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Geant4/processes/electromagnetic/adjoint/src/G4AdjointBremsstrahlungModel.cc

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Differences between /processes/electromagnetic/adjoint/src/G4AdjointBremsstrahlungModel.cc (Version 11.3.0) and /processes/electromagnetic/adjoint/src/G4AdjointBremsstrahlungModel.cc (Version 10.0.p2)


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 25 //                                                 25 //
 26                                                <<  26 // $Id: G4AdjointBremsstrahlungModel.cc 75591 2013-11-04 12:33:11Z gcosmo $
                                                   >>  27 //
 27 #include "G4AdjointBremsstrahlungModel.hh"         28 #include "G4AdjointBremsstrahlungModel.hh"
 28                                                << 
 29 #include "G4AdjointCSManager.hh"                   29 #include "G4AdjointCSManager.hh"
                                                   >>  30 
                                                   >>  31 #include "G4PhysicalConstants.hh"
                                                   >>  32 #include "G4SystemOfUnits.hh"
                                                   >>  33 
                                                   >>  34 #include "G4Integrator.hh"
                                                   >>  35 #include "G4TrackStatus.hh"
                                                   >>  36 #include "G4ParticleChange.hh"
 30 #include "G4AdjointElectron.hh"                    37 #include "G4AdjointElectron.hh"
 31 #include "G4AdjointGamma.hh"                       38 #include "G4AdjointGamma.hh"
 32 #include "G4Electron.hh"                           39 #include "G4Electron.hh"
 33 #include "G4EmModelManager.hh"                 <<  40 #include "G4Timer.hh"
 34 #include "G4Gamma.hh"                          << 
 35 #include "G4ParticleChange.hh"                 << 
 36 #include "G4PhysicalConstants.hh"              << 
 37 #include "G4SeltzerBergerModel.hh"                 41 #include "G4SeltzerBergerModel.hh"
 38 #include "G4SystemOfUnits.hh"                  << 
 39 #include "G4TrackStatus.hh"                    << 
 40                                                    42 
 41 ////////////////////////////////////////////// << 
 42 G4AdjointBremsstrahlungModel::G4AdjointBremsst << 
 43   : G4VEmAdjointModel("AdjointeBremModel")     << 
 44 {                                              << 
 45   fDirectModel = aModel;                       << 
 46   Initialize();                                << 
 47 }                                              << 
 48                                                    43 
 49 //////////////////////////////////////////////     44 ////////////////////////////////////////////////////////////////////////////////
 50 G4AdjointBremsstrahlungModel::G4AdjointBremsst <<  45 //
 51   : G4VEmAdjointModel("AdjointeBremModel")     <<  46 G4AdjointBremsstrahlungModel::G4AdjointBremsstrahlungModel(G4VEmModel* aModel):
 52 {                                              <<  47  G4VEmAdjointModel("AdjointeBremModel")
 53   fDirectModel = new G4SeltzerBergerModel();   <<  48 { 
 54   Initialize();                                << 
 55 }                                              << 
 56                                                << 
 57 ////////////////////////////////////////////// << 
 58 void G4AdjointBremsstrahlungModel::Initialize( << 
 59 {                                              << 
 60   SetUseMatrix(false);                             49   SetUseMatrix(false);
 61   SetUseMatrixPerElement(false);                   50   SetUseMatrixPerElement(false);
                                                   >>  51   
                                                   >>  52   theDirectStdBremModel = aModel;
                                                   >>  53   theDirectEMModel=theDirectStdBremModel;
                                                   >>  54   theEmModelManagerForFwdModels = new G4EmModelManager();
                                                   >>  55   isDirectModelInitialised = false;
                                                   >>  56   G4VEmFluctuationModel* f=0;
                                                   >>  57   G4Region* r=0;
                                                   >>  58   theEmModelManagerForFwdModels->AddEmModel(1, theDirectStdBremModel, f, r);
 62                                                    59 
 63   fEmModelManagerForFwdModels = new G4EmModelM << 
 64   fEmModelManagerForFwdModels->AddEmModel(1, f << 
 65   SetApplyCutInRange(true);                        60   SetApplyCutInRange(true);
                                                   >>  61   highKinEnergy= 1.*GeV;
                                                   >>  62   lowKinEnergy = 1.0*keV;
 66                                                    63 
 67   fElectron = G4Electron::Electron();          <<  64   lastCZ =0.;
 68   fGamma    = G4Gamma::Gamma();                << 
 69                                                    65 
 70   fAdjEquivDirectPrimPart   = G4AdjointElectro <<  66   
 71   fAdjEquivDirectSecondPart = G4AdjointGamma:: <<  67   theAdjEquivOfDirectPrimPartDef =G4AdjointElectron::AdjointElectron();
 72   fDirectPrimaryPart        = fElectron;       <<  68   theAdjEquivOfDirectSecondPartDef=G4AdjointGamma::AdjointGamma();
 73   fSecondPartSameType       = false;           <<  69   theDirectPrimaryPartDef=G4Electron::Electron();
                                                   >>  70   second_part_of_same_type=false;
                                                   >>  71 
                                                   >>  72   
                                                   >>  73   /*UsePenelopeModel=false;
                                                   >>  74   if (UsePenelopeModel) {
                                                   >>  75     G4PenelopeBremsstrahlungModel* thePenelopeModel = new G4PenelopeBremsstrahlungModel(G4Electron::Electron(),"PenelopeBrem");
                                                   >>  76   theEmModelManagerForFwdModels = new G4EmModelManager();
