[u/mrichter/AliRoot.git] / PWGGA / CaloTrackCorrelations / AliAnaElectron.h

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

//_________________________________________________________________________
//
// Class for the electron identification, 
// Clusters from calorimeters are identified as electrons
// and kept in the AOD. Few histograms produced.
// Copy of AliAnaPhoton just add electron id.
//

//-- Author: Gustavo Conesa (LPSC-IN2P3-CNRS)

// --- ROOT system ---
class TH2F ;
class TH1F;
class TH3D;
class TString ;
class TObjString;

// --- ANALYSIS system ---
#include "AliAnaCaloTrackCorrBaseClass.h"
class AliStack;
class TParticle;

class TList ;

class AliAnaElectron : public AliAnaCaloTrackCorrBaseClass {

 public: 
  
  AliAnaElectron() ;                                       // default ctor
  
  virtual ~AliAnaElectron() { ; }                          // virtual dtor
	
  //---------------------------------------
  // General analysis frame methods
  //---------------------------------------
  
  TObjString * GetAnalysisCuts();
  
  TList      * GetCreateOutputObjects();
  
  void         Init();

  void         InitParameters();

  void         MakeAnalysisFillAOD()  ;

  void         MakeAnalysisFillHistograms() ; 
  
  void         Print(const Option_t * opt)const;
    
  
  // Analysis methods
  
  Bool_t       ClusterSelected(AliVCluster* cl, TLorentzVector mom, Int_t nMaxima) ;
  
  void         FillShowerShapeHistograms( AliVCluster* cluster, Int_t mcTag , Int_t pidTag) ;
  
  void         SwitchOnFillShowerShapeHistograms()    { fFillSSHistograms = kTRUE  ; }
  void         SwitchOffFillShowerShapeHistograms()   { fFillSSHistograms = kFALSE ; }  
    
  void         WeightHistograms(AliVCluster *clus);
  
  void         SwitchOnFillWeightHistograms()         { fFillWeightHistograms = kTRUE  ; }
  void         SwitchOffFillWeightHistograms()        { fFillWeightHistograms = kFALSE ; }  
  
  //---------------------------------------
  // Analysis parameters setters getters
  //---------------------------------------
  
  // ** Cluster selection methods **
  
  void         SetdEdxCut(Double_t min, Double_t max) { fdEdxMin    = min ; 
                                                        fdEdxMax    = max          ; }
  
  void         SetEOverP(Double_t min, Double_t max)  { fEOverPMin  = min ; 
                                                        fEOverPMax  = max          ; }

  
  void         SetMinDistanceToBadChannel(Float_t m1, Float_t m2, Float_t m3) {
                fMinDist = m1; fMinDist2 = m2; fMinDist3 = m3; }

  void         SetTimeCut(Double_t min, Double_t max) { fTimeCutMin = min; 
                                                        fTimeCutMax = max          ; }
  Double_t     GetTimeCutMin()                  const { return fTimeCutMin         ; }
  Double_t     GetTimeCutMax()                  const { return fTimeCutMax         ; }	
	
  void         SetNCellCut(Int_t n)                   { fNCellsCut = n             ; }
  Double_t     GetNCellCut()                    const { return fNCellsCut          ; }
  
  void         SetNLMCut(Int_t min, Int_t max)        { fNLMCutMin = min;
                                                        fNLMCutMax = max                ; }
  Int_t        GetNLMCutMin()                   const { return fNLMCutMin               ; }
  Int_t        GetNLMCutMax()                   const { return fNLMCutMax               ; }
  
  void         FillNOriginHistograms(Int_t n)         { fNOriginHistograms = n ; 
                                                        if(n > 10) fNOriginHistograms = 10; }

  
  void         FillAODWithElectrons()                 { fAODParticle = AliCaloPID::kElectron      ; }
  void         FillAODWithHadrons()                   { fAODParticle = AliCaloPID::kChargedHadron ; }
  void         FillAODWithAny()                       { fAODParticle = 0 ; }

  void         SwitchOnOnlySimpleSSHistoFill()        { fFillOnlySimpleSSHisto = kTRUE  ; }
  void         SwitchOffOnlySimpleHistoFill()         { fFillOnlySimpleSSHisto = kFALSE ; }
  
