/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$ */ //_________________________________________________________________________ // RecPoint implementation for PHOS-EMC // An EmcRecPoint is a cluster of digits //*-- //*-- Author: Dmitri Peressounko (RRC KI & SUBATECH) // --- ROOT system --- #include "TH2.h" #include "TMath.h" #include "TCanvas.h" #include "TGraph.h" // --- Standard library --- // --- AliRoot header files --- #include "AliPHOSLoader.h" #include "AliGenerator.h" #include "AliPHOSGeometry.h" #include "AliPHOSDigit.h" #include "AliPHOSEmcRecPoint.h" ClassImp(AliPHOSEmcRecPoint) //____________________________________________________________________________ AliPHOSEmcRecPoint::AliPHOSEmcRecPoint() : AliPHOSRecPoint() { // ctor fMulDigit = 0 ; fAmp = 0. ; fCoreEnergy = 0 ; fEnergyList = 0 ; fNExMax = 0 ; //Not unfolded yet fTime = -1. ; fLocPos.SetX(1000000.) ; //Local position should be evaluated fDebug=0; } //____________________________________________________________________________ AliPHOSEmcRecPoint::AliPHOSEmcRecPoint(const char * opt) : AliPHOSRecPoint(opt) { // ctor fMulDigit = 0 ; fAmp = 0. ; fNExMax = 0 ; //Not unfolded yet fCoreEnergy = 0 ; fEnergyList = 0 ; fTime = -1. ; fLocPos.SetX(1000000.) ; //Local position should be evaluated fDebug=0; } //____________________________________________________________________________ AliPHOSEmcRecPoint::AliPHOSEmcRecPoint(const AliPHOSEmcRecPoint & rp) : AliPHOSRecPoint(rp) { // cpy ctor fMulDigit = rp.fMulDigit ; fAmp = rp.fAmp ; fCoreEnergy = rp.fCoreEnergy ; fEnergyList = new Float_t[rp.fMulDigit] ; Int_t index ; for(index = 0 ; index < fMulDigit ; index++) fEnergyList[index] = rp.fEnergyList[index] ; fNExMax = rp.fNExMax ; fTime = rp.fTime ; } //____________________________________________________________________________ AliPHOSEmcRecPoint::~AliPHOSEmcRecPoint() { // dtor if ( fEnergyList ) delete[] fEnergyList ; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::AddDigit(AliPHOSDigit & digit, Float_t Energy) { // Adds a digit to the RecPoint // and accumulates the total amplitude and the multiplicity if(fEnergyList == 0) fEnergyList = new Float_t[fMaxDigit]; if ( fMulDigit >= fMaxDigit ) { // increase the size of the lists fMaxDigit*=2 ; Int_t * tempo = new Int_t[fMaxDigit]; Float_t * tempoE = new Float_t[fMaxDigit]; Int_t index ; for ( index = 0 ; index < fMulDigit ; index++ ){ tempo[index] = fDigitsList[index] ; tempoE[index] = fEnergyList[index] ; } delete [] fDigitsList ; fDigitsList = new Int_t[fMaxDigit]; delete [] fEnergyList ; fEnergyList = new Float_t[fMaxDigit]; for ( index = 0 ; index < fMulDigit ; index++ ){ fDigitsList[index] = tempo[index] ; fEnergyList[index] = tempoE[index] ; } delete [] tempo ; delete [] tempoE ; } // if fDigitsList[fMulDigit] = digit.GetIndexInList() ; fEnergyList[fMulDigit] = Energy ; fMulDigit++ ; fAmp += Energy ; EvalPHOSMod(&digit) ; } //____________________________________________________________________________ Bool_t AliPHOSEmcRecPoint::AreNeighbours(AliPHOSDigit * digit1, AliPHOSDigit * digit2 ) const { // Tells if (true) or not (false) two digits are neighbors Bool_t aren = kFALSE ; AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); Int_t