[u/mrichter/AliRoot.git] / MUON / AliMUONSegment.cxx

/**************************************************************************
 * 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.                  *
 **************************************************************************/

/*
$Log$
Revision 1.7  2001/02/08 10:34:41  gosset
Add a "real" default constructor.

Revision 1.6  2001/02/05 14:49:29  hristov
Compare() declared const (R.Brun)

Revision 1.5  2001/01/08 11:01:02  gosset
Modifications used for addendum to Dimuon TDR (JP Cussonneau):
*. MaxBendingMomentum to make both a segment and a track (default 500)
*. MaxChi2 per degree of freedom to make a track (default 100)
*. MinBendingMomentum used also to make a track
   and not only a segment (default 3)
*. wider roads for track search in stations 1 to 3
*. extrapolation to actual Z instead of Z(chamber) in FollowTracks
*. in track fit:
   - limits on parameters X and Y (+/-500)
   - covariance matrices in double precision
   - normalization of covariance matrices before inversion
   - suppression of Minuit printouts
*. correction against memory leak (delete extrapHit) in FollowTracks
*. RMax to 10 degrees with Z(chamber) instead of fixed values;
   RMin and Rmax cuts suppressed in NewHitForRecFromGEANT,
   because useless with realistic geometry

Revision 1.4  2000/06/30 10:15:48  gosset
Changes to EventReconstructor...:
precision fit with multiple Coulomb scattering;
extrapolation to vertex with Branson correction in absorber (JPC)

Revision 1.3  2000/06/25 13:06:39  hristov
Inline functions moved from *.cxx to *.h files instead of forward declarations

Revision 1.2  2000/06/15 07:58:48  morsch
Code from MUON-dev joined

Revision 1.1.2.4  2000/06/12 10:10:21  morsch
Dummy copy constructor and assignment operator added

Revision 1.1.2.3  2000/06/09 21:01:16  morsch
Make includes consistent with new file structure.

Revision 1.1.2.2  2000/06/09 12:58:05  gosset
Removed comment beginnings in Log sections of .cxx files
Suppressed most violations of coding rules

Revision 1.1.2.1  2000/06/07 14:44:53  gosset
Addition of files for track reconstruction in C++
*/

///////////////////////////////////////////////////////////
//
// Segment for reconstruction
// in 
// ALICE 
// dimuon 
// spectrometer:
// two hits for reconstruction in the two chambers of one station
//
///////////////////////////////////////////////////////////

#include "AliMUON.h"
#include "AliMUONChamber.h" 
#include "AliMUONHitForRec.h" 
#include "AliMUONSegment.h" 
#include "AliMUONTrackParam.h" 
#include "AliRun.h" // for gAlice

ClassImp(AliMUONSegment) // Class implementation in ROOT context

  //__________________________________________________________________________
AliMUONSegment::AliMUONSegment()
{
  // Default constructor
  fHitForRecPtr1 = 0; // pointer to HitForRec in first chamber
  fHitForRecPtr2 = 0; // pointer to HitForRec in second chamber
  // Bending plane:
  fBendingCoor = 0.0; // Coordinate in bending plane
  fBendingSlope = 0.0; // Slope in bending plane
  // Covariance in bending plane:
  fBendingCoorReso2 = 0.0; // Covariance(coordinate C1 in first chamber)
  fBendingSlopeReso2 = 0.0; // Covariance(slope)
  fBendingCoorSlopeReso2 = 0.0; // Covariance(C1,slope)
  fBendingImpact = 0.0; // Impact parameter in bending plane
  // Non Bending plane:
  fNonBendingCoor = 0.0; // Coordinate in non bending plane
  fNonBendingSlope = 0.0; // Slope in non bending plane
  // Covariance in non bending plane:
  fNonBendingCoorReso2 = 0.0; // Covariance(coordinate C1 in first chamber)
  fNonBendingSlopeReso2 = 0.0; // Covariance(slope)
  fNonBendingCoorSlopeReso2 = 0.0; // Covariance(C1,slope)
  fNonBendingImpact = 0.0; // Impact parameter in non bending plane
  fInTrack = kFALSE; // TRUE if segment belongs to one track
}

  //__________________________________________________________________________
AliMUONSegment::AliMUONSegment(AliMUONHitForRec* Hit1, AliMUONHitForRec* Hit2)
{
  // Constructor for AliMUONSegment from two HitForRec's,
  // one, in the first chamber of the station, pointed to by "Hit1",
  // the other one, in the second chamber of the station, pointed to by "Hit1".
  // Fills the pointers to both hits,
  // the slope, the covariance for (coordinate in first chamber, slope),
  // and the impact parameter at vertex (Z=0),
  // in bending and non bending planes.
  // Puts the "fInTrack" flag to "kFALSE".
  Double_t dz;
  // pointers to HitForRec's
  fHitForRecPtr1 = Hit1;
  fHitForRecPtr2 = Hit2;
  dz = Hit1->GetZ() - Hit2->GetZ();
  // bending plane
  fBendingCoor = Hit1->GetBendingCoor();
  fBendingSlope = (fBendingCoor - Hit2->GetBendingCoor()) / dz;
  fBendingImpact = fBendingCoor - Hit1->GetZ() * fBendingSlope;
  fBendingCoorReso2 = Hit1->GetBendingReso2();
  fBendingSlopeReso2 = ( Hit1->GetBendingReso2() +
			 Hit2->GetBendingReso2() ) / dz / dz;
  fBendingCoorSlopeReso2 = Hit1->GetBendingReso2() / dz;
  // non bending plane
  fNonBendingCoor = Hit1->GetNonBendingCoor();
  fNonBendingSlope = (fNonBendingCoor - Hit2->GetNonBendingCoor()) / dz;
  fNonBendingImpact = fNonBendingCoor - Hit1->GetZ() * fNonBendingSlope;
  fNonBendingCoorReso2 = Hit1->GetNonBendingReso2();
  fNonBendingSlopeReso2 = ( Hit1->GetNonBendingReso2() +
			    Hit2->GetNonBendingReso2() ) / dz / dz;
  fNonBendingCoorSlopeReso2 = Hit1->GetNonBendingReso2() / dz;
  // "fInTrack" flag to "kFALSE"
  fInTrack = kFALSE;
  return;
}

