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Geant4/parameterisations/channeling/src/G4BaierKatkov.cc

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Diff markup

Differences between /parameterisations/channeling/src/G4BaierKatkov.cc (Version 11.3.0) and /parameterisations/channeling/src/G4BaierKatkov.cc (Version 8.2.p1)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 // Author:      Alexei Sytov                      
 27 // Co-author:   Gianfranco Paterno (modificati    
 28 // On the base of the CRYSTALRAD realization o    
 29 // A. I. Sytov, V. V. Tikhomirov, and L. Bandi    
 30                                                   
 31 #include "G4BaierKatkov.hh"                       
 32                                                   
 33 #include "Randomize.hh"                           
 34 #include "G4Gamma.hh"                             
 35 #include "G4SystemOfUnits.hh"                     
 36 #include "G4PhysicalConstants.hh"                 
 37 #include "G4Log.hh"                               
 38                                                   
 39 G4BaierKatkov::G4BaierKatkov()                    
 40 {                                                 
 41     //sets the default spectrum energy range o    
 42     //calls ResetRadIntegral()                    
 43     SetSpectrumEnergyRange(0.1*MeV,1.*GeV,110)    
 44                                                   
 45     //Do not worry if the maximal energy > par    
 46     //this elements of spectrum with non-physi    
 47     //will not be processed (they will be 0)      
 48                                                   
 49     G4cout << " "<< G4endl;                       
 50     G4cout << "G4BaierKatkov model is activate    
 51     G4cout << " "<< G4endl;                       
 52 }                                                 
 53                                                   
 54 //....oooOO0OOooo........oooOO0OOooo........oo    
 55                                                   
 56 void G4BaierKatkov::ResetRadIntegral()            
 57 {                                                 
 58     fAccumSpectrum.clear();                       
 59                                                   
 60     //reinitialize intermediate integrals with    
 61     fFa.resize(fNMCPhotons);                      
 62     fSs.resize(fNMCPhotons);                      
 63     fSc.resize(fNMCPhotons);                      
 64     fSsx.resize(fNMCPhotons);                     
 65     fSsy.resize(fNMCPhotons);                     
 66     fScx.resize(fNMCPhotons);                     
 67     fScy.resize(fNMCPhotons);                     
 68     std::fill(fFa.begin(), fFa.end(), 0.);        
 69     std::fill(fSs.begin(), fSs.end(), 0.);        
 70     std::fill(fSc.begin(), fSc.end(), 0.);        
 71     std::fill(fSsx.begin(), fSsx.end(), 0.);      
 72     std::fill(fSsy.begin(), fSsy.end(), 0.);      
 73     std::fill(fScx.begin(), fScx.end(), 0.);      
 74     std::fill(fScy.begin(), fScy.end(), 0.);      
 75                                                   
 76     //Reset radiation integral internal variab    
 77     fMeanPhotonAngleX =0.;        //average an    
 78                                   //radiated p    
 79     fParamPhotonAngleX=1.e-3*rad; //a paramete    
 80                                   //radiated p    
 81     fMeanPhotonAngleY =0.;        //average an    
 82                                   //radiated p    
 83     fParamPhotonAngleY=1.e-3*rad; //a paramete    
 84                                   //radiated p    
 85                                                   
 86     fImin0 = 0;//set the first vector element     
 87                                                   
 88     //reset the trajectory                        
 89     fParticleAnglesX.clear();                     
 90     fParticleAnglesY.clear();                     
 91     fScatteringAnglesX.clear();                   
 92     fScatteringAnglesY.clear();                   
 93     fSteps.clear();                               
 94     fGlobalTimes.clear();                         
 95     fParticleCoordinatesXYZ.clear();              
 96                                                   
 97     //resets the vector of element numbers at     
 98     fImax0.clear();                               
 99     //sets 0 element of the vector of element     
100     fImax0.push_back(0.);                         
101                                                   
102     //resets the radiation probability            
103     fTotalRadiationProbabilityAlongTrajectory.    
