Geant4 Cross Reference

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Geant4/parameterisations/channeling/src/G4ChannelingFastSimModel.cc

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Diff markup

Differences between /parameterisations/channeling/src/G4ChannelingFastSimModel.cc (Version 11.3.0) and /parameterisations/channeling/src/G4ChannelingFastSimModel.cc (Version 6.2)


  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 PaternĂ² (modificat    
 28 // On the base of the CRYSTALRAD realization o    
 29 // A. I. Sytov, V. V. Tikhomirov, and L. Bandi    
 30                                                   
 31 /// \file G4ChannelingFastSimModel.cc             
 32 /// \brief Implementation of the G4ChannelingF    
 33 //                                                
 34 //                                                
 35 //                                                
 36 #include "G4ChannelingFastSimModel.hh"            
 37                                                   
 38 #include "Randomize.hh"                           
 39                                                   
 40 #include "G4TransportationManager.hh"             
 41 #include "G4SystemOfUnits.hh"                     
 42                                                   
 43 //....oooOO0OOooo........oooOO0OOooo........oo    
 44                                                   
 45 G4ChannelingFastSimModel::G4ChannelingFastSimM    
 46                                                   
 47 : G4VFastSimulationModel(modelName, envelope)     
 48 {                                                 
 49 }                                                 
 50                                                   
 51 //....oooOO0OOooo........oooOO0OOooo........oo    
 52                                                   
 53 G4ChannelingFastSimModel::G4ChannelingFastSimM    
 54 : G4VFastSimulationModel(modelName)               
 55 {                                                 
 56                                                   
 57 }                                                 
 58                                                   
 59 //....oooOO0OOooo........oooOO0OOooo........oo    
 60                                                   
 61 G4ChannelingFastSimModel::~G4ChannelingFastSim    
 62 {                                                 
 63 }                                                 
 64                                                   
 65 //....oooOO0OOooo........oooOO0OOooo........oo    
 66                                                   
 67 G4bool G4ChannelingFastSimModel::IsApplicable(    
 68 {                                                 
 69   return std::abs(particleType.GetPDGCharge())    
 70 }                                                 
 71                                                   
 72 //....oooOO0OOooo........oooOO0OOooo........oo    
 73                                                   
 74 G4bool G4ChannelingFastSimModel::ModelTrigger(    
 75 {                                                 
 76   //default output                                
 77   G4bool modelTrigger = false;                    
 78                                                   
 79   G4int particleDefinitionID =                    
 80           fastTrack.GetPrimaryTrack()->GetPart    
 81   //kinetic energy                                
 82   G4double ekinetic = fastTrack.GetPrimaryTrac    
 83                                                   
 84   //energy cut, at the beginning, to not check    
 85   if(ekinetic > GetLowKineticEnergyLimit(parti    
 86   {                                               
 87       //current logical volume                    
 88       G4LogicalVolume* crystallogic = fastTrac    
 89       fCrystalData->SetGeometryParameters(crys    
 90                                                   
 91       G4ThreeVector momentumDirection = fastTr    
 92       // the particle angle vs crystal plane o    
 93       G4double angle = std::atan(momentumDirec    
 94       //recalculate angle into the lattice ref    
 95       angle = fCrystalData->                      
 96               AngleXFromBoxToLattice(angle,       
 97                                      (fCrystal    
 98                                           fast    
 99       if (fCrystalData->GetModel()==2)            
100       {                                           
101           angle = std::sqrt(angle*angle+          
102                             std::pow(std::atan    
103                                                   
104       }                                           
105                                                   
106       //particle mass                             
107       G4double mass = fastTrack.GetPrimaryTrac    
108       //particle total energy                     
109       G4double etotal = mass + ekinetic;          
110       //particle charge                           
111       G4double charge = fastTrack.GetPrimaryTr    
112                         GetParticleDefinition(    
113                                                   
114       //Particle position                         
115       G4ThreeVector xyz0 = fastTrack.GetPrimar    
116       //Step estimate                             
117       G4double dz0 = fCrystalData->GetMaxSimul    
118       xyz0 += 2*dz0*momentumDirection;//overes    
119                                       //in cha    
120                                                   
121       //Applies the parameterisation not at th    
122       //above low energy limit and below angul    
123                                                   
124       modelTrigger = (crystallogic->GetSolid()    
125                       Inside(xyz0)==kInside) &    
126                       momentumDirection.z()>0.    
