Geant4 Cross Reference

Cross-Referencing   Geant4
Geant4/examples/extended/medical/dna/neuron/src/Run.cc

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Diff markup

Differences between /examples/extended/medical/dna/neuron/src/Run.cc (Version 11.3.0) and /examples/extended/medical/dna/neuron/src/Run.cc (Version 10.1.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 // This example is provided by the Geant4-DNA     
 27 // Any report or published results obtained us    
 28 // shall cite the following Geant4-DNA collabo    
 29 // Med. Phys. 37 (2010) 4692-4708                 
 30 // and papers                                     
 31 // M. Batmunkh et al. J Radiat Res Appl Sci 8     
 32 // O. Belov et al. Physica Medica 32 (2016) 15    
 33 // The Geant4-DNA web site is available at htt    
 34 //                                                
 35 // -------------------------------------------    
 36 // November 2016                                  
 37 // -------------------------------------------    
 38 //                                                
 39 /// \file Run.cc                                  
 40 /// \brief Implementation of the Run class        
 41                                                   
 42 #include "Run.hh"                                 
 43                                                   
 44 #include "DetectorConstruction.hh"                
 45 #include "PrimaryGeneratorAction.hh"              
 46                                                   
 47 #include "G4AnalysisManager.hh"                   
 48 #include "G4EmCalculator.hh"                      
 49 #include "G4H2O.hh"                               
 50 #include "G4Molecule.hh"                          
 51 #include "G4MoleculeCounter.hh"                   
 52 #include "G4MoleculeGun.hh"                       
 53 #include "G4MoleculeTable.hh"                     
 54 #include "G4SystemOfUnits.hh"                     
 55 #include "G4UnitsTable.hh"                        
 56 #include "G4ios.hh"                               
 57                                                   
 58 #include <G4Scheduler.hh>                         
 59 #include <iomanip>                                
 60                                                   
 61 //....oooOO0OOooo........oooOO0OOooo........oo    
 62                                                   
 63 Run::Run(DetectorConstruction* det) : G4Run(),    
 64 {                                                 
 65   fSoma3DEdep = new G4double[fDetector->GetnbS    
 66   for (G4int i = 0; i < fDetector->GetnbSomaco    
 67     fSoma3DEdep[i] = 0.;                          
 68   }                                               
 69   fDend3DEdep = new G4double[fDetector->GetnbD    
 70   for (G4int i = 0; i < fDetector->GetnbDendri    
 71     fDend3DEdep[i] = 0.;                          
 72   }                                               
 73   fAxon3DEdep = new G4double[fDetector->GetnbA    
 74   for (G4int i = 0; i < fDetector->GetnbAxonco    
 75     fAxon3DEdep[i] = 0.;                          
 76   }                                               
 77                                                   
 78   fEdepAll = fEdepAll_err = fEdepMedium = fEde    
 79     fEdepSoma = fEdepSoma_err = 0.;               
 80   fEdepDend = fEdepDend_err = fEdepAxon = fEde    
 81 }                                                 
 82                                                   
 83 //....oooOO0OOooo........oooOO0OOooo........oo    
 84                                                   
 85 Run::~Run()                                       
 86 {                                                 
 87   delete[] fSoma3DEdep;                           
 88   delete[] fDend3DEdep;                           
 89   delete[] fAxon3DEdep;                           
 90 }                                                 
 91                                                   
 92 //....oooOO0OOooo........oooOO0OOooo........oo    
 93                                                   
 94 void Run::SetPrimary(G4ParticleDefinition* par    
 95 {                                                 
 96   fParticle = particle;                           
 97   fEkin = energy;                                 
 98 }                                                 
 99                                                   
100 //....oooOO0OOooo........oooOO0OOooo........oo    
101                                                   
102 void Run::AddPrimaryLET(G4double let)             
103 {                                                 
104   fLET += let;                                    
105   fLET2 += let * let;                             
106 }                                                 
107                                                   
108 //....oooOO0OOooo........oooOO0OOooo........oo    
109                                                   
110 void Run::SetTrackLength(G4double t)              
111 {                                                 
112   ftrackLength = t;                               
113   fTrackLen += t;                                 
114   fTrackLen2 += t * t;                            
115 }                                                 
116                                                   
117 //....oooOO0OOooo........oooOO0OOooo........oo    
118                                                   
119 void Run::CountProcesses(const G4VProcess* pro    
120 {                                                 
121   G4String procName = process->GetProcessName(    
122   std::map<G4String, G4int>::iterator it = fPr    
123   if (it == fProcCounter.end()) {                 
124     fProcCounter[procName] = 1;                   
