//_________________________________________________________________________
// Class for PID selection with calorimeters
-// The Output of the 2 main methods GetPdg is a PDG number identifying the cluster,
+// The Output of the 2 main methods GetIdentifiedParticleType is a PDG number identifying the cluster,
// being kPhoton, kElectron, kPi0 ... as defined in the header file
-// - GetPdg(const TString calo, const Double_t * pid, const Float_t energy)
+// - GetIdentifiedParticleType(const TString calo, const Double_t * pid, const Float_t energy)
// Reads the PID weights array of the ESDs and depending on its magnitude identifies the particle
-// - GetPdg(const TString calo,const TLorentzVector mom, const AliAODCaloCluster * cluster)
+// - GetIdentifiedParticleType(const TString calo,const TLorentzVector mom, const AliVCluster * cluster)
// Recalcultes PID, the bayesian or any new one to be implemented in the future
// Right now only the possibility to recalculate EMCAL with bayesian and simple PID.
// In order to recalculate Bayesian, it is necessary to load the EMCALUtils library
// where flux is AliCaloPID::kLow or AliCaloPID::kHigh
// If it is necessary to change the parameters use the constructor
// AliCaloPID(AliEMCALPIDUtils *utils) and set the parameters before.
-// - SetPIDBits: Simple PID, depending on the thresholds fDispCut fTOFCut and even the
+// - SetPIDBits: Simple PID, depending on the thresholds fL0Cut fTOFCut and even the
// result of the PID bayesian a different PID bit is set.
//
// All these methods can be called in the analysis you are interested.
// --- ROOT system ---
#include <TMath.h>
#include <TString.h>
-#include <TFormula.h>
//---- ANALYSIS system ----
#include "AliCaloPID.h"
-#include "AliAODCaloCluster.h"
+#include "AliVCluster.h"
+#include "AliVTrack.h"
#include "AliAODPWG4Particle.h"
-#ifdef __EMCALUTIL__
-#include "AliEMCALPIDUtils.h"
-#endif
+#include "AliCalorimeterUtils.h"
+
ClassImp(AliCaloPID)
//________________________________________________
AliCaloPID::AliCaloPID() :
-TObject(), fEMCALPhotonWeight(0.), fEMCALPi0Weight(0.),
-fEMCALElectronWeight(0.), fEMCALChargeWeight(0.),
-fEMCALNeutralWeight(0.),
-fPHOSPhotonWeight(0.), fPHOSPi0Weight(0.),
-fPHOSElectronWeight(0.), fPHOSChargeWeight(0.) ,
-fPHOSNeutralWeight(0.), fPHOSWeightFormula(0),
-fPHOSPhotonWeightFormula(0x0), fPHOSPi0WeightFormula(0x0),
-fDispCut(0.),fTOFCut(0.), fDebug(-1),
-fRecalculateBayesian(kFALSE), fParticleFlux(kLow)
-#ifdef __EMCALUTIL__
-, fEMCALPIDUtils(new AliEMCALPIDUtils)
-#endif
+TObject(),
+fEMCALPhotonWeight(0.), fEMCALPi0Weight(0.),
+fEMCALElectronWeight(0.), fEMCALChargeWeight(0.), fEMCALNeutralWeight(0.),
+fPHOSPhotonWeight(0.), fPHOSPi0Weight(0.),
+fPHOSElectronWeight(0.), fPHOSChargeWeight(0.) , fPHOSNeutralWeight(0.),
+fPHOSWeightFormula(0), fPHOSPhotonWeightFormula(0), fPHOSPi0WeightFormula(0),
+fPHOSPhotonWeightFormulaExpression(""), fPHOSPi0WeightFormulaExpression(""),
+fL0CutMax(100.), fL0CutMin(0), fTOFCut(0.),
+fDebug(-1),
+fRecalculateBayesian(kFALSE), fParticleFlux(kLow), fEMCALPIDUtils(),
+fHistoNEBins(100), fHistoEMax(100.), fHistoEMin(0.),
+fHistoNDEtaBins(100), fHistoDEtaMax(0.15), fHistoDEtaMin(-0.15),
+fHistoNDPhiBins(100), fHistoDPhiMax(0.15), fHistoDPhiMin(-0.15),
+fhTrackMatchedDEta(0x0), fhTrackMatchedDPhi(0x0), fhTrackMatchedDEtaDPhi(0x0)
{
//Ctor
//________________________________________________
AliCaloPID::AliCaloPID(const Int_t flux) :
-TObject(), fEMCALPhotonWeight(0.), fEMCALPi0Weight(0.),
