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Geant4/processes/electromagnetic/adjoint/include/G4AdjointCSManager.hh

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Differences between /processes/electromagnetic/adjoint/include/G4AdjointCSManager.hh (Version 11.3.0) and /processes/electromagnetic/adjoint/include/G4AdjointCSManager.hh (Version 9.2.p4)


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 25 //                                                 25 //
 26 ////////////////////////////////////////////// <<  26 /////////////////////////////////////////////////////////////////////////////////
 27 //  Class:    G4AdjointCSManager               <<  27 //      Module:   G4AdjointCSManager.hh
 28 //  Author:         L. Desorgher               <<  28 //  Author:         L. Desorgher
 29 //  Organisation:   SpaceIT GmbH               <<  29 //  Date:   1st April 2007
                                                   >>  30 //  Organisation:   SpaceIT GmbH
                                                   >>  31 //  Customer:       ESA/ESTEC
                                                   >>  32 /////////////////////////////////////////////////////////////////////////////////
 30 //                                                 33 //
 31 // Class is responsible for the management of  <<  34 // CHANGE HISTORY
 32 // matrices, and for the computation of the to <<  35 // --------------
 33 // sections. Total adjoint and forward cross s <<  36 //      ChangeHistory: 
 34 // weight of a particle after a tracking step  <<  37 //    1st April 2007 creation by L. Desorgher     
 35 // reverse reaction. It is also used to sample <<  38 //
 36 // given adjoint cross section matrix.         <<  39 //-------------------------------------------------------------
                                                   >>  40 //  Documentation:
                                                   >>  41 //    Is responsible for the management of all adjoint cross sections matrices, and for the computation of the total forward and adjoint cross sections.
                                                   >>  42 //    Total adjoint and forward cross sections are needed to correct continuously the weight of a particle after a tracking step. 
                                                   >>  43 //    It is also used to sample an adjoint secondary from a given adjoint cross section matrix.
 37 //                                                 44 //
 38 ////////////////////////////////////////////// << 
 39                                                << 
 40 #ifndef G4AdjointCSManager_h                       45 #ifndef G4AdjointCSManager_h
 41 #define G4AdjointCSManager_h 1                     46 #define G4AdjointCSManager_h 1
 42                                                    47 
 43 #include "globals.hh"                          <<  48 #include"globals.hh"
 44 #include "G4AdjointCSMatrix.hh"                <<  49 #include<vector>
 45 #include "G4ThreadLocalSingleton.hh"           <<  50 #include"G4AdjointCSMatrix.hh"
 46                                                    51 
 47 #include <vector>                              << 
 48                                                    52 
 49 class G4Element;                               <<  53 class G4VEmAdjointModel;
 50 class G4Material;                              << 
 51 class G4MaterialCutsCouple;                        54 class G4MaterialCutsCouple;
                                                   >>  55 class G4Material;
 52 class G4ParticleDefinition;                        56 class G4ParticleDefinition;
 53 class G4PhysicsTable;                          <<  57 class G4Element;
 54 class G4VEmProcess;                                58 class G4VEmProcess;
 55 class G4VEmAdjointModel;                       << 
 56 class G4VEnergyLossProcess;                        59 class G4VEnergyLossProcess;
                                                   >>  60 class G4PhysicsTable;
 57                                                    61 
                                                   >>  62 ////////////////////////////////////////////////////////////////////////////////
                                                   >>  63 //
 58 class G4AdjointCSManager                           64 class G4AdjointCSManager
 59 {                                                  65 {
 60   friend class G4ThreadLocalSingleton<G4Adjoin <<  66   
 61                                                <<  67   public:
 62  public:                                       <<  68         ~G4AdjointCSManager();
 63   ~G4AdjointCSManager();                       <<  69   static G4AdjointCSManager* GetAdjointCSManager();
 64   static G4AdjointCSManager* GetAdjointCSManag <<  70 
 65                                                <<  71   public:
 66   G4int GetNbProcesses();                      <<  72         G4int GetNbProcesses();
 67                                                <<  73   
 68   // Registration of the different models and  <<  74   //Registration of the different models and processes
