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Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. * 17 // * 17 // * * 18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************* 24 // ******************************************************************** 25 // 25 // >> 26 // >> 27 // 26 // G4ForwardXrayTR 28 // G4ForwardXrayTR 27 // 29 // 28 // Class for description 30 // Class for description 29 // 31 // 30 // Class for forward X-ray transition radiatio 32 // Class for forward X-ray transition radiation generated 31 // by relativistic charged particle crossed in 33 // by relativistic charged particle crossed interface between material 1 32 // and material 2 (1 -> 2) 34 // and material 2 (1 -> 2) 33 35 34 // History: 36 // History: 35 // 22.09.97, V. Grichine (Vladimir.Grichine@ce 37 // 22.09.97, V. Grichine (Vladimir.Grichine@cern.ch) 36 // 26.01.00, V.Grichine, new constructor and p 38 // 26.01.00, V.Grichine, new constructor and protected DM for fast sim. models 37 // 10.03.03, V.Ivanchenko migrade to "cut per 39 // 10.03.03, V.Ivanchenko migrade to "cut per region" 38 // 03.06.03, V.Ivanchenko fix compilation warn 40 // 03.06.03, V.Ivanchenko fix compilation warnings 39 41 40 #ifndef G4FORWARDXRAYTR_H 42 #ifndef G4FORWARDXRAYTR_H 41 #define G4FORWARDXRAYTR_H 43 #define G4FORWARDXRAYTR_H 42 44 >> 45 43 #include "globals.hh" 46 #include "globals.hh" 44 #include "G4Track.hh" << 47 #include "templates.hh" 45 #include "G4TransitionRadiation.hh" << 48 #include "geomdefs.hh" 46 #include "G4VParticleChange.hh" << 49 #include "Randomize.hh" >> 50 #include "G4Step.hh" >> 51 #include "G4VDiscreteProcess.hh" >> 52 #include "G4DynamicParticle.hh" >> 53 #include "G4Material.hh" >> 54 #include "G4LogicalBorderSurface.hh" >> 55 #include "G4LogicalSkinSurface.hh" >> 56 #include "G4OpticalSurface.hh" >> 57 #include "G4OpticalPhoton.hh" >> 58 #include "G4TransportationManager.hh" 47 59 48 class G4ParticleDefinition; << 60 #include "G4TransitionRadiation.hh" 49 class G4PhysicsTable; << 61 #include "G4PhysicsTable.hh" 50 class G4PhysicsLogVector; << 62 #include "G4Gamma.hh" >> 63 #include "G4PhysicsLogVector.hh" 51 64 52 class G4ForwardXrayTR : public G4TransitionRad 65 class G4ForwardXrayTR : public G4TransitionRadiation 53 { 66 { 54 public: << 67 public: 55 explicit G4ForwardXrayTR(const G4String& mat << 56 const G4String& pro << 57 68 58 explicit G4ForwardXrayTR(const G4String& pro << 69 // Constructors 59 70 60 ~G4ForwardXrayTR(); << 71 explicit G4ForwardXrayTR( const G4String& matName1, // G4Material* pMat1, >> 72 const G4String& matName2, // G4Material* pMat2, >> 73 const G4String& processName="XrayTR" ); >> 74 >> 75 explicit G4ForwardXrayTR( const G4String& processName="XrayTR" ); 61 76 62 G4ForwardXrayTR(const G4ForwardXrayTR& right << 77 // Destructor // virtual 63 G4ForwardXrayTR& operator=(const G4ForwardXr << 64 78 65 /////////////////////// Methods ////// << 79 virtual ~G4ForwardXrayTR(); 66 80 67 void ProcessDescription(std::ostream&) const << 81 /////////////////////// Methods ///////////////////////////////// 68 void DumpInfo() const override { ProcessDesc << 69 82 70 void BuildXrayTRtables(); 83 void BuildXrayTRtables(); 71 84 72 