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Geant4/processes/electromagnetic/xrays/src/G4RegularXTRadiator.cc

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Differences between /processes/electromagnetic/xrays/src/G4RegularXTRadiator.cc (Version 11.3.0) and /processes/electromagnetic/xrays/src/G4RegularXTRadiator.cc (Version 9.1.p2)


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 25 //                                                 25 //
                                                   >>  26 //
                                                   >>  27 // $Id: G4RegularXTRadiator.cc,v 1.9 2006/06/29 19:56:09 gunter Exp $
                                                   >>  28 // GEANT4 tag $Name: geant4-09-01-patch-02 $
                                                   >>  29 //
                                                   >>  30 
                                                   >>  31 #include <complex>
 26                                                    32 
 27 #include "G4RegularXTRadiator.hh"                  33 #include "G4RegularXTRadiator.hh"
                                                   >>  34 #include "Randomize.hh"
 28                                                    35 
 29 #include "G4Gamma.hh"                              36 #include "G4Gamma.hh"
 30 #include "G4PhysicalConstants.hh"              <<  37 
                                                   >>  38 using namespace std;
 31                                                    39 
 32 //////////////////////////////////////////////     40 ////////////////////////////////////////////////////////////////////////////
                                                   >>  41 //
 33 // Constructor, destructor                         42 // Constructor, destructor
 34 G4RegularXTRadiator::G4RegularXTRadiator(G4Log <<  43 
 35                                          G4Mat <<  44 G4RegularXTRadiator::G4RegularXTRadiator(G4LogicalVolume *anEnvelope,
 36                                          G4Mat <<  45            G4Material* foilMat,G4Material* gasMat, 
 37                                          G4dou <<  46                                          G4double a, G4double b, G4int n,
 38                                          const <<  47                                          const G4String& processName) :
 39   : G4VXTRenergyLoss(anEnvelope, foilMat, gasM <<  48   G4VXTRenergyLoss(anEnvelope,foilMat,gasMat,a,b,n,processName)
 40 {                                                  49 {
 41   G4cout << "Regular X-ray TR radiator EM proc <<  50   G4cout<<"Regular X-ray TR  radiator EM process is called"<<G4endl ;
 42                                                    51 
 43   // Build energy and angular integral spectra     52   // Build energy and angular integral spectra of X-ray TR photons from
 44   // a radiator                                    53   // a radiator
 45                                                    54 
 46   fAlphaPlate = 10000;                             55   fAlphaPlate = 10000;
 47   fAlphaGas   = 1000;                              56   fAlphaGas   = 1000;
 48   G4cout << "fAlphaPlate = " << fAlphaPlate << <<  57   G4cout<<"fAlphaPlate = "<<fAlphaPlate<<" ; fAlphaGas = "<<fAlphaGas<<G4endl ;
 49          << G4endl;                            <<  58 
                                                   >>  59   // BuildTable() ;
 50 }                                                  60 }
 51                                                    61 
 52 //////////////////////////////////////////////     62 ///////////////////////////////////////////////////////////////////////////
 53 G4RegularXTRadiator::~G4RegularXTRadiator() =  << 
 54                                                    63 
 55 void G4RegularXTRadiator::ProcessDescription(s <<  64 G4RegularXTRadiator::~G4RegularXTRadiator()
 56 {                                                  65 {
 57   out << "Simulation of X-ray transition radia <<  66   ;
 58          "relativistic charged particles cross << 
 59          "two materials. Thicknesses of plates << 
 60 }                                                  67 }
 61                                                    68 
 62 ////////////////////////////////////////////// << 
 63 G4double G4RegularXTRadiator::SpectralXTRdEdx( << 
 64 {                                              << 
 65   G4double result, sum = 0., tmp, cof1, cof2,  << 
 66   G4double aMa, bMb, sigma, dump;              << 
 67   G4int k, kMax, kMin;                         << 
 68                                                << 
 69   aMa   = fPlateThick * GetPlateLinearPhotoAbs << 
 70   bMb   = fGasThick * GetGasLinearPhotoAbs(ene << 
 71   sigma = 0.5 * (aMa + bMb);                   << 
 72   dump  = std::exp(-fPlateNumber * sigma);     << 
 73   if(verboseLevel > 2)                         << 
 74     G4cout << " dump = " << dump << G4endl;    << 
 75   cofPHC = 4 * pi * hbarc;                     << 
 76   tmp    = (fSigma1 - fSigma2) / cofPHC / ener << 
 77   cof1   = fPlateThick * tmp;                  << 
 78   cof2   = fGasThick * tmp;                    << 
 79                                                << 
 80   cofMin = energy * (fPlateThick + fGasThick)  << 
 81   cofMin += (fPlateThick * fSigma1 + fGasThick << 
 82   cofMin /= cofPHC;                            << 
 83                                                << 
 84   theta2 = cofPHC / (energy * (fPlateThick + f << 
 85                                                << 
 86   kMin = G4int(cofMin);                        << 
