Geant4  10.00.p02
G4QGSParticipants.cc
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26 #include <utility>
27 
28 #include "G4QGSParticipants.hh"
29 #include "globals.hh"
30 #include "G4SystemOfUnits.hh"
31 #include "G4LorentzVector.hh"
32 
33 // Class G4QGSParticipants
34 
35 // HPW Feb 1999
36 // Promoting model parameters from local variables class properties
38 
39 G4QGSParticipants::G4QGSParticipants() : theDiffExcitaton(), //0.7*GeV, 250*MeV, 250*MeV),
40  ModelMode(SOFT),
41  //nCutMax(7),ThresholdParameter(0.45*GeV),
42  nCutMax(7),ThresholdParameter(0.000*GeV),
43  QGSMThreshold(3*GeV),theNucleonRadius(1.5*fermi)
44 
45 {
46 }
47 
49 : G4VParticipants(),ModelMode(right.ModelMode), nCutMax(right.nCutMax),
50  ThresholdParameter(right.ThresholdParameter), QGSMThreshold(right.QGSMThreshold),
51  theNucleonRadius(right.theNucleonRadius)
52 {
53 }
54 
55 
57 {
58 }
59 
61 {
62 
63  // Find the collisions and collition conditions
64  G4VSplitableHadron* aProjectile = SelectInteractions(thePrimary);
65 
66  // now build the parton pairs. HPW
67  SplitHadrons();
68 
69  // soft collisions first HPW, ordering is vital
71 
72  // the rest is diffractive HPW
74 
75  // clean-up, if necessary
76  std::for_each(theInteractions.begin(), theInteractions.end(), DeleteInteractionContent());
77  theInteractions.clear();
78  std::for_each(theTargets.begin(), theTargets.end(), DeleteSplitableHadron());
79  theTargets.clear();
80  delete aProjectile;
81 }
82 
84 {
85  G4VSplitableHadron* aProjectile = new G4QGSMSplitableHadron(thePrimary, TRUE); // @@@ check the TRUE
86  G4PomeronCrossSection theProbability(thePrimary.GetDefinition()); // @@@ should be data member
87  G4double outerRadius = theNucleus->GetOuterRadius();
88  // Check reaction threshold
89 
91  G4Nucleon * pNucleon = theNucleus->GetNextNucleon();
92  G4LorentzVector aPrimaryMomentum(thePrimary.GetMomentum(), thePrimary.GetTotalEnergy());
93  //--DEBUG--G4cout << " qgspart- " << aPrimaryMomentum << " # " << aPrimaryMomentum.mag()
94  //--DEBUG-- << pNucleon->Get4Momentum() << " # " << (pNucleon->Get4Momentum()).mag()<< G4endl;
95  G4double s_nucleus = (aPrimaryMomentum + pNucleon->Get4Momentum()).mag2();
96  G4double ThresholdMass = thePrimary.GetMass() + pNucleon->GetDefinition()->GetPDGMass();
97  ModelMode = SOFT;
98  if (sqr(ThresholdMass + ThresholdParameter) > s_nucleus)
99  {
101  //throw G4HadronicException(__FILE__, __LINE__, "Initial energy is too low. The 4-vectors of the input are inconsistant with the particle masses.");
102  }
103  if (sqr(ThresholdMass + QGSMThreshold) > s_nucleus) // thus only diffractive in cascade!
