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Please see the license in the file << 14 // * use. * 16 // * for the full disclaimer and the limitatio << 17 // * 15 // * * 18 // * This code implementation is the result << 16 // * This code implementation is the intellectual property of the * 19 // * technical work of the GEANT4 collaboratio << 17 // * GEANT4 collaboration. * 20 // * By using, copying, modifying or distri << 18 // * By copying, distributing or modifying the Program (or any work * 21 // * any work based on the software) you ag << 19 // * based on the Program) you indicate your acceptance of this * 22 // * use in resulting scientific publicati << 20 // * statement, and all its terms. * 23 // * acceptance of all terms of the Geant4 Sof << 24 // ******************************************* 21 // ******************************************************************** 25 // 22 // 26 // G4VRangeToEnergyConverter << 27 // 23 // 28 // Class description: << 24 // $Id: G4VRangeToEnergyConverter.hh,v 1.2 2003/11/08 06:10:48 kurasige Exp $ >> 25 // GEANT4 tag $Name: geant4-06-00-patch-01 $ 29 // 26 // 30 // Base class for Range to Energy Converters. << 27 // 31 // Cut in energy corresponding to given cut va << 28 // ------------------------------------------------------------ 32 // is calculated for a material by using Conve << 29 // GEANT 4 class header file 33 << 30 // 34 // Author: H.Kurashige, 05 October 2002 - Firs << 31 // 35 // ------------------------------------------- << 32 // Class Description 36 #ifndef G4VRangeToEnergyConverter_hh << 33 // This class is base class for Range to Energy Converters. 37 #define G4VRangeToEnergyConverter_hh 1 << 34 // Cut in energy corresponding to given cut value in range >> 35 // is calculated for a material by using Convert method >> 36 // >> 37 // ------------------------------------------------------------ >> 38 // First Implementation 5 Oct. 2002 H.Kurahige >> 39 // ------------------------------------------------------------ 38 40 39 #include <vector> << 41 #ifndef G4VRangeToEnergyConverter_h >> 42 #define G4VRangeToEnergyConverter_h 1 40 43 41 #include "globals.hh" 44 #include "globals.hh" >> 45 #include "G4ios.hh" >> 46 #include <vector> >> 47 42 #include "G4ParticleDefinition.hh" 48 #include "G4ParticleDefinition.hh" >> 49 >> 50 #include "G4PhysicsTable.hh" >> 51 #include "G4Element.hh" 43 #include "G4Material.hh" 52 #include "G4Material.hh" >> 53 class G4PhysicsLogVector; 44 54 45 class G4VRangeToEnergyConverter 55 class G4VRangeToEnergyConverter 46 { 56 { 47 public: << 57 public: // with description >> 58 // constructor >> 59 G4VRangeToEnergyConverter(); 48 60 49 explicit G4VRangeToEnergyConverter(); << 61 // copy constructor >> 62 G4VRangeToEnergyConverter(const G4VRangeToEnergyConverter &right); 50 63 >> 64 G4VRangeToEnergyConverter & operator=(const G4VRangeToEnergyConverter &right); >> 65 >> 66 public: >> 67 // destructor 51 virtual ~G4VRangeToEnergyConverter(); 68 virtual ~G4VRangeToEnergyConverter(); 52 69 53 // operators are not used << 70 // equal opperators 54 G4VRangeToEnergyConverter(const G4VRangeToEn << 71 G4int operator==(const G4VRangeToEnergyConverter &right) const; 55 G4VRangeToEnergyConverter& operator= << 72 G4int operator!=(const G4VRangeToEnergyConverter &right) const; 56 (const G4VRangeToEnergyConverter &r) = delet << 73 57 G4bool operator==(const G4VRangeToEnergyConv << 74 public: // with description 58 G4bool operator!=(const G4VRangeToEnergyConv << 75 // calculate energy cut from given range cut for the material 59 << 76 virtual G4double Convert(G4double rangeCut, const G4Material* material); 60 // Calculate energy cut from given range cut << 77 61 virtual G4double Convert(const G4double rang << 78 // set energy range for all particle type 62 << 79 static void SetEnergyRange(G4double lowedge, G4double highedge); 63 // Set energy range for all particle type << 64 // if highedge > 10 GeV, highedge value is n << 65 static void SetEnergyRange(const G4double lo << 66 80 67 // Get energy range for all particle type << 81 // get energy range for all particle type 68 static G4double GetLowEdgeEnergy(); 82 static G4double GetLowEdgeEnergy(); 69 static G4double GetHighEdgeEnergy(); 83 static G4double GetHighEdgeEnergy(); 70 << 71 // Get/set max cut energy for all particle t << 72 // No check on the value << 73 static G4double GetMaxEnergyCut(); << 74 