* provided "as is" without express or implied warranty. *
**************************************************************************/
+/* $Id$ */
+
//_________________________________________________________________________
-// Algorithm class to identify the type of particle from the PHOS TrackSegment alone
-//*-- Author : Y. Schutz SUBATECH
-//////////////////////////////////////////////////////////////////////////////
+// Implementation version v1 of the PHOS particle identifier
+// Particle identification based on the
+// - RCPV: distance from CPV recpoint to EMCA recpoint.
+// - TOF
+// - PCA: Principal Components Analysis..
+// The identified particle has an identification number corresponding
+// to a 9 bits number:
+// -Bit 0 to 2: bit set if RCPV > CpvEmcDistance (each bit corresponds
+// to a different efficiency-purity point of the photon identification)
+// -Bit 3 to 5: bit set if TOF < TimeGate (each bit corresponds
+// to a different efficiency-purity point of the photon identification)
+// -Bit 6 to 9: bit set if Principal Components are
+// inside an ellipse defined by the parameters a, b, c, x0 and y0.
+// (each bit corresponds to a different efficiency-purity point of the
+// photon identification)
+// The PCA (Principal components analysis) needs a file that contains
+// a previous analysis of the correlations between the particles. This
+// file is $ALICE_ROOT/PHOS/PCA8pa15_0.5-100.root. Analysis done for
+// energies between 0.5 and 100 GeV.
+// A calibrated energy is calculated. The energy of the reconstructed
+// cluster is corrected with the formula A + B * E + C * E^2, whose
+// parameters where obtained through the study of the reconstructed
+// energy distribution of monoenergetic photons.
+//
+// All the parameters (RCPV(2 rows-3 columns),TOF(1r-3c),PCA(5r-4c)
+// and calibration(1r-3c))are stored in a file called
+// $ALICE_ROOT/PHOS/Parameters.dat. Each time that AliPHOSPIDv1 is
+// initialized, this parameters are copied to a Matrix (9,4), a
+// TMatrixD object.
+//
+// use case:
+// root [0] AliPHOSPIDv1 * p = new AliPHOSPIDv1("galice1.root")
+// Warning in <TDatabasePDG::TDatabasePDG>: object already instantiated
+// // reading headers from file galice1.root and create RecParticles
+ // TrackSegments and RecPoints are used
+// // set file name for the branch RecParticles
+// root [1] p->ExecuteTask("deb all time")
+// // available options
+// // "deb" - prints # of reconstructed particles
+// // "deb all" - prints # and list of RecParticles
+// // "time" - prints benchmarking results
+//
+// root [2] AliPHOSPIDv1 * p2 = new AliPHOSPIDv1("galice1.root","v1",kTRUE)
+// Warning in <TDatabasePDG::TDatabasePDG>: object already instantiated
+// //Split mode.
+// root [3] p2->ExecuteTask()
+//
+
+//*-- Author: Yves Schutz (SUBATECH) & Gines Martinez (SUBATECH) &
+// Gustavo Conesa April 2002
+// PCA redesigned by Gustavo Conesa October 2002:
+// The way of using the PCA has changed. Instead of 2
+// files with the PCA, each one with different energy ranges
+// of application, we use the wide one (0.5-100 GeV), and instead
+// of fixing 3 ellipses for different ranges of energy, it has been
+// studied the dependency of the ellipses parameters with the
+// energy, and they are implemented in the code as a funtion
+// of the energy.
+//
+//
+//
// --- ROOT system ---
+#include "TROOT.h"
+#include "TTree.h"
+#include "TFile.h"
+#include "TSystem.h"
+#include "TBenchmark.h"
+#include "TMatrixD.h"
+#include "TPrincipal.h"
// --- Standard library ---
-#include <iostream>
+//#include <Riostream.h>
// --- AliRoot header files ---
+#include "AliGenerator.h"
#include "AliPHOSPIDv1.h"
#include "AliPHOSTrackSegment.h"
#include "AliPHOSRecParticle.h"
+#include "AliPHOSGeometry.h"
+#include "AliPHOSGetter.h"
ClassImp( AliPHOSPIDv1)
-
//____________________________________________________________________________
- AliPHOSPIDv1::AliPHOSPIDv1(): fCutOnDispersion(1.5)
+AliPHOSPIDv1::AliPHOSPIDv1():AliPHOSPID()
+{
+ // default ctor
+
+ InitParameters() ;
+ fDefaultInit = kTRUE ;
-{
+}
+
+//____________________________________________________________________________
+AliPHOSPIDv1::AliPHOSPIDv1(AliPHOSPIDv1 & pid ):AliPHOSPID(pid)
+{
// ctor
+ InitParameters() ;
+
+ Init() ;
+ fDefaultInit = kFALSE ;
+
+}
+
+//____________________________________________________________________________
+AliPHOSPIDv1::AliPHOSPIDv1(const char * headerFile,const char * name, const Bool_t toSplit)
+:AliPHOSPID(headerFile, name,toSplit)
+{
+ //ctor with the indication on where to look for the track segments
+
+ InitParameters() ;
+
+ Init() ;
+ fDefaultInit = kFALSE ;
}
//____________________________________________________________________________
- AliPHOSPIDv1::~AliPHOSPIDv1()
+AliPHOSPIDv1::~AliPHOSPIDv1()
{
// dtor
+ // fDefaultInit = kTRUE if PID created by default ctor (to get just the parameters)
