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Geant4/processes/electromagnetic/xrays/include/G4VXTRenergyLoss.hh

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Differences between /processes/electromagnetic/xrays/include/G4VXTRenergyLoss.hh (Version 11.3.0) and /processes/electromagnetic/xrays/include/G4VXTRenergyLoss.hh (Version 8.1.p1)


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 26 ////////////////////////////////////////////// << 
 27 //                                                 26 //
                                                   >>  27 // $Id: G4VXTRenergyLoss.hh,v 1.18 2006/06/29 19:55:55 gunter Exp $
                                                   >>  28 // GEANT4 tag $Name: geant4-08-01-patch-01 $
                                                   >>  29 //
                                                   >>  30 // 
                                                   >>  31 ///////////////////////////////////////////////////////////////////////////
                                                   >>  32 // 
 28 // base class for 'fast' parametrisation model     33 // base class for 'fast' parametrisation model describing X-ray transition
 29 // created in some G4Envelope. Angular distrib <<  34 // created in some G4Envelope. Anglur distribuiton is very rough !!! (see DoIt
 30 // method                                          35 // method
 31 //                                             <<  36 // 
 32 // History:                                        37 // History:
 33 // 06.10.05  V. Grichine first step to discret <<  38 // 06.10.05 V. Grichine first step to discrete process
 34 // 15.01.02  V. Grichine first version         <<  39 // 15.01.02 V. Grichine first version
 35 // 28.07.05, P.Gumplinger add G4ProcessType to     40 // 28.07.05, P.Gumplinger add G4ProcessType to constructor
 36 // 28.09.07, V.Ivanchenko general cleanup with <<  41 //
 37 // 19.09.21, V. Grichine, set/get functions fo << 
 38                                                    42 
 39 #ifndef G4VXTRenergyLoss_h                     << 
 40 #define G4VXTRenergyLoss_h 1                   << 
 41                                                    43 
                                                   >>  44 #ifndef G4XTRenergyLoss_h
                                                   >>  45 #define G4XTRenergyLoss_h 1
                                                   >>  46 
                                                   >>  47 
                                                   >>  48 #include <complex>
 42 #include "globals.hh"                              49 #include "globals.hh"
 43 #include "G4Gamma.hh"                          <<  50 #include "Randomize.hh"
                                                   >>  51 
 44 #include "G4LogicalVolume.hh"                      52 #include "G4LogicalVolume.hh"
 45 #include "G4Material.hh"                       <<  53 
 46 #include "G4ParticleChange.hh"                 << 
 47 #include "G4PhysicsTable.hh"                       54 #include "G4PhysicsTable.hh"
                                                   >>  55 #include "G4PhysicsLogVector.hh"
                                                   >>  56 #include "G4Gamma.hh"
                                                   >>  57 #include "G4ThreeVector.hh"
                                                   >>  58 #include "G4ParticleMomentum.hh"
 48 #include "G4Step.hh"                               59 #include "G4Step.hh"
 49 #include "G4Track.hh"                              60 #include "G4Track.hh"
                                                   >>  61 #include "G4VContinuousProcess.hh"
 50 #include "G4VDiscreteProcess.hh"                   62 #include "G4VDiscreteProcess.hh"
                                                   >>  63 #include "G4DynamicParticle.hh"
                                                   >>  64 #include "G4Material.hh" 
                                                   >>  65 #include "G4PhysicsTable.hh"
                                                   >>  66 #include "G4MaterialPropertiesTable.hh"
                                                   >>  67 #include "G4PhysicsOrderedFreeVector.hh"
                                                   >>  68 #include "G4Integrator.hh"
                                                   >>  69 #include "G4ParticleChange.hh"
                                                   >>  70 
                                                   >>  71 
 51                                                    72 
 52 class G4SandiaTable;                           << 
 53 class G4VParticleChange;                           73 class G4VParticleChange;
 54 class G4PhysicsFreeVector;                         74 class G4PhysicsFreeVector;
 55 class G4PhysicsLinearVector;                   << 
 56 class G4PhysicsLogVector;                      << 
 57                                                    75 
 58 class G4VXTRenergyLoss : public G4VDiscretePro <<  76 class G4XTRenergyLoss : public G4VDiscreteProcess  // G4VContinuousProcess
 59 {                                                  77 {
 60  public:                                       <<  78 public:
 61   explicit G4VXTRenergyLoss(G4LogicalVolume* a <<  79 
 62                             G4Material*, G4dou <<  80   G4XTRenergyLoss (G4LogicalVolume *anEnvelope,G4Material*,G4Material*,
 63                             const G4String& pr <<  81                     G4double,G4double,G4int,
 64                             G4ProcessType type <<  82                     const G4String & processName = "XTRenergyLoss",
 65   virtual ~G4VXTRenergyLoss();                 <<  83                     G4ProcessType type = fElectromagnetic);
                                                   >>  84    virtual  ~G4XTRenergyLoss ();
                                                   >>  85 
                                                   >>  86   // These virtual has to be implemented in inherited particular TR radiators
                                                   >>  87  
                                                   >>  88   virtual  G4double GetStackFactor( G4double energy, G4double gamma,
                                                   >>  89                                                      G4double varAngle );
                                                   >>  90 
 66                                                    91 
 67   virtual void ProcessDescription(std::ostream <<  92   G4bool IsApplicable(const G4ParticleDefinition&);
 68   virtual void DumpInfo() const override { Pro << 
 69                                                    93 
 70   G4VXTRenergyLoss(G4VXTRenergyLoss&) = delete <<  94   G4double GetContinuousStepLimit(const G4Track& aTrack,
 71   G4VXTRenergyLoss& operator=(const G4VXTRener <<  95           G4double  ,
                                                   >>  96           G4double  ,
                                                   >>  97                                         G4double& );
                                                   >>  98         // Returns the continuous step limit defined by the XTR process.