AliMUONSegment::AliMUONSegment (const AliMUONSegment& MUONSegment)
{
// Dummy copy constructor
}

AliMUONSegment & AliMUONSegment::operator=(const AliMUONSegment& MUONSegment)
{
// Dummy assignment operator
    return *this;
}

  //__________________________________________________________________________
Int_t AliMUONSegment::Compare(const TObject* Segment) const
{
  // "Compare" function to sort with increasing absolute value
  // of the "impact parameter" in bending plane.
  // Returns -1 (0, +1) if |impact parameter| of current Segment
  // is smaller than (equal to, larger than) |impact parameter| of Segment
  if (TMath::Abs(((AliMUONSegment*)this)->fBendingSlope)
      < TMath::Abs(((AliMUONSegment*)Segment)->fBendingSlope))
    return(-1);
  // continuous parameter, hence no need for testing equal case
  else return(+1);
}

  //__________________________________________________________________________
Double_t AliMUONSegment::NormalizedChi2WithSegment(AliMUONSegment* Segment, Double_t Sigma2Cut)
{
  // Calculate the normalized Chi2 between the current Segment (this)
  // and the Segment pointed to by "Segment",
  // i.e. the square deviations between the coordinates and the slopes,
  // in both the bending and the non bending plane,
  // divided by the variance of the same quantities and by "Sigma2Cut".
  // Returns 5 if none of the 4 quantities is OK,
  // something smaller than or equal to 4 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 = 5.0;
  // coordinate in bending plane
  diff = this->fBendingCoor - Segment->fBendingCoor;
  normDiff = diff * diff /
    (this->fBendingCoorReso2 + Segment->fBendingCoorReso2) / Sigma2Cut;
  if (normDiff > 1.0) return chi2Max;
  chi2 = chi2 + normDiff;
  // slope in bending plane
  diff = this->fBendingSlope - Segment->fBendingSlope;
  normDiff = diff * diff /
    (this->fBendingSlopeReso2 + Segment->fBendingSlopeReso2) / Sigma2Cut;
  if (normDiff > 1.0) return chi2Max;
  chi2 = chi2 + normDiff;
  // coordinate in non bending plane
  diff = this->fNonBendingCoor - Segment->fNonBendingCoor;
  normDiff = diff * diff /
    (this->fNonBendingCoorReso2 + Segment->fNonBendingCoorReso2) / Sigma2Cut;
  if (normDiff > 1.0) return chi2Max;
  chi2 = chi2 + normDiff;
  // slope in non bending plane
  diff = this->fNonBendingSlope - Segment->fNonBendingSlope;
  normDiff = diff * diff /
    (this->fNonBendingSlopeReso2 + Segment->fNonBendingSlopeReso2) / Sigma2Cut;
  if (normDiff > 1.0) return chi2Max;
  chi2 = chi2 + normDiff;
  return chi2;
}

  //__________________________________________________________________________
AliMUONSegment* AliMUONSegment::CreateSegmentFromLinearExtrapToStation (Int_t Station, Double_t MCSfactor)
{
  // Extrapolates linearly the current Segment (this) to station (0..) "Station".
  // Multiple Coulomb scattering calculated from "MCSfactor"
  // corresponding to one chamber,
  // with one chamber for the coordinate, two chambers for the angle,
  // due to the arrangement in stations.
  // Valid from station(1..) 4 to 5 or vice versa.
  // Returns the pointer to the created AliMUONSegment object
  // corresponding to this extrapolation.
  // The caller has the responsibility to delete this object.
  AliMUONSegment* extrapSegment = new AliMUONSegment(); // creates empty new segment
  // dZ from first hit of current Segment to first chamber of station "Station"
  AliMUON *pMUON = (AliMUON*) gAlice->GetModule("MUON"); // necessary ????
  Double_t dZ =
    (&(pMUON->Chamber(2 * Station)))->Z() - (this->fHitForRecPtr1)->GetZ();
  // Data in bending plane
  //  coordinate
  extrapSegment->fBendingCoor = this->fBendingCoor + this->fBendingSlope * dZ;
  //  slope
  extrapSegment->fBendingSlope = this->fBendingSlope;
  //  covariance, including multiple Coulomb scattering over dZ due to one chamber
  extrapSegment->fBendingCoorReso2 = this->fBendingCoorReso2 +
    (this->fBendingSlopeReso2 + MCSfactor) * dZ * dZ; // missing non diagonal term: "2.0 * this->fBendingCoorSlopeReso2 * dZ" !!!!
  extrapSegment->fBendingSlopeReso2 = this->fBendingSlopeReso2 + 2.0 * MCSfactor;
  extrapSegment->fBendingCoorSlopeReso2 =
    this->fBendingCoorSlopeReso2 + this->fBendingSlopeReso2 * dZ; // missing: contribution from multiple Coulomb scattering !!!!
  // Data in non bending plane
  //  coordinate
  extrapSegment->fNonBendingCoor =
    this->fNonBendingCoor + this->fNonBendingSlope * dZ;
  //  slope
  extrapSegment->fNonBendingSlope = this->fNonBendingSlope;
  //  covariance, including multiple Coulomb scattering over dZ due to one chamber
  extrapSegment->fNonBendingCoorReso2 = this->fNonBendingCoorReso2 +
    (this->fNonBendingSlopeReso2 + MCSfactor) *dZ * dZ; // missing non diagonal term: "2.0 * this->fNonBendingCoorSlopeReso2 * dZ" !!!!
  extrapSegment->fNonBendingSlopeReso2 =
    this->fNonBendingSlopeReso2 + 2.0 * MCSfactor;
  extrapSegment->fNonBendingCoorSlopeReso2 =
    this->fNonBendingCoorSlopeReso2 + this->fNonBendingSlopeReso2 * dZ; // missing: contribution from multiple Coulomb scattering !!!!
  return extrapSegment;
}