-fEMCALElectronWeight(0.), fEMCALChargeWeight(0.),
-fEMCALNeutralWeight(0.),
-fPHOSPhotonWeight(0.), fPHOSPi0Weight(0.),
-fPHOSElectronWeight(0.), fPHOSChargeWeight(0.) ,
-fPHOSNeutralWeight(0.), fPHOSWeightFormula(0),
-fPHOSPhotonWeightFormula(0x0), fPHOSPi0WeightFormula(0x0),
-fDispCut(0.),fTOFCut(0.), fDebug(-1),
-fRecalculateBayesian(kTRUE), fParticleFlux(flux)
-#ifdef __EMCALUTIL__
-, fEMCALPIDUtils(new AliEMCALPIDUtils)
-#endif
+TObject(),
+fEMCALPhotonWeight(0.), fEMCALPi0Weight(0.),
+fEMCALElectronWeight(0.), fEMCALChargeWeight(0.), fEMCALNeutralWeight(0.),
+fPHOSPhotonWeight(0.), fPHOSPi0Weight(0.),
+fPHOSElectronWeight(0.), fPHOSChargeWeight(0.) , fPHOSNeutralWeight(0.),
+fPHOSWeightFormula(0), fPHOSPhotonWeightFormula(0), fPHOSPi0WeightFormula(0),
+fPHOSPhotonWeightFormulaExpression(""), fPHOSPi0WeightFormulaExpression(""),
+fL0CutMax(100.), fL0CutMin(0), fTOFCut(0.),
+fDebug(-1),
+fRecalculateBayesian(kFALSE), fParticleFlux(flux), fEMCALPIDUtils(),
+fHistoNEBins(100), fHistoEMax(100.), fHistoEMin(0.),
+fHistoNDEtaBins(100), fHistoDEtaMax(0.15), fHistoDEtaMin(-0.15),
+fHistoNDPhiBins(100), fHistoDPhiMax(0.15), fHistoDPhiMin(-0.15),
+fhTrackMatchedDEta(0x0), fhTrackMatchedDPhi(0x0), fhTrackMatchedDEtaDPhi(0x0)
{
- //Ctor
+ //Ctor
- //Initialize parameters
- InitParameters();
+ //Initialize parameters
+ InitParameters();
+
}
//________________________________________________
AliCaloPID::AliCaloPID(const TTask * emcalpid) :
-TObject(), fEMCALPhotonWeight(0.), fEMCALPi0Weight(0.),
-fEMCALElectronWeight(0.), fEMCALChargeWeight(0.),
-fEMCALNeutralWeight(0.),
-fPHOSPhotonWeight(0.), fPHOSPi0Weight(0.),
-fPHOSElectronWeight(0.), fPHOSChargeWeight(0.) ,
-fPHOSNeutralWeight(0.), fPHOSWeightFormula(0),
-fPHOSPhotonWeightFormula(0x0), fPHOSPi0WeightFormula(0x0),
-fDispCut(0.),fTOFCut(0.), fDebug(-1),
-fRecalculateBayesian(kTRUE), fParticleFlux(-1)
-#ifdef __EMCALUTIL__
-, fEMCALPIDUtils( (AliEMCALPIDUtils*) emcalpid)
-#endif
-{
- //Ctor
-
- //Initialize parameters
- InitParameters();
-}
-
-//____________________________________________________________________________
-AliCaloPID::AliCaloPID(const AliCaloPID & pid) :
-TObject(pid), fEMCALPhotonWeight(pid.fEMCALPhotonWeight),
-fEMCALPi0Weight(pid.fEMCALPi0Weight),
-fEMCALElectronWeight(pid.fEMCALElectronWeight),
-fEMCALChargeWeight(pid.fEMCALChargeWeight),
-fEMCALNeutralWeight(pid.fEMCALNeutralWeight),
-fPHOSPhotonWeight(pid.fPHOSPhotonWeight),
-fPHOSPi0Weight(pid.fPHOSPi0Weight),
-fPHOSElectronWeight(pid.fPHOSElectronWeight),
-fPHOSChargeWeight(pid.fPHOSChargeWeight),
-fPHOSNeutralWeight(pid.fPHOSNeutralWeight),
-fPHOSWeightFormula(pid.fPHOSWeightFormula),
-fPHOSPhotonWeightFormula(pid.fPHOSPhotonWeightFormula),
-fPHOSPi0WeightFormula(pid.fPHOSPi0WeightFormula),
-fDispCut(pid.fDispCut),fTOFCut(pid.fTOFCut),
-fDebug(pid.fDebug), fRecalculateBayesian(pid.fRecalculateBayesian),
-fParticleFlux(pid.fParticleFlux)
-#ifdef __EMCALUTIL__
-, fEMCALPIDUtils(pid.fEMCALPIDUtils)
-#endif
+TObject(),
+fEMCALPhotonWeight(0.), fEMCALPi0Weight(0.),
+fEMCALElectronWeight(0.), fEMCALChargeWeight(0.), fEMCALNeutralWeight(0.),
+fPHOSPhotonWeight(0.), fPHOSPi0Weight(0.),
+fPHOSElectronWeight(0.), fPHOSChargeWeight(0.) , fPHOSNeutralWeight(0.),
+fPHOSWeightFormula(0), fPHOSPhotonWeightFormula(0), fPHOSPi0WeightFormula(0),
+fPHOSPhotonWeightFormulaExpression(""), fPHOSPi0WeightFormulaExpression(""),
+fL0CutMax(100.), fL0CutMin(0), fTOFCut(0.),
+fDebug(-1),