104     //sets the radiation probability at the tr    
105     fTotalRadiationProbabilityAlongTrajectory.    
106 }                                                 
107                                                   
108 //....oooOO0OOooo........oooOO0OOooo........oo    
109                                                   
110 void G4BaierKatkov::SetSpectrumEnergyRange(G4d    
111                                            G4d    
112                                            G4i    
113 {                                                 
114     fMinPhotonEnergy = emin;                      
115     fMaxPhotonEnergy = emax;                      
116     fNBinsSpectrum = numberOfBins;                
117                                                   
118     fLogEmaxdEmin = G4Log(fMaxPhotonEnergy/fMi    
119                                                   
120     //in initializing fNPhotonsPerBin             
121     fNPhotonsPerBin.resize(fNBinsSpectrum);       
122     std::fill(fNPhotonsPerBin.begin(), fNPhoto    
123                                                   
124     //initializing the Spectrum                   
125     fSpectrum.resize(fNBinsSpectrum);             
126     std::fill(fSpectrum.begin(), fSpectrum.end    
127                                                   
128     //initializing the fAccumTotalSpectrum        
129     fAccumTotalSpectrum.resize(fNBinsSpectrum)    
130     std::fill(fAccumTotalSpectrum.begin(), fAc    
131                                                   
132     //initializing the fTotalSpectrum             
133     fTotalSpectrum.resize(fNBinsSpectrum);        
134     std::fill(fTotalSpectrum.begin(), fTotalSp    
135                                                   
136     fPhotonEnergyInSpectrum.clear();              
137     for (G4int j=0;j<fNBinsSpectrum;j++)          
138     {                                             
139         //bin position (mean between 2 bin lim    
140         fPhotonEnergyInSpectrum.push_back(fMin    
141                                        (std::e    
142                                         std::e    
143     }                                             
144                                                   
145     fItrajectories = 0;                           
146                                                   
147     ResetRadIntegral();                           
148 }                                                 
149                                                   
150 //....oooOO0OOooo........oooOO0OOooo........oo    
151                                                   
152 void G4BaierKatkov::AddStatisticsInPhotonEnerg    
153                                                   
154                                                   
155 {                                                 
156                                                   
157     if(timesPhotonStatistics<=1)                  
158     {                                             
159         G4cout << "G4BaierKatkov model, "         
160                   "function AddStatisticsInPho    
161                               << emin/CLHEP::M    
162                               << emax/CLHEP::M    
163                               << timesPhotonSt    
164         G4cout << "Warning: the statistics fac    
165         G4cout << "The statistics was not adde    
166         G4cout << " "<< G4endl;                   
167     }                                             
168     else if(fMinPhotonEnergy>emin)                
169     {                                             
170         G4cout << "G4BaierKatkov model, "         
171                   "function AddStatisticsInPho    
172                               << emin/CLHEP::M    
173                               << emax/CLHEP::M    
174                               << timesPhotonSt    
175         G4cout << "Warning: the minimal energy    
176                   "the minimal energy cut of t    
177                << fMinPhotonEnergy/CLHEP::MeV     
178         G4cout << "The statistics was not adde    
179         G4cout << " "<< G4endl;                   
180     }                                             
181     else if(emax-emin<DBL_EPSILON)                
182     {                                             
183         G4cout << "G4BaierKatkov model, "         
184                   "function AddStatisticsInPho    
185                               << emin/CLHEP::M    
186                               << emax/CLHEP::M    
187                               << timesPhotonSt    
188         G4cout << "Warning: the maximal energy    
189         G4cout << "The statistics was not adde    
190         G4cout << " "<< G4endl;                   
191     }                                             
192     else                                          
193     {                                             
194         G4bool setrange = true;                   
195         G4double logAddRangeEmindEmin = G4Log(    
196         G4double logAddRangeEmaxdEmin = G4Log(    
197                                                   
198         G4int nAddRange = (G4int)fTimesPhotonS    
199         for (G4int j=0;j<nAddRange;j++)           
200         {                                         
201             if((logAddRangeEmindEmin>=fLogAddR    
202                 logAddRangeEmindEmin< fLogAddR    
203                (logAddRangeEmaxdEmin> fLogAddR    
204                 logAddRangeEmaxdEmin<=fLogAddR    
205                (logAddRangeEmindEmin<=fLogAddR    
206                 logAddRangeEmaxdEmin>=fLogAddR    
207             {                                     
208                 G4cout << "G4BaierKatkov model    
209                           "function AddStatist    
210                                       << emin/    
211                                       << emax/    
212                                       << times    
213                G4cout << "Warning: the energy     
214                          "added energy range."    