                                                   >>  77     isPenelopeModelInitialised = false;
                                                   >>  78   G4VEmFluctuationModel* f=0;
                                                   >>  79   G4Region* r=0;
                                                   >>  80   theDirectEMModel=thePenelopeModel;
                                                   >>  81   theEmModelManagerForFwdModels->AddEmModel(1, thePenelopeModel, f, r);
                                                   >>  82   }
                                                   >>  83   */  
                                                   >>  84   
 74                                                    85 
 75   fCSManager = G4AdjointCSManager::GetAdjointC <<  86   
 76 }                                                  87 }
                                                   >>  88 ////////////////////////////////////////////////////////////////////////////////
                                                   >>  89 //
                                                   >>  90 G4AdjointBremsstrahlungModel::G4AdjointBremsstrahlungModel():
                                                   >>  91  G4VEmAdjointModel("AdjointeBremModel")
                                                   >>  92 {
                                                   >>  93   SetUseMatrix(false);
                                                   >>  94   SetUseMatrixPerElement(false);
                                                   >>  95 
                                                   >>  96   theDirectStdBremModel = new G4SeltzerBergerModel();
                                                   >>  97   theDirectEMModel=theDirectStdBremModel;
                                                   >>  98   theEmModelManagerForFwdModels = new G4EmModelManager();
                                                   >>  99   isDirectModelInitialised = false;
                                                   >> 100   G4VEmFluctuationModel* f=0;
                                                   >> 101   G4Region* r=0;
                                                   >> 102   theEmModelManagerForFwdModels->AddEmModel(1, theDirectStdBremModel, f, r);
                                                   >> 103  // theDirectPenelopeBremModel =0;
                                                   >> 104   SetApplyCutInRange(true);
                                                   >> 105   highKinEnergy= 1.*GeV;
                                                   >> 106   lowKinEnergy = 1.0*keV;
                                                   >> 107   lastCZ =0.;
                                                   >> 108   theAdjEquivOfDirectPrimPartDef =G4AdjointElectron::AdjointElectron();
                                                   >> 109   theAdjEquivOfDirectSecondPartDef=G4AdjointGamma::AdjointGamma();
                                                   >> 110   theDirectPrimaryPartDef=G4Electron::Electron();
                                                   >> 111   second_part_of_same_type=false;
 77                                                   112 
                                                   >> 113 }
 78 //////////////////////////////////////////////    114 ////////////////////////////////////////////////////////////////////////////////
                                                   >> 115 //
 79 G4AdjointBremsstrahlungModel::~G4AdjointBremss    116 G4AdjointBremsstrahlungModel::~G4AdjointBremsstrahlungModel()
 80 {                                              << 117 {if (theDirectStdBremModel) delete theDirectStdBremModel;
 81   if(fEmModelManagerForFwdModels)              << 118  if (theEmModelManagerForFwdModels) delete theEmModelManagerForFwdModels;
 82     delete fEmModelManagerForFwdModels;        << 
 83 }                                                 119 }
 84                                                   120 
 85 //////////////////////////////////////////////    121 ////////////////////////////////////////////////////////////////////////////////
 86 void G4AdjointBremsstrahlungModel::SampleSecon << 122 //
 87   const G4Track& aTrack, G4bool isScatProjToPr << 123 void G4AdjointBremsstrahlungModel::SampleSecondaries(const G4Track& aTrack,
 88   G4ParticleChange* fParticleChange)           << 124                        G4bool IsScatProjToProjCase,
                                                   >> 125                  G4ParticleChange* fParticleChange)
 89 {                                                 126 {
 90   if(!fUseMatrix)                              << 127  if (!UseMatrix) return RapidSampleSecondaries(aTrack,IsScatProjToProjCase,fParticleChange); 
 91     return RapidSampleSecondaries(aTrack, isSc << 
 92                                                << 
 93   const G4DynamicParticle* theAdjointPrimary = << 
 94   DefineCurrentMaterial(aTrack.GetMaterialCuts << 
 95                                                << 
 96   G4double adjointPrimKinEnergy   = theAdjoint << 
 97   G4double adjointPrimTotalEnergy = theAdjoint << 
 98                                                   128 
 99   if(adjointPrimKinEnergy > GetHighEnergyLimit << 129  const G4DynamicParticle* theAdjointPrimary =aTrack.GetDynamicParticle();
100   {                                            << 130  DefineCurrentMaterial(aTrack.GetMaterialCutsCouple());
101     return;                                    << 131  
102   }                                            << 132  
                                                   >> 133  G4double adjointPrimKinEnergy = theAdjointPrimary->GetKineticEnergy();
                                                   >> 134  G4double adjointPrimTotalEnergy = theAdjointPrimary->GetTotalEnergy();
                                                   >> 135  
                                                   >> 136  if (adjointPrimKinEnergy>HighEnergyLimit*0.999){
                                                   >> 137   return;
                                                   >> 138  }
