#ifndef ALIPHOSPIDV1_H #define ALIPHOSPIDV1_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ /* $Id$ */ //_________________________________________________________________________ // Implementation version v1 of the PHOS particle identifier // Identification is based on information from CPV and EMC // Oh yeah //*-- Author: Yves Schutz (SUBATECH), Gustavo Conesa. // --- ROOT system --- class TVector3 ; class TMatrix ; class TPrincipal ; class TROOT ; class TTree ; class TCanvas ; class TFolder ; class TMatrixD ; class TFormula; // --- Standard library --- // --- AliRoot header files --- class AliPHOSEmcRecPoint ; class AliPHOSCpvRecPoint ; class AliPHOSClusterizerv1 ; class AliPHOSTrackSegmentMakerv1 ; #include "AliPHOSPID.h" #include "AliESDtrack.h" class AliPHOSPIDv1 : public AliPHOSPID { public: AliPHOSPIDv1() ; // ctor AliPHOSPIDv1(const TString alirunFileNameFile, const TString eventFolderName = AliConfig::GetDefaultEventFolderName()) ; AliPHOSPIDv1(const AliPHOSPIDv1 & pid) ; // cpy ctor virtual ~AliPHOSPIDv1() ; // dtor virtual void Exec(Option_t *option); // Does the job //Get file name that contain the PCA const TString GetFileNamePrincipal(TString particle) const; //Get file name that contain PID parameters const TString GetFileNameParameters() const {return fFileNameParameters ;} // Get number of rec.particles in this run virtual Int_t GetRecParticlesInRun() const {return fRecParticlesInRun ;} // Get PID parameters as they are defined in fParameters Float_t GetParameterCalibration (Int_t i) const; Float_t GetParameterCpv2Emc (Int_t i, TString axis) const; Float_t GetParameterTimeGate (Int_t i) const; Float_t GetParameterToCalculateEllipse(TString particle, TString param, Int_t i) const ; Float_t GetParameterPhotonBoundary (Int_t i) const; Float_t GetParameterPi0Boundary (Int_t i) const; // Get energy-dependent PID parameters Float_t GetCalibratedEnergy (Float_t e) const; Float_t GetCpv2EmcDistanceCut (TString axis, Float_t e) const ; Float_t GetEllipseParameter (TString particle, TString param, Float_t e) const; //Do bayesian PID void SetBayesianPID(Bool_t set){ fBayesian = set ;} // Set PID parameters to change appropriate element of fParameters void SetParameterCalibration (Int_t i, Float_t param); void SetParameterCpv2Emc (Int_t i, TString axis, Float_t cut) ; void SetParameterTimeGate (Int_t i, Float_t gate) ; void SetParameterToCalculateEllipse(TString particle, TString param, Int_t i, Float_t value) ; void SetParameterPhotonBoundary(Int_t i, Float_t param); void SetParameterPi0Boundary (Int_t i, Float_t param); //Switch to "on flyght" mode, without writing to TreeR and file void SetWriting(Bool_t toWrite = kFALSE){fWrite = toWrite;} void Print() const ; virtual const char * Version() const { return "pid-v1" ; } AliPHOSPIDv1 & operator = (const AliPHOSPIDv1 & /*pid*/) { return *this ;} private: const TString BranchName() const ; virtual void Init() ; virtual void InitParameters() ; void MakeRecParticles(void ) ; void MakePID(void) ; //Functions to calculate the PID probability // Double_t ChargedHadronDistProb(Double_t x, Double_t y, Double_t * parg, Double_t * parl) ; Double_t GausF (Double_t x, Double_t y, Double_t *par) ; //gaussian probability, parameter dependence a+b/(x*x)+c/x Double_t GausPol2(Double_t x, Double_t y, Double_t *par) ; //gaussian probability, parameter dependence a+b*x+c*x*x Double_t LandauF(Double_t x, Double_t y, Double_t *par) ; //gaussian probability, parameter dependence a+b/(x*x)+c/x Double_t LandauPol2(Double_t x, Double_t y, Double_t *par) ; //gaussian probability, parameter dependence a+b*x+c*x*x // Relative Distance CPV-EMC Float_t GetDistance (AliPHOSEmcRecPoint * emc, AliPHOSCpvRecPoint * cpv, Option_t * axis)const ; Int_t GetCPVBit (AliPHOSEmcRecPoint * emc, AliPHOSCpvRecPoint * cpv, Int_t