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Geant4/materials/src/G4LatticeLogical.cc

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Differences between /materials/src/G4LatticeLogical.cc (Version 11.3.0) and /materials/src/G4LatticeLogical.cc (Version 10.0)


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 25                                                <<  25 //
 26 /// \file materials/src/G4LatticeLogical.cc        26 /// \file materials/src/G4LatticeLogical.cc
 27 /// \brief Implementation of the G4LatticeLogi     27 /// \brief Implementation of the G4LatticeLogical class
 28                                                <<  28 //
                                                   >>  29 // $Id: G4LatticeLogical.cc 76764 2013-11-15 09:37:24Z gcosmo $
                                                   >>  30 //
 29 #include "G4LatticeLogical.hh"                     31 #include "G4LatticeLogical.hh"
 30                                                << 
 31 #include "G4PhysicalConstants.hh"              << 
 32 #include "G4SystemOfUnits.hh"                      32 #include "G4SystemOfUnits.hh"
 33                                                <<  33 #include "G4PhysicalConstants.hh"
 34 #include <cmath>                                   34 #include <cmath>
 35 #include <fstream>                                 35 #include <fstream>
 36                                                    36 
 37                                                    37 
                                                   >>  38 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
                                                   >>  39 
 38 G4LatticeLogical::G4LatticeLogical()               40 G4LatticeLogical::G4LatticeLogical()
 39 {                                              <<  41   : verboseLevel(0), fVresTheta(0), fVresPhi(0), fDresTheta(0), fDresPhi(0),
 40   for (G4int i = 0; i < 3; i++) {              <<  42     fA(0), fB(0), fLDOS(0), fSTDOS(0), fFTDOS(0),
 41     for (G4int j = 0; j < MAXRES; j++) {       <<  43     fBeta(0), fGamma(0), fLambda(0), fMu(0) {
 42       for (G4int k = 0; k < MAXRES; k++) {     <<  44   for (G4int i=0; i<3; i++) {
 43         fMap[i][j][k] = 0.;                    <<  45     for (G4int j=0; j<MAXRES; j++) {
 44         fN_map[i][j][k].set(0., 0., 0.);       <<  46       for (G4int k=0; k<MAXRES; k++) {
                                                   >>  47   fMap[i][j][k] = 0.;
                                                   >>  48   fN_map[i][j][k].set(0.,0.,0.);
 45       }                                            49       }
 46     }                                              50     }
 47   }                                                51   }
 48 }                                                  52 }
 49                                                    53 
                                                   >>  54 G4LatticeLogical::~G4LatticeLogical() {;}
                                                   >>  55 
                                                   >>  56 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
                                                   >>  57 
                                                   >>  58 
 50 ///////////////////////////////////////////        59 ///////////////////////////////////////////
 51 // Load map of group velocity scalars (m/s)    <<  60 //Load map of group velocity scalars (m/s)
 52 ////////////////////////////////////////////       61 ////////////////////////////////////////////
 53 G4bool G4LatticeLogical::LoadMap(G4int tRes, G <<  62 G4bool G4LatticeLogical::LoadMap(G4int tRes, G4int pRes,
 54 {                                              <<  63          G4int polarizationState, G4String map) {
 55   if (tRes > MAXRES || pRes > MAXRES) {        <<  64   if (tRes>MAXRES || pRes>MAXRES) {
 56     G4cerr << "G4LatticeLogical::LoadMap excee <<  65     G4cerr << "G4LatticeLogical::LoadMap exceeds maximum resolution of "
 57            << MAXRES << ". terminating." << G4 <<  66            << MAXRES << " by " << MAXRES << ". terminating." << G4endl;
 58     return false;  // terminate if resolution  <<  67     return false;     //terminate if resolution out of bounds.
