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Geant4/processes/electromagnetic/lowenergy/src/G4PenelopeRayleighModel.cc

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Differences between /processes/electromagnetic/lowenergy/src/G4PenelopeRayleighModel.cc (Version 11.3.0) and /processes/electromagnetic/lowenergy/src/G4PenelopeRayleighModel.cc (Version 8.1.p1)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 //                                                
 27 // Author: Luciano Pandola                        
 28 //                                                
 29 // History:                                       
 30 // --------                                       
 31 // 03 Dec 2009   L Pandola    First implementa    
 32 // 25 May 2011   L.Pandola    Renamed (make v2    
 33 // 19 Sep 2013   L.Pandola    Migration to MT     
 34 //                                                
 35                                                   
 36 #include "G4PenelopeRayleighModel.hh"             
 37 #include "G4PhysicalConstants.hh"                 
 38 #include "G4SystemOfUnits.hh"                     
 39 #include "G4PenelopeSamplingData.hh"              
 40 #include "G4ParticleDefinition.hh"                
 41 #include "G4MaterialCutsCouple.hh"                
 42 #include "G4ProductionCutsTable.hh"               
 43 #include "G4DynamicParticle.hh"                   
 44 #include "G4PhysicsTable.hh"                      
 45 #include "G4ElementTable.hh"                      
 46 #include "G4Element.hh"                           
 47 #include "G4PhysicsFreeVector.hh"                 
 48 #include "G4AutoLock.hh"                          
 49 #include "G4Exp.hh"                               
 50                                                   
 51 //....oooOO0OOooo........oooOO0OOooo........oo    
 52                                                   
 53 const G4int G4PenelopeRayleighModel::fMaxZ;       
 54 G4PhysicsFreeVector* G4PenelopeRayleighModel::    
 55 G4PhysicsFreeVector* G4PenelopeRayleighModel::    
 56                                                   
 57 //....oooOO0OOooo........oooOO0OOooo........oo    
 58                                                   
 59 G4PenelopeRayleighModel::G4PenelopeRayleighMod    
 60              const G4String& nam)                 
 61   :G4VEmModel(nam),fParticleChange(nullptr),fP    
 62    fLogFormFactorTable(nullptr),fPMaxTable(nul    
 63    fIsInitialised(false),fLocalTable(false)       
 64 {                                                 
 65   fIntrinsicLowEnergyLimit = 100.0*eV;            
 66   fIntrinsicHighEnergyLimit = 100.0*GeV;          
 67   //  SetLowEnergyLimit(fIntrinsicLowEnergyLim    
 68   SetHighEnergyLimit(fIntrinsicHighEnergyLimit    
 69                                                   
 70   if (part)                                       
 71     SetParticle(part);                            
 72                                                   
 73   //                                              
 74   fVerboseLevel= 0;                               
 75   // Verbosity scale:                             
 76   // 0 = nothing                                  
 77   // 1 = warning for energy non-conservation      
 78   // 2 = details of energy budget                 
 79   // 3 = calculation of cross sections, file o    
 80   // 4 = entering in methods                      
 81                                                   
 82   //build the energy grid. It is the same for     
 83   G4double logenergy = G4Log(fIntrinsicLowEner    
 84   G4double logmaxenergy = G4Log(1.5*fIntrinsic    
 85   //finer grid below 160 keV                      
 86   G4double logtransitionenergy = G4Log(160*keV    
 87   G4double logfactor1 = G4Log(10.)/250.;          
 88   G4double logfactor2 = logfactor1*10;            
 89   fLogEnergyGridPMax.push_back(logenergy);        
 90   do{                                             
 91     if (logenergy < logtransitionenergy)          
 92       logenergy += logfactor1;                    
 93     else                                          
 94       logenergy += logfactor2;                    
 95     fLogEnergyGridPMax.push_back(logenergy);      
 96   }while (logenergy < logmaxenergy);              
 97 }                                                 
 98                                                   
 99 //....oooOO0OOooo........oooOO0OOooo........oo    
100                                                   
101 G4PenelopeRayleighModel::~G4PenelopeRayleighMo    
102 {                                                 
103   if (IsMaster() || fLocalTable)                  
104     {                                             
105                                                   
106       for(G4int i=0; i<=fMaxZ; ++i)               
107   {                                               
108     if(fLogAtomicCrossSection[i])                 
109       {                                           
110         delete fLogAtomicCrossSection[i];         
111         fLogAtomicCrossSection[i] = nullptr;      
112       }                                           
113     if(fAtomicFormFactor[i])                      
114       {                                           
115         delete fAtomicFormFactor[i];              
116         fAtomicFormFactor[i] = nullptr;           
117       }                                           
118   }                                               
119       ClearTables();                              
120     }                                             
121 }                                                 
122                                                   
123 //....oooOO0OOooo........oooOO0OOooo........oo    
124 void G4PenelopeRayleighModel::ClearTables()       
125 {                                                 
126    if (fLogFormFactorTable)                       
127      {                                            
128        for (auto& item : (*fLogFormFactorTable    
129    if (item.second) delete item.second;           
130        delete fLogFormFactorTable;                
131        fLogFormFactorTable = nullptr; //zero e    
132      }                                            
133    if (fPMaxTable)                                
134      {                                            
135        for (auto& item : (*fPMaxTable))           
136    if (item.second) delete item.second;           
137        delete fPMaxTable;                         
138        fPMaxTable = nullptr; //zero explicitly    
139      }                                            
140    if (fSamplingTable)                            
141      {                                            
142        for (auto& item : (*fSamplingTable))       
143    if (item.second) delete item.second;           
144        delete fSamplingTable;                     
145        fSamplingTable = nullptr; //zero explic    
146      }                                            
147    return;                                        
148 }                                                 
149                                                   
150 //....oooOO0OOooo........oooOO0OOooo........oo    
151                                                   
152 void G4PenelopeRayleighModel::Initialise(const    
153            const G4DataVector& )                  
154 {                                                 
155   if (fVerboseLevel > 3)                          
156     G4cout << "Calling G4PenelopeRayleighModel    
157                                                   
158   SetParticle(part);                              
159                                                   
160   //Only the master model creates/fills/destro    
161   if (IsMaster() && part == fParticle)            
162     {                                             
163       //clear tables depending on materials, n    
164       ClearTables();                              
165                                                   
166       if (fVerboseLevel > 3)                      
167   G4cout << "Calling G4PenelopeRayleighModel::    
168                                                   
169       //create new tables                         
170       if (!fLogFormFactorTable)                   
171   fLogFormFactorTable = new std::map<const G4M    
172       if (!fPMaxTable)                            