125   }                                               
126   else {                                          
127     fProcCounter[procName]++;                     
128   }                                               
129 }                                                 
130                                                   
131 //....oooOO0OOooo........oooOO0OOooo........oo    
132                                                   
133 void Run::ParticleCount(G4String name, G4doubl    
134 {                                                 
135   std::map<G4String, ParticleData>::iterator i    
136   if (it == fParticleDataMap1.end()) {            
137     fParticleDataMap1[name] = ParticleData(1,     
138   }                                               
139   else {                                          
140     ParticleData& data = it->second;              
141     data.fCount++;                                
142     data.fEmean += Ekin;                          
143     // update min max                             
144     G4double emin = data.fEmin;                   
145     if (Ekin < emin) data.fEmin = Ekin;           
146     G4double emax = data.fEmax;                   
147     if (Ekin > emax) data.fEmax = Ekin;           
148   }                                               
149 }                                                 
150                                                   
151 //....oooOO0OOooo........oooOO0OOooo........oo    
152                                                   
153 void Run::ParticleCountNeuron(G4String name, G    
154 {                                                 
155   std::map<G4String, ParticleData>::iterator i    
156   if (it == fParticleDataMap2.end()) {            
157     fParticleDataMap2[name] = ParticleData(1,     
158   }                                               
159   else {                                          
160     ParticleData& data = it->second;              
161     data.fCount++;                                
162     data.fEmean += Ekin;                          
163     // update min max                             
164     G4double emin = data.fEmin;                   
165     if (Ekin < emin) data.fEmin = Ekin;           
166     G4double emax = data.fEmax;                   
167     if (Ekin > emax) data.fEmax = Ekin;           
168   }                                               
169 }                                                 
170                                                   
171 //....oooOO0OOooo........oooOO0OOooo........oo    
172 /*                                                
173 void Run::MoleculeCount(G4String, G4double)       
174 {                                                 
175 //fMoleculeNumber = G4MoleculeCounter::Instanc    
176 //                  ->GetNMoleculesAtTime(mole    
177 }                                                 
178 */                                                
179 //....oooOO0OOooo........oooOO0OOooo........oo    
180                                                   
181 void Run::MoleculeCountNeuron(G4Molecule* mole    
182 {                                                 
183   G4String moleculename = molecule->GetName();    
184   std::map<G4String, G4int>::iterator it = fMo    
185   if (it == fMoleculeNumber.end()) {              
186     fMoleculeNumber[moleculename] = 1;            
187   }                                               
188   else {                                          
189     fMoleculeNumber[moleculename]++;              
190   }                                               
191 }                                                 
192                                                   
193 //....oooOO0OOooo........oooOO0OOooo........oo    
194                                                   
195 void Run::AddEflow(G4double eflow)                
196 {                                                 
197   fEnergyFlow += eflow;                           
198   fEnergyFlow2 += eflow * eflow;                  
199 }                                                 
200                                                   
201 //....oooOO0OOooo........oooOO0OOooo........oo    
202                                                   
203 void Run::Merge(const G4Run* run)                 
204 {                                                 
205   const Run* localRun = static_cast<const Run*    
206                                                   
207   // primary particle info                        
208   //                                              
209   fParticle = localRun->fParticle;                
210   fEkin = localRun->fEkin;                        
211   ftrackLength = localRun->ftrackLength;          
212   fTrackLen += localRun->fTrackLen;               
213   fTrackLen2 += localRun->fTrackLen2;             
214   fLET += localRun->fLET;                         
215   fLET2 += localRun->fLET2;                       
216                                                   
217   // map: processes count in simulation medium    
218   std::map<G4String, G4int>::const_iterator it    
219   for (itp = localRun->fProcCounter.begin(); i    
220     G4String procName = itp->first;               
221     G4int localCount = itp->second;               
222     if (fProcCounter.find(procName) == fProcCo    
223       fProcCounter[procName] = localCount;        
224     }                                             
225     else {                                        
226       fProcCounter[procName] += localCount;       
227     }                                             
228   }                                               
229                                                   