  //__________________________________________________________________________
AliMUONHitForRec* AliMUONSegment::CreateHitForRecFromLinearExtrapToChamber (Int_t Chamber, Double_t MCSfactor)
{
  // Extrapolates linearly the current Segment (this) to chamber(0..) "Chamber".
  // Multiple Coulomb scattering calculated from "MCSfactor"
  // corresponding to one chamber.
  // Valid from station(1..) 4 to 5 or vice versa.
  // Returns the pointer to the created AliMUONHitForRec object
  // corresponding to this extrapolation.
  // The caller has the responsibility to delete this object.
  AliMUONHitForRec* extrapHitForRec = new AliMUONHitForRec(); // creates empty new HitForRec
  // dZ from first hit of current Segment to chamber
  AliMUON *pMUON = (AliMUON*) gAlice->GetModule("MUON"); // necessary ????
  Double_t dZ =
    (&(pMUON->Chamber(Chamber)))->Z() - (this->fHitForRecPtr1)->GetZ();
  // Data in bending plane
  //  coordinate
  extrapHitForRec->SetBendingCoor(this->fBendingCoor + this->fBendingSlope * dZ);
  //  covariance, including multiple Coulomb scattering over dZ due to one chamber
  extrapHitForRec->SetBendingReso2(this->fBendingCoorReso2 +
				   (this->fBendingSlopeReso2 + MCSfactor) * dZ * dZ); // missing non diagonal term: "2.0 * this->fBendingCoorSlopeReso2 * dZ" !!!!
  // Data in non bending plane
  //  coordinate
 extrapHitForRec ->SetNonBendingCoor(this->fNonBendingCoor +
				     this->fNonBendingSlope * dZ);
  //  covariance, including multiple Coulomb scattering over dZ due to one chamber
  extrapHitForRec->
    SetNonBendingReso2(this->fNonBendingCoorReso2 +
		       (this->fNonBendingSlopeReso2 + MCSfactor) * dZ * dZ); // missing non diagonal term: "2.0 * this->fNonBendingCoorSlopeReso2 * dZ" !!!!
  return extrapHitForRec;
}

  //__________________________________________________________________________
void AliMUONSegment::UpdateFromStationTrackParam(AliMUONTrackParam *TrackParam, Double_t MCSfactor, Double_t Dz1, Double_t Dz2, Double_t Dz3, Int_t Station, Double_t InverseMomentum)
{
  // Fill data members with values calculated from the array of track parameters
  // pointed to by "TrackParam" (index = 0 and 1 for first and second chambers
  // of the station, respectively).
  // Multiple Coulomb scattering is taking into account with "MCSfactor"
  // corresponding to one chamber,
  // with one chamber for the coordinate, two chambers for the angle,
  // due to the arrangement in stations.
  // Resolution coming from:
  // coordinate in closest station at "Dz1" from current "Station",
  // slope between closest stations, with "Dz2" interval between them,
  // interval "Dz3" between chambers of closest station,
  // extrapolation over "Dz1" from closest station,
  // "InverseMomentum".
  // When called, "fBendingCoorReso2" and "fNonBendingCoorReso2"
  // are assumed to be filled
  // with the variance on bending and non bending coordinates.
  // The "road" is parametrized from the old reco_muon.F
  // with 8 cm between stations.
  AliMUONTrackParam *param0;
//   Double_t cReso2, sReso2;
  // parameters to define the widths of the searching roads in station 0,1,2
  // width = p0 + p1/ (momentum)^2
  //                  station number:        0         1          2
//   static Double_t p0BendingCoor[3] =     { 6.43e-2, 1.64e-2,   0.034 };   
//   static Double_t p1BendingCoor[3] =     {    986.,    821.,    446. };  
//   static Double_t p0BendingSlope[3] =    { 3.54e-6, 3.63e-6,  3.6e-6 };  
//   static Double_t p1BendingSlope[3] =    { 4.49e-3,  4.8e-3,   0.011 };  
//   static Double_t p0NonBendingCoor[3] =  { 4.66e-2, 4.83e-2,   0.049 };   
//   static Double_t p1NonBendingCoor[3] =  {   1444.,    866.,    354. };  
//   static Double_t p0NonBendingSlope[3] = { 6.14e-4, 6.49e-4, 6.85e-4 };  
//   static Double_t p1NonBendingSlope[3] = {      0.,      0.,      0. };
  
  static Double_t p0BendingCoor[3] =     { 6.43e-2, 6.43e-2,   6.43e-2  };   
  static Double_t p1BendingCoor[3] =     {    986.,    986.,       986. };  
  static Double_t p0BendingSlope[3] =    {   3.6e-6,   3.6e-6,     3.6e-6  };  
  static Double_t p1BendingSlope[3] =    {  1.1e-2,  1.1e-2,    1.1e-2  };  
  static Double_t p0NonBendingCoor[3] =  {   0.049,   0.049,     0.049  };   
  static Double_t p1NonBendingCoor[3] =  {   1444.,   1444.,      1444. };  
  static Double_t p0NonBendingSlope[3] = {   6.8e-4,   6.8e-4,     6.8e-4  };  
  static Double_t p1NonBendingSlope[3] = {      0.,      0.,         0. };  
  param0 = &(TrackParam[0]);

