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Geant4/processes/electromagnetic/standard/src/G4GoudsmitSaundersonMscModel.cc

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Differences between /processes/electromagnetic/standard/src/G4GoudsmitSaundersonMscModel.cc (Version 11.3.0) and /processes/electromagnetic/standard/src/G4GoudsmitSaundersonMscModel.cc (Version 6.2.p1)


  1 //                                                  1 
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  6 // * the Geant4 Collaboration.  It is provided    
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 11 // * Neither the authors of this software syst    
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 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 //                                                
 27 // -------------------------------------------    
 28 //                                                
 29 // GEANT4 Class implementation file               
 30 //                                                
 31 // File name:     G4GoudsmitSaundersonMscModel    
 32 //                                                
 33 // Author:        Mihaly Novak / (Omrane Kadri    
 34 //                                                
 35 // Creation date: 20.02.2009                      
 36 //                                                
 37 // Modifications:                                 
 38 // 04.03.2009 V.Ivanchenko cleanup and format     
 39 // 12.05.2010 O.Kadri: adding Qn1 and Qn12 as     
 40 // 18.05.2015 M. Novak provide PRELIMINARY ver    
 41 //            This class has been revised and     
 42 //            A new version of Kawrakow-Bielaj    
 43 //            based on the screened Rutherford    
 44 //            electrons/positrons has been int    
 45 //            angular distributions over a 2D     
 46 //            and the CDFs are now stored in a    
 47 //            together with the corresponding     
 48 //            These angular distributions are     
 49 //            G4GoudsmitSaundersonTable class     
 50 //            it was no, single, few or multip    
 51 //            angular deflection (i.e. cos(the    
 52 //            Two screening options are provid    
 53 //             - if fIsUsePWATotalXsecData=TRU    
 54 //               was called before initialisat    
 55 //               determined such that the firs    
 56 //               computed according to the scr    
 57 //               scattering will reproduce the    
 58 //               and first transport mean free    
 59 //             - if fIsUsePWATotalXsecData=FAL    
 60 //               SetOptionPWAScreening(FALSE)     
 61 //               screening parameter value A i    
 62 //               formula (by using material de    
 63 //               precomputed for each material    
 64 //               G4GoudsmitSaundersonTable) [3    
 65 //            Elastic and first trasport mean     
 66 //            The new version is self-consiste    
 67 //            robust and accurate compared to     
 68 //            Spin effects as well as a more a    
 69 //            computations of Lewis moments wi    
 70 // 02.09.2015 M. Novak: first version of new s    
 71 //            fUseSafetyPlus corresponds to Ur    
 72 //            fUseDistanceToBoundary correspon    
 73 //            fUseSafety  corresponds to EGSnr    
 74 //            Range factor can be significantl    
 75 // 23.08.2017 M. Novak: added corrections to a    
 76 //            It can be activated by setting t    
 77 //            before initialization using the     
 78 //            The fMottCorrection member is re    
 79 //            correction (rejection) functions    
 80 //            Goudsmit-Saunderson agnular dist    
 81 //            effects and screening correction    
 82 //            GS angular distributions is: DCS    
 83 //               # DCS_{SR} is the relativisti    
 84 //                 solution of the Klein-Gordo    
 85 //                 scattering of spinless e- o    
 86 //                 note: the default (without     
 87 //                 are based on this DCS_{SR}     
 88 //               # DCS_{R} is the Rutherford D    
 89 //                 screening                      
 90 //               # DCS_{Mott} is the Mott DCS     
 91 //                 Coulomb potential i.e. scat    
 92 //                 point-like unscreened Coulo    
 93 //               # moreover, the screening par    
 94 //                 the DCS_{cor} with this cor    
 95 //                 transport cross sections ob    
 96 //                 (i.e. from elsepa [4])         
 97 //            Unlike the default GS, the Mott-    
 98 //            (different for e- and e+ <= the     
 99 //            (Z and material) dependent.         
100 // 27.10.2017 M. Novak:                           
101 //            - Mott-correction flag is set no    
102 //            - new form of PWA correction to     
103 //            - changed step limit flag conven    
104 //               # fUseSafety corresponds to U    
105 //               # fUseDistanceToBoundary corr    
106 //               # fUseSafetyPlus corresponds     
107 // 02.02.2018 M. Novak: implemented CrossSecti    
108 //                                                
109 // Class description:                             
110 //   Kawrakow-Bielajew Goudsmit-Saunderson MSC    
111 //   for elastic scattering of e-/e+. Option,     
112 //   also available now (SetOptionMottCorrecti    
113 //   algorithm (UseSafety) is available beyond    
114 //   and true to geomerty and geometry to true    
115 //   from the Urban model[5]. The most accurat    
116 //   UseSafetyPlus MSC step limit with Mott-co    
117 //   are expected to be set through the G4EmPa    
118 //    # G4EmParameters::Instance()->SetMscStep    
119 //    # G4EmParameters::Instance()->SetUseMott    
120 //                                                
121 //                                                
122 // References:                                    
123 //   [1] A.F.Bielajew, NIMB 111 (1996) 195-208    
124 //   [2] I.Kawrakow, A.F.Bielajew, NIMB 134(19    
125 //   [3] I.Kawrakow, E.Mainegra-Hing, D.W.O.Ro    
126 //       Report PIRS-701 (2013)                   
127 //   [4] F.Salvat, A.Jablonski, C.J. Powell, C    
128 //   [5] L.Urban, Preprint CERN-OPEN-2006-077     
129 //                                                
130 // -------------------------------------------    
131                                                   
132                                                   
133 #include "G4GoudsmitSaundersonMscModel.hh"        
134                                                   
135 #include "G4GoudsmitSaundersonTable.hh"           
136 #include "G4GSPWACorrections.hh"                  
137                                                   
138 #include "G4PhysicalConstants.hh"                 
139 #include "G4SystemOfUnits.hh"                     
140                                                   
141 #include "G4ParticleChangeForMSC.hh"              
142 #include "G4DynamicParticle.hh"                   
143 #include "G4Electron.hh"                          
144 #include "G4Positron.hh"                          
145                                                   
146 #include "G4LossTableManager.hh"                  
147 #include "G4EmParameters.hh"                      
148 #include "G4Track.hh"                             
149 #include "G4PhysicsTable.hh"                      
150 #include "Randomize.hh"                           
151 #include "G4Log.hh"                               
152 #include "G4Exp.hh"                               
153 #include "G4Pow.hh"                               
154 #include <fstream>                                
155                                                   
156                                                   
157 // set accurate energy loss and dispalcement s    
158 G4bool G4GoudsmitSaundersonMscModel::gIsUseAcc    
159 // set the usual optimization to be always act    
160 G4bool G4GoudsmitSaundersonMscModel::gIsOptimi    
161                                                   
162                                                   
163 G4GoudsmitSaundersonMscModel::G4GoudsmitSaunde    
164   : G4VMscModel(nam) {                            
165   charge                 = 0;                     
