Geant4 Cross Reference |
>> 1 // This code implementation is the intellectual property of >> 2 // the GEANT4 collaboration. 1 // 3 // 2 // ******************************************* << 4 // By copying, distributing or modifying the Program (or any work 3 // * License and Disclaimer << 5 // based on the Program) you indicate your acceptance of this statement, 4 // * << 6 // and all its terms. 5 // * The Geant4 software is copyright of th << 6 // * the Geant4 Collaboration. It is provided << 7 // * conditions of the Geant4 Software License << 8 // * LICENSE and available at http://cern.ch/ << 9 // * include a list of copyright holders. << 10 // * << 11 // * Neither the authors of this software syst << 12 // * institutes,nor the agencies providing fin << 13 // * work make any representation or warran << 14 // * regarding this software system or assum << 15 // * use. Please see the license in the file << 16 // * for the full disclaimer and the limitatio << 17 // * << 18 // * This code implementation is the result << 19 // * technical work of the GEANT4 collaboratio << 20 // * By using, copying, modifying or distri << 21 // * any work based on the software) you ag << 22 // * use in resulting scientific publicati << 23 // * acceptance of all terms of the Geant4 Sof << 24 // ******************************************* << 25 // 7 // >> 8 // $Id: G4NeutrinoE.cc,v 1.3 2000/02/27 06:23:41 kurasige Exp $ >> 9 // GEANT4 tag $Name: geant4-03-00 $ >> 10 // >> 11 // 26 // ------------------------------------------- 12 // ---------------------------------------------------------------------- 27 // GEANT 4 class implementation file 13 // GEANT 4 class implementation file 28 // 14 // >> 15 // For information related to this code contact: >> 16 // CERN, CN Division, ASD Group 29 // History: first implementation, based o 17 // History: first implementation, based on object model of 30 // 4th April 1996, G.Cosmo << 18 // 4th April 1996, G.Cosmo 31 // by H.Kurashige,7 July 199 19 // by H.Kurashige,7 July 1996 32 // ******************************************* 20 // ********************************************************************** 33 // New impelemenataion as an utility class M << 21 34 // ------------------------------------------- << 22 #include "g4std/fstream" >> 23 #include "g4std/iomanip" 35 24 36 #include "G4NeutrinoE.hh" 25 #include "G4NeutrinoE.hh" 37 26 38 #include "G4ParticleTable.hh" << 27 // ###################################################################### 39 #include "G4String.hh" << 28 // ### NEUTRINO ### 40 #include "G4SystemOfUnits.hh" << 29 // ###################################################################### >> 30 >> 31 G4NeutrinoE::G4NeutrinoE( >> 32 const G4String& aName, G4double mass, >> 33 G4double width, G4double charge, >> 34 G4int iSpin, G4int iParity, >> 35 G4int iConjugation, G4int iIsospin, >> 36 G4int iIsospin3, G4int gParity, >> 37 const G4String& pType, G4int lepton, >> 38 G4int baryon, G4int encoding, >> 39 G4bool stable, G4double lifetime, >> 40 G4DecayTable *decaytable ) >> 41 : G4VLepton( aName,mass,width,charge,iSpin,iParity, >> 42 iConjugation,iIsospin,iIsospin3,gParity,pType, >> 43 lepton,baryon,encoding,stable,lifetime,decaytable ) >> 44 { >> 45 SetParticleSubType("e"); >> 46 } 41 47 42 G4NeutrinoE* G4NeutrinoE::theInstance = nullpt << 48 // ...................................................................... >> 49 // ... static member definitions ... >> 50 // ...................................................................... >> 51 // >> 52 // Arguments for constructor are as follows >> 53 // name mass width charge >> 54 // 2*spin parity C-conjugation >> 55 // 2*Isospin 2*Isospin3 G-parity >> 56 // type lepton number baryon number PDG encoding >> 57 // stable lifetime decay table 43 58 44 G4NeutrinoE* G4NeutrinoE::Definition() << 59 G4NeutrinoE G4NeutrinoE::theNeutrinoE( 45 { << 60 "nu_e", 0.0*MeV, 0.0*MeV, 0.0, 46 if (theInstance != nullptr) return theInstan << 47 const G4String name = "nu_e"; << 48 // search in particle table] << 49 G4ParticleTable* pTable = G4ParticleTable::G << 50 G4ParticleDefinition* anInstance = pTable->F << 51 if (anInstance == nullptr) { << 52 // create particle << 53 // << 54 // Arguments for constructor are as fol << 55 // name mass << 56 // 2*spin parity C- << 57 // 2*Isospin 2*Isospin3 << 58 // type lepton number ba << 59 // stable lifetime << 60 // shortlived subType << 61 << 62 // clang-format off << 63 anInstance = new G4ParticleDefinition( << 64 name, 0.0*MeV, << 65 1, 0, 0, 61 1, 0, 0, 66 0, 0, 0, 62 0, 0, 0, 67 "lepton", 1, 63 "lepton", 1, 0, 12, 68 true, -1.0, nullptr, << 64 true, 0.0, NULL 69 false, "e" << 65 ); 70 ); << 66 71 // clang-format on << 67 G4NeutrinoE* G4NeutrinoE::NeutrinoEDefinition() {return &theNeutrinoE;} 72 } << 68 // initialization for static cut values 73 theInstance = static_cast<G4NeutrinoE*>(anIn << 69 G4double G4NeutrinoE::theNeutrinoELengthCut = -1.0; 74 return theInstance; << 70 G4double* G4NeutrinoE::theNeutrinoEKineticEnergyCuts = NULL; 75 } << 76 71 77 G4NeutrinoE* G4NeutrinoE::NeutrinoEDefinition( << 78 { << 79 return Definition(); << 80 } << 81 72 82 G4NeutrinoE* G4NeutrinoE::NeutrinoE() << 73 // ********************************************************************** >> 74 // **************************** SetCuts ********************************* >> 75 // ********************************************************************** >> 76 >> 77 void G4NeutrinoE::SetCuts(G4double aCut) 83 { 78 { 84 return Definition(); << 79 theCutInMaxInteractionLength = aCut; >> 80 >> 81 const G4MaterialTable* materialTable = G4Material::GetMaterialTable(); >> 82 // Create the vector of cuts in energy >> 83 // corresponding to the stopping range cut >> 84 if(theKineticEnergyCuts) delete [] theKineticEnergyCuts; >> 85 theKineticEnergyCuts = new G4double [materialTable->length()]; >> 86 >> 87 // Build range vector for every material, convert cut into energy-cut, >> 88 // fill theKineticEnergyCuts and delete the range vector >> 89 for (G4int J=0; J<materialTable->length(); J++) >> 90 { >> 91 G4Material* aMaterial = (*materialTable)[J]; >> 92 theKineticEnergyCuts[J] = 0.0*keV; >> 93 } >> 94 theNeutrinoELengthCut = theCutInMaxInteractionLength; >> 95 theNeutrinoEKineticEnergyCuts = theKineticEnergyCuts; >> 96 >> 97 // Rebuild the physics tables for every process for this particle type >> 98 85 } 99 } >> 100 >> 101 >> 102 86 103