// OLD version
//   // Bending plane
//   fBendingCoor = param0->GetBendingCoor(); // coordinate
//   fBendingSlope = param0->GetBendingSlope(); // slope
//   cReso2 = fBendingCoorReso2;
//   sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
//   fBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
//   fBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
//   // Non bending plane
//   fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
//   fNonBendingSlope = param0->GetNonBendingSlope(); // slope
//   cReso2 = fNonBendingCoorReso2;
//   sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
//   fNonBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
//   fNonBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;

  // Coordinate and slope
  // Bending plane
  fBendingCoor = param0->GetBendingCoor(); // coordinate
  fBendingSlope = param0->GetBendingSlope(); // slope
  // Non bending plane
  fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
  fNonBendingSlope = param0->GetNonBendingSlope(); // slope

  // Resolutions
  // cReso2 and sReso2 have to be subtracted here from the parametrization
  // because they are added in the functions "NormalizedChi2WithSegment"
  // and "NormalizedChi2WithHitForRec"
  // Bending plane
//   cReso2 = fBendingCoorReso2;
//   sReso2 = (2. * cReso2 )/ (Dz3*Dz3) ;
  fBendingCoorReso2 = p0BendingCoor[Station] + p1BendingCoor[Station]*InverseMomentum*InverseMomentum ;  // - cReso2
  fBendingSlopeReso2 = p0BendingSlope[Station] + p1BendingSlope[Station]*InverseMomentum*InverseMomentum; //  - sReso2;
  // Non bending plane
//   cReso2 = fNonBendingCoorReso2;
//   sReso2 =  (2. * cReso2 )/ (Dz3*Dz3) ;
  fNonBendingCoorReso2 = p0NonBendingCoor[Station] + p1NonBendingCoor[Station]*InverseMomentum*InverseMomentum; // - cReso2;
  fNonBendingSlopeReso2 = p0NonBendingSlope[Station] + p1NonBendingSlope[Station]*InverseMomentum*InverseMomentum; //  - sReso2;
  return;
}