+
+ delete [] fX ; // Principal input
+ delete [] fP ; // Principal components
+ delete [] fPPi0 ; // Pi0 Principal components
+
+ if (!fDefaultInit) {
+// AliPHOSGetter * gime = AliPHOSGetter::GetInstance() ;
+ // remove the task from the folder list
+// gime->RemoveTask("P",GetName()) ;
+// TString name(GetName()) ;
+// name.ReplaceAll("pid", "clu") ;
+// gime->RemoveTask("C",name) ;
+
+// // remove the data from the folder list
+// name = GetName() ;
+// name.Remove(name.Index(":")) ;
+// gime->RemoveObjects("RE", name) ; // EMCARecPoints
+// gime->RemoveObjects("RC", name) ; // CPVRecPoints
+// gime->RemoveObjects("T", name) ; // TrackSegments
+// gime->RemoveObjects("P", name) ; // RecParticles
+
+// // Delete gAlice
+// gime->CloseFile() ;
+
+ fSplitFile = 0 ;
+ }
+}
+
+//____________________________________________________________________________
+const TString AliPHOSPIDv1::BranchName() const
+{
+ // gives the name of the current branch
+ TString branchName(GetName() ) ;
+ branchName.Remove(branchName.Index(Version())-1) ;
+ return branchName ;
+}
+
+//____________________________________________________________________________
+void AliPHOSPIDv1::Init()
+{
+ // Make all memory allocations that are not possible in default constructor
+ // Add the PID task to the list of PHOS tasks
+
+ if ( strcmp(GetTitle(), "") == 0 )
+ SetTitle("galice.root") ;
+
+ TString branchname(GetName()) ;
+ branchname.Remove(branchname.Index(Version())-1) ;
+ AliPHOSGetter * gime = AliPHOSGetter::GetInstance(GetTitle(),branchname.Data(),fToSplit ) ;
+
+ // gime->SetRecParticlesTitle(BranchName()) ;
+ if ( gime == 0 ) {
+ Error("Init", "Could not obtain the Getter object !" ) ;
+ return ;
+ }
+
+ fSplitFile = 0 ;
+ if(fToSplit){
+ //First - extract full path if necessary
+ TString fileName(GetTitle()) ;
+ Ssiz_t islash = fileName.Last('/') ;
+ if(islash<fileName.Length())
+ fileName.Remove(islash+1,fileName.Length()) ;
+ else
+ fileName="" ;
+ fileName+="PHOS.RecData." ;
+ if((strcmp(branchname.Data(),"Default")!=0)&&(strcmp(branchname.Data(),"")!=0)){
+ fileName+=branchname.Data() ;
+ fileName+="." ;
+ }
+ fileName+="root" ;
+ fSplitFile = static_cast<TFile*>(gROOT->GetFile(fileName.Data()));
+ if(!fSplitFile)
+ fSplitFile = TFile::Open(fileName.Data(),"update") ;
+ }
+
+ gime->PostPID(this) ;
+ // create a folder on the white board //YSAlice/WhiteBoard/RecParticles/PHOS/recparticlesName
+ gime->PostRecParticles(branchname) ;
+
+}
+
+//____________________________________________________________________________
+void AliPHOSPIDv1::InitParameters()
+{
+// fFrom = "" ;
+// fHeaderFileName = GetTitle() ;
+// TString name(GetName()) ;
+// if (name.IsNull())
+// name = "Default" ;
+// fTrackSegmentsTitle = name ;
+// fRecPointsTitle = name ;
+// fRecParticlesTitle = name ;
+// name.Append(":") ;
+// name.Append(Version()) ;
+// SetName(name) ;
+ fRecParticlesInRun = 0 ;
+ fNEvent = 0 ;
+ // fClusterizer = 0 ;
+ // fTSMaker = 0 ;
+ fRecParticlesInRun = 0 ;
+ TString pidName( GetName()) ;
+ if (pidName.IsNull() )
+ pidName = "Default" ;
+ pidName.Append(":") ;
+ pidName.Append(Version()) ;
+ SetName(pidName) ;
+ fPi0Analysis = kFALSE ;
+ SetParameters() ; // fill the parameters matrix from parameters file
+}
+
+//____________________________________________________________________________
+const Float_t AliPHOSPIDv1::GetCpvtoEmcDistanceCut(const Float_t e, const TString Axis) const
+{
+ // Get CpvtoEmcDistance Cut depending on the cluster energy, axis and
+ // Purity-Efficiency point
+
+ Int_t i = -1;
+ if (Axis.Contains("X")) i = 1;
+ else if (Axis.Contains("Z")) i = 2;
+ else
+ Error("GetCpvtoEmcDistanceCut"," Invalid axis option ");
+
+ Float_t a = (*fParameters)(i,0) ;
+ Float_t b = (*fParameters)(i,1) ;
+ Float_t c = (*fParameters)(i,2) ;
+
+ Float_t sig = a + TMath::Exp(b-c*e);
+ return sig;
+}
+//____________________________________________________________________________
+
+const Double_t AliPHOSPIDv1::GetTimeGate(const Int_t effpur) const
+{
+ // Get TimeGate parameter depending on Purity-Efficiency point
+
+ if(effpur>2 || effpur<0)
+ Error("GetTimeGate","Invalid Efficiency-Purity choice %d",effpur);
+ return (*fParameters)(3,effpur) ;
+
+}
+//_____________________________________________________________________________
+const Float_t AliPHOSPIDv1::GetDistance(AliPHOSEmcRecPoint * emc,AliPHOSRecPoint * cpv, Option_t * Axis)const
+{
+ // Calculates the distance between the EMC RecPoint and the PPSD RecPoint
+
+ const AliPHOSGeometry * geom = AliPHOSGetter::GetInstance()->PHOSGeometry() ;
+ TVector3 vecEmc ;
+ TVector3 vecCpv ;
+ if(cpv){
+ emc->GetLocalPosition(vecEmc) ;
+ cpv->GetLocalPosition(vecCpv) ;
+ if(emc->GetPHOSMod() == cpv->GetPHOSMod()){
+ // Correct to difference in CPV and EMC position due to different distance to center.