 69                                                <<  75   
 70   std::size_t RegisterEmAdjointModel(G4VEmAdjo <<  76   void RegisterEmAdjointModel(G4VEmAdjointModel*);
 71                                                <<  77   
 72   void RegisterEmProcess(G4VEmProcess* aProces <<  78   void RegisterEmProcess(G4VEmProcess* aProcess, G4ParticleDefinition* aPartDef);
 73                          G4ParticleDefinition* <<  79   
 74                                                <<  80   void RegisterEnergyLossProcess(G4VEnergyLossProcess* aProcess, G4ParticleDefinition* aPartDef);
 75   void RegisterEnergyLossProcess(G4VEnergyLoss <<  81   
 76                                  G4ParticleDef <<  82   void RegisterAdjointParticle(G4ParticleDefinition* aPartDef);
 77                                                <<  83   
 78   void RegisterAdjointParticle(G4ParticleDefin <<  84   //Building of thr CS Matrices and Total Forward and Adjoint LambdaTables
 79                                                <<  85   //----------------------------------------------------------------------
 80   // Building of the CS Matrices and Total For <<  86   
 81   void BuildCrossSectionMatrices();            <<  87   void BuildCrossSectionMatrices();
 82                                                <<  88   void BuildTotalSigmaTables();
 83   void BuildTotalSigmaTables();                <<  89   
 84                                                <<  90   
 85   // Get TotalCrossSections form Total Lambda  <<  91   //Get TotalCrossSections form Total Lambda Tables
 86   // correction and scaling of the             <<  92   //-------------------------------------------------
 87   G4double GetTotalAdjointCS(G4ParticleDefinit <<  93   G4double GetTotalAdjointCS(G4ParticleDefinition* aPartDef, G4double Ekin,
 88                              const G4MaterialC <<  94                const G4MaterialCutsCouple* aCouple);
 89                                                <<  95   G4double GetTotalForwardCS(G4ParticleDefinition* aPartDef, G4double Ekin,
 90   G4double GetTotalForwardCS(G4ParticleDefinit <<  96                const G4MaterialCutsCouple* aCouple);           
 91                              const G4MaterialC <<  97   
 92                                                <<  98   
 93   G4double GetAdjointSigma(G4double Ekin_nuc,  <<  99   
 94                            G4bool is_scat_proj << 100   //Weight correction 
 95                            const G4MaterialCut << 101   //------------------
 96                                                << 102   
 97   void GetEminForTotalCS(G4ParticleDefinition* << 103   G4double GetContinuousWeightCorrection(G4ParticleDefinition* aPartDef, G4double PreStepEkin,G4double AfterStepEkin,
 98                          const G4MaterialCutsC << 104                const G4MaterialCutsCouple* aCouple, G4double step_length);
 99                          G4double& emin_adj, G << 105   G4double GetPostStepWeightCorrection(G4ParticleDefinition* aPrimPartDef, G4ParticleDefinition* aSecondPartDef,
100                                                << 106               G4double EkinPrim,G4double EkinSecond,
101   void GetMaxFwdTotalCS(G4ParticleDefinition*  << 107                const G4MaterialCutsCouple* aCouple);
102                         const G4MaterialCutsCo << 108              
103                         G4double& e_sigma_max, << 109   
104                                                << 110   double ComputeAdjointCS(G4Material* aMaterial,
105   void GetMaxAdjTotalCS(G4ParticleDefinition*  << 111               G4VEmAdjointModel* aModel, 
106                         const G4MaterialCutsCo << 112               G4double PrimEnergy,
107                         G4double& e_sigma_max, << 113               G4double Tcut,
108                                                << 114               G4bool IsScatProjToProjCase,
109   // CrossSection Correction 1 or FwdCS/AdjCS  << 115               std::vector<double>& 
110   // forward_CS_is_used and forward_CS_mode    << 116                    AdjointCS_for_each_element);
111   G4double GetCrossSectionCorrection(G4Particl << 117            
112                                      G4double  << 118   
113                                      const G4M << 119   G4Element*  SampleElementFromCSMatrices(G4Material* aMaterial,
114                                      G4bool& f << 120                    G4VEmAdjointModel* aModel,
115                                                << 121                    G4double PrimEnergy,
116   // Cross section mode                        << 122                     G4double Tcut,
117   inline void SetFwdCrossSectionMode(G4bool aB << 123                    G4bool IsScatProjToProjCase);
118                                                << 124   G4double ComputeTotalAdjointCS(const G4MaterialCutsCouple* aMatCutCouple,G4ParticleDefinition* aPart,G4double PrimEnergy);              
119   // Weight correction                         << 125   G4ParticleDefinition* GetAdjointParticleEquivalent(G4ParticleDefinition* theFwdPartDef);