104  {
106  }
107 
108  // first find the collisions HPW
109  std::for_each(theInteractions.begin(), theInteractions.end(), DeleteInteractionContent());
110  theInteractions.clear();
111  G4int totalCuts = 0;
112 
113  #ifdef debug_QGS
114  G4double eK = thePrimary.GetKineticEnergy()/GeV;
115  #endif
116  #ifdef debug_G4QGSParticipants
117  G4double impactUsed = 0;
118  G4LorentzVector intNuclMom;
119  #endif
120 
121  while(theInteractions.size() == 0)
122  {
123  // choose random impact parameter HPW
124  std::pair<G4double, G4double> theImpactParameter;
125  theImpactParameter = theNucleus->ChooseImpactXandY(outerRadius+theNucleonRadius);
126  G4double impactX = theImpactParameter.first;
127  G4double impactY = theImpactParameter.second;
128 
129  // loop over nucleons to find collisions
131  G4int nucleonCount = 0; // debug
133  #ifdef debug_G4QGSParticipants
134  intNuclMom=aPrimaryMomentum;
135  #endif
136  while( (pNucleon = theNucleus->GetNextNucleon()) )
137  {
138  if(totalCuts>1.5*thePrimary.GetKineticEnergy()/GeV)
139  {
140  break;
141  }
142  nucleonCount++; // debug
143  // Needs to be moved to Probability class @@@
144  G4LorentzVector nucleonMomentum=pNucleon->Get4Momentum();
145  nucleonMomentum.setE(nucleonMomentum.e()-pNucleon->GetBindingEnergy());
146  G4double s_nucleon = (aPrimaryMomentum + nucleonMomentum).mag2();
147  G4double Distance2 = sqr(impactX - pNucleon->GetPosition().x()) +
148  sqr(impactY - pNucleon->GetPosition().y());
149  G4double Probability = theProbability.GetInelasticProbability(s_nucleon, Distance2);
150  // test for inelastic collision
151  G4double rndNumber = G4UniformRand();
152  // ModelMode = DIFFRACTIVE;
153  if (Probability > rndNumber)
154  {
155  #ifdef debug_G4QGSParticipants
156  G4cout << "DEBUG p="<< Probability<<" r="<<rndNumber<<" d="<<std::sqrt(Distance2)<<G4endl;
157  G4cout << " qgspart+ " << aPrimaryMomentum << " # " << aPrimaryMomentum.mag()
158  << pNucleon->Get4Momentum() << " # " << (pNucleon->Get4Momentum()).mag()<< G4endl;
159  intNuclMom += nucleonMomentum;
160  #endif
161  pNucleon->SetMomentum(nucleonMomentum);
162  G4QGSMSplitableHadron* aTarget = new G4QGSMSplitableHadron(*pNucleon);
164  theTargets.push_back(aTarget);
165  pNucleon->Hit(aTarget);
166  if ((theProbability.GetDiffractiveProbability(s_nucleon, Distance2)/Probability > G4UniformRand()
167  &&(ModelMode==SOFT)) || (ModelMode==DIFFRACTIVE ))
168  {
169  // diffractive interaction occurs
170  if(IsSingleDiffractive())
171  {
172  theSingleDiffExcitation.ExciteParticipants(aProjectile, aTarget);
173  }
174  else
175  {
176  theDiffExcitaton.ExciteParticipants(aProjectile, aTarget);
177  }
178  G4InteractionContent * aInteraction = new G4InteractionContent(aProjectile);
179  aInteraction->SetTarget(aTarget);
180  theInteractions.push_back(aInteraction);
181  aInteraction->SetNumberOfDiffractiveCollisions(1);
182  totalCuts += 1;
183  }
184  else
185  {
186  // nondiffractive soft interaction occurs
187  // sample nCut+1 (cut Pomerons) pairs of strings can be produced
188  G4int nCut;
189  G4double * running = new G4double[nCutMax];
190  running[0] = 0;
191  for(nCut = 0; nCut < nCutMax; nCut++)
192  {
193  running[nCut] = theProbability.GetCutPomeronProbability(s_nucleon, Distance2, nCut + 1);
194  if(nCut!=0) running[nCut] += running[nCut-1];
195  }
196  G4double random = running[nCutMax-1]*G4UniformRand();
197  for(nCut = 0; nCut < nCutMax; nCut++)
198  {
199  if(running[nCut] > random) break;
200  }
201  delete [] running;
202  nCut = 0;
203  aTarget->IncrementCollisionCount(nCut+1);
204  aProjectile->IncrementCollisionCount(nCut+1);