relid1[4] ; phosgeom->AbsToRelNumbering(digit1->GetId(), relid1) ; Int_t relid2[4] ; phosgeom->AbsToRelNumbering(digit2->GetId(), relid2) ; Int_t rowdiff = TMath::Abs( relid1[2] - relid2[2] ) ; Int_t coldiff = TMath::Abs( relid1[3] - relid2[3] ) ; if (( coldiff <= 1 ) && ( rowdiff <= 1 ) && (coldiff + rowdiff > 0)) aren = kTRUE ; return aren ; } //____________________________________________________________________________ Int_t AliPHOSEmcRecPoint::Compare(const TObject * obj) const { // Compares two RecPoints according to their position in the PHOS modules Float_t delta = 1 ; //Width of "Sorting row". If you changibg this //value (what is senseless) change as vell delta in //AliPHOSTrackSegmentMakerv* and other RecPoints... Int_t rv ; AliPHOSEmcRecPoint * clu = (AliPHOSEmcRecPoint *)obj ; Int_t phosmod1 = GetPHOSMod() ; Int_t phosmod2 = clu->GetPHOSMod() ; TVector3 locpos1; GetLocalPosition(locpos1) ; TVector3 locpos2; clu->GetLocalPosition(locpos2) ; if(phosmod1 == phosmod2 ) { Int_t rowdif = (Int_t)TMath::Ceil(locpos1.X()/delta)-(Int_t)TMath::Ceil(locpos2.X()/delta) ; if (rowdif> 0) rv = 1 ; else if(rowdif < 0) rv = -1 ; else if(locpos1.Z()>locpos2.Z()) rv = -1 ; else rv = 1 ; } else { if(phosmod1 < phosmod2 ) rv = -1 ; else rv = 1 ; } return rv ; } //______________________________________________________________________________ void AliPHOSEmcRecPoint::ExecuteEvent(Int_t event, Int_t, Int_t) const { // Execute action corresponding to one event // This member function is called when a AliPHOSRecPoint is clicked with the locator // // If Left button is clicked on AliPHOSRecPoint, the digits are switched on // and switched off when the mouse button is released. AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); static TGraph * digitgraph = 0 ; if (!gPad->IsEditable()) return; TH2F * histo = 0 ; TCanvas * histocanvas ; //try to get run loader from default event folder AliRunLoader* rn = AliRunLoader::GetRunLoader(AliConfig::GetDefaultEventFolderName()); if (rn == 0x0) { Error("ExecuteEvent","Can not find Run Loader in Default Event Folder"); return; } AliPHOSLoader* gime = dynamic_cast(rn->GetLoader("PHOSLoader")); if (gime == 0x0) { Error("ExecuteEvent","Can not find PHOS Loader from Run Loader"); return; } const TClonesArray * digits = gime->Digits() ; switch (event) { case kButton1Down: { AliPHOSDigit * digit ; Int_t iDigit; Int_t relid[4] ; const Int_t kMulDigit = AliPHOSEmcRecPoint::GetDigitsMultiplicity() ; Float_t * xi = new Float_t[kMulDigit] ; Float_t * zi = new Float_t[kMulDigit] ; // create the histogram for the single cluster // 1. gets histogram boundaries Float_t ximax = -999. ; Float_t zimax = -999. ; Float_t ximin = 999. ; Float_t zimin = 999. ; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi[iDigit], zi[iDigit]); if ( xi[iDigit] > ximax ) ximax = xi[iDigit] ; if ( xi[iDigit] < ximin ) ximin = xi[iDigit] ; if ( zi[iDigit] > zimax ) zimax = zi[iDigit] ; if ( zi[iDigit] < zimin ) zimin = zi[iDigit] ; } ximax += phosgeom->GetCrystalSize(0) / 2. ; zimax += phosgeom->GetCrystalSize(2) / 2. ; ximin -= phosgeom->GetCrystalSize(0) / 2. ; zimin -= phosgeom->GetCrystalSize(2) / 2. ; Int_t xdim = (int)( (ximax - ximin ) / phosgeom->GetCrystalSize(0) + 