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<< 51 { } 56 } << 57 52 58 //....oooOO0OOooo........oooOO0OOooo........oo 53 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 59 54 60 RunAction::~RunAction() 55 RunAction::~RunAction() 61 { << 56 { } 62 delete fHistoManager; << 63 } << 64 57 65 //....oooOO0OOooo........oooOO0OOooo........oo 58 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 66 G4Run* RunAction::GenerateRun() << 59 67 { << 60 void RunAction::BeginOfRunAction(const G4Run* aRun) 68 fRun = new Run(fDetector, fKinematic, isMast << 61 { 69 return fRun; << 62 // do not save Rndm status >> 63 G4RunManager::GetRunManager()->SetRandomNumberStore(false); >> 64 CLHEP::HepRandom::showEngineStatus(); >> 65 >> 66 G4cout << "### Run " << aRun->GetRunID() << " start." << G4endl; >> 67 >> 68 G4int NbofEvents = aRun->GetNumberOfEventToBeProcessed(); >> 69 if (NbofEvents == 0) return; >> 70 >> 71 //run conditions >> 72 // >> 73 G4ParticleDefinition* particleGun >> 74 = kinematic->GetParticleGun()->GetParticleDefinition(); >> 75 G4String partName = particleGun->GetParticleName(); >> 76 energyGun = kinematic->GetParticleGun()->GetParticleEnergy(); >> 77 >> 78 //geometry : effective wall volume >> 79 // >> 80 G4double cavityThickness = detector->GetCavityThickness(); >> 81 G4Material* mateCavity = detector->GetCavityMaterial(); >> 82 G4double densityCavity = mateCavity->GetDensity(); >> 83 massCavity = cavityThickness*densityCavity; >> 84 >> 85 G4double wallThickness = detector->GetWallThickness(); >> 86 G4Material* mateWall = detector->GetWallMaterial(); >> 87 G4double densityWall = mateWall->GetDensity(); >> 88 >> 89 G4EmCalculator emCal; >> 90 G4double RangeWall = emCal.GetCSDARange(energyGun,particleGun,mateWall); >> 91 G4double factor = 1.2; >> 92 G4double effWallThick = factor*RangeWall; >> 93 if ((effWallThick > wallThickness)||(effWallThick <= 0.)) >> 94 effWallThick = wallThickness; >> 95 massWall = 2*effWallThick*densityWall; >> 96 >> 97 G4double massTotal = massWall + massCavity; >> 98 G4double massWallRatio = massWall/massTotal; >> 99 kinematic->RunInitialisation(effWallThick, massWallRatio ); >> 100 >> 101 G4double massRatio = massCavity/massWall; >> 102 >> 103 //check radius >> 104 // >> 105 G4double worldRadius = detector->GetWorldRadius(); >> 106 G4double RangeCavity = emCal.GetCSDARange(energyGun,particleGun,mateCavity); >> 107 >> 108 std::ios::fmtflags mode = G4cout.flags(); >> 109 G4cout.setf(std::ios::fixed,std::ios::floatfield); >> 110 G4int prec = G4cout.precision(3); >> 111 >> 112 G4cout << "\n ======================== run conditions =====================\n"; >> 113 >> 114 G4cout << "\n The run will be " << NbofEvents << " "<< partName << " of " >> 115 << G4BestUnit(energyGun,"Energy") << " through 2*" >> 116 << G4BestUnit(effWallThick,"Length") << " of " >> 117 << mateWall->GetName() << " (density: " >> 118 << G4BestUnit(densityWall,"Volumic Mass") << "); Mass/cm2 = " >> 119 << G4BestUnit(massWall*cm2,"Mass") >> 120 << "\n csdaRange: " << G4BestUnit(RangeWall,"Length") << G4endl; >> 121 >> 122 G4cout << "\n the cavity is " >> 123 << G4BestUnit(cavityThickness,"Length") << " of " >> 124 << mateCavity->GetName() << " (density: " >> 125 << G4BestUnit(densityCavity,"Volumic Mass") << "); Mass/cm2 = " >> 126 << G4BestUnit(massCavity*cm2,"Mass") >> 127 << " --> massRatio = " << std::setprecision(6) << massRatio << G4endl; >> 128 >> 129 G4cout.precision(3); >> 130 G4cout << " World radius: " << G4BestUnit(worldRadius,"Length") >> 131 << "; range in cavity: " << G4BestUnit(RangeCavity,"Length") >> 132 << G4endl; >> 133 >> 134 G4cout << "\n ============================================================\n"; >> 135 >> 136 //stopping power from EmCalculator >> 137 // >> 138 G4double dedxWall = >> 139 emCal.GetDEDX(energyGun,G4Electron::Electron(),mateWall); >> 140 dedxWall /= densityWall; >> 141 G4double dedxCavity = >> 142 emCal.GetDEDX(energyGun,G4Electron::Electron(),mateCavity); >> 143 dedxCavity /= densityCavity; >> 144 >> 145 G4cout << std::setprecision(4) >> 146 << "\n StoppingPower in wall = " >> 147 << G4BestUnit(dedxWall,"Energy*Surface/Mass") >> 148 << "\n in cavity = " >> 149 << G4BestUnit(dedxCavity,"Energy*Surface/Mass") >> 150 << G4endl; >> 151 >> 152 //process counter >> 153 // >> 154 ProcCounter = new ProcessesCount; >> 155 >> 156 //charged particles and energy flow in cavity >> 157 // >> 158 PartFlowCavity[0] = PartFlowCavity[1] = 0; >> 159 EnerFlowCavity[0] = EnerFlowCavity[1] = 0.; >> 160 >> 161 //total energy deposit and charged track segment in cavity >> 162 // >> 163 EdepCavity = EdepCavity2 = trkSegmCavity = 0.; >> 164 nbEventCavity = 0; >> 165 >> 166 //stepLenth of charged particles >> 167 // >> 168 stepWall = stepWall2 = stepCavity = stepCavity2 =0.; >> 169 nbStepWall = nbStepCavity = 0; >> 170 >> 171 //histograms >> 172 // >> 173 histoManager->book(); >> 174 >> 175 // reset default formats >> 176 G4cout.setf(mode,std::ios::floatfield); >> 177 G4cout.precision(prec); 70 } 178 } 71 179 72 //....oooOO0OOooo........oooOO0OOooo........oo 180 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 73 181 74 void RunAction::BeginOfRunAction(const G4Run* << 182 void RunAction::CountProcesses(G4String procName) 75 { 183 { 76 // do not save Rndm status << 184 //does the process already encounted ? 77 G4RunManager::GetRunManager()->SetRandomNumb << 185 size_t nbProc = ProcCounter->size(); 78 if (isMaster) { << 186 size_t i = 0; 79 CLHEP::HepRandom::showEngineStatus(); << 187 while ((i<nbProc)&&((*ProcCounter)[i]->GetName()!=procName)) i++; 80 G4cout << "### Run " << aRun->GetRunID() < << 188 if (i == nbProc) ProcCounter->push_back( new OneProcessCount(procName)); 81 } << 82 189 83 // G4int NbofEvents = aRun->GetNumberOfEvent << 190 (*ProcCounter)[i]->Count(); 84 // if (NbofEvents == 0) return; << 191 } 85 192 86 // run conditions << 193 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 87 // << 88 G4ParticleDefinition* particleGun = fKinemat << 89 G4String partName = particleGun->GetParticle << 90 // G4double energyGun = fKinematic->GetParti << 91 194 92 // histograms << 195 void RunAction::SurveyConvergence(G4int NbofEvents) >> 196 { >> 197 if (NbofEvents == 0) return; >> 198 >> 199 >> 200 //beam fluence 93 // 201 // 94 /* << 202 G4int Nwall = kinematic->GetWallCount(); 95 << 203 G4int Ncavity = kinematic->GetCavityCount(); 96 G4AnalysisManager* analysisManager = G4Ana << 204 G4double Iwall = Nwall/massWall; 97 if ( analysisManager->IsActive() ) { << 205 G4double Icavity = Ncavity/massCavity; 98 analysisManager->OpenFile(); << 206 G4double Iratio = Icavity/Iwall; 99 } << 207 G4double Itot = NbofEvents/(massWall+massCavity); 100 */ << 208 G4double energyFluence = energyGun*Itot; >> 209 >> 210 //total dose in cavity >> 211 // >> 212 G4double doseCavity = EdepCavity/massCavity; >> 213 G4double ratio = doseCavity/energyFluence; >> 214 G4double err = 100*(ratio-1.); >> 215 >> 216 std::ios::fmtflags mode = G4cout.flags(); >> 217 G4cout.setf(std::ios::fixed,std::ios::floatfield); >> 218 G4int prec = G4cout.precision(5); >> 219 >> 220 G4cout << "\n--->evntNb= " << NbofEvents >> 221 << " Nwall= " << Nwall >> 222 << " Ncav= " << Ncavity >> 223 << " Ic/Iw= " << Iratio >> 224 << " Ne-_cav= " << PartFlowCavity[0] >> 225 << " doseCavity/Ebeam= " << ratio >> 226 << " (100*(ratio-1) = " << err << " %)" >> 227 << G4endl; >> 228 >> 229 // reset default formats >> 230 G4cout.setf(mode,std::ios::floatfield); >> 231 G4cout.precision(prec); 101 } 232 } 102 233 103 //....oooOO0OOooo........oooOO0OOooo........oo 234 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 104 235 105 void RunAction::EndOfRunAction(const G4Run*) << 236 void RunAction::EndOfRunAction(const G4Run* aRun) 106 { 237 { 107 // compute and print statistic << 238 std::ios::fmtflags mode = G4cout.flags(); 108 if (isMaster) fRun->EndOfRun(); << 239 G4cout.setf(std::ios::fixed,std::ios::floatfield); >> 240 G4int prec = G4cout.precision(3); >> 241 >> 242 G4int NbofEvents = aRun->GetNumberOfEvent(); >> 243 if (NbofEvents == 0) return; 109 244 110 // save histograms << 245 //frequency of processes 111 G4AnalysisManager* analysisManager = G4Analy << 246 // 112 if (analysisManager->IsActive()) { << 247 G4cout << "\n Process calls frequency --->"; 113 analysisManager->Write(); << 248 for (size_t i=0; i< ProcCounter->size();i++) { 114 analysisManager->CloseFile(); << 249 G4String procName = (*ProcCounter)[i]->GetName(); >> 250 G4int count = (*ProcCounter)[i]->GetCounter(); >> 251 G4cout << " " << procName << "= " << count; 115 } 252 } 116 << 253 G4cout << G4endl; >> 254 >> 255 //charged particle flow in cavity >> 256 // >> 257 G4cout >> 258 << "\n Charged particle flow in cavity :" >> 259 << "\n Enter --> nbParticles = " << PartFlowCavity[0] >> 260 << "\t Energy = " << G4BestUnit (EnerFlowCavity[0], "Energy") >> 261 << "\n Exit --> nbParticles = " << PartFlowCavity[1] >> 262 << "\t Energy = " << G4BestUnit (EnerFlowCavity[1], "Energy") >> 263 << G4endl; >> 264 >> 265 if (PartFlowCavity[0] == 0) return; >> 266 >> 267 //beam fluence >> 268 // >> 269 G4int Nwall = kinematic->GetWallCount(); >> 270 G4int Ncavity = kinematic->GetCavityCount(); >> 271 G4double Iwall = Nwall/massWall; >> 272 G4double Icavity = Ncavity/massCavity; >> 273 G4double Iratio = Icavity/Iwall; >> 274 G4double Itot = NbofEvents/(massWall+massCavity); >> 275 G4double energyFluence = energyGun*Itot; >> 276 >> 277 G4cout.precision(5); >> 