127                       std::abs(angle) <           
128                       std::max(                   
129                           GetLindhardAngleNumb    
130                           fCrystalData->GetLin    
131                                                   
132                                                   
133                           GetHighAngleLimit(pa    
134   }                                               
135                                                   
136   return modelTrigger;                            
137 }                                                 
138                                                   
139 //....oooOO0OOooo........oooOO0OOooo........oo    
140                                                   
141 void G4ChannelingFastSimModel::DoIt(const G4Fa    
142                      G4FastStep& fastStep)        
143 {                                                 
144   G4double etotal;//particle total energy         
145   G4double etotalPreStep;//etotal at the previ    
146   G4double etotalToSetParticleProperties;//eto    
147                                          //Set    
148   G4double ekinetic = 0;//kinetic energy          
149   G4double eDeposited = 0.;//deposited energy     
150   G4double elossAccum = 0;// accumulate local     
151   G4double mass;  //particle mass                 
152   G4double charge;//particle charge               
153   G4double tGlobal; //global time                 
154   G4double tGlobalPreStep; //global time at th    
155   G4ThreeVector xyz0;// the coordinates in the    
156   G4ThreeVector xyz0PreStep;// xyz at the prev    
157   G4ThreeVector xyz;// the coordinates in the     
158                     //a channel (elementary pe    
159   G4double x,y,z;   // the coordinates in the     
160                     //a channel (elementary pe    
161   G4double tx0,ty0; // the angles in the local    
162   G4double tx,ty;   // the angles in the co-ro    
163                     //a channel (elementary pe    
164   G4double txPreStep,tyPreStep;// tx,ty at the    
165   G4ThreeVector momentumDirection;                
166   G4ThreeVector scatteringAnglesAndEnergyLoss;    
167   G4double lindhardAngleNumberHighLimit0; //cu    
168                                           //[L    
169   G4double highAngleLimit0; //current absolute    
170                                                   
171   //coordinates in Runge-Kutta calculations       
172   G4double x1=0.,x2=0.,x3=0.,x4=0.,y1=0.,y2=0.    
173   //angles in Runge-Kutta calculations            
174   G4double tx1=0.,tx2=0.,tx3=0.,tx4=0.,ty1=0.,    
175   //variables in Runge-Kutta calculations         
176   G4double kvx1=0.,kvx2=0.,kvx3=0.,kvx4=0.,kvy    
177   //simulation step along z (internal step of     
178   G4double dz,dzd3,dzd8;//dzd3 = dz/3; dzd8 =     
179   //simulation step along the momentum directi    
180   G4double momentumDirectionStep;                 
181   //effective simulation step (taking into acc    
182   G4double effectiveStep;                         
183                                                   
184   // flag, if Inside(xyz0) switches to kInside    
185   G4bool inside = false;                          
186                                                   
187   G4LogicalVolume* crystallogic = fastTrack.Ge    
188   fCrystalData->SetGeometryParameters(crystall    
189                                                   
190   //set the max number of secondaries (photons    
191   if (fRad)                                       
192   {                                               
193       fastStep.SetNumberOfSecondaryTracks(fMax    
194       //reseting the BaierKatkov integral to s    
195       fBaierKatkov->ResetRadIntegral();//to av    
196   }                                               
197                                                   
198   mass = fastTrack.GetPrimaryTrack()->GetParti    
199   etotal = mass + fastTrack.GetPrimaryTrack()-    
200   charge = fastTrack.GetPrimaryTrack()->GetPar    
201                                                   
202   G4String particleName =                         
203       fastTrack.GetPrimaryTrack()->GetParticle    
204                                                   
205   lindhardAngleNumberHighLimit0 =                 
206       GetLindhardAngleNumberHighLimit(fastTrac    
207                                       GetParti    
208   highAngleLimit0 = GetHighAngleLimit(fastTrac    
209                                       GetParti    
210                                                   
211   //set fCrystalData parameters depending on t    
212   fCrystalData->SetParticleProperties(etotal,     
213                                                   
214   //global time                                   
215   tGlobal = fastTrack.GetPrimaryTrack()->GetGl    
216                                                   
217   //coordinates in the co-rotating reference s    
218   xyz0= fastTrack.GetPrimaryTrackLocalPosition    
219   xyz = fCrystalData->CoordinatesFromBoxToLatt    
220   x=xyz.x();                                      
221   y=xyz.y();                                      
222   z=xyz.z();                                      
223                                                   
224   momentumDirection=fastTrack.GetPrimaryTrackL    
225   //angle in the co-rotating reference system     
226   //(!!! ONLY FORWARD DIRECTION, momentumDirec    
227   //valid for high energies defined by the sta    
228   tx0 = std::atan(momentumDirection.x()/moment    
229   ty0 = std::atan(momentumDirection.y()/moment    
230                                                   
231   //angles in the co-rotating reference system    
232   tx = fCrystalData->AngleXFromBoxToLattice(tx    
233   ty = ty0;                                       
234                                                   
235   etotalToSetParticleProperties = etotal*0.999    
236   G4bool inCrystal=true;//flag necessary to es    