120   G4double GetContinuousWeightCorrection(G4Par << 126   G4ParticleDefinition* GetForwardParticleEquivalent(G4ParticleDefinition* theAdjPartDef);
121                                          G4dou << 127   
122                                          G4dou << 128   //inline
123                                          const << 129   inline void SetTmin(G4double aVal){Tmin=aVal;}
124                                          G4dou << 130   inline void SetTmax(G4double aVal){Tmax=aVal;}
125                                                << 131   inline void SetNbins(G4int aInt){nbins=aInt;}
126   G4double GetPostStepWeightCorrection();      << 132   
127                                                << 133   
128   // called by the adjoint model to get the CS << 134   
129   G4double ComputeAdjointCS(G4Material* aMater << 135   //inline
130                             G4double PrimEnerg << 136   inline void ConsiderContinuousWeightCorrection(G4bool aBool){consider_continuous_weight_correction=aBool;}
131                             G4bool isScatProjT << 137   inline void ConsiderPoststepWeightCorrection(G4bool aBool){consider_poststep_weight_correction=aBool;}
132                             std::vector<G4doub << 138   
133                                                << 139   
134   // called by the adjoint model to sample sec << 140   
135   G4Element* SampleElementFromCSMatrices(G4Mat << 141   
136                                          G4VEm << 142   private:
137                                          G4dou << 143         static  G4AdjointCSManager* theInstance;
138                                          G4boo << 144     std::vector< std::vector<G4AdjointCSMatrix*> > theAdjointCSMatricesForScatProjToProj; //x dim is for G4VAdjointEM* while y dim is for elements
139                                                << 145   std::vector< std::vector<G4AdjointCSMatrix*> > theAdjointCSMatricesForProdToProj;
140   // Total Adjoint CS is computed at initialis << 146   std::vector< G4VEmAdjointModel*> listOfAdjointEMModel;
141   G4double ComputeTotalAdjointCS(const G4Mater << 147     
142                                  G4ParticleDef << 148   std::vector<G4AdjointCSMatrix*> 
143                                  G4double Prim << 149         BuildCrossSectionsMatricesForAGivenModelAndElement(G4VEmAdjointModel* aModel,
144                                                << 150                        G4int Z,
145   G4ParticleDefinition* GetAdjointParticleEqui << 151                        G4int A,
146     G4ParticleDefinition* theFwdPartDef);      << 152                        G4int nbin_pro_decade);
147                                                << 153   
148   G4ParticleDefinition* GetForwardParticleEqui << 154   std::vector<G4AdjointCSMatrix*> 
149     G4ParticleDefinition* theAdjPartDef);      << 155         BuildCrossSectionsMatricesForAGivenModelAndMaterial(G4VEmAdjointModel* aModel,
150                                                << 156                        G4Material* aMaterial,
151   // inline                                    << 157                        G4int nbin_pro_decade);
152   inline void SetIon(G4ParticleDefinition* adj << 158   
153   {                                            << 159   
154     fAdjIon = adjIon;                          << 160   G4Material* lastMaterial;
155     fFwdIon = fwdIon;                          << 161   G4double    lastPrimaryEnergy;
156   }                                            << 162   G4double    lastTcut; 
157                                                << 163   std::vector< size_t> listOfIndexOfAdjointEMModelInAction;
158  private:                                      << 164   std::vector< G4bool> listOfIsScatProjToProjCase;
159   G4AdjointCSManager();                        << 165   std::vector< std::vector<double> > lastAdjointCSVsModelsAndElements;
160                                                << 166   G4bool CrossSectionMatrixesAreBuilt;
161   void DefineCurrentMaterial(const G4MaterialC << 167   
162                                                << 168   //total adjoint and total forward cross section table in function of material and in function of adjoint particle type
163   void DefineCurrentParticle(const G4ParticleD << 169   //--------------------------------------------------------------------------------------------------------------------
164                                                << 170   std::vector<G4PhysicsTable*>        theTotalForwardSigmaTableVector;
165   G4double ComputeAdjointCS(G4double aPrimEner << 171   std::vector<G4PhysicsTable*>        theTotalAdjointSigmaTableVector;
166                             G4AdjointCSMatrix* << 172    
167                             G4double Tcut);    << 173   //list of forward G4VEMLossProcess and of G4VEMProcess for the different adjoint particle
168                                                << 174   //--------------------------------------------------------------
