; // parameters
+
UInt_t fIndex[kMAX_CLUSTERS_PER_TRACK]; // global indexes of clusters
+ UInt_t fIndexBackup[kMAX_CLUSTERS_PER_TRACK]; //backup indexes of clusters - used in iterations
Float_t fdQdl[kMAX_CLUSTERS_PER_TRACK]; // cluster amplitudes corrected
// for track angles
-
+
Float_t fLhElectron; // Likelihood to be an electron
-
+ Int_t fNWrong; // number of wrong clusters
+ Int_t fNRotate; // number of rotation
+ Int_t fNCross; // number of the cross materials
+ AliTRDtrack * fBackupTrack; //! backup track
ClassDef(AliTRDtrack,2) // TRD reconstructed tracks
};