237   //do calculations until the particle is insi    
238   do                                              
239   {                                               
240       //remember the global time before the ne    
241       tGlobalPreStep=tGlobal;                     
242       //remember the coordinates before the ne    
243       xyz0PreStep = xyz0;                         
244       //remember the angles and the total ener    
245       txPreStep = tx;                             
246       tyPreStep = ty;                             
247       etotalPreStep = etotal;                     
248                                                   
249       dz = fCrystalData->GetSimulationStep(tx,    
250       dzd3=dz/3;                                  
251       dzd8=dz/8;                                  
252                                                   
253       //trajectory calculation:                   
254       //Runge-Cutt "3/8"                          
255       //fCrystalData->GetCurv(z)*fCrystalData-    
256       //the radius on x; GetCurv gets 1/R for     
257                                                   
258       //first step                                
259       kvx1=fCrystalData->Ex(x,y);                 
260       x1=x+tx*dzd3;                               
261       tx1=tx+(kvx1-fCrystalData->GetCurv(z)*fC    
262       if (fCrystalData->GetModel()==2)            
263       {                                           
264          kvy1=fCrystalData->Ey(x,y);              
265          y1=y+ty*dzd3;                            
266          ty1=ty+kvy1*dzd3;                        
267       }                                           
268                                                   
269       //second step                               
270       kvx2=fCrystalData->Ex(x1,y1);               
271       x2=x-tx*dzd3+tx1*dz;                        
272       tx2=tx-(kvx1-fCrystalData->GetCurv(z)*fC    
273               (kvx2-fCrystalData->GetCurv(z)*f    
274       if (fCrystalData->GetModel()==2)            
275       {                                           
276          kvy2=fCrystalData->Ey(x1,y1);            
277          y2=y-ty*dzd3+ty1*dz;                     
278          ty2=ty-kvy1*dzd3+kvy2*dz;                
279       }                                           
280                                                   
281       //third step                                
282       kvx3=fCrystalData->Ex(x2,y2);               
283       x3=x+(tx-tx1+tx2)*dz;                       
284       tx3=tx+(kvx1-kvx2+kvx3-fCrystalData->Get    
285       if (fCrystalData->GetModel()==2)            
286       {                                           
287          kvy3=fCrystalData->Ey(x2,y2);            
288          y3=y+(ty-ty1+ty2)*dz;                    
289          ty3=ty+(kvy1-kvy2+kvy3)*dz;              
290       }                                           
291                                                   
292       //fourth step                               
293       kvx4=fCrystalData->Ex(x3,y3);               
294       x4=x+(tx+3.*tx1+3.*tx2+tx3)*dzd8;           
295       tx4=tx+(kvx1+3.*kvx2+3.*kvx3+kvx4)*dzd8-    
296               fCrystalData->GetCurv(z)*fCrysta    
297       if (fCrystalData->GetModel()==2)            
298       {                                           
299           kvy4=fCrystalData->Ey(x3,y3);           
300           y4=y+(ty+3.*ty1+3.*ty2+ty3)*dzd8;       
301           ty4=ty+(kvy1+3.*kvy2+3.*kvy3+kvy4)*d    
302       }                                           
303       else                                        
304       {                                           
305           y4 =y+ty*dz;                            
306           ty4=ty;                                 
307       }                                           
308                                                   
309       x=x4;                                       
310       tx=tx4;                                     
311       y=y4;                                       
312       ty=ty4;                                     
313                                                   
314       z+=dz*fCrystalData->GetCorrectionZ();//m    
315                                           //("    
316                                                   
317       xyz = fCrystalData->ChannelChange(x,y,z)    
318       x=xyz.x();                                  
319       y=xyz.y();                                  
320       z=xyz.z();                                  
321                                                   
322       //the coordinates in the local reference    
323       //this vector will be used in the cycle     
324       //in the radiation model (if activated)     
325       xyz0=fCrystalData->CoordinatesFromLattic    
326                                                   
327       momentumDirectionStep=                      
328               dz*std::sqrt(1+std::pow(std::tan    
329       tGlobal+=momentumDirectionStep/(fCrystal    
330                                                   
331       //default scattering and energy loss 0      
332       scatteringAnglesAndEnergyLoss = G4ThreeV    
333                                                   
334       //calculate separately for each element     
335       for (G4int i = 0; i < fCrystalData->GetN    
336       {                                           
337           //effective step taking into account    
338           effectiveStep = momentumDirectionSte    
339           //Coulomb scattering on screened ato    
340           scatteringAnglesAndEnergyLoss += fCr    
341                          CoulombAtomicScatteri    
342                                                   
343           //Amorphous part of ionization energ    
344           elossAccum += fCrystalData->Ionizati    
345       }                                           
