/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$ */ // ------------------------ // Class AliMUONHitForRec // ------------------------ // Hit for reconstruction in ALICE dimuon spectrometer // Author: J. Gosset #include "AliTrackReference.h" #include "AliMUONHitForRec.h" #include "AliMUONRawCluster.h" #include "AliMUONHit.h" #include "AliMUONConstants.h" #include "AliLog.h" ClassImp(AliMUONHitForRec) // Class implementation in ROOT context //__________________________________________________________________________ AliMUONHitForRec::AliMUONHitForRec() : TObject() { /// Default Constructor fFirstTrackHitPtr = 0; fLastTrackHitPtr = 0; } //__________________________________________________________________________ AliMUONHitForRec::AliMUONHitForRec(AliTrackReference* theGhit) : TObject() { /// Constructor for AliMUONHitForRec from a track ref. hit. /// Fills the bending, non bending, and Z coordinates, /// which are taken from the coordinates of the track ref. hit, /// the track number (track ref. and not TH), /// and the chamber number (0...). fBendingCoor = theGhit->Y(); fNonBendingCoor = theGhit->X(); fZ = theGhit->Z(); // fTrack = theGhit->fTrack; ????????? fChamberNumber = AliMUONConstants::ChamberNumber(fZ); fDetElemId = 0; // other fields will be updated in // AliMUONEventReconstructor::NewHitForRecFromTrackRef, // except the following ones fIndexOfFirstSegment = -1; fNSegments = 0; fFirstTrackHitPtr = fLastTrackHitPtr = NULL; fNTrackHits = 0; return; } // //__________________________________________________________________________ // AliMUONHitForRec::AliMUONHitForRec(AliMUONReconstHit* CathCorrel) // { // // Constructor for AliMUONHitForRec from a (cathode correlated) raw cluster. // // Fills the bending and non bending coordinates. // // Only the first correlation is taken into account. // // The bending coordinate is taken from the first cathode. // // The non bending coordinate is taken // // from the second cathode if it exists, // // from the first one otherwise. // fBendingCoor = CathCorrel->fY[3]; // if (CathCorrel->fCorrelIndex[0] >= 0) fNonBendingCoor = CathCorrel->fX[0]; // else fNonBendingCoor = CathCorrel->fX[3]; // return; // } //__________________________________________________________________________ AliMUONHitForRec::AliMUONHitForRec(AliMUONRawCluster* theRawCluster) : TObject() { /// Constructor for AliMUONHitForRec from a raw cluster. /// Fills the bending and non bending coordinates. fNonBendingCoor = theRawCluster->GetX(0); fBendingCoor = theRawCluster->GetY(0); fDetElemId = theRawCluster->GetDetElemId(); // other fields will be updated in // AliMUONEventReconstructor::AddHitsForRecFromRawClusters, // except the following ones fTTRTrack = -1; fTrackRefSignal = -1; fIndexOfFirstSegment = -1; fNSegments = 0; fFirstTrackHitPtr = fLastTrackHitPtr = NULL; fNTrackHits = 0; return; } //__________________________________________________________________________ AliMUONHitForRec::AliMUONHitForRec (const AliMUONHitForRec& theMUONHitForRec) : TObject(theMUONHitForRec) { /// Copy constructor fBendingCoor = theMUONHitForRec.fBendingCoor; fNonBendingCoor = theMUONHitForRec.fNonBendingCoor; fZ = theMUONHitForRec.fZ; fBendingReso2 = theMUONHitForRec.fBendingReso2; fNonBendingReso2 = theMUONHitForRec.fNonBendingReso2; fChamberNumber = theMUONHitForRec.fChamberNumber; fDetElemId = theMUONHitForRec.fDetElemId; fHitNumber = theMUONHitForRec.fHitNumber; fTTRTrack = theMUONHitForRec.fTTRTrack; fTrackRefSignal = theMUONHitForRec.fTrackRefSignal; fIndexOfFirstSegment = theMUONHitForRec.fIndexOfFirstSegment; fNSegments = theMUONHitForRec.fNSegments; fFirstTrackHitPtr = theMUONHitForRec.fFirstTrackHitPtr; fLastTrackHitPtr = theMUONHitForRec.fLastTrackHitPtr; fNTrackHits = theMUONHitForRec.fNTrackHits; } //__________________________________________________________________________ AliMUONHitForRec & AliMUONHitForRec::operator=(const AliMUONHitForRec& theMUONHitForRec) { /// Assignment operator fBendingCoor = theMUONHitForRec.fBendingCoor; fNonBendingCoor = theMUONHitForRec.fNonBendingCoor; fZ = theMUONHitForRec.fZ; fBendingReso2 = theMUONHitForRec.fBendingReso2; fNonBendingReso2 = theMUONHitForRec.fNonBendingReso2; fChamberNumber = theMUONHitForRec.fChamberNumber; fDetElemId = theMUONHitForRec.fDetElemId; fHitNumber = theMUONHitForRec.fHitNumber; fTTRTrack = theMUONHitForRec.fTTRTrack; fTrackRefSignal = theMUONHitForRec.fTrackRefSignal; fIndexOfFirstSegment = theMUONHitForRec.fIndexOfFirstSegment; fNSegments = theMUONHitForRec.fNSegments; fFirstTrackHitPtr = theMUONHitForRec.fFirstTrackHitPtr; fLastTrackHitPtr = theMUONHitForRec.fLastTrackHitPtr; fNTrackHits = theMUONHitForRec.fNTrackHits; return *this; } //__________________________________________________________________________ /*AZ Int_t AliMUONHitForRec::Compare(const TObject* Hit) const { // "Compare" function to sort with increasing chamber number. // Returns -1 (0, +1) if ChamberNumber of current HitForRec // is smaller than (equal to, larger than) ChamberNumber of Hit if (fChamberNumber < ((AliMUONHitForRec*)Hit)->fChamberNumber) return(-1); else if (fChamberNumber == ((AliMUONHitForRec*)Hit)->fChamberNumber) return( 0); else return(+1); } */ //__________________________________________________________________________ Int_t AliMUONHitForRec::Compare(const TObject* Hit) const { /// "Compare" function to sort with decreasing Z-coordinate (spectro. MUON z<0). /// Returns 1 (0, -1) if Z-coordinate of current HitForRec /// is smaller than (equal to, larger than) Z-coordinate of Hit if (fZ < ((AliMUONHitForRec*)Hit)->fZ) return(1); else if (fZ == ((AliMUONHitForRec*)Hit)->fZ) return( 0); else return(-1); } //__________________________________________________________________________ Double_t AliMUONHitForRec::NormalizedChi2WithHitForRec(AliMUONHitForRec* hitForRec, Double_t Sigma2Cut) const { /// Calculate the normalized Chi2 between the current hitForRec (this) /// and the hitForRec pointed to by "hitForRec", /// i.e. the square deviations between the coordinates, /// in both the bending and the non bending plane, /// divided by the variance of the same quantities and by "Sigma2Cut". /// Returns 3 if none of the 2 quantities is OK, /// something smaller than or equal to 2 otherwise. /// Would it be more correct to use a real chi square /// including the non diagonal term ???? Double_t chi2, chi2Max, diff, normDiff; chi2 = 0.0; chi2Max = 3.0; // coordinate in bending plane diff = fBendingCoor - hitForRec->fBendingCoor; normDiff = diff * diff / (fBendingReso2 + hitForRec->fBendingReso2) / Sigma2Cut; if (normDiff > 1.0) return chi2Max; chi2 = chi2 + normDiff; // coordinate in non bending plane diff = fNonBendingCoor - hitForRec->fNonBendingCoor; normDiff = diff * diff / (fNonBendingReso2 + hitForRec->fNonBendingReso2) / Sigma2Cut; if (normDiff > 1.0) return chi2Max; chi2 = chi2 + normDiff; return chi2; }