+fRecalculateBayesian(kFALSE), fParticleFlux(kLow), fEMCALPIDUtils((AliEMCALPIDUtils*) emcalpid),
+fHistoNEBins(100), fHistoEMax(100.), fHistoEMin(0.),
+fHistoNDEtaBins(100), fHistoDEtaMax(0.15), fHistoDEtaMin(-0.15),
+fHistoNDPhiBins(100), fHistoDPhiMax(0.15), fHistoDPhiMin(-0.15),
+fhTrackMatchedDEta(0x0), fhTrackMatchedDPhi(0x0), fhTrackMatchedDEtaDPhi(0x0)
{
- // cpy ctor
-
-}
-
-//_________________________________________________________________________
-AliCaloPID & AliCaloPID::operator = (const AliCaloPID & pid)
-{
- // assignment operator
-
- if(&pid == this) return *this;
-
- fEMCALPhotonWeight = pid. fEMCALPhotonWeight ;
- fEMCALPi0Weight = pid.fEMCALPi0Weight ;
- fEMCALElectronWeight = pid.fEMCALElectronWeight;
- fEMCALChargeWeight = pid.fEMCALChargeWeight;
- fEMCALNeutralWeight = pid.fEMCALNeutralWeight;
-
- fPHOSPhotonWeight = pid.fPHOSPhotonWeight ;
- fPHOSPi0Weight = pid.fPHOSPi0Weight ;
- fPHOSElectronWeight = pid.fPHOSElectronWeight;
- fPHOSChargeWeight = pid.fPHOSChargeWeight;
- fPHOSNeutralWeight = pid.fPHOSNeutralWeight;
-
- fPHOSWeightFormula = pid.fPHOSWeightFormula;
- fPHOSPhotonWeightFormula = pid.fPHOSPhotonWeightFormula;
- fPHOSPi0WeightFormula = pid.fPHOSPi0WeightFormula;
-
- fDispCut = pid.fDispCut;
- fTOFCut = pid.fTOFCut;
- fDebug = pid.fDebug;
-
- fRecalculateBayesian = pid.fRecalculateBayesian;
- fParticleFlux = pid.fParticleFlux;
-#ifdef __EMCALUTIL__
- fEMCALPIDUtils = pid.fEMCALPIDUtils;
-#endif
-
+ //Ctor
- return *this;
-
+ //Initialize parameters
+ InitParameters();
}
//_________________________________
AliCaloPID::~AliCaloPID() {
//Dtor
- if(fPHOSPhotonWeightFormula) delete fPHOSPhotonWeightFormula ;
- if(fPHOSPi0WeightFormula) delete fPHOSPi0WeightFormula ;
-#ifdef __EMCALUTIL__
- if(fEMCALPIDUtils) delete fEMCALPIDUtils ;
-#endif
+ delete fPHOSPhotonWeightFormula ;
+ delete fPHOSPi0WeightFormula ;
+ delete fEMCALPIDUtils ;
+
+}
+
+//________________________________________________________________________
+TList * AliCaloPID::GetCreateOutputObjects()
+{
+ // Create histograms to be saved in output file and
+ // store them in outputContainer of the analysis class that calls this class.
+
+ TList * outputContainer = new TList() ;
+ outputContainer->SetName("CaloPIDHistos") ;
+
+ outputContainer->SetOwner(kFALSE);
+
+ fhTrackMatchedDEta = new TH2F
+ ("TrackMatchedDEta",
+ "d#eta of cluster-track vs cluster energy",
+ fHistoNEBins,fHistoEMin,fHistoEMax,fHistoNDEtaBins,fHistoDEtaMin,fHistoDEtaMax);
+ fhTrackMatchedDEta->SetYTitle("d#eta");
+ fhTrackMatchedDEta->SetXTitle("E_{cluster} (GeV)");
+
+ fhTrackMatchedDPhi = new TH2F
+ ("TrackMatchedDPhi",
+ "d#phi of cluster-track vs cluster energy"
+ ,fHistoNEBins,fHistoEMin,fHistoEMax,fHistoNDPhiBins,fHistoDPhiMin,fHistoDPhiMax);
+ fhTrackMatchedDPhi->SetYTitle("d#phi (rad)");
+ fhTrackMatchedDPhi->SetXTitle("E_{cluster} (GeV)");
+
+ fhTrackMatchedDEtaDPhi = new TH2F
+ ("TrackMatchedDEtaDPhi",
+ "d#eta vs d#phi of cluster-track vs cluster energy"
+ ,fHistoNDEtaBins,fHistoDEtaMin,fHistoDEtaMax,fHistoNDPhiBins,fHistoDPhiMin,fHistoDPhiMax);
+ fhTrackMatchedDEtaDPhi->SetYTitle("d#phi (rad)");
+ fhTrackMatchedDEtaDPhi->SetXTitle("d#eta");
+
+ outputContainer->Add(fhTrackMatchedDEta) ;
+ outputContainer->Add(fhTrackMatchedDPhi) ;
+ outputContainer->Add(fhTrackMatchedDEtaDPhi) ;
+
+ return outputContainer;
}
+
//_______________________________________________________________
void AliCaloPID::InitParameters()
{
//Initialize the parameters of the PID.