0.5 ) ; Int_t zdim = (int)( (zimax - zimin ) / phosgeom->GetCrystalSize(2) + 0.5 ) ; // 2. gets the histogram title Text_t title[100] ; sprintf(title,"Energy=%1.2f GeV ; Digits ; %d ", GetEnergy(), GetDigitsMultiplicity()) ; if (!histo) { delete histo ; histo = 0 ; } histo = new TH2F("cluster3D", title, xdim, ximin, ximax, zdim, zimin, zimax) ; Float_t x, z ; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, x, z); histo->Fill(x, z, fEnergyList[iDigit] ) ; } if (!digitgraph) { digitgraph = new TGraph(kMulDigit,xi,zi); digitgraph-> SetMarkerStyle(5) ; digitgraph-> SetMarkerSize(1.) ; digitgraph-> SetMarkerColor(1) ; digitgraph-> Paint("P") ; } // Print() ; histocanvas = new TCanvas("cluster", "a single cluster", 600, 500) ; histocanvas->Draw() ; histo->Draw("lego1") ; delete[] xi ; delete[] zi ; break; } case kButton1Up: if (digitgraph) { delete digitgraph ; digitgraph = 0 ; } break; } } //____________________________________________________________________________ void AliPHOSEmcRecPoint::EvalDispersion(Float_t logWeight,TClonesArray * digits) { // Calculates the dispersion of the shower at the origine of the RecPoint Float_t d = 0. ; Float_t wtot = 0. ; Float_t x = 0.; Float_t z = 0.; AliPHOSDigit * digit ; AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); // Calculates the center of gravity in the local PHOS-module coordinates Int_t iDigit; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; Int_t relid[4] ; Float_t xi ; Float_t zi ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); Float_t w = TMath::Max( 0., logWeight + TMath::Log( fEnergyList[iDigit] / fAmp ) ) ; x += xi * w ; z += zi * w ; wtot += w ; } x /= wtot ; z /= wtot ; // Calculates the dispersion in coordinates wtot = 0.; for(iDigit=0; iDigit < fMulDigit; iDigit++) { digit = (AliPHOSDigit *) digits->At(fDigitsList[iDigit]) ; Int_t relid[4] ; Float_t xi ; Float_t zi ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); Float_t w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; d += w*((xi-x)*(xi-x) + (zi-z)*(zi-z) ) ; wtot+=w ; } d /= wtot ; fDispersion = TMath::Sqrt(d) ; } //______________________________________________________________________________ void AliPHOSEmcRecPoint::EvalCoreEnergy(Float_t logWeight, TClonesArray * digits) { // This function calculates energy in the core, // i.e. within a radius rad = 3cm around the center. Beyond this radius // in accordance with shower profile the energy deposition // should be less than 2% Float_t coreRadius = 3 ; Float_t x = 0 ; Float_t z = 0 ; AliPHOSDigit * digit ; AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); Int_t iDigit; // Calculates the center of gravity in the local PHOS-module coordinates Float_t wtot = 0; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; Int_t relid[4] ; Float_t xi ; Float_t zi ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); Float_t w = TMath::Max( 0., logWeight + TMath::Log( fEnergyList[iDigit] / fAmp ) ) ; x += xi * w ; z += zi * w ; wtot += w ; } x /= wtot ; z /= wtot ; for(iDigit=0; iDigit < fMulDigit; iDigit++) { digit = (AliPHOSDigit *) ( digits->At(fDigitsList[iDigit]) ) ; Int_t relid[4] ; Float_t xi ; Float_t zi ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); Float_t