173   fPMaxTable = new std::map<const G4Material*,    
174       if (!fSamplingTable)                        
175   fSamplingTable = new std::map<const G4Materi    
176                                                   
177       G4ProductionCutsTable* theCoupleTable =     
178   G4ProductionCutsTable::GetProductionCutsTabl    
179                                                   
180       for (G4int i=0;i<(G4int)theCoupleTable->    
181   {                                               
182     const G4Material* material =                  
183       theCoupleTable->GetMaterialCutsCouple(i)    
184     const G4ElementVector* theElementVector =     
185                                                   
186     for (std::size_t j=0;j<material->GetNumber    
187       {                                           
188         G4int iZ = theElementVector->at(j)->Ge    
189         //read data files only in the master      
190         if (!fLogAtomicCrossSection[iZ])          
191     ReadDataFile(iZ);                             
192       }                                           
193                                                   
194     //1) If the table has not been built for t    
195     if (!fLogFormFactorTable->count(material))    
196       BuildFormFactorTable(material);             
197                                                   
198     //2) retrieve or build the sampling table     
199     if (!(fSamplingTable->count(material)))       
200       InitializeSamplingAlgorithm(material);      
201                                                   
202     //3) retrieve or build the pMax data          
203     if (!fPMaxTable->count(material))             
204       GetPMaxTable(material);                     
205   }                                               
206                                                   
207       if (fVerboseLevel > 1) {                    
208   G4cout << "Penelope Rayleigh model v2008 is     
209          << "Energy range: "                      
210          << LowEnergyLimit() / keV << " keV -     
211          << HighEnergyLimit() / GeV << " GeV"     
212          << G4endl;                               
213       }                                           
214     }                                             
215                                                   
216   if(fIsInitialised) return;                      
217   fParticleChange = GetParticleChangeForGamma(    
218   fIsInitialised = true;                          
219 }                                                 
220                                                   
221 //....oooOO0OOooo........oooOO0OOooo........oo    
222                                                   
223 void G4PenelopeRayleighModel::InitialiseLocal(    
224                  G4VEmModel *masterModel)         
225 {                                                 
226   if (fVerboseLevel > 3)                          
227     G4cout << "Calling  G4PenelopeRayleighMode    
228   //                                              
229   //Check that particle matches: one might hav    
230   //for e+ and e-).                               
231   //                                              
232   if (part == fParticle)                          
233     {                                             
234       //Get the const table pointers from the     
235       const G4PenelopeRayleighModel* theModel     
236   static_cast<G4PenelopeRayleighModel*> (maste    
237                                                   
238       //Copy pointers to the data tables          
239       for(G4int i=0; i<=fMaxZ; ++i)               
240   {                                               
241     fLogAtomicCrossSection[i] = theModel->fLog    
242     fAtomicFormFactor[i] = theModel->fAtomicFo    
243   }                                               
244       fLogFormFactorTable = theModel->fLogForm    
245       fPMaxTable = theModel->fPMaxTable;          
246       fSamplingTable = theModel->fSamplingTabl    
247                                                   
248       //copy the G4DataVector with the grid       
249       fLogQSquareGrid = theModel->fLogQSquareG    
250                                                   
251       //Same verbosity for all workers, as the    
252       fVerboseLevel = theModel->fVerboseLevel;    
253     }                                             
254                                                   
255   return;                                         
256 }                                                 
257                                                   
258                                                   
259 //....oooOO0OOooo........oooOO0OOooo........oo    
260 namespace { G4Mutex  PenelopeRayleighModelMute    
261 G4double G4PenelopeRayleighModel::ComputeCross    
262                    G4double energy,               
263                    G4double Z,                    
264                    G4double,                      
265                    G4double,                      
266                    G4double)                      
267 {                                                 
268   // Cross section of Rayleigh scattering in P    
269   // tabulation, Cuellen et al. (1997), with n    
270   // et al. J. Phys. Chem. Ref. Data 4 (1975)     
271                                                   
272    if (fVerboseLevel > 3)                         
273     G4cout << "Calling CrossSectionPerAtom() o    
274                                                   
275    G4int iZ = G4int(Z);                           
276                                                   
277    if (!fLogAtomicCrossSection[iZ])               
278      {                                            
279        //If we are here, it means that Initial    
280        //not filled up. This can happen in a U    
281        if (fVerboseLevel > 0)                     
282   {                                               
283     //Issue a G4Exception (warning) only in ve    
284     G4ExceptionDescription ed;                    
285     ed << "Unable to retrieve the cross sectio    
286     ed << "This can happen only in Unit Tests     
287     G4Exception("G4PenelopeRayleighModel::Comp    
288           "em2040",JustWarning,ed);               
289   }                                               
290        //protect file reading via autolock        
291        G4AutoLock lock(&PenelopeRayleighModelM    
292        ReadDataFile(iZ);                          
293        lock.unlock();                             
294      }                                            
295                                                   
296    G4double cross = 0;                            
297    G4PhysicsFreeVector* atom = fLogAtomicCross    
298    if (!atom)                                     
299      {                                            
300        G4ExceptionDescription ed;                 
301        ed << "Unable to find Z=" << iZ << " in    
302        G4Exception("G4PenelopeRayleighModel::C    
303        "em2041",FatalException,ed);               
304        return 0;                                  
305      }                                            
306    G4double logene = G4Log(energy);               
307    G4double logXS = atom->Value(logene);          
308    cross = G4Exp(logXS);                          
309                                                   
310    if (fVerboseLevel > 2)                         
311      {                                            
312        G4cout << "Rayleigh cross section at "     
313    " = " << cross/barn << " barn" << G4endl;      
314      }                                            
315    return cross;                                  
316 }                                                 
317                                                   
318                                                   
319 //....oooOO0OOooo........oooOO0OOooo........oo    
320 void G4PenelopeRayleighModel::BuildFormFactorT    
321 {                                                 
322   /*                                              
323     1) get composition and equivalent molecula    
324   */                                              
325   std::size_t nElements = material->GetNumberO    
326   const G4ElementVector* elementVector = mater    
327   const G4double* fractionVector = material->G    