                                                   >> 139   
                                                   >> 140   G4double projectileKinEnergy = SampleAdjSecEnergyFromCSMatrix(adjointPrimKinEnergy,
                                                   >> 141                 IsScatProjToProjCase);
                                                   >> 142  //Weight correction
                                                   >> 143  //-----------------------             
                                                   >> 144  CorrectPostStepWeight(fParticleChange, 
                                                   >> 145            aTrack.GetWeight(), 
                                                   >> 146            adjointPrimKinEnergy,
                                                   >> 147            projectileKinEnergy,
                                                   >> 148            IsScatProjToProjCase); 
                                                   >> 149  
                                                   >> 150  
                                                   >> 151  //Kinematic
                                                   >> 152  //---------
                                                   >> 153  G4double projectileM0 = theAdjEquivOfDirectPrimPartDef->GetPDGMass();
                                                   >> 154  G4double projectileTotalEnergy = projectileM0+projectileKinEnergy;
                                                   >> 155  G4double projectileP2 = projectileTotalEnergy*projectileTotalEnergy - projectileM0*projectileM0; 
                                                   >> 156  G4double projectileP = std::sqrt(projectileP2);
                                                   >> 157  
                                                   >> 158  
                                                   >> 159  //Angle of the gamma direction with the projectile taken from G4eBremsstrahlungModel
                                                   >> 160  //------------------------------------------------
                                                   >> 161   G4double u;
                                                   >> 162   const G4double a1 = 0.625 , a2 = 3.*a1 , d = 27. ;
103                                                   163 
104   G4double projectileKinEnergy =               << 164   if (9./(9.+d) > G4UniformRand()) u = - std::log(G4UniformRand()*G4UniformRand())/a1;
105     SampleAdjSecEnergyFromCSMatrix(adjointPrim << 165      else                          u = - std::log(G4UniformRand()*G4UniformRand())/a2;
106                                                   166 
107   // Weight correction                         << 167   G4double theta = u*electron_mass_c2/projectileTotalEnergy;
108   CorrectPostStepWeight(fParticleChange, aTrac << 
109                         adjointPrimKinEnergy,  << 
110                         isScatProjToProj);     << 
111                                                << 
112   // Kinematic                                 << 
113   G4double projectileM0          = fAdjEquivDi << 
114   G4double projectileTotalEnergy = projectileM << 
115   G4double projectileP2 =                      << 
116     projectileTotalEnergy * projectileTotalEne << 
117   G4double projectileP = std::sqrt(projectileP << 
118                                                   168 
119   // Angle of the gamma direction with the pro << 169   G4double sint = std::sin(theta);
120   // G4eBremsstrahlungModel                    << 170   G4double cost = std::cos(theta);
121   G4double u;                                  << 171 
122   if(0.25 > G4UniformRand())                   << 172   G4double phi = twopi * G4UniformRand() ;
123     u = -std::log(G4UniformRand() * G4UniformR << 173   
124   else                                         << 174   G4ThreeVector projectileMomentum;
125     u = -std::log(G4UniformRand() * G4UniformR << 175   projectileMomentum=G4ThreeVector(std::cos(phi)*sint,std::sin(phi)*sint,cost)*projectileP; //gamma frame
126                                                << 176   if (IsScatProjToProjCase) {//the adjoint primary is the scattered e-
127   G4double theta = u * electron_mass_c2 / proj << 177     G4ThreeVector gammaMomentum = (projectileTotalEnergy-adjointPrimTotalEnergy)*G4ThreeVector(0.,0.,1.);
128   G4double sint  = std::sin(theta);            << 178   G4ThreeVector dirProd=projectileMomentum-gammaMomentum;
129   G4double cost  = std::cos(theta);            << 179   G4double cost1 = std::cos(dirProd.angle(projectileMomentum));
130                                                << 180   G4double sint1 =  std::sqrt(1.-cost1*cost1);
131   G4double phi = twopi * G4UniformRand();      << 181   projectileMomentum=G4ThreeVector(std::cos(phi)*sint1,std::sin(phi)*sint1,cost1)*projectileP;
132                                                << 182   
133   G4ThreeVector projectileMomentum =           << 
134     G4ThreeVector(std::cos(phi) * sint, std::s << 
135     projectileP;  // gamma frame               << 
136   if(isScatProjToProj)                         << 
137   {  // the adjoint primary is the scattered e << 
138     G4ThreeVector gammaMomentum =              << 
139       (projectileTotalEnergy - adjointPrimTota << 
140       G4ThreeVector(0., 0., 1.);               << 
141     G4ThreeVector dirProd = projectileMomentum << 
142     G4double cost1        = std::cos(dirProd.a << 
143     G4double sint1        = std::sqrt(1. - cos << 
144     projectileMomentum =                       << 
145       G4ThreeVector(std::cos(phi) * sint1, std << 
146       projectileP;                             << 
147   }                                               183   }
148                                                << 184   
149   projectileMomentum.rotateUz(theAdjointPrimar    185   projectileMomentum.rotateUz(theAdjointPrimary->GetMomentumDirection());
150                                                << 186  
151   if(!isScatProjToProj)                        << 187  
152   {  // kill the primary and add a secondary   << 188  
153     fParticleChange->ProposeTrackStatus(fStopA << 189   if (!IsScatProjToProjCase ){ //kill the primary and add a secondary