  // For histograms in arrays, index in the array, corresponding to a particle
  enum mcTypes    { kmcPhoton = 0,        kmcPi0Decay = 1,       kmcOtherDecay = 2,  
                    kmcPi0 = 3,           kmcEta = 4,            kmcElectron = 5,       
                    kmcConversion = 6,    kmcOther = 7,          kmcAntiNeutron = 8,    
                    kmcAntiProton = 9                                                 };    
  
  enum mcssTypes  { kmcssPhoton = 0,      kmcssOther = 1,       kmcssPi0 = 2,         
                    kmcssEta = 3,         kmcssConversion = 4,  kmcssElectron = 5       };  
  
  private:
 
  Float_t  fMinDist ;                          // Minimal distance to bad channel to accept cluster
  Float_t  fMinDist2;                          // Cuts on Minimal distance to study acceptance evaluation
  Float_t  fMinDist3;                          // One more cut on distance used for acceptance-efficiency study
  Double_t fTimeCutMin  ;                      // Remove clusters/cells with time smaller than this value, in ns
  Double_t fTimeCutMax  ;                      // Remove clusters/cells with time larger than this value, in ns
  Int_t    fNCellsCut ;                        // Accept for the analysis clusters with more than fNCellsCut cells
  Int_t    fNLMCutMin  ;                       // Remove clusters/cells with number of local maxima smaller than this value
  Int_t    fNLMCutMax  ;                       // Remove clusters/cells with number of local maxima larger than this value
  Bool_t   fFillSSHistograms ;                 // Fill shower shape histograms
  Bool_t   fFillOnlySimpleSSHisto;             // Fill selected cluster histograms, selected SS histograms
  Bool_t   fFillWeightHistograms ;             // Fill weigth histograms
  Int_t    fNOriginHistograms;                 // Fill only NOriginHistograms of the 14 defined types

  Float_t  fdEdxMin;                           // Max dEdx for electrons
  Float_t  fdEdxMax;                           // Min dEdx for electrons
  Float_t  fEOverPMin;                         // Max E/p for electrons, after dEdx cut
  Float_t  fEOverPMax;                         // Min E/p for electrons, after dEdx cut

  Int_t    fAODParticle;                       // Select the type of particle to put in AODs for other analysis
  
  //Histograms
  TH2F * fhdEdxvsE;                            //! matched track dEdx vs cluster E 
  TH2F * fhdEdxvsP;                            //! matched track dEdx vs track P
  TH2F * fhEOverPvsE;                          //! matched track E cluster over P track vs cluster E, after dEdx cut 
  TH2F * fhEOverPvsP;                          //! matched track E cluster over P track vs track P, after dEdx cut 

  TH2F * fhdEdxvsECutM02;                      //! matched track dEdx vs cluster E, mild M02 cut
  TH2F * fhdEdxvsPCutM02;                      //! matched track dEdx vs track P, mild M02 cut
  TH2F * fhEOverPvsECutM02;                    //! matched track E cluster over P track vs cluster E, after dEdx cut, mild M02 cut
  TH2F * fhEOverPvsPCutM02;                    //! matched track E cluster over P track vs track P, after dEdx cut, mild M02 cut
  
  TH2F * fhdEdxvsECutEOverP;                   //! matched track dEdx vs cluster E , cut on EOverP
  TH2F * fhdEdxvsPCutEOverP;                   //! matched track dEdx vs track P, cut on EOverP
  TH2F * fhEOverPvsECutM02CutdEdx;             //! matched track E cluster over P track vs cluster E, after dEdx cut and mild M02 cut
  TH2F * fhEOverPvsPCutM02CutdEdx;             //! matched track E cluster over P track vs track P, after dEdx cut and mild M02 cut