328                                                   
329   std::vector<G4double> *StechiometricFactors     
330   for (std::size_t i=0;i<nElements;++i)           
331     {                                             
332       G4double fraction = fractionVector[i];      
333       G4double atomicWeigth = (*elementVector)    
334       StechiometricFactors->push_back(fraction    
335     }                                             
336   //Find max                                      
337   G4double MaxStechiometricFactor = 0.;           
338   for (std::size_t i=0;i<nElements;++i)           
339     {                                             
340       if ((*StechiometricFactors)[i] > MaxStec    
341         MaxStechiometricFactor = (*Stechiometr    
342     }                                             
343   if (MaxStechiometricFactor<1e-16)               
344     {                                             
345       G4ExceptionDescription ed;                  
346       ed << "Inconsistent data of atomic compo    
347   material->GetName() << G4endl;                  
348       G4Exception("G4PenelopeRayleighModel::Bu    
349       "em2042",FatalException,ed);                
350     }                                             
351   //Normalize                                     
352   for (std::size_t i=0;i<nElements;++i)           
353     (*StechiometricFactors)[i] /=  MaxStechiom    
354                                                   
355   /*                                              
356     CREATE THE FORM FACTOR TABLE                  
357   */                                              
358   G4PhysicsFreeVector* theFFVec = new G4Physic    
359                                                   
360   for (std::size_t k=0;k<fLogQSquareGrid.size(    
361     {                                             
362       G4double ff2 = 0; //squared form factor     
363       for (std::size_t i=0;i<nElements;++i)       
364   {                                               
365     G4int iZ = (*elementVector)[i]->GetZasInt(    
366     G4PhysicsFreeVector* theAtomVec = fAtomicF    
367     G4double f = (*theAtomVec)[k]; //the q-gri    
368     ff2 += f*f*(*StechiometricFactors)[i];        
369   }                                               
370       if (ff2)                                    
371   theFFVec->PutValue(k,fLogQSquareGrid[k],G4Lo    
372     }                                             
373   theFFVec->FillSecondDerivatives(); //vector     
374   fLogFormFactorTable->insert(std::make_pair(m    
375                                                   
376   delete StechiometricFactors;                    
377   return;                                         
378 }                                                 
379                                                   
380 //....oooOO0OOooo........oooOO0OOooo........oo    
381                                                   
382 void G4PenelopeRayleighModel::SampleSecondarie    
383             const G4MaterialCutsCouple* couple    
384             const G4DynamicParticle* aDynamicG    
385             G4double,                             
386             G4double)                             
387 {                                                 
388   // Sampling of the Rayleigh final state (nam    
389   // from the Penelope2008 model. The scatteri    
390   // cross section dOmega/d(cosTheta) from Bor    
391   // anomalous scattering effects. The Form Fa    
392   // analytical cross section is retrieved via    
393   // are tabulated for F(Q). Form factor for c    
394   // the additivity rule. The sampling from th    
395   // Transform with Aliasing (RITA) algorithm;    
396   // for each material and managed by G4Penelo    
397   // The sampling algorithm (rejection method)    
398   // increases with energy. For E=100 keV the     
399   // hydrogen and uranium, respectively.          
400                                                   
401   if (fVerboseLevel > 3)                          
402     G4cout << "Calling SamplingSecondaries() o    
403                                                   
404   G4double photonEnergy0 = aDynamicGamma->GetK    
405                                                   
406   if (photonEnergy0 <= fIntrinsicLowEnergyLimi    
407     {                                             
408       fParticleChange->ProposeTrackStatus(fSto    
409       fParticleChange->SetProposedKineticEnerg    
410       fParticleChange->ProposeLocalEnergyDepos    
411       return ;                                    
412     }                                             
413                                                   
414   G4ParticleMomentum photonDirection0 = aDynam    
415                                                   
416   const G4Material* theMat = couple->GetMateri    
417                                                   
418   //1) Verify if tables are ready                 
419   //Either Initialize() was not called, or we     
420   //not invoked                                   
421   if (!fPMaxTable || !fSamplingTable || !fLogF    
422     {                                             
423       //create a **thread-local** version of t    
424       //Unit Tests                                
425       fLocalTable = true;                         
426       if (!fLogFormFactorTable)                   
427   fLogFormFactorTable = new std::map<const G4M    
428       if (!fPMaxTable)                            
429   fPMaxTable = new std::map<const G4Material*,    
430       if (!fSamplingTable)                        
431   fSamplingTable = new std::map<const G4Materi    
432     }                                             
433                                                   
434   if (!fSamplingTable->count(theMat))             
435     {                                             
436       //If we are here, it means that Initiali    
437       //not filled up. This can happen in a Un    
438       if (fVerboseLevel > 0)                      
439   {                                               
440     //Issue a G4Exception (warning) only in ve    
441     G4ExceptionDescription ed;                    
442     ed << "Unable to find the fSamplingTable d    
443       theMat->GetName() << G4endl;                
444     ed << "This can happen only in Unit Tests"    
445     G4Exception("G4PenelopeRayleighModel::Samp    
446           "em2019",JustWarning,ed);               
447   }                                               
448       const G4ElementVector* theElementVector     
449       //protect file reading via autolock         
450       G4AutoLock lock(&PenelopeRayleighModelMu    
451       for (std::size_t j=0;j<theMat->GetNumber    
452   {                                               
453     G4int iZ = theElementVector->at(j)->GetZas    
454     if (!fLogAtomicCrossSection[iZ])              
455       {                                           
456         lock.lock();                              
457         ReadDataFile(iZ);                         
458         lock.unlock();                            
459       }                                           
460   }                                               
461       lock.lock();                                
462       //1) If the table has not been built for    
463       if (!fLogFormFactorTable->count(theMat))    
464   BuildFormFactorTable(theMat);                   
465                                                   
466       //2) retrieve or build the sampling tabl    
467       if (!(fSamplingTable->count(theMat)))       
468   InitializeSamplingAlgorithm(theMat);            
469                                                   
470       //3) retrieve or build the pMax data        
471       if (!fPMaxTable->count(theMat))             
472   GetPMaxTable(theMat);                           
473       lock.unlock();                              
474     }                                             
475                                                   
476   //Ok, restart the job                           
477   G4PenelopeSamplingData* theDataTable = fSamp    
478   G4PhysicsFreeVector* thePMax = fPMaxTable->f    
479                                                   
480   G4double cosTheta = 1.0;                        
481                                                   
482   //OK, ready to go!                              