+ // we assume, that particle moves from center
+ Float_t dCPV = geom->GetIPtoOuterCoverDistance();
+ Float_t dEMC = geom->GetIPtoCrystalSurface() ;
+ dEMC = dEMC / dCPV ;
+ vecCpv = dEMC * vecCpv - vecEmc ;
+ if (Axis == "X") return vecCpv.X();
+ if (Axis == "Y") return vecCpv.Y();
+ if (Axis == "Z") return vecCpv.Z();
+ if (Axis == "R") return vecCpv.Mag();
+ }
+
+ return 100000000 ;
+ }
+ return 100000000 ;
+}
+//____________________________________________________________________________
+const Int_t AliPHOSPIDv1::GetCPVBit(AliPHOSEmcRecPoint * emc,AliPHOSRecPoint * cpv,const Int_t EffPur, const Float_t e) const
+{
+ // return 1 if a combination of EMC and CPV is neutral rec.points matches a neutral particle
+ // return 0 otherwise
+ if(EffPur>2 || EffPur<0)
+ Error("GetCPVBit","Invalid Efficiency-Purity choice %d",EffPur);
+
+ Float_t sigX = GetCpvtoEmcDistanceCut(e,"X");
+ Float_t sigZ = GetCpvtoEmcDistanceCut(e,"Z");
+
+ Float_t deltaX = TMath::Abs(GetDistance(emc, cpv, "X"));
+ Float_t deltaZ = TMath::Abs(GetDistance(emc, cpv, "Z"));
+
+ if((deltaX>sigX*(EffPur+1)) || (deltaZ>sigZ*(EffPur+1)))
+ return 1;//Neutral
+ else
+ return 0;//Charged
+
+}
+
+//____________________________________________________________________________
+const Double_t AliPHOSPIDv1::GetCalibratedEnergy(const Float_t e) const
+{
+// It calibrates Energy depending on the recpoint energy.
+// The energy of the reconstructed cluster is corrected with
+// the formula A + B* E + C* E^2, whose parameters where obtained
+// through the study of the reconstructed energy distribution of
+// monoenergetic photons.
+
+ Double_t p[]={0.,0.,0.};
+ Int_t i;
+ for(i=0;i<3;i++) p[i]= (*fParameters)(0,i);
+ Double_t enerec = p[0] + p[1]* e+ p[2] * e * e;
+ return enerec ;
+
+}
+//____________________________________________________________________________
+const Int_t AliPHOSPIDv1::GetPrincipalBit(const Double_t* p ,const Int_t effpur, const Float_t e)const
+{
+ //Is the particle inside de PCA ellipse?
+
+ Int_t prinbit = 0 ;
+ Double_t a = GetEllipseParameter("a", e);
+ Double_t b = GetEllipseParameter("b", e);
+ Double_t c = GetEllipseParameter("c", e);
+ Double_t xCenter = GetEllipseParameter("x0", e);
+ Double_t yCenter = GetEllipseParameter("y0", e);
+
+ Double_t r = TMath::Power((p[0] - xCenter)/a,2) +
+ TMath::Power((p[1] - yCenter)/b,2) +
+ c*(p[0] - xCenter)*(p[1] - yCenter)/(a*b) ;
+ //3 different ellipses defined
+ if((effpur==2)&&(r <1./2.)) prinbit= 1;
+ if((effpur==1)&&(r <2. )) prinbit= 1;
+ if((effpur==0)&&(r <9./2.)) prinbit= 1;
+
+ if(r<0)
+ Error("GetPrincipalBit", "Negative square? R=%f \n",r) ;
+
+ return prinbit;
+
+}
+//____________________________________________________________________________
+const Int_t AliPHOSPIDv1::GetPrincipalPi0Bit(const Double_t* p, const Int_t effpur, const Float_t e)const
+{
+ //Is the particle inside de Pi0 PCA ellipse?