166   currentMaterialIndex   = -1;                    
167   //                                              
168   fr                     = 0.1;                   
169   rangeinit              = 1.e+21;                
170   geombig                = 1.e+50*mm;             
171   geomlimit              = geombig;               
172   tgeom                  = geombig;               
173   tlimit                 = 1.e+10*mm;             
174   presafety              = 0.*mm;                 
175   //                                              
176   particle               = nullptr;               
177   theManager             = G4LossTableManager:    
178   firstStep              = true;                  
179   currentKinEnergy       = 0.0;                   
180   currentRange           = 0.0;                   
181   //                                              
182   tlimitminfix2          = 1.*nm;                 
183   tausmall               = 1.e-16;                
184   mass                   = electron_mass_c2;      
185   taulim                 = 1.e-6;                 
186   //                                              
187   currentCouple          = nullptr;               
188   fParticleChange        = nullptr;               
189   //                                              
190   fZeff                  = 1.;                    
191   //                                              
192   par1                   = 0.;                    
193   par2                   = 0.;                    
194   par3                   = 0.;                    
195   //                                              
196   // Moliere screeing parameter will be used a    
197   // appalied to the integrated quantities (sc    
198   // and second moments) derived from the corr    
199   // this PWA correction is ignored if Mott-co    
200   // Mott-correction contains all these correc    
201   fIsUsePWACorrection    = true;                  
202   //                                              
203   fIsUseMottCorrection   = false;                 
204   //                                              
205   fLambda0               = 0.0; // elastic mea    
206   fLambda1               = 0.0; // first trans    
207   fScrA                  = 0.0; // screening p    
208   fG1                    = 0.0; // first trans    
209   //                                              
210   fMCtoScrA              = 1.0;                   
211   fMCtoQ1                = 1.0;                   
212   fMCtoG2PerG1           = 1.0;                   
213   //                                              
214   fTheTrueStepLenght     = 0.;                    
215   fTheTransportDistance  = 0.;                    
216   fTheZPathLenght        = 0.;                    
217   //                                              
218   fTheDisplacementVector.set(0.,0.,0.);           
219   fTheNewDirection.set(0.,0.,1.);                 
220   //                                              
221   fIsEverythingWasDone   = false;                 
222   fIsMultipleSacettring  = false;                 
223   fIsSingleScattering    = false;                 
224   fIsEndedUpOnBoundary   = false;                 
225   fIsNoScatteringInMSC   = false;                 
226   fIsNoDisplace          = false;                 
227   fIsInsideSkin          = false;                 
228   fIsWasOnBoundary       = false;                 
229   fIsFirstRealStep       = false;                 
230   rndmEngineMod          = G4Random::getTheEng    
231   //                                              
232   fGSTable               = nullptr;               
233   fPWACorrection         = nullptr;               
234 }                                                 
235                                                   
236                                                   
237 G4GoudsmitSaundersonMscModel::~G4GoudsmitSaund    
238   if (IsMaster()) {                               
239     if (fGSTable) {                               
240       delete fGSTable;                            
241       fGSTable = nullptr;                         
242     }                                             
243     if (fPWACorrection) {                         
244       delete fPWACorrection;                      
245       fPWACorrection = nullptr;                   
246     }                                             
247   }                                               
248 }                                                 
249                                                   
250                                                   
251 void G4GoudsmitSaundersonMscModel::Initialise(    
252   SetParticle(p);                                 
253   InitialiseParameters(p);                        
254   // -create GoudsmitSaundersonTable and init     
255   //  Mott-correction was required                
256   if (IsMaster()) {                               
257     // get the Mott-correction flag from EmPar    
258     if (G4EmParameters::Instance()->UseMottCor    
259       fIsUseMottCorrection = true;                
260     }                                             
261     // Mott-correction includes other way of P    
262     // when Mott-correction is activated by th    
263     if (fIsUseMottCorrection) {                   
264       fIsUsePWACorrection = false;                
265     }                                             
266     // clear GS-table                             
267     if (fGSTable) {                               
268       delete fGSTable;                            
269       fGSTable = nullptr;                         
270     }                                             
271     // clear PWA corrections table if any         
272     if (fPWACorrection) {                         
273       delete fPWACorrection;                      
274       fPWACorrection = nullptr;                   
275     }                                             
276     // create GS-table                            
277     G4bool isElectron = true;                     
278     if (p->GetPDGCharge()>0.) {                   
279       isElectron = false;                         
280     }                                             
281     fGSTable = new G4GoudsmitSaundersonTable(i    
282     // G4GSTable will be initialised:             
283     // - Screened-Rutherford DCS based GS angu    
284     // - Mott-correction will be initialised i    
285     fGSTable->SetOptionMottCorrection(fIsUseMo    
286     // - set PWA correction (correction to int    
287     fGSTable->SetOptionPWACorrection(fIsUsePWA    
288     // init                                       
289     fGSTable->Initialise(LowEnergyLimit(),High    
290     // create PWA corrections table if it was     
291     if (fIsUsePWACorrection) {                    
292       fPWACorrection = new G4GSPWACorrections(    
293       fPWACorrection->Initialise();               
294     }                                             
295   }                                               
296   fParticleChange = GetParticleChangeForMSC(p)    
297 }                                                 
298                                                   
299                                                   
300 void G4GoudsmitSaundersonMscModel::InitialiseL    
301    fGSTable               = static_cast<G4Goud    
302    fIsUseMottCorrection   = static_cast<G4Goud    
303    fIsUsePWACorrection    = static_cast<G4Goud    
304    fPWACorrection         = static_cast<G4Goud    
305 }                                                 
306                                                   
307                                                   
308 // computes macroscopic first transport cross     
309 G4double G4GoudsmitSaundersonMscModel::CrossSe    
310                                          const    
311                                          G4dou    
312                                          G4dou    
313                                          G4dou    
314   G4double xsecTr1  = 0.; // cross section per    
315   //                                              
316   fLambda0 = 0.0; // elastic mean free path       
317   fLambda1 = 0.0; // first transport mean free    
318   fScrA    = 0.0; // screening parameter          
319   fG1      = 0.0; // first transport coef.        
