Geant4 9.6.0
Toolkit for the simulation of the passage of particles through matter
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G4RPGInelastic.cc
Go to the documentation of this file.
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26// $Id$
27//
28
29#include "G4RPGInelastic.hh"
30#include "Randomize.hh"
32#include "G4SystemOfUnits.hh"
35#include "G4RPGTwoBody.hh"
36
37
39 : G4HadronicInteraction(modelName)
40{
41 cache = 0.0;
60
61 G4cout << " **************************************************** " << G4endl;
62 G4cout << " * The RPG model is currently under development and * " << G4endl;
63 G4cout << " * should not be used. * " << G4endl;
64 G4cout << " **************************************************** " << G4endl;
65}
66
67
69 G4int n, G4double b, G4double c)
70{
71 const G4double expxu = 82.; // upper bound for arg. of exp
72 const G4double expxl = -expxu; // lower bound for arg. of exp
73 G4double npf = 0.0;
74 G4double nmf = 0.0;
75 G4double nzf = 0.0;
76 G4int i;
77 for( i=2; i<=np; i++ )npf += std::log((double)i);
78 for( i=2; i<=nneg; i++ )nmf += std::log((double)i);
79 for( i=2; i<=nz; i++ )nzf += std::log((double)i);
80 G4double r;
81 r = std::min( expxu, std::max( expxl, -(np-nneg+nz+b)*(np-nneg+nz+b)/(2*c*c*n*n)-npf-nmf-nzf ) );
82 return std::exp(r);
83}
84
85
87{
88 G4int j = std::min(n,10);
89 G4int result = 1;
90 if (j <= 1) return result;
91 for (G4int i = 2; i <= j; ++i) result *= i;
92 return result;
93}
94
95
97 const G4ReactionProduct &currentParticle,
98 const G4ReactionProduct &targetParticle,
99 G4ReactionProduct &leadParticle )
100{
101 // The following was in GenerateXandPt and TwoCluster.
102 // Add a parameter to the GenerateXandPt function telling it about the
103 // strange particle.
104 //
105 // Assumes that the original particle was a strange particle
106 //
107 G4bool lead = false;
108 if( (currentParticle.GetMass() >= G4KaonPlus::KaonPlus()->GetPDGMass()) &&
109 (currentParticle.GetDefinition() != G4Proton::Proton()) &&
110 (currentParticle.GetDefinition() != G4Neutron::Neutron()) )
111 {
112 lead = true;
113 leadParticle = currentParticle; // set lead to the incident particle
114 }
115 else if( (targetParticle.GetMass() >= G4KaonPlus::KaonPlus()->GetPDGMass()) &&
116 (targetParticle.GetDefinition() != G4Proton::Proton()) &&
117 (targetParticle.GetDefinition() != G4Neutron::Neutron()) )
118 {
119 lead = true;
120 leadParticle = targetParticle; // set lead to the target particle
121 }
122 return lead;
123}
124
125
126 void G4RPGInelastic::SetUpPions(const G4int np, const G4int nneg,
127 const G4int nz,
129 G4int &vecLen)
130 {
131 if( np+nneg+nz == 0 )return;
132 G4int i;
134 for( i=0; i<np; ++i )
135 {
136 p = new G4ReactionProduct;
138 (G4UniformRand() < 0.5) ? p->SetSide( -1 ) : p->SetSide( 1 );
139 vec.SetElement( vecLen++, p );
140 }
141 for( i=np; i<np+nneg; ++i )
142 {
143 p = new G4ReactionProduct;
145 (G4UniformRand() < 0.5) ? p->SetSide( -1 ) : p->SetSide( 1 );
146 vec.SetElement( vecLen++, p );
147 }
148 for( i=np+nneg; i<np+nneg+nz; ++i )
149 {
150 p = new G4ReactionProduct;
152 (G4UniformRand() < 0.5) ? p->SetSide( -1 ) : p->SetSide( 1 );
153 vec.SetElement( vecLen++, p );
154 }
155 }
156
157
159 const G4double energy, // MeV, <0 means annihilation channels
160 G4double &n,
161 G4double &anpn )
162 {
163 const G4double expxu = 82.; // upper bound for arg. of exp
164 const G4double expxl = -expxu; // lower bound for arg. of exp
165 const G4int numSec = 60;
166 //
167 // the only difference between the calculation for annihilation channels
