// --- AliRoot header files ---
#include "AliEMCALClusterizer.h"
-class AliEMCALTowerRecPoint ;
+class TH1F;
+class AliEMCALRecPoint ;
class AliEMCALDigit ;
class AliEMCALDigitizer ;
class AliEMCALGeometry ;
-
+class AliEMCALCalibData ;
class AliEMCALClusterizerv1 : public AliEMCALClusterizer {
public:
AliEMCALClusterizerv1() ;
- AliEMCALClusterizerv1(const TString alirunFileNameFile, const TString eventFolderName = AliConfig::fgkDefaultEventFolderName);
+
virtual ~AliEMCALClusterizerv1() ;
-
+
virtual Int_t AreNeighbours(AliEMCALDigit * d1, AliEMCALDigit * d2)const ;
// Checks if digits are in neighbour cells
- virtual Float_t Calibrate(Int_t amp, Int_t where)const ; // Tranforms Amp to energy
-
- virtual void GetNumberOfClustersFound(int * numb )const{ numb[0] = fNumberOfPREClusters ;
- numb[1] = fNumberOfECAClusters ;
- numb[2] = fNumberOfHCAClusters ; }
+ virtual Float_t Calibrate(Int_t amp, Int_t cellId) ; // Tranforms Amp to energy
- virtual Float_t GetPREClusteringThreshold()const{ return fPREClusteringThreshold; }
- virtual Float_t GetECAClusteringThreshold()const{ return fECAClusteringThreshold;}
- virtual Float_t GetHCAClusteringThreshold()const{ return fHCAClusteringThreshold;}
-
- virtual Float_t GetPRELocalMaxCut()const { return fPRELocMaxCut;}
- virtual Float_t GetPREShoLogWeight()const { return fPREW0;}
+ virtual void GetNumberOfClustersFound(int numb )const{ numb = fNumberOfECAClusters ;}
+ virtual Float_t GetECAClusteringThreshold()const{ return fECAClusteringThreshold;}
virtual Float_t GetECALocalMaxCut()const { return fECALocMaxCut;}
- virtual Float_t GetECALogWeight()const { return fECAW0;}
- virtual Float_t GetHCALocalMaxCut()const { return fHCALocMaxCut;}
- virtual Float_t GetHCALogWeight()const { return fHCAW0;}
+ virtual Float_t GetECALogWeight()const { return fECAW0;}
+ virtual Float_t GetMinECut()const { return fMinECut;}
- virtual Float_t GetTimeGate() const { return fTimeGate ; }
- virtual const char * GetRecPointsBranch() const{ return GetName() ;}
- virtual const Int_t GetRecPointsInRun() const {return fRecPointsInRun ;}
+ virtual Float_t GetTimeCut() const { return fTimeCut ; }
- void Exec(Option_t *option); // Does the job
+ virtual void Digits2Clusters(Option_t *option); // Does the job
virtual void Print(Option_t * option)const ;
virtual void SetECAClusteringThreshold(Float_t cluth) { fECAClusteringThreshold = cluth ; }
+ virtual void SetMinECut(Float_t mine) { fMinECut = mine; }
virtual void SetECALocalMaxCut(Float_t cut) { fECALocMaxCut = cut ; }
virtual void SetECALogWeight(Float_t w) { fECAW0 = w ; }
- virtual void SetHCAClusteringThreshold(Float_t cluth) { fHCAClusteringThreshold = cluth ; }
- virtual void SetHCALocalMaxCut(Float_t cut) { fHCALocMaxCut = cut ; }
- virtual void SetHCALogWeight(Float_t w) { fHCAW0 = w ; }
- virtual void SetTimeGate(Float_t gate) { fTimeGate = gate ;}
- virtual void SetPREClusteringThreshold(Float_t cluth) { fPREClusteringThreshold = cluth ; }
- virtual void SetPRELocalMaxCut(Float_t cut) { fPRELocMaxCut = cut ; }
- virtual void SetPRELogWeight(Float_t w) { fPREW0 = w ; }
+ virtual void SetTimeCut(Float_t gate) { fTimeCut = gate ;}
virtual void SetUnfolding(Bool_t toUnfold = kTRUE ) {fToUnfold = toUnfold ;}
static Double_t ShowerShape(Double_t r) ; // Shape of EM shower used in unfolding;
//class member function (not object member function)
static void UnfoldingChiSquare(Int_t & nPar, Double_t * Grad, Double_t & fret, Double_t * x, Int_t iflag) ;
// Chi^2 of the fit. Should be static to be passes to MINUIT
- void Unload() ;
virtual const char * Version() const { return "clu-v1" ; }
-
+
+ TList* BookHists();
+ void SaveHists(const char *fn="reco.root"); //*MENU*
+ void PrintRecoInfo(); //*MENU*
+ void DrawLambdasHists(); //*MENU*
protected:
- void WriteRecPoints(Int_t event) ;
- virtual void MakeClusters( ) ;
-
+ virtual void MakeClusters();
+
+/////////////////////
+ TList *fHists; //!