320   // use Moliere's screening (with Mott-corret    
321   G4double efEnergy = std::max(kineticEnergy,     
322   // total mometum square                         
323   G4double pt2     = efEnergy*(efEnergy+2.0*el    
324   // beta square                                  
325   G4double beta2   = pt2/(pt2+electron_mass_c2    
326   // current material index                       
327   G4int    matindx = (G4int)mat->GetIndex();      
328   // Moliere's b_c                                
329   G4double bc      = fGSTable->GetMoliereBc(ma    
330   // get the Mott-correcton factors if Mott-co    
331   fMCtoScrA       = 1.0;                          
332   fMCtoQ1         = 1.0;                          
333   fMCtoG2PerG1    = 1.0;                          
334   G4double scpCor = 1.0;                          
335   if (fIsUseMottCorrection) {                     
336     fGSTable->GetMottCorrectionFactors(G4Log(e    
337     // ! no scattering power correction since     
338     // scpCor = fGSTable->ComputeScatteringPow    
339   } else if (fIsUsePWACorrection) {               
340     fPWACorrection->GetPWACorrectionFactors(G4    
341     // scpCor = fGSTable->ComputeScatteringPow    
342   }                                               
343   // screening parameter:                         
344   // - if Mott-corretioncorrection: the Screen    
345   //   screening parameter gives back the (els    
346   // - if PWA correction: he Screened-Rutherfo    
347   //   gives back the (elsepa) PWA first trans    
348   fScrA    = fGSTable->GetMoliereXc2(matindx)/    
349   // elastic mean free path in Geant4 internal    
350   // (if Mott-corretion: the corrected screeni    
351   // corrected with the screening parameter co    
352   fLambda0 = beta2*(1.+fScrA)*fMCtoScrA/bc/scp    
353   // first transport coefficient (if Mott-corr    
354   // consistent with the one used during the p    
355   fG1      = 2.0*fScrA*((1.0+fScrA)*G4Log(1.0/    
356   // first transport mean free path               
357   fLambda1 = fLambda0/fG1;                        
358   xsecTr1  = 1./fLambda1;                         
359   return xsecTr1;                                 
360 }                                                 
361                                                   
362                                                   
363 // gives back the first transport mean free pa    
364 G4double                                          
365 G4GoudsmitSaundersonMscModel::GetTransportMean    
366                                                   
367   // kinetic energy is assumed to be in Geant4    
368   G4double efEnergy = kineticEnergy;              
369   //                                              
370   const G4Material*  mat = currentCouple->GetM    
371   //                                              
372   fLambda0 = 0.0; // elastic mean free path       
373   fLambda1 = 0.0; // first transport mean free    
374   fScrA    = 0.0; // screening parameter          
375   fG1      = 0.0; // first transport coef.        
376                                                   
377   // use Moliere's screening (with Mott-corret    
378   if  (efEnergy<10.*CLHEP::eV) efEnergy = 10.*    
379   // total mometum square                         
380   G4double pt2     = efEnergy*(efEnergy+2.0*el    
381   // beta square                                  
382   G4double beta2   = pt2/(pt2+electron_mass_c2    
383   // current material index                       
384   G4int    matindx = (G4int)mat->GetIndex();      
385   // Moliere's b_c                                
386   G4double bc      = fGSTable->GetMoliereBc(ma    
387   // get the Mott-correcton factors if Mott-co    
388   fMCtoScrA       = 1.0;                          
389   fMCtoQ1         = 1.0;                          
390   fMCtoG2PerG1    = 1.0;                          
391   G4double scpCor = 1.0;                          
392   if (fIsUseMottCorrection) {                     
393     fGSTable->GetMottCorrectionFactors(G4Log(e    
394     scpCor = fGSTable->ComputeScatteringPowerC    
395   } else if (fIsUsePWACorrection) {               
396     fPWACorrection->GetPWACorrectionFactors(G4    
397     // scpCor = fGSTable->ComputeScatteringPow    
398   }                                               
399   // screening parameter:                         
400   // - if Mott-corretioncorrection: the Screen    
401   //   screening parameter gives back the (els    
402   // - if PWA correction: he Screened-Rutherfo    
403   //   gives back the (elsepa) PWA first trans    
404   fScrA    = fGSTable->GetMoliereXc2(matindx)/    
405   // elastic mean free path in Geant4 internal    
406   // (if Mott-corretion: the corrected screeni    
407   // corrected with the screening parameter co    
408   fLambda0 = beta2*(1.+fScrA)*fMCtoScrA/bc/scp    
409   // first transport coefficient (if Mott-corr    
410   // consistent with the one used during the p    
411   fG1      = 2.0*fScrA*((1.0+fScrA)*G4Log(1.0/    
412   // first transport mean free path               
413   fLambda1 = fLambda0/fG1;                        
414                                                   
415   return fLambda1;                                
416 }                                                 
417                                                   
418                                                   
419 G4double                                          
420 G4GoudsmitSaundersonMscModel::GetTransportMean    
421                                                   
422   // kinetic energy is assumed to be in Geant4    
423   G4double efEnergy = kineticEnergy;              
424   //                                              
425   const G4Material*  mat = currentCouple->GetM    
426   //                                              
427   G4double lambda0 = 0.0; // elastc mean free     
428   G4double lambda1 = 0.0; // first transport m    
429   G4double scrA    = 0.0; // screening paramet    
430   G4double g1      = 0.0; // first transport m    
431                                                   
432   // use Moliere's screening (with Mott-corret    
433   if  (efEnergy<10.*CLHEP::eV) efEnergy = 10.*    
434   // total mometum square in Geant4 internal e    
435   G4double pt2     = efEnergy*(efEnergy+2.0*el    
436   G4double beta2   = pt2/(pt2+electron_mass_c2    
437   G4int    matindx = (G4int)mat->GetIndex();      
438   G4double bc      = fGSTable->GetMoliereBc(ma    
439   // get the Mott-correcton factors if Mott-co    
440   G4double mctoScrA    = 1.0;                     
441   G4double mctoQ1      = 1.0;                     
442   G4double mctoG2PerG1 = 1.0;                     
443   G4double scpCor      = 1.0;                     
444   if (fIsUseMottCorrection) {                     
445     fGSTable->GetMottCorrectionFactors(G4Log(e    
446     scpCor = fGSTable->ComputeScatteringPowerC    
447   } else if (fIsUsePWACorrection) {               
448     fPWACorrection->GetPWACorrectionFactors(G4    
449     // scpCor = fGSTable->ComputeScatteringPow    
450   }                                               
451   scrA    = fGSTable->GetMoliereXc2(matindx)/(    