215                G4cout << "The statistics was n    
216                G4cout << " "<< G4endl;            
217                setrange = false;                  
218                break;                             
219             }                                     
220         }                                         
221         if (setrange)                             
222         {                                         
223             fLogAddRangeEmindEmin.push_back(lo    
224             fLogAddRangeEmaxdEmin.push_back(lo    
225             fTimesPhotonStatistics.push_back(t    
226                                                   
227             G4cout << "G4BaierKatkov model: in    
228                       "in Baier-Katkov with a     
229                    << timesPhotonStatistics <<    
230             G4cout << "in the energy spectrum     
231                    << emin/CLHEP::MeV << " MeV    
232                    << emax/CLHEP::MeV << " MeV    
233         }                                         
234     }                                             
235 }                                                 
236                                                   
237 //....oooOO0OOooo........oooOO0OOooo........oo    
238                                                   
239 void G4BaierKatkov::SetPhotonSamplingParameter    
240                                                   
241                                                   
242                                                   
243                                                   
244 {                                                 
245     fLogEdEmin = G4Log(ekin/fMinPhotonEnergy);    
246     fMeanPhotonAngleX  = (maxPhotonAngleX+minP    
247     fParamPhotonAngleX = (maxPhotonAngleX-minP    
248     fMeanPhotonAngleY  = (maxPhotonAngleY+minP    
249     fParamPhotonAngleY = (maxPhotonAngleY-minP    
250 }                                                 
251                                                   
252 //....oooOO0OOooo........oooOO0OOooo........oo    
253                                                   
254 void G4BaierKatkov::GeneratePhotonSampling()      
255 {                                                 
256     fPhotonEnergyInIntegral.clear();              
257     fPhotonAngleInIntegralX.clear();              
258     fPhotonAngleInIntegralY.clear();              
259     fPhotonAngleNormCoef.clear();                 
260     fInsideVirtualCollimator.clear();             
261     fIBinsSpectrum.clear();                       
262                                                   
263     G4double ksi=0.;                              
264     std::vector<G4int> moreStatistics;            
265     moreStatistics.resize(fTimesPhotonStatisti    
266     std::fill(moreStatistics.begin(), moreStat    
267     G4int nAddRange = (G4int)fTimesPhotonStati    
268                                                   
269     //sampling of the energy of a photon emiss    
270     //(integration variables, Monte Carlo inte    
271     for (G4int j=0;j<fNMCPhotons;j++)             
272     {                                             
273         ksi = G4UniformRand()*fLogEdEmin;         
274         fIBinsSpectrum.push_back((G4int)std::t    
275                                      ksi*fNBin    
276         //we consider also the energy outside     
277         //(E>Emax => fLogEdEmin>fLogEmaxdEmin)    
278         //in this case we don't count the phot    
279         if(fIBinsSpectrum[j]<fNBinsSpectrum) {    
280                                                   
281         fPhotonEnergyInIntegral.push_back(fMin    
282                                                   
283         fPhotonAngleNormCoef.push_back(1.);       
284                                                   
285         for (G4int j2=0;j2<nAddRange;j2++)        
286         {                                         
287             if(ksi>fLogAddRangeEmindEmin[j2]&&    
288                ksi<fLogAddRangeEmaxdEmin[j2])     
289             {                                     
290                //calculating the current stati    
291                //to increase it proportionally    
292                moreStatistics[j2]+=1;             
293                fPhotonAngleNormCoef[j]/=fTimes    
294                break;                             
295             }                                     
296         }                                         