G4double GetMeanFreePath(const G4Track&, G4d 85 G4double GetMeanFreePath(const G4Track&, G4double, 73 G4ForceCondition* c << 86 G4ForceCondition* condition) override; 74 87 75 G4VParticleChange* PostStepDoIt(const G4Trac << 88 G4VParticleChange* PostStepDoIt( const G4Track& aTrack, 76 const G4Step << 89 const G4Step& aStep ) override; 77 90 78 G4double GetEnergyTR(G4int iMat, G4int jMat, 91 G4double GetEnergyTR(G4int iMat, G4int jMat, G4int iTkin) const; >> 92 >> 93 G4double GetThetaTR(G4int iMat, G4int jMat, G4int iTkin) const; 79 94 80 G4double GetThetaTR(G4int iMat, G4int jMat, << 81 95 82 ///////////////////// Angle distribution // << 96 ///////////////////// Angle distribution ///////////////////////////// >> 97 // 83 98 84 G4double SpectralAngleTRdensity(G4double ene << 99 G4double SpectralAngleTRdensity( G4double energy, 85 G4double var << 100 G4double varAngle ) const override; 86 101 87 G4double AngleDensity(G4double energy, G4dou << 102 G4double AngleDensity( G4double energy, >> 103 G4double varAngle ) const; 88 104 89 G4double EnergyInterval(G4double energy1, G4 << 105 G4double EnergyInterval( G4double energy1, 90 G4double varAngle) c << 106 G4double energy2, >> 107 G4double varAngle ) const; 91 108 92 G4double AngleSum(G4double varAngle1, G4doub << 109 G4double AngleSum( G4double varAngle1, >> 110 G4double varAngle2 ) const; 93 111 94 ///////////////////////// Energy distributi << 112 ///////////////////////// Energy distribution /////////////////////////////// 95 113 96 G4double SpectralDensity(G4double energy, G4 << 114 G4double SpectralDensity( G4double energy, >> 115 G4double x ) const; 97 116 98 G4double AngleInterval(G4double energy, G4do << 117 G4double AngleInterval( G4double energy, 99 G4double varAngle2) c << 118 G4double varAngle1, >> 119 G4double varAngle2 ) const; 100 120 101 G4double EnergySum(G4double energy1, G4doubl << 121 G4double EnergySum( G4double energy1, >> 122 G4double energy2 ) const; 102 123 103 /////////////////////////// Access functio << 124 >> 125 /////////////////////////// Access functions //////////////////////////// 104 126 105 G4PhysicsTable* GetAngleDistrTable(); 127 G4PhysicsTable* GetAngleDistrTable(); 106 G4PhysicsTable* GetEnergyDistrTable(); 128 G4PhysicsTable* GetEnergyDistrTable(); 107 129 108 static G4int GetSympsonNumber(); << 130 static G4int GetSympsonNumber(); 109 static G4int GetBinTR(); << 131 static G4int GetBinTR(); 110 132 111 static G4double GetMinProtonTkin(); 133 static G4double GetMinProtonTkin(); 112 static G4double GetMaxProtonTkin(); 134 static G4double GetMaxProtonTkin(); 113 static G4int GetTotBin(); << 135 static G4int GetTotBin(); >> 136 >> 137 >> 138 protected: // for access from X-ray TR fast simulation models >> 139 >> 140 // private : /////////////// Data members /////////////////////////// >> 141 >> 142 G4ParticleDefinition* fPtrGamma; // pointer to TR photon >> 143 >> 144 const std::vector<G4double>* fGammaCutInKineticEnergy; >> 145 // TR photon cut in energy array >> 146 G4double fGammaTkinCut; // Tkin cut of TR photon in current mat. >> 147 >> 148 G4PhysicsTable* fAngleDistrTable; >> 149 G4PhysicsTable* fEnergyDistrTable; >> 150 >> 151 G4PhysicsLogVector* fProtonEnergyVector; >> 