[819] | 1 | // |
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| 2 | // ******************************************************************** |
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| 3 | // * License and Disclaimer * |
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| 4 | // * * |
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| 5 | // * The Geant4 software is copyright of the Copyright Holders of * |
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| 6 | // * the Geant4 Collaboration. It is provided under the terms and * |
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| 7 | // * conditions of the Geant4 Software License, included in the file * |
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| 8 | // * LICENSE and available at http://cern.ch/geant4/license . These * |
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| 9 | // * include a list of copyright holders. * |
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| 10 | // * * |
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| 11 | // * Neither the authors of this software system, nor their employing * |
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| 12 | // * institutes,nor the agencies providing financial support for this * |
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| 13 | // * work make any representation or warranty, express or implied, * |
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| 14 | // * regarding this software system or assume any liability for its * |
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| 15 | // * use. Please see the license in the file LICENSE and URL above * |
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| 16 | // * for the full disclaimer and the limitation of liability. * |
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| 17 | // * * |
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| 18 | // * This code implementation is the result of the scientific and * |
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| 19 | // * technical work of the GEANT4 collaboration. * |
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| 20 | // * By using, copying, modifying or distributing the software (or * |
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| 21 | // * any work based on the software) you agree to acknowledge its * |
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| 22 | // * use in resulting scientific publications, and indicate your * |
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| 23 | // * acceptance of all terms of the Geant4 Software license. * |
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| 24 | // ******************************************************************** |
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| 25 | // |
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| 26 | // neutron_hp -- source file |
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| 27 | // J.P. Wellisch, Nov-1996 |
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| 28 | // A prototype of the low energy neutron transport model. |
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| 29 | // |
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| 30 | // 070523 bug fix for G4FPE_DEBUG on by A. Howard ( and T. Koi) |
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[962] | 31 | // 080612 bug fix contribution from Benoit Pirard and Laurent Desorgher (Univ. Bern) #5 |
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[819] | 32 | // |
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| 33 | #include "G4NeutronHPAngular.hh" |
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| 34 | |
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| 35 | void G4NeutronHPAngular::Init(std::ifstream & aDataFile) |
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| 36 | { |
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| 37 | // G4cout << "here we are entering the Angular Init"<<G4endl; |
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| 38 | aDataFile >> theAngularDistributionType >> targetMass; |
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| 39 | aDataFile >> frameFlag; |
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| 40 | if(theAngularDistributionType == 0) |
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| 41 | { |
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| 42 | theIsoFlag = true; |
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| 43 | } |
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| 44 | else if(theAngularDistributionType==1) |
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| 45 | { |
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| 46 | G4int nEnergy; |
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| 47 | aDataFile >> nEnergy; |
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| 48 | theCoefficients = new G4NeutronHPLegendreStore(nEnergy); |
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| 49 | theCoefficients->InitInterpolation(aDataFile); |
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| 50 | G4double temp, energy; |
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| 51 | G4int tempdep, nLegendre; |
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| 52 | G4int i, ii; |
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| 53 | for (i=0; i<nEnergy; i++) |
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| 54 | { |
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| 55 | aDataFile >> temp >> energy >> tempdep >> nLegendre; |
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| 56 | energy *=eV; |
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| 57 | theCoefficients->Init(i, energy, nLegendre); |
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| 58 | theCoefficients->SetTemperature(i, temp); |
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| 59 | G4double coeff=0; |
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| 60 | for(ii=0; ii<nLegendre; ii++) |
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| 61 | { |
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| 62 | aDataFile >> coeff; |
