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Geant4/examples/extended/electromagnetic/TestEm3/src/SteppingAction.cc

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Differences between /examples/extended/electromagnetic/TestEm3/src/SteppingAction.cc (Version 11.3.0) and /examples/extended/electromagnetic/TestEm3/src/SteppingAction.cc (Version 10.3)


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 25 //                                                 25 //
 26 /// \file electromagnetic/TestEm3/src/Stepping     26 /// \file electromagnetic/TestEm3/src/SteppingAction.cc
 27 /// \brief Implementation of the SteppingActio     27 /// \brief Implementation of the SteppingAction class
 28 //                                                 28 //
                                                   >>  29 // $Id: SteppingAction.cc 98762 2016-08-09 14:08:07Z gcosmo $
 29 //                                                 30 //
 30 //....oooOO0OOooo........oooOO0OOooo........oo     31 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 31 //....oooOO0OOooo........oooOO0OOooo........oo     32 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 32                                                    33 
 33 #include "SteppingAction.hh"                       34 #include "SteppingAction.hh"
 34                                                    35 
 35 #include "DetectorConstruction.hh"                 36 #include "DetectorConstruction.hh"
                                                   >>  37 #include "Run.hh"
 36 #include "EventAction.hh"                          38 #include "EventAction.hh"
 37 #include "HistoManager.hh"                         39 #include "HistoManager.hh"
 38 #include "Run.hh"                              << 
 39                                                    40 
 40 #include "G4PhysicalConstants.hh"              << 
 41 #include "G4Positron.hh"                           41 #include "G4Positron.hh"
 42 #include "G4RunManager.hh"                         42 #include "G4RunManager.hh"
                                                   >>  43 #include "G4PhysicalConstants.hh"
 43                                                    44 
 44 //....oooOO0OOooo........oooOO0OOooo........oo     45 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 45                                                    46 
 46 SteppingAction::SteppingAction(DetectorConstru     47 SteppingAction::SteppingAction(DetectorConstruction* det, EventAction* evt)
 47   : fDetector(det), fEventAct(evt)             <<  48 :G4UserSteppingAction(),fDetector(det),fEventAct(evt) 
 48 {}                                             <<  49 { }
 49                                                    50 
 50 //....oooOO0OOooo........oooOO0OOooo........oo     51 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 51                                                    52 
 52 void SteppingAction::UserSteppingAction(const  <<  53 SteppingAction::~SteppingAction()
 53 {                                              <<  54 { }
 54   // track informations                        << 
 55   const G4StepPoint* prePoint = aStep->GetPreS << 
 56                                                    55 
 57   // if World, return                          <<  56 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 58   //                                           << 
 59   G4VPhysicalVolume* volume = prePoint->GetTou << 
 60   // if sum of absorbers do not fill exactly a << 
 61   const G4Material* mat = volume->GetLogicalVo << 
 62   if (mat == fDetector->GetWorldMaterial()) re << 
 63                                                    57 
                                                   >>  58 void SteppingAction::UserSteppingAction(const G4Step* aStep)
                                                   >>  59 {
                                                   >>  60   //track informations
                                                   >>  61   const G4StepPoint* prePoint = aStep->GetPreStepPoint();   
 64   const G4StepPoint* endPoint = aStep->GetPost     62   const G4StepPoint* endPoint = aStep->GetPostStepPoint();
 65   const G4ParticleDefinition* particle = aStep <<  63   const G4ParticleDefinition* particle = aStep->GetTrack()->GetDefinition(); 
 66                                                <<  64     
 67   // here we are in an absorber. Locate it     <<  65   //if World, return
 68   //                                           <<  66   //
 69   G4int absorNum = prePoint->GetTouchableHandl <<  67   G4VPhysicalVolume* volume = prePoint->GetTouchableHandle()->GetVolume();    
 70   G4int layerNum = prePoint->GetTouchableHandl <<  68   //if sum of absorbers do not fill exactly a layer: check material, not volume.
 71                                                <<  69   G4Material* mat = volume->GetLogicalVolume()->GetMaterial();
 72   // get Run                                   <<  70   if (mat == fDetector->GetWorldMaterial()) return; 
 73   Run* run = static_cast<Run*>(G4RunManager::G <<  71  
 74                                                <<  72   //here we are in an absorber. Locate it
                                                   >>  73   //
                                                   >>  74   G4int absorNum  = prePoint->GetTouchableHandle()->GetCopyNumber(0);
                                                   >>  75   G4int layerNum  = prePoint->GetTouchableHandle()->GetCopyNumber(1);
                                                   >>  76   
                                                   >>  77   //get Run
                                                   >>  78   Run* run = static_cast<Run*>(
                                                   >>  79              G4RunManager::GetRunManager()->GetNonConstCurrentRun());
                                                   >>  80                        
 75   // collect energy deposit taking into accoun     81   // collect energy deposit taking into account track weight
 76   G4double edep = aStep->GetTotalEnergyDeposit <<  82   G4double edep = aStep->GetTotalEnergyDeposit()*aStep->GetTrack()->GetWeight();
 77                                                <<  83   
 78   // collect step length of charged particles      84   // collect step length of charged particles
 79   G4double stepl = 0.;                             85   G4double stepl = 0.;
 80   if (particle->GetPDGCharge() != 0.) {            86   if (particle->GetPDGCharge() != 0.) {
 81     stepl = aStep->GetStepLength();                87     stepl = aStep->GetStepLength();
 82     run->AddChargedStep();                         88     run->AddChargedStep();
 83   }                                            <<  89   } else { run->AddNeutralStep(); }
 84   else {                                       <<  90   
 85     run->AddNeutralStep();                     << 
 86   }                                            << 
 87                                                << 
 88   //  G4cout << "Nabs= " << absorNum << "   ed     91   //  G4cout << "Nabs= " << absorNum << "   edep(keV)= " << edep << G4endl;
 89                                                <<  92   
 90   // sum up per event                              93   // sum up per event
 91   fEventAct->SumEnergy(absorNum, edep, stepl); <<  94   fEventAct->SumEnergy(absorNum,edep,stepl);
 92                                                <<  95   
 93   // longitudinal profile of edep per absorber <<  96   //longitudinal profile of edep per absorber
 94   if (edep > 0.) {                             <<  97   if (edep>0.) {
 95     G4AnalysisManager::Instance()->FillH1(kMax <<  98     G4AnalysisManager::Instance()->FillH1(kMaxAbsor+absorNum, 
                                                   >>  99                                           G4double(layerNum+1), edep);
 96   }                                               100   }
 97   // energy flow                               << 101   //energy flow
 98   //                                              102   //
 99   //  unique identificator of layer+absorber   << 103   // unique identificator of layer+absorber
100   G4int Idnow = (fDetector->GetNbOfAbsor()) *  << 104   G4int Idnow = (fDetector->GetNbOfAbsor())*layerNum + absorNum;
101   G4int plane;                                    105   G4int plane;
102   //                                              106   //
103   // leaving the absorber ?                    << 107   //leaving the absorber ?
