[u/mrichter/AliRoot.git] / ITS / AliITSMultReconstructor.h

#ifndef ALIITSMULTRECONSTRUCTOR_H
#define ALIITSMULTRECONSTRUCTOR_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

/* $Id$ */

/////////////////////////////////////////////////////////////////////////
// 
// AliITSMultReconstructor - find clusters in the pixels (theta and
// phi) and tracklets.
// 
// These can be used to extract charged particles multiplcicity from the ITS.
//
// A tracklet consist of two ITS clusters, one in the first pixel
// layer and one in the second. The clusters are associates if the 
// differencies in Phi (azimuth) and Zeta (longitudinal) are inside 
// a fiducial volume. In case of multiple candidates it is selected the
// candidate with minimum distance in Phi. 
// The boolean fOnlyOneTrackletPerC2 allows to control if two clusters 
// in layer 2 can be associated to the same cluster in layer 1 or not.
//
/////////////////////////////////////////////////////////////////////////

#include "TObject.h"

class TTree;
class TH1F;
class TH2F; 

class AliITSgeom;

class AliITSMultReconstructor : public TObject 
{
public:
  AliITSMultReconstructor();
  virtual ~AliITSMultReconstructor();

  void SetGeometry(AliITSgeom* geo) {fGeometry = geo;}

  void Reconstruct(TTree* tree, Float_t* vtx, Float_t* vtxRes);

  void SetPhiWindow(Float_t w=0.08) {fPhiWindow=w;}
  void SetZetaWindow(Float_t w=1.) {fZetaWindow=w;}
  void SetOnlyOneTrackletPerC2(Bool_t b = kFALSE) {fOnlyOneTrackletPerC2 = b;}
  
  Int_t GetNClustersLayer1() const {return fNClustersLay1;}
  Int_t GetNClustersLayer2() const {return fNClustersLay2;}
  Int_t GetNTracklets() const {return fNTracklets;}
  Int_t GetNSingleClusters() const {return fNSingleCluster;}

  Float_t* GetClusterLayer1(Int_t n) {return fClustersLay1[n];}
  Float_t* GetClusterLayer2(Int_t n) {return fClustersLay2[n];}
  Float_t* GetTracklet(Int_t n) {return fTracklets[n];}
  Float_t* GetCluster(Int_t n) {return fSClusters[n];}

  void SetHistOn(Bool_t b=kFALSE) {fHistOn=b;}
  void SaveHists();

protected:
  AliITSMultReconstructor(const AliITSMultReconstructor& mr);
  AliITSMultReconstructor& operator=(const AliITSMultReconstructor& mr);

  AliITSgeom*   fGeometry;            // ITS geometry
  
  Float_t**     fClustersLay1;        // clusters in the 1st layer of ITS 
  Float_t**     fClustersLay2;        // clusters in the 2nd layer of ITS 
  Float_t**     fTracklets;           // tracklets 
  Float_t**     fSClusters;           // single clusters (unassociated)
  Bool_t*       fAssociationFlag;     // flag for the associations 
  
  Int_t         fNClustersLay1; // Number of clusters (Layer1)
  Int_t         fNClustersLay2; // Number of clusters (Layer2)
  Int_t         fNTracklets;    // Number of tracklets
  Int_t         fNSingleCluster;    // Number of unassociated clusters

  Float_t       fPhiWindow;     // Search window in phi
  Float_t       fZetaWindow;    // SEarch window in eta

  Bool_t        fOnlyOneTrackletPerC2; // only one tracklet per cluster in L. 2
  
  Bool_t        fHistOn; // Option to define and fill the histograms 


  TH1F*         fhClustersDPhiAcc;   // Phi2 - Phi1 for tracklets 
  TH1F*         fhClustersDThetaAcc; // Theta2 - Theta1 for tracklets 
  TH1F*         fhClustersDZetaAcc;  // z2 - z1projected for tracklets 
  TH1F*         fhClustersDPhiAll;   // Phi2 - Phi1 all the combinations 
  TH1F*         fhClustersDThetaAll; // Theta2 - Theta1 all the combinations
  TH1F*         fhClustersDZetaAll;  // z2 - z1projected all the combinations
 
  TH2F*         fhDPhiVsDThetaAll; // 2D plot for all the combinations  
  TH2F*         fhDPhiVsDThetaAcc; // same plot for tracklets 
  TH2F*         fhDPhiVsDZetaAll;  // 2d plot for all the combination 
  TH2F*         fhDPhiVsDZetaAcc;  // same plot for tracklets 

  TH1F*         fhetaTracklets;    // Pseudorapidity distr. for tracklets 
  TH1F*         fhphiTracklets;    // Azimuthal (Phi) distr. for tracklets  
  TH1F*         fhetaClustersLay1; // Pseudorapidity distr. for Clusters L. 1
  TH1F*         fhphiClustersLay1; // Azimuthal (Phi) distr. for Clusters L. 1 
 

  void LoadClusterArrays(TTree* tree);

  ClassDef(AliITSMultReconstructor,2)
};