452   // total elastic mean free path in Geant4 in    
453   lambda0 = beta2*(1.+scrA)*mctoScrA/bc/scpCor    
454   g1      = 2.0*scrA*((1.0+scrA)*G4Log(1.0/scr    
455   lambda1 = lambda0/g1;                           
456                                                   
457   return lambda1;                                 
458 }                                                 
459                                                   
460                                                   
461 void G4GoudsmitSaundersonMscModel::StartTracki    
462   SetParticle(track->GetDynamicParticle()->Get    
463   firstStep = true;                               
464   tlimit    = tgeom = rangeinit = geombig;        
465   rangeinit = 1.e+21;                             
466 }                                                 
467                                                   
468                                                   
469 G4double G4GoudsmitSaundersonMscModel::Compute    
470                                                   
471   G4double skindepth = 0.;                        
472   //                                              
473   const G4DynamicParticle* dp = track.GetDynam    
474   G4StepPoint* sp             = track.GetStep(    
475   G4StepStatus stepStatus     = sp->GetStepSta    
476   currentCouple               = track.GetMater    
477   SetCurrentCouple(currentCouple);                
478   currentMaterialIndex        = (G4int)current    
479   currentKinEnergy            = dp->GetKinetic    
480   currentRange                = GetRange(parti    
481                                          dp->G    
482   // elastic and first transport mfp, screenin    
483   // (Mott-correction will be used if it was r    
484   fLambda1 = GetTransportMeanFreePath(particle    
485   // Set initial values:                          
486   //  : lengths are initialised to currentMini    
487   //    step length from all other physics        
488   fTheTrueStepLenght    = currentMinimalStep;     
489   fTheTransportDistance = currentMinimalStep;     
490   fTheZPathLenght       = currentMinimalStep;     
491   fTheDisplacementVector.set(0.,0.,0.);           
492   fTheNewDirection.set(0.,0.,1.);                 
493                                                   
494   // Can everything be done in the step limit     
495   fIsEverythingWasDone  = false;                  
496   // Multiple scattering needs to be sample ?     
497   fIsMultipleSacettring = false;                  
498   // Single scattering needs to be sample ?       
499   fIsSingleScattering   = false;                  
500   // Was zero deflection in multiple scatterin    
501   fIsNoScatteringInMSC  = false;                  
502   // Do not care about displacement in MSC sam    
503   // ( used only in the case of gIsOptimizatio    
504   fIsNoDisplace = false;                          
505   // get pre-step point safety                    
506   presafety = sp->GetSafety();                    
507   //                                              
508   fZeff = currentCouple->GetMaterial()->GetIon    
509   // distance will take into account max-fluct    
510   G4double distance = currentRange;               
511   distance *= (1.20-fZeff*(1.62e-2-9.22e-5*fZe    
512   //                                              
513   // Possible optimization : if the distance i    
514   // particle will never leave this volume ->     
515   // as the effect of multiple elastic scatter    
516   // Important : this optimization can cause p    
517   // in a bigger volume since MSC won't be don    
518   // distance < safety so don't use optimized-    
519   if (gIsOptimizationOn && (distance<presafety    
520      // Indicate that we need to do MSC after     
521      fIsMultipleSacettring = true;                
522      fIsNoDisplace = true;                        
523   } else if (steppingAlgorithm==fUseDistanceTo    
524     //Compute geomlimit (and presafety) :         
525     // - geomlimit will be:                       
526     //    == the straight line distance to the    
527     //       longer than that                     
528     //    == a big value [geombig = 1.e50*mm]     
529     //       the straight line distance to the    
530     // - presafety will be updated as well        
531     // So the particle can travell 'gemlimit'     
532     // line!) in its current direction:           
533     //  (1) before reaching a boundary (geomli    
534     //  (2) before reaching its current range     
535     geomlimit = ComputeGeomLimit(track, presaf    
536     // Record that the particle is on a bounda    
537     if ( (stepStatus==fGeomBoundary) || (stepS    
538       fIsWasOnBoundary = true;                    
539     }                                             
540     // Set skin depth = skin x elastic_mean_fr    
541     skindepth     = skin*fLambda0;                
542     // Init the flag that indicates that the p    
543     // distance from a boundary                   
544     fIsInsideSkin = false;                        
545     // Check if we can try Single Scattering b    
546     // distance from/to a boundary OR the curr    
547     // shorter than skindepth. NOTICE: the lat    
548     // because the MSC angular sampling is fin    
549     // faster to try single scattering in case    
550     if ((stepStatus==fGeomBoundary) || (presaf    
551       // check if we are within skindepth dist    
552       if ((stepStatus == fGeomBoundary) || (pr    
553         fIsInsideSkin    = true;                  
554         fIsWasOnBoundary = true;                  
555       }                                           
556       //Try single scattering:                    
557       // - sample distance to next single scat    
558       // - compare to current minimum length      
559       //      == if sslimit is the shorter:       
560       //          - set the step length to ssl    
561       //          - indicate that single scatt    
562       //      == else : nothing to do             
563       //- in both cases, the step length was v    
564       //  true path length are the same           
565       G4double sslimit = -1.*fLambda0*G4Log(G4    
566       // compare to current minimum step lengt    
567       if (sslimit<fTheTrueStepLenght) {           
568         fTheTrueStepLenght  = sslimit;            
569         fIsSingleScattering = true;               
570       }                                           
571       // short step -> true step length equal     
572       fTheZPathLenght       = fTheTrueStepLeng    
573       // Set taht everything is done in step-l    
574       // We will check if we need to perform t    
575       // sampling i.e. if single elastic scatt    
576       fIsEverythingWasDone  = true;               
577     } else {                                      
578       // After checking we know that we cannot    
579       // need to make an MSC step                 
580       // Indicate that we need to make and MSC    
581       // do it now i.e. if presafety>final_tru    
582       // fIsEverythingWasDone = false which in    
583       // MSC after transportation.                