154     fParticleChange->AddSecondary(             << 190   fParticleChange->ProposeTrackStatus(fStopAndKill);
155       new G4DynamicParticle(fAdjEquivDirectPri << 191   fParticleChange->AddSecondary(new G4DynamicParticle(theAdjEquivOfDirectPrimPartDef,projectileMomentum));
156   }                                            << 192   }
157   else                                         << 193   else {
158   {                                            << 194   fParticleChange->ProposeEnergy(projectileKinEnergy);
159     fParticleChange->ProposeEnergy(projectileK << 195   fParticleChange->ProposeMomentumDirection(projectileMomentum.unit());
160     fParticleChange->ProposeMomentumDirection( << 196   
161   }                                            << 197   } 
162 }                                              << 198 } 
163                                                << 
164 //////////////////////////////////////////////    199 ////////////////////////////////////////////////////////////////////////////////
165 void G4AdjointBremsstrahlungModel::RapidSample << 200 //
166   const G4Track& aTrack, G4bool isScatProjToPr << 201 void G4AdjointBremsstrahlungModel::RapidSampleSecondaries(const G4Track& aTrack,
167   G4ParticleChange* fParticleChange)           << 202                        G4bool IsScatProjToProjCase,
168 {                                              << 203                  G4ParticleChange* fParticleChange)
169   const G4DynamicParticle* theAdjointPrimary = << 204 { 
170   DefineCurrentMaterial(aTrack.GetMaterialCuts << 205 
171                                                << 206  const G4DynamicParticle* theAdjointPrimary =aTrack.GetDynamicParticle();
172   G4double adjointPrimKinEnergy   = theAdjoint << 207  DefineCurrentMaterial(aTrack.GetMaterialCutsCouple());
173   G4double adjointPrimTotalEnergy = theAdjoint << 208  
                                                   >> 209  
                                                   >> 210  G4double adjointPrimKinEnergy = theAdjointPrimary->GetKineticEnergy();
                                                   >> 211  G4double adjointPrimTotalEnergy = theAdjointPrimary->GetTotalEnergy();
                                                   >> 212  
                                                   >> 213  if (adjointPrimKinEnergy>HighEnergyLimit*0.999){
                                                   >> 214   return;
                                                   >> 215  }
                                                   >> 216   
                                                   >> 217  G4double projectileKinEnergy =0.;
                                                   >> 218  G4double gammaEnergy=0.;
                                                   >> 219  G4double diffCSUsed=0.; 
                                                   >> 220  if (!IsScatProjToProjCase){
                                                   >> 221   gammaEnergy=adjointPrimKinEnergy;
                                                   >> 222   G4double Emax = GetSecondAdjEnergyMaxForProdToProjCase(adjointPrimKinEnergy);
                                                   >> 223         G4double Emin=  GetSecondAdjEnergyMinForProdToProjCase(adjointPrimKinEnergy);;
                                                   >> 224   if (Emin>=Emax) return;
                                                   >> 225   projectileKinEnergy=Emin*std::pow(Emax/Emin,G4UniformRand());
                                                   >> 226   diffCSUsed=100.*CS_biasing_factor*lastCZ/projectileKinEnergy;
                                                   >> 227   
                                                   >> 228  }
                                                   >> 229  else { G4double Emax = GetSecondAdjEnergyMaxForScatProjToProjCase(adjointPrimKinEnergy);
                                                   >> 230   G4double Emin = GetSecondAdjEnergyMinForScatProjToProjCase(adjointPrimKinEnergy,currentTcutForDirectSecond);
                                                   >> 231   if (Emin>=Emax) return;
                                                   >> 232   G4double f1=(Emin-adjointPrimKinEnergy)/Emin;
                                                   >> 233   G4double f2=(Emax-adjointPrimKinEnergy)/Emax/f1;
                                                   >> 234   //G4cout<<"f1 and f2 "<<f1<<'\t'<<f2<<G4endl;
                                                   >> 235   projectileKinEnergy=adjointPrimKinEnergy/(1.-f1*std::pow(f2,G4UniformRand()));
                                                   >> 236   gammaEnergy=projectileKinEnergy-adjointPrimKinEnergy;
                                                   >> 237   diffCSUsed=lastCZ*adjointPrimKinEnergy/projectileKinEnergy/gammaEnergy;
                                                   >> 238   
                                                   >> 239  }
                                                   >> 240   
                                                   >> 241   
                                                   >> 242   
                                                   >> 243                 
                                                   >> 244  //Weight correction
                                                   >> 245  //-----------------------
                                                   >> 246  //First w_corr is set to the ratio between adjoint total CS and fwd total CS
                                                   >> 247  G4double w_corr=G4AdjointCSManager::GetAdjointCSManager()->GetPostStepWeightCorrection();
                                                   >> 248 
                                                   >> 249  //Then another correction is needed due to the fact that a biaised differential CS has been used rather than the one consistent with the direct model
                                                   >> 250  //Here we consider the true  diffCS as the one obtained by the numericla differentiation over Tcut of the direct CS, corrected by the Migdal term.