346       //electron scattering and coherent part     
347       scatteringAnglesAndEnergyLoss += fCrysta    
348                                                   
349                                                   
350                                                   
351       tx += scatteringAnglesAndEnergyLoss.x();    
352       ty += scatteringAnglesAndEnergyLoss.y();    
353       elossAccum += scatteringAnglesAndEnergyL    
354                                                   
355       // recalculate the energy depended param    
356       //(only if the energy decreased enough,     
357       if (etotalToSetParticleProperties>etotal    
358       {                                           
359           fCrystalData->SetParticleProperties(    
360           etotalToSetParticleProperties = etot    
361       }                                           
362                                                   
363       //chain of conditions to escape the cycl    
364       // if Inside(xyz0)==kInside has been alr    
365       //(a particle has been inside the crysta    
366       if (inside)                                 
367       {                                           
368           // if low energy                        
369          if (etotal-mass<=GetLowKineticEnergyL    
370                                                   
371                                                   
372              {inCrystal = false;}//escape the     
373          //check if the angle w.r.t. the axes     
374          //return to standard Geant4:             
375          else if (fCrystalData->GetModel()==1)    
376          {                                        
377              //if the angle w.r.t. the planes     
378              if (std::abs(tx) >=                  
379                  std::max(lindhardAngleNumberH    
380                               fCrystalData->Ge    
381                           highAngleLimit0))       
382                 {inCrystal = false;}//escape t    
383          }                                        
384          else if (fCrystalData->GetModel()==2)    
385          {                                        
386              //if the angle w.r.t. the axes is    
387              if (std::sqrt(tx*tx+ty*ty) >=        
388                  std::max(lindhardAngleNumberH    
389                               fCrystalData->Ge    
390                           highAngleLimit0))       
391                 {inCrystal = false;}//escape t    
392          }                                        
393                                                   
394            //radiation production & radiation     
395            //works only if the radiation model    
396            if (fRad)                              
397            {                                      
398                //back to the local reference s    
399                tx0 = fCrystalData->AngleXFromL    
400                ty0 = ty;                          
401                //xyz0 was calculated above        
402                                                   
403                //running the radiation model a    
404                if(fBaierKatkov->DoRadiation(et    
405                                            tx0    
406                                            sca    
407                                            sca    
408                                            mom    
409                                            cry    
410                                            Get    
411                                            Ins    
412                // also it was checked if the p    
413                // calculate the radiation inte    
414                {                                  
415                    //a photon has been emitted    
416                    //shift the particle back i    
417                    etotal = fBaierKatkov->GetP    
418                    tx0 = fBaierKatkov->GetPart    
419                    ty0 = fBaierKatkov->GetPart    
420                    tGlobal = fBaierKatkov->Get    
421                    xyz0 = fBaierKatkov->GetPar    
422                                                   
423                    //add secondary photon         
424                    fBaierKatkov->GeneratePhoto    
425                                                   
426                    //particle energy was chang    
427                    fCrystalData->SetParticlePr    
428                                                   
429                    //coordinates in the co-rot    
430                    xyz = fCrystalData->Coordin    
431                    x=xyz.x();                     
432                    y=xyz.y();                     
433                    z=xyz.z();                     
434                                                   
435                    //angles in the co-rotating    
436                    tx = fCrystalData->AngleXFr    
437                    ty = ty0;                      
438                }                                  
439            }                                      
440            else                                   
441            {                                      
442                //we calculate deposited energy    
443                //of radiation otherwise we do     
444                etotal -= elossAccum;              
445                eDeposited += elossAccum;          
446                elossAccum=0;                      
447                ekinetic = etotal-mass;            
448                if(ekinetic<1*keV)                 
449                {                                  
450                    G4cout << "Warning in G4Cha    
451                    ekinetic << "<" << 1*keV <<    
452                    eDeposited-=(1*keV-ekinetic    
453                    ekinetic = 1*keV;              
454                    G4cout << "Setting deposite    
455                    eDeposited << " & ekinetic=    
