Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4RKPropagation Class Reference

#include <G4RKPropagation.hh>

+ Inheritance diagram for G4RKPropagation:

Public Member Functions

 G4RKPropagation ()
 
virtual ~G4RKPropagation ()
 
virtual void Init (G4V3DNucleus *nucleus)
 
virtual void Transport (G4KineticTrackVector &theActive, const G4KineticTrackVector &theSpectators, G4double theTimeStep)
 
G4bool GetSphereIntersectionTimes (const G4KineticTrack *track, G4double &t1, G4double &t2)
 
G4ThreeVector GetMomentumTransfer () const
 
G4double GetBarrier (G4int encoding)
 
G4double GetField (G4int encoding, G4ThreeVector pos)
 
- Public Member Functions inherited from G4VFieldPropagation
 G4VFieldPropagation ()
 
virtual ~G4VFieldPropagation ()
 
virtual void Init (G4V3DNucleus *theNucleus)=0
 
virtual void Transport (G4KineticTrackVector &theActive, const G4KineticTrackVector &theSpectators, G4double theTimeStep)=0
 
virtual G4ThreeVector GetMomentumTransfer () const =0
 

Detailed Description

Definition at line 38 of file G4RKPropagation.hh.

Constructor & Destructor Documentation

◆ G4RKPropagation()

G4RKPropagation::G4RKPropagation ( )

Definition at line 80 of file G4RKPropagation.cc.

80 :
81theOuterRadius(0), theNucleus(0),
82theFieldMap(0), theEquationMap(0),
83theField(0)
84{ }

◆ ~G4RKPropagation()

G4RKPropagation::~G4RKPropagation ( )
virtual

Definition at line 87 of file G4RKPropagation.cc.

88{
89 // free theFieldMap memory
90 if(theFieldMap) delete_FieldsAndMap(theFieldMap);
91
92 // free theEquationMap memory
93 if(theEquationMap) delete_EquationsAndMap(theEquationMap);
94
95 if (theField) delete theField;
96}

Member Function Documentation

◆ GetBarrier()

G4double G4RKPropagation::GetBarrier ( G4int  encoding)
inline

Definition at line 84 of file G4RKPropagation.hh.

85 {
86 std::map <G4int, G4VNuclearField *, std::less<G4int> >::iterator iter;
87 iter = theFieldMap->find(encoding);
88 if(iter == theFieldMap->end()) return 0;
89 return (*theFieldMap)[encoding]->GetBarrier();
90 }
#define encoding
Definition: xmlparse.cc:605

◆ GetField()

G4double G4RKPropagation::GetField ( G4int  encoding,
G4ThreeVector  pos 
)
inline

Definition at line 92 of file G4RKPropagation.hh.

93 {
94 std::map <G4int, G4VNuclearField *, std::less<G4int> >::iterator iter;
95 iter = theFieldMap->find(encoding);
96 if(iter == theFieldMap->end()) return 0;
97 return (*theFieldMap)[encoding]->GetField(pos);
98 }

◆ GetMomentumTransfer()

G4ThreeVector G4RKPropagation::GetMomentumTransfer ( ) const
virtual

Implements G4VFieldPropagation.

Definition at line 471 of file G4RKPropagation.cc.

473{
474 return theMomentumTranfer;
475}

◆ GetSphereIntersectionTimes()

G4bool G4RKPropagation::GetSphereIntersectionTimes ( const G4KineticTrack track,
G4double t1,
G4double t2 
)

Definition at line 606 of file G4RKPropagation.cc.

608{
609 G4double radius = theOuterRadius + 3*fermi; // "safety" of 3 fermi
610 G4ThreeVector speed = kt->GetTrackingMomentum().vect()/kt->GetTrackingMomentum().e(); // bost vector
611 G4double scalarProd = kt->GetPosition().dot(speed);
612 G4double speedMag2 = speed.mag2();
613 G4double sqrtArg = scalarProd*scalarProd -
614 speedMag2*(kt->GetPosition().mag2()-radius*radius);
615 if(sqrtArg <= 0.) // particle will not intersect the sphere
616 {
617 return false;
618 }
619 t1 = (-scalarProd - std::sqrt(sqrtArg))/speedMag2/c_light;
620 t2 = (-scalarProd + std::sqrt(sqrtArg))/speedMag2/c_light;
621 return true;
622}
double G4double
Definition: G4Types.hh:83
double mag2() const
double dot(const Hep3Vector &) const

Referenced by Transport().