483   G4double qmax = 2.0*photonEnergy0/electron_m    
484                                                   
485   if (qmax < 1e-10) //very low momentum transf    
486     {                                             
487       G4bool loopAgain=false;                     
488       do                                          
489   {                                               
490     loopAgain = false;                            
491     cosTheta = 1.0-2.0*G4UniformRand();           
492     G4double G = 0.5*(1+cosTheta*cosTheta);       
493     if (G4UniformRand()>G)                        
494       loopAgain = true;                           
495   }while(loopAgain);                              
496     }                                             
497   else //larger momentum transfer                 
498     {                                             
499       std::size_t nData = theDataTable->GetNum    
500       G4double LastQ2inTheTable = theDataTable    
501       G4double q2max = std::min(qmax*qmax,Last    
502                                                   
503       G4bool loopAgain = false;                   
504       G4double MaxPValue = thePMax->Value(phot    
505       G4double xx=0;                              
506                                                   
507       //Sampling by rejection method. The reje    
508       //G = 0.5*(1+cos^2(theta))                  
509       //                                          
510       do{                                         
511   loopAgain = false;                              
512   G4double RandomMax = G4UniformRand()*MaxPVal    
513   xx = theDataTable->SampleValue(RandomMax);      
514   //xx is a random value of q^2 in (0,q2max),s    
515   //F(Q^2) via the RITA algorithm                 
516   if (xx > q2max)                                 
517     loopAgain = true;                             
518   cosTheta = 1.0-2.0*xx/q2max;                    
519   G4double G = 0.5*(1+cosTheta*cosTheta);         
520   if (G4UniformRand()>G)                          
521     loopAgain = true;                             
522       }while(loopAgain);                          
523     }                                             
524                                                   
525   G4double sinTheta = std::sqrt(1-cosTheta*cos    
526                                                   
527   // Scattered photon angles. ( Z - axis along    
528   G4double phi = twopi * G4UniformRand() ;        
529   G4double dirX = sinTheta*std::cos(phi);         
530   G4double dirY = sinTheta*std::sin(phi);         
531   G4double dirZ = cosTheta;                       
532                                                   
533   // Update G4VParticleChange for the scattere    
534   G4ThreeVector photonDirection1(dirX, dirY, d    
535                                                   
536   photonDirection1.rotateUz(photonDirection0);    
537   fParticleChange->ProposeMomentumDirection(ph    
538   fParticleChange->SetProposedKineticEnergy(ph    
539                                                   
540   return;                                         
541 }                                                 
542                                                   
543                                                   
544 //....oooOO0OOooo........oooOO0OOooo........oo    
545                                                   
546 void G4PenelopeRayleighModel::ReadDataFile(con    
547 {                                                 
548   if (fVerboseLevel > 2)                          
549     {                                             
550       G4cout << "G4PenelopeRayleighModel::Read    
551       G4cout << "Going to read Rayleigh data f    
552     }                                             
553     const char* path = G4FindDataDir("G4LEDATA    
554     if(!path)                                     
555     {                                             
556       G4String excep = "G4LEDATA environment v    
557       G4Exception("G4PenelopeRayleighModel::Re    
558       "em0006",FatalException,excep);             
559       return;                                     
560     }                                             
561                                                   
562   /*                                              
563     Read first the cross section file             
564   */                                              
565   std::ostringstream ost;                         
566   if (Z>9)                                        
567     ost << path << "/penelope/rayleigh/pdgra"     
568   else                                            
569     ost << path << "/penelope/rayleigh/pdgra0"    
570   std::ifstream file(ost.str().c_str());          
571   if (!file.is_open())                            
572     {                                             
573       G4String excep = "Data file " + G4String    
574       G4Exception("G4PenelopeRayleighModel::Re    
575       "em0003",FatalException,excep);             
576     }                                             
577   G4int readZ =0;                                 
578   std::size_t nPoints= 0;                         
579   file >> readZ >> nPoints;                       
580   //check the right file is opened.               
581   if (readZ != Z || nPoints <= 0 || nPoints >=    
582     {                                             
583       G4ExceptionDescription ed;                  
584       ed << "Corrupted data file for Z=" << Z     
585       G4Exception("G4PenelopeRayleighModel::Re    
586       "em0005",FatalException,ed);                
587       return;                                     
588     }                                             
589                                                   
590   fLogAtomicCrossSection[Z] = new G4PhysicsFre    
591   G4double ene=0,f1=0,f2=0,xs=0;                  
592   for (std::size_t i=0;i<nPoints;++i)             
593     {                                             
594       file >> ene >> f1 >> f2 >> xs;              
595       //dimensional quantities                    
596       ene *= eV;                                  
597       xs *= cm2;                                  
598       fLogAtomicCrossSection[Z]->PutValue(i,G4    
599       if (file.eof() && i != (nPoints-1)) //fi    
600   {                                               
601     G4ExceptionDescription ed ;                   
602     ed << "Corrupted data file for Z=" << Z <<    
603     ed << "Found less than " << nPoints << "en    
604     G4Exception("G4PenelopeRayleighModel::Read    
605           "em0005",FatalException,ed);            
606   }                                               
607     }                                             
608   file.close();                                   
609                                                   
610   /*                                              
611     Then read the form factor file                
612   */                                              
613   std::ostringstream ost2;                        
614   if (Z>9)                                        
615     ost2 << path << "/penelope/rayleigh/pdaff"    
616   else                                            
617     ost2 << path << "/penelope/rayleigh/pdaff0    
618   file.open(ost2.str().c_str());                  
619   if (!file.is_open())                            
620     {                                             
621       G4String excep = "Data file " + G4String    
622       G4Exception("G4PenelopeRayleighModel::Re    
623       "em0003",FatalException,excep);             
624     }                                             
625   file >> readZ >> nPoints;                       
626   //check the right file is opened.               
627   if (readZ != Z || nPoints <= 0 || nPoints >=    
628     {                                             
629       G4ExceptionDescription ed;                  
630       ed << "Corrupted data file for Z=" << Z     
631       G4Exception("G4PenelopeRayleighModel::Re    
632       "em0005",FatalException,ed);                
633       return;                                     
634     }                                             
635   fAtomicFormFactor[Z] = new G4PhysicsFreeVect    
636   G4double q=0,ff=0,incoh=0;                      
637   G4bool fillQGrid = false;                       
638   //fill this vector only the first time.         
