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Geant4/processes/optical/include/G4OpBoundaryProcess.hh

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Differences between /processes/optical/include/G4OpBoundaryProcess.hh (Version 11.3.0) and /processes/optical/include/G4OpBoundaryProcess.hh (Version 9.2.p3)


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 25 //                                                 25 //
 26 //                                                 26 //
                                                   >>  27 // $Id: G4OpBoundaryProcess.hh,v 1.18.2.1 2009/08/11 12:53:17 gcosmo Exp $
                                                   >>  28 // GEANT4 tag $Name: geant4-09-02-patch-03 $
 27 //                                                 29 //
 28 //                                             <<  30 // 
 29 //////////////////////////////////////////////     31 ////////////////////////////////////////////////////////////////////////
 30 // Optical Photon Boundary Process Class Defin     32 // Optical Photon Boundary Process Class Definition
 31 //////////////////////////////////////////////     33 ////////////////////////////////////////////////////////////////////////
 32 //                                                 34 //
 33 // File:        G4OpBoundaryProcess.hh             35 // File:        G4OpBoundaryProcess.hh
 34 // Description: Discrete Process -- reflection     36 // Description: Discrete Process -- reflection/refraction at
 35 //                                  optical in     37 //                                  optical interfaces
 36 // Version:     1.1                                38 // Version:     1.1
 37 // Created:     1997-06-18                         39 // Created:     1997-06-18
 38 // Modified:    2005-07-28 add G4ProcessType t     40 // Modified:    2005-07-28 add G4ProcessType to constructor
 39 //              1999-10-29 add method and clas     41 //              1999-10-29 add method and class descriptors
 40 //              1999-10-10 - Fill NewMomentum/ <<  42 //              1999-10-10 - Fill NewMomentum/NewPolarization in 
 41 //                           DoAbsorption. The     43 //                           DoAbsorption. These members need to be
 42 //                           filled since DoIt <<  44 //                           filled since DoIt calls 
 43 //                           aParticleChange.S     45 //                           aParticleChange.SetMomentumChange etc.
 44 //                           upon return (than     46 //                           upon return (thanks to: Clark McGrew)
 45 //              2006-11-04 - add capability of     47 //              2006-11-04 - add capability of calculating the reflectivity
 46 //                           off a metal surfa     48 //                           off a metal surface by way of a complex index
 47 //                           of refraction - T     49 //                           of refraction - Thanks to Sehwook Lee and John
 48 //                           Hauptman (Dept. o     50 //                           Hauptman (Dept. of Physics - Iowa State Univ.)
 49 //              2009-11-10 - add capability of << 
 50 //                           with Look-Up-Tabl << 
 51 //                           optical reflectan << 
 52 //                           treatments - Than << 
 53 //                           William Moses (La << 
 54 //              2013-06-01 - add the capabilit << 
 55 //                           of a dichronic fi << 
 56 //              2017-02-24 - add capability of << 
 57 //                           with Look-Up-Tabl << 
 58 //                                                 51 //
 59 // Author:      Peter Gumplinger                   52 // Author:      Peter Gumplinger
 60 //              adopted from work by Werner Ke     53 //              adopted from work by Werner Keil - April 2/96
                                                   >>  54 // mail:        gum@triumf.ca
 61 //                                                 55 //
 62 //////////////////////////////////////////////     56 ////////////////////////////////////////////////////////////////////////
 63                                                    57 
 64 #ifndef G4OpBoundaryProcess_h                      58 #ifndef G4OpBoundaryProcess_h
 65 #define G4OpBoundaryProcess_h 1                    59 #define G4OpBoundaryProcess_h 1
 66                                                    60 
 67 #include "G4OpticalPhoton.hh"                  <<  61 /////////////
 68 #include "G4OpticalSurface.hh"                 <<  62 // Includes
                                                   >>  63 /////////////
                                                   >>  64 
                                                   >>  65 #include "globals.hh"
                                                   >>  66 #include "templates.hh"
                                                   >>  67 #include "geomdefs.hh"
                                                   >>  68 #include "Randomize.hh"
                                                   >>  69 
 69 #include "G4RandomTools.hh"                        70 #include "G4RandomTools.hh"
                                                   >>  71 #include "G4RandomDirection.hh"
                                                   >>  72 
                                                   >>  73 #include "G4Step.hh"
 70 #include "G4VDiscreteProcess.hh"                   74 #include "G4VDiscreteProcess.hh"
                                                   >>  75 #include "G4DynamicParticle.hh"
                                                   >>  76 #include "G4Material.hh"
                                                   >>  77 #include "G4LogicalBorderSurface.hh"
                                                   >>  78 #include "G4LogicalSkinSurface.hh"
                                                   >>  79 #include "G4OpticalSurface.hh"
                                                   >>  80 #include "G4OpticalPhoton.hh"
                                                   >>  81 #include "G4TransportationManager.hh"
 71                                                    82 
 72 enum G4OpBoundaryProcessStatus                 <<  83 // Class Description:
 73 {                                              <<  84 // Discrete Process -- reflection/refraction at optical interfaces.