                                                   >> 251  //Basically any other differential CS   diffCS could be used here (example Penelope). 
                                                   >> 252  
                                                   >> 253  G4double diffCS = DiffCrossSectionPerVolumePrimToSecond(currentMaterial, projectileKinEnergy, gammaEnergy);
                                                   >> 254  w_corr*=diffCS/diffCSUsed;
                                                   >> 255      
                                                   >> 256  G4double new_weight = aTrack.GetWeight()*w_corr;
                                                   >> 257  fParticleChange->SetParentWeightByProcess(false);
                                                   >> 258  fParticleChange->SetSecondaryWeightByProcess(false);
                                                   >> 259  fParticleChange->ProposeParentWeight(new_weight);
                                                   >> 260  
                                                   >> 261  //Kinematic
                                                   >> 262  //---------
                                                   >> 263  G4double projectileM0 = theAdjEquivOfDirectPrimPartDef->GetPDGMass();
                                                   >> 264  G4double projectileTotalEnergy = projectileM0+projectileKinEnergy;
                                                   >> 265  G4double projectileP2 = projectileTotalEnergy*projectileTotalEnergy - projectileM0*projectileM0; 
                                                   >> 266  G4double projectileP = std::sqrt(projectileP2);
                                                   >> 267  
                                                   >> 268  
                                                   >> 269  //Angle of the gamma direction with the projectile taken from G4eBremsstrahlungModel
                                                   >> 270  //------------------------------------------------
                                                   >> 271   G4double u;
                                                   >> 272   const G4double a1 = 0.625 , a2 = 3.*a1 , d = 27. ;
174                                                   273 
175   if(adjointPrimKinEnergy > GetHighEnergyLimit << 274   if (9./(9.+d) > G4UniformRand()) u = - std::log(G4UniformRand()*G4UniformRand())/a1;
176   {                                            << 275      else                          u = - std::log(G4UniformRand()*G4UniformRand())/a2;
177     return;                                    << 
178   }                                            << 
179                                                   276 
180   G4double projectileKinEnergy = 0.;           << 277   G4double theta = u*electron_mass_c2/projectileTotalEnergy;
181   G4double gammaEnergy         = 0.;           << 
182   G4double diffCSUsed          = 0.;           << 
183   if(!isScatProjToProj)                        << 
184   {                                            << 
185     gammaEnergy   = adjointPrimKinEnergy;      << 
186     G4double Emax = GetSecondAdjEnergyMaxForPr << 
187     G4double Emin = GetSecondAdjEnergyMinForPr << 
188     if(Emin >= Emax)                           << 
189       return;                                  << 
190     projectileKinEnergy = Emin * std::pow(Emax << 
191     diffCSUsed          = fCsBiasingFactor * f << 
192   }                                            << 
193   else                                         << 
194   {                                            << 
195     G4double Emax =                            << 
196       GetSecondAdjEnergyMaxForScatProjToProj(a << 
197     G4double Emin =                            << 
198       GetSecondAdjEnergyMinForScatProjToProj(a << 
199     if(Emin >= Emax)                           << 
200       return;                                  << 
201     G4double f1 = (Emin - adjointPrimKinEnergy << 
202     G4double f2 = (Emax - adjointPrimKinEnergy << 
203     projectileKinEnergy =                      << 
204       adjointPrimKinEnergy / (1. - f1 * std::p << 
205     gammaEnergy = projectileKinEnergy - adjoin << 
206     diffCSUsed =                               << 
207       fLastCZ * adjointPrimKinEnergy / project << 
208   }                                            << 
209                                                   278 
210   // Weight correction:                        << 279   G4double sint = std::sin(theta);
211   // First w_corr is set to the ratio between  << 280   G4double cost = std::cos(theta);
212   // if this has to be done in the model.      << 281 
213   // For the case of forced interaction this w << 282   G4double phi = twopi * G4UniformRand() ;
214   // the forced interaction.  It is important  << 283   
215   // creation of the secondary                 << 284   G4ThreeVector projectileMomentum;
216   G4double w_corr = fOutsideWeightFactor;      << 285   projectileMomentum=G4ThreeVector(std::cos(phi)*sint,std::sin(phi)*sint,cost)*projectileP; //gamma frame
217   if(fInModelWeightCorr)                       << 286   if (IsScatProjToProjCase) {//the adjoint primary is the scattered e-
218   {                                            << 287     G4ThreeVector gammaMomentum = (projectileTotalEnergy-adjointPrimTotalEnergy)*G4ThreeVector(0.,0.,1.);
219     w_corr = fCSManager->GetPostStepWeightCorr << 288   G4ThreeVector dirProd=projectileMomentum-gammaMomentum;
                                                   >> 289   G4double cost1 = std::cos(dirProd.angle(projectileMomentum));
                                                   >> 290   G4double sint1 =  std::sqrt(1.-cost1*cost1);
                                                   >> 291   projectileMomentum=G4ThreeVector(std::cos(phi)*sint1,std::sin(phi)*sint1,cost1)*projectileP;
                                                   >> 292   
220   }                                               293   }
221                                                << 294   
222   // Then another correction is needed due to  << 
223   // differential CS has been used rather than << 
224   // direct model Here we consider the true di << 
225   // numerical differentiation over Tcut of th << 
226   // Migdal term. Basically any other differen << 
227   // (example Penelope).                       << 
228   G4double diffCS = DiffCrossSectionPerVolumeP << 
