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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 == detector->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 75 // collect energy deposit taking into accoun 77 // collect energy deposit taking into account track weight 76 G4double edep = aStep->GetTotalEnergyDeposit << 78 G4double edep = aStep->GetTotalEnergyDeposit()*aStep->GetTrack()->GetWeight(); 77 << 79 78 // collect step length of charged particles 80 // collect step length of charged particles 79 G4double stepl = 0.; 81 G4double stepl = 0.; 80 if (particle->GetPDGCharge() != 0.) { << 82 if (particle->GetPDGCharge() != 0.) stepl = aStep->GetStepLength(); 81 stepl = aStep->GetStepLength(); << 83 82 run->AddChargedStep(); << 83 } << 84 else { << 85 run->AddNeutralStep(); << 86 } << 87 << 88 // G4cout << "Nabs= " << absorNum << " ed 84 // G4cout << "Nabs= " << absorNum << " edep(keV)= " << edep << G4endl; 89 << 85 90 // sum up per event 86 // sum up per event 91 fEventAct->SumEnergy(absorNum, edep, stepl); << 87 eventAct->SumEnergy(absorNum,edep,stepl); 92 << 88 93 // longitudinal profile of edep per absorber << 89 //longitudinal profile of edep per absorber 94 if (edep > 0.) { << 90 if (edep>0.) histoManager->FillHisto(MaxAbsor+absorNum, 95 G4AnalysisManager::Instance()->FillH1(kMax << 91 G4double(layerNum+1), edep); 96 } << 92 97 // energy flow << 93 //energy flow 98 // 94 // 99 // unique identificator of layer+absorber << 95 // unique identificator of layer+absorber 100 G4int Idnow = (fDetector->GetNbOfAbsor()) * << 96 G4int Idnow = (detector->GetNbOfAbsor())*layerNum + absorNum; 101 G4int plane; 97 G4int plane; 102 // 98 // 103 // leaving the absorber ? << 99 //leaving the absorber ? 104 if (endPoint->GetStepStatus() == fGeomBounda 100 if (endPoint->GetStepStatus() == fGeomBoundary) { 105 G4ThreeVector position = endPoint->GetPosi << 101 G4ThreeVector position = endPoint->GetPosition(); 106 G4ThreeVector direction = endPoint->GetMom 102 G4ThreeVector direction = endPoint->GetMomentumDirection(); 107 G4double sizeYZ = 0.5 * fDetector->GetCalo << 103 G4double sizeYZ = 0.5*detector->GetCalorSizeYZ(); 108 G4double Eflow = endPoint->GetKineticEnerg 104 G4double Eflow = endPoint->GetKineticEnergy(); 109 if (particle == G4Positron::Positron()) Ef << 105 if (particle == G4Positron::Positron()) Eflow += 2*electron_mass_c2; 110 if ((std::abs(position.y()) >= sizeYZ) || << 106 if ((std::abs(position.y()) >= sizeYZ) || (std::abs(position.z()) >= sizeYZ)) 111 run->SumLateralEleak(Idnow, Eflow); << 107 runAct->sumLateralEleak(Idnow, Eflow); 112 else if (direction.x() >= 0.) << 108 else if (direction.x() >= 0.) runAct->sumEnergyFlow(plane=Idnow+1, Eflow); 113 run->SumEnergyFlow(plane = Idnow + 1, Ef << 109 else runAct->sumEnergyFlow(plane=Idnow, -Eflow); 114 else << 110 } 115 run->SumEnergyFlow(plane = Idnow, -Eflow << 111 116 } << 112 //// example of Birk attenuation 117 << 113 ///G4double destep = aStep->GetTotalEnergyDeposit(); 118 //// example of Birk attenuation << 114 ///G4double response = BirksAttenuation(aStep); 119 /// G4double destep = aStep->GetTotalEnerg << 115 ///G4cout << " Destep: " << destep/keV << " keV" 120 /// G4double response = BirksAttenuation(aSt << 116 /// << " response after Birks: " << response/keV << " keV" << G4endl; 121 /// G4cout << " Destep: " << destep/keV << " << 122 /// << " response after Birks: " << re << 123 } 117 } 124 118 125 //....oooOO0OOooo........oooOO0OOooo........oo 119 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 126 120 127 G4double SteppingAction::BirksAttenuation(cons 121 G4double SteppingAction::BirksAttenuation(const G4Step* aStep) 128 { 122 { 129 // Example of Birk attenuation law in organi << 123 //Example of Birk attenuation law in organic scintillators. 130 // adapted from Geant3 PHYS337. See MIN 80 ( << 124 //adapted from Geant3 PHYS337. See MIN 80 (1970) 239-244 131 // << 125 // 132 const G4Material* material = aStep->GetTrack << 126 G4Material* material = aStep->GetTrack()->GetMaterial(); 133 G4double birk1 = material->GetIonisation()-> << 127 G4double birk1 = material->GetIonisation()->GetBirksConstant(); 134 G4double destep = aStep->GetTotalEnergyDepos << 128 G4double destep = aStep->GetTotalEnergyDeposit(); 135 G4double stepl = aStep->GetStepLength(); << 129 G4double stepl = aStep->GetStepLength(); 136 G4double charge = aStep->GetTrack()->GetDefi << 130 G4double charge = aStep->GetTrack()->GetDefinition()->GetPDGCharge(); 137 // << 131 // 138 G4double response = destep; << 132 G4double response = destep; 139 if (birk1 * destep * stepl * charge != 0.) { << 133 if (birk1*destep*stepl*charge != 0.) 140 response = destep / (1. + birk1 * destep / << 134 { 141 } << 135 response = destep/(1. + birk1*destep/stepl); 142 return response; << 136 } >> 137 return response; 143 } 138 } 144 139 145 //....oooOO0OOooo........oooOO0OOooo........oo 140 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... >> 141 146 142