Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4ParticleHPFFFissionFS.cc
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25//
26// neutron_hp -- source file
27// J.P. Wellisch, Nov-1996
28// A prototype of the low energy neutron transport model.
29//
30// P. Arce, June-2014 Conversion neutron_hp to particle_hp
31//
34#include "G4SystemOfUnits.hh"
35
37{
38 std::map<G4int,std::map<G4double,std::map<G4int,G4double >* >* >::iterator it = FissionProductYieldData.begin();
39 while ( it != FissionProductYieldData.end() ) { // Loop checking, 11.05.2015, T. Koi
40 std::map<G4double,std::map<G4int,G4double>* >* firstLevel = it->second;
41 if ( firstLevel ) {
42 std::map<G4double,std::map<G4int,G4double>*>::iterator it2 = firstLevel->begin();
43 while ( it2 != firstLevel->end() ) { // Loop checking, 11.05.2015, T. Koi
44 delete it2->second;
45 it2->second = 0;
46 firstLevel->erase(it2);
47 it2=firstLevel->begin();
48 }
49 }
50 delete firstLevel;
51 it->second = 0;
52 FissionProductYieldData.erase(it);
53 it = FissionProductYieldData.begin();
54 }
55
56 std::map< G4int , std::map< G4double , G4int >* >::iterator ii = mMTInterpolation.begin();
57 while ( ii != mMTInterpolation.end() ) { // Loop checking, 11.05.2015, T. Koi
58 delete ii->second;
59 mMTInterpolation.erase(ii);
60 ii = mMTInterpolation.begin();
61 }
62}
63
65{
66 //G4cout << "G4ParticleHPFFFissionFS::Init" << G4endl;
67 G4String aString = "FF";
68
69 G4String tString = dirName;
70 G4bool dbool;
71 G4ParticleHPDataUsed aFile = theNames.GetName(static_cast<G4int>(A), static_cast<G4int>(Z), M, tString, aString , dbool);
72 G4String filename = aFile.GetName();
73 theBaseA = aFile.GetA();
74 theBaseZ = aFile.GetZ();
75
76//3456
77 if ( !dbool || ( Z < 2.5 && ( std::abs(theBaseZ-Z)>0.0001 || std::abs(theBaseA-A)>0.0001) ) )
78 {
79 hasAnyData = false;
80 hasFSData = false;
81 hasXsec = false;
82 return; // no data for exactly this isotope.
83 }
84 //std::ifstream theData(filename, std::ios::in);
85 std::istringstream theData(std::ios::in);
87 G4double dummy;
88 if ( !theData )
89 {
90 //theData.close();
91 hasFSData = false;
92 hasXsec = false;
93 hasAnyData = false;
94 return; // no data for this FS for this isotope
95 }
96
97
98 hasFSData = true;
99 // MT Energy FPS Yield
100 //std::map< int , std::map< double , std::map< int , double >* >* > FisionProductYieldData;
101 while ( theData.good() ) // Loop checking, 11.05.2015, T. Koi
102 {
103 G4int iMT, iMF;
104 G4int imax;
105 //Reading the data
106 // MT MF AWR
107 theData >> iMT >> iMF >> dummy;
108 // nBlock
109 theData >> imax;
110 //if ( !theData.good() ) continue;
111 // Ei FPS Yield
112 std::map< G4double , std::map< G4int , G4double >* >* mEnergyFSPData = new std::map< G4double , std::map< G4int , G4double >* >;
113
114 std::map< G4double , G4int >* mInterporation = new std::map< G4double , G4int >;
115 for ( G4int i = 0 ; i <= imax ; i++ )
116 {
117
118 G4double YY=0.0;
119 G4double Ei;
120 G4int jmax;
121 G4int ip;
122 // energy of incidence neutron
123 theData >> Ei;
124 // Number of data set followings
125 theData >> jmax;
126 // interpolation scheme
127 theData >> ip;
128 mInterporation->insert( std::pair<G4double,G4int>(Ei*eV,ip) );
129 // nNumber nIP
130 std::map<G4int,G4double>* mFSPYieldData = new std::map<G4int,G4double>;
131 for ( G4int j = 0 ; j < jmax ; j++ )
132 {
133 G4int FSP;