  TH2F * fhMCdEdxvsE[10];                       //! matched track dEdx vs cluster E, coming from MC particle
  TH2F * fhMCdEdxvsP[10];                       //! matched track dEdx vs track P, coming from MC particle
  TH2F * fhMCEOverPvsE[10];                     //! matched track E cluster over P track vs cluster E, after dEdx cut, coming from MC particle
  TH2F * fhMCEOverPvsP[10];                     //! matched track E cluster over P track vs track P, after dEdx cut, coming from MC particle
  
  TH2F * fhNCellsE[2];                         //! number of cells in cluster vs E
  TH2F * fhNLME[2];                            //! number of local maxima in cluster vs E
  TH2F * fhMaxCellDiffClusterE[2];             //! Fraction of energy carried by cell with maximum energy
  TH2F * fhTimeE[2];                           //! E vs Time of selected cluster 

  TH1F * fhE[2]    ;                           //! Number of identified electron vs energy
  TH1F * fhPt[2]   ;                           //! Number of identified electron vs transerse momentum 
  TH2F * fhPhi[2]  ;                           //! Azimuthal angle of identified  electron vs transerse momentum 
  TH2F * fhEta[2]  ;                           //! Pseudorapidity of identified  electron vs transerse momentum 
  TH2F * fhEtaPhi[2]  ;                        //! Pseudorapidity vs Phi of identified  electron for transerse momentum > 0.5
  TH2F * fhEtaPhi05[2]  ;                      //! Pseudorapidity vs Phi of identified  electron for transerse momentum < 0.5
  
  //Shower shape
  
  TH2F * fhDispE[2];                           //! cluster dispersion vs E
  TH2F * fhLam0E[2];                           //! cluster lambda0 vs  E
  TH2F * fhLam1E[2];                           //! cluster lambda1 vs  E  

  TH2F * fhDispETRD[2];                        //! cluster dispersion vs E, SM covered by TRD
  TH2F * fhLam0ETRD[2];                        //! cluster lambda0 vs  E, SM covered by TRD
  TH2F * fhLam1ETRD[2];                        //! cluster lambda1 vs  E, SM covered by TRD 
  
  TH2F * fhNCellsLam0LowE[2];                  //! cluster N cells vs lambda0, E<2
  TH2F * fhNCellsLam0HighE[2];                 //! cluster N Cells vs lambda0, E>2

  TH2F * fhEtaLam0LowE[2];                     //! cluster eta vs lambda0, E<2
  TH2F * fhPhiLam0LowE[2];                     //! cluster phi vs lambda0, E<2
  TH2F * fhEtaLam0HighE[2];                    //! cluster eta vs lambda0, E>2
  TH2F * fhPhiLam0HighE[2];                    //! cluster phi vs lambda0, E>2
    
  TH2F * fhDispEtaE[2] ;                       //! shower dispersion in eta direction
  TH2F * fhDispPhiE[2] ;                       //! shower dispersion in phi direction
  TH2F * fhSumEtaE[2] ;                        //! shower dispersion in eta direction
  TH2F * fhSumPhiE[2] ;                        //! shower dispersion in phi direction
  TH2F * fhSumEtaPhiE[2] ;                     //! shower dispersion in eta and phi direction
  TH2F * fhDispEtaPhiDiffE[2] ;                //! shower dispersion eta - phi
  TH2F * fhSphericityE[2] ;                    //! shower sphericity in eta vs phi
  TH2F * fhDispEtaDispPhiEBin[2][5] ;          //! shower dispersion in eta direction vs phi direction for 5 E bins [0-2],[2-4],[4-6],[6-10],[> 10]

  // Weight studies
  
  TH2F * fhECellClusterRatio;                  //! e cell / e cluster vs e cluster for selected electrons
  TH2F * fhECellClusterLogRatio;               //! log (e cell / e cluster)  vs e cluster for selected electrons
  TH2F * fhEMaxCellClusterRatio;               //! e max cell / e cluster vs e cluster for selected electrons
  TH2F * fhEMaxCellClusterLogRatio;            //! log (e max cell / e cluster) vs e cluster for selected electrons
  TH2F * fhLambda0ForW0[14];                   //! L0 for 7 defined w0= 3, 3.5 ... 6 for selected electrons
  //TH2F * fhLambda1ForW0[14];                    //! L1 for 7 defined w0= 3, 3.5 ... 6 for selected electrons
  
  //Fill MC dependent histograms, Origin of this cluster is ...