// OLD function, with roads automatically calculated instead from being parametrized
// kept because it would be a better solution,
// if one can really find the right values.
//   //__________________________________________________________________________
// void AliMUONSegment::UpdateFromStationTrackParam(AliMUONTrackParam *TrackParam, Double_t MCSfactor, Double_t Dz1, Double_t Dz2)
// {
//   // Fill data members with values calculated from the array of track parameters
//   // pointed to by "TrackParam" (index = 0 and 1 for first and second chambers
//   // of the station, respectively).
//   // Multiple Coulomb scattering is taking into account with "MCSfactor"
//   // corresponding to one chamber,
//   // with one chamber for the coordinate, two chambers for the angle,
//   // due to the arrangement in stations.
//   // Resolution coming from:
//   // coordinate in closest station at "Dz1",
//   // slope between closest stations, with "Dz2" interval between them,
//   // extrapolation over "Dz" from closest station.
//   // When called, "fBendingCoorReso2" and "fNonBendingCoorReso2"
//   // are assumed to be filled
//   // with the variance on bending and non bending coordinates.
//   AliMUONTrackParam *param0;
//   Double_t cReso2, sReso2;
//   param0 = &(TrackParam[0]);
//   // Bending plane
//   fBendingCoor = param0->GetBendingCoor(); // coordinate
//   fBendingSlope = param0->GetBendingSlope(); // slope
//   cReso2 = fBendingCoorReso2;
//   sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
//   fBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
//   fBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
//   // Non bending plane
//   fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
//   fNonBendingSlope = param0->GetNonBendingSlope(); // slope
//   cReso2 = fNonBendingCoorReso2;
//   sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
//   fNonBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
//   fNonBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
//   return;
// }
Commit	Line	Data
a9e2aefa	1	/**************************************************************************
	2	* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	3	* *
	4	* Author: The ALICE Off-line Project. *
	5	* Contributors are mentioned in the code where appropriate. *
	6	* *
	7	* Permission to use, copy, modify and distribute this software and its *
	8	* documentation strictly for non-commercial purposes is hereby granted *
	9	* without fee, provided that the above copyright notice appears in all *
	10	* copies and that both the copyright notice and this permission notice *
	11	* appear in the supporting documentation. The authors make no claims *
	12	* about the suitability of this software for any purpose. It is *
	13	* provided "as is" without express or implied warranty. *
	14	**************************************************************************/
	15
	16	/*
	17	$Log$
3831f268	18	Revision 1.7 2001/02/08 10:34:41 gosset
	19	Add a "real" default constructor.
	20
762647ff	21	Revision 1.6 2001/02/05 14:49:29 hristov
	22	Compare() declared const (R.Brun)
	23
2a941f4e	24	Revision 1.5 2001/01/08 11:01:02 gosset
	25	Modifications used for addendum to Dimuon TDR (JP Cussonneau):
	26	*. MaxBendingMomentum to make both a segment and a track (default 500)
	27	*. MaxChi2 per degree of freedom to make a track (default 100)
	28	*. MinBendingMomentum used also to make a track
	29	and not only a segment (default 3)
	30	*. wider roads for track search in stations 1 to 3
	31	*. extrapolation to actual Z instead of Z(chamber) in FollowTracks
	32	*. in track fit:
	33	- limits on parameters X and Y (+/-500)
	34	- covariance matrices in double precision
	35	- normalization of covariance matrices before inversion
	36	- suppression of Minuit printouts
	37	*. correction against memory leak (delete extrapHit) in FollowTracks
	38	*. RMax to 10 degrees with Z(chamber) instead of fixed values;
	39	RMin and Rmax cuts suppressed in NewHitForRecFromGEANT,
	40	because useless with realistic geometry
	41
d0bfce8d	42	Revision 1.4 2000/06/30 10:15:48 gosset
	43	Changes to EventReconstructor...:
	44	precision fit with multiple Coulomb scattering;
	45	extrapolation to vertex with Branson correction in absorber (JPC)
	46
04b5ea16	47	Revision 1.3 2000/06/25 13:06:39 hristov
	48	Inline functions moved from .cxx to .h files instead of forward declarations
	49
9b03f36b	50	Revision 1.2 2000/06/15 07:58:48 morsch
	51	Code from MUON-dev joined
	52
a9e2aefa	53	Revision 1.1.2.4 2000/06/12 10:10:21 morsch
	54	Dummy copy constructor and assignment operator added
	55
	56	Revision 1.1.2.3 2000/06/09 21:01:16 morsch
	57	Make includes consistent with new file structure.
	58
	59	Revision 1.1.2.2 2000/06/09 12:58:05 gosset
	60	Removed comment beginnings in Log sections of .cxx files
	61	Suppressed most violations of coding rules
	62
	63	Revision 1.1.2.1 2000/06/07 14:44:53 gosset
	64	Addition of files for track reconstruction in C++
	65	*/
	66
3831f268	67	///////////////////////////////////////////////////////////
a9e2aefa	68	//
3831f268	69	// Segment for reconstruction
	70	// in
	71	// ALICE
	72	// dimuon
	73	// spectrometer:
a9e2aefa	74	// two hits for reconstruction in the two chambers of one station
3831f268	75	//
3831f268	76	///////////////////////////////////////////////////////////
a9e2aefa	77
a9e2aefa	78	#include "AliMUON.h"
3831f268	79	#include "AliMUONChamber.h"
a9e2aefa	80	#include "AliMUONHitForRec.h"
3831f268	81	#include "AliMUONSegment.h"
a9e2aefa	82	#include "AliMUONTrackParam.h"
3831f268	83	#include "AliRun.h" // for gAlice
a9e2aefa	84
	85	ClassImp(AliMUONSegment) // Class implementation in ROOT context
	86
762647ff	87	//__________________________________________________________________________