584       fIsMultipleSacettring = true;               
585       // Init the first-real-step falg: it wil    
586       // non-single scattering step in this vo    
587       fIsFirstRealStep      = false;              
588       // If previously the partcile was on bou    
589       // well. When it is not within skin anym    
590       // so we make the first real MSC step wi    
591       if (fIsWasOnBoundary && !fIsInsideSkin)     
592         // reset the 'was on boundary' indicat    
593         fIsWasOnBoundary  = false;                
594         fIsFirstRealStep  = true;                 
595       }                                           
596       // If this is the first-real msc step (t    
597       // skin) or this is the first step with     
598       // primary):                                
599       //   - set the initial range that will b    
600       //     (only in this volume, because aft    
601       //     first-real MSC step we will reset    
602       //  - don't let the partcile to cross th    
603       if (firstStep || fIsFirstRealStep || ran    
604         rangeinit = currentRange;                 
605         // If geomlimit < geombig than the par    
606         // along its initial direction before     
607         // Otherwise we can be sure that the p    
608         // before reaching the boundary along     
609         // geometrical limit appalied. [Howeve    
610         // first or the first-real MSC step. A    
611         // MSC step the direction will change     
612         // But we will try to end up within sk    
613         // the actual value of geomlimit(See l    
614         // boundary).]                            
615         if (geomlimit<geombig) {                  
616           // transfrom straight line distance     
617           // length based on the mean values (    
618           // first-transport mean free path i.    
619           if ((1.-geomlimit/fLambda1)> 0.) {      
620             geomlimit = -fLambda1*G4Log(1.-geo    
621           }                                       
622           // the 2-different case that could l    
623           if (firstStep) {                        
624             tgeom = 2.*geomlimit/facgeom;         
625           } else {                                
626             tgeom = geomlimit/facgeom;            
627           }                                       
628         } else {                                  
629           tgeom = geombig;                        
630         }                                         
631       }                                           
632       // True step length limit from range fac    
633       // range is used that was set at the fir    
634       // in this volume with this particle.       
635       tlimit = facrange*rangeinit;                
636       // Take the minimum of the true step len    
637       // geometrical constraint or range-facto    
638       tlimit = std::min(tlimit,tgeom);            
639       // Step reduction close to boundary: we     
640       // from the boundary ( Notice: in case o    
641       // because geomlimit is the straigth lin    
642       // the currect direction (if geomlimit<g    
643       // change the initial direction. So te p    
644       // before in a different direction. Howe    
645       // path length to this (straight line) l    
646       // transport distance (straight line) wi    
647       // geomlimit-0.999*skindepth after the c    
648       if (geomlimit<geombig) {                    
649         tlimit = std::min(tlimit, geomlimit-0.    
650       }                                           
651       // randomize 1st step or 1st 'normal' st    
652       if (firstStep || fIsFirstRealStep) {        
653         fTheTrueStepLenght = std::min(fTheTrue    
654       } else {                                    
655         fTheTrueStepLenght = std::min(fTheTrue    
656       }                                           
657     }                                             
658   } else if (steppingAlgorithm==fUseSafetyPlus    
659     presafety =  ComputeSafety(sp->GetPosition    
660     geomlimit = presafety;                        
661     // Set skin depth = skin x elastic_mean_fr    
662     skindepth = skin*fLambda0;                    
663     // Check if we can try Single Scattering b    
664     // distance from/to a boundary OR the curr    
665     // shorter than skindepth. NOTICE: the lat    
666     // because the MSC angular sampling is fin    
667     // faster to try single scattering in case    
668     if ((stepStatus==fGeomBoundary) || (presaf    
669       //Try single scattering:                    
670       // - sample distance to next single scat    
671       // - compare to current minimum length      
672       //      == if sslimit is the shorter:       
673       //          - set the step length to ssl    
674       //          - indicate that single scatt    
675       //      == else : nothing to do             
676       //- in both cases, the step length was v    
677       //  true path length are the same           
678       G4double sslimit = -1.*fLambda0*G4Log(G4    
679       // compare to current minimum step lengt    
680       if (sslimit<fTheTrueStepLenght) {           
681         fTheTrueStepLenght  = sslimit;            
682         fIsSingleScattering = true;               
683       }                                           
684       // short step -> true step length equal     
685       fTheZPathLenght       = fTheTrueStepLeng    
686       // Set taht everything is done in step-l    
687       // We will check if we need to perform t    
688       // sampling i.e. if single elastic scatt    
689       fIsEverythingWasDone  = true;               
690     } else {                                      
691       // After checking we know that we cannot    
692       // need to make an MSC step                 
693       // Indicate that we need to make and MSC    
694       fIsMultipleSacettring = true;               
695       fIsEverythingWasDone  = true;               
696       // limit from range factor                  
697       fTheTrueStepLenght    = std::min(fTheTru    
698       // never let the particle go further tha    
699       // if we are here we are out of the skin    
700       if (fTheTrueStepLenght>presafety) {         
701         fTheTrueStepLenght = std::min(fTheTrue    
702       }                                           
703       // make sure that we are still within th    
704       // i.e. true step length is not longer t    
705       // We schould take into account energy l    
706       // step length as well. So let it 0.5 x     
707       fTheTrueStepLenght = std::min(fTheTrueSt    
708     }                                             
709   } else {                                        
710     // This is the default stepping algorithm:    
711     // accurate that corresponds to fUseSafety    
712     // model can handle any short steps so we     
713     //                                            
714     // NO single scattering in case of skin or    
715     // model will be single or even no scatter    
716     // compared to the elastic mean free path.    
717     //                                            
718     // indicate that MSC needs to be done (alw    
719     fIsMultipleSacettring = true;                 
720     if (stepStatus!=fGeomBoundary) {              
721       presafety = ComputeSafety(sp->GetPositio    
722     }                                             
723     // Far from boundary-> in optimized mode d    
724     if ((distance<presafety) && (gIsOptimizati    
725       fIsNoDisplace = true;                       
726     } else {                                      
727       // Urban like                               
728       if (firstStep || (stepStatus==fGeomBound    
729         rangeinit = currentRange;                 
730         fr        = facrange;                     
731 // We don't use this: we won't converge to the    
732 //                    decreasing range-factor.    