 74   Undefined,                                   <<  85 // Class inherits publicly from G4VDiscreteProcess.
 75   Transmission,                                <<  86 // Class Description - End:
 76   FresnelRefraction,                           <<  87 
 77   FresnelReflection,                           <<  88 /////////////////////
 78   TotalInternalReflection,                     <<  89 // Class Definition
 79   LambertianReflection,                        <<  90 /////////////////////
 80   LobeReflection,                              <<  91 
 81   SpikeReflection,                             <<  92 enum G4OpBoundaryProcessStatus {  Undefined,
 82   BackScattering,                              <<  93                                   FresnelRefraction, FresnelReflection,
 83   Absorption,                                  <<  94                                   TotalInternalReflection,
 84   Detection,                                   <<  95                                   LambertianReflection, LobeReflection,
 85   NotAtBoundary,                               <<  96                                   SpikeReflection, BackScattering,
 86   SameMaterial,                                <<  97                                   Absorption, Detection, NotAtBoundary,
 87   StepTooSmall,                                <<  98                                   SameMaterial, StepTooSmall, NoRINDEX };
 88   NoRINDEX,                                    << 
 89   PolishedLumirrorAirReflection,               << 
 90   PolishedLumirrorGlueReflection,              << 
 91   PolishedAirReflection,                       << 
 92   PolishedTeflonAirReflection,                 << 
 93   PolishedTiOAirReflection,                    << 
 94   PolishedTyvekAirReflection,                  << 
 95   PolishedVM2000AirReflection,                 << 
 96   PolishedVM2000GlueReflection,                << 
 97   EtchedLumirrorAirReflection,                 << 
 98   EtchedLumirrorGlueReflection,                << 
 99   EtchedAirReflection,                         << 
100   EtchedTeflonAirReflection,                   << 
101   EtchedTiOAirReflection,                      << 
102   EtchedTyvekAirReflection,                    << 
103   EtchedVM2000AirReflection,                   << 
104   EtchedVM2000GlueReflection,                  << 
105   GroundLumirrorAirReflection,                 << 
106   GroundLumirrorGlueReflection,                << 
107   GroundAirReflection,                         << 
108   GroundTeflonAirReflection,                   << 
109   GroundTiOAirReflection,                      << 
110   GroundTyvekAirReflection,                    << 
111   GroundVM2000AirReflection,                   << 
112   GroundVM2000GlueReflection,                  << 
113   Dichroic,                                    << 
114   CoatedDielectricReflection,                  << 
115   CoatedDielectricRefraction,                  << 
116   CoatedDielectricFrustratedTransmission       << 
117 };                                             << 
118                                                    99 
119 class G4OpBoundaryProcess : public G4VDiscrete    100 class G4OpBoundaryProcess : public G4VDiscreteProcess
120 {                                                 101 {
121  public:                                       << 
122   explicit G4OpBoundaryProcess(const G4String& << 
123                                G4ProcessType t << 
124   virtual ~G4OpBoundaryProcess();              << 
125                                                   102 
126   virtual G4bool IsApplicable(                 << 103 private:
127     const G4ParticleDefinition& aParticleType) << 104 
128   // Returns true -> 'is applicable' only for  << 105         //////////////
                                                   >> 106         // Operators
                                                   >> 107         //////////////
                                                   >> 108 
                                                   >> 109         // G4OpBoundaryProcess& operator=(const G4OpBoundaryProcess &right);
129                                                   110 
130   virtual G4double GetMeanFreePath(const G4Tra << 111         // G4OpBoundaryProcess(const G4OpBoundaryProcess &right);
131                                    G4ForceCond << 
132   // Returns infinity; i. e. the process does  << 
133   // 'Forced' condition for the DoIt to be inv << 