	88	AliMUONSegment::AliMUONSegment()
	89	{
	90	// Default constructor
	91	fHitForRecPtr1 = 0; // pointer to HitForRec in first chamber
	92	fHitForRecPtr2 = 0; // pointer to HitForRec in second chamber
	93	// Bending plane:
	94	fBendingCoor = 0.0; // Coordinate in bending plane
	95	fBendingSlope = 0.0; // Slope in bending plane
	96	// Covariance in bending plane:
	97	fBendingCoorReso2 = 0.0; // Covariance(coordinate C1 in first chamber)
	98	fBendingSlopeReso2 = 0.0; // Covariance(slope)
	99	fBendingCoorSlopeReso2 = 0.0; // Covariance(C1,slope)
	100	fBendingImpact = 0.0; // Impact parameter in bending plane
	101	// Non Bending plane:
	102	fNonBendingCoor = 0.0; // Coordinate in non bending plane
	103	fNonBendingSlope = 0.0; // Slope in non bending plane
	104	// Covariance in non bending plane:
	105	fNonBendingCoorReso2 = 0.0; // Covariance(coordinate C1 in first chamber)
	106	fNonBendingSlopeReso2 = 0.0; // Covariance(slope)
	107	fNonBendingCoorSlopeReso2 = 0.0; // Covariance(C1,slope)
	108	fNonBendingImpact = 0.0; // Impact parameter in non bending plane
	109	fInTrack = kFALSE; // TRUE if segment belongs to one track
	110	}
	111
a9e2aefa	112	//__________________________________________________________________________
	113	AliMUONSegment::AliMUONSegment(AliMUONHitForRec* Hit1, AliMUONHitForRec* Hit2)
	114	{
	115	// Constructor for AliMUONSegment from two HitForRec's,
	116	// one, in the first chamber of the station, pointed to by "Hit1",
	117	// the other one, in the second chamber of the station, pointed to by "Hit1".
	118	// Fills the pointers to both hits,
	119	// the slope, the covariance for (coordinate in first chamber, slope),
	120	// and the impact parameter at vertex (Z=0),
	121	// in bending and non bending planes.
	122	// Puts the "fInTrack" flag to "kFALSE".
	123	Double_t dz;
	124	// pointers to HitForRec's
	125	fHitForRecPtr1 = Hit1;
	126	fHitForRecPtr2 = Hit2;
	127	dz = Hit1->GetZ() - Hit2->GetZ();
	128	// bending plane
	129	fBendingCoor = Hit1->GetBendingCoor();
	130	fBendingSlope = (fBendingCoor - Hit2->GetBendingCoor()) / dz;
	131	fBendingImpact = fBendingCoor - Hit1->GetZ() * fBendingSlope;
	132	fBendingCoorReso2 = Hit1->GetBendingReso2();
	133	fBendingSlopeReso2 = ( Hit1->GetBendingReso2() +
	134	Hit2->GetBendingReso2() ) / dz / dz;
	135	fBendingCoorSlopeReso2 = Hit1->GetBendingReso2() / dz;
	136	// non bending plane
	137	fNonBendingCoor = Hit1->GetNonBendingCoor();
	138	fNonBendingSlope = (fNonBendingCoor - Hit2->GetNonBendingCoor()) / dz;
	139	fNonBendingImpact = fNonBendingCoor - Hit1->GetZ() * fNonBendingSlope;
	140	fNonBendingCoorReso2 = Hit1->GetNonBendingReso2();
	141	fNonBendingSlopeReso2 = ( Hit1->GetNonBendingReso2() +
	142	Hit2->GetNonBendingReso2() ) / dz / dz;
	143	fNonBendingCoorSlopeReso2 = Hit1->GetNonBendingReso2() / dz;
	144	// "fInTrack" flag to "kFALSE"
	145	fInTrack = kFALSE;
	146	return;
	147	}
	148
	149	AliMUONSegment::AliMUONSegment (const AliMUONSegment& MUONSegment)
	150	{
	151	// Dummy copy constructor
	152	}
	153
	154	AliMUONSegment & AliMUONSegment::operator=(const AliMUONSegment& MUONSegment)
	155	{
	156	// Dummy assignment operator
	157	return *this;
	158	}
	159
a9e2aefa	160	//__________________________________________________________________________
2a941f4e	161	Int_t AliMUONSegment::Compare(const TObject* Segment) const
a9e2aefa	162	{
	163	// "Compare" function to sort with increasing absolute value
	164	// of the "impact parameter" in bending plane.
	165	// Returns -1 (0, +1) if \|impact parameter\| of current Segment
	166	// is smaller than (equal to, larger than) \|impact parameter\| of Segment
	167	if (TMath::Abs(((AliMUONSegment*)this)->fBendingSlope)
	168	< TMath::Abs(((AliMUONSegment*)Segment)->fBendingSlope))
	169	return(-1);
	170	// continuous parameter, hence no need for testing equal case
	171	else return(+1);
	172	}
	173
	174	//__________________________________________________________________________
	175	Double_t AliMUONSegment::NormalizedChi2WithSegment(AliMUONSegment* Segment, Double_t Sigma2Cut)
	176	{
	177	// Calculate the normalized Chi2 between the current Segment (this)
	178	// and the Segment pointed to by "Segment",
	179	// i.e. the square deviations between the coordinates and the slopes,
	180	// in both the bending and the non bending plane,
	181	// divided by the variance of the same quantities and by "Sigma2Cut".
	182	// Returns 5 if none of the 4 quantities is OK,
	183	// something smaller than or equal to 4 otherwise.
	184	// Would it be more correct to use a real chi square
	185	// including the non diagonal term ????
	186	Double_t chi2, chi2Max, diff, normDiff;
	187	chi2 = 0.0;
	188	chi2Max = 5.0;
	189	// coordinate in bending plane
	190	diff = this->fBendingCoor - Segment->fBendingCoor;
	191	normDiff = diff * diff /
	192	(this->fBendingCoorReso2 + Segment->fBendingCoorReso2) / Sigma2Cut;
	193	if (normDiff > 1.0) return chi2Max;
	194	chi2 = chi2 + normDiff;
	195	// slope in bending plane
	196	diff = this->fBendingSlope - Segment->fBendingSlope;
	197	normDiff = diff * diff /
	198	(this->fBendingSlopeReso2 + Segment->fBendingSlopeReso2) / Sigma2Cut;
	199	if (normDiff > 1.0) return chi2Max;
	200	chi2 = chi2 + normDiff;
	201	// coordinate in non bending plane
	202	diff = this->fNonBendingCoor - Segment->fNonBendingCoor;
	203	normDiff = diff * diff /
	204	(this->fNonBendingCoorReso2 + Segment->fNonBendingCoorReso2) / Sigma2Cut;
	205	if (normDiff > 1.0) return chi2Max;
	206	chi2 = chi2 + normDiff;
	207	// slope in non bending plane
	208	diff = this->fNonBendingSlope - Segment->fNonBendingSlope;
	209	normDiff = diff * diff /
	210	(this->fNonBendingSlopeReso2 + Segment->fNonBendingSlopeReso2) / Sigma2Cut;
	211	if (normDiff > 1.0) return chi2Max;
	212	chi2 = chi2 + normDiff;