- fEMCALPhotonWeight = 0.5 ;
- fEMCALPi0Weight = 0.5 ;
- fEMCALElectronWeight = 0.5 ;
- fEMCALChargeWeight = 0.5 ;
- fEMCALNeutralWeight = 0.5 ;
+ fEMCALPhotonWeight = 0.6 ;
+ fEMCALPi0Weight = 0.6 ;
+ fEMCALElectronWeight = 0.6 ;
+ fEMCALChargeWeight = 0.6 ;
+ fEMCALNeutralWeight = 0.6 ;
- fPHOSPhotonWeight = 0.5 ;
- fPHOSPi0Weight = 0.5 ;
- fPHOSElectronWeight = 0.5 ;
- fPHOSChargeWeight = 0.5 ;
- fPHOSNeutralWeight = 0.5 ;
+ fPHOSPhotonWeight = 0.6 ;
+ fPHOSPi0Weight = 0.6 ;
+ fPHOSElectronWeight = 0.6 ;
+ fPHOSChargeWeight = 0.6 ;
+ fPHOSNeutralWeight = 0.6 ;
//Formula to set the PID weight threshold for photon or pi0
- fPHOSWeightFormula = kTRUE;
- fPHOSPhotonWeightFormula =
- new TFormula("photonWeight","0.98*(x<40)+ 0.68*(x>=100)+(x>=40 && x<100)*(0.98+x*(6e-3)-x*x*(2e-04)+x*x*x*(1.1e-06))");
- fPHOSPi0WeightFormula =
- new TFormula("pi0Weight","0.98*(x<65)+ 0.915*(x>=100)+(x>=65 && x-x*(1.95e-3)-x*x*(4.31e-05)+x*x*x*(3.61e-07))");
+ fPHOSWeightFormula = kFALSE;
+ fPHOSPhotonWeightFormulaExpression = "0.98*(x<40)+ 0.68*(x>=100)+(x>=40 && x<100)*(0.98+x*(6e-3)-x*x*(2e-04)+x*x*x*(1.1e-06))";
+ fPHOSPi0WeightFormulaExpression = "0.98*(x<65)+ 0.915*(x>=100)+(x>=65 && x-x*(1.95e-3)-x*x*(4.31e-05)+x*x*x*(3.61e-07))" ;
- fDispCut = 1.5;
+ fL0CutMax = 0.3;
+ fL0CutMin = 0.01;
fTOFCut = 5.e-9;
- fDebug = -1;
+ fDebug =-1;
if(fRecalculateBayesian){
-#ifdef __EMCALUTIL__
if(fParticleFlux == kLow){
printf("AliCaloPID::Init() - SetLOWFluxParam\n");
fEMCALPIDUtils->SetLowFluxParam() ;
printf("AliCaloPID::Init() - SetHIGHFluxParam\n");
fEMCALPIDUtils->SetHighFluxParam() ;
}
-#endif
}
}
//_______________________________________________________________
-Int_t AliCaloPID::GetPdg(const TString calo, const Double_t * pid, const Float_t energy) const {
+Int_t AliCaloPID::GetIdentifiedParticleType(const TString calo, const Double_t * pid, const Float_t energy) {
//Return most probable identity of the particle.
if(!pid){
- printf("AliCaloPID::GetPdg() - pid pointer not initialized!!!\n");
+ printf("AliCaloPID::GetIdentifiedParticleType() - pid pointer not initialized!!!\n");
abort();
}
Float_t wE = fPHOSElectronWeight ;
Float_t wCh = fPHOSChargeWeight ;
Float_t wNe = fPHOSNeutralWeight ;
-
-
+
if(calo == "PHOS" && fPHOSWeightFormula){
- wPh = fPHOSPhotonWeightFormula->Eval(energy) ;
- wPi0 = fPHOSPi0WeightFormula->Eval(energy);
+ wPh = GetPHOSPhotonWeightFormula()->Eval(energy) ;
+ wPi0 = GetPHOSPi0WeightFormula() ->Eval(energy);
}
if(calo == "EMCAL"){
}
- if(fDebug > 0) printf("AliCaloPID::GetPdg: calo %s, ph %0.2f, pi0 %0.2f, el %0.2f, conv el %0.2f, hadrons: pion %0.2f, kaon %0.2f, proton %0.2f , neutron %0.2f, kaon %0.2f \n",
- calo.Data(),pid[AliAODCluster::kPhoton], pid[AliAODCluster::kPi0],
- pid[AliAODCluster::kElectron], pid[AliAODCluster::kEleCon],
- pid[AliAODCluster::kPion], pid[AliAODCluster::kKaon], pid[AliAODCluster::kProton],
- pid[AliAODCluster::kNeutron], pid[AliAODCluster::kKaon0]);
+ if(fDebug > 0) printf("AliCaloPID::GetIdentifiedParticleType: calo %s, ph %0.2f, pi0 %0.2f, el %0.2f, conv el %0.2f, hadrons: pion %0.2f, kaon %0.2f, proton %0.2f , neutron %0.2f, kaon %0.2f \n",
+ calo.Data(),pid[AliVCluster::kPhoton], pid[AliVCluster::kPi0],
+ pid[AliVCluster::kElectron], pid[AliVCluster::kEleCon],
+ pid[AliVCluster::kPion], pid[AliVCluster::kKaon], pid[AliVCluster::kProton],
+ pid[AliVCluster::kNeutron], pid[AliVCluster::kKaon0]);
Int_t pdg = kNeutralUnknown ;
- Float_t chargedHadronWeight = pid[AliAODCluster::kProton]+pid[AliAODCluster::kKaon]+
- pid[AliAODCluster::kPion]+pid[AliAODCluster::kMuon];
- Float_t neutralHadronWeight = pid[AliAODCluster::kNeutron]+pid[AliAODCluster::kKaon0];
- Float_t allChargedWeight = pid[AliAODCluster::kElectron]+pid[AliAODCluster::kEleCon]+ chargedHadronWeight;