297     }                                             
298                                                   
299     for (G4int j2=0;j2<nAddRange;j2++)            
300     {                                             
301         G4int totalAddRangeStatistics = moreSt    
302         for (G4int j=moreStatistics[j2];j<tota    
303         {                                         
304             ksi = fLogAddRangeEmindEmin[j2]+      
305                   G4UniformRand()*(std::min(fL    
306                                    fLogAddRang    
307             fIBinsSpectrum.push_back((G4int)st    
308                                          ksi*f    
309          /*   //we consider also the energy ou    
310             //(E>Emax => fLogEdEmin>fLogEmaxdE    
311             //in this case we don't count the     
312             if(fIBinsSpectrum.back()<fNBinsSpe    
313                 {fNPhotonsPerBin[fIBinsSpectru    
314                                                   
315             fPhotonEnergyInIntegral.push_back(    
316                                                   
317             fPhotonAngleNormCoef.push_back(1./    
318         }                                         
319     }                                             
320                                                   
321     G4double rho=1.;                              
322     const G4double rhocut=15.;//radial angular    
323     G4double norm=std::atan(rhocut*rhocut)*       
324                             CLHEP::pi*fParamPh    
325                                                   
326     //sampling of the angles of a photon emiss    
327     //(integration variables, Monte Carlo inte    
328     G4int nmctotal = (G4int)fPhotonEnergyInInt    
329     for (G4int j=0;j<nmctotal;j++)                
330     {                                             
331         //photon distribution with long tails     
332         //after a strong single scattering)       
333         //at ellipsescale < 1 => half of stati    
334         do                                        
335         {                                         
336             rho = std::sqrt(std::tan(CLHEP::ha    
337         }                                         
338         while (rho>rhocut);                       
339                                                   
340         ksi = G4UniformRand();                    
341         fPhotonAngleInIntegralX.push_back(fMea    
342                                          fPara    
343                                           rho*    
344         fPhotonAngleInIntegralY.push_back(fMea    
345                                          fPara    
346                                           rho*    
347         fPhotonAngleNormCoef[j]*=(1.+rho*rho*r    
348                                                   
349         //test if the photon with these angles    
350         //(doesn't influence the Geant4 simula    
351         //but only the accumulation of fTotalS    
352         fInsideVirtualCollimator.push_back(fVi    
353                                            std    
354                                                   
355                                                   
356                                                   
357     }                                             
358     //reinitialize the vector of radiation CDF    
359     fPhotonProductionCDF.resize(nmctotal+1);//    
360     std::fill(fPhotonProductionCDF.begin(), fP    
361                                                   
362     //if we have additional photons               
363     if (nmctotal>fNMCPhotons)                     
364     {                                             
365         //reinitialize intermediate integrals     
366         fFa.resize(nmctotal);                     
367         fSs.resize(nmctotal);                     
368         fSc.resize(nmctotal);                     
369         fSsx.resize(nmctotal);                    
370         fSsy.resize(nmctotal);                    
371         fScx.resize(nmctotal);                    
372         fScy.resize(nmctotal);                    
373         std::fill(fFa.begin(), fFa.end(), 0.);    
374         std::fill(fSs.begin(), fSs.end(), 0.);    
375         std::fill(fSc.begin(), fSc.end(), 0.);    
376         std::fill(fSsx.begin(), fSsx.end(), 0.    
377         std::fill(fSsy.begin(), fSsy.end(), 0.    
378         std::fill(fScx.begin(), fScx.end(), 0.    
379         std::fill(fScy.begin(), fScy.end(), 0.    