 59   }                                                68   }
 60                                                    69 
 61   std::ifstream fMapFile(map.data());              70   std::ifstream fMapFile(map.data());
 62   if (! fMapFile.is_open()) {                  <<  71   if (!fMapFile.is_open()) return false;
 63     return false;                              << 
 64   }                                            << 
 65                                                    72 
 66   G4double vgrp = 0.;                              73   G4double vgrp = 0.;
 67   for (G4int theta = 0; theta < tRes; theta++) <<  74   for (G4int theta = 0; theta<tRes; theta++) {
 68     for (G4int phi = 0; phi < pRes; phi++) {   <<  75     for (G4int phi = 0; phi<pRes; phi++) {
 69       fMapFile >> vgrp;                            76       fMapFile >> vgrp;
 70       fMap[polarizationState][theta][phi] = vg <<  77       fMap[polarizationState][theta][phi] = vgrp * (m/s);
 71     }                                              78     }
 72   }                                                79   }
 73                                                    80 
 74   if (verboseLevel != 0) {                     <<  81   if (verboseLevel) {
 75     G4cout << "\nG4LatticeLogical::LoadMap(" <     82     G4cout << "\nG4LatticeLogical::LoadMap(" << map << ") successful"
 76            << " (Vg scalars " << tRes << " x " <<  83      << " (Vg scalars " << tRes << " x " << pRes << " for polarization "
 77            << ")." << G4endl;                  <<  84      << polarizationState << ")." << G4endl;
 78   }                                                85   }
 79                                                    86 
 80   fVresTheta = tRes;  // store map dimensions  <<  87   fVresTheta=tRes; //store map dimensions
 81   fVresPhi = pRes;                             <<  88   fVresPhi=pRes;
 82   return true;                                     89   return true;
 83 }                                                  90 }
 84                                                    91 
                                                   >>  92 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
                                                   >>  93 
 85                                                    94 
 86 ////////////////////////////////////               95 ////////////////////////////////////
 87 // Load map of group velocity unit vectors     <<  96 //Load map of group velocity unit vectors
 88 ///////////////////////////////////                97 ///////////////////////////////////
 89 G4bool G4LatticeLogical::Load_NMap(G4int tRes, <<  98 G4bool G4LatticeLogical::Load_NMap(G4int tRes, G4int pRes,
 90 {                                              <<  99            G4int polarizationState, G4String map) {
 91   if (tRes > MAXRES || pRes > MAXRES) {        << 100   if (tRes>MAXRES || pRes>MAXRES) {
 92     G4cerr << "G4LatticeLogical::LoadMap excee << 101     G4cerr << "G4LatticeLogical::LoadMap exceeds maximum resolution of "
 93            << MAXRES << ". terminating." << G4 << 102            << MAXRES << " by " << MAXRES << ". terminating." << G4endl;
 94     return false;  // terminate if resolution  << 103     return false;     //terminate if resolution out of bounds.
 95   }                                               104   }
 96                                                   105 
 97   std::ifstream fMapFile(map.data());             106   std::ifstream fMapFile(map.data());
 98   if (! fMapFile.is_open()) {                  << 107   if(!fMapFile.is_open()) return false;
 99     return false;                              << 
100   }                                            << 
101                                                   108 
102   G4double x, y, z;  // Buffers to read coordi << 109   G4double x,y,z; // Buffers to read coordinates from file
103   G4ThreeVector dir;                              110   G4ThreeVector dir;
104   for (G4int theta = 0; theta < tRes; theta++) << 111   for (G4int theta = 0; theta<tRes; theta++) {
105     for (G4int phi = 0; phi < pRes; phi++) {   << 112     for (G4int phi = 0; phi<pRes; phi++) {
106       fMapFile >> x >> y >> z;                    113       fMapFile >> x >> y >> z;
107       dir.set(x, y, z);                        << 114       dir.set(x,y,z);
108       fN_map[polarizationState][theta][phi] =  << 115       fN_map[polarizationState][theta][phi] = dir.unit(); // Enforce unity
109     }                                             116     }
110   }                                               117   }
111                                                   118 
112   if (verboseLevel != 0) {                     << 119   if (verboseLevel) {
113     G4cout << "\nG4LatticeLogical::Load_NMap("    120     G4cout << "\nG4LatticeLogical::Load_NMap(" << map << ") successful"
114            << " (Vdir " << tRes << " x " << pR << 121      << " (Vdir " << tRes << " x " << pRes << " for polarization "
115            << ")." << G4endl;                  << 122      << polarizationState << ")." << G4endl;
116   }                                               123   }
117                                                   124 
118   fDresTheta = tRes;  // store map dimensions  << 125   fDresTheta=tRes; //store map dimensions
119   fDresPhi = pRes;                             << 126   fDresPhi=pRes;
120   return true;                                    127   return true;
121 }                                                 128 }
122                                                   129 
