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Geant4/processes/hadronic/models/particle_hp/src/G4ParticleHPNBodyPhaseSpace.cc

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Diff markup

Differences between /processes/hadronic/models/particle_hp/src/G4ParticleHPNBodyPhaseSpace.cc (Version 11.3.0) and /processes/hadronic/models/particle_hp/src/G4ParticleHPNBodyPhaseSpace.cc (Version 10.7.p1)


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 28 // P. Arce, June-2014 Conversion neutron_hp to     28 // P. Arce, June-2014 Conversion neutron_hp to particle_hp
 29 //                                                 29 //
 30 #include "G4ParticleHPNBodyPhaseSpace.hh"          30 #include "G4ParticleHPNBodyPhaseSpace.hh"
 31                                                << 
 32 #include "G4Alpha.hh"                          << 
 33 #include "G4Deuteron.hh"                       << 
 34 #include "G4Electron.hh"                       << 
 35 #include "G4Gamma.hh"                          << 
 36 #include "G4He3.hh"                            << 
 37 #include "G4Neutron.hh"                        << 
 38 #include "G4PhysicalConstants.hh"                  31 #include "G4PhysicalConstants.hh"
                                                   >>  32 #include "Randomize.hh"
                                                   >>  33 #include "G4ThreeVector.hh"
                                                   >>  34 #include "G4Gamma.hh"
                                                   >>  35 #include "G4Electron.hh"
 39 #include "G4Positron.hh"                           36 #include "G4Positron.hh"
                                                   >>  37 #include "G4Neutron.hh"
 40 #include "G4Proton.hh"                             38 #include "G4Proton.hh"
 41 #include "G4ThreeVector.hh"                    <<  39 #include "G4Deuteron.hh"
 42 #include "G4Triton.hh"                             40 #include "G4Triton.hh"
 43 #include "Randomize.hh"                        <<  41 #include "G4He3.hh"
                                                   >>  42 #include "G4Alpha.hh"
 44                                                    43 
 45 G4ReactionProduct* G4ParticleHPNBodyPhaseSpace <<  44 G4ReactionProduct * G4ParticleHPNBodyPhaseSpace::Sample(G4double anEnergy, G4double massCode, G4double )
 46                                                << 
 47 {                                                  45 {
 48   auto result = new G4ReactionProduct;         <<  46    G4ReactionProduct * result = new G4ReactionProduct;
 49   auto Z = static_cast<G4int>(massCode / 1000) <<  47    G4int Z = static_cast<G4int>(massCode/1000);
 50   auto A = static_cast<G4int>(massCode - 1000  <<  48    G4int A = static_cast<G4int>(massCode-1000*Z);
 51                                                <<  49 
 52   if (massCode == 0) {                         <<  50    if(massCode==0)
 53     result->SetDefinition(G4Gamma::Gamma());   <<  51    {
 54   }                                            <<  52      result->SetDefinition(G4Gamma::Gamma());
 55   else if (A == 0) {                           <<  53    }
 56     result->SetDefinition(G4Electron::Electron <<  54    else if(A==0)
 57     if (Z == 1) result->SetDefinition(G4Positr <<  55    {
 58   }                                            <<  56      result->SetDefinition(G4Electron::Electron());     
 59   else if (A == 1) {                           <<  57      if(Z==1) result->SetDefinition(G4Positron::Positron());
 60     result->SetDefinition(G4Neutron::Neutron() <<  58    }
 61     if (Z == 1) result->SetDefinition(G4Proton <<  59    else if(A==1)
 62   }                                            <<  60    {
 63   else if (A == 2) {                           <<  61      result->SetDefinition(G4Neutron::Neutron());
 64     result->SetDefinition(G4Deuteron::Deuteron <<  62      if(Z==1) result->SetDefinition(G4Proton::Proton());
 65   }                                            <<  63    }
 66   else if (A == 3) {                           <<  64    else if(A==2)
 67     result->SetDefinition(G4Triton::Triton()); <<  65    {
 68     if (Z == 2) result->SetDefinition(G4He3::H <<  66      result->SetDefinition(G4Deuteron::Deuteron());      
 69   }                                            <<  67    }
 70   else if (A == 4) {                           <<  68    else if(A==3)
 71     result->SetDefinition(G4Alpha::Alpha());   <<  69    {
 72     if (Z != 2) throw G4HadronicException(__FI <<  70      result->SetDefinition(G4Triton::Triton());  
 73   }                                            <<  71      if(Z==2) result->SetDefinition(G4He3::He3());
 74   else {                                       <<  72    }
 75     throw G4HadronicException(__FILE__, __LINE <<  73    else if(A==4)
 76                               "G4ParticleHPNBo <<  74    {
 77   }                                            <<  75      result->SetDefinition(G4Alpha::Alpha());
 78                                                <<  76      if(Z!=2) throw G4HadronicException(__FILE__, __LINE__, "Unknown ion case 1");    
 79   // Get the energy from phase-space distribut <<  77    }
 80   // in CMS                                    <<  78    else
 81   // P = Cn*std::sqrt(E')*(Emax-E')**(3*n/2-4) <<  79    {