168 // and normal is the starting value, iBegin, for the loop below
169 //
170 G4int iBegin = 1;
171 G4double en = energy;
172 if( energy < 0.0 )
173 {
174 iBegin = 2;
175 en *= -1.0;
176 }
177 //
178 // number of total particles vs. centre of mass Energy - 2*proton mass
179 //
180 G4double aleab = std::log(en/GeV);
181 n = 3.62567 + aleab*(0.665843 + aleab*(0.336514 + aleab*(0.117712 + 0.0136912*aleab)));
182 n -= 2.0;
183 //
184 // normalization constant for kno-distribution
185 //
186 anpn = 0.0;
187 G4double test, temp;
188 for( G4int i=iBegin; i<=numSec; ++i )
189 {
190 temp = pi*i/(2.0*n*n);
191 test = std::exp( std::min( expxu, std::max( expxl, -(pi/4.0)*(i*i)/(n*n) ) ) );
192 if( temp < 1.0 )
193 {
194 if( test >= 1.0e-10 )anpn += temp*test;
195 }
196 else
197 anpn += temp*test;
198 }
199 }
200
201void
203 G4int& vecLen,
204 const G4HadProjectile* originalIncident,
205 const G4DynamicParticle* originalTarget,
206 G4ReactionProduct& modifiedOriginal,
207 G4Nucleus& targetNucleus,
208 G4ReactionProduct& currentParticle,
209 G4ReactionProduct& targetParticle,
210 G4bool& incidentHasChanged,
211 G4bool& targetHasChanged,
212 G4bool quasiElastic)
213{
214 cache = 0;
215 what = originalIncident->Get4Momentum().vect();
216
217 G4ReactionProduct leadingStrangeParticle;
218
219 // strangeProduction.ReactionStage(originalIncident, modifiedOriginal,
220 // incidentHasChanged, originalTarget,
221 // targetParticle, targetHasChanged,
222 // targetNucleus, currentParticle,
223 // vec, vecLen,
224 // false, leadingStrangeParticle);
225
226 if( quasiElastic )
227 {
228 twoBody.ReactionStage(originalIncident, modifiedOriginal,
229 incidentHasChanged, originalTarget,
230 targetParticle, targetHasChanged,
231 targetNucleus, currentParticle,
232 vec, vecLen,
233 false, leadingStrangeParticle);
234 return;
235 }
236
237 G4bool leadFlag = MarkLeadingStrangeParticle(currentParticle,
238 targetParticle,
239 leadingStrangeParticle );
240 //
241 // Note: the number of secondaries can be reduced in GenerateXandPt
242 // and TwoCluster
243 //
244 G4bool finishedGenXPt = false;
245 G4bool annihilation = false;
246 if( originalIncident->GetDefinition()->GetPDGEncoding() < 0 &&
247 currentParticle.GetMass() == 0.0 && targetParticle.GetMass() == 0.0 )
248 {
249 // original was an anti-particle and annihilation has taken place
250 annihilation = true;
251 G4double ekcor = 1.0;
252 G4double ek = originalIncident->GetKineticEnergy();
253 G4double ekOrg = ek;
254
255 const G4double tarmas = originalTarget->GetDefinition()->GetPDGMass();
256 if( ek > 1.0*GeV )ekcor = 1./(ek/GeV);
257 const G4double atomicWeight = targetNucleus.GetA_asInt();
258 ek = 2*tarmas + ek*(1.+ekcor/atomicWeight);
259 G4double tkin = targetNucleus.Cinema(ek);
260 ek += tkin;
261 ekOrg += tkin;
262 // modifiedOriginal.SetKineticEnergy( ekOrg );
263 //
264 // evaporation -- re-calculate black track energies
265 // this was Done already just before the cascade
266 //
267 tkin = targetNucleus.AnnihilationEvaporationEffects(ek, ekOrg);
268 ekOrg -= tkin;
269 ekOrg = std::max( 0.0001*GeV, ekOrg );
270 modifiedOriginal.SetKineticEnergy( ekOrg );
271 G4double amas = originalIncident->GetDefinition()->GetPDGMass();
272 G4double et = ekOrg + amas;
273 G4double p = std::sqrt( std::abs(et*et-amas*amas) );
274 G4double pp = modifiedOriginal.GetMomentum().mag();
275 if( pp > 0.0 )
276 {
277 G4ThreeVector momentum = modifiedOriginal.GetMomentum();
278 modifiedOriginal.SetMomentum( momentum * (p/pp) );
279 }
280 if( ekOrg <= 0.0001 )
281 {
282 modifiedOriginal.SetKineticEnergy( 0.0 );
283 modifiedOriginal.SetMomentum( 0.0, 0.0, 0.0 );
284 }
285 }
286
287 // twsup gives percentage of time two-cluster model is called
288
289 const G4double twsup[] = { 1.0, 0.7, 0.5, 0.3, 0.2, 0.1 };
290 G4double rand1 = G4UniformRand();
291 G4double rand2 = G4UniformRand();
292
293 // Cache current, target, and secondaries
294 G4ReactionProduct saveCurrent = currentParticle;
295 G4ReactionProduct saveTarget = targetParticle;
296 std::vector<G4ReactionProduct> savevec;
297 for (G4int i = 0; i < vecLen; i++) savevec.push_back(*vec[i]);
298
299 // Call fragmentation code if
300 // 1) there is annihilation, or
301 // 2) there are more than 5 secondaries, or
302 // 3) incident KE is > 1 GeV AND
303 // ( incident is a kaon AND rand < 0.5 OR twsup )
304 //
305
306 if( annihilation || vecLen > 5 ||
307 ( modifiedOriginal.GetKineticEnergy()/GeV >= 1.0 &&
308
309 (((originalIncident->GetDefinition() == G4KaonPlus::KaonPlus() ||
310 originalIncident->GetDefinition() == G4KaonMinus::KaonMinus() ||
311 originalIncident->GetDefinition() == G4KaonZeroLong::KaonZeroLong() ||
312 originalIncident->GetDefinition() == G4KaonZeroShort::KaonZeroShort()) &&
313 rand1 < 0.5)
314 || rand2 > twsup[vecLen]) ) )
315
316 finishedGenXPt =
317 fragmentation.ReactionStage(originalIncident, modifiedOriginal,
318 incidentHasChanged, originalTarget,
319 targetParticle, targetHasChanged,
320 targetNucleus, currentParticle,
321 vec, vecLen,
322 leadFlag, leadingStrangeParticle);
323
324 if (finishedGenXPt) return;
325
326 G4bool finishedTwoClu = false;
327
328 if (modifiedOriginal.GetTotalMomentum() < 1.0) {
329 for (G4int i = 0; i < vecLen; i++) delete vec[i];
330 vecLen = 0;
331
332 } else {
333 // Occaisionally, GenerateXandPt will fail in the annihilation channel.
334 // Restore current, target and secondaries to pre-GenerateXandPt state
335 // before trying annihilation in TwoCluster
336
337 if (!finishedGenXPt && annihilation) {
338 currentParticle = saveCurrent;
339 targetParticle = saveTarget;
340 for (G4int i = 0; i < vecLen; i++) delete vec[i];
341 vecLen = 0;
342 vec.Initialize( 0 );
343 for (G4int i = 0; i < G4int(savevec.size()); i++) {
345 *p = savevec[i];
346 vec.SetElement( vecLen++, p );
347 }
348 }
349
350 // Big violations of energy conservation in this method - don't use
351 //
352 // pionSuppression.ReactionStage(originalIncident, modifiedOriginal,
353 // incidentHasChanged, originalTarget,
354 // targetParticle, targetHasChanged,
355 // targetNucleus, currentParticle,
356 // vec, vecLen,
357 // false, leadingStrangeParticle);
358
359 try
360 {
361 finishedTwoClu =
362 twoCluster.ReactionStage(originalIncident, modifiedOriginal,
363 incidentHasChanged, originalTarget,
364 targetParticle, targetHasChanged,
365 targetNucleus, currentParticle,
366 vec, vecLen,
367 leadFlag, leadingStrangeParticle);
368 }
370 {
371 aC.Report(G4cout);
372 throw G4HadReentrentException(__FILE__, __LINE__, "Failing to calculate momenta");
373 }
374 }
375
376 if (finishedTwoClu) return;
377
378 twoBody.ReactionStage(originalIncident, modifiedOriginal,
379 incidentHasChanged, originalTarget,
380 targetParticle, targetHasChanged,
381 targetNucleus, currentParticle,
382 vec, vecLen,
383 false, leadingStrangeParticle);
384}
385
386/*
387 void G4RPGInelastic::
388 Rotate(G4FastVector<G4ReactionProduct,256> &vec, G4int &vecLen)
389 {
390 G4double rotation = 2.*pi*G4UniformRand();
391 cache = rotation;
392 G4int i;
393 for( i=0; i<vecLen; ++i )
394 {
395 G4ThreeVector momentum = vec[i]->GetMomentum();
396 momentum = momentum.rotate(rotation, what);
397 vec[i]->SetMomentum(momentum);
398 }
399 }
400*/
401
402void
404 G4int& vecLen,
405 G4ReactionProduct& currentParticle,
406 G4ReactionProduct& targetParticle,
407 G4bool& incidentHasChanged )
408{
412 G4int i;
413
414 if (currentParticle.GetDefinition() == particleDef[k0]) {
415 if (G4UniformRand() < 0.5) {
416 currentParticle.SetDefinitionAndUpdateE(aKaonZL);
417 incidentHasChanged = true;
418 } else {
419 currentParticle.SetDefinitionAndUpdateE(aKaonZS);
420 }
421 } else if (currentParticle.GetDefinition() == particleDef[k0b]) {
422 if (G4UniformRand() < 0.5) {
423 currentParticle.SetDefinitionAndUpdateE(aKaonZL);
424 } else {
425 currentParticle.SetDefinitionAndUpdateE(aKaonZS);
426 incidentHasChanged = true;
427 }
428 }
429
430 if (targetParticle.GetDefinition() == particleDef[k0] ||
431 targetParticle.GetDefinition() == particleDef[k0b] ) {
432 if (G4UniformRand() < 0.5) {
433 targetParticle.SetDefinitionAndUpdateE(aKaonZL);
434 } else {
435 targetParticle.SetDefinitionAndUpdateE(aKaonZS);
436 }
437 }
438
439 for (i = 0; i < vecLen; ++i) {
440 if (vec[i]->GetDefinition() == particleDef[k0] ||
441 vec[i]->GetDefinition() == particleDef[k0b] ) {
442 if (G4UniformRand() < 0.5) {
443 vec[i]->SetDefinitionAndUpdateE(aKaonZL);
444 } else {
445 vec[i]->SetDefinitionAndUpdateE(aKaonZS);
446 }
447 }
448 }
449
450 if (incidentHasChanged) {
452 p0->SetDefinition(currentParticle.GetDefinition() );
453 p0->SetMomentum(currentParticle.GetMomentum() );
457
458 } else {
459 G4double p = currentParticle.GetMomentum().mag()/MeV;
460 G4ThreeVector mom = currentParticle.GetMomentum();
461 if (p > DBL_MIN)
462 theParticleChange.SetMomentumChange(mom.x()/p, mom.y()/p, mom.z()/p );
463 else
465
466 G4double aE = currentParticle.GetKineticEnergy();
467 if (std::fabs(aE)<.1*eV) aE=.1*eV;
469 }
470
471 if (targetParticle.GetMass() > 0.0) // Tgt particle can be eliminated in TwoBody
472 {
473 G4ThreeVector momentum = targetParticle.GetMomentum();
474 momentum = momentum.rotate(cache, what);
475 G4double targKE = targetParticle.GetKineticEnergy();
476 G4ThreeVector dir(0.0, 0.0, 1.0);
477 if (targKE < DBL_MIN)
478 targKE = DBL_MIN;
479 else
480 dir = momentum/momentum.mag();
481
482 G4DynamicParticle* p1 =
483 new G4DynamicParticle(targetParticle.GetDefinition(), dir, targKE);
484
486 }
487
489 for (i = 0; i < vecLen; ++i) {
490 G4double secKE = vec[i]->GetKineticEnergy();
491 G4ThreeVector momentum = vec[i]->GetMomentum();
492 G4ThreeVector dir(0.0, 0.0, 1.0);
493 if (secKE < DBL_MIN)
494 secKE = DBL_MIN;
495 else
496 dir = momentum/momentum.mag();
497
498 p = new G4DynamicParticle(vec[i]->GetDefinition(), dir, secKE);
500 delete vec[i];
501 }
502}
503
504
505std::pair<G4int, G4double>
507{
508 G4int index = 29;
509 G4double fraction = 0.0;
510
511 for (G4int i = 1; i < 30; i++) {
512 if (e < energyScale[i]) {
513 index = i-1;
514 fraction = (e - energyScale[index]) / (energyScale[i] - energyScale[index]);
515 break;
516 }
517 }
518 return std::pair<G4int, G4double>(index, fraction);
519}
520
521
522G4int
523G4RPGInelastic::sampleFlat(std::vector<G4double> sigma) const
524{
525 G4int i;
526 G4double sum(0.);
527 for (i = 0; i < G4int(sigma.size()); i++) sum += sigma[i];
528
529 G4double fsum = sum*G4UniformRand();
530 G4double partialSum = 0.0;
531 G4int channel = 0;
532
533 for (i = 0; i < G4int(sigma.size()); i++) {
534 partialSum += sigma[i];
535 if (fsum < partialSum) {
536 channel = i;
537 break;
538 }
539 }
540
541 return channel;
542}
543
544
546 G4int &vecLen,
547 G4ReactionProduct &currentParticle,
548 G4ReactionProduct &targetParticle,
549 G4double Q, G4double B, G4double S)
550{
551 G4ParticleDefinition* projDef = currentParticle.GetDefinition();
552 G4ParticleDefinition* targDef = targetParticle.GetDefinition();
553 G4double chargeSum = projDef->GetPDGCharge() + targDef->GetPDGCharge();
554 G4double baryonSum = projDef->GetBaryonNumber() + targDef->GetBaryonNumber();
555 G4double strangenessSum = projDef->GetQuarkContent(3) -
556 projDef->GetAntiQuarkContent(3) +
557 targDef->GetQuarkContent(3) -
558 targDef->GetAntiQuarkContent(3);
559
560 G4ParticleDefinition* secDef = 0;
561 for (G4int i = 0; i < vecLen; i++) {
562 secDef = vec[i]->GetDefinition();
563 chargeSum += secDef->GetPDGCharge();
564 baryonSum += secDef->GetBaryonNumber();
565 strangenessSum += secDef->GetQuarkContent(3)
566 - secDef->GetAntiQuarkContent(3);
567 }
568
569 G4bool OK = true;
570 if (chargeSum != Q) {
571 G4cout << " Charge not conserved " << G4endl;
572 OK = false;
573 }
574 if (baryonSum != B) {
575 G4cout << " Baryon number not conserved " << G4endl;
576 OK = false;
577 }
578 if (strangenessSum != S) {
579 G4cout << " Strangeness not conserved " << G4endl;
580 OK = false;
581 }
582
583 if (!OK) {
584 G4cout << " projectile: " << projDef->GetParticleName()
585 << " target: " << targDef->GetParticleName() << G4endl;
586 for (G4int i = 0; i < vecLen; i++) {
587 secDef = vec[i]->GetDefinition();
588 G4cout << secDef->GetParticleName() << " " ;
589 }
590 G4cout << G4endl;
591 }
592
593}
594
595
596const G4double G4RPGInelastic::energyScale[30] = {
597 0.0, 0.01, 0.013, 0.018, 0.024, 0.032, 0.042, 0.056, 0.075, 0.1,
598 0.13, 0.18, 0.24, 0.32, 0.42, 0.56, 0.75, 1.0, 1.3, 1.8,
599 2.4, 3.2, 4.2, 5.6, 7.5, 10.0, 13.0, 18.0, 24.0, 32.0 };
600
601
602/* end of file */
@ stopAndKill
double G4double
Definition: G4Types.hh:64
int G4int
Definition: G4Types.hh:66
bool G4bool
Definition: G4Types.hh:67
#define G4endl
Definition: G4ios.hh:52
G4DLLIMPORT std::ostream G4cout
#define G4UniformRand()
Definition: Randomize.hh:53
double z() const
double x() const
double y() const
double mag() const
Hep3Vector & rotate(double, const Hep3Vector &)
Definition: ThreeVectorR.cc:28
Hep3Vector vect() const
static G4AntiKaonZero * AntiKaonZero()
static G4AntiNeutron * AntiNeutron()
static G4AntiProton * AntiProton()
Definition: G4AntiProton.cc:93
void SetDefinition(const G4ParticleDefinition *aParticleDefinition)
G4ParticleDefinition * GetDefinition() const
void SetMomentum(const G4ThreeVector &momentum)
void SetElement(G4int anIndex, Type *anElement)
Definition: G4FastVector.hh:76
void Initialize(G4int items)
Definition: G4FastVector.hh:63
void SetStatusChange(G4HadFinalStateStatus aS)
void AddSecondary(G4DynamicParticle *aP)
void SetEnergyChange(G4double anEnergy)
void SetMomentumChange(const G4ThreeVector &aV)
const G4ParticleDefinition * GetDefinition() const
G4double GetKineticEnergy() const
const G4LorentzVector & Get4Momentum() const
void Report(std::ostream &aS)
static G4KaonMinus * KaonMinus()
Definition: G4KaonMinus.cc:113
static G4KaonPlus * KaonPlus()
Definition: G4KaonPlus.cc:113
static G4KaonZeroLong * KaonZeroLong()
static G4KaonZeroShort * KaonZeroShort()
static G4KaonZero * KaonZero()
Definition: G4KaonZero.cc:104
static G4Lambda * Lambda()
Definition: G4Lambda.cc:108
static G4Neutron * Neutron()
Definition: G4Neutron.cc:104
G4int GetA_asInt() const
Definition: G4Nucleus.hh:109
G4double AnnihilationEvaporationEffects(G4double kineticEnergy, G4double ekOrg)
Definition: G4Nucleus.cc:323
G4double Cinema(G4double kineticEnergy)
Definition: G4Nucleus.cc:368
static G4OmegaMinus * OmegaMinus()
G4int GetQuarkContent(G4int flavor) const
G4double GetPDGCharge() const
const G4String & GetParticleName() const
G4int GetAntiQuarkContent(G4int flavor) const
static G4PionMinus * PionMinus()
Definition: G4PionMinus.cc:98
static G4PionPlus * PionPlus()
Definition: G4PionPlus.cc:98
static G4PionZero * PionZero()
Definition: G4PionZero.cc:104
static G4Proton * Proton()
Definition: G4Proton.cc:93
G4bool ReactionStage(const G4HadProjectile *, G4ReactionProduct &, G4bool &, const G4DynamicParticle *, G4ReactionProduct &, G4bool &, const G4Nucleus &, G4ReactionProduct &, G4FastVector< G4ReactionProduct, 256 > &, G4int &, G4bool, G4ReactionProduct &)
G4int sampleFlat(std::vector< G4double > sigma) const
std::pair< G4int, G4double > interpolateEnergy(G4double ke) const
void SetUpPions(const G4int np, const G4int nm, const G4int nz, G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen)
void CheckQnums(G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4double Q, G4double B, G4double S)
void GetNormalizationConstant(const G4double availableEnergy, G4double &n, G4double &anpn)
void CalculateMomenta(G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen, const G4HadProjectile *originalIncident, const G4DynamicParticle *originalTarget, G4ReactionProduct &modifiedOriginal, G4Nucleus &targetNucleus, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4bool &incidentHasChanged, G4bool &targetHasChanged, G4bool quasiElastic)
G4RPGTwoBody twoBody
G4RPGFragmentation fragmentation
G4RPGTwoCluster twoCluster
void SetUpChange(G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4bool &incidentHasChanged)
G4bool MarkLeadingStrangeParticle(const G4ReactionProduct &currentParticle, const G4ReactionProduct &targetParticle, G4ReactionProduct &leadParticle)
G4ParticleDefinition * particleDef[18]
G4int Factorial(G4int n)
G4double Pmltpc(G4int np, G4int nm, G4int nz, G4int n, G4double b, G4double c)
G4RPGInelastic(const G4String &modelName="RPGInelastic")
G4bool ReactionStage(const G4HadProjectile *, G4ReactionProduct &, G4bool &, const G4DynamicParticle *, G4ReactionProduct &, G4bool &, const G4Nucleus &, G4ReactionProduct &, G4FastVector< G4ReactionProduct, 256 > &, G4int &, G4bool, G4ReactionProduct &)
Definition: G4RPGTwoBody.cc:44
G4bool ReactionStage(const G4HadProjectile *, G4ReactionProduct &, G4bool &, const G4DynamicParticle *, G4ReactionProduct &, G4bool &, const G4Nucleus &, G4ReactionProduct &, G4FastVector< G4ReactionProduct, 256 > &, G4int &, G4bool, G4ReactionProduct &)
void SetMomentum(const G4double x, const G4double y, const G4double z)
G4double GetTotalMomentum() const
G4double GetKineticEnergy() const
G4ThreeVector GetMomentum() const
void SetSide(const G4int sid)
void SetDefinitionAndUpdateE(G4ParticleDefinition *aParticleDefinition)
void SetKineticEnergy(const G4double en)
G4ParticleDefinition * GetDefinition() const
void SetDefinition(G4ParticleDefinition *aParticleDefinition)
G4double GetMass() const
static G4SigmaMinus * SigmaMinus()
static G4SigmaPlus * SigmaPlus()
Definition: G4SigmaPlus.cc:108
static G4SigmaZero * SigmaZero()
Definition: G4SigmaZero.cc:99
static G4XiMinus * XiMinus()
Definition: G4XiMinus.cc:106
static G4XiZero * XiZero()
Definition: G4XiZero.cc:106
#define DBL_MIN
Definition: templates.hh:75