- Float_t allNeutralWeight = pid[AliAODCluster::kPhoton]+pid[AliAODCluster::kPi0]+ neutralHadronWeight;
+ Float_t chargedHadronWeight = pid[AliVCluster::kProton]+pid[AliVCluster::kKaon]+
+ pid[AliVCluster::kPion]+pid[AliVCluster::kMuon];
+ Float_t neutralHadronWeight = pid[AliVCluster::kNeutron]+pid[AliVCluster::kKaon0];
+ Float_t allChargedWeight = pid[AliVCluster::kElectron]+pid[AliVCluster::kEleCon]+ chargedHadronWeight;
+ Float_t allNeutralWeight = pid[AliVCluster::kPhoton]+pid[AliVCluster::kPi0]+ neutralHadronWeight;
//Select most probable ID
if(calo=="PHOS"){
- if(pid[AliAODCluster::kPhoton] > wPh) pdg = kPhoton ;
- else if(pid[AliAODCluster::kPi0] > wPi0) pdg = kPi0 ;
- else if(pid[AliAODCluster::kElectron] > wE) pdg = kElectron ;
- else if(pid[AliAODCluster::kEleCon] > wE) pdg = kEleCon ;
- else if(chargedHadronWeight > wCh) pdg = kChargedHadron ;
- else if(neutralHadronWeight > wNe) pdg = kNeutralHadron ;
+ if(pid[AliVCluster::kPhoton] > wPh) pdg = kPhoton ;
+ else if(pid[AliVCluster::kPi0] > wPi0) pdg = kPi0 ;
+ else if(pid[AliVCluster::kElectron] > wE) pdg = kElectron ;
+ else if(pid[AliVCluster::kEleCon] > wE) pdg = kEleCon ;
+ else if(chargedHadronWeight > wCh) pdg = kChargedHadron ;
+ else if(neutralHadronWeight > wNe) pdg = kNeutralHadron ;
else if(allChargedWeight > allNeutralWeight)
pdg = kChargedUnknown ;
else
pdg = kNeutralUnknown ;
}
else{//EMCAL
-
- if(pid[AliAODCluster::kPhoton]+pid[AliAODCluster::kElectron] > wPh) pdg = kPhoton ; //temporal sollution until track matching for electrons is considered
- //if(pid[AliAODCluster::kPhoton] > wPh) pdg = kPhoton ;
- else if(pid[AliAODCluster::kPi0] > wPi0) pdg = kPi0 ;
- //else if(pid[AliAODCluster::kElectron] > wE) pdg = kElectron ;
+
+ if(pid[AliVCluster::kPhoton] > wPh) pdg = kPhoton ;
+ else if(pid[AliVCluster::kElectron] > wE) pdg = kElectron ;
+ else if(pid[AliVCluster::kPhoton]+pid[AliVCluster::kElectron] > wPh) pdg = kPhoton ; //temporal sollution until track matching for electrons is considered
+ else if(pid[AliVCluster::kPi0] > wPi0) pdg = kPi0 ;
else if(chargedHadronWeight + neutralHadronWeight > wCh) pdg = kChargedHadron ;
else if(neutralHadronWeight + chargedHadronWeight > wNe) pdg = kNeutralHadron ;
- else pdg = kNeutralUnknown ;
-
+ else pdg = kNeutralUnknown ;
}
- if(fDebug > 0)printf("AliCaloPID::GetPdg:Final Pdg: %d \n", pdg);
-
+ if(fDebug > 0)printf("AliCaloPID::GetIdentifiedParticleType:Final Pdg: %d, cluster energy %2.2f \n", pdg,energy);
+ //printf("PDG1\n");
return pdg ;
}
//_______________________________________________________________
-Int_t AliCaloPID::GetPdg(const TString calo,const TLorentzVector mom, const AliAODCaloCluster * cluster) const {
+Int_t AliCaloPID::GetIdentifiedParticleType(const TString calo,const TLorentzVector mom, const AliVCluster * cluster) {
//Recalculated PID with all parameters
+
Float_t lambda0 = cluster->GetM02();
- Float_t energy = mom.E();
-
- if(fDebug > 0) printf("AliCaloPID::GetPdg: Calorimeter %s, E %3.2f, l0 %3.2f, l1 %3.2f, disp %3.2f, tof %1.11f, distCPV %3.2f, distToBC %1.1f, NMax %d\n",
- calo.Data(),energy,lambda0,cluster->GetM20(),cluster->GetDispersion(),cluster->GetTOF(),
- cluster->GetEmcCpvDistance(), cluster->GetDistToBadChannel(),cluster->GetNExMax());
-
+ Float_t lambda1 = cluster->GetM20();
+ Float_t energy = mom.E();
+
+ if(fDebug > 0) printf("AliCaloPID::GetIdentifiedParticleType: Calorimeter %s, E %3.2f, l0 %3.2f, l1 %3.2f, disp %3.2f, tof %1.11f, distCPV %3.2f, distToBC %1.1f, NMax %d\n",
+ calo.Data(),energy,lambda0,cluster->GetM20(),cluster->GetDispersion(),cluster->GetTOF(),
+ cluster->GetEmcCpvDistance(), cluster->GetDistanceToBadChannel(),cluster->GetNExMax());
+
if(calo == "EMCAL") {
//Recalculate Bayesian
if(fRecalculateBayesian){
-#ifdef __EMCALUTIL__
-
if(fDebug > 0) {
- const Double_t *pid0 = cluster->PID();