230   // map: created particles count outside neur    
231   std::map<G4String, ParticleData>::const_iter    
232   for (itc = localRun->fParticleDataMap1.begin    
233     G4String name = itc->first;                   
234     const ParticleData& localData = itc->secon    
235     if (fParticleDataMap1.find(name) == fParti    
236       fParticleDataMap1[name] =                   
237         ParticleData(localData.fCount, localDa    
238     }                                             
239     else {                                        
240       ParticleData& data = fParticleDataMap1[n    
241       data.fCount += localData.fCount;            
242       data.fEmean += localData.fEmean;            
243       G4double emin = localData.fEmin;            
244       if (emin < data.fEmin) data.fEmin = emin    
245       G4double emax = localData.fEmax;            
246       if (emax > data.fEmax) data.fEmax = emax    
247     }                                             
248   }                                               
249                                                   
250   // map: created particles count inside neuro    
251   std::map<G4String, ParticleData>::const_iter    
252   for (itn = localRun->fParticleDataMap2.begin    
253     G4String name = itn->first;                   
254     const ParticleData& localData = itn->secon    
255     if (fParticleDataMap2.find(name) == fParti    
256       fParticleDataMap2[name] =                   
257         ParticleData(localData.fCount, localDa    
258     }                                             
259     else {                                        
260       ParticleData& data = fParticleDataMap2[n    
261       data.fCount += localData.fCount;            
262       data.fEmean += localData.fEmean;            
263       G4double emin = localData.fEmin;            
264       if (emin < data.fEmin) data.fEmin = emin    
265       G4double emax = localData.fEmax;            
266       if (emax > data.fEmax) data.fEmax = emax    
267     }                                             
268   }                                               
269                                                   
270   std::map<G4String, G4int>::const_iterator it    
271   for (itm = localRun->fMoleculeNumber.begin()    
272     G4String moleculeName = itm->first;           
273     G4int localCount = itm->second;               
274     if (fMoleculeNumber.find(moleculeName) ==     
275       fMoleculeNumber[moleculeName] = localCou    
276     }                                             
277     else {                                        
278       fMoleculeNumber[moleculeName] += localCo    
279     }                                             
280   }                                               
281                                                   
282   // hits compartments in neuron compartments     
283   //                                              
284   for (G4int i = 0; i < fDetector->GetnbSomaco    
285     fSoma3DEdep[i] += localRun->fSoma3DEdep[i]    
286   }                                               
287   for (G4int i = 0; i < fDetector->GetnbDendri    
288     fDend3DEdep[i] += localRun->fDend3DEdep[i]    
289   }                                               
290   for (G4int i = 0; i < fDetector->GetnbAxonco    
291     fAxon3DEdep[i] += localRun->fAxon3DEdep[i]    
292   }                                               
293                                                   
294   // accumulate sums                              
295   //                                              
296   fEdepAll += localRun->fEdepAll;                 
297   fEdepAll_err += localRun->fEdepAll_err;         
298   fEdepMedium += localRun->fEdepMedium;           
299   fEdepMedium_err += localRun->fEdepMedium_err    
300   fEdepSlice += localRun->fEdepSlice;             
301   fEdepSlice_err += localRun->fEdepSlice_err;     
302   fEdepSoma += localRun->fEdepSoma;               
303   fEdepSoma_err += localRun->fEdepSoma_err;       
304   fEdepDend += localRun->fEdepDend;               
305   fEdepDend_err += localRun->fEdepDend_err;       
306   fEdepAxon += localRun->fEdepAxon;               
307   fEdepAxon_err += localRun->fEdepAxon_err;       
308   fEdepNeuron += localRun->fEdepNeuron;           
309   fEdepNeuron_err += localRun->fEdepNeuron_err    
310                                                   
311   fEnergyFlow += localRun->fEnergyFlow;           
312   fEnergyFlow2 += localRun->fEnergyFlow2;         
313                                                   
314   G4Run::Merge(run);                              
315 }                                                 
316                                                   
317 //....oooOO0OOooo........oooOO0OOooo........oo    
318                                                   
319 void Run::EndOfRun()                              
320 {                                                 
321   G4int prec = 5, wid = prec + 2;                 
322   G4int dfprec = G4cout.precision(prec);          
323                                                   
324   // Characteristics of Primary particle          
325   G4String Particle = fParticle->GetParticleNa    
326   G4double GunArea;                               
327                                                   
328   G4Material* material = fDetector->GetTargetM    
329                                                   
330   // compute track length of primary track        
331   //                                              
332   fTrackLen /= numberOfEvent;                     
333   fTrackLen2 /= numberOfEvent;                    
334   G4double rms = fTrackLen2 - fTrackLen * fTra    
335   if (rms > 0.)                                   