 72                                                    99 
 73   // Virtual methods to be implemented in inhe << 100   G4VParticleChange* AlongStepDoIt(const G4Track& aTrack, 
 74   virtual G4double GetStackFactor(G4double ene << 101            const G4Step&  aStep);
 75                                   G4double var << 
 76                                                   102 
 77   virtual G4bool IsApplicable(const G4Particle << 103   G4VParticleChange* PostStepDoIt(const G4Track& aTrack, 
                                                   >> 104            const G4Step&  aStep);
 78                                                   105 
 79   virtual G4VParticleChange* PostStepDoIt(cons << 106   G4double GetMeanFreePath(const G4Track& aTrack,
 80                                           cons << 107                            G4double previousStepSize,
                                                   >> 108                            G4ForceCondition* condition);
 81                                                   109 
 82   virtual G4double GetMeanFreePath(const G4Tra << 110   void BuildPhysicsTable(const G4ParticleDefinition&);
 83                                    G4double pr << 111   void BuildTable() ;
 84                                    G4ForceCond << 112   void BuildEnergyTable() ;
                                                   >> 113   void BuildAngleTable() ;
                                                   >> 114   void BuildGlobalAngleTable() ;
 85                                                   115 
 86   virtual void BuildPhysicsTable(const G4Parti << 116   G4complex OneInterfaceXTRdEdx( G4double energy, 
 87   void BuildEnergyTable();                     << 117                                 G4double gamma,
 88   void BuildAngleForEnergyBank();              << 118                                 G4double varAngle ) ;
 89                                                   119 
 90   void BuildTable(){};                         << 120   G4double SpectralAngleXTRdEdx(G4double varAngle) ;
 91   void BuildAngleTable();                      << 
 92   void BuildGlobalAngleTable();                << 
 93                                                   121 
 94   G4complex OneInterfaceXTRdEdx(G4double energ << 122   virtual  G4double SpectralXTRdEdx(G4double energy) ;
 95                                 G4double varAn << 
 96                                                   123 
 97   G4double SpectralAngleXTRdEdx(G4double varAn << 124   G4double AngleSpectralXTRdEdx(G4double energy) ;
 98                                                   125 
 99   virtual G4double SpectralXTRdEdx(G4double en << 126   G4double AngleXTRdEdx(G4double varAngle) ;
100                                                   127 
101   G4double AngleSpectralXTRdEdx(G4double energ << 
102                                                   128 
103   G4double AngleXTRdEdx(G4double varAngle);    << 129   /////////////////////////////////////////////////////////////
                                                   >> 130 
                                                   >> 131   G4double OneBoundaryXTRNdensity( G4double energy,
                                                   >> 132                                    G4double gamma,
                                                   >> 133            G4double varAngle ) const ;
104                                                   134 
105   G4double OneBoundaryXTRNdensity(G4double ene << 
106                                   G4double var << 
107                                                   135 
108   // for photon energy distribution tables        136   // for photon energy distribution tables
109   G4double XTRNSpectralAngleDensity(G4double v << 
110   G4double XTRNSpectralDensity(G4double energy << 
111                                                   137 
                                                   >> 138   G4double XTRNSpectralAngleDensity(G4double varAngle) ;
                                                   >> 139   G4double XTRNSpectralDensity(G4double energy) ;