278 G4cout >> 279 << "\n beamFluence in wall = " << Nwall >> 280 << "\t in cavity = " << Ncavity >> 281 << "\t Icav/Iwall = " << Iratio >> 282 << "\t energyFluence = " << energyFluence/(MeV*cm2/mg) << " MeV*cm2/mg" >> 283 << G4endl; >> 284 >> 285 //error on Edep in cavity >> 286 // >> 287 if (nbEventCavity == 0) return; >> 288 G4double meanEdep = EdepCavity/nbEventCavity; >> 289 G4double meanEdep2 = EdepCavity2/nbEventCavity; >> 290 G4double varianceEdep = meanEdep2 - meanEdep*meanEdep; >> 291 G4double dEoverE = 0.; >> 292 if(varianceEdep>0.) dEoverE = std::sqrt(varianceEdep/nbEventCavity)/meanEdep; >> 293 >> 294 //total dose in cavity >> 295 // >> 296 G4double doseCavity = EdepCavity/massCavity; >> 297 G4double ratio = doseCavity/energyFluence, error = ratio*dEoverE; >> 298 >> 299 G4cout >> 300 << "\n Total edep in cavity = " << G4BestUnit(EdepCavity,"Energy") >> 301 << " +- " << 100*dEoverE << " %" >> 302 << "\n Total dose in cavity = " << doseCavity/(MeV*cm2/mg) << " MeV*cm2/mg" >> 303 << " +- " << 100*dEoverE << " %" >> 304 << "\n\n DoseCavity/EnergyFluence = " << ratio >> 305 << " +- " << error << G4endl; >> 306 >> 307 >> 308 //track length in cavity >> 309 G4double meantrack = trkSegmCavity/PartFlowCavity[0]; >> 310 >> 311 G4cout.precision(4); >> 312 G4cout >> 313 << "\n Total charged trackLength in cavity = " >> 314 << G4BestUnit(trkSegmCavity,"Length") >> 315 << " (mean value = " << G4BestUnit(meantrack,"Length") << ")" >> 316 << G4endl; >> 317 >> 318 //compute mean step size of charged particles >> 319 // >> 320 stepWall /= nbStepWall; stepWall2 /= nbStepWall; >> 321 G4double rms = stepWall2 - stepWall*stepWall; >> 322 if (rms>0.) rms = std::sqrt(rms); else rms = 0.; >> 323 G4double nbTrackWall = kinematic->GetWallCount(); >> 324 >> 325 G4cout >> 326 << "\n StepSize of ch. tracks in wall = " >> 327 << G4BestUnit(stepWall,"Length") << " +- " << G4BestUnit( rms,"Length") >> 328 << "\t (nbSteps/track = " << double(nbStepWall)/nbTrackWall << ")"; >> 329 >> 330 stepCavity /= nbStepCavity; stepCavity2 /= nbStepCavity; >> 331 rms = stepCavity2 - stepCavity*stepCavity; >> 332 if (rms>0.) rms = std::sqrt(rms); else rms = 0.; >> 333 >> 334 G4cout >> 335 << "\n StepSize of ch. tracks in cavity = " >> 336 << G4BestUnit(stepCavity,"Length") << " +- " << G4BestUnit( rms,"Length") >> 337 << "\t (nbSteps/track = " << double(nbStepCavity)/PartFlowCavity[0] << ")"; >> 338 >> 339 G4cout << G4endl; >> 340 >> 341 // reset default formats >> 342 G4cout.setf(mode,std::ios::floatfield); >> 343 G4cout.precision(prec); >> 344 >> 345 // delete and remove all contents in ProcCounter >> 346 while (ProcCounter->size()>0){ >> 347 OneProcessCount* aProcCount=ProcCounter->back(); >> 348 ProcCounter->pop_back(); >> 349 delete aProcCount; >> 350 } >> 351 delete ProcCounter; >> 352 >> 353 // save histograms >> 354 histoManager->save(); >> 355 117 // show Rndm status 356 // show Rndm status 118 if (isMaster) CLHEP::HepRandom::showEngineSt << 357 CLHEP::HepRandom::showEngineStatus(); 119 } 358 } 120 359 121 //....oooOO0OOooo........oooOO0OOooo........oo 360 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 122 361