336     rms = std::sqrt(rms);                         
337   else                                            
338     rms = 0.;                                     
339                                                   
340   G4int TotNbofEvents = numberOfEvent;            
341   G4double EdepTotal = fEdepAll;                  
342   G4double EdepTotal2 = fEdepAll_err;             
343   EdepTotal /= TotNbofEvents;                     
344   EdepTotal2 /= TotNbofEvents;                    
345   G4double rmst = EdepTotal2 - EdepTotal * Ede    
346   if (rmst > 0.)                                  
347     rmst = std::sqrt(rmst);                       
348   else                                            
349     rmst = 0.;                                    
350                                                   
351   // Stopping Power from input Table.             
352   G4EmCalculator emCalculator;                    
353   G4double dEdxFull = 0.;                         
354   if (fParticle->GetPDGCharge() != 0.) {          
355     dEdxFull = emCalculator.ComputeTotalDEDX(f    
356   }                                               
357                                                   
358   // Stopping Power from simulation.              
359   G4double meandEdx = (EdepTotal / fTrackLen)     
360   G4double meandEdxerr = (rmst / fTrackLen) /     
361   G4int ncols = 0;                                
362   G4float tmp, En;                                
363   G4int Ntrav = 0;                                
364   FILE* fp = fopen("OutputPerEvent.out", "r");    
365   while (1) {                                     
366     ncols = fscanf(fp, " %f %f %f %f %f %f %f     
367     if (ncols < 0) break;                         
368     if (En > 0) Ntrav++;                          
369   }                                               
370   fclose(fp);                                     
371   // The surface area is calculated as spheric    
372   GunArea = fDetector->GetTotSurfMedium();        
373   // Fluence dose of single paticle track         
374   G4double FluenceDoseperBeam = 0.160218 * (dE    
375                                                   
376   G4cout << "\n ======= The summary of simulat    
377   G4cout << "\n  Primary particle                 
378          << "\n  Kinetic energy of beam           
379          << "\n  Particle traversals the neuro    
380          << "\n  Full LET of beam as formulas     
381          << "\n  Mean LET of beam as simulatio    
382          << " keV/um"                             
383          << "\n  Mean track length of beam        
384          << "\n  Particle fluence                 
385          << " particles/cm^2"                     
386          << "\n  Fluence dose (full)              
387          << numberOfEvent * FluenceDoseperBeam    
388          << "\n  Fluence dose ber beam            
389          << G4endl;                               
390                                                   
391   if (numberOfEvent == 0) {                       
392     G4cout.precision(dfprec);                     
393     return;                                       
394   }                                               
395                                                   
396   // frequency of processes in all volume         
397   //                                              
398   G4cout << "\n List of generated physical pro    
399                                                   
400   G4int index = 0;                                
401   std::map<G4String, G4int>::iterator it;         
402   for (it = fProcCounter.begin(); it != fProcC    
403     G4String procName = it->first;                
404     G4int count = it->second;                     
405     G4String space = " ";                         
406     if (++index % 1 == 0) space = "\n";           
407     G4cout << " " << std::setw(20) << procName    
408   }                                               
409   G4cout << G4endl;                               
410                                                   
411   // particles count outside neuron structure     
412   //                                              
413   G4cout << "\n List of generated particles ou    
414                                                   
415   std::map<G4String, ParticleData>::iterator i    
416   for (itc = fParticleDataMap1.begin(); itc !=    
417     G4String name = itc->first;                   
418     ParticleData data = itc->second;              
419     G4int count = data.fCount;                    
420     G4double eMean = data.fEmean / count;         
421     G4double eMin = data.fEmin;                   
422     G4double eMax = data.fEmax;                   
423     //-----> secondary particles flux             
424     G4double Eflow = data.fEmean / TotNbofEven    