                                                   >> 140   
112   // for photon angle distribution tables         141   // for photon angle distribution tables
113   G4double XTRNAngleSpectralDensity(G4double e << 
114   G4double XTRNAngleDensity(G4double varAngle) << 
115                                                   142 
116   void GetNumberOfPhotons();                   << 143   G4double XTRNAngleSpectralDensity(G4double energy) ;
                                                   >> 144   G4double XTRNAngleDensity(G4double varAngle) ;
                                                   >> 145 
                                                   >> 146   void GetNumberOfPhotons() ;  
117                                                   147 
118   // Auxiliary functions for plate/gas materia    148   // Auxiliary functions for plate/gas material parameters
119   G4double GetPlateFormationZone(G4double, G4d << 149 
120   G4complex GetPlateComplexFZ(G4double, G4doub << 150   G4double  GetPlateFormationZone(G4double,G4double,G4double);
121   void ComputePlatePhotoAbsCof();              << 151   G4complex GetPlateComplexFZ(G4double,G4double,G4double);
122   G4double GetPlateLinearPhotoAbs(G4double);   << 152   void      ComputePlatePhotoAbsCof();
123   void GetPlateZmuProduct();                   << 153   G4double  GetPlateLinearPhotoAbs(G4double);
124   G4double GetPlateZmuProduct(G4double, G4doub << 154   void      GetPlateZmuProduct() ;
125                                                << 155   G4double  GetPlateZmuProduct(G4double,G4double,G4double);
126   G4double GetGasFormationZone(G4double, G4dou << 156 
127   G4complex GetGasComplexFZ(G4double, G4double << 157   G4double  GetGasFormationZone(G4double,G4double,G4double);
128   void ComputeGasPhotoAbsCof();                << 158   G4complex GetGasComplexFZ(G4double,G4double,G4double);
129   G4double GetGasLinearPhotoAbs(G4double);     << 159   void      ComputeGasPhotoAbsCof();
130   void GetGasZmuProduct();                     << 160   G4double  GetGasLinearPhotoAbs(G4double);
131   G4double GetGasZmuProduct(G4double, G4double << 161   void      GetGasZmuProduct();
                                                   >> 162   G4double  GetGasZmuProduct(G4double,G4double,G4double);
132                                                   163 
133   G4double GetPlateCompton(G4double);             164   G4double GetPlateCompton(G4double);
134   G4double GetGasCompton(G4double);               165   G4double GetGasCompton(G4double);
135   G4double GetComptonPerAtom(G4double, G4doubl << 166   G4double GetComptonPerAtom(G4double,G4double);
136                                                << 
137   G4double GetXTRrandomEnergy(G4double scaledT << 
138   G4double GetXTRenergy(G4int iPlace, G4double << 
139                                                   167 
140   G4double GetRandomAngle(G4double energyXTR,  << 168   G4double GetXTRrandomEnergy( G4double scaledTkin, G4int iTkin );
141   G4double GetAngleXTR(G4int iTR, G4double pos << 169   G4double GetXTRenergy( G4int iPlace, G4double position, G4int iTransfer  );
142                                                   170 
143   // set/get methods for class fields          << 171   G4double GetRandomAngle( G4double energyXTR, G4int iTkin );
144                                                << 172   G4double GetAngleXTR(G4int iTR,G4double position,G4int iAngle);
145   void     SetGamma(G4double gamma) { fGamma = << 
146   G4double GetGamma() { return fGamma; };      << 
147   void     SetEnergy(G4double energy) { fEnerg << 
148   G4double GetEnergy() { return fEnergy; };    << 
149   void     SetVarAngle(G4double varAngle) { fV << 
150   G4double GetVarAngle() { return fVarAngle; } << 
151   void   SetCompton(G4bool pC) { fCompton = pC << 
152   G4bool GetCompton() { return fCompton; };    << 
153                                                << 
154   G4int GetKrange(){ return fKrange;};         << 
155   void SetKrange( G4int kk ){ fKrange = kk;};  << 