  TH2F * fhMCDeltaE[2][10]  ;                  //! MC-Reco E distribution coming from MC particle     
  TH2F * fhMC2E[2][10]  ;                      //! E distribution, Reco vs MC coming from MC particle
  
  TH1F * fhMCE[2][10];                          //! Number of identified electron vs cluster energy coming from MC particle
  TH1F * fhMCPt[2][10];                         //! Number of identified electron vs cluster energy coming from MC particle
  TH2F * fhMCPhi[2][10];                        //! Phi of identified electron coming from MC particle
  TH2F * fhMCEta[2][10];                        //! eta of identified electron coming from MC particle
  
  // Shower Shape MC

  TH2F * fhMCELambda0[2][6] ;                   //! E vs Lambda0 from MC particle
  
  TH2F * fhMCEDispEta[2][6] ;                   //! shower dispersion in eta direction from MC particle
  TH2F * fhMCEDispPhi[2][6] ;                   //! shower dispersion in phi direction from MC particle
  TH2F * fhMCESumEtaPhi[2][6] ;                 //! shower dispersion in eta vs phi direction from MC particle
  TH2F * fhMCEDispEtaPhiDiff[2][6] ;            //! shower dispersion in eta -phi direction from MC particle
  TH2F * fhMCESphericity[2][6] ;                //! shower sphericity, eta vs phi from MC particle

  TH2F * fhMCElectronELambda0NoOverlap ;        //! E vs Lambda0 from MC electrons, no overlap
  TH2F * fhMCElectronELambda0TwoOverlap ;       //! E vs Lambda0 from MC electrons, 2 particles overlap
  TH2F * fhMCElectronELambda0NOverlap ;         //! E vs Lambda0 from MC electrons, N particles overlap
  
  //Embedding
  TH2F * fhEmbeddedSignalFractionEnergy ;       //! Fraction of electron energy of embedded signal vs cluster energy
  
  TH2F * fhEmbedElectronELambda0FullSignal ;    //!  Lambda0 vs E for embedded electrons with more than 90% of the cluster energy
  TH2F * fhEmbedElectronELambda0MostlySignal ;  //!  Lambda0 vs E for embedded electrons with 90%<fraction<50% 
  TH2F * fhEmbedElectronELambda0MostlyBkg ;     //!  Lambda0 vs E for embedded electrons with 50%<fraction<10% 
  TH2F * fhEmbedElectronELambda0FullBkg ;       //!  Lambda0 vs E for embedded electrons with less than 10% of the cluster energy
  
  AliAnaElectron(              const AliAnaElectron & el) ; // cpy ctor  
  AliAnaElectron & operator = (const AliAnaElectron & el) ; // cpy assignment
  
  ClassDef(AliAnaElectron,5)

} ;
 