 82   G4double maxE = GetEmax(anEnergy, result->Ge <<  80      throw G4HadronicException(__FILE__, __LINE__, "G4ParticleHPNBodyPhaseSpace: Unknown ion case 2");
 83   if (maxE <= 0) {                             <<  81    }
 84     maxE = 1. * CLHEP::eV;                     <<  82 
 85   }                                            <<  83 // Get the energy from phase-space distribution
 86   G4double energy = 0.;                        <<  84    // in CMS
 87   G4double max(0);                             <<  85    // P = Cn*std::sqrt(E')*(Emax-E')**(3*n/2-4)
 88   if (theTotalCount <= 3) {                    <<  86    G4double maxE = GetEmax(anEnergy, result->GetMass());
 89     max = maxE / 2.;                           <<  87    if(maxE<=0){
 90   }                                            <<  88      maxE=1.*CLHEP::eV;
 91   else if (theTotalCount == 4) {               <<  89    }
 92     max = maxE / 5.;                           <<  90    G4double energy;
 93   }                                            <<  91    G4double max(0);
 94   else if (theTotalCount == 5) {               <<  92    if(theTotalCount<=3)
 95     max = maxE / 8.;                           <<  93    {
 96   }                                            <<  94      max = maxE/2.;
 97   else {                                       <<  95    }
 98     throw G4HadronicException(                 <<  96    else if(theTotalCount==4)
 99       __FILE__, __LINE__,                      <<  97    {
100       "NeutronHP Phase-space distribution cann <<  98      max = maxE/5.;
101   }                                            <<  99    }
102   G4double testit;                             << 100    else if(theTotalCount==5)
103   G4double rand0 = Prob(max, maxE, theTotalCou << 101    {
104   G4double rand;                               << 102      max = maxE/8.;
105                                                << 103    }
106   G4int icounter = 0;                          << 104    else
107   G4int icounter_max = 1024;                   << 105    {
108   do {                                         << 106      throw G4HadronicException(__FILE__, __LINE__, "NeutronHP Phase-space distribution cannot cope with this number of particles");
109     icounter++;                                << 107    }
110     if (icounter > icounter_max) {             << 108    G4double testit;
111       G4cout << "Loop-counter exceeded the thr << 109    G4double rand0 = Prob(max, maxE, theTotalCount);
112              << __FILE__ << "." << G4endl;     << 110    G4double rand;
113       break;                                   << 111    
114     }                                          << 112    G4int icounter=0;
115     rand = rand0 * G4UniformRand();            << 113    G4int icounter_max=1024;
116     energy = maxE * G4UniformRand();           << 114    do
117     testit = Prob(energy, maxE, theTotalCount) << 115    {
118   } while (rand > testit);  // Loop checking,  << 116       icounter++;
119   result->SetKineticEnergy(energy);            << 117       if ( icounter > icounter_max ) {
120                                                << 118          G4cout << "Loop-counter exceeded the threshold value at " << __LINE__ << "th line of " << __FILE__ << "." << G4endl;
121   // now do random direction                   << 119          break;
122   G4double cosTh = 2. * G4UniformRand() - 1.;  << 120       }
123   G4double phi = twopi * G4UniformRand();      << 121      rand = rand0*G4UniformRand();
124   G4double theta = std::acos(cosTh);           << 122      energy = maxE*G4UniformRand();
125   G4double sinth = std::sin(theta);            << 123      testit = Prob(energy, maxE, theTotalCount);
126   G4double mtot = result->GetTotalMomentum();  << 124    }
127   G4ThreeVector tempVector(mtot * sinth * std: << 125    while(rand > testit); // Loop checking, 11.05.2015, T. Koi
128                            mtot * std::cos(the << 126    result->SetKineticEnergy(energy);
129   result->SetMomentum(tempVector);             << 127    
130   G4ReactionProduct aCMS = *GetTarget() + *Get << 128 // now do random direction
131   result->Lorentz(*result, -1. * aCMS);        << 129    G4double cosTh = 2.*G4UniformRand()-1.;
132   return result;                               << 130    G4double phi = twopi*G4UniformRand();
                                                   >> 131    G4double theta = std::acos(cosTh);
                                                   >> 132    G4double sinth = std::sin(theta);
                                                   >> 133    G4double mtot = result->GetTotalMomentum(); 
                                                   >> 134    G4ThreeVector tempVector(mtot*sinth*std::cos(phi), mtot*sinth*std::sin(phi), mtot*std::cos(theta) );
                                                   >> 135    result->SetMomentum(tempVector);
                                                   >> 136    G4ReactionProduct aCMS = *GetTarget()+*GetProjectileRP();
                                                   >> 137    result->Lorentz(*result, -1.*aCMS);
                                                   >> 138    return result;
133 }                                                 139 }
134                                                   140