639   if (!fLogQSquareGrid.size())                    
640     fillQGrid = true;                             
641   for (std::size_t i=0;i<nPoints;++i)             
642     {                                             
643       file >> q >> ff >> incoh;                   
644       //q and ff are dimensionless (q is in un    
645       fAtomicFormFactor[Z]->PutValue(i,q,ff);     
646       if (fillQGrid)                              
647   {                                               
648     fLogQSquareGrid.push_back(2.0*G4Log(q));      
649   }                                               
650       if (file.eof() && i != (nPoints-1)) //fi    
651   {                                               
652     G4ExceptionDescription ed;                    
653     ed << "Corrupted data file for Z=" << Z <<    
654     ed << "Found less than " << nPoints << "en    
655     G4Exception("G4PenelopeRayleighModel::Read    
656           "em0005",FatalException,ed);            
657   }                                               
658     }                                             
659   file.close();                                   
660   return;                                         
661 }                                                 
662                                                   
663 //....oooOO0OOooo........oooOO0OOooo........oo    
664                                                   
665 G4double G4PenelopeRayleighModel::GetFSquared(    
666 {                                                 
667   G4double f2 = 0;                                
668   //Input value QSquared could be zero: protec    
669   //the FPE exception                             
670   //If Q<1e-10, set Q to 1e-10                    
671   G4double logQSquared = (QSquared>1e-10) ? G4    
672   //last value of the table                       
673   G4double maxlogQ2 = fLogQSquareGrid[fLogQSqu    
674                                                   
675   //now it should  be all right                   
676   G4PhysicsFreeVector* theVec = fLogFormFactor    
677                                                   
678   if (!theVec)                                    
679     {                                             
680       G4ExceptionDescription ed;                  
681       ed << "Unable to retrieve F squared tabl    
682       G4Exception("G4PenelopeRayleighModel::Ge    
683       "em2046",FatalException,ed);                
684       return 0;                                   
685     }                                             
686   if (logQSquared < -20) // Q < 1e-9              
687     {                                             
688       G4double logf2 = (*theVec)[0]; //first v    
689       f2 = G4Exp(logf2);                          
690     }                                             
691   else if (logQSquared > maxlogQ2)                
692     f2 =0;                                        
693   else                                            
694     {                                             
695       //log(Q^2) vs. log(F^2)                     
696       G4double logf2 = theVec->Value(logQSquar    
697       f2 = G4Exp(logf2);                          
698                                                   
699     }                                             
700   if (fVerboseLevel > 3)                          
701     {                                             
702       G4cout << "G4PenelopeRayleighModel::GetF    
703       G4cout << "Q^2 = " <<  QSquared << " (un    
704     }                                             
705   return f2;                                      
706 }                                                 
707                                                   
708 //....oooOO0OOooo........oooOO0OOooo........oo    
709                                                   
710 void G4PenelopeRayleighModel::InitializeSampli    
711 {                                                 
712   G4double q2min = 0;                             
713   G4double q2max = 0;                             
714   const std::size_t np = 150; //hard-coded in     
715   //G4cout << "Init N= " << fLogQSquareGrid.si    
716   for (std::size_t i=1;i<fLogQSquareGrid.size(    
717     {                                             
718       G4double Q2 = G4Exp(fLogQSquareGrid[i]);    
719       if (GetFSquared(mat,Q2) >  1e-35)           
720   {                                               
721     q2max = G4Exp(fLogQSquareGrid[i-1]);          
722   }                                               
723       //G4cout << "Q2= " << Q2 << " q2max= " <    
724     }                                             
725                                                   
726   std::size_t nReducedPoints = np/4;              
727                                                   
728   //check for errors                              
729   if (np < 16)                                    
730     {                                             
731       G4Exception("G4PenelopeRayleighModel::In    
732       "em2047",FatalException,                    
733       "Too few points to initialize the sampli    
734     }                                             
735   if (q2min > (q2max-1e-10))                      
736     {                                             
737       G4cout << "q2min= " << q2min << " q2max=    
738       G4Exception("G4PenelopeRayleighModel::In    
739       "em2048",FatalException,                    
740       "Too narrow grid to initialize the sampl    
741     }                                             
742                                                   
743   //This is subroutine RITAI0 of Penelope         
744   //Create an object of type G4PenelopeRayleig    
745                                                   
746   //temporary vectors --> Then everything is s    
747   G4DataVector* x = new G4DataVector();           
748                                                   
749   /*******************************************    
750     Start with a grid of NUNIF points uniforml    
751   ********************************************    
752   std::size_t NUNIF = std::min(std::max(((std:    
753   const G4int nip = 51; //hard-coded in Penelo    
754                                                   
755   G4double dx = (q2max-q2min)/((G4double) NUNI    
756   x->push_back(q2min);                            
757   for (std::size_t i=1;i<NUNIF-1;++i)             
758     {                                             
759       G4double app = q2min + i*dx;                
760       x->push_back(app); //increase               
761     }                                             
762   x->push_back(q2max);                            
763                                                   
764   if (fVerboseLevel> 3)                           
765     G4cout << "Vector x has " << x->size() <<     
766                                                   
767   //Allocate temporary storage vectors            
768   G4DataVector* area = new G4DataVector();        
769   G4DataVector* a = new G4DataVector();           
770   G4DataVector* b = new G4DataVector();           
771   G4DataVector* c = new G4DataVector();           
772   G4DataVector* err = new G4DataVector();         
773                                                   
774   for (std::size_t i=0;i<NUNIF-1;++i) //build     
775     {                                             
776       //Temporary vectors for this loop           
777       G4DataVector* pdfi = new G4DataVector();    
778       G4DataVector* pdfih = new G4DataVector()    
779       G4DataVector* sumi = new G4DataVector();    
780                                                   
781       G4double dxi = ((*x)[i+1]-(*x)[i])/(G4do    
782       G4double pdfmax = 0;                        
783       for (G4int k=0;k<nip;k++)                   
784   {                                               
785     G4double xik = (*x)[i]+k*dxi;                 
786     G4double pdfk = std::max(GetFSquared(mat,x    
787     pdfi->push_back(pdfk);                        
788     pdfmax = std::max(pdfmax,pdfk);               
789     if (k < (nip-1))                              
790       {                                           
791         G4double xih = xik + 0.5*dxi;             
792         G4double pdfIK = std::max(GetFSquared(    
793         pdfih->push_back(pdfIK);                  
794         pdfmax = std::max(pdfmax,pdfIK);          
795       }                                           
796   }                                               
797                                                   
798       //Simpson's integration                     
799       G4double cons = dxi*0.5*(1./3.);            
800       sumi->push_back(0.);                        
801       for (G4int k=1;k<nip;k++)                   
802   {                                               