 87   if(cofMin > kMin)                            << 
 88     kMin++;                                    << 
 89                                                << 
 90   kMax = kMin + 49;                            << 
 91                                                    69 
 92   if(verboseLevel > 2)                         << 
 93   {                                            << 
 94     G4cout << cof1 << "     " << cof2 << "     << 
 95     G4cout << "kMin = " << kMin << ";    kMax  << 
 96   }                                            << 
 97   for(k = kMin; k <= kMax; ++k)                << 
 98   {                                            << 
 99     tmp    = pi * fPlateThick * (k + cof2) / ( << 
100     result = (k - cof1) * (k - cof1) * (k + co << 
101     if(k == kMin && kMin == G4int(cofMin))     << 
102     {                                          << 
103       sum +=                                   << 
104         0.5 * std::sin(tmp) * std::sin(tmp) *  << 
105     }                                          << 
106     else                                       << 
107     {                                          << 
108       sum += std::sin(tmp) * std::sin(tmp) * s << 
109     }                                          << 
110     theta2k = std::sqrt(theta2 * std::abs(k -  << 
111                                                << 
112     if(verboseLevel > 2)                       << 
113     {                                          << 
114       G4cout << k << "   " << theta2k << "     << 
115              << std::sin(tmp) * std::sin(tmp)  << 
116              << "      " << sum << G4endl;     << 
117     }                                          << 
118   }                                            << 
119   result = 2 * (cof1 + cof2) * (cof1 + cof2) * << 
120   result *= (1 - dump + 2 * dump * fPlateNumbe << 
121                                                << 
122   return result;                               << 
123 }                                              << 
124                                                    70 
125 //////////////////////////////////////////////     71 ///////////////////////////////////////////////////////////////////////////
                                                   >>  72 //
126 // Approximation for radiator interference fac     73 // Approximation for radiator interference factor for the case of
127 // fully Regular radiator. The plate and gas g <<  74 // fully Regular radiator. The plate and gas gap thicknesses are fixed .
128 // The mean values of the plate and gas gap th <<  75 // The mean values of the plate and gas gap thicknesses 
129 // are supposed to be about XTR formation zone <<  76 // are supposed to be about XTR formation zones but much less than 
130 // mean absorption length of XTR photons in co <<  77 // mean absorption length of XTR photons in coresponding material.
131                                                <<  78 
132 G4double G4RegularXTRadiator::GetStackFactor(G <<  79 G4double 
133                                              G <<  80 G4RegularXTRadiator::GetStackFactor( G4double energy, 
                                                   >>  81                                          G4double gamma, G4double varAngle )
134 {                                                  82 {
                                                   >>  83 
135   // some gamma (10000/1000) like algorithm        84   // some gamma (10000/1000) like algorithm
136                                                    85 
137   G4double result, Za, Zb, Ma, Mb;                 86   G4double result, Za, Zb, Ma, Mb;
138                                                <<  87   
139   Za = GetPlateFormationZone(energy, gamma, va <<  88   Za = GetPlateFormationZone(energy,gamma,varAngle);
140   Zb = GetGasFormationZone(energy, gamma, varA <<  89   Zb = GetGasFormationZone(energy,gamma,varAngle);
141                                                    90 
142   Ma = GetPlateLinearPhotoAbs(energy);             91   Ma = GetPlateLinearPhotoAbs(energy);
143   Mb = GetGasLinearPhotoAbs(energy);               92   Mb = GetGasLinearPhotoAbs(energy);
144                                                    93 
145   G4complex Ca(1.0 + 0.5 * fPlateThick * Ma /  << 
146                fPlateThick / Za / fAlphaPlate) << 
147   G4complex Cb(1.0 + 0.5 * fGasThick * Mb / fA << 
148                fGasThick / Zb / fAlphaGas);    << 
149                                                    94 
150   G4complex Ha = std::pow(Ca, -fAlphaPlate);   <<  95   G4complex Ca(1.0+0.5*fPlateThick*Ma/fAlphaPlate,fPlateThick/Za/fAlphaPlate); 
151   G4complex Hb = std::pow(Cb, -fAlphaGas);     <<  96   G4complex Cb(1.0+0.5*fGasThick*Mb/fAlphaGas,fGasThick/Zb/fAlphaGas); 
152   G4complex H  = Ha * Hb;                      <<  97 
                                                   >>  98   G4complex Ha = pow(Ca,-fAlphaPlate);  
                                                   >>  99   G4complex Hb = pow(Cb,-fAlphaGas);
                                                   >> 100   G4complex H  = Ha*Hb;
                                                   >> 101   
                                                   >> 102   G4complex F1 =   (1.0 - Ha)*(1.0 - Hb )/(1.0 - H)
                                                   >> 103                  * G4double(fPlateNumber);
                                                   >> 104 
                                                   >> 105   G4complex F2 =   (1.0-Ha)*(1.0-Ha)*Hb/(1.0-H)/(1.0-H)