134 G4int mFSP;
135 G4double Y;
136 theData >> FSP >> mFSP >> Y;
137 G4int k = FSP*100+mFSP;
138 YY = YY + Y;
139 //if ( iMT == 454 )G4cout << iMT << " " << i << " " << j << " " << k << " " << Y << " " << YY << G4endl;
140 mFSPYieldData->insert( std::pair<G4int,G4double>( k , YY ) );
141 }
142 mEnergyFSPData->insert( std::pair<G4double,std::map<G4int,G4double>*>(Ei*eV,mFSPYieldData) );
143 }
144
145 FissionProductYieldData.insert( std::pair< G4int , std::map< G4double , std::map< G4int , G4double >* >* > (iMT,mEnergyFSPData));
146 mMTInterpolation.insert( std::pair<G4int,std::map<G4double,G4int>*> (iMT,mInterporation) );
147 }
148 //theData.close();
149}
150
152{
153 G4DynamicParticleVector * aResult;
154// G4cout <<"G4ParticleHPFFFissionFS::ApplyYourself +"<<G4endl;
155 aResult = G4ParticleHPFissionBaseFS::ApplyYourself(nNeutrons);
156 return aResult;
157}
158
160{
161 //G4cout << "G4ParticleHPFFFissionFS::GetAFissionFragment " << G4endl;
162
163 G4double rand =G4UniformRand();
164 //G4cout << rand << G4endl;
165
166 std::map< G4double , std::map< G4int , G4double >* >* mEnergyFSPData = FissionProductYieldData.find( 454 )->second;
167
168 //It is not clear that the treatment of the scheme 2 on two-dimensional interpolation.
169 //So, here just use the closest energy point array of yield data.
170 //TK120531
171 G4double key_energy = DBL_MAX;
172 if ( mEnergyFSPData->size() == 1 )
173 {
174 key_energy = mEnergyFSPData->begin()->first;
175 }
176 else
177 {
178 //Find closest energy point
179 G4double Dmin=DBL_MAX;
180 G4int i = 0;
181 for ( std::map< G4double , std::map< G4int , G4double >* >::iterator it = mEnergyFSPData->begin() ;
182 it != mEnergyFSPData->end() ; it++ )
183 {
184 G4double e = (it->first);
185 G4double d = std::fabs ( energy - e );
186 if ( d < Dmin )
187 {
188 Dmin = d;
189 key_energy = e;
190 }
191 i++;
192 }
193 }
194
195 std::map<G4int,G4double>* mFSPYieldData = (*mEnergyFSPData)[key_energy];
196
197 G4int ifrag=0;
198 G4double ceilling = mFSPYieldData->rbegin()->second; // Because of numerical accuracy, this is not always 2
199 for ( std::map<G4int,G4double>::iterator it = mFSPYieldData->begin() ; it != mFSPYieldData->end() ; it++ )
200 {
201 //if ( ( rand - it->second/ceilling ) < 1.0e-6 ) std::cout << rand - it->second/ceilling << std::endl;
202 if ( rand <= it->second/ceilling )
203 {
204 //G4cout << it->first << " " << it->second/ceilling << G4endl;
205 ifrag = it->first;
206 break;
207 }
208 }
209
210 fragZ = ifrag/100000;
211 fragA = (ifrag%100000)/100;
212 fragM = (ifrag%100);
213
214 //G4cout << fragZ << " " << fragA << " " << fragM << G4endl;
215}
double Y(double density)
double A(double temperature)
std::vector< G4DynamicParticle * > G4DynamicParticleVector
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
#define G4UniformRand()
Definition: Randomize.hh:52
G4DynamicParticleVector * ApplyYourself(G4int nNeutrons)
void Init(G4double A, G4double Z, G4int M, G4String &dirName, G4String &aFSType, G4ParticleDefinition *)
void GetAFissionFragment(G4double, G4int &, G4int &, G4int &)
G4DynamicParticleVector * ApplyYourself(G4int Prompt)
static G4ParticleHPManager * GetInstance()
void GetDataStream(G4String, std::istringstream &iss)
G4ParticleHPDataUsed GetName(G4int A, G4int Z, G4String base, G4String rest, G4bool &active)
#define DBL_MAX
Definition: templates.hh:62