distance = TMath::Sqrt((xi-x)*(xi-x)+(zi-z)*(zi-z)) ; if(distance < coreRadius) fCoreEnergy += fEnergyList[iDigit] ; } } //____________________________________________________________________________ void AliPHOSEmcRecPoint::EvalElipsAxis(Float_t logWeight,TClonesArray * digits) { // Calculates the axis of the shower ellipsoid Double_t wtot = 0. ; Double_t x = 0.; Double_t z = 0.; Double_t dxx = 0.; Double_t dzz = 0.; Double_t dxz = 0.; AliPHOSDigit * digit ; AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); Int_t iDigit; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; Int_t relid[4] ; Float_t xi ; Float_t zi ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); Double_t w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; dxx += w * xi * xi ; x += w * xi ; dzz += w * zi * zi ; z += w * zi ; dxz += w * xi * zi ; wtot += w ; } dxx /= wtot ; x /= wtot ; dxx -= x * x ; dzz /= wtot ; z /= wtot ; dzz -= z * z ; dxz /= wtot ; dxz -= x * z ; // //Apply correction due to non-perpendicular incidence // Double_t CosX ; // Double_t CosZ ; // AliPHOSGetter * gime = AliPHOSGetter::Instance() ; // AliPHOSGeometry * phosgeom = (AliPHOSGeometry*)gime->PHOSGeometry(); // Double_t DistanceToIP= (Double_t ) phosgeom->GetIPtoCrystalSurface() ; // CosX = DistanceToIP/TMath::Sqrt(DistanceToIP*DistanceToIP+x*x) ; // CosZ = DistanceToIP/TMath::Sqrt(DistanceToIP*DistanceToIP+z*z) ; // dxx = dxx/(CosX*CosX) ; // dzz = dzz/(CosZ*CosZ) ; // dxz = dxz/(CosX*CosZ) ; fLambda[0] = 0.5 * (dxx + dzz) + TMath::Sqrt( 0.25 * (dxx - dzz) * (dxx - dzz) + dxz * dxz ) ; if(fLambda[0] > 0) fLambda[0] = TMath::Sqrt(fLambda[0]) ; fLambda[1] = 0.5 * (dxx + dzz) - TMath::Sqrt( 0.25 * (dxx - dzz) * (dxx - dzz) + dxz * dxz ) ; if(fLambda[1] > 0) //To avoid exception if numerical errors lead to negative lambda. fLambda[1] = TMath::Sqrt(fLambda[1]) ; else fLambda[1]= 0. ; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::EvalMoments(Float_t logWeight,TClonesArray * digits) { // Calculate the shower moments in the eigen reference system // M2x, M2z, M3x, M4z // Calculate the angle between the shower position vector and the eigen vector Double_t wtot = 0. ; Double_t x = 0.; Double_t z = 0.; Double_t dxx = 0.; Double_t dzz = 0.; Double_t dxz = 0.; Double_t lambda0=0, lambda1=0; AliPHOSDigit * digit ; AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); Int_t iDigit; // 1) Find covariance matrix elements: // || dxx dxz || // || dxz dzz || Float_t xi ; Float_t zi ; Int_t relid[4] ; Double_t w; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; x += w * xi ; z += w * zi ; dxx += w * xi * xi ; dzz += w * zi * zi ; dxz += w * xi * zi ; wtot += w ; } x /= wtot ; z /= wtot ; dxx /= wtot ; dzz /= wtot ; dxz /= wtot ; dxx -= x * x ; dzz -= z * z ; dxz -= x * z ; // 2) Find covariance matrix eigen values lambda0 and lambda1 lambda0 = 0.5 * (dxx + dzz) + TMath::Sqrt( 0.25 * (dxx - dzz) * (dxx - dzz) + dxz * dxz ) ; lambda1 = 0.5 * (dxx + dzz) - TMath::Sqrt( 0.25 * (dxx - dzz) * (dxx - dzz) + dxz * dxz ) ; // 3) Find covariance matrix eigen vectors e0 and e1 TVector2 e0,e1; if (dxz != 0) e0.Set(1.,(lambda0-dxx)/dxz); else e0.Set(0.,1.); e0 = e0.Unit(); e1.Set(-e0.Y(),e0.X()); // 4) Rotate cluster