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| 63 | theCoefficients->SetCoeff(i, ii+1, coeff); |
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| 64 | } |
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| 65 | } |
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| 66 | } |
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| 67 | else if (theAngularDistributionType==2) |
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| 68 | { |
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| 69 | G4int nEnergy; |
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| 70 | aDataFile >> nEnergy; |
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| 71 | theProbArray = new G4NeutronHPPartial(nEnergy, nEnergy); |
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| 72 | theProbArray->InitInterpolation(aDataFile); |
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| 73 | G4double temp, energy; |
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| 74 | G4int tempdep; |
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| 75 | for(G4int i=0; i<nEnergy; i++) |
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| 76 | { |
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| 77 | aDataFile >> temp >> energy >> tempdep; |
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| 78 | energy *= eV; |
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| 79 | theProbArray->SetT(i, temp); |
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| 80 | theProbArray->SetX(i, energy); |
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| 81 | theProbArray->InitData(i, aDataFile); |
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| 82 | } |
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| 83 | } |
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| 84 | else |
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| 85 | { |
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| 86 | theIsoFlag = false; |
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| 87 | G4cout << "unknown distribution found for Angular"<<G4endl; |
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| 88 | throw G4HadronicException(__FILE__, __LINE__, "unknown distribution needs implementation!!!"); |
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| 89 | } |
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| 90 | } |
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| 91 | |
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| 92 | void G4NeutronHPAngular::SampleAndUpdate(G4ReactionProduct & aHadron) |
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| 93 | { |
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| 94 | if(theIsoFlag) |
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| 95 | { |
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| 96 | // G4cout << "Angular result "<<aHadron.GetTotalMomentum()<<" "; |
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| 97 | // @@@ add code for isotropic emission in CMS. |
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| 98 | G4double costheta = 2.*G4UniformRand()-1; |
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| 99 | G4double theta = std::acos(costheta); |
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| 100 | G4double phi = twopi*G4UniformRand(); |
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| 101 | G4double sinth = std::sin(theta); |
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| 102 | G4double en = aHadron.GetTotalMomentum(); |
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| 103 | G4ThreeVector temp(en*sinth*std::cos(phi), en*sinth*std::sin(phi), en*std::cos(theta) ); |
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| 104 | aHadron.SetMomentum( temp ); |
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| 105 | aHadron.Lorentz(aHadron, -1.*theTarget); |
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| 106 | } |
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| 107 | else |
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| 108 | { |
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[962] | 109 | if(frameFlag == 1) // LAB |
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[819] | 110 | { |
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| 111 | G4double en = aHadron.GetTotalMomentum(); |
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| 112 | G4ReactionProduct boosted; |
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| 113 | boosted.Lorentz(theNeutron, theTarget); |
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| 114 | G4double kineticEnergy = boosted.GetKineticEnergy(); |
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[962] | 115 | G4double cosTh = 0.0; |
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| 116 | if(theAngularDistributionType == 1) cosTh = theCoefficients->SampleMax(kineticEnergy); |
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| 117 | if(theAngularDistributionType == 2) cosTh = theProbArray->Sample(kineticEnergy); |
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[819] | 118 | G4double theta = std::acos(cosTh); |
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| 119 | G4double phi = twopi*G4UniformRand(); |
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| 120 | G4double sinth = std::sin(theta); |
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| 121 | G4ThreeVector temp(en*sinth*std::cos(phi), en*sinth*std::sin(phi), en*std::cos(theta) ); |
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| 122 | aHadron.SetMomentum( temp ); |
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| 123 | } |
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[962] | 124 | else if(frameFlag == 2) // costh in CMS |
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[819] | 125 | { |
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| 126 | G4ReactionProduct boostedN; |
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| 127 | boostedN.Lorentz(theNeutron, theTarget); |
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| 128 | G4double kineticEnergy = boostedN.GetKineticEnergy(); |
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[962] | 129 | |