134   // at a boundary will any action be taken.   << 
135                                                   112 
136   G4VParticleChange* PostStepDoIt(const G4Trac << 113 public: // Without description
137                                   const G4Step << 
138   // This is the method implementing boundary  << 
139                                                   114 
140   virtual G4OpBoundaryProcessStatus GetStatus( << 115         ////////////////////////////////
141   // Returns the current status.               << 116         // Constructors and Destructor
                                                   >> 117         ////////////////////////////////
142                                                   118 
143   virtual void SetInvokeSD(G4bool);            << 119         G4OpBoundaryProcess(const G4String& processName = "OpBoundary",
144   // Set flag for call to InvokeSD method.     << 120                                      G4ProcessType type = fOptical);
145                                                   121 
146   virtual void PreparePhysicsTable(const G4Par << 122   ~G4OpBoundaryProcess();
147                                                   123 
148   virtual void Initialise();                   << 124   ////////////
                                                   >> 125   // Methods
                                                   >> 126         ////////////
149                                                   127 
150   void SetVerboseLevel(G4int);                 << 128 public: // With description
151                                                   129 
152  private:                                      << 130         G4bool IsApplicable(const G4ParticleDefinition& aParticleType);
153   G4OpBoundaryProcess(const G4OpBoundaryProces << 131         // Returns true -> 'is applicable' only for an optical photon.
154   G4OpBoundaryProcess& operator=(const G4OpBou << 
155                                                   132 
156   G4bool G4BooleanRand(const G4double prob) co << 133   G4double GetMeanFreePath(const G4Track& ,
                                                   >> 134          G4double ,
                                                   >> 135          G4ForceCondition* condition);
                                                   >> 136         // Returns infinity; i. e. the process does not limit the step,
                                                   >> 137         // but sets the 'Forced' condition for the DoIt to be invoked at
                                                   >> 138         // every step. However, only at a boundary will any action be
                                                   >> 139         // taken.
157                                                   140 
158   G4ThreeVector GetFacetNormal(const G4ThreeVe << 141   G4VParticleChange* PostStepDoIt(const G4Track& aTrack,
159                                const G4ThreeVe << 142                const G4Step&  aStep);
                                                   >> 143         // This is the method implementing boundary processes.
160                                                   144 
161   void DielectricMetal();                      << 145   G4OpticalSurfaceModel GetModel() const;
162   void DielectricDielectric();                 << 146         // Returns the optical surface mode.
163                                                   147 
164   void DielectricLUT();                        << 148         G4OpBoundaryProcessStatus GetStatus() const;
165   void DielectricLUTDAVIS();                   << 149         // Returns the current status.
166                                                   150 
167   void DielectricDichroic();                   << 151   G4double GetIncidentAngle();
168   void CoatedDielectricDielectric();           << 152         // Returns the incident angle of optical photon
169                                                   153 
170   void ChooseReflection();                     << 154   G4double GetReflectivity(G4double E1_perp,
171   void DoAbsorption();                         << 155                                  G4double E1_parl,
172   void DoReflection();                         << 156                                  G4double incidentangle,
                                                   >> 157                            G4double RealRindex,
                                                   >> 158                                  G4double ImaginaryRindex);