425                                                   
426     G4cout << "  " << std::setw(13) << name <<    
427            << "  Emean = " << std::setw(wid) <    
428            << G4BestUnit(eMin, "Energy") << "     
429            << ") \tEflow/event = " << G4BestUn    
430   }                                               
431                                                   
432   // particles count inside neuron structure      
433   //                                              
434   G4cout << "\n Number of secondary particles     
435                                                   
436   std::map<G4String, ParticleData>::iterator i    
437   for (itn = fParticleDataMap2.begin(); itn !=    
438     G4String name = itn->first;                   
439     ParticleData data = itn->second;              
440     G4int count = data.fCount;                    
441                                                   
442     G4cout << "  " << std::setw(13) << name <<    
443   }                                               
444                                                   
445   // molecules count inside neuron                
446   //  Time cut (from 1 ps to 10 ps) in class I    
447   G4cout << "\n Number of molecular products i    
448          << "\n    time: 1 ps - 10 ps " << G4e    
449   // if (1 ns < time <= 10 ns ) MoleculeCount(    
450   G4int ind = 0;                                  
451   std::map<G4String, G4int>::iterator itm;        
452   for (itm = fMoleculeNumber.begin(); itm != f    
453     G4String moleculeName = itm->first;           
454     G4int count = itm->second;                    
455     G4String space = " ";                         
456     if (++ind % 3 == 0) space = "\n";             
457                                                   
458     G4cout << "  " << std::setw(13) << molecul    
459   }                                               
460                                                   
461   // compute total Energy and Dose deposited f    
462   G4cout << "\n Total energy (MeV) deposition     
463                                                   
464   G4cout << "  " << std::setw(13) << "All volu    
465          << "  " << std::setw(13) << "Bounding    
466          << (fEdepSlice + fEdepNeuron) / MeV <    
467          << "  " << std::setw(13) << "Neuron:     
468          << "  " << std::setw(13) << "Soma:       
469          << "  " << std::setw(13) << "Dendrite    
470          << "  " << std::setw(13) << "Axon:       
471                                                   
472   // compute mean Energy and Dose deposited in    
473   //                                              
474   // G4AnalysisManager* analys = G4AnalysisMan    
475   G4int somaCompHit = 0;                          
476   G4double somaCompEdep = 0.;                     
477   G4double somaCompDose = 0.;                     
478   G4double somaCompEdep2 = 0.;                    
479   G4double somaCompDose2 = 0.;                    
480   // Remove old outputs                           
481   remove("Soma3DEdep.out");                       
482   for (G4int i = 0; i < fDetector->GetnbSomaco    
483     if (fSoma3DEdep[i] > 0.0) {                   
484       somaCompHit++;                              
485       somaCompEdep += fSoma3DEdep[i];             
486       somaCompEdep2 += fSoma3DEdep[i] * fSoma3    
487                                                   
488       std::ofstream WriteDataInSoma("Soma3DEde    
489       // Index of targeted compartments           
490       WriteDataInSoma << fDetector->GetPosSoma    
491                       << fDetector->GetPosSoma    
492                       << fDetector->GetPosSoma    
493                       << "   "                    
494                       // Edep in compartments     
495                       << fSoma3DEdep[i] / keV     
496     }                                             
497   }                                               
498   // compute mean Energy and Dose deposited in    
499   // +- RMS : Root Mean Square                    
500   G4double rmsEdepS = 0.;                         
501   G4double rmsDoseS = 0.;                         
502   if (somaCompHit > 0) {                          
503     somaCompEdep /= somaCompHit;                  
504     somaCompEdep2 /= somaCompHit;                 
505     rmsEdepS = somaCompEdep2 - somaCompEdep *     
506     if (rmsEdepS > 0.)                            
507       rmsEdepS = std::sqrt(rmsEdepS);             
508     else                                          
509       rmsEdepS = 0.;                              
510     somaCompDose /= somaCompHit;                  
511     somaCompDose2 /= somaCompHit;                 
512     rmsDoseS = somaCompDose2 - somaCompDose *     
513     if (rmsDoseS > 0.)                            