380     }                                             
381 }                                                 
382                                                   
383 //....oooOO0OOooo........oooOO0OOooo........oo    
384                                                   
385 G4double G4BaierKatkov::RadIntegral(G4double e    
386                                     std::vecto    
387                                     std::vecto    
388                                     std::vecto    
389                                     std::vecto    
390                                     std::vecto    
391                                     G4int imin    
392 {                                                 
393     //preliminary values are defined:             
394                                                   
395     G4double om=0.;// photon energy               
396     G4double eprime=0., eprime2=0.; //E'=E-ome    
397     G4double omprime=0.,omprimed2=0.;//om'=(E*    
398     G4double vxin =0.,vyin=0.,vxno=0.,vyno=0.;    
399                                                   
400     G4double dzmod=0.;                            
401     G4double fa1=0.,faseBefore=0.,faseBeforedz    
402     G4double faseAfter=0.,fa2dfaseBefore2=0.;     
403                                                   
404     G4double skJ=0, skIx=0., skIy=0.;             
405     G4double sinfa1=0.,cosfa1=0.;                 
406     G4double i2=0.,j2=0.;// Ix^2+Iy^2 and of B    
407                                                   
408     std::size_t nparts=vectorParticleAnglesX.s    
409     G4int kmin = imin;                            
410     if(imin==0) {kmin=1;}//skipping 0 trajecto    
411                                                   
412     //total radiation probability for each pho    
413     G4double totalRadiationProbabilityPhj = 0.    
414                                                   
415     //total radiation probability along this t    
416     fTotalRadiationProbabilityAlongTrajectory.    
417                                                   
418     //reset Spectrum                              
419     std::fill(fSpectrum.begin(), fSpectrum.end    
420                                                   
421     //intermediate vectors to reduce calculati    
422     std::vector<G4double> axt;//acceleration o    
423     axt.resize(nparts);                           
424     std::vector<G4double> ayt;//acceleration o    
425     ayt.resize(nparts);                           
426     std::vector<G4double> dz;//step in in MeV^    
427     dz.resize(nparts);                            
428     //setting values interesting for us           
429     for(std::size_t k=kmin;k<nparts;k++)          
430     {                                             
431         dz[k]=vectorSteps[k]/CLHEP::hbarc;// d    
432                                                   
433         // accelerations                          
434         axt[k]=(vectorParticleAnglesX[k]-vecto    
435                 vectorParticleAnglesX[k-1])/dz    
436         ayt[k]=(vectorParticleAnglesY[k]-vecto    
437                 vectorParticleAnglesY[k-1])/dz    
438     }                                             
439                                                   
440     //intermediate variables to reduce calcula    
441     //the calculations inside for (G4int j=0;j    
442     //{for(G4int k=kmin;k<nparts;k++){...         
443     //are the main cpu time consumption           
444     G4double e2 = etotal*etotal;                  
445     G4double gammaInverse2 = mass*mass/(etotal    
446                                                   
447     G4double coefNormLogdNMC = fLogEdEmin/fNMC    
448                                           //ad    
449                                           //ta    
450     G4double coefNorm = CLHEP::fine_structure_    
451     G4double e2pluseprime2 = 0.;//e2pluseprime    
452     G4double coefNormom2deprime2 = 0.; //coefN    
453     G4double gammaInverse2om2 = 0.; //gammaInv    
454                                                   
455     std::size_t nmctotal = fPhotonEnergyInInte    
456     for (std::size_t j=0;j<nmctotal;j++)          
457         //the final number of photons may be d    
458     {                                             
459         om = fPhotonEnergyInIntegral[j];          
460         eprime=etotal-om; //E'=E-omega            
461         eprime2 = eprime*eprime;                  
462         e2pluseprime2 =e2+eprime2;                
463         omprime=etotal*om/eprime;//om'=(E*om/E    
464         omprimed2=omprime/2;                      
465         coefNormom2deprime2 = coefNorm*om*om/e    
466         gammaInverse2om2 = gammaInverse2*om*om    
467                                                   
468         for(std::size_t k=kmin;k<nparts;k++)      
469         {                                         
470             //the angles of a photon produced     
471             vxin = vectorParticleAnglesX[k]-fP    
472             vyin = vectorParticleAnglesY[k]-fP    
473             //the angles of a photon produced     
474             vxno = vxin-vectorScatteringAngles    