                                                   >> 130 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
123                                                   131 
124 // Given the phonon wave vector k, phonon phys << 132 //Given the phonon wave vector k, phonon physical volume Vol 
125 // and polarizationState(0=LON, 1=FT, 2=ST),   << 133 //and polarizationState(0=LON, 1=FT, 2=ST), 
126 // returns phonon velocity in m/s              << 134 //returns phonon velocity in m/s
127                                                   135 
128 G4double G4LatticeLogical::MapKtoV(G4int polar << 136 G4double G4LatticeLogical::MapKtoV(G4int polarizationState,
129 {                                              << 137            const G4ThreeVector& k) const {
130   G4double theta, phi, tRes, pRes;                138   G4double theta, phi, tRes, pRes;
131                                                   139 
132   tRes = pi / fVresTheta;                      << 140   tRes=pi/fVresTheta;
133   pRes = twopi / fVresPhi;                     << 141   pRes=twopi/fVresPhi;
134                                                << 142   
135   theta = k.getTheta();                        << 143   theta=k.getTheta();
136   phi = k.getPhi();                            << 144   phi=k.getPhi();
137                                                << 145 
138   if (phi < 0) {                               << 146   if(phi<0) phi = phi + twopi;
139     phi = phi + twopi;                         << 147   if(theta>pi) theta=theta-pi;
140   }                                            << 148 
141   if (theta > pi) {                            << 149   G4double Vg = fMap[polarizationState][int(theta/tRes)][int(phi/pRes)];
142     theta = theta - pi;                        << 150 
143   }                                            << 151   if(Vg == 0){
144                                                << 152       G4cout<<"\nFound v=0 for polarization "<<polarizationState
145   G4double Vg = fMap[polarizationState][int(th << 153             <<" theta "<<theta<<" phi "<<phi<< " translating to map coords "
146                                                << 154             <<"theta "<< int(theta/tRes) << " phi " << int(phi/pRes)<<G4endl;
147   if (Vg == 0) {                               << 155   }
148     G4cout << "\nFound v=0 for polarization "  << 156 
149            << phi << " translating to map coor << 157   if (verboseLevel>1) {
150            << "theta " << int(theta / tRes) << << 158     G4cout << "G4LatticeLogical::MapKtoV theta,phi=" << theta << " " << phi
151   }                                            << 159      << " : ith,iph " << int(theta/tRes) << " " << int(phi/pRes)
152                                                << 160      << " : V " << Vg << G4endl;
153   if (verboseLevel > 1) {                      << 
154     G4cout << "G4LatticeLogical::MapKtoV theta << 
155            << int(theta / tRes) << " " << int( << 
156   }                                               161   }
157                                                   162 
158   return Vg;                                      163   return Vg;
159 }                                                 164 }
160                                                   165 
                                                   >> 166 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
161                                                   167 
162 // Given the phonon wave vector k, phonon phys << 168 //Given the phonon wave vector k, phonon physical volume Vol 
163 // and polarizationState(0=LON, 1=FT, 2=ST),   << 169 //and polarizationState(0=LON, 1=FT, 2=ST), 
164 // returns phonon propagation direction as dim << 170 //returns phonon propagation direction as dimensionless unit vector
165                                                   171 
166 G4ThreeVector G4LatticeLogical::MapKtoVDir(G4i << 172 G4ThreeVector G4LatticeLogical::MapKtoVDir(G4int polarizationState,
167 {                                              << 173              const G4ThreeVector& k) const {  
168   G4double theta, phi, tRes, pRes;                174   G4double theta, phi, tRes, pRes;
169                                                   175 
170   tRes = pi / (fDresTheta - 1);  // The summan << 176   tRes=pi/(fDresTheta-1);//The summant "-1" is required:index=[0:array length-1]
171   pRes = 2 * pi / (fDresPhi - 1);              << 177   pRes=2*pi/(fDresPhi-1);
172                                                << 
173   theta = k.getTheta();                        << 
174   phi = k.getPhi();                            << 
175                                                << 
176   if (theta > pi) {                            << 
177     theta = theta - pi;                        << 
178   }                                            << 
179   // phi=[0 to 2 pi] in accordance with DMC // << 
180   if (phi < 0) {                               << 
181     phi = phi + 2 * pi;                        << 
182   }                                            << 
183                                                   178 
184   auto iTheta = int(theta / tRes + 0.5);       << 179   theta=k.getTheta();
185   auto iPhi = int(phi / pRes + 0.5);           << 180   phi=k.getPhi(); 
186                                                   181 
187   if (verboseLevel > 1) {                      << 182   if(theta>pi) theta=theta-pi;
188     G4cout << "G4LatticeLogical::MapKtoVDir th << 183   //phi=[0 to 2 pi] in accordance with DMC //if(phi>pi/2) phi=phi-pi/2;
189            << iTheta << " " << iPhi << " : dir << 184   if(phi<0) phi = phi + 2*pi;
190            << G4endl;                          << 185 