- printf("AliCaloPID::GetPdg: BEFORE calo %s, ph %0.2f, pi0 %0.2f, el %0.2f, conv el %0.2f, hadrons: pion %0.2f, kaon %0.2f, proton %0.2f , neutron %0.2f, kaon %0.2f \n",
- calo.Data(),pid0[AliAODCluster::kPhoton], pid0[AliAODCluster::kPi0],
- pid0[AliAODCluster::kElectron], pid0[AliAODCluster::kEleCon],
- pid0[AliAODCluster::kPion], pid0[AliAODCluster::kKaon], pid0[AliAODCluster::kProton],
- pid0[AliAODCluster::kNeutron], pid0[AliAODCluster::kKaon0]);
+ const Double_t *pid0 = cluster->GetPID();
+ printf("AliCaloPID::GetIdentifiedParticleType: BEFORE calo %s, ph %0.2f, pi0 %0.2f, el %0.2f, conv el %0.2f, hadrons: pion %0.2f, kaon %0.2f, proton %0.2f , neutron %0.2f, kaon %0.2f \n",
+ calo.Data(),pid0[AliVCluster::kPhoton], pid0[AliVCluster::kPi0],
+ pid0[AliVCluster::kElectron], pid0[AliVCluster::kEleCon],
+ pid0[AliVCluster::kPion], pid0[AliVCluster::kKaon], pid0[AliVCluster::kProton],
+ pid0[AliVCluster::kNeutron], pid0[AliVCluster::kKaon0]);
}
- fEMCALPIDUtils->ComputePID(energy, lambda0);
- Double_t pid[AliPID::kSPECIESN];
- for(Int_t i = 0; i < AliPID::kSPECIESN; i++) pid[i] = fEMCALPIDUtils->GetPIDFinal(i);
- return GetPdg(calo, pid, energy);
+ fEMCALPIDUtils->ComputePID(energy, lambda0);
+ Double_t pid[AliPID::kSPECIESN];
+ for(Int_t i = 0; i < AliPID::kSPECIESN; i++) pid[i] = fEMCALPIDUtils->GetPIDFinal(i);
+ return GetIdentifiedParticleType(calo, pid, energy);
-#endif
-
- }
-
- // If no use of bayesian, simple PID
- if(lambda0 < 0.25) return kPhoton ;
- //else return kNeutralHadron ;
- else return kPi0 ;
- }
-
- // if(calo == "PHOS") {
- // if(cluster->GetM02()< 0.25) return kPhoton ;
- // else return kNeutralHadron ;
- // }
+ }
+
+ // If no use of bayesian, simplest PID
+ if(lambda0 < fL0CutMax && lambda0 > fL0CutMin) return kPhoton ;
+ else return kPi0 ; // Wild guess, it can be hadron but not photon
- return kNeutralHadron ;
+ }//EMCAL
+ else {//PHOS
+
+ // Do not use bayesian, cut based on shower ellipse
+ return IsPHOSPhoton(lambda0,lambda1);
+ }
+
}
//__________________________________________________
//Put data member values in string to keep in output container
TString parList ; //this will be list of parameters used for this analysis.
- char onePar[255] ;
- sprintf(onePar,"--- AliCaloPID ---\n") ;
+ const Int_t buffersize = 255;
+ char onePar[buffersize] ;
+ snprintf(onePar,buffersize,"--- AliCaloPID ---\n") ;
parList+=onePar ;
- sprintf(onePar,"fDispCut =%2.2f (Cut on dispersion, used in PID evaluation) \n",fDispCut) ;
+ snprintf(onePar,buffersize,"fL0CutMin =%2.2f, fL0CutMax =%2.2f (Cut on Shower Shape, used in PID evaluation) \n",fL0CutMin, fL0CutMax) ;
parList+=onePar ;
- sprintf(onePar,"fTOFCut =%e (Cut on TOF, used in PID evaluation) \n",fTOFCut) ;
+ snprintf(onePar,buffersize,"fTOFCut =%e (Cut on TOF, used in PID evaluation) \n",fTOFCut) ;
parList+=onePar ;
- sprintf(onePar,"fEMCALPhotonWeight =%2.2f (EMCAL bayesian weight for photons)\n",fEMCALPhotonWeight) ;
+ snprintf(onePar,buffersize,"fEMCALPhotonWeight =%2.2f (EMCAL bayesian weight for photons)\n",fEMCALPhotonWeight) ;
parList+=onePar ;
- sprintf(onePar,"fEMCALPi0Weight =%2.2f (EMCAL bayesian weight for pi0)\n",fEMCALPi0Weight) ;
+ snprintf(onePar,buffersize,"fEMCALPi0Weight =%2.2f (EMCAL bayesian weight for pi0)\n",fEMCALPi0Weight) ;
parList+=onePar ;
- sprintf(onePar,"fEMCALElectronWeight =%2.2f(EMCAL bayesian weight for electrons)\n",fEMCALElectronWeight) ;
+ snprintf(onePar,buffersize,"fEMCALElectronWeight =%2.2f(EMCAL bayesian weight for electrons)\n",fEMCALElectronWeight) ;
parList+=onePar ;
- sprintf(onePar,"fEMCALChargeWeight =%2.2f (EMCAL bayesian weight for charged hadrons)\n",fEMCALChargeWeight) ;
+ snprintf(onePar,buffersize,"fEMCALChargeWeight =%2.2f (EMCAL bayesian weight for charged hadrons)\n",fEMCALChargeWeight) ;
parList+=onePar ;
- sprintf(onePar,"fEMCALNeutralWeight =%2.2f (EMCAL bayesian weight for neutral hadrons)\n",fEMCALNeutralWeight) ;