803     G4double previous = (*sumi)[k-1];             
804     G4double next = previous + cons*((*pdfi)[k    
805     sumi->push_back(next);                        
806   }                                               
807                                                   
808       G4double lastIntegral = (*sumi)[sumi->si    
809       area->push_back(lastIntegral);              
810       //Normalize cumulative function             
811       G4double factor = 1.0/lastIntegral;         
812       for (std::size_t k=0;k<sumi->size();++k)    
813   (*sumi)[k] *= factor;                           
814                                                   
815       //When the PDF vanishes at one of the in    
816       if ((*pdfi)[0] < 1e-35)                     
817   (*pdfi)[0] = 1e-5*pdfmax;                       
818       if ((*pdfi)[pdfi->size()-1] < 1e-35)        
819   (*pdfi)[pdfi->size()-1] = 1e-5*pdfmax;          
820                                                   
821       G4double pli = (*pdfi)[0]*factor;           
822       G4double pui = (*pdfi)[pdfi->size()-1]*f    
823       G4double B_temp = 1.0-1.0/(pli*pui*dx*dx    
824       G4double A_temp = (1.0/(pli*dx))-1.0-B_t    
825       G4double C_temp = 1.0+A_temp+B_temp;        
826       if (C_temp < 1e-35)                         
827   {                                               
828     a->push_back(0.);                             
829     b->push_back(0.);                             
830     c->push_back(1.);                             
831   }                                               
832       else                                        
833   {                                               
834     a->push_back(A_temp);                         
835     b->push_back(B_temp);                         
836     c->push_back(C_temp);                         
837   }                                               
838                                                   
839       //OK, now get ERR(I), the integral of th    
840       //and the true pdf, extended over the in    
841       G4int icase = 1; //loop code                
842       G4bool reLoop = false;                      
843       err->push_back(0.);                         
844       do                                          
845   {                                               
846     reLoop = false;                               
847     (*err)[i] = 0.; //zero variable               
848     for (G4int k=0;k<nip;k++)                     
849       {                                           
850         G4double rr = (*sumi)[k];                 
851         G4double pap = (*area)[i]*(1.0+((*a)[i    
852     ((1.0-(*b)[i]*rr*rr)*(*c)[i]*((*x)[i+1]-(*    
853         if (k == 0 || k == nip-1)                 
854     (*err)[i] += 0.5*std::fabs(pap-(*pdfi)[k])    
855         else                                      
856     (*err)[i] += std::fabs(pap-(*pdfi)[k]);       
857       }                                           
858     (*err)[i] *= dxi;                             
859                                                   
860     //If err(I) is too large, the pdf is appro    
861     if ((*err)[i] > 0.1*(*area)[i] && icase ==    
862       {                                           
863         (*b)[i] = 0;                              
864         (*a)[i] = 0;                              
865         (*c)[i] = 1.;                             
866         icase = 2;                                
867         reLoop = true;                            
868       }                                           
869   }while(reLoop);                                 
870       delete pdfi;                                
871       delete pdfih;                               
872       delete sumi;                                
873     } //end of first loop over i                  
874                                                   
875   //Now assign last point                         
876   (*x)[x->size()-1] = q2max;                      
877   a->push_back(0.);                               
878   b->push_back(0.);                               
879   c->push_back(0.);                               
880   err->push_back(0.);                             
881   area->push_back(0.);                            
882                                                   
883   if (x->size() != NUNIF || a->size() != NUNIF    
884       err->size() != NUNIF || area->size() !=     
885     {                                             
886       G4ExceptionDescription ed;                  
887       ed << "Problem in building the Table for    
888       G4Exception("G4PenelopeRayleighModel::In    
889       "em2049",FatalException,ed);                
890     }                                             
891                                                   
892   /*******************************************    
893    New grid points are added by halving the su    
894   This is done up to np=150 points in the grid    
895   ********************************************    
896   do                                              
897     {                                             
898       G4double maxError = 0.0;                    
899       std::size_t iErrMax = 0;                    
900       for (std::size_t i=0;i<err->size()-2;++i    
901   {                                               
902     //maxError is the lagest of the interval e    
903     if ((*err)[i] > maxError)                     
904       {                                           
905         maxError = (*err)[i];                     
906         iErrMax = i;                              
907       }                                           
908   }                                               
909                                                   
910       //OK, now I have to insert one new point    
911       G4double newx = 0.5*((*x)[iErrMax]+(*x)[    
912                                                   
913       x->insert(x->begin()+iErrMax+1,newx);       
914       //Add place-holders in the other vectors    
915       area->insert(area->begin()+iErrMax+1,0.)    
916       a->insert(a->begin()+iErrMax+1,0.);         
917       b->insert(b->begin()+iErrMax+1,0.);         
918       c->insert(c->begin()+iErrMax+1,0.);         
919       err->insert(err->begin()+iErrMax+1,0.);     
920                                                   
921       //Now calculate the other parameters        
922       for (std::size_t i=iErrMax;i<=iErrMax+1;    
923   {                                               
924     //Temporary vectors for this loop             
925     G4DataVector* pdfi = new G4DataVector();      
926     G4DataVector* pdfih = new G4DataVector();     
927     G4DataVector* sumi = new G4DataVector();      
928                                                   
929     G4double dxLocal = (*x)[i+1]-(*x)[i];         
930     G4double dxi = ((*x)[i+1]-(*x)[i])/(G4doub    
931     G4double pdfmax = 0;                          
932     for (G4int k=0;k<nip;k++)                     
933       {                                           
934         G4double xik = (*x)[i]+k*dxi;             
935         G4double pdfk = std::max(GetFSquared(m    
936         pdfi->push_back(pdfk);                    
937         pdfmax = std::max(pdfmax,pdfk);           
938         if (k < (nip-1))                          
939     {                                             
940       G4double xih = xik + 0.5*dxi;               
941       G4double pdfIK = std::max(GetFSquared(ma    
942       pdfih->push_back(pdfIK);                    
943       pdfmax = std::max(pdfmax,pdfIK);            
944     }                                             
945       }                                           
946                                                   
947     //Simpson's integration                       
948     G4double cons = dxi*0.5*(1./3.);              
949     sumi->push_back(0.);                          
950     for (G4int k=1;k<nip;k++)                     
951       {                                           
952         G4double previous = (*sumi)[k-1];         
953         G4double next = previous + cons*((*pdf    
954         sumi->push_back(next);                    
955       }                                           
956     G4double lastIntegral = (*sumi)[sumi->size    
957     (*area)[i] = lastIntegral;                    
958                                                   
959     //Normalize cumulative function               
960     G4double factor = 1.0/lastIntegral;           
961     for (std::size_t k=0;k<sumi->size();++k)      
962       (*sumi)[k] *= factor;                       
963                                                   
964     //When the PDF vanishes at one of the inte    
965     if ((*pdfi)[0] < 1e-35)                       
966       (*pdfi)[0] = 1e-5*pdfmax;                   