229     fCurrentMaterial, projectileKinEnergy, gam << 
230   w_corr *= diffCS / diffCSUsed;               << 
231                                                << 
232   G4double new_weight = aTrack.GetWeight() * w << 
233   fParticleChange->SetParentWeightByProcess(fa << 
234   fParticleChange->SetSecondaryWeightByProcess << 
235   fParticleChange->ProposeParentWeight(new_wei << 
236                                                << 
237   // Kinematic                                 << 
238   G4double projectileM0          = fAdjEquivDi << 
239   G4double projectileTotalEnergy = projectileM << 
240   G4double projectileP2 =                      << 
241     projectileTotalEnergy * projectileTotalEne << 
242   G4double projectileP = std::sqrt(projectileP << 
243                                                << 
244   // Use the angular model of the forward mode << 
245   // Dummy dynamic particle to use the model   << 
246   G4DynamicParticle* aDynPart =                << 
247     new G4DynamicParticle(fElectron, G4ThreeVe << 
248                                                << 
249   // Get the element from the direct model     << 
250   const G4Element* elm = fDirectModel->SelectR << 
251     fCurrentCouple, fElectron, projectileKinEn << 
252   G4int Z         = elm->GetZasInt();          << 
253   G4double energy = aDynPart->GetTotalEnergy() << 
254   G4ThreeVector projectileMomentum =           << 
255     fDirectModel->GetAngularDistribution()->Sa << 
256                                             fC << 
257   G4double phi = projectileMomentum.getPhi();  << 
258                                                << 
259   if(isScatProjToProj)                         << 
260   {  // the adjoint primary is the scattered e << 
261     G4ThreeVector gammaMomentum =              << 
262       (projectileTotalEnergy - adjointPrimTota << 
263       G4ThreeVector(0., 0., 1.);               << 
264     G4ThreeVector dirProd = projectileMomentum << 
265     G4double cost1        = std::cos(dirProd.a << 
266     G4double sint1        = std::sqrt(1. - cos << 
267     projectileMomentum =                       << 
268       G4ThreeVector(std::cos(phi) * sint1, std << 
269       projectileP;                             << 
270   }                                            << 
271                                                << 
272   projectileMomentum.rotateUz(theAdjointPrimar    295   projectileMomentum.rotateUz(theAdjointPrimary->GetMomentumDirection());
273                                                << 296  
274   if(!isScatProjToProj)                        << 297  
275   {  // kill the primary and add a secondary   << 298  
276     fParticleChange->ProposeTrackStatus(fStopA << 299   if (!IsScatProjToProjCase ){ //kill the primary and add a secondary
277     fParticleChange->AddSecondary(             << 300   fParticleChange->ProposeTrackStatus(fStopAndKill);
278       new G4DynamicParticle(fAdjEquivDirectPri << 301   fParticleChange->AddSecondary(new G4DynamicParticle(theAdjEquivOfDirectPrimPartDef,projectileMomentum));
279   }                                            << 302   }
280   else                                         << 303   else {
281   {                                            << 304   fParticleChange->ProposeEnergy(projectileKinEnergy);
282     fParticleChange->ProposeEnergy(projectileK << 305   fParticleChange->ProposeMomentumDirection(projectileMomentum.unit());
283     fParticleChange->ProposeMomentumDirection( << 306   
284   }                                            << 307   } 
285 }                                              << 308 } 
                                                   >> 309 ////////////////////////////////////////////////////////////////////////////////
                                                   >> 310 //
                                                   >> 311 G4double G4AdjointBremsstrahlungModel::DiffCrossSectionPerVolumePrimToSecond(const G4Material* aMaterial,
                                                   >> 312                                       G4double kinEnergyProj,  // kinetic energy of the primary particle before the interaction 
                                                   >> 313                                       G4double kinEnergyProd // kinetic energy of the secondary particle 
                                                   >> 314               )
                                                   >> 315 {if (!isDirectModelInitialised) {
                                                   >> 316   theEmModelManagerForFwdModels->Initialise(G4Electron::Electron(),G4Gamma::Gamma(),1.,0);
                                                   >> 317   isDirectModelInitialised =true;
                                                   >> 318  }
                                                   >> 319 
                                                   >> 320  return  DiffCrossSectionPerVolumePrimToSecondApproximated2(aMaterial,
                                                   >> 321                                                      kinEnergyProj, 
                                                   >> 322                                                      kinEnergyProd);
                                                   >> 323  /*return G4VEmAdjointModel::DiffCrossSectionPerVolumePrimToSecond(aMaterial,
                                                   >> 324                                                      kinEnergyProj, 
                                                   >> 325                                                      kinEnergyProd);*/                                 
                                                   >> 326 }             
286                                                   327 
287 //////////////////////////////////////////////    328 ////////////////////////////////////////////////////////////////////////////////
288 G4double G4AdjointBremsstrahlungModel::DiffCro << 329 //
289   const G4Material* aMaterial,                 << 330 G4double G4AdjointBremsstrahlungModel::DiffCrossSectionPerVolumePrimToSecondApproximated1(
290   G4double kinEnergyProj,  // kin energy of pr << 331                 const G4Material* aMaterial,
291   G4double kinEnergyProd   // kinetic energy o << 332                                       G4double kinEnergyProj,  // kinetic energy of the primary particle before the interaction 