156                                                << 
157                                                << 
158   void     SetAlphaGas(G4double ag){ fAlphaGas << 
159   G4double GetAlphaGas() { return fAlphaGas; } << 
160   void     SetAlphaPlate(G4double ap){ fAlphaP << 
161   G4double GetAlphaPlate() { return fAlphaPlat << 
162                                                << 
163   void     SetTheMinEnergyTR(G4double minetr){ << 
164   G4double GetTheMinEnergyTR() { return fTheMi << 
165   void     SetTheMaxEnergyTR(G4double maxetr){ << 
166   G4double GetTheMaxEnergyTR() { return fTheMa << 
167                                                << 
168   void     SetMinEnergyTR(G4double minetr){ fM << 
169   G4double GetMinEnergyTR() { return fMinEnerg << 
170   void     SetMaxEnergyTR(G4double maxetr){ fM << 
171   G4double GetMaxEnergyTR() { return fMaxEnerg << 
172                                                << 
173   void     SetTheMinAngle(G4double minang){ fT << 
174   G4double GetTheMinAngle() { return fTheMinAn << 
175   void     SetTheMaxAngle(G4double maxang){ fT << 
176   G4double GetTheMaxAngle() { return fTheMaxAn << 
177                                                << 
178   void     SetMinThetaTR(G4double minatr){ fMi << 
179   G4double GetMinThetaTR() { return fMinThetaT << 
180   void     SetMaxThetaTR(G4double maxatr){ fMa << 
181   G4double GetMaxThetaTR() { return fMaxThetaT << 
182                                                   173 
183   // modes of XTR angle distribution           << 174   G4double GetGamma()   {return fGamma;}; 
184                                                << 175   G4double GetEnergy()  {return fEnergy;};                
185   void   SetFastAngle(G4bool fatr){ fFastAngle << 176   G4double GetVarAngle(){return fVarAngle;};
186   G4bool GetFastAngle() { return fFastAngle; } << 177                
187   void   SetAngleRadDistr(G4bool fatr){ fAngle << 178   void SetGamma(G4double gamma)      {fGamma    = gamma;}; 
188   G4bool GetAngleRadDistr() { return fAngleRad << 179   void SetEnergy(G4double energy)    {fEnergy   = energy;};                
189                                                << 180   void SetVarAngle(G4double varAngle){fVarAngle = varAngle;};               
                                                   >> 181   void SetAngleRadDistr(G4bool pAngleRadDistr){fAngleRadDistr=pAngleRadDistr;};               
                                                   >> 182   void SetCompton(G4bool pC){fCompton=pC;};               
                                                   >> 183   void SetVerboseLevel(G4int verbose){fVerbose=verbose;};
190                                                   184 
191                                                << 
192                                                   185 
193   G4PhysicsLogVector* GetProtonVector() { retu << 186   static G4PhysicsLogVector* GetProtonVector(){ return fProtonEnergyVector;};
194   G4int GetTotBin() { return fTotBin; };       << 187   static G4int GetTotBin(){return fTotBin;};           
195   G4PhysicsFreeVector* GetAngleVector(G4double    188   G4PhysicsFreeVector* GetAngleVector(G4double energy, G4int n);
                                                   >> 189 protected:
196                                                   190 
197  protected:                                    << 191   G4ParticleDefinition* fPtrGamma ;  // pointer to TR photon
198   //   min TR energy                           << 
199   G4double fTheMinEnergyTR;                    << 
200   //   max TR energy                           << 
201   G4double fTheMaxEnergyTR;                    << 
202   G4double fTheMinAngle;  //  min theta of TR  << 
203   G4double fTheMaxAngle;  //  1.e-4;  //  max  << 
204                                                   192 
205   // static const members                      << 193   G4double* fGammaCutInKineticEnergy ; // TR photon cut in energy array
206                                                << 194   G4double  fGammaTkinCut ;            // Tkin cut of TR photon in current mat.