+ TH1F* fPointE; //histogram of point energy
+ TH1F* fPointL1; //histogram of point L1
+ TH1F* fPointL2; //histogram of point L2
+ TH1F* fPointDis; //histogram of point dispersion
+ TH1F* fPointMult; //histogram of point multiplicity
+ TH1F* fDigitAmp; //histogram of digit ADC Amplitude
+ TH1F* fMaxE; //histogram of maximum point energy
+ TH1F* fMaxL1; //histogram of largest (first) of eigenvalue of covariance matrix
+ TH1F* fMaxL2; //histogram of smalest (second) of eigenvalue of covariace matrix
+ TH1F* fMaxDis; //histogram of point dispersion
+///////////////////////
+
+
private:
+ AliEMCALClusterizerv1(const AliEMCALClusterizerv1 &); //copy ctor
+ AliEMCALClusterizerv1 & operator = (const AliEMCALClusterizerv1 &);
- const TString BranchName() const ;
void GetCalibrationParameters(void) ;
- Bool_t FindFit(AliEMCALTowerRecPoint * emcRP, AliEMCALDigit ** MaxAt, Float_t * maxAtEnergy,
+ Bool_t FindFit(AliEMCALRecPoint * emcRP, AliEMCALDigit ** MaxAt, Float_t * maxAtEnergy,
Int_t NPar, Float_t * FitParametres) const; //Used in UnfoldClusters, calls TMinuit
void Init() ;
void InitParameters() ;
- virtual void MakeUnfolding() ;
- void UnfoldCluster(AliEMCALTowerRecPoint * iniEmc,Int_t Nmax,
- AliEMCALDigit ** maxAt,Float_t * maxAtEnergy ) ; //Unfolds cluster using TMinuit package
+ virtual void MakeUnfolding() const;
+ void UnfoldCluster(AliEMCALRecPoint * /*iniEmc*/, Int_t /*Nmax*/,
+ AliEMCALDigit ** /*maxAt*/,
+ Float_t * /*maxAtEnergy*/ ) const; //Unfolds cluster using TMinuit package
void PrintRecPoints(Option_t * option) ;
private:
+ AliEMCALGeometry* fGeom; //! pointer to geometry for utilities
Bool_t fDefaultInit; //! Says if the task was created by defaut ctor (only parameters are initialized)
-
- Int_t fNTowers ; // number of Towers in EMCAL
-
Bool_t fToUnfold ; // To perform unfolding
-
- Int_t fNumberOfPREClusters ; // number of clusters found in PRE section
Int_t fNumberOfECAClusters ; // number of clusters found in EC section
- Int_t fNumberOfHCAClusters ; // number of clusters found in HC section
-
+
//Calibration parameters... to be replaced by database
- Float_t fADCchannelPRE ; // width of one ADC channel for PRE section (GeV)
- Float_t fADCpedestalPRE ; // pedestal of ADC for PRE section (GeV)
+
+ AliEMCALCalibData * fCalibData ; //! Calibration database if aval
Float_t fADCchannelECA ; // width of one ADC channel for EC section (GeV)
Float_t fADCpedestalECA ; // pedestal of ADC for EC section (GeV)
- Float_t fADCchannelHCA ; // width of one ADC channel for HC section (GeV)
- Float_t fADCpedestalHCA ; // pedestal of ADC for HC section (GeV)
- Float_t fECAClusteringThreshold ; // minimum energy to include a EC digit in a cluster
- Float_t fHCAClusteringThreshold ; // minimum energy to include a HC digit in a cluster
- Float_t fPREClusteringThreshold ; // minimum energy to include a PRE digit in a cluster
+ Float_t fECAClusteringThreshold ; // minimum energy to seed a EC digit in a cluster
Float_t fECALocMaxCut ; // minimum energy difference to distinguish local maxima in a cluster
Float_t fECAW0 ; // logarithmic weight for the cluster center of gravity calculation
- Float_t fHCALocMaxCut ; // minimum energy difference to distinguish local maxima in a cluster
- Float_t fHCAW0 ; // logarithmic weight for the cluster center of gravity calculation
- Float_t fPRELocMaxCut ; // minimum energy difference to distinguish local maxima in a CPV cluster
- Float_t fPREW0 ; // logarithmic weight for the CPV cluster center of gravity calculation
- Int_t fRecPointsInRun ; //! Total number of recpoints in one run
- Float_t fTimeGate ; // Maximum time difference between the digits in ont EMC cluster
-
- ClassDef(AliEMCALClusterizerv1,2) // Clusterizer implementation version 1
+ Float_t fTimeCut ; // Maximum time difference between the digits in ont EMC cluster
+ Float_t fMinECut; // Minimum energy for a digit to be a member of a cluster
+
+ ClassDef(AliEMCALClusterizerv1,6) // Clusterizer implementation version 1
};