967     if ((*pdfi)[pdfi->size()-1] < 1e-35)          
968       (*pdfi)[pdfi->size()-1] = 1e-5*pdfmax;      
969                                                   
970     G4double pli = (*pdfi)[0]*factor;             
971     G4double pui = (*pdfi)[pdfi->size()-1]*fac    
972     G4double B_temp = 1.0-1.0/(pli*pui*dxLocal    
973     G4double A_temp = (1.0/(pli*dxLocal))-1.0-    
974     G4double C_temp = 1.0+A_temp+B_temp;          
975     if (C_temp < 1e-35)                           
976       {                                           
977         (*a)[i]= 0.;                              
978         (*b)[i] = 0.;                             
979         (*c)[i] = 1;                              
980       }                                           
981     else                                          
982       {                                           
983         (*a)[i]= A_temp;                          
984         (*b)[i] = B_temp;                         
985         (*c)[i] = C_temp;                         
986       }                                           
987     //OK, now get ERR(I), the integral of the     
988     //and the true pdf, extended over the inte    
989     G4int icase = 1; //loop code                  
990     G4bool reLoop = false;                        
991     do                                            
992       {                                           
993         reLoop = false;                           
994         (*err)[i] = 0.; //zero variable           
995         for (G4int k=0;k<nip;k++)                 
996     {                                             
997       G4double rr = (*sumi)[k];                   
998       G4double pap = (*area)[i]*(1.0+((*a)[i]+    
999         ((1.0-(*b)[i]*rr*rr)*(*c)[i]*((*x)[i+1    
1000       if (k == 0 || k == nip-1)                  
1001         (*err)[i] += 0.5*std::fabs(pap-(*pdfi    
1002       else                                       
1003         (*err)[i] += std::fabs(pap-(*pdfi)[k]    
1004     }                                            
1005         (*err)[i] *= dxi;                        
1006                                                  
1007         //If err(I) is too large, the pdf is     
1008         if ((*err)[i] > 0.1*(*area)[i] && ica    
1009     {                                            
1010       (*b)[i] = 0;                               
1011       (*a)[i] = 0;                               
1012       (*c)[i] = 1.;                              
1013       icase = 2;                                 
1014       reLoop = true;                             
1015     }                                            
1016       }while(reLoop);                            
1017     delete pdfi;                                 
1018     delete pdfih;                                
1019     delete sumi;                                 
1020   }                                              
1021     }while(x->size() < np);                      
1022                                                  
1023   if (x->size() != np || a->size() != np ||      
1024       err->size() != np || area->size() != np    
1025     {                                            
1026       G4Exception("G4PenelopeRayleighModel::I    
1027       "em2050",FatalException,                   
1028       "Problem in building the extended Table    
1029     }                                            
1030                                                  
1031   /******************************************    
1032    Renormalization                               
1033   *******************************************    
1034   G4double ws = 0;                               
1035   for (std::size_t i=0;i<np-1;++i)               
1036     ws += (*area)[i];                            
1037   ws = 1.0/ws;                                   
1038   G4double errMax = 0;                           
1039   for (std::size_t i=0;i<np-1;++i)               
1040     {                                            
1041       (*area)[i] *= ws;                          
1042       (*err)[i] *= ws;                           
1043       errMax = std::max(errMax,(*err)[i]);       
1044     }                                            
1045                                                  
1046   //Vector with the normalized cumulative dis    
1047   G4DataVector* PAC = new G4DataVector();        
1048   PAC->push_back(0.);                            
1049   for (std::size_t i=0;i<np-1;++i)               
1050     {                                            
1051       G4double previous = (*PAC)[i];             
1052       PAC->push_back(previous+(*area)[i]);       
1053     }                                            
1054   (*PAC)[PAC->size()-1] = 1.;                    
1055                                                  
1056   /******************************************    
1057   Pre-calculated limits for the initial binar    
1058   *******************************************    
1059   std::vector<std::size_t> *ITTL = new std::v    
1060   std::vector<std::size_t> *ITTU = new std::v    
1061                                                  
1062   //Just create place-holders                    
1063   for (std::size_t i=0;i<np;++i)                 
1064     {                                            
1065       ITTL->push_back(0);                        
1066       ITTU->push_back(0);                        
1067     }                                            
1068                                                  
1069   G4double bin = 1.0/(np-1);                     
1070   (*ITTL)[0]=0;                                  
1071   for (std::size_t i=1;i<(np-1);++i)             
1072     {                                            
1073       G4double ptst = i*bin;                     
1074       G4bool found = false;                      
1075       for (std::size_t j=(*ITTL)[i-1];j<np &&    
1076   {                                              
1077     if ((*PAC)[j] > ptst)                        
1078       {                                          
1079         (*ITTL)[i] = j-1;                        
1080         (*ITTU)[i-1] = j;                        
1081         found = true;                            
1082       }                                          
1083   }                                              
1084     }                                            
1085   (*ITTU)[ITTU->size()-2] = ITTU->size()-1;      
1086   (*ITTU)[ITTU->size()-1] = ITTU->size()-1;      
1087   (*ITTL)[ITTL->size()-1] = ITTU->size()-2;      
1088                                                  
1089   if (ITTU->size() != np || ITTU->size() != n    
1090     {                                            
1091       G4Exception("G4PenelopeRayleighModel::I    
1092       "em2051",FatalException,                   
1093       "Problem in building the Limit Tables f    
1094     }                                            
1095                                                  
1096   /******************************************    
1097     Copy tables                                  
1098   *******************************************    
1099   G4PenelopeSamplingData* theTable = new G4Pe    
1100   for (std::size_t i=0;i<np;++i)                 
1101     {                                            
1102       theTable->AddPoint((*x)[i],(*PAC)[i],(*    
1103     }                                            
1104                                                  
1105   if (fVerboseLevel > 2)                         
1106     {                                            
1107       G4cout << "****************************    
1108   G4endl;                                        
1109       G4cout << "Sampling table for Penelope     
1110       theTable->DumpTable();                     
1111     }                                            
1112   fSamplingTable->insert(std::make_pair(mat,t    
1113                                                  
1114   //Clean up temporary vectors                   
1115   delete x;                                      
1116   delete a;                                      
1117   delete b;                                      
1118   delete c;                                      
1119   delete err;                                    
1120   delete area;                                   
1121   delete PAC;                                    
1122   delete ITTL;                                   
1123   delete ITTU;                                   
1124                                                  
1125   //DONE!                                        
1126   return;                                        
1127 }                                                
1128                                                  
1129 //....oooOO0OOooo........oooOO0OOooo........o    
1130                                                  