                                                   >> 186   G4int iTheta = int(theta/tRes+0.5);
                                                   >> 187   G4int iPhi = int(phi/pRes+0.5);
                                                   >> 188 
                                                   >> 189   if (verboseLevel>1) {
                                                   >> 190     G4cout << "G4LatticeLogical::MapKtoVDir theta,phi=" << theta << " " << phi
                                                   >> 191      << " : ith,iph " << iTheta << " " << iPhi
                                                   >> 192      << " : dir " << fN_map[polarizationState][iTheta][iPhi] << G4endl;
191   }                                               193   }
192                                                   194 
193   return fN_map[polarizationState][iTheta][iPh    195   return fN_map[polarizationState][iTheta][iPhi];
194 }                                                 196 }
195                                                   197 
                                                   >> 198 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
196                                                   199 
197 // Dump structure in format compatible with re    200 // Dump structure in format compatible with reading back
198                                                   201 
199 void G4LatticeLogical::Dump(std::ostream& os)  << 202 void G4LatticeLogical::Dump(std::ostream& os) const {
200 {                                              << 203   os << "dyn " << fBeta << " " << fGamma << " " << fLambda << " " << fMu
201   os << "dyn " << fBeta << " " << fGamma << "  << 204      << "\nscat " << fB << " decay " << fA
202      << " decay " << fA << "\nLDOS " << fLDOS  << 205      << "\nLDOS " << fLDOS << " STDOS " << fSTDOS << " FTDOS " << fFTDOS
203      << std::endl;                                206      << std::endl;
204                                                   207 
205   Dump_NMap(os, 0, "LVec.ssv");                   208   Dump_NMap(os, 0, "LVec.ssv");
206   Dump_NMap(os, 1, "FTVec.ssv");                  209   Dump_NMap(os, 1, "FTVec.ssv");
207   Dump_NMap(os, 2, "STVec.ssv");                  210   Dump_NMap(os, 2, "STVec.ssv");
208                                                   211 
209   DumpMap(os, 0, "L.ssv");                        212   DumpMap(os, 0, "L.ssv");
210   DumpMap(os, 1, "FT.ssv");                       213   DumpMap(os, 1, "FT.ssv");
211   DumpMap(os, 2, "ST.ssv");                       214   DumpMap(os, 2, "ST.ssv");
212 }                                                 215 }
213                                                   216 
214 void G4LatticeLogical::DumpMap(std::ostream& o << 217 void G4LatticeLogical::DumpMap(std::ostream& os, G4int pol,
215 {                                              << 218              const G4String& name) const {
216   os << "VG " << name << " "                   << 219   os << "VG " << name << " " << (pol==0?"L":pol==1?"FT":pol==2?"ST":"??")
217      << (pol == 0    ? "L"                     << 
218           : pol == 1 ? "FT"                    << 
219           : pol == 2 ? "ST"                    << 
220                      : "??")                   << 
221      << " " << fVresTheta << " " << fVresPhi <    220      << " " << fVresTheta << " " << fVresPhi << std::endl;
222                                                   221 
223   for (G4int iTheta = 0; iTheta < fVresTheta;  << 222   for (G4int iTheta=0; iTheta<fVresTheta; iTheta++) {
224     for (G4int iPhi = 0; iPhi < fVresPhi; iPhi << 223     for (G4int iPhi=0; iPhi<fVresPhi; iPhi++) {
225       os << fMap[pol][iTheta][iPhi] << std::en    224       os << fMap[pol][iTheta][iPhi] << std::endl;
226     }                                             225     }
227   }                                               226   }
228 }                                                 227 }
229                                                   228 
230 void G4LatticeLogical::Dump_NMap(std::ostream& << 229 void G4LatticeLogical::Dump_NMap(std::ostream& os, G4int pol,
231 {                                              << 230          const G4String& name) const {
232   os << "VDir " << name << " "                 << 231   os << "VDir " << name << " " << (pol==0?"L":pol==1?"FT":pol==2?"ST":"??")
233      << (pol == 0    ? "L"                     << 
234           : pol == 1 ? "FT"                    << 
235           : pol == 2 ? "ST"                    << 
236                      : "??")                   << 
237      << " " << fDresTheta << " " << fDresPhi <    232      << " " << fDresTheta << " " << fDresPhi << std::endl;
238                                                   233 
239   for (G4int iTheta = 0; iTheta < fDresTheta;  << 234   for (G4int iTheta=0; iTheta<fDresTheta; iTheta++) {
240     for (G4int iPhi = 0; iPhi < fDresPhi; iPhi << 235     for (G4int iPhi=0; iPhi<fDresPhi; iPhi++) {
241       os << fN_map[pol][iTheta][iPhi].x() << " << 236       os << fN_map[pol][iTheta][iPhi].x()
242          << fN_map[pol][iTheta][iPhi].z() << s << 237    << " " << fN_map[pol][iTheta][iPhi].y()
                                                   >> 238    << " " << fN_map[pol][iTheta][iPhi].z()
                                                   >> 239    << std::endl;
243     }                                             240     }
244   }                                               241   }
245 }                                                 242 }
                                                   >> 243 
246                                                   244