514       rmsDoseS = std::sqrt(rmsDoseS);             
515     else                                          
516       rmsDoseS = 0.;                              
517   }                                               
518                                                   
519   G4int DendCompHit = 0;                          
520   G4double DendCompEdep = 0.;                     
521   G4double DendCompDose = 0.;                     
522   G4double DendCompEdep2 = 0.;                    
523   G4double DendCompDose2 = 0.;                    
524   remove("Dend3DEdep.out");                       
525   std::ofstream WriteDataInDend("Dend3DEdep.ou    
526   for (G4int i = 0; i < fDetector->GetnbDendri    
527     if (fDend3DEdep[i] > 0.0) {                   
528       DendCompHit++;                              
529       DendCompEdep += fDend3DEdep[i];             
530       DendCompEdep2 += fDend3DEdep[i] * fDend3    
531                                                   
532       WriteDataInDend  //<<   i+1            <    
533                        // position of compartm    
534         << fDetector->GetPosDendcomp(i).x() <<    
535         << '\t' << "   " << fDetector->GetPosD    
536         << fDetector->GetDistADendSoma(i) << '    
537         << "   " << fDend3DEdep[i] / keV << '\    
538     }                                             
539   }                                               
540   // +- RMS : Root Mean Square                    
541   G4double rmsEdepD = 0.;                         
542   G4double rmsDoseD = 0.;                         
543   if (DendCompHit > 0) {                          
544     DendCompEdep /= DendCompHit;                  
545     DendCompEdep2 /= DendCompHit;                 
546     rmsEdepD = DendCompEdep2 - DendCompEdep *     
547     if (rmsEdepD > 0.)                            
548       rmsEdepD = std::sqrt(rmsEdepD);             
549     else                                          
550       rmsEdepD = 0.;                              
551     DendCompDose /= DendCompHit;                  
552     DendCompDose2 /= DendCompHit;                 
553     rmsDoseD = DendCompDose2 - DendCompDose *     
554     if (rmsDoseD > 0.)                            
555       rmsDoseD = std::sqrt(rmsDoseD);             
556     else                                          
557       rmsDoseD = 0.;                              
558   }                                               
559                                                   
560   G4int AxonCompHit = 0;                          
561   G4double AxonCompEdep = 0.;                     
562   G4double AxonCompDose = 0.;                     
563   G4double AxonCompEdep2 = 0.;                    
564   G4double AxonCompDose2 = 0.;                    
565   remove("Axon3DEdep.out");                       
566   std::ofstream WriteDataInAxon("Axon3DEdep.ou    
567   for (G4int i = 0; i < fDetector->GetnbAxonco    
568     if (fAxon3DEdep[i] > 0.0) {                   
569       AxonCompHit++;                              
570       AxonCompEdep += fAxon3DEdep[i];             
571       AxonCompEdep2 += fAxon3DEdep[i] * fAxon3    
572                                                   
573       WriteDataInAxon  //<<   i+1            <    
574                        // position of compartm    
575         << fDetector->GetPosAxoncomp(i).x() <<    
576         << '\t' << "   " << fDetector->GetPosA    
577         << fDetector->GetDistAxonsoma(i) << '\    
578         << G4endl;                                
579     }                                             
580   }                                               
581   // +- RMS : Root Mean Square                    
582   G4double rmsEdepA = 0.;                         
583   G4double rmsDoseA = 0.;                         
584   if (AxonCompHit > 0) {                          
585     AxonCompEdep /= AxonCompHit;                  
586     AxonCompEdep2 /= AxonCompHit;                 
587     rmsEdepA = AxonCompEdep2 - AxonCompEdep *     
588     if (rmsEdepA > 0.)                            
589       rmsEdepA = std::sqrt(rmsEdepA);             
590     else                                          
591       rmsEdepA = 0.;                              
592     AxonCompDose /= AxonCompHit;                  
593     AxonCompDose2 /= AxonCompHit;                 
594     rmsDoseA = AxonCompDose2 - AxonCompDose *     
595     if (rmsDoseA > 0.)                            
596       rmsDoseA = std::sqrt(rmsDoseA);             
597     else                                          
598       rmsDoseA = 0.;                              
599   }                                               
600                                                   
601   G4cout << "\n Number of compartments travers    
602   G4cout << "  " << std::setw(13) << "Soma:  "    
603          << " of total: " << fDetector->GetnbS    
604          << "  " << std::setw(13) << "Dendrite    
605          << " of total: " << fDetector->GetnbD    
606          << "  " << std::setw(13) << "Axon: "     
607          << " of total: " << fDetector->GetnbA    
608   G4cout << "\n Dendritic (or Axon) compartmen    
609          << " at the distance from Soma have b    
610          << "\n Dend3DEdep.out, Axon3DEdep.out    
611          << "\n Outputs of energy deposition p    
612          << "\n OutputPerEvent.out" << G4endl;    
613                                                   
614   // remove all contents in fProcCounter, fCou    
615   fProcCounter.clear();                           
616   fParticleDataMap2.clear();                      
617                                                   
618   // restore default format                       
619   G4cout.precision(dfprec);                       
620 }                                                 
621                                                   
622 //....oooOO0OOooo........oooOO0OOooo........oo    
623