104   if (endPoint->GetStepStatus() == fGeomBounda    108   if (endPoint->GetStepStatus() == fGeomBoundary) {
105     G4ThreeVector position = endPoint->GetPosi << 109     G4ThreeVector position  = endPoint->GetPosition();
106     G4ThreeVector direction = endPoint->GetMom    110     G4ThreeVector direction = endPoint->GetMomentumDirection();
107     G4double sizeYZ = 0.5 * fDetector->GetCalo << 111     G4double sizeYZ = 0.5*fDetector->GetCalorSizeYZ();       
108     G4double Eflow = endPoint->GetKineticEnerg    112     G4double Eflow = endPoint->GetKineticEnergy();
109     if (particle == G4Positron::Positron()) Ef << 113     if (particle == G4Positron::Positron()) Eflow += 2*electron_mass_c2;
110     if ((std::abs(position.y()) >= sizeYZ) ||  << 114    if ((std::abs(position.y()) >= sizeYZ) || (std::abs(position.z()) >= sizeYZ))
111       run->SumLateralEleak(Idnow, Eflow);      << 115                                   run->SumLateralEleak(Idnow, Eflow);
112     else if (direction.x() >= 0.)              << 116     else if (direction.x() >= 0.) run->SumEnergyFlow(plane=Idnow+1, Eflow);
113       run->SumEnergyFlow(plane = Idnow + 1, Ef << 117     else                          run->SumEnergyFlow(plane=Idnow,  -Eflow);    
114     else                                       << 118   }   
115       run->SumEnergyFlow(plane = Idnow, -Eflow << 119 
116   }                                            << 120 ////  example of Birk attenuation
117                                                << 121 ///G4double destep   = aStep->GetTotalEnergyDeposit();
118   ////  example of Birk attenuation            << 122 ///G4double response = BirksAttenuation(aStep);
119   /// G4double destep   = aStep->GetTotalEnerg << 123 ///G4cout << " Destep: " << destep/keV << " keV"
120   /// G4double response = BirksAttenuation(aSt << 124 ///       << " response after Birks: " << response/keV << " keV" << G4endl;
121   /// G4cout << " Destep: " << destep/keV << " << 
122   ///       << " response after Birks: " << re << 
123 }                                                 125 }
124                                                   126 
125 //....oooOO0OOooo........oooOO0OOooo........oo    127 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
126                                                   128 
127 G4double SteppingAction::BirksAttenuation(cons    129 G4double SteppingAction::BirksAttenuation(const G4Step* aStep)
128 {                                                 130 {
129   // Example of Birk attenuation law in organi << 131  //Example of Birk attenuation law in organic scintillators.
130   // adapted from Geant3 PHYS337. See MIN 80 ( << 132  //adapted from Geant3 PHYS337. See MIN 80 (1970) 239-244
131   //                                           << 133  //
132   const G4Material* material = aStep->GetTrack << 134  G4Material* material = aStep->GetTrack()->GetMaterial();
133   G4double birk1 = material->GetIonisation()-> << 135  G4double birk1       = material->GetIonisation()->GetBirksConstant();
134   G4double destep = aStep->GetTotalEnergyDepos << 136  G4double destep      = aStep->GetTotalEnergyDeposit();
135   G4double stepl = aStep->GetStepLength();     << 137  G4double stepl       = aStep->GetStepLength();  
136   G4double charge = aStep->GetTrack()->GetDefi << 138  G4double charge      = aStep->GetTrack()->GetDefinition()->GetPDGCharge();
137   //                                           << 139  //
138   G4double response = destep;                  << 140  G4double response = destep;
139   if (birk1 * destep * stepl * charge != 0.) { << 141  if (birk1*destep*stepl*charge != 0.)
140     response = destep / (1. + birk1 * destep / << 142    {
141   }                                            << 143      response = destep/(1. + birk1*destep/stepl);
142   return response;                             << 144    }
                                                   >> 145  return response;
143 }                                                 146 }
144                                                   147 
145 //....oooOO0OOooo........oooOO0OOooo........oo    148 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
                                                   >> 149 
146                                                   150