EffPur, Float_t e) const; Int_t GetPrincipalBit (TString particle, const Double_t* P, Int_t EffPur, Float_t e)const ; //Principal cut Int_t GetHardPhotonBit(AliPHOSEmcRecPoint * emc) const; Int_t GetHardPi0Bit (AliPHOSEmcRecPoint * emc) const; TVector3 GetMomentumDirection(AliPHOSEmcRecPoint * emc, AliPHOSCpvRecPoint * cpv)const ; void PrintRecParticles(Option_t * option) ; virtual void WriteRecParticles() ; void SetParameters() ; //Fills the matrix of parameters void Unload(); //PID population void SetInitPID(const Double_t * pid) ; void GetInitPID(Double_t * pid) const ; private: Bool_t fBayesian ; // Do PID bayesian Bool_t fDefaultInit; //! kTRUE if the task was created by defaut ctor (only parameters are initialized) Bool_t fWrite ; //! To write result to file Int_t fNEvent ; //! current event number TString fFileNamePrincipalPhoton ; // File name of the photon principals TString fFileNamePrincipalPi0 ; // File name of the pi0 principals TString fFileNameParameters ; // File name with PID parameters TPrincipal *fPrincipalPhoton ; //! TPrincipal from photon pca file TPrincipal *fPrincipalPi0 ; //! TPrincipal from pi0 pca file Double_t *fX ; //! Shower shape for the principal data Double_t *fPPhoton ; //! Principal photon eigenvalues Double_t *fPPi0 ; //! Principal pi0 eigenvalues Int_t fRecParticlesInRun ; //! Total number of recparticles in one run TMatrix *fParameters; //! Matrix of identification Parameters //Initial pid population Double_t fInitPID[AliPID::kSPECIESN] ; // Initial population to do bayesian PID // pid probability function parameters // ToF Double_t fTphoton[3] ; // gaussian tof response for photon TFormula * fTFphoton ; // the formula /* Double_t fTelectron[3] ; // gaussian tof response for electrons */ /* TFormula * fTFelectron ; // the formula */ /* Double_t fTmuon[3] ; // gaussian tof response for muon */ /* TFormula * fTFmuon ; // the formula */ Double_t fTpiong[3] ; // gaussian tof response for pions TFormula * fTFpiong ; // the formula /* Double_t fTpionl[3] ; // gaussian tof response for pions */ /* TFormula * fTFpionl ; // the formula */ Double_t fTkaong[3] ; // landau tof response for kaons TFormula * fTFkaong ; // the formula Double_t fTkaonl[3] ; // landau tof response for kaons TFormula * fTFkaonl ; // the formula Double_t fThhadrong[3] ; // gaus tof response for heavy hadrons TFormula * fTFhhadrong ; // the formula Double_t fThhadronl[3] ; // landau tof response for heavy hadrons TFormula * fTFhhadronl ; // the formula /* Double_t fTpion[9] ; // gaussian tof response for pions */ /* Double_t fTkaon[9] ; // landau tof response for kaons */ /* Double_t fThhadron[9] ; // landau tof response for nucleons */ //Shower dispersion Double_t fDmuon[3] ; // gaussian ss response for muon TFormula * fDFmuon ; // the formula Double_t fDphoton[9] ; // gaussian ss response for EM Double_t fDpi0[9] ; // gaussian ss response for pi0 Double_t fDhadron[9] ; // gaussian ss response for hadrons // gaussian ss response for muons //CPV-EMCAL distance /* Double_t fCPVelectron[9] ; // gaussian emc-cpv distance response for electron */ /* Double_t fCPVcharged[9] ; // landau emc-cpv distance response for charged part (no elect) */ Double_t fXelectron[9] ; // gaussian emc-cpv distance response for electron Double_t fXcharged[9] ; // landau emc-cpv distance response for charged part (no elect) */ Double_t fZelectron[9] ; // gaussian emc-cpv distance response for electron Double_t fZcharged[9] ; // landau emc-cpv distance response for charged part (no elect) */ /* Double_t fCPVchargedg[9] ; // gaussian emc-cpv distance response for charged part (no elect) */ /* Double_t fCPVchargedl[9] ; // landau emc-cpv distance response for charged part (no elect) */ ClassDef( AliPHOSPIDv1,11) // Particle identifier implementation version 1 }; #endif // AliPHOSPIDV1_H