◆ Init()

void G4RKPropagation::Init ( G4V3DNucleus nucleus)
virtual

Implements G4VFieldPropagation.

Definition at line 99 of file G4RKPropagation.cc.

101{
102
103 // free theFieldMap memory
104 if(theFieldMap) delete_FieldsAndMap(theFieldMap);
105
106 // free theEquationMap memory
107 if(theEquationMap) delete_EquationsAndMap(theEquationMap);
108
109 if (theField) delete theField;
110
111 // Initialize the nuclear field map.
112 theNucleus = nucleus;
113 theOuterRadius = theNucleus->GetOuterRadius();
114
115 theFieldMap = new std::map <G4int, G4VNuclearField*, std::less<G4int> >;
116
117 (*theFieldMap)[G4Proton::Proton()->GetPDGEncoding()] = new G4ProtonField(theNucleus);
118 (*theFieldMap)[G4Neutron::Neutron()->GetPDGEncoding()] = new G4NeutronField(theNucleus);
119 (*theFieldMap)[G4AntiProton::AntiProton()->GetPDGEncoding()] = new G4AntiProtonField(theNucleus);
120 (*theFieldMap)[G4KaonPlus::KaonPlus()->GetPDGEncoding()] = new G4KaonPlusField(theNucleus);
121 (*theFieldMap)[G4KaonMinus::KaonMinus()->GetPDGEncoding()] = new G4KaonMinusField(theNucleus);
122 (*theFieldMap)[G4KaonZero::KaonZero()->GetPDGEncoding()] = new G4KaonZeroField(theNucleus);
123 (*theFieldMap)[G4PionPlus::PionPlus()->GetPDGEncoding()] = new G4PionPlusField(theNucleus);
124 (*theFieldMap)[G4PionMinus::PionMinus()->GetPDGEncoding()] = new G4PionMinusField(theNucleus);
125 (*theFieldMap)[G4PionZero::PionZero()->GetPDGEncoding()] = new G4PionZeroField(theNucleus);
126 (*theFieldMap)[G4SigmaPlus::SigmaPlus()->GetPDGEncoding()] = new G4SigmaPlusField(theNucleus);
127 (*theFieldMap)[G4SigmaMinus::SigmaMinus()->GetPDGEncoding()] = new G4SigmaMinusField(theNucleus);
128 (*theFieldMap)[G4SigmaZero::SigmaZero()->GetPDGEncoding()] = new G4SigmaZeroField(theNucleus);
129
130 theEquationMap = new std::map <G4int, G4Mag_EqRhs*, std::less<G4int> >;
131
132 // theField needed by the design of G4Mag_eqRhs
133 theField = new G4KM_DummyField; //Field not needed for integration
134 G4KM_OpticalEqRhs * opticalEq;
135 G4KM_NucleonEqRhs * nucleonEq;
136 G4double mass;
137 G4double opticalCoeff;
138
139 nucleonEq = new G4KM_NucleonEqRhs(theField, theNucleus);
140 mass = G4Proton::Proton()->GetPDGMass();
141 nucleonEq->SetMass(mass);
142 (*theEquationMap)[G4Proton::Proton()->GetPDGEncoding()] = nucleonEq;
143
144 nucleonEq = new G4KM_NucleonEqRhs(theField, theNucleus);
145 mass = G4Neutron::Neutron()->GetPDGMass();
146 nucleonEq->SetMass(mass);
147 (*theEquationMap)[G4Neutron::Neutron()->GetPDGEncoding()] = nucleonEq;
148
149 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
151 opticalCoeff =
152 (*theFieldMap)[G4AntiProton::AntiProton()->GetPDGEncoding()]->GetCoeff();
153 opticalEq->SetFactor(mass,opticalCoeff);
154 (*theEquationMap)[G4AntiProton::AntiProton()->GetPDGEncoding()] = opticalEq;
155
156 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
158 opticalCoeff =
159 (*theFieldMap)[G4KaonPlus::KaonPlus()->GetPDGEncoding()]->GetCoeff();
160 opticalEq->SetFactor(mass,opticalCoeff);
161 (*theEquationMap)[G4KaonPlus::KaonPlus()->GetPDGEncoding()] = opticalEq;
162
163 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
165 opticalCoeff =
