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Geant4/processes/electromagnetic/adjoint/src/G4AdjointForcedInteractionForGamma.cc

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Diff markup

Differences between /processes/electromagnetic/adjoint/src/G4AdjointForcedInteractionForGamma.cc (Version 11.3.0) and /processes/electromagnetic/adjoint/src/G4AdjointForcedInteractionForGamma.cc (Version 7.0.p1)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
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 10 // *                                              
 11 // * Neither the authors of this software syst    
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 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26                                                   
 27 #include "G4AdjointForcedInteractionForGamma.h    
 28                                                   
 29 #include "G4AdjointCSManager.hh"                  
 30 #include "G4AdjointGamma.hh"                      
 31 #include "G4MaterialCutsCouple.hh"                
 32 #include "G4ParticleChange.hh"                    
 33 #include "G4SystemOfUnits.hh"                     
 34 #include "G4VEmAdjointModel.hh"                   
 35                                                   
 36 G4AdjointForcedInteractionForGamma::G4AdjointF    
 37   const G4String& process_name)                   
 38   : G4VContinuousDiscreteProcess(process_name)    
 39   , fAdjointComptonModel(nullptr)                 
 40   , fAdjointBremModel(nullptr)                    
 41 {                                                 
 42   fCSManager      = G4AdjointCSManager::GetAdj    
 43   fParticleChange = new G4ParticleChange();       
 44 }                                                 
 45                                                   
 46 //////////////////////////////////////////////    
 47 G4AdjointForcedInteractionForGamma::~G4Adjoint    
 48 {                                                 
 49   if(fParticleChange)                             
 50     delete fParticleChange;                       
 51 }                                                 
 52                                                   
 53 //////////////////////////////////////////////    
 54 void G4AdjointForcedInteractionForGamma::Proce    
 55   std::ostream& out) const                        
 56 {                                                 
 57   out << "Forced interaction for gamma.\n";       
 58 }                                                 
 59                                                   
 60 //////////////////////////////////////////////    
 61 void G4AdjointForcedInteractionForGamma::Build    
 62   const G4ParticleDefinition&)                    
 63 {                                                 
 64   fCSManager->BuildCrossSectionMatrices();  //    
 65   fCSManager->BuildTotalSigmaTables();            
 66 }                                                 
 67                                                   
 68 // Note on weight correction for forced intera    
 69 // For the forced interaction applied here we     
 70 // for the probability of survival over a fixe    
 71 // using a linear transformation of the non-bi    
 72 // math this is written P'(x)=C1P(x)+C2 , with    
 73 // L can cross different volumes with differen    
 74 // interaction, we get the limit conditions:      
 75 // P'(L)=0  and  P'(0)=1       (L can be used     
 76 // From simple solving of linear equations we     
 77 // get C1=1/(1-P(L)) and C2=-P(L)/(1-P(L))        
 78 // P'(x)=(P(x)-P(L))/(1-P(L))                     
 79 // For the probability over a step x1 to x2, P    
 80 // The effective cross                            
 81 // section is defined -d(P'(x))/dx/P'(x).         