static void SetMaxEnergyCut(const G4double v << 75 84 76 // Return pointer to the particle type which << 85 // return pointer to the particle type which this converter takes care 77 inline const G4ParticleDefinition* GetPartic << 86 const G4ParticleDefinition* GetParticleType() const; 78 87 79 inline void SetVerboseLevel(G4int value); << 88 // return the Loss Table 80 inline G4int GetVerboseLevel() const; << 89 const G4PhysicsTable* GetLossTable() const; 81 // control flag for output message << 90 //-------------- Loss Table ------------------------------------------ >> 91 // theLossTable is a collection of loss vectors for all elements. >> 92 // Each loss vector has energy loss values (cross section values >> 93 // for neutral particles) which are calculated by >> 94 // ComputeLoss(G4double AtomicNumber,G4double KineticEnergy). >> 95 >> 96 protected: >> 97 static G4double LowestEnergy, HighestEnergy; >> 98 >> 99 const G4ParticleDefinition* theParticle; >> 100 typedef G4PhysicsTable G4LossTable; >> 101 G4LossTable* theLossTable; >> 102 G4int NumberOfElements; >> 103 >> 104 typedef G4PhysicsLogVector G4LossVector; >> 105 G4int TotBin; >> 106 >> 107 protected:// with description >> 108 virtual void BuildLossTable(); >> 109 >> 110 virtual G4double ComputeLoss(G4double AtomicNumber, >> 111 G4double KineticEnergy >> 112 ) const; >> 113 >> 114 //-------------- Range Table ------------------------------------------ >> 115 protected: >> 116 typedef G4PhysicsLogVector G4RangeVector; >> 117 virtual void BuildRangeVector(const G4Material* aMaterial, >> 118 G4double maxEnergy, >> 119 G4double aMass, >> 120 G4RangeVector* rangeVector); >> 121 >> 122 protected: >> 123 G4double ConvertCutToKineticEnergy( >> 124 G4RangeVector* theRangeVector, >> 125 G4double theCutInLength, >> 126 size_t materialIndex >> 127 ) const; >> 128 >> 129 G4double RangeLinSimpson( >> 130 G4int numberOfElements, >> 131 const G4ElementVector* elementVector, >> 132 const G4double* atomicNumDensityVector, >> 133 G4double aMass, >> 134 G4double taulow, G4double tauhigh, >> 135 G4int nbin >> 136 ); >> 137 >> 138 G4double RangeLogSimpson( >> 139 G4int numberOfElements, >> 140 const G4ElementVector* elementVector, >> 141 const G4double* atomicNumDensityVector, >> 142 G4double aMass, >> 143 G4double ltaulow, G4double ltauhigh, >> 144 G4int nbin >> 145 ); >> 146 >> 147 public: // with description >> 148 void SetVerboseLevel(G4int value); >> 149 G4int GetVerboseLevel() const; >> 150 // controle flag for output message 82 // 0: Silent 151 // 0: Silent 83 // 1: Warning message 152 // 1: Warning message 84 // 2: More 153 // 2: More 85 154 86 protected: << 155 private: 87 << 156 G4int verboseLevel; 88 virtual G4double ComputeValue(const G4int Z, << 89 << 90 private: << 91 << 92 static void FillEnergyVector(const G4double << 93 << 94 G4double ConvertForGamma(const G4double rang << 95 << 96 G4double ConvertForElectron(const G4double r << 97 const G4Material << 98 << 99 inline G4double LiniearInterpolation(const G << 100 const G << 101 const G << 102 << 103 protected: << 104 << 105 const G4ParticleDefinition* theParticle = nu << 106 G4int fPDG = 0; << 107 157 108 private: << 109 << 110 static G4double sEmin; << 111 static G4double sEmax; << 112 static std::vector<G4double>* sEnergy; << 113 static G4int sNbinPerDecade; << 114 static G4int sNbin; << 115 << 116 G4int verboseLevel = 1; << 117 G4bool isFirstInstance = false; << 118 }; 158 }; 119 159 120 // ------------------ << 121 // Inline methods << 122 // ------------------ << 123 << 124 inline 160 inline 125 void G4VRangeToEnergyConverter::SetVerboseLeve << 161 void G4VRangeToEnergyConverter::SetVerboseLevel(G4int value) 126 { 162 { 127 verboseLevel = value; << 163 verboseLevel = value; 128 } 164 } 129 165 130 inline 166 inline 131 G4int G4VRangeToEnergyConverter::GetVerboseLev << 167 G4int G4VRangeToEnergyConverter::GetVerboseLevel() const 132 { 168 { 133 return verboseLevel; << 169 return verboseLevel; 134 } 170 } 135 171 136 inline << 137 const G4ParticleDefinition* G4VRangeToEnergyCo << 138 { << 139 return theParticle; << 140 } << 141 << 142 inline G4double G4VRangeToEnergyConverter::Lin << 143 const G4double e1, const G4dou << 144 const G4double r1, const G4dou << 145 { << 146 return (r1 == r2) ? e1 : e1 + (e2 - e1)*(r - << 147 } << 148 172 149 #endif 173 #endif >> 174 >> 175 >> 176 >> 177 >> 178 >> 179 >> 180 >> 181 150 182