tensor from (x,z) to (e0,e1) system // and calculate moments M3x and M4z Float_t cosPhi = e0.X(); Float_t sinPhi = e0.Y(); Float_t xiPHOS ; Float_t ziPHOS ; Double_t dx3, dz3, dz4; wtot = 0.; x = 0.; z = 0.; dxx = 0.; dzz = 0.; dxz = 0.; dx3 = 0.; dz3 = 0.; dz4 = 0.; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xiPHOS, ziPHOS); xi = xiPHOS*cosPhi + ziPHOS*sinPhi; zi = ziPHOS*cosPhi - xiPHOS*sinPhi; w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; x += w * xi ; z += w * zi ; dxx += w * xi * xi ; dzz += w * zi * zi ; dxz += w * xi * zi ; dx3 += w * xi * xi * xi; dz3 += w * zi * zi * zi ; dz4 += w * zi * zi * zi * zi ; wtot += w ; } x /= wtot ; z /= wtot ; dxx /= wtot ; dzz /= wtot ; dxz /= wtot ; dx3 /= wtot ; dz3 /= wtot ; dz4 /= wtot ; dx3 += -3*dxx*x + 2*x*x*x; dz4 += -4*dz3*z + 6*dzz*z*z -3*z*z*z*z; dxx -= x * x ; dzz -= z * z ; dxz -= x * z ; // 5) Find an angle between cluster center vector and eigen vector e0 Float_t phi = TMath::ACos ((x*e0.X() + z*e0.Y()) / sqrt(x*x + z*z)); fM2x = lambda0; fM2z = lambda1; fM3x = dx3; fM4z = dz4; fPhixe = phi; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::EvalAll(Float_t logWeight, TClonesArray * digits ) { // Evaluates all shower parameters EvalLocalPosition(logWeight, digits) ; EvalElipsAxis(logWeight, digits) ; EvalMoments(logWeight, digits) ; EvalDispersion(logWeight, digits) ; EvalCoreEnergy(logWeight, digits); EvalTime(digits) ; AliPHOSRecPoint::EvalAll(digits) ; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::EvalLocalPosition(Float_t logWeight, TClonesArray * digits) { // Calculates the center of gravity in the local PHOS-module coordinates Float_t wtot = 0. ; Int_t relid[4] ; Float_t x = 0. ; Float_t z = 0. ; AliPHOSDigit * digit ; AliPHOSGeometry * phosgeom = AliPHOSLoader::GetPHOSGeometry(); Int_t iDigit; for(iDigit=0; iDigitAt(fDigitsList[iDigit]) ; Float_t xi ; Float_t zi ; phosgeom->AbsToRelNumbering(digit->GetId(), relid) ; phosgeom->RelPosInModule(relid, xi, zi); Float_t w = TMath::Max( 0., logWeight + TMath::Log( fEnergyList[iDigit] / fAmp ) ) ; x += xi * w ; z += zi * w ; wtot += w ; } x /= wtot ; z /= wtot ; // Correction for the depth of the shower starting point (TDR p 127) Float_t para = 0.925 ; Float_t parb = 6.52 ; Float_t xo,yo,zo ; //Coordinates of the origin gAlice->Generator()->GetOrigin(xo,yo,zo) ; Float_t phi = phosgeom->GetPHOSAngle(relid[0]) ; //Transform to the local ref.frame Float_t xoL,yoL ; xoL = xo*TMath::Cos(phi)-yo*TMath::Sin(phi) ; yoL = xo*TMath::Sin(phi)+yo*TMath::Cos(phi) ; Float_t radius = phosgeom->GetIPtoCrystalSurface()-yoL; Float_t incidencephi = TMath::ATan((x-xoL ) / radius) ; Float_t incidencetheta = TMath::ATan((z-zo) / radius) ; Float_t depthx = ( para * TMath::Log(fAmp) + parb ) * TMath::Sin(incidencephi) ; Float_t depthz = ( para * TMath::Log(fAmp) + parb ) * TMath::Sin(incidencetheta) ; fLocPos.SetX(x - depthx) ; fLocPos.SetY(0.) ; fLocPos.SetZ(z - depthz) ; fLocPosM = 0 ; } //____________________________________________________________________________ Float_t AliPHOSEmcRecPoint::GetMaximalEnergy(void) const { // Finds the maximum energy in the cluster Float_t menergy = 0. ; Int_t iDigit; for(iDigit=0; iDigit menergy) menergy = fEnergyList[iDigit] ; } return