475             vyno = vyin-vectorScatteringAngles    
476                                                   
477             //phase difference before scatteri    
478             faseBefore=omprimed2*(gammaInverse    
479                                                   
480             faseBeforedz = faseBefore*dz[k];      
481             faseBeforedzd2 = faseBeforedz/2.;     
482             fFa[j]+=faseBeforedz; //              
483             fa1=fFa[j]-faseBeforedzd2;//          
484             dzmod=2*std::sin(faseBeforedzd2)/f    
485                                                   
486             //phi''/faseBefore^2                  
487             fa2dfaseBefore2 = omprime*(axt[k]*    
488                                                   
489             //phase difference after scatterin    
490             faseAfter=omprimed2*(gammaInverse2    
491                                                   
492             skJ=1/faseAfter-1/faseBefore-fa2df    
493             skIx=vxin/faseAfter-vxno/faseBefor    
494                                                   
495             skIy=vyin/faseAfter-vyno/faseBefor    
496                                                   
497                                                   
498             sinfa1 = std::sin(fa1);               
499             cosfa1 = std::cos(fa1);               
500                                                   
501             fSs[j]+=sinfa1*skJ;//sum sin integ    
502             fSc[j]+=cosfa1*skJ;//sum cos integ    
503             fSsx[j]+=sinfa1*skIx;// sum sin in    
504             fSsy[j]+=sinfa1*skIy;// sum sin in    
505             fScx[j]+=cosfa1*skIx;// sum cos in    
506             fScy[j]+=cosfa1*skIy;// sum cos in    
507                                                   
508             i2=fSsx[j]*fSsx[j]+fScx[j]*fScx[j]    
509             j2=fSs[j]*fSs[j]+fSc[j]*fSc[j];//M    
510                                                   
511             //updating the total radiation pro    
512             totalRadiationProbabilityPhj = coe    
513                     (i2*e2pluseprime2+j2*gamma    
514             fTotalRadiationProbabilityAlongTra    
515         }                                         
516                                                   
517         fPhotonProductionCDF[j+1] = fTotalRadi    
518                                                   
519         //filling spectrum (adding photon prob    
520         //we consider also the energy outside     
521         //(E>Emax => fLogEdEmin>fLogEmaxdEmin)    
522         //in this case we don't count the phot    
523         //we fill the spectrum only in case of    
524         if((fIBinsSpectrum[j]<fNBinsSpectrum)&    
525             {fSpectrum[fIBinsSpectrum[j]] += t    
526                     (om*coefNormLogdNMC);}        
527                                                   
528     } // end cycle                                
529                                                   
530     fAccumSpectrum.push_back(fSpectrum);          
531                                                   
532     return fTotalRadiationProbabilityAlongTraj    
533 }                                                 
534                                                   
535 //....oooOO0OOooo........oooOO0OOooo........oo    
536                                                   
537 G4int G4BaierKatkov::FindVectorIndex(std::vect    
538 {                                                 
539     auto iteratorbegin = myvector.begin();        
540     auto iteratorend   = myvector.end();          
541                                                   
542     //vector index (for non precise values low    
543     auto loweriterator = std::lower_bound(iter    
544     //return the index of the vector element      
545     return (G4int)std::distance(iteratorbegin,    
546 }                                                 
547                                                   
548 //....oooOO0OOooo........oooOO0OOooo........oo    
549                                                   
550 G4bool G4BaierKatkov::SetPhotonProductionParam    
551 {                                                 
552     //flag if a photon was produced               
553     G4bool flagPhotonProduced = false;            
554                                                   
555     //how many small pieces of a trajectory ar    
556     //before radiation (all if not radiation)     
557     std::size_t nodeNumber = fAccumSpectrum.si    
558                                                   
559     //ksi is a random number                      
560     //Generally ksi = G4UniformRand() is ok, b    
561     //we use as a correction for the case         
562     //when the radiation probability becomes t    
563     G4double ksi = -G4Log(G4UniformRand());       
564                                                   
565     if (ksi< fTotalRadiationProbabilityAlongTr    
566     {                                             
567       G4double ksi1 = G4UniformRand()*fTotalRa    
568                                                   
569       //randomly choosing the photon to be pro    
570       //according to the probabilities calcula    