                                                   >> 159         // Returns the Reflectivity on a metalic surface
173                                                   160 
174   G4double GetIncidentAngle();                 << 161         void CalculateReflectivity(void);
175   // Returns the incident angle of optical pho << 
176                                                   162 
177   G4double GetReflectivity(G4double E1_perp, G << 163         void SetModel(G4OpticalSurfaceModel model);
178                            G4double incidentan << 164   // Set the optical surface model to be followed
179                            G4double ImaginaryR << 165         // (glisur || unified).
180   // Returns the Reflectivity on a metallic su << 
181                                                   166 
182   G4double GetReflectivityThroughThinLayer(G4d << 167 private:
183                                            G4d << 
184                                            G4d << 
185   // Returns the Reflectivity on a coated surf << 
186                                                   168 
187   void CalculateReflectivity();                << 169   G4bool G4BooleanRand(const G4double prob) const;
188                                                   170 
189   void BoundaryProcessVerbose() const;         << 171   G4ThreeVector GetFacetNormal(const G4ThreeVector& Momentum,
                                                   >> 172              const G4ThreeVector&  Normal) const;
190                                                   173 
191   // Invoke SD for post step point if the phot << 174   void DielectricMetal();
192   G4bool InvokeSD(const G4Step* step);         << 175   void DielectricDielectric();
193                                                   176 
194   G4ThreeVector fOldMomentum;                  << 177   void ChooseReflection();
195   G4ThreeVector fOldPolarization;              << 178   void DoAbsorption();
                                                   >> 179   void DoReflection();
196                                                   180 
197   G4ThreeVector fNewMomentum;                  << 181 private:
198   G4ThreeVector fNewPolarization;              << 
199                                                   182 
200   G4ThreeVector fGlobalNormal;                 << 183   G4double thePhotonMomentum;
201   G4ThreeVector fFacetNormal;                  << 
202                                                   184 
203   const G4Material* fMaterial1;                << 185   G4ThreeVector OldMomentum;
204   const G4Material* fMaterial2;                << 186   G4ThreeVector OldPolarization;
205                                                   187 
206   G4OpticalSurface* fOpticalSurface;           << 188   G4ThreeVector NewMomentum;
                                                   >> 189   G4ThreeVector NewPolarization;
207                                                   190 
208   G4MaterialPropertyVector* fRealRIndexMPV;    << 191   G4ThreeVector theGlobalNormal;
209   G4MaterialPropertyVector* fImagRIndexMPV;    << 192   G4ThreeVector theFacetNormal;
210   G4Physics2DVector* fDichroicVector;          << 
211                                                   193 
212   G4double fPhotonMomentum;                    << 194   G4Material* Material1;
213   G4double fRindex1;                           << 195   G4Material* Material2;
214   G4double fRindex2;                           << 
215                                                   196 
216   G4double fSint1;                             << 197   G4OpticalSurface* OpticalSurface;
217                                                   198 
218   G4double fReflectivity;                      << 199         G4MaterialPropertyVector* PropertyPointer;
219   G4double fEfficiency;                        << 200         G4MaterialPropertyVector* PropertyPointer1;
220   G4double fTransmittance;                     << 201         G4MaterialPropertyVector* PropertyPointer2;
221   G4double fSurfaceRoughness;                  << 
222                                                   202 
223   G4double fProb_sl, fProb_ss, fProb_bs;       << 203   G4double Rindex1;
224   G4double fCarTolerance;                      << 204   G4double Rindex2;
225                                                   205 
226   // Used by CoatedDielectricDielectric()      << 206   G4double cost1, cost2, sint1, sint2;
227   G4double fCoatedRindex, fCoatedThickness;    << 
228                                                   207 
229   G4OpBoundaryProcessStatus fStatus;           << 208   G4OpBoundaryProcessStatus theStatus;
230   G4OpticalSurfaceModel fModel;                << 
231   G4OpticalSurfaceFinish fFinish;              << 
232                                                   209 
233   G4int f_iTE, f_iTM;                          << 210   G4OpticalSurfaceModel theModel;
234                                                   211 
235   G4int fNumSmallStepWarnings = 0; // number o << 212   G4OpticalSurfaceFinish theFinish;
236   G4int fNumBdryTypeWarnings = 0;  // number o << 
237                                                   213 
238   size_t idx_dichroicX      = 0;               << 214   G4double theReflectivity;
239   size_t idx_dichroicY      = 0;               << 215   G4double theEfficiency;
240   size_t idx_rindex1        = 0;               << 216   G4double prob_sl, prob_ss, prob_bs;
241   size_t idx_rindex_surface = 0;               << 