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| 130 | G4double cosTh = 0.0; |
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| 131 | if(theAngularDistributionType == 1) cosTh = theCoefficients->SampleMax(kineticEnergy); |
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| 132 | if(theAngularDistributionType == 2) cosTh = theProbArray->Sample(kineticEnergy); |
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| 133 | |
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| 134 | //080612TK bug fix contribution from Benoit Pirard and Laurent Desorgher (Univ. Bern) |
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| 135 | /* |
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| 136 | if(theAngularDistributionType == 1) // LAB |
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| 137 | { |
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| 138 | G4double en = aHadron.GetTotalMomentum(); |
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| 139 | G4ReactionProduct boosted; |
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| 140 | boosted.Lorentz(theNeutron, theTarget); |
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| 141 | G4double kineticEnergy = boosted.GetKineticEnergy(); |
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| 142 | G4double cosTh = theCoefficients->SampleMax(kineticEnergy); |
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[819] | 143 | G4double theta = std::acos(cosTh); |
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| 144 | G4double phi = twopi*G4UniformRand(); |
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[962] | 145 | G4double sinth = std::sin(theta); |
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| 146 | G4ThreeVector temp(en*sinth*std::cos(phi), en*sinth*std::sin(phi), en*std::cos(theta) ); |
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| 147 | aHadron.SetMomentum( temp ); |
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| 148 | } |
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| 149 | else if(theAngularDistributionType == 2) // costh in CMS |
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| 150 | { |
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| 151 | */ |
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| 152 | |
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| 153 | // G4ReactionProduct boostedN; |
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| 154 | // boostedN.Lorentz(theNeutron, theTarget); |
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| 155 | // G4double kineticEnergy = boostedN.GetKineticEnergy(); |
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| 156 | // G4double cosTh = theProbArray->Sample(kineticEnergy); |
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| 157 | |
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| 158 | G4double theta = std::acos(cosTh); |
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| 159 | G4double phi = twopi*G4UniformRand(); |
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[819] | 160 | G4double sinth = std::sin(theta); |
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| 161 | |
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| 162 | G4ThreeVector temp(sinth*std::cos(phi), sinth*std::sin(phi), std::cos(theta) ); //CMS |
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[962] | 163 | |
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| 164 | //080612TK bug fix contribution from Benoit Pirard and Laurent Desorgher (Univ. Bern) #5 |
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| 165 | /* |
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[819] | 166 | G4double en = aHadron.GetTotalEnergy(); // Target rest |
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| 167 | |
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| 168 | // get trafo from Target rest frame to CMS |
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| 169 | G4ReactionProduct boostedT; |
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| 170 | boostedT.Lorentz(theTarget, theTarget); |
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| 171 | |
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| 172 | G4ThreeVector the3Neutron = boostedN.GetMomentum(); |
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| 173 | G4double nEnergy = boostedN.GetTotalEnergy(); |
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| 174 | G4ThreeVector the3Target = boostedT.GetMomentum(); |
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| 175 | G4double tEnergy = boostedT.GetTotalEnergy(); |
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| 176 | G4double totE = nEnergy+tEnergy; |
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| 177 | G4ThreeVector the3trafo = -the3Target-the3Neutron; |
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| 178 | G4ReactionProduct trafo; // for transformation from CMS to target rest frame |
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| 179 | trafo.SetMomentum(the3trafo); |
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| 180 | G4double cmsMom = std::sqrt(the3trafo*the3trafo); |
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| 181 | G4double sqrts = std::sqrt((totE-cmsMom)*(totE+cmsMom)); |
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| 182 | trafo.SetMass(sqrts); |
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| 183 | trafo.SetTotalEnergy(totE); |
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| 184 | |
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| 185 | G4double gamma = trafo.GetTotalEnergy()/trafo.GetMass(); |
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| 186 | G4double cosalpha = temp*trafo.GetMomentum()/trafo.GetTotalMomentum()/temp.mag(); |
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| 187 | G4double fac = cosalpha*trafo.GetTotalMomentum()/trafo.GetMass(); |
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| 188 | fac*=gamma; |
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| 189 | |
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| 190 | G4double mom; |