#endif//ALIANAELECTRON_H
Commit	Line	Data
d9105d92	1	#ifndef ALIANAELECTRON_H
	2	#define ALIANAELECTRON_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
d9105d92	5
	6	//_________________________________________________________________________
	7	//
	8	// Class for the electron identification,
	9	// Clusters from calorimeters are identified as electrons
	10	// and kept in the AOD. Few histograms produced.
	11	// Copy of AliAnaPhoton just add electron id.
	12	//
	13
	14	//-- Author: Gustavo Conesa (LPSC-IN2P3-CNRS)
	15
	16	// --- ROOT system ---
	17	class TH2F ;
	18	class TH1F;
	19	class TH3D;
	20	class TString ;
	21	class TObjString;
	22
	23	// --- ANALYSIS system ---
745913ae	24	#include "AliAnaCaloTrackCorrBaseClass.h"
d9105d92	25	class AliStack;
	26	class TParticle;
	27
	28	class TList ;
	29
745913ae	30	class AliAnaElectron : public AliAnaCaloTrackCorrBaseClass {
d9105d92	31
	32	public:
	33
	34	AliAnaElectron() ; // default ctor
	35
	36	virtual ~AliAnaElectron() { ; } // virtual dtor
d9105d92	37
	38	//---------------------------------------
	39	// General analysis frame methods
	40	//---------------------------------------
	41
	42	TObjString * GetAnalysisCuts();
	43
	44	TList * GetCreateOutputObjects();
	45
	46	void Init();
	47
	48	void InitParameters();
	49
	50	void MakeAnalysisFillAOD() ;
	51
	52	void MakeAnalysisFillHistograms() ;
	53
	54	void Print(const Option_t * opt)const;
	55
	56
	57	// Analysis methods
	58
7e9a1194	59	Bool_t ClusterSelected(AliVCluster* cl, TLorentzVector mom, Int_t nMaxima) ;
d9105d92	60
b94e038e	61	void FillShowerShapeHistograms( AliVCluster* cluster, Int_t mcTag , Int_t pidTag) ;
d9105d92	62
	63	void SwitchOnFillShowerShapeHistograms() { fFillSSHistograms = kTRUE ; }
	64	void SwitchOffFillShowerShapeHistograms() { fFillSSHistograms = kFALSE ; }
dbba06ca	65
78a28af3	66	void WeightHistograms(AliVCluster *clus);
	67
	68	void SwitchOnFillWeightHistograms() { fFillWeightHistograms = kTRUE ; }
	69	void SwitchOffFillWeightHistograms() { fFillWeightHistograms = kFALSE ; }
	70
d9105d92	71	//---------------------------------------
	72	// Analysis parameters setters getters
	73	//---------------------------------------
	74
d9105d92	75	// Cluster selection methods
	76
	77	void SetdEdxCut(Double_t min, Double_t max) { fdEdxMin = min ;
	78	fdEdxMax = max ; }
	79
	80	void SetEOverP(Double_t min, Double_t max) { fEOverPMin = min ;
	81	fEOverPMax = max ; }
	82
	83
	84	void SetMinDistanceToBadChannel(Float_t m1, Float_t m2, Float_t m3) {
	85	fMinDist = m1; fMinDist2 = m2; fMinDist3 = m3; }
	86
	87	void SetTimeCut(Double_t min, Double_t max) { fTimeCutMin = min;
	88	fTimeCutMax = max ; }
	89	Double_t GetTimeCutMin() const { return fTimeCutMin ; }
	90	Double_t GetTimeCutMax() const { return fTimeCutMax ; }
	91
	92	void SetNCellCut(Int_t n) { fNCellsCut = n ; }
	93	Double_t GetNCellCut() const { return fNCellsCut ; }
7e9a1194	94
	95	void SetNLMCut(Int_t min, Int_t max) { fNLMCutMin = min;
	96	fNLMCutMax = max ; }
	97	Int_t GetNLMCutMin() const { return fNLMCutMin ; }
	98	Int_t GetNLMCutMax() const { return fNLMCutMax ; }
	99