#endif
Commit	Line	Data
ac903f1b	1	#ifndef ALIITSMULTRECONSTRUCTOR_H
	2	#define ALIITSMULTRECONSTRUCTOR_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
	6	/* $Id$ */
	7
	8	/////////////////////////////////////////////////////////////////////////
	9	//
	10	// AliITSMultReconstructor - find clusters in the pixels (theta and
	11	// phi) and tracklets.
	12	//
	13	// These can be used to extract charged particles multiplcicity from the ITS.
	14	//
	15	// A tracklet consist of two ITS clusters, one in the first pixel
	16	// layer and one in the second. The clusters are associates if the
	17	// differencies in Phi (azimuth) and Zeta (longitudinal) are inside
	18	// a fiducial volume. In case of multiple candidates it is selected the
	19	// candidate with minimum distance in Phi.
	20	// The boolean fOnlyOneTrackletPerC2 allows to control if two clusters
	21	// in layer 2 can be associated to the same cluster in layer 1 or not.
	22	//
	23	/////////////////////////////////////////////////////////////////////////
	24
	25	#include "TObject.h"
	26
	27	class TTree;
	28	class TH1F;
3ef75756	29	class TH2F;
3ef75756	30
ac903f1b	31	class AliITSgeom;
	32
	33	class AliITSMultReconstructor : public TObject
	34	{
	35	public:
	36	AliITSMultReconstructor();
ddced3c8	37	virtual ~AliITSMultReconstructor();
ac903f1b	38
	39	void SetGeometry(AliITSgeom* geo) {fGeometry = geo;}
	40
	41	void Reconstruct(TTree* tree, Float_t* vtx, Float_t* vtxRes);
	42
	43	void SetPhiWindow(Float_t w=0.08) {fPhiWindow=w;}
3ef75756	44	void SetZetaWindow(Float_t w=1.) {fZetaWindow=w;}
3ef75756	45	void SetOnlyOneTrackletPerC2(Bool_t b = kFALSE) {fOnlyOneTrackletPerC2 = b;}
ac903f1b	46
	47	Int_t GetNClustersLayer1() const {return fNClustersLay1;}
	48	Int_t GetNClustersLayer2() const {return fNClustersLay2;}
	49	Int_t GetNTracklets() const {return fNTracklets;}
968e8539	50	Int_t GetNSingleClusters() const {return fNSingleCluster;}
ac903f1b	51
	52	Float_t* GetClusterLayer1(Int_t n) {return fClustersLay1[n];}
	53	Float_t* GetClusterLayer2(Int_t n) {return fClustersLay2[n];}
	54	Float_t* GetTracklet(Int_t n) {return fTracklets[n];}
968e8539	55	Float_t* GetCluster(Int_t n) {return fSClusters[n];}
ac903f1b	56
	57	void SetHistOn(Bool_t b=kFALSE) {fHistOn=b;}
	58	void SaveHists();
3ef75756	59
ac903f1b	60	protected:
3ef75756	61	AliITSMultReconstructor(const AliITSMultReconstructor& mr);
7537d03c	62	AliITSMultReconstructor& operator=(const AliITSMultReconstructor& mr);
ac903f1b	63
	64	AliITSgeom* fGeometry; // ITS geometry
	65
	66	Float_t** fClustersLay1; // clusters in the 1st layer of ITS
	67	Float_t** fClustersLay2; // clusters in the 2nd layer of ITS
	68	Float_t** fTracklets; // tracklets
968e8539	69	Float_t** fSClusters; // single clusters (unassociated)
ac903f1b	70	Bool_t* fAssociationFlag; // flag for the associations
	71
	72	Int_t fNClustersLay1; // Number of clusters (Layer1)
	73	Int_t fNClustersLay2; // Number of clusters (Layer2)
	74	Int_t fNTracklets; // Number of tracklets
968e8539	75	Int_t fNSingleCluster; // Number of unassociated clusters
ac903f1b	76
	77	Float_t fPhiWindow; // Search window in phi
	78	Float_t fZetaWindow; // SEarch window in eta
	79
3ef75756	80	Bool_t fOnlyOneTrackletPerC2; // only one tracklet per cluster in L. 2
ac903f1b	81
3ef75756	82	Bool_t fHistOn; // Option to define and fill the histograms
ddced3c8	83
3ef75756	84
	85	TH1F* fhClustersDPhiAcc; // Phi2 - Phi1 for tracklets
	86	TH1F* fhClustersDThetaAcc; // Theta2 - Theta1 for tracklets
	87	TH1F* fhClustersDZetaAcc; // z2 - z1projected for tracklets
	88	TH1F* fhClustersDPhiAll; // Phi2 - Phi1 all the combinations
	89	TH1F* fhClustersDThetaAll; // Theta2 - Theta1 all the combinations
	90	TH1F* fhClustersDZetaAll; // z2 - z1projected all the combinations
	91
	92	TH2F* fhDPhiVsDThetaAll; // 2D plot for all the combinations
	93	TH2F* fhDPhiVsDThetaAcc; // same plot for tracklets
	94	TH2F* fhDPhiVsDZetaAll; // 2d plot for all the combination
	95	TH2F* fhDPhiVsDZetaAcc; // same plot for tracklets
	96
	97	TH1F* fhetaTracklets; // Pseudorapidity distr. for tracklets
	98	TH1F* fhphiTracklets; // Azimuthal (Phi) distr. for tracklets
	99	TH1F* fhetaClustersLay1; // Pseudorapidity distr. for Clusters L. 1
	100	TH1F* fhphiClustersLay1; // Azimuthal (Phi) distr. for Clusters L. 1
	101
ac903f1b	102
	103	void LoadClusterArrays(TTree* tree);
	104
968e8539	105	ClassDef(AliITSMultReconstructor,2)
ac903f1b	106	};
	107
	108	#endif