+
+ Int_t prinbit = 0 ;
+ Double_t a = GetEllipseParameterPi0("a", e);
+ Double_t b = GetEllipseParameterPi0("b", e);
+ Double_t c = GetEllipseParameterPi0("c", e);
+ Double_t xCenter = GetEllipseParameterPi0("x0", e);
+ Double_t yCenter = GetEllipseParameterPi0("y0", e);
+
+ Double_t r = TMath::Power((p[0] - xCenter)/a,2) +
+ TMath::Power((p[1] - yCenter)/b,2) +
+ c*(p[0] - xCenter)*(p[1] - yCenter)/(a*b) ;
+ //3 different ellipses defined
+ if((effpur==2)&&(r <1./2.)) prinbit= 1;
+ if((effpur==1)&&(r <2. )) prinbit= 1;
+ if((effpur==0)&&(r <9./2.)) prinbit= 1;
+
+ if(r<0)
+ Error("GetPrincipalPi0Bit", "Negative square?") ;
+
+ return prinbit;
+
+}
+//_____________________________________________________________________________
+void AliPHOSPIDv1::SetCpvtoEmcDistanceCutParameters(Float_t e, Int_t effpur, TString Axis,Float_t cut)
+{
+ // Set the parameters to calculate Cpvto EmcDistanceCut depending on the cluster energy and
+ // Purity-Efficiency point
+
+ if(effpur>2 || effpur<0)
+ Error("SetCpvtoEmcDistanceCutParameters","Invalid Efficiency-Purity choice %d",effpur);
+
+ Int_t i = -1;
+ if (Axis.Contains("X")) i = 1;
+ else if(Axis.Contains("Z")) i = 2;
+ else
+ Error("SetCpvtoEmcDistanceCutParameters"," Invalid axis option");
+
+ (*fParameters)(i,effpur) = cut ;
+}
+//_____________________________________________________________________________
+void AliPHOSPIDv1::SetTimeGate(Int_t effpur, Float_t gate)
+{
+ // Set the parameter TimeGate depending on the cluster energy and
+ // Purity-Efficiency point
+ if(effpur>2 || effpur<0)
+ Error("SetTimeGate","Invalid Efficiency-Purity choice %d",effpur);
+
+ (*fParameters)(3,effpur)= gate ;
+}
+//_____________________________________________________________________________
+void AliPHOSPIDv1::SetParameters()
+{
+ // PCA : To do the Principal Components Analysis it is necessary
+ // the Principal file, which is opened here
+ fX = new double[7]; // Data for the PCA
+ fP = new double[7]; // Eigenvalues of the PCA
+ fPPi0 = new double[7]; // Eigenvalues of the Pi0 PCA
+
+ // Read photon principals from the photon file
+
+ fFileName = "$ALICE_ROOT/PHOS/PCA8pa15_0.5-100.root" ;
+ TFile f( fFileName.Data(), "read" ) ;
+ fPrincipal = dynamic_cast<TPrincipal*> (f.Get("principal")) ;
+ f.Close() ;
+
+ // Read pi0 principals from the pi0 file
+
+ fFileNamePi0 = "$ALICE_ROOT/PHOS/PCA_pi0_40-120.root" ;
+ TFile fPi0( fFileNamePi0.Data(), "read" ) ;
+ fPrincipalPi0 = dynamic_cast<TPrincipal*> (fPi0.Get("principal")) ;
+ fPi0.Close() ;
+
+ // Open parameters file and initialization of the Parameters matrix.
+ // In the File Parameters.dat are all the parameters. These are introduced
+ // in a matrix of 9x4
+ //
+ // All the parameters defined in this file are, in order of row:
+ // -CpvtoEmcDistanceCut (2 row (x and z) and 3 columns, each one depending
+ // on the parameter of the funtion that sets the cut in x or z.
+ // -TimeGate, 1 row and 3 columns (3 efficiency-purty cuts)
+ // -PCA, parameters of the functions that
+ // calculate the ellipse parameters, x0,y0,a, b, c. These 5 parameters
+ // (5 rows) depend on 4 parameters (columns).
+ // -Finally there is a row with the energy calibration parameters,
+ // 3 parameters.
+
+ fFileNamePar = gSystem->ExpandPathName("$ALICE_ROOT/PHOS/Parameters.dat");
+ fParameters = new TMatrixD(14,4) ;
+ const Int_t kmaxLeng=255;
+ char string[kmaxLeng];
+
+ // Open a text file with PID parameters
+ FILE *fd = fopen(fFileNamePar.Data(),"r");
+ if (!fd)
+ Fatal("SetParameter","File %s with a PID parameters cannot be opened\n",
+ fFileNamePar.Data());
+
+ Int_t i=0;
+ // Read parameter file line-by-line and skip empty line and comments
+ while (fgets(string,kmaxLeng,fd) != NULL) {
+ if (string[0] == '\n' ) continue;
+ if (string[0] == '!' ) continue;
+ sscanf(string, "%lf %lf %lf %lf",
+ &(*fParameters)(i,0), &(*fParameters)(i,1),
+ &(*fParameters)(i,2), &(*fParameters)(i,3));
+ i++;
+ }
+ fclose(fd);
+}
+
+
+//________________________________________________________________________
+void AliPHOSPIDv1::SetEllipseParameter(TString Param, Int_t i, Double_t par)
+{
+ // Set the parameter "i" that is needed to calculate the ellipse
+ // parameter "Param".
+
+ Int_t p= -1;
+ if (Param.Contains("a")) p=4;
+ else if(Param.Contains("b")) p=5;
+ else if(Param.Contains("c")) p=6;
+ else if(Param.Contains("x0"))p=7;
+ else if(Param.Contains("y0"))p=8;
+ if((i>4)||(i<0))
+ Error("SetEllipseParameter", "No parameter with index %d", i) ;
+ else if(p==-1)
+ Error("SetEllipseParameter", "No parameter with name %s", Param.Data() ) ;
+ else
+ (*fParameters)(p,i) = par ;
+}
+//________________________________________________________________________
+void AliPHOSPIDv1::SetEllipseParameterPi0(TString Param, Int_t i, Double_t par)
+{
+ // Set the parameter "i" that is needed to calculate the ellipse
+ // parameter "Param".