733 //              rangeinit = std::max(rangeinit    
734 //              if(fLambda1 > lambdalimit) {      
735 //                fr *= (0.75+0.25*fLambda1/la    
736 //              }                                 
737                                                   
738       }                                           
739       //step limit                                
740       tlimit = std::max(fr*rangeinit, facsafet    
741       // first step randomization                 
742       if (firstStep || stepStatus==fGeomBounda    
743         fTheTrueStepLenght = std::min(fTheTrue    
744       } else {                                    
745         fTheTrueStepLenght = std::min(fTheTrue    
746       }                                           
747     }                                             
748   }                                               
749   //                                              
750   // unset first-step                             
751   firstStep =false;                               
752   // performe single scattering, multiple scat    
753   if (fIsEverythingWasDone) {                     
754     if (fIsSingleScattering) {                    
755       // sample single scattering                 
756       //G4double ekin   = 0.5*(currentKinEnerg    
757       G4double lekin  = G4Log(currentKinEnergy    
758       G4double pt2    = currentKinEnergy*(curr    
759       G4double beta2  = pt2/(pt2+CLHEP::electr    
760       G4double cost   = fGSTable->SingleScatte    
761       // protection                               
762       if (cost<-1.) cost = -1.;                   
763       if (cost> 1.) cost =  1.;                   
764       // compute sint                             
765       G4double dum    = 1.-cost;                  
766       G4double sint   = std::sqrt(dum*(2.-dum)    
767       G4double phi    = CLHEP::twopi*G4Uniform    
768       G4double sinPhi = std::sin(phi);            
769       G4double cosPhi = std::cos(phi);            
770       fTheNewDirection.set(sint*cosPhi,sint*si    
771     } else if (fIsMultipleSacettring) {           
772       // sample multiple scattering               
773       SampleMSC(); // fTheZPathLenght, fTheDis    
774     } // and if single scattering but it was l    
775   } //else { do nothing here but after transpo    
776   //                                              
777   return ConvertTrueToGeom(fTheTrueStepLenght,    
778 }                                                 
779                                                   
780                                                   
781 G4double G4GoudsmitSaundersonMscModel::Compute    
782   // convert true ->geom                          
783   // It is called from the step limitation Com    
784   // !fIsEverythingWasDone but protect:           
785   par1 = -1.;                                     
786   par2 = par3 = 0.;                               
787   // if fIsEverythingWasDone = TRUE  => fTheZP    
788   // so return with the already known value       
789   // Otherwise:                                   
790   if (!fIsEverythingWasDone) {                    
791     // this correction needed to run MSC with     
792     // and makes no harm for a normal run         
793     fTheTrueStepLenght = std::min(fTheTrueStep    
794     //  do the true -> geom transformation        
795     fTheZPathLenght = fTheTrueStepLenght;         
796     // z = t for very small true-path-length      
797     if (fTheTrueStepLenght<tlimitminfix2) {       
798       return fTheZPathLenght;                     
799     }                                             
800     G4double tau = fTheTrueStepLenght/fLambda1    
801     if (tau<=tausmall) {                          
802       fTheZPathLenght = std::min(fTheTrueStepL    
803     } else  if (fTheTrueStepLenght<currentRang    
804       if (tau<taulim) fTheZPathLenght = fTheTr    
805       else            fTheZPathLenght = fLambd    
806     } else if (currentKinEnergy<mass || fTheTr    
807       par1 = 1./currentRange ;     // alpha =1    
808       par2 = 1./(par1*fLambda1) ;  // 1/(alpha    
809       par3 = 1.+par2 ;             // 1+1/        
810       if (fTheTrueStepLenght<currentRange) {      
811         fTheZPathLenght = 1./(par1*par3) * (1.    
812       } else {                                    
813         fTheZPathLenght = 1./(par1*par3);         
814       }                                           
815     } else {                                      
816       G4double rfin    = std::max(currentRange    
817       G4double T1      = GetEnergy(particle,rf    
818       G4double lambda1 = GetTransportMeanFreeP    
819       //                                          
820       par1 = (fLambda1-lambda1)/(fLambda1*fThe    
821       par2 = 1./(par1*fLambda1);                  
822       par3 = 1.+par2 ;                            
823       G4Pow *g4calc = G4Pow::GetInstance();       
824       fTheZPathLenght = 1./(par1*par3) * (1.-g    
825     }                                             
826   }                                               
827   fTheZPathLenght = std::min(fTheZPathLenght,     
828   //                                              
829   return fTheZPathLenght;                         
830 }                                                 
831                                                   
832                                                   
833 G4double G4GoudsmitSaundersonMscModel::Compute    
834   // init                                         
835   fIsEndedUpOnBoundary = false;                   
836   // step defined other than transportation       
837   if (geomStepLength==fTheZPathLenght) {          
838     return fTheTrueStepLenght;                    
839   }                                               
840   // else ::                                      
841   // - set the flag that transportation was th    
842   // - convert geom -> true by using the mean     
843   fIsEndedUpOnBoundary = true; // OR LAST STEP    
844   fTheZPathLenght      = geomStepLength;          
845   // was a short single scattering step           
846   if (fIsEverythingWasDone && !fIsMultipleSace    
847     fTheTrueStepLenght = geomStepLength;          
848     return fTheTrueStepLenght;                    
849   }                                               
850   // t = z for very small step                    
851   if (geomStepLength<tlimitminfix2) {             
852     fTheTrueStepLenght = geomStepLength;          
853   // recalculation                                
854   } else {                                        
855     G4double tlength = geomStepLength;            
856     if (geomStepLength>fLambda1*tausmall) {       
857       if (par1< 0.) {                             
858         tlength = -fLambda1*G4Log(1.-geomStepL    
859       } else {                                    
860         if (par1*par3*geomStepLength<1.) {        
861           G4Pow *g4calc = G4Pow::GetInstance()    
862           tlength = (1.-g4calc->powA( 1.-par1*    