571       G4int iphoton = FindVectorIndex(fPhotonP    
572                                                   
573                                                   
574       //energy of the photon produced             
575       fEph0 = fPhotonEnergyInIntegral[iphoton]    
576       //anagles of the photon produced            
577       G4double photonAngleX = fPhotonAngleInIn    
578       G4double photonAngleY = fPhotonAngleInIn    
579                                                   
580       G4double momentumDirectionZ = 1./           
581           std::sqrt(1.+std::pow(std::tan(photo    
582                        std::pow(std::tan(photo    
583                                                   
584       //momentum direction vector of the photo    
585       PhMomentumDirection.set(momentumDirectio    
586                               momentumDirectio    
587                               momentumDirectio    
588                                                   
589       //random calculation of the radiation po    
590       //ksi = G4UniformRand()*fTotalRadiationP    
591                                                   
592       //sort fTotalRadiationProbabilityAlongTr    
593       //(increasing but oscillating function =    
594       std::vector<G4double> temporaryVector;      
595       temporaryVector.assign(fTotalRadiationPr    
596                              fTotalRadiationPr    
597       std::sort(temporaryVector.begin(), tempo    
598                                                   
599       //index of the point of radiation ("post    
600       G4int iNode = FindVectorIndex(temporaryV    
601                                                   
602       //index of the point of radiation ("post    
603       auto it = std::find_if(fTotalRadiationPr    
604                              fTotalRadiationPr    
605                              [&](G4double valu    
606                        {return std::abs(value     
607       iNode = (G4int)std::distance(fTotalRadia    
608                                                   
609       //the piece of trajectory number (necess    
610       nodeNumber = FindVectorIndex(fImax0,iNod    
611                                                   
612       //set new parameters of the charged part    
613       //(returning the particle back to the ra    
614       //remembering the new parameters for cor    
615       fNewParticleEnergy = etotal-fEph0;          
616       fNewParticleAngleX = fParticleAnglesX[iN    
617       fNewParticleAngleY = fParticleAnglesY[iN    
618       fNewGlobalTime = fGlobalTimes[iNode];       
619       fNewParticleCoordinateXYZ = fParticleCoo    
620                                                   
621       //particle angle correction from momentu    
622       //(important for fEph0 comparable to E,     
623       // may kick off a particle from channeli    
624       G4double pratio = fEph0/std::sqrt(etotal    
625       fNewParticleAngleX -= std::asin(pratio*s    
626       fNewParticleAngleY -= std::asin(pratio*s    
627                                                   
628       flagPhotonProduced = true;                  
629     }                                             
630                                                   
631     //accumulation during entire code run         
632     for (G4int j=0;j<fNBinsSpectrum;j++)          
633     {                                             
634         fAccumTotalSpectrum[j] += fAccumSpectr    
635         //in the case of missing photon in spe    
636         //(may happen only at the beginning of    
637         if(fNPhotonsPerBin[j]==0)                 
638         {                                         
639            fTotalSpectrum[j] = 0;                 
640         }                                         
641         else                                      
642         {                                         
643            fTotalSpectrum[j] = fAccumTotalSpec    
644         }                                         
645     }                                             
646                                                   
647     return flagPhotonProduced;                    
648 }                                                 
649                                                   
650 //....oooOO0OOooo........oooOO0OOooo........oo    
651                                                   
652 G4bool G4BaierKatkov::DoRadiation(G4double eto    
653                                   G4double ang    
654                                   G4double ang    
655                                   G4double ste    
656                                   G4ThreeVecto    
657                                   G4bool flagE    
658 {                                                 
659     /**                                           
660     DoRadiation description                       
661                                                   
662     The real trajectory is divided onto parts.    
663     Every part is accumulated until the radiat    
664     i.e. the radiation probability exceeds som    
665     fSinglePhotonRadiationProbabilityLimit.       