+ if(!fPi0Analysis) Error("SetPi0EllipseParameter", "Pi 0 Analysis is off") ;
+ Int_t p= -1;
+ if (Param.Contains("a")) p=9;
+ else if(Param.Contains("b")) p=10;
+ else if(Param.Contains("c")) p=11;
+ else if(Param.Contains("x0"))p=12;
+ else if(Param.Contains("y0"))p=13;
+ if((i>4)||(i<0))
+ Error("SetPi0EllipseParameter", "No parameter with index %d", i) ;
+ else if(p==-1)
+ Error("SetPi0EllipseParameter", "No parameter with name %s", Param.Data() ) ;
+ else
+ (*fParameters)(p,i) = par ;
+}
+//________________________________________________________________________
+const Double_t AliPHOSPIDv1::GetParameterToCalculateEllipse(const TString Param, const Int_t i) const
+{
+ // Get the parameter "i" that is needed to calculate the ellipse
+ // parameter "Param".
+
+ Int_t p= -1;
+ Double_t par = -1;
+
+ if (Param.Contains("a")) p=4;
+ else if(Param.Contains("b")) p=5;
+ else if(Param.Contains("c")) p=6;
+ else if(Param.Contains("x0"))p=7;
+ else if(Param.Contains("y0"))p=8;
+
+ if((i>4)||(i<0))
+ Error("GetParameterToCalculateEllipse", "No parameter with index", i) ;
+ else if(p==-1)
+ Error("GetParameterToCalculateEllipse", "No parameter with name %s", Param.Data() ) ;
+ else
+ par = (*fParameters)(p,i) ;
+
+ return par;
+
+}
+//____________________________________________________________________________
+const Double_t AliPHOSPIDv1::GetParameterToCalculatePi0Ellipse(const TString Param, const Int_t i) const
+{
+ // Get the parameter "i" that is needed to calculate the ellipse
+ // parameter "Param".
+
+ if(!fPi0Analysis) Error("GetParameterToCalculatePi0Ellipse", "Pi 0 Analysis is off") ;
+
+ Int_t p= -1;
+ Double_t par = -1;
+
+ if(Param.Contains("a")) p=9;
+ if(Param.Contains("b")) p=10;
+ if(Param.Contains("c")) p=11;
+ if(Param.Contains("x0"))p=12;
+ if(Param.Contains("y0"))p=13;
+
+ if((i>4)||(i<0))
+ Error("GetParameterToCalculatePi0Ellipse", "No parameter with index", i) ;
+ else if(p==-1)
+ Error("GetParameterToCalculatePi0Ellipse", "No parameter with name %s", Param.Data() ) ;
+ else
+ par = (*fParameters)(p,i) ;
+
+ return par;
+
+}
+//____________________________________________________________________________
+void AliPHOSPIDv1::SetCalibrationParameter(Int_t i,Double_t param) const
+{
+ (*fParameters)(0,i) = param ;
+}
+//____________________________________________________________________________
+const Double_t AliPHOSPIDv1::GetCalibrationParameter(const Int_t i) const
+{
+ Float_t param = (*fParameters)(0,i);
+ return param;
}
+//____________________________________________________________________________
+const Double_t AliPHOSPIDv1::GetEllipseParameter(const TString Param,Float_t E) const
+{
+ // Calculates the parameter Param of the ellipse
+
+ Double_t p[4]={0.,0.,0.,0.};
+ Double_t value = 0.0;
+ Int_t i;
+ if(Param.Contains("a")){
+ for(i=0;i<4;i++)p[i]=(*fParameters)(4,i);
+ if(E>70.)E=70.;
+ }
+
+ else if(Param.Contains("b")){
+ for(i=0;i<4;i++)p[i]=(*fParameters)(5,i);
+ if(E>70.)E=70.;
+ }
+
+ else if(Param.Contains("c"))
+ for(i=0;i<4;i++)p[i]=(*fParameters)(6,i);
+
+ else if(Param.Contains("x0")){
+ for(i=0;i<4;i++)p[i]=(*fParameters)(7,i);
+ if(E<1.)E=1.1;
+ }
+ else if(Param.Contains("y0"))
+ for(i=0;i<4;i++)p[i]=(*fParameters)(8,i);
+
+ value = p[0]/TMath::Sqrt(E)+p[1]*E+p[2]*E*E+p[3];
+ return value;
+}
+
+//____________________________________________________________________________
+// const Double_t AliPHOSPIDv1::GetEllipseParameter(const TString Param,Float_t E) const
+// {
+// // Calculates the parameter Param of the pi0 ellipse
+
+// Double_t p[3] = {0.,0.,0.};
+// Double_t value = 0.0;
+// Int_t i;
+
+// if(Param.Contains("a"))
+// for(i=0;i<3;i++)p[i]=(*fParameters)(4,i);
+// else if(Param.Contains("b"))
+// for(i=0;i<3;i++)p[i]=(*fParameters)(5,i);
+// else if(Param.Contains("c"))
+// for(i=0;i<3;i++)p[i]=(*fParameters)(6,i);
+// else if(Param.Contains("x0"))
+// for(i=0;i<3;i++)p[i]=(*fParameters)(7,i);
+// else if(Param.Contains("y0"))
+// for(i=0;i<3;i++)p[i]=(*fParameters)(8,i);
+
+// value = p[0] + p[1]*E + p[2]*E*E;
+// return value;
+// }
+//____________________________________________________________________________
+const Double_t AliPHOSPIDv1::GetEllipseParameterPi0(const TString Param,Float_t E) const
+{
+ // Calculates the parameter Param of the pi0 ellipse