d9105d92	100	void FillNOriginHistograms(Int_t n) { fNOriginHistograms = n ;
764ab1f4	101	if(n > 10) fNOriginHistograms = 10; }
d9105d92	102
764ab1f4	103
	104	void FillAODWithElectrons() { fAODParticle = AliCaloPID::kElectron ; }
	105	void FillAODWithHadrons() { fAODParticle = AliCaloPID::kChargedHadron ; }
	106	void FillAODWithAny() { fAODParticle = 0 ; }
	107
	108	void SwitchOnOnlySimpleSSHistoFill() { fFillOnlySimpleSSHisto = kTRUE ; }
	109	void SwitchOffOnlySimpleHistoFill() { fFillOnlySimpleSSHisto = kFALSE ; }
	110
d9105d92	111	// For histograms in arrays, index in the array, corresponding to a particle
c5693f62	112	enum mcTypes { kmcPhoton = 0, kmcPi0Decay = 1, kmcOtherDecay = 2,
	113	kmcPi0 = 3, kmcEta = 4, kmcElectron = 5,
	114	kmcConversion = 6, kmcOther = 7, kmcAntiNeutron = 8,
	115	kmcAntiProton = 9 };
d9105d92	116
c5693f62	117	enum mcssTypes { kmcssPhoton = 0, kmcssOther = 1, kmcssPi0 = 2,
c5693f62	118	kmcssEta = 3, kmcssConversion = 4, kmcssElectron = 5 };
d9105d92	119
	120	private:
	121
d9105d92	122	Float_t fMinDist ; // Minimal distance to bad channel to accept cluster
	123	Float_t fMinDist2; // Cuts on Minimal distance to study acceptance evaluation
	124	Float_t fMinDist3; // One more cut on distance used for acceptance-efficiency study
	125	Double_t fTimeCutMin ; // Remove clusters/cells with time smaller than this value, in ns
	126	Double_t fTimeCutMax ; // Remove clusters/cells with time larger than this value, in ns
	127	Int_t fNCellsCut ; // Accept for the analysis clusters with more than fNCellsCut cells
7e9a1194	128	Int_t fNLMCutMin ; // Remove clusters/cells with number of local maxima smaller than this value
7e9a1194	129	Int_t fNLMCutMax ; // Remove clusters/cells with number of local maxima larger than this value
d9105d92	130	Bool_t fFillSSHistograms ; // Fill shower shape histograms
7e9a1194	131	Bool_t fFillOnlySimpleSSHisto; // Fill selected cluster histograms, selected SS histograms
78a28af3	132	Bool_t fFillWeightHistograms ; // Fill weigth histograms
d9105d92	133	Int_t fNOriginHistograms; // Fill only NOriginHistograms of the 14 defined types
	134
	135	Float_t fdEdxMin; // Max dEdx for electrons
	136	Float_t fdEdxMax; // Min dEdx for electrons
	137	Float_t fEOverPMin; // Max E/p for electrons, after dEdx cut
	138	Float_t fEOverPMax; // Min E/p for electrons, after dEdx cut
	139
764ab1f4	140	Int_t fAODParticle; // Select the type of particle to put in AODs for other analysis
764ab1f4	141
7e9a1194	142	//Histograms
d9105d92	143	TH2F * fhdEdxvsE; //! matched track dEdx vs cluster E
	144	TH2F * fhdEdxvsP; //! matched track dEdx vs track P
	145	TH2F * fhEOverPvsE; //! matched track E cluster over P track vs cluster E, after dEdx cut
	146	TH2F * fhEOverPvsP; //! matched track E cluster over P track vs track P, after dEdx cut
	147
7e9a1194	148	TH2F * fhdEdxvsECutM02; //! matched track dEdx vs cluster E, mild M02 cut
	149	TH2F * fhdEdxvsPCutM02; //! matched track dEdx vs track P, mild M02 cut
	150	TH2F * fhEOverPvsECutM02; //! matched track E cluster over P track vs cluster E, after dEdx cut, mild M02 cut
	151	TH2F * fhEOverPvsPCutM02; //! matched track E cluster over P track vs track P, after dEdx cut, mild M02 cut