456                    etotal = mass+ekinetic;        
457                }                                  
458            }                                      
459                                                   
460            //precise check if the particle is     
461            if (crystallogic->GetSolid()->         
462                    Inside(xyz0)!=kInside)         
463            {                                      
464                //one step back to remain insid    
465                //after the escape of the volum    
466                tGlobal = tGlobalPreStep;          
467                xyz0 = xyz0PreStep;                
468                tx = txPreStep;                    
469                ty = tyPreStep;                    
470                etotal = etotalPreStep;            
471                z-=dz*fCrystalData->GetCorrecti    
472                // change the flag => this part    
473                // the model before escape this    
474                                                   
475                inCrystal = false; //escape the    
476            }                                      
477       }                                           
478       else                                        
479       {                                           
480           // if Inside(xyz0)==kInside we can e    
481           if (crystallogic->GetSolid()->          
482                            Inside(xyz0)==kInsi    
483                  {inside = true;}                 
484           // a very rare case, if a particle r    
485           // on the boundary and escapes the c    
486           else if (crystallogic->GetSolid()->     
487                            Inside(xyz0)==kOuts    
488                  {inCrystal = false;}//escape     
489       }                                           
490   }                                               
491   while (inCrystal);                              
492                                                   
493   //the angles in the local reference system o    
494   tx0 = fCrystalData->AngleXFromLatticeToBox(t    
495   ty0 = ty;                                       
496                                                   
497   //set global time                               
498   fastStep.ProposePrimaryTrackFinalTime(tGloba    
499   //set final position                            
500   fastStep.ProposePrimaryTrackFinalPosition(xy    
501                                                   
502   //set deposited energy (due to ionization)      
503   etotal -= elossAccum;                           
504   eDeposited += elossAccum;                       
505   ekinetic = etotal-mass;                         
506   if(ekinetic<1*keV)                              
507   {                                               
508       G4cout << "Warning in G4ChannelingFastSi    
509       ekinetic << "<" << 1*keV << " !" << G4en    
510       eDeposited-=(1*keV-ekinetic);               
511       ekinetic = 1*keV;                           
512       G4cout << "Setting deposited energy=" <<    
513       eDeposited << " & ekinetic=" << ekinetic    
514   }                                               
515   fastStep.ProposeTotalEnergyDeposited(eDeposi    
516   //set final kinetic energy                      
517   fastStep.ProposePrimaryTrackFinalKineticEner    
518                                                   
519                                                   
520   //set final momentum direction                  
521   G4double momentumDirectionZ =                   
522           1./std::sqrt(1.+std::pow(std::tan(tx    
523   fastStep.ProposePrimaryTrackFinalMomentumDir    
524               G4ThreeVector(momentumDirectionZ    
525                             momentumDirectionZ    
526                             momentumDirectionZ    
527 }                                                 
528                                                   
529 //....oooOO0OOooo........oooOO0OOooo........oo    
530                                                   
531 void G4ChannelingFastSimModel::Input(const G4M    
532                                      const G4S    
533                                      const G4S    
534 {                                                 
535    //initializing the class with containing al    
536    //the crystal material and crystal lattice     
537    //Channeling scattering and ionization proc    
538    fCrystalData = new G4ChannelingFastSimCryst    
539    //setting all the crystal material and latt    
540    fCrystalData->SetMaterialProperties(crystal    
541                                                   
542    //setting default low energy cuts for kinet    
543    SetLowKineticEnergyLimit(1*GeV,"proton");      
544    SetLowKineticEnergyLimit(1*GeV,"anti_proton    
545    SetLowKineticEnergyLimit(200*MeV,"e-");        
546    SetLowKineticEnergyLimit(200*MeV,"e+");        
547                                                   
548    //set the model high limit of the angle exp    
549    SetLindhardAngleNumberHighLimit(100.,"proto    
550    SetLindhardAngleNumberHighLimit(100.,"anti_    
551    SetLindhardAngleNumberHighLimit(100.,"e-");    
552    SetLindhardAngleNumberHighLimit(100.,"e+");    
553 }                                                 
554                                                   
555 //....oooOO0OOooo........oooOO0OOooo........oo    
556                                                   
557 void G4ChannelingFastSimModel::RadiationModelA    
558 {                                                 
559     fRad = true;                                  
560     //activate the Baier-Katkov radiation mode    
561     fBaierKatkov = new G4BaierKatkov();           
562 }                                                 
563                                                   
564 //....oooOO0OOooo........oooOO0OOooo........oo    
565