+
+ Double_t p[3] = {0.,0.,0.};
+ Double_t value = 0.0;
+ Int_t i;
+ if(Param.Contains("a"))
+ for(i=0;i<3;i++)p[i]=(*fParameters)(9,i);
+ else if(Param.Contains("b"))
+ for(i=0;i<3;i++)p[i]=(*fParameters)(10,i);
+ else if(Param.Contains("c"))
+ for(i=0;i<3;i++)p[i]=(*fParameters)(11,i);
+ else if(Param.Contains("x0"))
+ for(i=0;i<3;i++)p[i]=(*fParameters)(12,i);
+ else if(Param.Contains("y0"))
+ for(i=0;i<3;i++)p[i]=(*fParameters)(13,i);
+
+ value = p[0] + p[1]*E + p[2]*E*E;
+ return value;
+}
//____________________________________________________________________________
-void AliPHOSPIDv1::GetParticleType(TrackSegmentsList * trsl, RecParticlesList * rpl)
+
+void AliPHOSPIDv1::Exec(Option_t * option)
{
- // main function, does the job
+ //Steering method
+
+ if( strcmp(GetName(), "")== 0 )
+ Init() ;
+
+ if(strstr(option,"tim"))
+ gBenchmark->Start("PHOSPID");
+
+ if(strstr(option,"print")) {
+ Print("") ;
+ return ;
+ }
- TIter next(trsl) ;
- AliPHOSTrackSegment * tracksegment ;
+
+ AliPHOSGetter * gime = AliPHOSGetter::GetInstance() ;
+ if(gime->BranchExists("RecParticles") )
+ return ;
+ Int_t nevents = gime->MaxEvent() ;
+ Int_t ievent ;
+
+ for(ievent = 0; ievent < nevents; ievent++){
+ gime->Event(ievent,"R") ;
+
+ if(gime->TrackSegments() && //Skip events, where no track segments made
+ gime->TrackSegments()->GetEntriesFast()) {
+ MakeRecParticles() ;
+ WriteRecParticles(ievent);
+ if(strstr(option,"deb"))
+ PrintRecParticles(option) ;
+ //increment the total number of rec particles per run
+ fRecParticlesInRun+=gime->RecParticles(BranchName())->GetEntriesFast() ;
+ }
+ }
+
+ if(strstr(option,"tim")){
+ gBenchmark->Stop("PHOSPID");
+ Info("Exec", "took %f seconds for PID %f seconds per event",
+ gBenchmark->GetCpuTime("PHOSPID"),
+ gBenchmark->GetCpuTime("PHOSPID")/nevents) ;
+ }
+}
+
+//____________________________________________________________________________
+void AliPHOSPIDv1::MakeRecParticles(){
+
+ // Makes a RecParticle out of a TrackSegment
+
+ AliPHOSGetter * gime = AliPHOSGetter::GetInstance() ;
+ TObjArray * emcRecPoints = gime->EmcRecPoints() ;
+ TObjArray * cpvRecPoints = gime->CpvRecPoints() ;
+ TClonesArray * trackSegments = gime->TrackSegments() ;
+ if ( !emcRecPoints || !cpvRecPoints || !trackSegments ) {
+ Fatal("MakeRecParticles", "RecPoints or TrackSegments not found !") ;
+ }
+ TClonesArray * recParticles = gime->RecParticles() ;
+ recParticles->Clear();
+
+ TIter next(trackSegments) ;
+ AliPHOSTrackSegment * ts ;
Int_t index = 0 ;
AliPHOSRecParticle * rp ;
- while ( (tracksegment = (AliPHOSTrackSegment *)next()) ) {
- new( (*rpl)[index] ) AliPHOSRecParticle(tracksegment) ;
- rp = (AliPHOSRecParticle *)(*rpl)[index] ;
- Int_t type = rp->GetType() ;
- if ( type == kNEUTRAL ) { // resolve neutral baryon from photon
- AliPHOSEmcRecPoint * recp = tracksegment->GetEmcRecPoint() ;
- Float_t * lambda = new Float_t[2];
- recp->GetElipsAxis(lambda) ;
- if ( ( lambda[0] > fLambda1m && lambda[0] < fLambda1M ) && // shower profile cut
- ( lambda[1] > fLambda2m && lambda[1] < fLambda2M ) )
- type = kNEUTRALEM ;
- else
- type = kNEUTRALHADRON ;
- delete lambda ;
- }
- if (type == kCHARGED) {
- if( tracksegment->GetEmcRecPoint()->GetDispersion() > fCutOnDispersion) // shower dispersion cut
- type = kCHARGEDHADRON ;
- else
- type = kELECTRON ;
- }
- rp->SetType(type) ;
+ while ( (ts = (AliPHOSTrackSegment *)next()) ) {
+
+ new( (*recParticles)[index] ) AliPHOSRecParticle() ;
+ rp = (AliPHOSRecParticle *)recParticles->At(index) ;
+ rp->SetTrackSegment(index) ;
+ rp->SetIndexInList(index) ;
+
+ AliPHOSEmcRecPoint * emc = 0 ;
+ if(ts->GetEmcIndex()>=0)
+ emc = (AliPHOSEmcRecPoint *) emcRecPoints->At(ts->GetEmcIndex()) ;
+
+ AliPHOSRecPoint * cpv = 0 ;
+ if(ts->GetCpvIndex()>=0)
+ cpv = (AliPHOSRecPoint *) cpvRecPoints->At(ts->GetCpvIndex()) ;
+
+ // Now set type (reconstructed) of the particle
+
+ // Choose the cluster energy range
+
+ if (!emc) {
+ Fatal("MakeRecParticles", "-> emc(%d) = %d", ts->GetEmcIndex(), emc ) ;
+ }
+
+ Float_t e = emc->GetEnergy() ;
+
+ Float_t lambda[2] ;
+ emc->GetElipsAxis(lambda) ;
+
+ if((lambda[0]>0.01) && (lambda[1]>0.01)){
+ // Looking PCA. Define and calculate the data (X),
+ // introduce in the function X2P that gives the components (P).