menergy ; } //____________________________________________________________________________ Int_t AliPHOSEmcRecPoint::GetMultiplicityAtLevel(Float_t H) const { // Calculates the multiplicity of digits with energy larger than H*energy Int_t multipl = 0 ; Int_t iDigit ; for(iDigit=0; iDigit H * fAmp) multipl++ ; } return multipl ; } //____________________________________________________________________________ Int_t AliPHOSEmcRecPoint::GetNumberOfLocalMax( AliPHOSDigit ** maxAt, Float_t * maxAtEnergy, Float_t locMaxCut,TClonesArray * digits) const { // Calculates the number of local maxima in the cluster using fLocalMaxCut as the minimum // energy difference between two local maxima AliPHOSDigit * digit ; AliPHOSDigit * digitN ; Int_t iDigitN ; Int_t iDigit ; for(iDigit = 0; iDigit < fMulDigit; iDigit++) maxAt[iDigit] = (AliPHOSDigit*) digits->At(fDigitsList[iDigit]) ; for(iDigit = 0 ; iDigit < fMulDigit; iDigit++) { if(maxAt[iDigit]) { digit = maxAt[iDigit] ; for(iDigitN = 0; iDigitN < fMulDigit; iDigitN++) { digitN = (AliPHOSDigit *) digits->At(fDigitsList[iDigitN]) ; if ( AreNeighbours(digit, digitN) ) { if (fEnergyList[iDigit] > fEnergyList[iDigitN] ) { maxAt[iDigitN] = 0 ; // but may be digit too is not local max ? if(fEnergyList[iDigit] < fEnergyList[iDigitN] + locMaxCut) maxAt[iDigit] = 0 ; } else { maxAt[iDigit] = 0 ; // but may be digitN too is not local max ? if(fEnergyList[iDigit] > fEnergyList[iDigitN] - locMaxCut) maxAt[iDigitN] = 0 ; } } // if Areneighbours } // while digitN } // slot not empty } // while digit iDigitN = 0 ; for(iDigit = 0; iDigit < fMulDigit; iDigit++) { if(maxAt[iDigit]){ maxAt[iDigitN] = maxAt[iDigit] ; maxAtEnergy[iDigitN] = fEnergyList[iDigit] ; iDigitN++ ; } } return iDigitN ; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::EvalTime(TClonesArray * digits) { // Define a rec.point time as a time in the cell with the maximum energy Float_t maxE = 0; Int_t maxAt = 0; for(Int_t idig=0; idig < fMulDigit; idig++){ if(fEnergyList[idig] > maxE){ maxE = fEnergyList[idig] ; maxAt = idig; } } fTime = ((AliPHOSDigit*) digits->At(fDigitsList[maxAt]))->GetTime() ; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::Purify(Float_t threshold){ //Removes digits below threshold Int_t * tempo = new Int_t[fMaxDigit]; Float_t * tempoE = new Float_t[fMaxDigit]; Int_t mult = 0 ; for(Int_t iDigit=0;iDigit< fMulDigit ;iDigit++){ if(fEnergyList[iDigit] > threshold){ tempo[mult] = fDigitsList[iDigit] ; tempoE[mult] = fEnergyList[iDigit] ; mult++ ; } } fMulDigit = mult ; delete [] fDigitsList ; delete [] fEnergyList ; fDigitsList = new Int_t[fMulDigit]; fEnergyList = new Float_t[fMulDigit]; fAmp = 0.; //Recalculate total energy for(Int_t iDigit=0;iDigit< fMulDigit ;iDigit++){ fDigitsList[iDigit] = tempo[iDigit]; fEnergyList[iDigit] = tempoE[iDigit] ; fAmp+=tempoE[iDigit]; } delete [] tempo ; delete [] tempoE ; } //____________________________________________________________________________ void AliPHOSEmcRecPoint::Print(Option_t *) const { // Print the list of digits belonging to the cluster TString message ; message = "AliPHOSEmcRecPoint:\n" ; message += " digits # = " ; Info("Print", message.Data()) ; Int_t iDigit; for(iDigit=0; iDigit