863         } else {                                  
864           tlength = currentRange;                 
865         }                                         
866       }                                           
867       if (tlength<geomStepLength || tlength>fT    
868         tlength = geomStepLength;                 
869       }                                           
870     }                                             
871     fTheTrueStepLenght = tlength;                 
872   }                                               
873   //                                              
874   return fTheTrueStepLenght;                      
875 }                                                 
876                                                   
877 G4ThreeVector&                                    
878 G4GoudsmitSaundersonMscModel::SampleScattering    
879   if (steppingAlgorithm==fUseDistanceToBoundar    
880     // single scattering was and scattering ha    
881     fTheNewDirection.rotateUz(oldDirection);      
882     fParticleChange->ProposeMomentumDirection(    
883     return fTheDisplacementVector;                
884   } else if (steppingAlgorithm==fUseSafetyPlus    
885     if (fIsEndedUpOnBoundary) { // do nothing     
886       return fTheDisplacementVector;              
887     } else if (fIsEverythingWasDone) { // evry    
888       // check single scattering and see if it    
889       if (fIsSingleScattering) {                  
890         fTheNewDirection.rotateUz(oldDirection    
891         fParticleChange->ProposeMomentumDirect    
892         return fTheDisplacementVector;            
893       }                                           
894       // check if multiple scattering happened    
895       if (fIsMultipleSacettring && !fIsNoScatt    
896            fTheNewDirection.rotateUz(oldDirect    
897            fTheDisplacementVector.rotateUz(old    
898            fParticleChange->ProposeMomentumDir    
899       }                                           
900       // The only thing that could happen if w    
901       // is that  single scattering was tried     
902       // So no displacement and no scattering     
903       return fTheDisplacementVector;              
904     }                                             
905     //                                            
906     // The only thing that could still happen     
907     // optimization branch: so sample MSC angl    
908   }                                               
909   //else MSC needs to be done here                
910   SampleMSC();                                    
911   if (!fIsNoScatteringInMSC) {                    
912     fTheNewDirection.rotateUz(oldDirection);      
913     fParticleChange->ProposeMomentumDirection(    
914     if (!fIsNoDisplace) {                         
915       fTheDisplacementVector.rotateUz(oldDirec    
916     }                                             
917   }                                               
918   //                                              
919   return fTheDisplacementVector;                  
920 }                                                 
921                                                   
922                                                   
923 void G4GoudsmitSaundersonMscModel::SampleMSC()    
924   fIsNoScatteringInMSC = false;                   
925   // kinetic energy is assumed to be in Geant4    
926   G4double kineticEnergy = currentKinEnergy;      
927   //                                              
928   // Energy loss correction: 2 version            
929   G4double eloss  = 0.0;                          
930 //  if (fTheTrueStepLenght > currentRange*dtrl    
931   eloss = kineticEnergy - GetEnergy(particle,c    
932 //  } else {                                      
933 //    eloss = fTheTrueStepLenght*GetDEDX(parti    
934 //  }                                             
935                                                   
936   G4double tau  = 0.;//    = kineticEnergy/ele    
937   G4double tau2 = 0.;//   = tau*tau;              
938   G4double eps0 = 0.;//   = eloss/kineticEnerg    
939   G4double epsm = 0.;//   = eloss/kineticEnerg    
940                                                   
941   // - init.                                      
942   G4double efEnergy = kineticEnergy;              
943   G4double efStep   = fTheTrueStepLenght;         
944                                                   
945   G4double kineticEnergy0 = kineticEnergy;        
946   if (gIsUseAccurate) {    // - use accurate e    
947     kineticEnergy  -= 0.5*eloss;  // mean ener    
948     // other parameters for energy loss correc    
949     tau             = kineticEnergy/electron_m    
950     tau2            = tau*tau;                    
951     eps0            = eloss/kineticEnergy0; //    
952     epsm            = eloss/kineticEnergy;  //    
953                                                   
954     efEnergy        = kineticEnergy * (1.-epsm    
955     G4double dum    = 0.166666*(4.+tau*(6.+tau    
956     efStep          = fTheTrueStepLenght*(1.-d    
957   } else {                              // - t    
958     kineticEnergy  -= 0.5*eloss;  // mean ener    
959     efEnergy        = kineticEnergy;              
960     G4double factor = 1./(1.+0.9784671*kinetic    
961     eps0            = eloss/kineticEnergy0;       
962     epsm            = eps0/(1.-0.5*eps0);         
963     G4double temp   = 0.3*(1 -factor*(1.-0.333    
964     efStep          = fTheTrueStepLenght*(1.+t    
965   }                                               
966   //                                              
967   // compute elastic mfp, first transport mfp,    
968   // if it was requested by the user)             
969   fLambda1 = GetTransportMeanFreePath(particle    
970   // s/lambda_el                                  
971   G4double lambdan=0.;                            
972   if (fLambda0>0.0) {                             
973     lambdan=efStep/fLambda0;                      
974   }                                               
975   if (lambdan<=1.0e-12) {                         
976       if (fIsEverythingWasDone) {                 
977         fTheZPathLenght = fTheTrueStepLenght;     
978       }                                           
979     fIsNoScatteringInMSC = true;                  
980     return;                                       
981   }                                               
982   // first moment: 2.* lambdan *scrA*((1.+scrA    
983   G4double Qn1 = lambdan *fG1;                    
984   // sample scattering angles                     
985   // new direction, relative to the orriginal     
986   G4double cosTheta1 = 1.0, sinTheta1 = 0.0, c    
987   G4double cosPhi1   = 1.0, sinPhi1   = 0.0, c    
988   G4double uss       = 0.0, vss       = 0.0, w    
989   G4double x_coord   = 0.0, y_coord   = 0.0, z    
990   G4double u2 = 0.0, v2 = 0.0;                    
991   // if we are above the upper grid limit with    
992   // => izotropic distribution: lambG1_max =7.    