242   size_t idx_reflect        = 0;               << 
243   size_t idx_eff            = 0;               << 
244   size_t idx_trans          = 0;               << 
245   size_t idx_lobe           = 0;               << 
246   size_t idx_spike          = 0;               << 
247   size_t idx_back           = 0;               << 
248   size_t idx_rindex2        = 0;               << 
249   size_t idx_groupvel       = 0;               << 
250   size_t idx_rrindex        = 0;               << 
251   size_t idx_irindex        = 0;               << 
252   size_t idx_coatedrindex   = 0;               << 
253                                                   217 
254   // Used by CoatedDielectricDielectric()      << 218         G4int iTE, iTM;
255   G4bool fCoatedFrustratedTransmission = true; << 
256                                                   219 
257   G4bool fInvokeSD;                            << 220         G4double kCarTolerance;
258 };                                                221 };
259                                                   222 
260 ////////////////////                              223 ////////////////////
261 // Inline methods                                 224 // Inline methods
262 ////////////////////                              225 ////////////////////
263                                                   226 
264 inline G4bool G4OpBoundaryProcess::G4BooleanRa << 227 inline
                                                   >> 228 G4bool G4OpBoundaryProcess::G4BooleanRand(const G4double prob) const
265 {                                                 229 {
266   // Returns a random boolean variable with th << 230   /* Returns a random boolean variable with the specified probability */
                                                   >> 231 
267   return (G4UniformRand() < prob);                232   return (G4UniformRand() < prob);
268 }                                                 233 }
269                                                   234 
270 inline G4bool G4OpBoundaryProcess::IsApplicabl << 235 inline
271   const G4ParticleDefinition& aParticleType)   << 236 G4bool G4OpBoundaryProcess::IsApplicable(const G4ParticleDefinition& 
                                                   >> 237                          aParticleType)
                                                   >> 238 {
                                                   >> 239    return ( &aParticleType == G4OpticalPhoton::OpticalPhoton() );
                                                   >> 240 }
                                                   >> 241 
                                                   >> 242 inline
                                                   >> 243 G4OpticalSurfaceModel G4OpBoundaryProcess::GetModel() const
                                                   >> 244 {
                                                   >> 245    return theModel;
                                                   >> 246 }
                                                   >> 247 
                                                   >> 248 inline
                                                   >> 249 G4OpBoundaryProcessStatus G4OpBoundaryProcess::GetStatus() const
272 {                                                 250 {
273   return (&aParticleType == G4OpticalPhoton::O << 251    return theStatus;
274 }                                                 252 }
275                                                   253 
276 inline G4OpBoundaryProcessStatus G4OpBoundaryP << 254 inline
                                                   >> 255 void G4OpBoundaryProcess::SetModel(G4OpticalSurfaceModel model)
277 {                                                 256 {
278   return fStatus;                              << 257    theModel = model;
279 }                                                 258 }
280                                                   259 
281 inline void G4OpBoundaryProcess::ChooseReflect << 260 inline
                                                   >> 261 void G4OpBoundaryProcess::ChooseReflection()
282 {                                                 262 {
283   G4double rand = G4UniformRand();             << 263                  G4double rand = G4UniformRand();
284   if(rand < fProb_ss)                          << 264                  if ( rand >= 0.0 && rand < prob_ss ) {
285   {                                            << 265                     theStatus = SpikeReflection;
286     fStatus      = SpikeReflection;            << 266                     theFacetNormal = theGlobalNormal;
287     fFacetNormal = fGlobalNormal;              << 267                  }
288   }                                            << 268                  else if ( rand >= prob_ss &&
289   else if(rand < fProb_ss + fProb_sl)          << 269                            rand <= prob_ss+prob_sl) {
290   {                                            << 270                     theStatus = LobeReflection;
291     fStatus = LobeReflection;                  << 271                  }
292   }                                            << 272                  else if ( rand > prob_ss+prob_sl &&
293   else if(rand < fProb_ss + fProb_sl + fProb_b << 273                            rand < prob_ss+prob_sl+prob_bs ) {
294   {                                            << 274                     theStatus = BackScattering;
295     fStatus = BackScattering;                  << 275                  }
296   }                                            << 276                  else {
297   else                                         << 277                     theStatus = LambertianReflection;
298   {                                            << 278                  }
299     fStatus = LambertianReflection;            << 
300   }                                            << 
301 }                                                 279 }
302                                                   280 
303 inline void G4OpBoundaryProcess::DoAbsorption( << 281 inline
                                                   >> 282 void G4OpBoundaryProcess::DoAbsorption()
304 {                                                 283 {
305   fStatus = Absorption;                        << 284               theStatus = Absorption;
306                                                   285 
307   if(G4BooleanRand(fEfficiency))               << 286               if ( G4BooleanRand(theEfficiency) ) {
308   {                                            << 287     
309     // EnergyDeposited =/= 0 means: photon has << 288                  // EnergyDeposited =/= 0 means: photon has been detected
310     fStatus = Detection;                       << 289                  theStatus = Detection;
311     aParticleChange.ProposeLocalEnergyDeposit( << 290                  aParticleChange.ProposeLocalEnergyDeposit(thePhotonMomentum);
312   }                                            << 291               }
313   else                                         << 292               else {
314   {                                            << 293                  aParticleChange.ProposeLocalEnergyDeposit(0.0);
315     aParticleChange.ProposeLocalEnergyDeposit( << 294               }
316   }                                            << 
317                                                   295 
318   fNewMomentum     = fOldMomentum;             << 296               NewMomentum = OldMomentum;
319   fNewPolarization = fOldPolarization;         << 297               NewPolarization = OldPolarization;
320                                                   298 
321   aParticleChange.ProposeTrackStatus(fStopAndK << 299 //              aParticleChange.ProposeEnergy(0.0);
                                                   >> 300               aParticleChange.ProposeTrackStatus(fStopAndKill);
322 }                                                 301 }
323                                                   302 
324 inline void G4OpBoundaryProcess::DoReflection( << 303 inline
                                                   >> 304 void G4OpBoundaryProcess::DoReflection()
325 {                                                 305 {
326   if(fStatus == LambertianReflection)          << 306         if ( theStatus == LambertianReflection ) {
327   {                                            << 307 
328     fNewMomentum = G4LambertianRand(fGlobalNor << 308           NewMomentum = G4LambertianRand(theGlobalNormal);
329     fFacetNormal = (fNewMomentum - fOldMomentu << 309           theFacetNormal = (NewMomentum - OldMomentum).unit();
330   }                                            << 310 
331   else if(fFinish == ground)                   << 311         }
332   {                                            << 312         else if ( theFinish == ground ) {
333     fStatus = LobeReflection;                  << 313 
334     if(!fRealRIndexMPV || !fImagRIndexMPV)     << 314     theStatus = LobeReflection;
335     {                                          << 315           if ( PropertyPointer1 && PropertyPointer2 ){
336       fFacetNormal = GetFacetNormal(fOldMoment << 316           } else {
337     }                                          << 317              theFacetNormal =
338     // else                                    << 318                  GetFacetNormal(OldMomentum,theGlobalNormal);
339       // complex ref. index to be implemented  << 319           }
340     fNewMomentum =                             << 320           G4double PdotN = OldMomentum * theFacetNormal;
341       fOldMomentum - (2. * fOldMomentum * fFac << 321           NewMomentum = OldMomentum - (2.*PdotN)*theFacetNormal;
342   }                                            << 322 
343   else                                         << 323         }
344   {                                            << 324         else {
345     fStatus      = SpikeReflection;            << 325 
346     fFacetNormal = fGlobalNormal;              << 326           theStatus = SpikeReflection;
347     fNewMomentum =                             << 327           theFacetNormal = theGlobalNormal;
348       fOldMomentum - (2. * fOldMomentum * fFac << 328           G4double PdotN = OldMomentum * theFacetNormal;
349   }                                            << 329           NewMomentum = OldMomentum - (2.*PdotN)*theFacetNormal;
350   fNewPolarization =                           << 330 
351     -fOldPolarization + (2. * fOldPolarization << 331         }
                                                   >> 332         G4double EdotN = OldPolarization * theFacetNormal;
                                                   >> 333         NewPolarization = -OldPolarization + (2.*EdotN)*theFacetNormal;
352 }                                                 334 }
353                                                   335 
354 #endif /* G4OpBoundaryProcess_h */                336 #endif /* G4OpBoundaryProcess_h */
355                                                   337