+
+ Float_t spher = 0. ;
+ Float_t emaxdTotal = 0. ;
+
+ if((lambda[0]+lambda[1])!=0)
+ spher=fabs(lambda[0]-lambda[1])/(lambda[0]+lambda[1]);
+
+ emaxdTotal=emc->GetMaximalEnergy()/emc->GetEnergy();
+
+ fX[0] = lambda[0] ;
+ fX[1] = lambda[1] ;
+ fX[2] = emc->GetDispersion() ;
+ fX[3] = spher ;
+ fX[4] = emc->GetMultiplicity() ;
+ fX[5] = emaxdTotal ;
+ fX[6] = emc->GetCoreEnergy() ;
+
+ fPrincipal->X2P(fX,fP);
+ if(fPi0Analysis)
+ fPrincipalPi0->X2P(fX,fPPi0);
+
+ }
+ else{
+ fP[0]=-100.0; //We do not accept clusters with
+ fP[1]=-100.0; //one cell as a photon-like
+ if(fPi0Analysis){
+ fPPi0[0]=-100.0;
+ fPPi0[1]=-100.0;
+ }
+ }
+
+ Float_t time =emc->GetTime() ;
+
+ // Loop of Efficiency-Purity (the 3 points of purity or efficiency
+ // are taken into account to set the particle identification)
+ for(Int_t eff_pur = 0; eff_pur < 3 ; eff_pur++){
+
+ // Looking at the CPV detector. If RCPV greater than CpvEmcDistance,
+ // 1st,2nd or 3rd bit (depending on the efficiency-purity point )
+ // is set to 1
+ if(GetCPVBit(emc, cpv, eff_pur,e) == 1 )
+ rp->SetPIDBit(eff_pur) ;
+
+ // Looking the TOF. If TOF smaller than gate, 4th, 5th or 6th
+ // bit (depending on the efficiency-purity point )is set to 1
+ if(time< (*fParameters)(2,eff_pur))
+ rp->SetPIDBit(eff_pur+3) ;
+
+ //If we are inside the ellipse, 7th, 8th or 9th
+ // bit (depending on the efficiency-purity point )is set to 1
+ if(GetPrincipalBit(fP,eff_pur,e) == 1)
+ rp->SetPIDBit(eff_pur+6) ;
+
+ //Pi0 analysis
+ //If we are inside the ellipse, 10th, 11th or 12th
+ // bit (depending on the efficiency-purity point )is set to 1
+ if(fPi0Analysis){
+ if(GetPrincipalPi0Bit(fPPi0,eff_pur,e) == 1)
+ rp->SetPIDBit(eff_pur+9) ;
+ }
+ }
+
+
+ //Set momentum, energy and other parameters
+ Float_t encal = GetCalibratedEnergy(e);
+ TVector3 dir = GetMomentumDirection(emc,cpv) ;
+ dir.SetMag(encal) ;
+ rp->SetMomentum(dir.X(),dir.Y(),dir.Z(),encal) ;
+ rp->SetCalcMass(0);
+ rp->Name(); //If photon sets the particle pdg name to gamma
+ rp->SetProductionVertex(0,0,0,0);
+ rp->SetFirstMother(-1);
+ rp->SetLastMother(-1);
+ rp->SetFirstDaughter(-1);
+ rp->SetLastDaughter(-1);
+ rp->SetPolarisation(0,0,0);
index++ ;
}
-
+
}
//____________________________________________________________________________
-void AliPHOSPIDv1:: Print()
+void AliPHOSPIDv1::Print()
{
- cout << "AliPHOSPIDv1 : cuts for the particle idendification based on the shower profile " << endl
- << fLambda1m << " < value1 < " << fLambda1M << endl
- << fLambda2m << " < value2 < " << fLambda2M << endl ;
+ // Print the parameters used for the particle type identification
+ TString message ;
+ message = "\n=============== AliPHOSPID1 ================\n" ;
+ message += "Making PID\n";
+ message += " Pricipal analysis file from 0.5 to 100 %s\n" ;
+ message += " Name of parameters file %s\n" ;
+ message += " Matrix of Parameters: 14x4\n" ;
+ message += " Energy Calibration 1x3 [3 parametres to calibrate energy: A + B* E + C * E^2]\n" ;
+ message += " RCPV 2x3 rows x and z, columns function cut parameters\n" ;
+ message += " TOF 1x3 [High Eff-Low Pur,Medium Eff-Pur, Low Eff-High Pur]\n" ;
+ message += " PCA 5x4 [5 ellipse parametres and 4 parametres to calculate them: A/Sqrt(E) + B* E + C * E^2 + D]\n" ;
+ message += " Pi0 PCA 5x3 [5 ellipse parametres and 3 parametres to calculate them: A + B* E + C * E^2]\n" ;