993   if (0.5*Qn1 > 7.0){                             
994     cosTheta1 = 1.-2.*G4UniformRand();            
995     sinTheta1 = std::sqrt((1.-cosTheta1)*(1.+c    
996     cosTheta2 = 1.-2.*G4UniformRand();            
997     sinTheta2 = std::sqrt((1.-cosTheta2)*(1.+c    
998   } else {                                        
999      // sample 2 scattering cost1, sint1, cost    
1000      G4double lekin  = G4Log(efEnergy);          
1001      G4double pt2    = efEnergy*(efEnergy+2.0    
1002      G4double beta2  = pt2/(pt2+CLHEP::electr    
1003      // backup GS angular dtr pointer (kineti    
1004      // if the first was an msc sampling (the    
1005      G4GoudsmitSaundersonTable::GSMSCAngularD    
1006      G4int mcEkinIdx    = -1;                    
1007      G4int mcDeltIdx    = -1;                    
1008      G4double transfPar = 0.;                    
1009      G4bool isMsc = fGSTable->Sampling(0.5*la    
1010                                        curren    
1011                                        true);    
1012      fGSTable->Sampling(0.5*lambdan, 0.5*Qn1,    
1013                         currentMaterialIndex,    
1014      if (cosTheta1+cosTheta2==2.) { // no sca    
1015         if (fIsEverythingWasDone)                
1016            fTheZPathLenght = fTheTrueStepLeng    
1017         fIsNoScatteringInMSC = true;             
1018         return;                                  
1019      }                                           
1020   }                                              
1021   // sample 2 azimuthal angles                   
1022   G4double phi1 = CLHEP::twopi*G4UniformRand(    
1023   sinPhi1 = std::sin(phi1);                      
1024   cosPhi1 = std::cos(phi1);                      
1025   G4double phi2 = CLHEP::twopi*G4UniformRand(    
1026   sinPhi2 = std::sin(phi2);                      
1027   cosPhi2 = std::cos(phi2);                      
1028                                                  
1029   // compute final direction realtive to z-di    
1030   u2  = sinTheta2*cosPhi2;                       
1031   v2  = sinTheta2*sinPhi2;                       
1032   G4double u2p = cosTheta1*u2 + sinTheta1*cos    
1033   uss  = u2p*cosPhi1 - v2*sinPhi1;               
1034   vss  = u2p*sinPhi1 + v2*cosPhi1;               
1035   wss  = cosTheta1*cosTheta2 - sinTheta1*u2;     
1036                                                  
1037   // set new direction (is scattering frame)     
1038   fTheNewDirection.set(uss,vss,wss);             
1039                                                  
1040   // set the fTheZPathLenght if we don't samp    
1041   // we should do everything at the step-limi    
1042   if(fIsNoDisplace && fIsEverythingWasDone)      
1043     fTheZPathLenght = fTheTrueStepLenght;        
1044                                                  
1045   // in optimized-mode if the current-safety     
1046   if(fIsNoDisplace)                              
1047     return;                                      
1048                                                  
1049   ///////////////////////////////////////////    
1050   // Compute final position                      
1051   Qn1 *=  fMCtoQ1;                               
1052   if (gIsUseAccurate) {                          
1053      // correction parameter                     
1054      G4double par =1.;                           
1055      if(Qn1<0.7) par = 1.;                       
1056      else if (Qn1<7.0) par = -0.031376*Qn1+1.    
1057      else par = 0.79;                            
1058                                                  
1059      // Moments with energy loss correction      
1060      // --first the uncorrected (for energy l    
1061      // gamma = G_2/G_1 based on G2 computed     
1062      G4double loga   = G4Log(1.0+1.0/fScrA);     
1063      G4double gamma  = 6.0*fScrA*(1.0 + fScrA    
1064      gamma *= fMCtoG2PerG1;                      
1065      // sample eta from p(eta)=2*eta i.e. P(e    
1066      G4double eta    = std::sqrt(G4UniformRan    
1067      G4double eta1   = 0.5*(1 - eta);  // use    
1068      // 0.5 +sqrt(6)/6 = 0.9082483;              
1069      // 1/(4*sqrt(6))  = 0.1020621;              
1070      // (4-sqrt(6)/(24*sqrt(6))) = 0.02637471    
1071      // delta = 0.9082483-(0.1020621-0.026374    
1072      G4double delta  = 0.9082483-(0.1020621-0    
1073                                                  
1074      // compute alpha1 and alpha2 for energy     
1075      G4double temp1 = 2.0 + tau;                 
1076      G4double temp  = (2.0+tau*temp1)/((tau+1    
1077      //Take logarithmic dependence               
1078      temp = temp - (tau+1.0)/((tau+2.0)*(loga    
1079      temp = temp * epsm;                         
1080      temp1 = 1.0 - temp;                         
1081      delta = delta + 0.40824829*(eps0*(tau+1.    
1082              (loga*(1.0+fScrA)-1.0)*(loga*(1.    
1083      G4double b      = eta*delta;                
1084      G4double c      = eta*(1.0-delta);          
1085                                                  
1086      //Calculate transport direction cosines:    
1087      // ut,vt,wt is the final position divide    
1088      G4double w1v2 = cosTheta1*v2;               
1089      G4double ut   = b*sinTheta1*cosPhi1 + c*    
1090      G4double vt   = b*sinTheta1*sinPhi1 + c*    
1091      G4double wt   = eta1*(1+temp) +       b*    
1092                                                  
1093      // long step correction                     
1094      ut *=par;                                   
1095      vt *=par;                                   
1096      wt *=par;                                   
1097                                                  
1098      // final position relative to the pre-st    
1099      // ut = x_f/s so needs to multiply by s     
1100      x_coord = ut*fTheTrueStepLenght;            
1101      y_coord = vt*fTheTrueStepLenght;            
1102      z_coord = wt*fTheTrueStepLenght;            
1103                                                  
1104      if(fIsEverythingWasDone){                   
1105        // We sample in the step limit so set     
1106        // and lateral displacement (x_coord,y    
1107        //Calculate transport distance            
1108        G4double transportDistance  = std::sqr    
1109        // protection                             
1110        if(transportDistance>fTheTrueStepLengh    
1111           transportDistance = fTheTrueStepLen    
1112        fTheZPathLenght = transportDistance;      
1113      }                                           
1114      // else:: we sample in the DoIt so          
1115      //       the fTheZPathLenght was already    
1116      fTheDisplacementVector.set(x_coord,y_coo    
1117   } else {                                       
1118      // compute zz = <z>/tPathLength             
1119      // s -> true-path-length                    
1120      // z -> geom-path-length:: when PRESTA i    
1121      // r -> lateral displacement = s/2 sin(t    
1122      G4double zz = 0.0;                          
1123      if(fIsEverythingWasDone){                   
1124         // We sample in the step limit so set    
1125         // and lateral displacement (x_coord,    
1126         if(Qn1<0.1) { // use 3-order Taylor a    
1127           zz = 1.0 - Qn1*(0.5 - Qn1*(0.166666    
1128         } else {                                 
1129           zz = (1.-G4Exp(-Qn1))/Qn1;             
1130         }                                        
1131      } else {                                    
1132         // we sample in the DoIt so              
1133         // the fTheZPathLenght was already se    
1134         zz = fTheZPathLenght/fTheTrueStepLeng    
1135      }                                           
1136                                                  
1137      G4double rr = (1.-zz*zz)/(1.-wss*wss); /    
1138      if(rr >= 0.25) rr = 0.25;            //     
1139      G4double rperp = fTheTrueStepLenght*std:    
1140      x_coord  = rperp*uss;                       
1141      y_coord  = rperp*vss;                       
1142      z_coord  = zz*fTheTrueStepLenght;           
1143                                                  
1144      if(fIsEverythingWasDone){                   
1145        G4double transportDistance = std::sqrt    
1146        fTheZPathLenght = transportDistance;      
1147      }                                           
1148                                                  
1149      fTheDisplacementVector.set(x_coord,y_coo    
1150    }                                             
1151 }                                                
1152