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| 191 | // For G4FPE_DEBUG ON |
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| 192 | G4double mom2 = ( en*fac*en*fac - |
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| 193 | (fac*fac - gamma*gamma)* |
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| 194 | (en*en - gamma*gamma*aHadron.GetMass()*aHadron.GetMass()) |
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| 195 | ); |
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| 196 | if ( mom2 > 0.0 ) |
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| 197 | mom = std::sqrt( mom2 ); |
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| 198 | else |
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| 199 | mom = 0.0; |
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| 200 | |
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| 201 | mom = -en*fac - mom; |
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| 202 | mom /= (fac*fac-gamma*gamma); |
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| 203 | temp = mom*temp; |
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| 204 | |
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| 205 | aHadron.SetMomentum( temp ); // now all in CMS |
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| 206 | aHadron.SetTotalEnergy( std::sqrt( mom*mom + aHadron.GetMass()*aHadron.GetMass() ) ); |
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| 207 | aHadron.Lorentz(aHadron, trafo); // now in target rest frame |
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[962] | 208 | */ |
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| 209 | // Determination of the hadron kinetic energy in CMS |
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| 210 | // aHadron.GetKineticEnergy() is actually the residual kinetic energy in CMS (or target frame) |
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| 211 | // kineticEnergy is incident neutron kinetic energy in CMS (or target frame) |
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| 212 | G4double QValue = aHadron.GetKineticEnergy() - kineticEnergy; |
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| 213 | G4double A1 = theTarget.GetMass()/boostedN.GetMass(); |
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| 214 | G4double A1prim = aHadron.GetMass()/ boostedN.GetMass(); |
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| 215 | G4double kinE = (A1+1-A1prim)/(A1+1)/(A1+1)*(A1*kineticEnergy+(1+A1)*QValue); |
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| 216 | G4double totalE = kinE + aHadron.GetMass(); |
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| 217 | G4double mom2 = totalE*totalE - aHadron.GetMass()*aHadron.GetMass(); |
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| 218 | G4double mom; |
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| 219 | if ( mom2 > 0.0 ) mom = std::sqrt( mom2 ); |
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| 220 | else mom = 0.0; |
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| 221 | |
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| 222 | aHadron.SetMomentum( mom*temp ); // Set momentum in CMS |
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| 223 | aHadron.SetKineticEnergy(kinE); // Set kinetic energy in CMS |
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| 224 | |
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| 225 | // get trafo from Target rest frame to CMS |
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| 226 | G4ReactionProduct boostedT; |
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| 227 | boostedT.Lorentz(theTarget, theTarget); |
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| 228 | |
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| 229 | G4ThreeVector the3Neutron = boostedN.GetMomentum(); |
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| 230 | G4double nEnergy = boostedN.GetTotalEnergy(); |
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| 231 | G4ThreeVector the3Target = boostedT.GetMomentum(); |
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| 232 | G4double tEnergy = boostedT.GetTotalEnergy(); |
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| 233 | G4double totE = nEnergy+tEnergy; |
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| 234 | G4ThreeVector the3trafo = -the3Target-the3Neutron; |
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| 235 | G4ReactionProduct trafo; // for transformation from CMS to target rest frame |
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| 236 | trafo.SetMomentum(the3trafo); |
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| 237 | G4double cmsMom = std::sqrt(the3trafo*the3trafo); |
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| 238 | G4double sqrts = std::sqrt((totE-cmsMom)*(totE+cmsMom)); |
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| 239 | trafo.SetMass(sqrts); |
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| 240 | trafo.SetTotalEnergy(totE); |
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| 241 | |
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| 242 | aHadron.Lorentz(aHadron, trafo); |
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| 243 | |
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[819] | 244 | } |
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| 245 | else |
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| 246 | { |
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| 247 | throw G4HadronicException(__FILE__, __LINE__, "Tried to sample non isotropic neutron angular"); |
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| 248 | } |
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| 249 | } |
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| 250 | aHadron.Lorentz(aHadron, -1.*theTarget); |
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| 251 | // G4cout << aHadron.GetMomentum()<<" "; |
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| 252 | // G4cout << aHadron.GetTotalMomentum()<<G4endl; |
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| 253 | } |
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