166 (*theFieldMap)[G4KaonMinus::KaonMinus()->GetPDGEncoding()]->GetCoeff();
167 opticalEq->SetFactor(mass,opticalCoeff);
168 (*theEquationMap)[G4KaonMinus::KaonMinus()->GetPDGEncoding()] = opticalEq;
169
170 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
172 opticalCoeff =
173 (*theFieldMap)[G4KaonZero::KaonZero()->GetPDGEncoding()]->GetCoeff();
174 opticalEq->SetFactor(mass,opticalCoeff);
175 (*theEquationMap)[G4KaonZero::KaonZero()->GetPDGEncoding()] = opticalEq;
176
177 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
179 opticalCoeff =
180 (*theFieldMap)[G4PionPlus::PionPlus()->GetPDGEncoding()]->GetCoeff();
181 opticalEq->SetFactor(mass,opticalCoeff);
182 (*theEquationMap)[G4PionPlus::PionPlus()->GetPDGEncoding()] = opticalEq;
183
184 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
186 opticalCoeff =
187 (*theFieldMap)[G4PionMinus::PionMinus()->GetPDGEncoding()]->GetCoeff();
188 opticalEq->SetFactor(mass,opticalCoeff);
189 (*theEquationMap)[G4PionMinus::PionMinus()->GetPDGEncoding()] = opticalEq;
190
191 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
193 opticalCoeff =
194 (*theFieldMap)[G4PionZero::PionZero()->GetPDGEncoding()]->GetCoeff();
195 opticalEq->SetFactor(mass,opticalCoeff);
196 (*theEquationMap)[G4PionZero::PionZero()->GetPDGEncoding()] = opticalEq;
197
198 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
200 opticalCoeff =
201 (*theFieldMap)[G4SigmaPlus::SigmaPlus()->GetPDGEncoding()]->GetCoeff();
202 opticalEq->SetFactor(mass,opticalCoeff);
203 (*theEquationMap)[G4SigmaPlus::SigmaPlus()->GetPDGEncoding()] = opticalEq;
204
205 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
207 opticalCoeff =
208 (*theFieldMap)[G4SigmaMinus::SigmaMinus()->GetPDGEncoding()]->GetCoeff();
209 opticalEq->SetFactor(mass,opticalCoeff);
210 (*theEquationMap)[G4SigmaMinus::SigmaMinus()->GetPDGEncoding()] = opticalEq;
211
212 opticalEq = new G4KM_OpticalEqRhs(theField, theNucleus);
214 opticalCoeff =
215 (*theFieldMap)[G4SigmaZero::SigmaZero()->GetPDGEncoding()]->GetCoeff();
216 opticalEq->SetFactor(mass,opticalCoeff);
217 (*theEquationMap)[G4SigmaZero::SigmaZero()->GetPDGEncoding()] = opticalEq;
218}
static G4AntiProton * AntiProton()
Definition: G4AntiProton.cc:92
void SetMass(G4double aMass)
void SetFactor(G4double mass, G4double opticalParameter)
static G4KaonMinus * KaonMinus()
Definition: G4KaonMinus.cc:112
static G4KaonPlus * KaonPlus()
Definition: G4KaonPlus.cc:112
static G4KaonZero * KaonZero()
Definition: G4KaonZero.cc:103
static G4Neutron * Neutron()
Definition: G4Neutron.cc:103
static G4PionMinus * PionMinus()
Definition: G4PionMinus.cc:97
static G4PionPlus * PionPlus()
Definition: G4PionPlus.cc:97
static G4PionZero * PionZero()
Definition: G4PionZero.cc:107
static G4Proton * Proton()
Definition: G4Proton.cc:92
static G4SigmaMinus * SigmaMinus()
static G4SigmaPlus * SigmaPlus()
Definition: G4SigmaPlus.cc:107
static G4SigmaZero * SigmaZero()
Definition: G4SigmaZero.cc:101
virtual G4double GetOuterRadius()=0

◆ Transport()

void G4RKPropagation::Transport ( G4KineticTrackVector theActive,
const G4KineticTrackVector theSpectators,
G4double  theTimeStep 
)
virtual

Implements G4VFieldPropagation.