1131 void G4PenelopeRayleighModel::GetPMaxTable(co    
1132 {                                                
1133   if (!fPMaxTable)                               
1134     {                                            
1135       G4cout << "G4PenelopeRayleighModel::Bui    
1136       G4cout << "Going to instanziate the fPM    
1137       G4cout << "That should _not_ be here! "    
1138       fPMaxTable = new std::map<const G4Mater    
1139     }                                            
1140   //check if the table is already there          
1141   if (fPMaxTable->count(mat))                    
1142     return;                                      
1143                                                  
1144   //otherwise build it                           
1145   if (!fSamplingTable)                           
1146     {                                            
1147       G4Exception("G4PenelopeRayleighModel::G    
1148       "em2052",FatalException,                   
1149       "SamplingTable is not properly instanti    
1150       return;                                    
1151     }                                            
1152                                                  
1153   //This should not be: the sampling table is    
1154   if (!fSamplingTable->count(mat))               
1155     {                                            
1156        G4ExceptionDescription ed;                
1157        ed << "Sampling table for material " <    
1158        G4Exception("G4PenelopeRayleighModel::    
1159                   "em2052",FatalException,       
1160                   ed);                           
1161        return;                                   
1162     }                                            
1163                                                  
1164   G4PenelopeSamplingData *theTable = fSamplin    
1165   std::size_t tablePoints = theTable->GetNumb    
1166                                                  
1167   std::size_t nOfEnergyPoints = fLogEnergyGri    
1168   G4PhysicsFreeVector* theVec = new G4Physics    
1169                                                  
1170   const std::size_t nip = 51; //hard-coded in    
1171                                                  
1172   for (std::size_t ie=0;ie<fLogEnergyGridPMax    
1173     {                                            
1174       G4double energy = G4Exp(fLogEnergyGridP    
1175       G4double Qm = 2.0*energy/electron_mass_    
1176       G4double Qm2 = Qm*Qm;                      
1177       G4double firstQ2 = theTable->GetX(0);      
1178       G4double lastQ2 = theTable->GetX(tableP    
1179       G4double thePMax = 0;                      
1180                                                  
1181       if (Qm2 > firstQ2)                         
1182   {                                              
1183     if (Qm2 < lastQ2)                            
1184       {                                          
1185         //bisection to look for the index of     
1186         std::size_t lowerBound = 0;              
1187         std::size_t upperBound = tablePoints-    
1188         while (lowerBound <= upperBound)         
1189     {                                            
1190       std::size_t midBin = (lowerBound + uppe    
1191       if( Qm2 < theTable->GetX(midBin))          
1192         { upperBound = midBin-1; }               
1193       else                                       
1194         { lowerBound = midBin+1; }               
1195     }                                            
1196         //upperBound is the output (but also     
1197         G4double Q1 = theTable->GetX(upperBou    
1198         G4double Q2 = Qm2;                       
1199         G4double DQ = (Q2-Q1)/((G4double)(nip    
1200         G4double theA = theTable->GetA(upperB    
1201         G4double theB = theTable->GetB(upperB    
1202         G4double thePAC = theTable->GetPAC(up    
1203         G4DataVector* fun = new G4DataVector(    
1204         for (std::size_t k=0;k<nip;++k)          
1205     {                                            
1206       G4double qi = Q1 + k*DQ;                   
1207       G4double tau = (qi-Q1)/                    
1208         (theTable->GetX(upperBound+1)-Q1);       
1209       G4double con1 = 2.0*theB*tau;              
1210       G4double ci = 1.0+theA+theB;               
1211       G4double con2 = ci-theA*tau;               
1212       G4double etap = 0;                         
1213       if (std::fabs(con1) > 1.0e-16*std::fabs    
1214         etap = con2*(1.0-std::sqrt(1.0-2.0*ta    
1215       else                                       
1216         etap = tau/con2;                         
1217       G4double theFun = (theTable->GetPAC(upp    
1218         (1.0+(theA+theB*etap)*etap)*(1.0+(the    
1219         ((1.0-theB*etap*etap)*ci*(theTable->G    
1220       fun->push_back(theFun);                    
1221     }                                            
1222         //Now intergrate numerically the fun     
1223         G4DataVector* sum = new G4DataVector;    
1224         G4double CONS = DQ*(1./12.);             
1225         G4double HCONS = 0.5*CONS;               
1226         sum->push_back(0.);                      
1227         G4double secondPoint = (*sum)[0] +       
1228     (5.0*(*fun)[0]+8.0*(*fun)[1]-(*fun)[2])*C    
1229         sum->push_back(secondPoint);             
1230         for (std::size_t hh=2;hh<nip-1;++hh)     
1231     {                                            
1232       G4double previous = (*sum)[hh-1];          
1233       G4double next = previous+(13.0*((*fun)[    
1234               (*fun)[hh+1]-(*fun)[hh-2])*HCON    
1235       sum->push_back(next);                      
1236     }                                            
1237         G4double last = (*sum)[nip-2]+(5.0*(*    
1238                (*fun)[nip-3])*CONS;              
1239         sum->push_back(last);                    
1240         thePMax = thePAC + (*sum)[sum->size()    
1241         delete fun;                              
1242         delete sum;                              
1243       }                                          
1244     else                                         
1245       {                                          
1246         thePMax = 1.0;                           
1247       }                                          
1248   }                                              
1249       else                                       
1250   {                                              
1251     thePMax = theTable->GetPAC(0);               
1252   }                                              
1253                                                  
1254       //Write number in the table                
1255       theVec->PutValue(ie,energy,thePMax);       
1256   }                                              
1257                                                  
1258   fPMaxTable->insert(std::make_pair(mat,theVe    
1259   return;                                        
1260 }                                                
1261                                                  
1262 //....oooOO0OOooo........oooOO0OOooo........o    
1263                                                  
1264 void G4PenelopeRayleighModel::DumpFormFactorT    
1265 {                                                
1266   G4cout << "********************************    
1267   G4cout << "G4PenelopeRayleighModel: Form Fa    
1268   //try to use the same format as Penelope-Fo    
1269   G4cout <<  "Q/(m_e*c)                 F(Q)     
1270   G4cout << "********************************    
1271   if (!fLogFormFactorTable->count(mat))          
1272     BuildFormFactorTable(mat);                   
1273                                                  
1274   G4PhysicsFreeVector* theVec = fLogFormFacto    
1275   for (std::size_t i=0;i<theVec->GetVectorLen    
1276     {                                            
1277       G4double logQ2 = theVec->GetLowEdgeEner    
1278       G4double Q = G4Exp(0.5*logQ2);             
1279       G4double logF2 = (*theVec)[i];             
1280       G4double F = G4Exp(0.5*logF2);             
1281       G4cout << Q << "              " << F <<    
1282     }                                            
1283   //DONE                                         
1284   return;                                        
1285 }                                                
1286                                                  
1287 //....oooOO0OOooo........oooOO0OOooo........o    
1288                                                  
1289 void G4PenelopeRayleighModel::SetParticle(con    
1290 {                                                
1291   if(!fParticle) {                               
1292     fParticle = p;                               
1293   }                                              
1294 }                                                
1295