 82 // We get therefore                               
 83 // sigma_eff = C1sigmaP(x)/(C1P(x)+C2) = sigma    
 84 //           = sigmaP(x)/(P(x)-P(L)) = sigma/(    
 85 //////////////////////////////////////////////    
 86 G4VParticleChange* G4AdjointForcedInteractionF    
 87   const G4Track& track, const G4Step&)            
 88 {                                                 
 89   fParticleChange->Initialize(track);             
 90   // For the free flight gamma no interaction     
 91   // properties is produced for further forced    
 92   // very beginning of the track so that the w    
 93   if(fCopyGammaForForced)                         
 94   {                                               
 95     G4ThreeVector theGammaMomentum = track.Get    
 96     fParticleChange->AddSecondary(                
 97       new G4DynamicParticle(G4AdjointGamma::Ad    
 98     fParticleChange->SetParentWeightByProcess(    
 99     fParticleChange->SetSecondaryWeightByProce    
100   }                                               
101   else                                            
102   {  // Occurrence of forced interaction          
103     // Selection of the model to be called        
104     G4VEmAdjointModel* theSelectedModel = null    
105     G4bool is_scat_proj_to_proj_case    = fals    
106     G4double factor=1.;                           
107     if(!fAdjointComptonModel && !fAdjointBremM    
108       return fParticleChange;                     
109     if(!fAdjointComptonModel)                     
110     {                                             
111       theSelectedModel          = fAdjointBrem    
112       is_scat_proj_to_proj_case = false;          
113       // This is needed because the results of    
114       // do it weight correction inside the mo    
115       fAdjointBremModel->AdjointCrossSection(t    
116                                              t    
117     }                                             
118     else if(!fAdjointBremModel)                   
119     {                                             
120       theSelectedModel          = fAdjointComp    
121       is_scat_proj_to_proj_case = true;           
122     }                                             
123     else                                          
124     {  // Choose the model according to a 50-5    
125       G4double bremAdjCS = fAdjointBremModel->    
126         track.GetMaterialCutsCouple(), track.G    
127       if(G4UniformRand()  < 0.5)                  
128       {                                           
129         theSelectedModel          = fAdjointBr    
130         is_scat_proj_to_proj_case = false;        
131         factor=bremAdjCS/fLastAdjCS/0.5;          
132       }                                           
133       else                                        
134       {                                           
135         theSelectedModel          = fAdjointCo    
136         is_scat_proj_to_proj_case = true;         
137         factor=(fLastAdjCS-bremAdjCS)/fLastAdj    
138       }                                           
139     }                                             
140                                                   
141     // Compute the weight correction factor       
142     G4double invEffectiveAdjointCS =              
143       (1. - std::exp(fNbAdjIntLength - fTotNbA    
144                                                   
145     // Call the  selected model without correc    
146     theSelectedModel->SetCorrectWeightForPostS    
147     theSelectedModel                              
148       ->SetAdditionalWeightCorrectionFactorFor    
149         factor*fLastAdjCS * invEffectiveAdjoin    
150     theSelectedModel->SampleSecondaries(track,    
151                                         fParti    
152     theSelectedModel->SetCorrectWeightForPostS    
153                                                   
154     fContinueGammaAsNewFreeFlight = true;         
155   }                                               
156   return fParticleChange;                         
157 }                                                 
158                                                   
159 //////////////////////////////////////////////    
160 G4VParticleChange* G4AdjointForcedInteractionF    
161   const G4Track& track, const G4Step&)            
162 {                                                 
163   fParticleChange->Initialize(track);             
164   // Compute nb of interactions length over st    
165   G4ThreeVector position = track.GetPosition()    
166   G4double stepLength    = track.GetStep()->Ge    
167   G4double ekin          = track.GetKineticEne    
168   fLastAdjCS = fCSManager->GetTotalAdjointCS(t    
169                                              t    
170   G4double nb_fwd_interaction_length_over_step    
171     stepLength * fCSManager->GetTotalForwardCS    
172                                                   
173                                                   
174                                                   
175   G4double nb_adj_interaction_length_over_step    
176   G4double fwd_survival_probability =             
177     std::exp(-nb_fwd_interaction_length_over_s    
178   G4double mc_induced_survival_probability = 1    
179                                                   
180   if(fFreeFlightGamma)                            
181   {  // for free_flight survival probability s    
182     // Accumulate the number of interaction le    
183     fTotNbAdjIntLength += nb_adj_interaction_l    
184     fAccTrackLength += stepLength;                
185   }                                               
186   else                                            
187   {                                               
188     G4double previous_acc_nb_adj_interaction_l    
189     fNbAdjIntLength += fCSBias*nb_adj_interact    
190     theNumberOfInteractionLengthLeft -= fCSBia    
191                                                   
192     // protection against rare race condition     
193     if(std::abs(fTotNbAdjIntLength - previous_    
194        1.e-15)                                    
195     {                                             
196       mc_induced_survival_probability = 1.e50;    
197     }                                             
198     else                                          
199     {                                             
200       mc_induced_survival_probability =           
201         std::exp(-fNbAdjIntLength) - std::exp(    
202       mc_induced_survival_probability /=          
203         (std::exp(-previous_acc_nb_adj_interac    
204          std::exp(-fTotNbAdjIntLength));          
205     }                                             
206   }                                               
207   G4double weight_correction =                    
208     fwd_survival_probability / mc_induced_surv    
209                                                   
210   // Caution!!!                                   