                                                   >> 106                  * (1.0 - pow(H,fPlateNumber));
                                                   >> 107 
                                                   >> 108   G4complex R  = (F1 + F2)*OneInterfaceXTRdEdx(energy,gamma,varAngle);
                                                   >> 109   
                                                   >> 110   result       = 2.0*real(R);
                                                   >> 111   
                                                   >> 112   return      result;
                                                   >> 113   
                                                   >> 114   /*
                                                   >> 115    // numerically stable but slow algorithm
                                                   >> 116 
                                                   >> 117   G4double result, Qa, Qb, Q, aZa, bZb, aMa, bMb;   // , D; 
                                                   >> 118  
                                                   >> 119   aZa = fPlateThick/GetPlateFormationZone(energy,gamma,varAngle);
                                                   >> 120   bZb = fGasThick/GetGasFormationZone(energy,gamma,varAngle);
                                                   >> 121   aMa = fPlateThick*GetPlateLinearPhotoAbs(energy);
                                                   >> 122   bMb = fGasThick*GetGasLinearPhotoAbs(energy);
                                                   >> 123   Qa = exp(-aMa);
                                                   >> 124   Qb = exp(-bMb);
                                                   >> 125   Q  = Qa*Qb;
                                                   >> 126   G4complex Ha( exp(-0.5*aMa)*cos(aZa),
                                                   >> 127                -exp(-0.5*aMa)*sin(aZa)   );  
                                                   >> 128   G4complex Hb( exp(-0.5*bMb)*cos(bZb),
                                                   >> 129                -exp(-0.5*bMb)*sin(bZb)    );
                                                   >> 130   G4complex H  = Ha*Hb;
                                                   >> 131   
                                                   >> 132   G4complex Hs = conj(H);
                                                   >> 133   D            = 1.0 /( (1 - sqrt(Q))*(1 - sqrt(Q)) + 
                                                   >> 134                   4*sqrt(Q)*sin(0.5*(aZa+bZb))*sin(0.5*(aZa+bZb)) );
                                                   >> 135   G4complex F1 = (1.0 - Ha)*(1.0 - Hb)*(1.0 - Hs)
                                                   >> 136                  * G4double(fPlateNumber)*D;
                                                   >> 137   G4complex F2 = (1.0-Ha)*(1.0-Ha)*Hb*(1.0-Hs)*(1.0-Hs)
                                                   >> 138                  * (1.0 - pow(H,fPlateNumber)) * D*D;
                                                   >> 139   G4complex R  = (F1 + F2)*OneInterfaceXTRdEdx(energy,gamma,varAngle);
                                                   >> 140   
                                                   >> 141 
                                                   >> 142   G4complex S(0.,0.), c(1.,0.);
                                                   >> 143   G4int k;
                                                   >> 144   for(k = 1; k < fPlateNumber; k++)
                                                   >> 145   {
                                                   >> 146     c *= H;
                                                   >> 147     S += ( G4double(fPlateNumber) - G4double(k) )*c; 
                                                   >> 148   }
                                                   >> 149   G4complex R  = (2.- Ha - 1./Ha)*S + (1. - Ha)*G4double(fPlateNumber);
                                                   >> 150             R *= OneInterfaceXTRdEdx(energy,gamma,varAngle);
                                                   >> 151   result       = 2.0*real(R); 
                                                   >> 152   return      result;
                                                   >> 153   */
                                                   >> 154 }
                                                   >> 155 
                                                   >> 156 
                                                   >> 157 //
                                                   >> 158 //
                                                   >> 159 ////////////////////////////////////////////////////////////////////////////
                                                   >> 160 
                                                   >> 161 
                                                   >> 162 
153                                                   163 
154   G4complex F1 = (1.0 - Ha) * (1.0 - Hb) / (1. << 
155                                                   164 
156   G4complex F2 = (1.0 - Ha) * (1.0 - Ha) * Hb  << 
157                  (1.0 - std::pow(H, fPlateNumb << 
158                                                   165 
159   G4complex R = (F1 + F2) * OneInterfaceXTRdEd << 
160                                                   166 
161   result = 2.0 * std::real(R);                 << 
162                                                   167 
163   return result;                               << 
164 }                                              << 
165                                                   168