+ snprintf(onePar,buffersize,"fEMCALNeutralWeight =%2.2f (EMCAL bayesian weight for neutral hadrons)\n",fEMCALNeutralWeight) ;
parList+=onePar ;
- sprintf(onePar,"fPHOSPhotonWeight =%2.2f (PHOS bayesian weight for photons)\n",fPHOSPhotonWeight) ;
+ snprintf(onePar,buffersize,"fPHOSPhotonWeight =%2.2f (PHOS bayesian weight for photons)\n",fPHOSPhotonWeight) ;
parList+=onePar ;
- sprintf(onePar,"fPHOSPi0Weight =%2.2f (PHOS bayesian weight for pi0)\n",fPHOSPi0Weight) ;
+ snprintf(onePar,buffersize,"fPHOSPi0Weight =%2.2f (PHOS bayesian weight for pi0)\n",fPHOSPi0Weight) ;
parList+=onePar ;
- sprintf(onePar,"fPHOSElectronWeight =%2.2f(PHOS bayesian weight for electrons)\n",fPHOSElectronWeight) ;
+ snprintf(onePar,buffersize,"fPHOSElectronWeight =%2.2f(PHOS bayesian weight for electrons)\n",fPHOSElectronWeight) ;
parList+=onePar ;
- sprintf(onePar,"fPHOSChargeWeight =%2.2f (PHOS bayesian weight for charged hadrons)\n",fPHOSChargeWeight) ;
+ snprintf(onePar,buffersize,"fPHOSChargeWeight =%2.2f (PHOS bayesian weight for charged hadrons)\n",fPHOSChargeWeight) ;
parList+=onePar ;
- sprintf(onePar,"fPHOSNeutralWeight =%2.2f (PHOS bayesian weight for neutral hadrons)\n",fPHOSNeutralWeight) ;
+ snprintf(onePar,buffersize,"fPHOSNeutralWeight =%2.2f (PHOS bayesian weight for neutral hadrons)\n",fPHOSNeutralWeight) ;
parList+=onePar ;
if(fPHOSWeightFormula){
- sprintf(onePar,"PHOS Photon Weight Formula: %s\n",(fPHOSPhotonWeightFormula->GetExpFormula("p")).Data()) ;
+ snprintf(onePar,buffersize,"PHOS Photon Weight Formula: %s\n",fPHOSPhotonWeightFormulaExpression.Data() ) ;
parList+=onePar;
- sprintf(onePar,"PHOS Pi0 Weight Formula: %s\n",(fPHOSPi0WeightFormula->GetExpFormula("p")).Data()) ;
- parList+=onePar;
+ snprintf(onePar,buffersize,"PHOS Pi0 Weight Formula: %s\n",fPHOSPi0WeightFormulaExpression.Data() ) ;
+ parList+=onePar;
}
return parList;
printf("PHOS Parametrized weight on? = %d\n", fPHOSWeightFormula) ;
if(fPHOSWeightFormula){
- printf("Photon weight formula = %s\n", (fPHOSPhotonWeightFormula->GetExpFormula("p")).Data());
- printf("Pi0 weight formula = %s\n", (fPHOSPhotonWeightFormula->GetExpFormula("p")).Data());
+ printf("Photon weight formula = %s\n", fPHOSPhotonWeightFormulaExpression.Data());
+ printf("Pi0 weight formula = %s\n", fPHOSPi0WeightFormulaExpression .Data());
}
printf("TOF cut = %e\n",fTOFCut);
- printf("Dispersion cut = %2.2f\n",fDispCut);
+ printf("Lambda0 cut min = %2.2f; max = %2.2f\n",fL0CutMin, fL0CutMax);
printf("Debug level = %d\n",fDebug);
printf("Recalculate Bayesian? = %d\n",fRecalculateBayesian);
if(fRecalculateBayesian) printf("Particle Flux? = %d\n",fParticleFlux);
}
//_______________________________________________________________
-void AliCaloPID::SetPIDBits(const TString calo, const AliAODCaloCluster * cluster, AliAODPWG4Particle * ph) {
+void AliCaloPID::SetPIDBits(const TString calo, const AliVCluster * cluster, AliAODPWG4Particle * ph, const AliCalorimeterUtils* cu) {
//Set Bits for PID selection
//Dispersion/lambdas
- Double_t disp=cluster->GetDispersion() ;
- // Double_t m20=calo->GetM20() ;
- // Double_t m02=calo->GetM02() ;
- ph->SetDispBit(disp<fDispCut) ;
+ //Double_t disp= cluster->GetDispersion() ;
+ Double_t l1 = cluster->GetM20() ;
+ Double_t l0 = cluster->GetM02() ;
+ Bool_t isDispOK = kTRUE ;
+ if(cluster->IsPHOS()){
+
+ isDispOK = IsPHOSPhoton(l0,l1);
+
+ }
+ else{//EMCAL
+
+ if(l0 > fL0CutMin && l0 < fL0CutMax) isDispOK = kTRUE;
+
+ }
+
+ ph->SetDispBit(isDispOK) ;
//TOF
Double_t tof=cluster->GetTOF() ;
ph->SetTOFBit(TMath::Abs(tof)<fTOFCut) ;
- //Charged veto
- // Double_t cpvR=calo->GetEmcCpvDistance() ;
- Int_t ntr=cluster->GetNTracksMatched(); //number of track matched
- ph->SetChargedBit(ntr>0) ; //Temporary cut, should we evaluate distance?