	152
	153	TH2F * fhdEdxvsECutEOverP; //! matched track dEdx vs cluster E , cut on EOverP
	154	TH2F * fhdEdxvsPCutEOverP; //! matched track dEdx vs track P, cut on EOverP
	155	TH2F * fhEOverPvsECutM02CutdEdx; //! matched track E cluster over P track vs cluster E, after dEdx cut and mild M02 cut
	156	TH2F * fhEOverPvsPCutM02CutdEdx; //! matched track E cluster over P track vs track P, after dEdx cut and mild M02 cut
	157
	158	TH2F * fhMCdEdxvsE[10]; //! matched track dEdx vs cluster E, coming from MC particle
	159	TH2F * fhMCdEdxvsP[10]; //! matched track dEdx vs track P, coming from MC particle
	160	TH2F * fhMCEOverPvsE[10]; //! matched track E cluster over P track vs cluster E, after dEdx cut, coming from MC particle
	161	TH2F * fhMCEOverPvsP[10]; //! matched track E cluster over P track vs track P, after dEdx cut, coming from MC particle
	162
	163	TH2F * fhNCellsE[2]; //! number of cells in cluster vs E
	164	TH2F * fhNLME[2]; //! number of local maxima in cluster vs E
d9105d92	165	TH2F * fhMaxCellDiffClusterE[2]; //! Fraction of energy carried by cell with maximum energy
42d47cb7	166	TH2F * fhTimeE[2]; //! E vs Time of selected cluster
42d47cb7	167
d9105d92	168	TH1F * fhE[2] ; //! Number of identified electron vs energy
	169	TH1F * fhPt[2] ; //! Number of identified electron vs transerse momentum
	170	TH2F * fhPhi[2] ; //! Azimuthal angle of identified electron vs transerse momentum
	171	TH2F * fhEta[2] ; //! Pseudorapidity of identified electron vs transerse momentum
	172	TH2F * fhEtaPhi[2] ; //! Pseudorapidity vs Phi of identified electron for transerse momentum > 0.5
	173	TH2F * fhEtaPhi05[2] ; //! Pseudorapidity vs Phi of identified electron for transerse momentum < 0.5
	174
	175	//Shower shape
	176
	177	TH2F * fhDispE[2]; //! cluster dispersion vs E
	178	TH2F * fhLam0E[2]; //! cluster lambda0 vs E
	179	TH2F * fhLam1E[2]; //! cluster lambda1 vs E
	180
	181	TH2F * fhDispETRD[2]; //! cluster dispersion vs E, SM covered by TRD
	182	TH2F * fhLam0ETRD[2]; //! cluster lambda0 vs E, SM covered by TRD
	183	TH2F * fhLam1ETRD[2]; //! cluster lambda1 vs E, SM covered by TRD
	184
	185	TH2F * fhNCellsLam0LowE[2]; //! cluster N cells vs lambda0, E<2
	186	TH2F * fhNCellsLam0HighE[2]; //! cluster N Cells vs lambda0, E>2
	187
	188	TH2F * fhEtaLam0LowE[2]; //! cluster eta vs lambda0, E<2
	189	TH2F * fhPhiLam0LowE[2]; //! cluster phi vs lambda0, E<2
	190	TH2F * fhEtaLam0HighE[2]; //! cluster eta vs lambda0, E>2
	191	TH2F * fhPhiLam0HighE[2]; //! cluster phi vs lambda0, E>2
	192
34c16486	193	TH2F * fhDispEtaE[2] ; //! shower dispersion in eta direction
	194	TH2F * fhDispPhiE[2] ; //! shower dispersion in phi direction
	195	TH2F * fhSumEtaE[2] ; //! shower dispersion in eta direction
	196	TH2F * fhSumPhiE[2] ; //! shower dispersion in phi direction
	197	TH2F * fhSumEtaPhiE[2] ; //! shower dispersion in eta and phi direction
	198	TH2F * fhDispEtaPhiDiffE[2] ; //! shower dispersion eta - phi
	199	TH2F * fhSphericityE[2] ; //! shower sphericity in eta vs phi
	200	TH2F * fhDispEtaDispPhiEBin[2][5] ; //! shower dispersion in eta direction vs phi direction for 5 E bins [0-2],[2-4],[4-6],[6-10],[> 10]