152 >> 153 static G4int fSympsonNumber; // Accuracy of Sympson integration >> 154 >> 155 static G4double fTheMinEnergyTR; // static min TR energy >> 156 static G4double fTheMaxEnergyTR; // static max TR energy >> 157 G4double fMinEnergyTR; // min TR energy in material >> 158 G4double fMaxEnergyTR; // max TR energy in material >> 159 static G4double fTheMaxAngle; // max theta of TR quanta >> 160 static G4double fTheMinAngle; // max theta of TR quanta >> 161 G4double fMaxThetaTR; // max theta of TR quanta >> 162 static G4int fBinTR; // number of bins in TR vectors >> 163 >> 164 static G4double fMinProtonTkin; // min Tkin of proton in tables >> 165 static G4double fMaxProtonTkin; // max Tkin of proton in tables >> 166 static G4int fTotBin; // number of bins in log scale >> 167 G4double fGamma; // current Lorentz factor >> 168 >> 169 static G4double fPlasmaCof; // physical consts for plasma energy >> 170 static G4double fCofTR; >> 171 >> 172 G4double fSigma1; // plasma energy Sq of matter1 >> 173 G4double fSigma2; // plasma energy Sq of matter2 >> 174 >> 175 private: >> 176 // Operators >> 177 >> 178 G4ForwardXrayTR(const G4ForwardXrayTR& right) = delete; >> 179 >> 180 G4ForwardXrayTR& operator=(const G4ForwardXrayTR& right) = delete; >> 181 >> 182 // G4bool operator==(const G4ForwardXrayTR& right)const; >> 183 // G4bool operator!=(const G4ForwardXrayTR& right)const; >> 184 >> 185 }; // end of G4ForwardXrayTR class --------------------------- >> 186 >> 187 #endif // G4FORWARDXRAYTR_H 114 188 115 protected: // for access from X-ray TR fast << 116 static constexpr G4double fTheMinEnergyTR = << 117 1. * CLHEP::keV; // static min TR energy << 118 static constexpr G4double fTheMaxEnergyTR = << 119 100. * CLHEP::keV; << 120 static constexpr G4double fTheMaxAngle = 1.0 << 121 static constexpr G4double fTheMinAngle = 5.0 << 122 static constexpr G4double fMinProtonTkin = << 123 100. * CLHEP::GeV; // min Tkin of proton << 124 static constexpr G4double fMaxProtonTkin = << 125 100. * CLHEP::TeV; // max Tkin of proton << 126 static constexpr G4double fPlasmaCof = << 127 4.0 * CLHEP::pi * CLHEP::fine_structure_co << 128 CLHEP::hbarc * CLHEP::hbarc / << 129 CLHEP::electron_mass_c2; // physical cons << 130 static constexpr G4double fCofTR = CLHEP::fi << 131 << 132 static constexpr G4int fSympsonNumber = << 133 100; // Acc << 134 static constexpr G4int fBinTR = 50; // nu << 135 static constexpr G4int fTotBin = 50; // num << 136 << 137 const std::vector<G4double>* fGammaCutInKine << 138 // TR photon cut in energy array << 139 << 140 G4ParticleDefinition* fPtrGamma; // pointer << 141 << 142 G4PhysicsTable* fAngleDistrTable; << 143 G4PhysicsTable* fEnergyDistrTable; << 144 << 145 G4PhysicsLogVector* fProtonEnergyVector; << 146 << 147 G4double fMinEnergyTR; // min TR energy i << 148 G4double fMaxEnergyTR; // max TR energy i << 149 G4double fMaxThetaTR; // max theta of TR << 150 G4double fGamma; // current Lorentz << 151 G4double fGammaTkinCut; // Tkin cut of TR p << 152 G4double fSigma1; // plasma energy Sq << 153 G4double fSigma2; // plasma energy Sq << 154 189 155 G4int secID = -1; // creator modelID << 156 }; << 157 190 158 #endif // G4FORWARDXRAYTR_H << 159 191