	213	return chi2;
	214	}
	215
	216	//__________________________________________________________________________
	217	AliMUONSegment* AliMUONSegment::CreateSegmentFromLinearExtrapToStation (Int_t Station, Double_t MCSfactor)
	218	{
	219	// Extrapolates linearly the current Segment (this) to station (0..) "Station".
	220	// Multiple Coulomb scattering calculated from "MCSfactor"
	221	// corresponding to one chamber,
	222	// with one chamber for the coordinate, two chambers for the angle,
	223	// due to the arrangement in stations.
	224	// Valid from station(1..) 4 to 5 or vice versa.
	225	// Returns the pointer to the created AliMUONSegment object
226	// corresponding to this extrapolation.
227	// The caller has the responsibility to delete this object.
228	AliMUONSegment* extrapSegment = new AliMUONSegment(); // creates empty new segment
229	// dZ from first hit of current Segment to first chamber of station "Station"
230	AliMUON pMUON = (AliMUON) gAlice->GetModule("MUON"); // necessary ????
231	Double_t dZ =
232	(&(pMUON->Chamber(2 * Station)))->Z() - (this->fHitForRecPtr1)->GetZ();
233	// Data in bending plane
234	// coordinate
235	extrapSegment->fBendingCoor = this->fBendingCoor + this->fBendingSlope * dZ;
236	// slope
237	extrapSegment->fBendingSlope = this->fBendingSlope;
238	// covariance, including multiple Coulomb scattering over dZ due to one chamber
239	extrapSegment->fBendingCoorReso2 = this->fBendingCoorReso2 +
240	(this->fBendingSlopeReso2 + MCSfactor) * dZ * dZ; // missing non diagonal term: "2.0 * this->fBendingCoorSlopeReso2 * dZ" !!!!
241	extrapSegment->fBendingSlopeReso2 = this->fBendingSlopeReso2 + 2.0 * MCSfactor;
242	extrapSegment->fBendingCoorSlopeReso2 =
243	this->fBendingCoorSlopeReso2 + this->fBendingSlopeReso2 * dZ; // missing: contribution from multiple Coulomb scattering !!!!
244	// Data in non bending plane
245	// coordinate
246	extrapSegment->fNonBendingCoor =
247	this->fNonBendingCoor + this->fNonBendingSlope * dZ;
248	// slope
249	extrapSegment->fNonBendingSlope = this->fNonBendingSlope;
250	// covariance, including multiple Coulomb scattering over dZ due to one chamber
251	extrapSegment->fNonBendingCoorReso2 = this->fNonBendingCoorReso2 +
252	(this->fNonBendingSlopeReso2 + MCSfactor) dZ dZ; // missing non diagonal term: "2.0 * this->fNonBendingCoorSlopeReso2 * dZ" !!!!
253	extrapSegment->fNonBendingSlopeReso2 =
254	this->fNonBendingSlopeReso2 + 2.0 * MCSfactor;
255	extrapSegment->fNonBendingCoorSlopeReso2 =
256	this->fNonBendingCoorSlopeReso2 + this->fNonBendingSlopeReso2 * dZ; // missing: contribution from multiple Coulomb scattering !!!!
257	return extrapSegment;
258	}
259
260	//__________________________________________________________________________
261	AliMUONHitForRec* AliMUONSegment::CreateHitForRecFromLinearExtrapToChamber (Int_t Chamber, Double_t MCSfactor)
262	{
263	// Extrapolates linearly the current Segment (this) to chamber(0..) "Chamber".
264	// Multiple Coulomb scattering calculated from "MCSfactor"
265	// corresponding to one chamber.
266	// Valid from station(1..) 4 to 5 or vice versa.
267	// Returns the pointer to the created AliMUONHitForRec object
268	// corresponding to this extrapolation.
269	// The caller has the responsibility to delete this object.
270	AliMUONHitForRec* extrapHitForRec = new AliMUONHitForRec(); // creates empty new HitForRec
271	// dZ from first hit of current Segment to chamber
272	AliMUON pMUON = (AliMUON) gAlice->GetModule("MUON"); // necessary ????
273	Double_t dZ =
274	(&(pMUON->Chamber(Chamber)))->Z() - (this->fHitForRecPtr1)->GetZ();
275	// Data in bending plane
276	// coordinate
277	extrapHitForRec->SetBendingCoor(this->fBendingCoor + this->fBendingSlope * dZ);
278	// covariance, including multiple Coulomb scattering over dZ due to one chamber
279	extrapHitForRec->SetBendingReso2(this->fBendingCoorReso2 +
280	(this->fBendingSlopeReso2 + MCSfactor) * dZ * dZ); // missing non diagonal term: "2.0 * this->fBendingCoorSlopeReso2 * dZ" !!!!
281	// Data in non bending plane
282	// coordinate
283	extrapHitForRec ->SetNonBendingCoor(this->fNonBendingCoor +
284	this->fNonBendingSlope * dZ);
285	// covariance, including multiple Coulomb scattering over dZ due to one chamber
286	extrapHitForRec->
287	SetNonBendingReso2(this->fNonBendingCoorReso2 +
288	(this->fNonBendingSlopeReso2 + MCSfactor) * dZ * dZ); // missing non diagonal term: "2.0 * this->fNonBendingCoorSlopeReso2 * dZ" !!!!
289	return extrapHitForRec;
290	}
291
292	//__________________________________________________________________________
04b5ea16	293	void AliMUONSegment::UpdateFromStationTrackParam(AliMUONTrackParam *TrackParam, Double_t MCSfactor, Double_t Dz1, Double_t Dz2, Double_t Dz3, Int_t Station, Double_t InverseMomentum)
a9e2aefa	294	{
	295	// Fill data members with values calculated from the array of track parameters
	296	// pointed to by "TrackParam" (index = 0 and 1 for first and second chambers
	297	// of the station, respectively).
	298	// Multiple Coulomb scattering is taking into account with "MCSfactor"
	299	// corresponding to one chamber,
	300	// with one chamber for the coordinate, two chambers for the angle,
	301	// due to the arrangement in stations.
	302	// Resolution coming from:
04b5ea16	303	// coordinate in closest station at "Dz1" from current "Station",
a9e2aefa	304	// slope between closest stations, with "Dz2" interval between them,
04b5ea16	305	// interval "Dz3" between chambers of closest station,
	306	// extrapolation over "Dz1" from closest station,
	307	// "InverseMomentum".
a9e2aefa	308	// When called, "fBendingCoorReso2" and "fNonBendingCoorReso2"
	309	// are assumed to be filled
	310	// with the variance on bending and non bending coordinates.
04b5ea16	311	// The "road" is parametrized from the old reco_muon.F