666     Typically fSinglePhotonRadiationProbabilit    
667     Then the photon generation as well as its     
668     in SetPhotonProductionParameters()            
669                                                   
670     Finally if radiation took place, this func    
671     (the parameters at the point of radiation     
672     fNewParticleEnergy; fNewParticleAngleX;       
673     fNewParticleAngleY; NewStep; fNewGlobalTim    
674                                                   
675     In order to control if the trajectory part    
676     one needs to divide it into smaller pieces    
677     fNSmallTrajectorySteps elements, typically    
678     radiation probability along the trajectory    
679     If it exceeds the fSinglePhotonRadiationPr    
680     the trajectory part is over and the radiat    
681                                                   
682     In order to calculate the radiation probab    
683     after each small piece of the trajectory.     
684     the previous small pieces for this part of    
685                                                   
686     To speed-up the simulations, the photon an    
687     at the start of the trajectory part.          
688     */                                            
689                                                   
690     //flag if a photon was produced               
691     G4bool flagPhotonProduced = false;            
692                                                   
693     //adding the next trajectory element to th    
694     fParticleAnglesX.push_back(angleX);           
695     fParticleAnglesY.push_back(angleY);           
696     fScatteringAnglesX.push_back(angleScatteri    
697     fScatteringAnglesY.push_back(angleScatteri    
698     fSteps.push_back(step);                       
699     fGlobalTimes.push_back(globalTime);           
700     fParticleCoordinatesXYZ.push_back(coordina    
701                                                   
702     G4double imax = fSteps.size();                
703     if((imax==fImin0+fNSmallTrajectorySteps)||    
704     {                                             
705         //set the angular limits at the start     
706         if(fImin0==0)                             
707         {                                         
708             //radiation within the angle = +-f    
709             G4double radiationAngleLimit=fRadi    
710                                                   
711             SetPhotonSamplingParameters(etotal    
712             *std::min_element(fParticleAnglesX    
713                               fParticleAnglesX    
714             *std::max_element(fParticleAnglesX    
715                               fParticleAnglesX    
716             *std::min_element(fParticleAnglesY    
717                               fParticleAnglesY    
718             *std::max_element(fParticleAnglesY    
719                               fParticleAnglesY    
720                                                   
721             //calculation of angles of photon     
722             //(these angles are integration va    
723             GeneratePhotonSampling();             
724         }                                         
725                                                   
726         //calculate Baier-Katkov integral afte    
727         //small piece of trajectory (fNSmallTr    
728         fTotalRadiationProbability = RadIntegr    
729                                                   
730                                                   
731                                                   
732                                                   
733         //setting the last element of this sma    
734         fImin0 = imax;                            
735         fImax0.push_back(imax*1.);                
736                                                   
737         //if the radiation probability is high    
738         //our trajectory => to simulate the ph    
739         if(fTotalRadiationProbability>fSingleP    
740                 flagEndTrajectory)                
741         {                                         
742             fItrajectories += 1; //count this     
743                                                   
744             flagPhotonProduced = SetPhotonProd    
745                                                   
746             // correction 19.07.2023 fItraject    
747                                                   
748             //reinitialize intermediate integr    
749             //reset radiation integral interna    
750             //reset the trajectory and radiati    
751             ResetRadIntegral();                   
752         }                                         
753     }                                             
754                                                   
755     return flagPhotonProduced;                    
756 }                                                 
757                                                   
758 //....oooOO0OOooo........oooOO0OOooo........oo    
759                                                   
760 void G4BaierKatkov::GeneratePhoton(G4FastStep     
761 {                                                 
762     const G4DynamicParticle theGamma = G4Dynam    
763                                                   
764     //generation of a secondary photon            
765     fastStep.CreateSecondaryTrack(theGamma,fNe    
766 }                                                 
767