207   // min Tkin of proton in tables              << 195   G4LogicalVolume* fEnvelope ;
208   static constexpr G4double fMinProtonTkin = 1 << 196   G4PhysicsTable* fAngleDistrTable ;
209   // max Tkin of proton in tables              << 197   G4PhysicsTable* fEnergyDistrTable ;
210   static constexpr G4double fMaxProtonTkin = 1 << 198 
211   // physical constants for plasma energy      << 199   static G4PhysicsLogVector* fProtonEnergyVector ;
212   static constexpr G4double fPlasmaCof =       << 200   static G4PhysicsLogVector* fXTREnergyVector ;
213     4. * CLHEP::pi * CLHEP::fine_structure_con << 201 
214     CLHEP::hbarc / CLHEP::electron_mass_c2;    << 202 
215   static constexpr G4double fCofTR = CLHEP::fi << 203   static G4double fTheMinEnergyTR;            //  static min TR energy
216                                                << 204   static G4double fTheMaxEnergyTR;            //  static max TR energy
217   G4int fTotBin;  //  number of bins in log-ga << 205          G4double fMinEnergyTR;               //  min TR energy in material
218   G4int fBinTR;   //  number of bins in TR ene << 206          G4double fMaxEnergyTR;               //  max TR energy in material
219   G4int fKrange;                               << 207   static G4double fTheMaxAngle;               //  max theta of TR quanta
220   G4ParticleDefinition* fPtrGamma;  // pointer << 208   static G4double fTheMinAngle;               //  max theta of TR quanta
221                                                << 209          G4double fMaxThetaTR;                //  max theta of TR quanta
222   G4double* fGammaCutInKineticEnergy;  // TR p << 210   static G4int    fBinTR;                     //  number of bins in TR vectors
223   G4LogicalVolume* fEnvelope;                  << 211 
224   G4PhysicsTable* fAngleDistrTable;            << 212   static G4double fMinProtonTkin;             // min Tkin of proton in tables
225   G4PhysicsTable* fEnergyDistrTable;           << 213   static G4double fMaxProtonTkin;             // max Tkin of proton in tables
226   G4PhysicsTable* fAngleForEnergyTable;        << 214   static G4int    fTotBin;                    // number of bins in log scale
227   G4PhysicsLogVector* fProtonEnergyVector;     << 215          G4double fGamma;                     // current Lorentz factor
228   G4PhysicsLogVector* fXTREnergyVector;        << 216          G4double fEnergy;                    // energy and
229   G4SandiaTable* fPlatePhotoAbsCof;            << 217          G4double fVarAngle;                  // angle squared
230   G4SandiaTable* fGasPhotoAbsCof;              << 
231                                                << 
232   G4ParticleChange fParticleChange;            << 
233   std::vector<G4PhysicsTable*> fAngleBank;     << 
234                                                << 
235   G4double fGammaTkinCut;  // Tkin cut of TR p << 
236   G4double fMinEnergyTR;   //  min TR energy i << 
237   G4double fMaxEnergyTR;   //  max TR energy i << 
238   G4double fMinThetaTR, fMaxThetaTR;    //  mi << 
239   G4double fTotalDist;                         << 
240   G4double fPlateThick;                        << 
241   G4double fGasThick;                          << 
242   G4double fAlphaPlate;                        << 
243   G4double fAlphaGas;                          << 
244   G4double fGamma;     // current Lorentz fact << 
245   G4double fEnergy;    // energy and           << 
246   G4double fVarAngle;  // angle squared!       << 
247   G4double fLambda;                               218   G4double fLambda;
248   G4double fSigma1;                            << 
249   G4double fSigma2;  // plasma energy Sq of ma << 
250                                                   219 
251   G4int fMatIndex1;                            << 220   static G4double fPlasmaCof ;               // physical consts for plasma energy
252   G4int fMatIndex2;                            << 221   static G4double fCofTR ;  
253   G4int fPlateNumber;                          << 222 
254                                                   223 
255   G4bool fExitFlux;                               224   G4bool fExitFlux;
256   G4bool fFastAngle, fAngleRadDistr;           << 225   G4bool fAngleRadDistr;
257   G4bool fCompton;                                226   G4bool fCompton;
                                                   >> 227   G4double fSigma1, fSigma2 ;               // plasma energy Sq of matter1/2
                                                   >> 228 
                                                   >> 229   G4int fMatIndex1, fMatIndex2 ;
258                                                   230 
259   G4int secID = -1;  // creator modelID        << 231   G4int fPlateNumber ;
                                                   >> 232   G4double fTotalDist ;
                                                   >> 233   G4double** fPlatePhotoAbsCof ;
                                                   >> 234   G4int      fPlateIntervalNumber ;
                                                   >> 235   G4double   fPlateThick ;
                                                   >> 236  
                                                   >> 237   G4double** fGasPhotoAbsCof ;
                                                   >> 238   G4int      fGasIntervalNumber ;
                                                   >> 239   G4double   fGasThick ;     
                                                   >> 240   G4double fAlphaPlate, fAlphaGas ;
                                                   >> 241 
                                                   >> 242   G4ParticleChange fParticleChange;
                                                   >> 243 
                                                   >> 244   G4PhysicsTable*                    fAngleForEnergyTable;
                                                   >> 245   std::vector<G4PhysicsTable*>       fAngleBank;
                                                   >> 246   G4int fVerbose;
260 };                                                247 };
                                                   >> 248 
                                                   >> 249 typedef G4XTRenergyLoss G4VXTRenergyLoss;
261                                                   250 
262 #endif                                            251 #endif
263                                                   252