04b5ea16	312	// with 8 cm between stations.
a9e2aefa	313	AliMUONTrackParam *param0;
d0bfce8d	314	// Double_t cReso2, sReso2;
04b5ea16	315	// parameters to define the widths of the searching roads in station 0,1,2
	316	// width = p0 + p1/ (momentum)^2
	317	// station number: 0 1 2
d0bfce8d	318	// static Double_t p0BendingCoor[3] = { 6.43e-2, 1.64e-2, 0.034 };
	319	// static Double_t p1BendingCoor[3] = { 986., 821., 446. };
	320	// static Double_t p0BendingSlope[3] = { 3.54e-6, 3.63e-6, 3.6e-6 };
	321	// static Double_t p1BendingSlope[3] = { 4.49e-3, 4.8e-3, 0.011 };
	322	// static Double_t p0NonBendingCoor[3] = { 4.66e-2, 4.83e-2, 0.049 };
	323	// static Double_t p1NonBendingCoor[3] = { 1444., 866., 354. };
	324	// static Double_t p0NonBendingSlope[3] = { 6.14e-4, 6.49e-4, 6.85e-4 };
	325	// static Double_t p1NonBendingSlope[3] = { 0., 0., 0. };
	326
	327	static Double_t p0BendingCoor[3] = { 6.43e-2, 6.43e-2, 6.43e-2 };
	328	static Double_t p1BendingCoor[3] = { 986., 986., 986. };
	329	static Double_t p0BendingSlope[3] = { 3.6e-6, 3.6e-6, 3.6e-6 };
	330	static Double_t p1BendingSlope[3] = { 1.1e-2, 1.1e-2, 1.1e-2 };
	331	static Double_t p0NonBendingCoor[3] = { 0.049, 0.049, 0.049 };
	332	static Double_t p1NonBendingCoor[3] = { 1444., 1444., 1444. };
	333	static Double_t p0NonBendingSlope[3] = { 6.8e-4, 6.8e-4, 6.8e-4 };
	334	static Double_t p1NonBendingSlope[3] = { 0., 0., 0. };
a9e2aefa	335	param0 = &(TrackParam[0]);
04b5ea16	336
	337	// OLD version
	338	// // Bending plane
	339	// fBendingCoor = param0->GetBendingCoor(); // coordinate
	340	// fBendingSlope = param0->GetBendingSlope(); // slope
	341	// cReso2 = fBendingCoorReso2;
	342	// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
	343	// fBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
	344	// fBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
	345	// // Non bending plane
	346	// fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
	347	// fNonBendingSlope = param0->GetNonBendingSlope(); // slope
	348	// cReso2 = fNonBendingCoorReso2;
	349	// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
	350	// fNonBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
	351	// fNonBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
	352
	353	// Coordinate and slope
a9e2aefa	354	// Bending plane
	355	fBendingCoor = param0->GetBendingCoor(); // coordinate
	356	fBendingSlope = param0->GetBendingSlope(); // slope
a9e2aefa	357	// Non bending plane
	358	fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
	359	fNonBendingSlope = param0->GetNonBendingSlope(); // slope
04b5ea16	360
	361	// Resolutions
	362	// cReso2 and sReso2 have to be subtracted here from the parametrization
	363	// because they are added in the functions "NormalizedChi2WithSegment"
	364	// and "NormalizedChi2WithHitForRec"
	365	// Bending plane
d0bfce8d	366	// cReso2 = fBendingCoorReso2;
	367	// sReso2 = (2. * cReso2 )/ (Dz3*Dz3) ;
	368	fBendingCoorReso2 = p0BendingCoor[Station] + p1BendingCoor[Station]InverseMomentumInverseMomentum ; // - cReso2
	369	fBendingSlopeReso2 = p0BendingSlope[Station] + p1BendingSlope[Station]InverseMomentumInverseMomentum; // - sReso2;
04b5ea16	370	// Non bending plane
d0bfce8d	371	// cReso2 = fNonBendingCoorReso2;
	372	// sReso2 = (2. * cReso2 )/ (Dz3*Dz3) ;
	373	fNonBendingCoorReso2 = p0NonBendingCoor[Station] + p1NonBendingCoor[Station]InverseMomentumInverseMomentum; // - cReso2;
	374	fNonBendingSlopeReso2 = p0NonBendingSlope[Station] + p1NonBendingSlope[Station]InverseMomentumInverseMomentum; // - sReso2;
a9e2aefa	375	return;
a9e2aefa	376	}
04b5ea16	377
	378	// OLD function, with roads automatically calculated instead from being parametrized
	379	// kept because it would be a better solution,
	380	// if one can really find the right values.
	381	// //__________________________________________________________________________
	382	// void AliMUONSegment::UpdateFromStationTrackParam(AliMUONTrackParam *TrackParam, Double_t MCSfactor, Double_t Dz1, Double_t Dz2)
	383	// {
	384	// // Fill data members with values calculated from the array of track parameters
	385	// // pointed to by "TrackParam" (index = 0 and 1 for first and second chambers
	386	// // of the station, respectively).
	387	// // Multiple Coulomb scattering is taking into account with "MCSfactor"
	388	// // corresponding to one chamber,
	389	// // with one chamber for the coordinate, two chambers for the angle,
	390	// // due to the arrangement in stations.
	391	// // Resolution coming from:
	392	// // coordinate in closest station at "Dz1",
	393	// // slope between closest stations, with "Dz2" interval between them,
	394	// // extrapolation over "Dz" from closest station.
	395	// // When called, "fBendingCoorReso2" and "fNonBendingCoorReso2"
	396	// // are assumed to be filled
	397	// // with the variance on bending and non bending coordinates.
	398	// AliMUONTrackParam *param0;
	399	// Double_t cReso2, sReso2;
	400	// param0 = &(TrackParam[0]);
	401	// // Bending plane
	402	// fBendingCoor = param0->GetBendingCoor(); // coordinate
	403	// fBendingSlope = param0->GetBendingSlope(); // slope
	404	// cReso2 = fBendingCoorReso2;
	405	// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
	406	// fBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
	407	// fBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
	408	// // Non bending plane
	409	// fNonBendingCoor = param0->GetNonBendingCoor(); // coordinate
	410	// fNonBendingSlope = param0->GetNonBendingSlope(); // slope
	411	// cReso2 = fNonBendingCoorReso2;
	412	// sReso2 = 2.0 * cReso2 / Dz2 / Dz2;
	413	// fNonBendingCoorReso2 = cReso2 + (sReso2 + MCSfactor) * Dz1 * Dz1;
	414	// fNonBendingSlopeReso2 = sReso2 + 2.0 * MCSfactor;
	415	// return;
	416	// }