169   std::vector<G4AdjointCSMatrix*> BuildCrossSe << 175   std::vector< std::vector<G4VEmProcess*>* >    listOfForwardEmProcess;
170     G4VEmAdjointModel* aModel, G4int Z, G4int  << 176   std::vector< std::vector<G4VEnergyLossProcess*>* >  listOfForwardEnergyLossProcess;
171                                                << 177   
172   std::vector<G4AdjointCSMatrix*> BuildCrossSe << 178   //list of adjoint particles considered
173     G4VEmAdjointModel* aModel, G4Material* aMa << 179   
174                                                << 180   std::vector< G4ParticleDefinition*> theListOfAdjointParticlesInAction;
175   static constexpr G4double fTmin = 0.1 * CLHE << 181   
176   static constexpr G4double fTmax = 100. * CLH << 182   
177   // fNbins chosen to avoid error              << 183   G4double Tmin,Tmax;
178   // in the CS value close to CS jump. (For ex << 184   G4int nbins;
179   static constexpr G4int fNbins = 320;         << 185   
180                                                << 186   
181   static G4ThreadLocal G4AdjointCSManager* fIn << 187   //Current material
182                                                << 188   //----------------
183   // only one ion can be considered by simulat << 189   G4MaterialCutsCouple* currentCouple;  
184   G4ParticleDefinition* fAdjIon = nullptr;     << 190   G4Material* currentMaterial;
185   G4ParticleDefinition* fFwdIon = nullptr;     << 191   size_t  currentMatIndex;
186                                                << 192   
187   G4MaterialCutsCouple* fCurrentCouple = nullp << 193   int verbose;
188   G4Material* fCurrentMaterial         = nullp << 194   
189                                                << 195   
190   // x dim is for G4VAdjointEM*, y dim is for  << 196   //Weight correction
191   std::vector<std::vector<G4AdjointCSMatrix*>> << 197   //------------------
192     fAdjointCSMatricesForScatProjToProj;       << 198   G4bool consider_continuous_weight_correction;
193                                                << 199   G4bool consider_poststep_weight_correction;
194   std::vector<std::vector<G4AdjointCSMatrix*>> << 200 
195                                                << 201   private:
196   std::vector<G4VEmAdjointModel*> fAdjointMode << 202         G4AdjointCSManager();  
197                                                << 203   void DefineCurrentMaterial(const G4MaterialCutsCouple* couple);
198   std::vector<std::size_t> fIndexOfAdjointEMMo << 204   double ComputeAdjointCS(G4double aPrimEnergy, G4AdjointCSMatrix* anAdjointCSMatrix, G4double Tcut);
199   std::vector<G4bool> fIsScatProjToProj;       << 
200   std::vector<std::vector<G4double>> fLastAdjo << 
201                                                << 
202   // total adjoint and total forward cross sec << 
203   // and in function of adjoint particle type  << 
204   std::vector<G4PhysicsTable*> fTotalFwdSigmaT << 
205   std::vector<G4PhysicsTable*> fTotalAdjSigmaT << 
206                                                << 
207   // Sigma table for each G4VAdjointEMModel    << 
208   std::vector<G4PhysicsTable*> fSigmaTableForA << 
209   std::vector<G4PhysicsTable*> fSigmaTableForA << 
210                                                << 
211   std::vector<std::vector<G4double>> fEminForF << 
212   std::vector<std::vector<G4double>> fEminForA << 
213   std::vector<std::vector<G4double>> fEkinofFw << 
214   std::vector<std::vector<G4double>> fEkinofAd << 
215                                                << 
216   // list of forward G4VEmProcess and of G4VEn << 
217   // adjoint particle                          << 
218   std::vector<std::vector<G4VEmProcess*>*> fFo << 
219   std::vector<std::vector<G4VEnergyLossProcess << 
220                                                << 
221   // list of adjoint particles considered      << 
222   std::vector<G4ParticleDefinition*> fAdjointP << 
223                                                << 
224   G4double fMassRatio              = 1.;  // i << 
225   G4double fLastCSCorrectionFactor = 1.;       << 
226                                                << 
227   G4ParticleDefinition* fCurrentParticleDef =  << 
228   std::size_t fCurrentParticleIndex = 0;       << 
229   std::size_t fCurrentMatIndex      = 0;       << 
230                                                   205 
231   G4bool fCSMatricesBuilt = false;             << 
232   G4bool fSigmaTableBuilt = false;             << 
233   G4bool fForwardCSUsed   = true;              << 
234   G4bool fForwardCSMode   = true;              << 
235   // Two CS mode are possible:                 << 
236   // 1) fForwardCSMode = false, the Adjoint CS << 
237   //    an AlongStep Weight Correction.        << 
238   // 2) fForwardCSMode = true, the Adjoint CS  << 
239   //    adjoint CS equal to the fwd one implyi << 
240   // For energies where the total Fwd CS or th << 
241   // the scaling is not possible and fForwardC << 
242 };                                                206 };
243 #endif                                            207 #endif
244                                                   208