+ //Charged veto
+ //Bool_t isNeutral = kTRUE ;
+ //if(cluster->IsPHOS()) isNeutral = cluster->GetEmcCpvDistance() > 5. ;
+ //else
+ Bool_t isNeutral = IsTrackMatched(cluster,cu);
+
+ ph->SetChargedBit(isNeutral);
//Set PID pdg
- ph->SetPdg(GetPdg(calo,cluster->PID(),ph->E()));
+ ph->SetIdentifiedParticleType(GetIdentifiedParticleType(calo,cluster->GetPID(),ph->E()));
if(fDebug > 0){
- printf("AliCaloPID::SetPIDBits: TOF %e, Dispersion %2.2f, NTracks %d\n",tof , disp, ntr);
+ printf("AliCaloPID::SetPIDBits: TOF %e, Lambda0 %2.2f, Lambda1 %2.2f\n",tof , l0, l1);
printf("AliCaloPID::SetPIDBits: pdg %d, bits: TOF %d, Dispersion %d, Charge %d\n",
- ph->GetPdg(), ph->GetTOFBit() , ph->GetDispBit() , ph->GetChargedBit());
+ ph->GetIdentifiedParticleType(), ph->GetTOFBit() , ph->GetDispBit() , ph->GetChargedBit());
+ }
+}
+
+//__________________________________________________________________________
+Bool_t AliCaloPID::IsTrackMatched(const AliVCluster* cluster, const AliCalorimeterUtils * cu) const {
+ //Check if there is any track attached to this cluster
+
+ Int_t nMatches = cluster->GetNTracksMatched();
+// if(nMatches>0){
+// printf("N matches %d, first match (ESD) %d or (AOD) %d\n",nMatches,cluster->GetTrackMatchedIndex(), cluster->GetTrackMatched(0));
+// if (cluster->GetTrackMatched(0)) printf("\t matched track id %d\n",((AliVTrack*)cluster->GetTrackMatched(0)) ->GetID() ) ;
+// }
+// else {
+// printf("Not Matched");
+// }
+
+ //If EMCAL track matching needs to be recalculated
+ if(cluster->IsEMCAL() && cu && cu->IsRecalculationOfClusterTrackMatchingOn()){
+ Float_t dR = 999., dZ = 999.;
+ cu->GetEMCALRecoUtils()->GetMatchedResiduals(cluster->GetID(),dR,dZ);
+
+ if(dR < 999) {
+
+ if(fhTrackMatchedDEta){
+ fhTrackMatchedDEta->Fill(cluster->E(),dZ);
+ fhTrackMatchedDPhi->Fill(cluster->E(),dR);
+ if(cluster->E() > 0.5)fhTrackMatchedDEtaDPhi->Fill(dZ,dR);
+ }
+ //printf("dR %f, dZ %f \n",dR,dZ);
+ return kTRUE;
+ }
+ else
+ return kFALSE;
+ }//EMCAL cluster and recalculation of matching on
+
+ if(fhTrackMatchedDEta){
+ fhTrackMatchedDEta->Fill(cluster->GetTrackDz(),cluster->E());
+ fhTrackMatchedDEta->Fill(cluster->GetTrackDx(),cluster->E());
+ if(cluster->E() > 0.5)fhTrackMatchedDEtaDPhi->Fill(cluster->GetTrackDz(),cluster->GetTrackDx());
}
+
+ if(!strcmp("AliESDCaloCluster",Form("%s",cluster->ClassName())))
+ {
+ if (nMatches > 0) {
+ if (nMatches == 1 ) {
+ Int_t iESDtrack = cluster->GetTrackMatchedIndex();
+ //printf("Track Matched index %d\n",iESDtrack);
+ if(iESDtrack==-1) return kFALSE ;// Default value of array, there is no match
+ else return kTRUE;
+ }//Just one, check
+ else return kTRUE ;//More than one, there is a match.
+ }// > 0
+ else return kFALSE; //It does not happen, but in case
+
+ }//ESDs
+ else
+ {
+ if(nMatches > 0) return kTRUE; //There is at least one match.
+ else return kFALSE;
+
+ }//AODs or MC (copy into AOD)
+
+ return kFALSE;
+
}
+//__________________________________________________________________________
+Bool_t IsPHOSPhoton(const Double_t l0, const Double_t l1) {
+ // Check the shape of the PHOS cluster
+ // Return true if photon like, from Dmitri P.
+ // TO DO, move parameters to data members
+
+ Double_t l0Mean = 1.22 ;
+ Double_t l1Mean = 2.0 ;
+ Double_t l0Sigma = 0.42 ;
+ Double_t l1Sigma = 0.71 ;
+ Double_t c =-0.59 ;
+
+ Double_t R2=(l1-l1Mean)*(l0-l0Mean)/l0Sigma/l0Sigma+(l1-l1Mean)*(l1-l1Mean)/l1Sigma/l1Sigma-c*(l0-l0Mean)*(l1-l1Mean)/l0Sigma/l1Sigma ;
+
+ return (R2<9.) ;
+
+}