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Geant4/processes/electromagnetic/xrays/src/G4XTRRegularRadModel.cc

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Differences between /processes/electromagnetic/xrays/src/G4XTRRegularRadModel.cc (Version 11.3.0) and /processes/electromagnetic/xrays/src/G4XTRRegularRadModel.cc (Version 2.0)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
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  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
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  8 // * LICENSE and available at  http://cern.ch/    
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 11 // * Neither the authors of this software syst    
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 14 // * regarding  this  software system or assum    
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 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
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 22 // * use  in  resulting  scientific  publicati    
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 24 // *******************************************    
 25 //                                                
 26                                                   
 27 #include "G4XTRRegularRadModel.hh"                
 28                                                   
 29 #include "G4PhysicalConstants.hh"                 
 30                                                   
 31 //////////////////////////////////////////////    
 32 // Constructor, destructor                        
 33 G4XTRRegularRadModel::G4XTRRegularRadModel(G4L    
 34                                            G4M    
 35                                            G4M    
 36                                            G4d    
 37                                            con    
 38   : G4VXTRenergyLoss(anEnvelope, foilMat, gasM    
 39 {                                                 
 40   G4cout << " XTR Regular discrete radiator mo    
 41                                                   
 42   fExitFlux = true;                               
 43 }                                                 
 44                                                   
 45 //////////////////////////////////////////////    
 46 G4XTRRegularRadModel::~G4XTRRegularRadModel()     
 47                                                   
 48 //////////////////////////////////////////////    
 49 void G4XTRRegularRadModel::ProcessDescription(    
 50 {                                                 
 51   out << "Describes X-ray transition radiation    
 52          "plates\n"                               
 53          "fixed.\n";                              
 54 }                                                 
 55                                                   
 56 //////////////////////////////////////////////    
 57 G4double G4XTRRegularRadModel::SpectralXTRdEdx    
 58 {                                                 
 59   static constexpr G4double cofPHC = 4. * pi *    
 60   G4double result, sum = 0., tmp, cof1, cof2,     
 61   G4double aMa, bMb, sigma, dump;                 
 62   G4int k, kMax, kMin;                            
 63                                                   
 64   aMa   = fPlateThick * GetPlateLinearPhotoAbs    
 65   bMb   = fGasThick * GetGasLinearPhotoAbs(ene    
 66   sigma = 0.5 * (aMa + bMb);                      
 67   dump  = std::exp(-fPlateNumber * sigma);        
 68   if(verboseLevel > 2)                            
 69     G4cout << " dump = " << dump << G4endl;       
 70   tmp  = (fSigma1 - fSigma2) / cofPHC / energy    
 71   cof1 = fPlateThick * tmp;                       
 72   cof2 = fGasThick * tmp;                         
 73                                                   
 74   cofMin = energy * (fPlateThick + fGasThick)     
 75   cofMin += (fPlateThick * fSigma1 + fGasThick    
 76   cofMin /= cofPHC;                               
 77                                                   
 78   theta2 = cofPHC / (energy * (fPlateThick + f    
 79                                                   
 80   kMin = G4int(cofMin);                           
 81   if(cofMin > kMin)                               
 82     kMin++;                                       
 83                                                   
 84   kMax = kMin + 49;                               
 85                                                   
 86   if(verboseLevel > 2)                            
 87   {                                               
 88     G4cout << cof1 << "     " << cof2 << "        
 89     G4cout << "kMin = " << kMin << ";    kMax     
 90   }                                               
 91   for(k = kMin; k <= kMax; ++k)                   
 92   {                                               
 93     tmp    = pi * fPlateThick * (k + cof2) / (    
 94     result = (k - cof1) * (k - cof1) * (k + co    
 95     if(k == kMin && kMin == G4int(cofMin))        
 96     {                                             
 97       sum +=                                      
 98         0.5 * std::sin(tmp) * std::sin(tmp) *     
 99     }                                             
100     else                                          
101     {                                             
102       sum += std::sin(tmp) * std::sin(tmp) * s    
103     }                                             
104     theta2k = std::sqrt(theta2 * std::abs(k -     
105                                                   
106     if(verboseLevel > 2)                          
107     {                                             
108       G4cout << k << "   " << theta2k << "        
109              << std::sin(tmp) * std::sin(tmp)     
110              << "      " << sum << G4endl;        
111     }                                             
112   }                                               
113   result = 2 * (cof1 + cof2) * (cof1 + cof2) *    
114   result *= dump * (-1 + dump + 2 * fPlateNumb    
115                                                   
116   return result;                                  
117 }                                                 
118                                                   
119 //////////////////////////////////////////////    
120 // Approximation for radiator interference fac    
121 // fully Regular radiator. The plate and gas g    
122 // The mean values of the plate and gas gap th    
123 // are supposed to be about XTR formation zone    
124 // mean absorption length of XTR photons in co    
125 G4double G4XTRRegularRadModel::GetStackFactor(    
126                                                   
127 {                                                 
128   G4double aZa = fPlateThick / GetPlateFormati    
129   G4double bZb = fGasThick / GetGasFormationZo    
130                                                   
131   G4double aMa = fPlateThick * GetPlateLinearP    
132   G4double bMb = fGasThick * GetGasLinearPhoto    
133                                                   
134   G4double Qa = std::exp(-aMa);                   
135   G4double Qb = std::exp(-bMb);                   
136   G4double Q  = Qa * Qb;                          
137                                                   
138   G4complex Ha(std::exp(-0.5 * aMa) * std::cos    
139                -std::exp(-0.5 * aMa) * std::si    
140                                                   
141   G4complex Hb(std::exp(-0.5 * bMb) * std::cos    
142                -std::exp(-0.5 * bMb) * std::si    
143                                                   
144   G4complex H  = Ha * Hb;                         
145   G4complex Hs = std::conj(H);                    
146                                                   
147   G4complex F2 = (1.0 - Ha) * (Qa - Ha) * Hb *    
148   F2 *= std::pow(Q, G4double(fPlateNumber)) -     
149                                                   
150   G4double result = (1. - std::pow(Q, G4double    
151   result *= (1. - Qa) * (1. + Qa - 2. * std::s    
152   result /= (1. - std::sqrt(Q)) * (1. - std::s    
153             4. * std::sqrt(Q) * std::sin(0.5 *    
154               std::sin(0.5 * (aZa + bZb));        
155                                                   
156   G4double I2 = 1.;                               
157   I2 /= (1. - std::sqrt(Q)) * (1. - std::sqrt(    
158         4. * std::sqrt(Q) * std::sin(0.5 * (aZ    
159           std::sin(0.5 * (aZa + bZb));            
160                                                   
161   I2 /= Q * ((std::sqrt(Q) - std::cos(aZa + bZ    
162                (std::sqrt(Q) - std::cos(aZa +     
163              std::sin(aZa + bZb) * std::sin(aZ    
164                                                   
165   G4complex stack = 2. * I2 * F2;                 
166   stack += result;                                
167   stack *= OneInterfaceXTRdEdx(energy, gamma,     
168                                                   
169   return std::real(stack);                        
170 }                                                 
171