292 )                                              << 333                                       G4double kinEnergyProd // kinetic energy of the secondary particle 
                                                   >> 334               )
293 {                                                 335 {
294   if(!fIsDirectModelInitialised)               << 336  G4double dCrossEprod=0.;
295   {                                            << 337  G4double Emax_proj = GetSecondAdjEnergyMaxForProdToProjCase(kinEnergyProd);
296     fEmModelManagerForFwdModels->Initialise(fE << 338  G4double Emin_proj = GetSecondAdjEnergyMinForProdToProjCase(kinEnergyProd);
297     fIsDirectModelInitialised = true;          << 339  
298   }                                            << 340  
299   return G4VEmAdjointModel::DiffCrossSectionPe << 341  //In this approximation we consider that the secondary gammas are sampled with 1/Egamma energy distribution
300     aMaterial, kinEnergyProj, kinEnergyProd);  << 342  //This is what is applied in the discrete standard model before the  rejection test  that make a correction
                                                   >> 343  //The application of the same rejection function is not possible here.
                                                   >> 344  //The differentiation of the CS over Ecut does not produce neither a good differential CS. That is due to the 
                                                   >> 345  // fact that in the discrete model the differential CS and the integrated CS are both fitted but separatly and 
                                                   >> 346  // therefore do not allow a correct numerical differentiation of the integrated CS to get the differential one. 
                                                   >> 347  // In the future we plan to use the brem secondary spectra from the G4Penelope implementation 
                                                   >> 348  
                                                   >> 349  if (kinEnergyProj>Emin_proj && kinEnergyProj<=Emax_proj){
                                                   >> 350   G4double sigma=theDirectEMModel->CrossSectionPerVolume(aMaterial,theDirectPrimaryPartDef,kinEnergyProj,1.*keV);
                                                   >> 351   dCrossEprod=sigma/kinEnergyProd/std::log(kinEnergyProj/keV);
                                                   >> 352  }
                                                   >> 353  return dCrossEprod;
                                                   >> 354   
301 }                                                 355 }
302                                                   356 
303 //////////////////////////////////////////////    357 ////////////////////////////////////////////////////////////////////////////////
304 G4double G4AdjointBremsstrahlungModel::Adjoint << 358 //
305   const G4MaterialCutsCouple* aCouple, G4doubl << 359 G4double G4AdjointBremsstrahlungModel::DiffCrossSectionPerVolumePrimToSecondApproximated2(
306   G4bool isScatProjToProj)                     << 360                 const G4Material* material,
                                                   >> 361                                       G4double kinEnergyProj,  // kinetic energy of the primary particle before the interaction 
                                                   >> 362                                       G4double kinEnergyProd // kinetic energy of the secondary particle 
                                                   >> 363               )
307 {                                                 364 {
308   static constexpr G4double maxEnergy = 100. * << 365  //In this approximation we derive the direct cross section over Tcut=gamma energy, en after apply the Migdla correction factor 
309   // 2.78.. == std::exp(1.)                    << 366   //used in the direct model
310   if(!fIsDirectModelInitialised)               << 367  
311   {                                            << 368  G4double dCrossEprod=0.;
312     fEmModelManagerForFwdModels->Initialise(fE << 369  
313     fIsDirectModelInitialised = true;          << 370  const G4ElementVector* theElementVector = material->GetElementVector();
                                                   >> 371  const double* theAtomNumDensityVector = material->GetAtomicNumDensityVector();
                                                   >> 372  G4double dum=0.;
                                                   >> 373  G4double E1=kinEnergyProd,E2=kinEnergyProd*1.001;
                                                   >> 374  G4double dE=E2-E1;
                                                   >> 375  for (size_t i=0; i<material->GetNumberOfElements(); i++) { 
                                                   >> 376   G4double C1=theDirectEMModel->ComputeCrossSectionPerAtom(theDirectPrimaryPartDef,kinEnergyProj,(*theElementVector)[i]->GetZ(),dum ,E1);
                                                   >> 377   G4double C2=theDirectEMModel->ComputeCrossSectionPerAtom(theDirectPrimaryPartDef,kinEnergyProj,(*theElementVector)[i]->GetZ(),dum,E2);
                                                   >> 378   dCrossEprod += theAtomNumDensityVector[i] * (C1-C2)/dE;
                                                   >> 379    
                                                   >> 380  }
                                                   >> 381  
                                                   >> 382  //Now the Migdal correction
                                                   >> 383 /*
                                                   >> 384  G4double totalEnergy = kinEnergyProj+electron_mass_c2 ;
                                                   >> 385  G4double kp2 = MigdalConstant*totalEnergy*totalEnergy
                                                   >> 386                                              *(material->GetElectronDensity());
                                                   >> 387                  
                                                   >> 388  
                                                   >> 389  G4double MigdalFactor = 1./(1.+kp2/(kinEnergyProd*kinEnergyProd)); // its seems that the factor used in the CS compuation i the direct
                                                   >> 390                     //model is different than the one used in the secondary sampling by a
                                                   >> 391                     //factor (1.+kp2) To be checked!