+ Info("Print", message.Data(), fFileName.Data(), fFileNamePar.Data() ) ;
+ fParameters->Print() ;
}
//____________________________________________________________________________
-void AliPHOSPIDv1::SetShowerProfileCuts(Float_t l1m, Float_t l1M, Float_t l2m, Float_t l2M)
+void AliPHOSPIDv1::WriteRecParticles(Int_t event)
{
- fLambda1m = l1m ;
- fLambda1M = l1M ;
- fLambda2m = l2m ;
- fLambda2M = l2M ;
+ // writes the reconstructed particles to file
+ AliPHOSGetter *gime = AliPHOSGetter::GetInstance() ;
+
+ TClonesArray * recParticles = gime->RecParticles() ;
+ recParticles->Expand(recParticles->GetEntriesFast() ) ;
+ TTree * treeR ;
+
+ if(fToSplit){
+ if(!fSplitFile)
+ return ;
+ fSplitFile->cd() ;
+ char name[10] ;
+ sprintf(name,"%s%d", "TreeR",event) ;
+ treeR = dynamic_cast<TTree*>(fSplitFile->Get(name));
+ }
+ else{
+ treeR = gAlice->TreeR();
+ }
+
+ if(!treeR){
+ gAlice->MakeTree("R", fSplitFile);
+ treeR = gAlice->TreeR() ;
+ }
+
+ //First rp
+ Int_t bufferSize = 32000 ;
+ TBranch * rpBranch = treeR->Branch("PHOSRP",&recParticles,bufferSize);
+ rpBranch->SetTitle(BranchName());
+
+
+ //second, pid
+ Int_t splitlevel = 0 ;
+ AliPHOSPIDv1 * pid = this ;
+ TBranch * pidBranch = treeR->Branch("AliPHOSPID","AliPHOSPIDv1",&pid,bufferSize,splitlevel);
+ pidBranch->SetTitle(BranchName());
+
+ rpBranch->Fill() ;
+ pidBranch->Fill() ;
+
+ treeR->AutoSave() ; //Write(0,kOverwrite) ;
+ if(gAlice->TreeR()!=treeR){
+ treeR->Delete();
+ }
}
+
+//____________________________________________________________________________
+TVector3 AliPHOSPIDv1::GetMomentumDirection(AliPHOSEmcRecPoint * emc, AliPHOSRecPoint * cpv)const
+{
+ // Calculates the momentum direction:
+ // 1. if only a EMC RecPoint, direction is given by IP and this RecPoint
+ // 2. if a EMC RecPoint and CPV RecPoint, direction is given by the line through the 2 recpoints
+ // However because of the poor position resolution of PPSD the direction is always taken as if we were
+ // in case 1.
+
+ TVector3 dir(0,0,0) ;
+
+ TVector3 emcglobalpos ;
+ TMatrix dummy ;
+
+ emc->GetGlobalPosition(emcglobalpos, dummy) ;
+
+ dir = emcglobalpos ;
+ dir.SetZ( -dir.Z() ) ; // why ?
+
+ //account correction to the position of IP
+ Float_t xo,yo,zo ; //Coordinates of the origin
+ gAlice->Generator()->GetOrigin(xo,yo,zo) ;
+ TVector3 origin(xo,yo,zo);
+ dir = dir - origin ;
+ dir.SetMag(1.) ;
+ return dir ;
+}
+//____________________________________________________________________________
+void AliPHOSPIDv1::PrintRecParticles(Option_t * option)
+{
+ // Print table of reconstructed particles
+
+ AliPHOSGetter *gime = AliPHOSGetter::GetInstance() ;
+
+ TClonesArray * recParticles = gime->RecParticles(BranchName()) ;
+
+ TString message ;
+ message = "\nevent " ;
+ message += gAlice->GetEvNumber() ;
+ message += " found " ;
+ message += recParticles->GetEntriesFast();
+ message += " RecParticles\n" ;
+
+ if(strstr(option,"all")) { // printing found TS
+ message += "\n PARTICLE Index \n" ;
+
+ Int_t index ;
+ for (index = 0 ; index < recParticles->GetEntries() ; index++) {
+ AliPHOSRecParticle * rp = (AliPHOSRecParticle * ) recParticles->At(index) ;
+ message += "\n" ;
+ message += rp->Name().Data() ;
+ message += " " ;
+ message += rp->GetIndexInList() ;
+ message += " " ;
+ message += rp->GetType() ;
+ }
+ }
+ Info("Print", message.Data() ) ;
+}
+
+
+