Definition at line 223 of file G4RKPropagation.cc.

227{
228 // reset momentum transfer to field
229 theMomentumTranfer=G4ThreeVector(0,0,0);
230
231 // Loop over tracks
232
233 std::vector<G4KineticTrack *>::iterator i;
234 for(i = active.begin(); i != active.end(); ++i)
235 {
236 G4double currTimeStep = timeStep;
237 G4KineticTrack * kt = *i;
239
240 std::map <G4int, G4VNuclearField*, std::less<G4int> >::iterator fieldIter= theFieldMap->find(encoding);
241
242 G4VNuclearField* currentField=0;
243 if ( fieldIter != theFieldMap->end() ) currentField=fieldIter->second;
244
245 // debug
246 // if ( timeStep > 1e30 ) {
247 // G4cout << " Name :" << kt->GetDefinition()->GetParticleName() << G4endl;
248 // }
249
250 // Get the time of intersections with the nucleus surface.
251 G4double t_enter, t_leave;
252 // if the particle does not intersecate with the nucleus go to next particle
253 if(!GetSphereIntersectionTimes(kt, t_enter, t_leave))
254 {
256 continue;
257 }
258
259
260#ifdef debug_1_RKPropagation
261 G4cout <<" kt,timeStep, Intersection times tenter, tleave "
262 <<kt<< " / state= " <<kt->GetState() <<" / " <<" "<< currTimeStep << " / " << t_enter << " / " << t_leave <<G4endl;
263#endif
264
265 // if the particle is already outside nucleus go to next @@GF should never happen? check!
266 // does happen for particles added as late....
267 // if(t_leave < 0 )
268 // {
269 // throw G4HadronicException(__FILE__, __LINE__, "G4RKPropagation:: Attempt to track particle past a nucleus");
270 // continue;
271 // }
272
273 // Apply a straight line propagation for particle types
274 // not included in the model
275 if( ! currentField )
276 {
277 if(currTimeStep == DBL_MAX)currTimeStep = t_leave*1.05;
278 FreeTransport(kt, currTimeStep);
279 if ( currTimeStep >= t_leave )
280 {
281 if ( kt->GetState() == G4KineticTrack::inside )
283 else
285 } else if (kt->GetState() == G4KineticTrack::outside && currTimeStep >= t_enter ){
287 }
288
289 continue;
290 }
291
292 if(t_enter > 0) // the particle is out. Transport free to the surface
293 {
294 if(t_enter > currTimeStep) // the particle won't enter the nucleus
295 {
296 FreeTransport(kt, currTimeStep);
297 continue;
298 }
299 else
300 {
301 FreeTransport(kt, t_enter); // go to surface
302 currTimeStep -= t_enter;
303 t_leave -= t_enter; // time left to leave nucleus
304 // on the surface the particle loose the barrier energy
305 // G4double newE = mom.e()-(*theFieldMap)[encoding]->GetBarrier();
306 // GetField = Barrier + FermiPotential
307 G4double newE = kt->GetTrackingMomentum().e()-currentField->GetField(kt->GetPosition());
308
309 if(newE <= kt->GetActualMass()) // the particle cannot enter the nucleus
310 {
311 // FixMe: should be "pushed back?"
312 // for the moment take it past the nucleus, so we'll not worry next time..
313 FreeTransport(kt, 1.1*t_leave); // take past nucleus
315 // G4cout << "G4RKPropagation: Warning particle cannot enter Nucleus :" << G4endl;
316 // G4cout << " enter nucleus, E out/in: " << kt->GetTrackingMomentum().e() << " / " << newE <<G4endl;
317 // G4cout << " the Field "<< currentField->GetField(kt->GetPosition()) << " "<< kt->GetPosition()<<G4endl;
318 // G4cout << " the particle "<<kt->GetDefinition()->GetParticleName()<<G4endl;
319 continue;
320 }
321 //
322 G4double newP = std::sqrt(newE*newE- sqr(kt->GetActualMass()));