	201
78a28af3	202	// Weight studies
	203
	204	TH2F * fhECellClusterRatio; //! e cell / e cluster vs e cluster for selected electrons
	205	TH2F * fhECellClusterLogRatio; //! log (e cell / e cluster) vs e cluster for selected electrons
	206	TH2F * fhEMaxCellClusterRatio; //! e max cell / e cluster vs e cluster for selected electrons
	207	TH2F * fhEMaxCellClusterLogRatio; //! log (e max cell / e cluster) vs e cluster for selected electrons
34c16486	208	TH2F * fhLambda0ForW0[14]; //! L0 for 7 defined w0= 3, 3.5 ... 6 for selected electrons
1a72f6c5	209	//TH2F * fhLambda1ForW0[14]; //! L1 for 7 defined w0= 3, 3.5 ... 6 for selected electrons
78a28af3	210
d9105d92	211	//Fill MC dependent histograms, Origin of this cluster is ...
	212
	213	TH2F * fhMCDeltaE[2][10] ; //! MC-Reco E distribution coming from MC particle
	214	TH2F * fhMC2E[2][10] ; //! E distribution, Reco vs MC coming from MC particle
	215
	216	TH1F * fhMCE[2][10]; //! Number of identified electron vs cluster energy coming from MC particle
	217	TH1F * fhMCPt[2][10]; //! Number of identified electron vs cluster energy coming from MC particle
	218	TH2F * fhMCPhi[2][10]; //! Phi of identified electron coming from MC particle
	219	TH2F * fhMCEta[2][10]; //! eta of identified electron coming from MC particle
	220
	221	// Shower Shape MC
	222
34c16486	223	TH2F * fhMCELambda0[2][6] ; //! E vs Lambda0 from MC particle
d9105d92	224
34c16486	225	TH2F * fhMCEDispEta[2][6] ; //! shower dispersion in eta direction from MC particle
	226	TH2F * fhMCEDispPhi[2][6] ; //! shower dispersion in phi direction from MC particle
	227	TH2F * fhMCESumEtaPhi[2][6] ; //! shower dispersion in eta vs phi direction from MC particle
	228	TH2F * fhMCEDispEtaPhiDiff[2][6] ; //! shower dispersion in eta -phi direction from MC particle
	229	TH2F * fhMCESphericity[2][6] ; //! shower sphericity, eta vs phi from MC particle
34c16486	230
	231	TH2F * fhMCElectronELambda0NoOverlap ; //! E vs Lambda0 from MC electrons, no overlap
	232	TH2F * fhMCElectronELambda0TwoOverlap ; //! E vs Lambda0 from MC electrons, 2 particles overlap
	233	TH2F * fhMCElectronELambda0NOverlap ; //! E vs Lambda0 from MC electrons, N particles overlap
d9105d92	234
	235	//Embedding
	236	TH2F * fhEmbeddedSignalFractionEnergy ; //! Fraction of electron energy of embedded signal vs cluster energy
	237
	238	TH2F * fhEmbedElectronELambda0FullSignal ; //! Lambda0 vs E for embedded electrons with more than 90% of the cluster energy
	239	TH2F * fhEmbedElectronELambda0MostlySignal ; //! Lambda0 vs E for embedded electrons with 90%<fraction<50%
	240	TH2F * fhEmbedElectronELambda0MostlyBkg ; //! Lambda0 vs E for embedded electrons with 50%<fraction<10%
	241	TH2F * fhEmbedElectronELambda0FullBkg ; //! Lambda0 vs E for embedded electrons with less than 10% of the cluster energy
	242
764ab1f4	243	AliAnaElectron( const AliAnaElectron & el) ; // cpy ctor
764ab1f4	244	AliAnaElectron & operator = (const AliAnaElectron & el) ; // cpy assignment
c5693f62	245
7e9a1194	246	ClassDef(AliAnaElectron,5)
d9105d92	247
	248	} ;
	249
	250
	251	#endif//ALIANAELECTRON_H
	252
	253
	254