211   // It is important to select the weight of t    
212   // current weight and not the weight of the     
213   // is changed after having applied all the a    
214   G4double new_weight =                           
215     weight_correction * track.GetStep()->GetPo    
216                                                   
217   fParticleChange->SetParentWeightByProcess(fa    
218   fParticleChange->SetSecondaryWeightByProcess    
219   fParticleChange->ProposeParentWeight(new_wei    
220                                                   
221   return fParticleChange;                         
222 }                                                 
223                                                   
224 //////////////////////////////////////////////    
225 G4double                                          
226 G4AdjointForcedInteractionForGamma::PostStepGe    
227   const G4Track& track, G4double, G4ForceCondi    
228 {                                                 
229   G4int step_id                      = track.G    
230   *condition                         = NotForc    
231   fCopyGammaForForced                = false;     
232   G4int track_id                     = track.G    
233   fFreeFlightGamma =                              
234     (track_id != fLastFreeFlightTrackId + 1 ||    
235   if(fFreeFlightGamma)                            
236   {                                               
237     if(step_id == 1 || fContinueGammaAsNewFree    
238     {                                             
239       *condition = Forced;                        
240       // A gamma with same conditions will be     
241       // for the forced interaction               
242       fCopyGammaForForced           = true;       
243       fLastFreeFlightTrackId         = track_i    
244       fAccTrackLength               = 0.;         
245       fTotNbAdjIntLength            = 0.;         
246       fContinueGammaAsNewFreeFlight = false;      
247       return 1.e-90;                              
248     }                                             
249     else                                          
250     {                                             
251       return DBL_MAX;                             
252     }                                             
253   }                                               
254   else                                            
255   {  // compute the interaction length for for    
256     if(step_id == 1)                              
257     {                                             
258       fCSBias=0.000001/fTotNbAdjIntLength;        
259       fTotNbAdjIntLength*=fCSBias;                
260       G4double min_val = std::exp(-fTotNbAdjIn    
261       theNumberOfInteractionLengthLeft =          
262         -std::log(min_val + G4UniformRand() *     
263       theInitialNumberOfInteractionLength = th    
264       fNbAdjIntLength                     = 0.    
265     }                                             
266     G4VPhysicalVolume* thePostPhysVolume =        
267       track.GetStep()->GetPreStepPoint()->GetP    
268     G4double ekin   = track.GetKineticEnergy()    
269     G4double postCS = 0.;                         
270     if(thePostPhysVolume)                         
271     {                                             
272       postCS = fCSManager->GetTotalAdjointCS(     
273         G4AdjointGamma::AdjointGamma(), ekin,     
274         thePostPhysVolume->GetLogicalVolume()-    
275     }                                             
276     if(postCS > 0.)                               
277       return theNumberOfInteractionLengthLeft     
278     else                                          
279       return DBL_MAX;                             
280   }                                               
281 }                                                 
282                                                   
283 //////////////////////////////////////////////    
284 G4double G4AdjointForcedInteractionForGamma::G    
285   const G4Track&, G4double, G4double, G4double    
286 {                                                 
287   return DBL_MAX;                                 
288 }                                                 
289                                                   
290 //////////////////////////////////////////////    
291 // Not used in this process but should be impl    
292 G4double G4AdjointForcedInteractionForGamma::G    
293                                                   
294                                                   
295 {                                                 
296   return 0.;                                      
297 }                                                 
298