323 G4LorentzVector new4Mom(newP*kt->GetTrackingMomentum().vect().unit(), newE);
324 G4ThreeVector transfer(kt->GetTrackingMomentum().vect()-new4Mom.vect());
325 G4ThreeVector boost= transfer / std::sqrt(transfer.mag2() + sqr(theNucleus->GetMass()));
326 new4Mom*=G4LorentzRotation(boost);
327 kt->SetTrackingMomentum(new4Mom);
329
330 /*
331 G4cout <<" Enter Nucleus - E/Field/Sum: " <<kt->GetTrackingMomentum().e() << " / "
332 << (*theFieldMap)[encoding]->GetField(kt->GetPosition()) << " / "
333 << kt->GetTrackingMomentum().e()-currentField->GetField(kt->GetPosition())
334 << G4endl
335 << " Barrier / field just inside nucleus (0.9999*kt->GetPosition())"
336 << (*theFieldMap)[encoding]->GetBarrier() << " / "
337 << (*theFieldMap)[encoding]->GetField(0.9999*kt->GetPosition())
338 << G4endl;
339 */
340 }
341 }
342
343 // FixMe: should I add a control on theCutOnP here?
344 // Transport the particle into the nucleus
345 // G4cerr << "RKPropagation t_leave, curTimeStep " <<t_leave << " " <<currTimeStep<<G4endl;
346 G4bool is_exiting=false;
347 if(currTimeStep > t_leave) // particle will exit from the nucleus
348 {
349 currTimeStep = t_leave;
350 is_exiting=true;
351 }
352
353#ifdef debug_1_RKPropagation
354 G4cerr << "RKPropagation is_exiting?, t_leave, curTimeStep " <<is_exiting<<" "<<t_leave << " " <<currTimeStep<<G4endl;
355 G4cout << "RKPropagation Ekin, field, projectile potential, p "
356 << kt->GetTrackingMomentum().e() - kt->GetTrackingMomentum().mag() << " "
357 << kt->GetPosition()<<" "
358 << G4endl << currentField->GetField(kt->GetPosition()) << " "
360 << kt->GetTrackingMomentum()
361 << G4endl;
362#endif
363
365 G4ThreeVector posold=kt->GetPosition();
366
367 // if (currentField->GetField(kt->GetPosition()) > kt->GetProjectilePotential() ||
368 if (currTimeStep > 0 &&
369 ! FieldTransport(kt, currTimeStep)) {
370 FreeTransport(kt,currTimeStep);
371 }
372
373#ifdef debug_1_RKPropagation
374 G4cout << "RKPropagation Ekin, field, p "
375 << kt->GetTrackingMomentum().e() - kt->GetTrackingMomentum().mag() << " "
376 << G4endl << currentField->GetField(kt->GetPosition())<< G4endl
377 << kt->GetTrackingMomentum()
378 << G4endl
379 << "delta p " << momold-kt->GetTrackingMomentum() << G4endl
380 << "del pos " << posold-kt->GetPosition()
381 << G4endl;
382#endif
383
384 // complete the transport
385 // FixMe: in some cases there could be a significant
386 // part to do still in the nucleus, or we stepped to far... depending on
387 // slope of potential
388 G4double t_in=-1, t_out=0; // set onto boundary.
389
390 // should go out, or are already out by a too long step..
391 if(is_exiting ||
392 (GetSphereIntersectionTimes(kt, t_in, t_out) &&t_in<0 && t_out<=0 )) // particle is exiting
393 {
394 if(t_in < 0 && t_out >= 0) //still inside, transport safely out.
395 {
396 // transport free to a position that is surely out of the nucleus, to avoid
397 // a new transportation and a new adding the barrier next loop.
398 G4ThreeVector savePos = kt->GetPosition();
399 FreeTransport(kt, t_out);
400 // and evaluate the right the energy
401 G4double newE=kt->GetTrackingMomentum().e();
402
403 // G4cout << " V pos/savePos << "
404 // << (*theFieldMap)[encoding]->GetField(kt->GetPosition())<< " / "
405 // << (*theFieldMap)[encoding]->GetField(savePos)
406 // << G4endl;
407
408 if ( std::abs(currentField->GetField(savePos)) > 0. &&