                                                   >> 392  
                                                   >> 393  dCrossEprod*=MigdalFactor;
                                                   >> 394  */
                                                   >> 395  return dCrossEprod;
                                                   >> 396   
                                                   >> 397 }
                                                   >> 398 ////////////////////////////////////////////////////////////////////////////////
                                                   >> 399 //
                                                   >> 400 G4double G4AdjointBremsstrahlungModel::AdjointCrossSection(const G4MaterialCutsCouple* aCouple,
                                                   >> 401                      G4double primEnergy,
                                                   >> 402                      G4bool IsScatProjToProjCase)
                                                   >> 403 { if (!isDirectModelInitialised) {
                                                   >> 404     theEmModelManagerForFwdModels->Initialise(G4Electron::Electron(),G4Gamma::Gamma(),1.,0);
                                                   >> 405   isDirectModelInitialised =true;
314   }                                               406   }
315   if(fUseMatrix)                               << 407   if (UseMatrix) return G4VEmAdjointModel::AdjointCrossSection(aCouple,primEnergy,IsScatProjToProjCase);
316     return G4VEmAdjointModel::AdjointCrossSect << 
317                                                << 
318   DefineCurrentMaterial(aCouple);                 408   DefineCurrentMaterial(aCouple);
319   G4double Cross = 0.;                         << 409   G4double Cross=0.;
320   // this gives the constant above             << 410   lastCZ=theDirectEMModel->CrossSectionPerVolume(aCouple->GetMaterial(),theDirectPrimaryPartDef,100.*MeV,100.*MeV/std::exp(1.));//this give the constant above
321   fLastCZ = fDirectModel->CrossSectionPerVolum << 411   
322     aCouple->GetMaterial(), fDirectPrimaryPart << 412   if (!IsScatProjToProjCase ){
323                                                << 413     G4double Emax_proj = GetSecondAdjEnergyMaxForProdToProjCase(primEnergy);
324   if(!isScatProjToProj)                        << 414     G4double Emin_proj = GetSecondAdjEnergyMinForProdToProjCase(primEnergy);
325   {                                            << 415   if (Emax_proj>Emin_proj && primEnergy > currentTcutForDirectSecond) Cross= 100.*CS_biasing_factor*lastCZ*std::log(Emax_proj/Emin_proj);
326     G4double Emax_proj = GetSecondAdjEnergyMax << 416   }
327     G4double Emin_proj = GetSecondAdjEnergyMin << 417   else {
328     if(Emax_proj > Emin_proj && primEnergy > f << 418     G4double Emax_proj = GetSecondAdjEnergyMaxForScatProjToProjCase(primEnergy);
329       Cross = fCsBiasingFactor * fLastCZ * std << 419   G4double Emin_proj = GetSecondAdjEnergyMinForScatProjToProjCase(primEnergy,currentTcutForDirectSecond);
330   }                                            << 420   if (Emax_proj>Emin_proj) Cross= lastCZ*std::log((Emax_proj-primEnergy)*Emin_proj/Emax_proj/(Emin_proj-primEnergy));
331   else                                         << 421     
332   {                                            << 422   }
333     G4double Emax_proj = GetSecondAdjEnergyMax << 423   return Cross; 
334     G4double Emin_proj =                       << 424 }              
335       GetSecondAdjEnergyMinForScatProjToProj(p << 425 
336     if(Emax_proj > Emin_proj)                  << 426 G4double G4AdjointBremsstrahlungModel::GetAdjointCrossSection(const G4MaterialCutsCouple* aCouple,
337       Cross = fLastCZ * std::log((Emax_proj -  << 427                      G4double primEnergy,
338                                  Emax_proj / ( << 428                      G4bool IsScatProjToProjCase)
339   }                                            << 429 { 
340   return Cross;                                << 430   return AdjointCrossSection(aCouple, primEnergy,IsScatProjToProjCase);
                                                   >> 431   lastCZ=theDirectEMModel->CrossSectionPerVolume(aCouple->GetMaterial(),theDirectPrimaryPartDef,100.*MeV,100.*MeV/std::exp(1.));//this give the constant above
                                                   >> 432   return G4VEmAdjointModel::GetAdjointCrossSection(aCouple, primEnergy,IsScatProjToProjCase);
                                                   >> 433     
341 }                                                 434 }
                                                   >> 435 
                                                   >> 436 
                                                   >> 437 
342                                                   438