205  G4InteractionContent * aInteraction = new G4InteractionContent(aProjectile);
206  aInteraction->SetTarget(aTarget);
207  aInteraction->SetNumberOfSoftCollisions(nCut+1);
208  theInteractions.push_back(aInteraction);
209  totalCuts += nCut+1;
210  #ifdef debug_G4QGSParticipants
211  impactUsed=Distance2;
212  #endif
213  }
214  }
215  }
216  #ifdef debug_G4QGSParticipants
217  G4cout << G4endl<<"NUCLEONCOUNT "<<nucleonCount<<G4endl;
218  G4cout << " Interact 4-Vect " << intNuclMom << G4endl;
219  #endif
220  }
221  #ifdef debug_G4QGSParticipants
222  G4cout << G4endl<<"CUTDEBUG "<< totalCuts <<G4endl;
223  G4cout << "Impact Parameter used = "<<impactUsed<<G4endl;
224  #endif
225  return aProjectile;
226 }
227 
229 {
230  // remove the "G4PartonPair::PROJECTILE", etc., which are not necessary. @@@
231  unsigned int i;
232  for(i = 0; i < theInteractions.size(); i++)
233  {
234  G4InteractionContent* anIniteraction = theInteractions[i];
235  G4VSplitableHadron* aProjectile = anIniteraction->GetProjectile();
236  G4Parton* aParton = aProjectile->GetNextParton();
237  G4PartonPair * aPartonPair;
238  // projectile first HPW
239  if (aParton)
240  {
241  aPartonPair = new G4PartonPair(aParton, aProjectile->GetNextAntiParton(),
244  #ifdef debug_G4QGSPart_PDiffColl
245  G4cout << "DiffPair Pro " << aPartonPair->GetParton1()->GetPDGcode() << " "
246  << aPartonPair->GetParton1()->Get4Momentum() << " "
247  << aPartonPair->GetParton1()->GetX() << " " << G4endl;
248  G4cout << " " << aPartonPair->GetParton2()->GetPDGcode() << " "
249  << aPartonPair->GetParton2()->Get4Momentum() << " "
250  << aPartonPair->GetParton2()->GetX() << " " << G4endl;
251  #endif
252  thePartonPairs.push_back(aPartonPair);
253  }
254  // then target HPW
255  G4VSplitableHadron* aTarget = anIniteraction->GetTarget();
256  aParton = aTarget->GetNextParton();
257  if (aParton)
258  {
259  aPartonPair = new G4PartonPair(aParton, aTarget->GetNextAntiParton(),
262  #ifdef debug_G4QGSPart_PDiffColl
263  G4cout << "DiffPair Tgt " << aPartonPair->GetParton1()->GetPDGcode() << " "
264  << aPartonPair->GetParton1()->Get4Momentum() << " "
265  << aPartonPair->GetParton1()->GetX() << " " << G4endl;
266  G4cout << " " << aPartonPair->GetParton2()->GetPDGcode() << " "
267  << aPartonPair->GetParton2()->Get4Momentum() << " "
268  << aPartonPair->GetParton2()->GetX() << " " << G4endl;
269  #endif
270  thePartonPairs.push_back(aPartonPair);
271  }
272  }
273 }
274 
276 {
277  std::vector<G4InteractionContent*>::iterator i;
278  G4LorentzVector str4Mom;
279  i = theInteractions.begin();
280  while ( i != theInteractions.end() )
281  {
282  G4InteractionContent* anIniteraction = *i;
283  G4PartonPair * aPair = NULL;
284  if (anIniteraction->GetNumberOfSoftCollisions())
285  {
286  G4VSplitableHadron* pProjectile = anIniteraction->GetProjectile();
287  G4VSplitableHadron* pTarget = anIniteraction->GetTarget();
288  for (G4int j = 0; j < anIniteraction->GetNumberOfSoftCollisions(); j++)
289  {
290  aPair = new G4PartonPair(pTarget->GetNextParton(), pProjectile->GetNextAntiParton(),
292  #ifdef debug_G4QGSPart_PSoftColl
293  G4cout << "SoftPair " << aPair->GetParton1()->GetPDGcode() << " "
294  << aPair->GetParton1()->Get4Momentum() << " "
295  << aPair->GetParton1()->GetX() << " " << G4endl;
296  G4cout << " " << aPair->GetParton2()->GetPDGcode() << " "
297  << aPair->GetParton2()->Get4Momentum() << " "
298  << aPair->GetParton2()->GetX() << " " << G4endl;
299  #endif
300  #ifdef debug_G4QGSParticipants
301  str4Mom += aPair->GetParton1()->Get4Momentum();
302  str4Mom += aPair->GetParton2()->Get4Momentum();
303  #endif
304  thePartonPairs.push_back(aPair);
305  aPair = new G4PartonPair(pProjectile->GetNextParton(), pTarget->GetNextAntiParton(),
307  #ifdef debug_G4QGSPart_PSoftColl
308  G4cout << "SoftPair " << aPair->GetParton1()->GetPDGcode() << " "
309  << aPair->GetParton1()->Get4Momentum() << " "
310  << aPair->GetParton1()->GetX() << " " << G4endl;
311  G4cout << " " << aPair->GetParton2()->GetPDGcode() << " "
312  << aPair->GetParton2()->Get4Momentum() << " "
313  << aPair->GetParton2()->GetX() << " " << G4endl;
314  #endif
315  #ifdef debug_G4QGSParticipants
316  str4Mom += aPair->GetParton1()->Get4Momentum();
317  str4Mom += aPair->GetParton2()->Get4Momentum();
318  #endif
319  thePartonPairs.push_back(aPair);
320  }
321  delete *i;
322  i=theInteractions.erase(i); // i now points to the next interaction
323  } else {
324  i++;
325  }
326  }
327  #ifdef debug_G4QGSPart_PSoftColl
328  G4cout << " string 4 mom " << str4Mom << G4endl;
329  #endif
330 }
G4bool ExciteParticipants(G4VSplitableHadron *aPartner, G4VSplitableHadron *bPartner) const
G4Parton * GetParton2(void)
Definition: G4PartonPair.hh:79
G4int GetPDGcode() const
Definition: G4Parton.hh:124
void SetMomentum(G4LorentzVector &aMomentum)
Definition: G4Nucleon.hh:70
virtual G4bool StartLoop()=0
const G4LorentzVector & Get4Momentum() const
Definition: G4Parton.hh:140
const G4double QGSMThreshold
virtual const G4LorentzVector & Get4Momentum() const
Definition: G4Nucleon.hh:72
virtual G4Parton * GetNextAntiParton()=0
virtual const G4ThreeVector & GetPosition() const
Definition: G4Nucleon.hh:68
#define G4ThreadLocal
Definition: tls.hh:52
int G4int
Definition: G4Types.hh:78
G4ParticleDefinition * GetDefinition() const
G4Parton * GetParton1(void)
Definition: G4PartonPair.hh:74
virtual G4double GetOuterRadius()=0
virtual ~G4QGSParticipants()
#define G4UniformRand()
Definition: Randomize.hh:87
G4GLOB_DLL std::ostream G4cout
virtual G4VSplitableHadron * SelectInteractions(const G4ReactionProduct &thePrimary)
virtual G4Parton * GetNextParton()=0
#define TRUE
Definition: globals.hh:55
void IncrementCollisionCount(G4int aCount)
static const double GeV
Definition: G4SIunits.hh:196
G4QGSDiffractiveExcitation theDiffExcitaton
virtual G4bool ExciteParticipants(G4VSplitableHadron *aPartner, G4VSplitableHadron *bPartner) const
G4V3DNucleus * theNucleus
G4double GetX()
Definition: G4Parton.hh:86
G4double GetKineticEnergy() const
std::pair< G4double, G4double > ChooseImpactXandY(G4double maxImpact)
Definition: G4V3DNucleus.hh:87
G4double GetTotalEnergy() const
void SetNumberOfDiffractiveCollisions(int)
std::vector< G4PartonPair * > thePartonPairs
G4double GetPDGMass() const
std::vector< G4VSplitableHadron * > theTargets
G4VSplitableHadron * GetTarget() const
G4VSplitableHadron * GetProjectile() const
void BuildInteractions(const G4ReactionProduct &thePrimary)
G4ThreeVector GetMomentum() const
#define G4endl
Definition: G4ios.hh:61
virtual G4ParticleDefinition * GetDefinition() const
Definition: G4Nucleon.hh:85
virtual G4Nucleon * GetNextNucleon()=0
void Hit(G4VSplitableHadron *aHit)
Definition: G4Nucleon.hh:90
T sqr(const T &x)
Definition: templates.hh:145
double G4double
Definition: G4Types.hh:76
G4SingleDiffractiveExcitation theSingleDiffExcitation
G4double GetBindingEnergy() const
Definition: G4Nucleon.hh:75
std::vector< G4InteractionContent * > theInteractions
const G4double theNucleonRadius
G4double GetMass() const
const G4double ThresholdParameter
static const double fermi
Definition: G4SIunits.hh:93
G4ThreadLocal G4int G4QGSParticipants_NPart
void SetTarget(G4VSplitableHadron *aTarget)
CLHEP::HepLorentzVector G4LorentzVector