409 std::abs(currentField->GetField(kt->GetPosition())) > 0.)
410 { // FixMe GF: savePos/pos may be out of nucleus, where GetField(..)=0
411 // This wrongly adds or subtracts the Barrier here while
412 // this is done later.
413 newE += currentField->GetField(savePos)
414 - currentField->GetField(kt->GetPosition());
415 }
416
417 // G4cout << " go border nucleus, E in/border: " << kt->GetTrackingMomentum() << " / " << newE <<G4endl;
418
419 if(newE < kt->GetActualMass())
420 {
421#ifdef debug_1_RKPropagation
422 G4cout << "RKPropagation-Transport: problem with particle exiting - ignored" << G4endl;
423 G4cout << " cannot leave nucleus, E in/out: " << kt->GetTrackingMomentum() << " / " << newE <<G4endl;
424#endif
425 if (kt->GetDefinition() == G4Proton::Proton() ||
426 kt->GetDefinition() == G4Neutron::Neutron() ) {
428 } else {
429 kt->SetState(G4KineticTrack::gone_out); //@@GF tofix
430 }
431 continue; // the particle cannot exit the nucleus
432 }
433 G4double newP = std::sqrt(newE*newE- sqr(kt->GetActualMass()));
434 G4LorentzVector new4Mom(newP*kt->GetTrackingMomentum().vect().unit(), newE);
435 G4ThreeVector transfer(kt->GetTrackingMomentum().vect()-new4Mom.vect());
436 G4ThreeVector boost= transfer / std::sqrt(transfer.mag2() + sqr(theNucleus->GetMass()));
437 new4Mom*=G4LorentzRotation(boost);
438 kt->SetTrackingMomentum(new4Mom);
439 }
440 // add the potential barrier
441 // FixMe the Coulomb field is not parallel to mom, this is simple approximation
442 G4double newE = kt->GetTrackingMomentum().e()+currentField->GetField(kt->GetPosition());
443 if(newE < kt->GetActualMass())
444 { // the particle cannot exit the nucleus @@@ GF check.
445#ifdef debug_1_RKPropagation
446 G4cout << " cannot leave nucleus, E in/out: " << kt->GetTrackingMomentum() << " / " << newE <<G4endl;
447#endif
448 if (kt->GetDefinition() == G4Proton::Proton() ||
449 kt->GetDefinition() == G4Neutron::Neutron() ) {
451 } else {
452 kt->SetState(G4KineticTrack::gone_out); //@@GF tofix
453 }
454 continue;
455 }
456 G4double newP = std::sqrt(newE*newE- sqr(kt->GetActualMass()));
457 G4LorentzVector new4Mom(newP*kt->GetTrackingMomentum().vect().unit(), newE);
458 G4ThreeVector transfer(kt->GetTrackingMomentum().vect()-new4Mom.vect());
459 G4ThreeVector boost= transfer / std::sqrt(transfer.mag2() + sqr(theNucleus->GetMass()));
460 new4Mom*=G4LorentzRotation(boost);
461 kt->SetTrackingMomentum(new4Mom);
463 }
464
465 }
466
467}
CLHEP::HepLorentzRotation G4LorentzRotation
CLHEP::Hep3Vector G4ThreeVector
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
G4GLOB_DLL std::ostream G4cerr
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
Hep3Vector unit() const
Hep3Vector vect() const
CascadeState SetState(const CascadeState new_state)
G4double GetProjectilePotential() const
CascadeState GetState() const
const G4ThreeVector & GetPosition() const
void SetTrackingMomentum(const G4LorentzVector &a4Momentum)
const G4ParticleDefinition * GetDefinition() const
const G4LorentzVector & GetTrackingMomentum() const
G4double GetActualMass() const
G4bool GetSphereIntersectionTimes(const G4KineticTrack *track, G4double &t1, G4double &t2)
virtual G4double GetMass()=0
virtual G4double GetField(const G4ThreeVector &aPosition)=0
T sqr(const T &x)
Definition: templates.hh:128
#define DBL_MAX
Definition: templates.hh:62

The documentation for this class was generated from the following files: