G4ChipsAntiBaryonElasticXS Class Reference

#include <G4ChipsAntiBaryonElasticXS.hh>

Inheritance diagram for G4ChipsAntiBaryonElasticXS:

Collaboration diagram for G4ChipsAntiBaryonElasticXS:

Public Member Functions
	G4ChipsAntiBaryonElasticXS ()
	~G4ChipsAntiBaryonElasticXS ()
virtual void	CrossSectionDescription (std::ostream &) const
virtual G4bool	IsIsoApplicable (const G4DynamicParticle *Pt, G4int Z, G4int A, const G4Element *elm, const G4Material *mat)
virtual G4double	GetIsoCrossSection (const G4DynamicParticle *, G4int tgZ, G4int A, const G4Isotope *iso=0, const G4Element *elm=0, const G4Material *mat=0)
virtual G4double	GetChipsCrossSection (G4double momentum, G4int Z, G4int N, G4int pdg)
G4double	GetExchangeT (G4int tZ, G4int tN, G4int pPDG)
Public Member Functions inherited from G4VCrossSectionDataSet
	G4VCrossSectionDataSet (const G4String &nam="")
virtual	~G4VCrossSectionDataSet ()
virtual G4bool	IsElementApplicable (const G4DynamicParticle *, G4int Z, const G4Material *mat=0)
G4double	GetCrossSection (const G4DynamicParticle *, const G4Element *, const G4Material *mat=0)
G4double	ComputeCrossSection (const G4DynamicParticle *, const G4Element *, const G4Material *mat=0)
virtual G4double	GetElementCrossSection (const G4DynamicParticle *, G4int Z, const G4Material *mat=0)
virtual G4Isotope *	SelectIsotope (const G4Element *, G4double kinEnergy)
virtual void	BuildPhysicsTable (const G4ParticleDefinition &)
virtual void	DumpPhysicsTable (const G4ParticleDefinition &)
virtual G4int	GetVerboseLevel () const
virtual void	SetVerboseLevel (G4int value)
G4double	GetMinKinEnergy () const
void	SetMinKinEnergy (G4double value)
G4double	GetMaxKinEnergy () const
void	SetMaxKinEnergy (G4double value)
const G4String &	GetName () const

Static Public Member Functions
static const char *	Default_Name ()

Additional Inherited Members
Protected Member Functions inherited from G4VCrossSectionDataSet
void	SetName (const G4String &)
Protected Attributes inherited from G4VCrossSectionDataSet
G4int	verboseLevel

Detailed Description

Definition at line 46 of file G4ChipsAntiBaryonElasticXS.hh.

Constructor & Destructor Documentation

G4ChipsAntiBaryonElasticXS::G4ChipsAntiBaryonElasticXS

(

)

Definition at line 59 of file G4ChipsAntiBaryonElasticXS.cc.

                                                      :G4VCrossSectionDataSet(Default_Name()), nPoints(128), nLast(nPoints-1)
{
  lPMin=-8.;  //Min tabulatedLogarithmMomentum(D)
  lPMax= 8.;  //Max tabulatedLogarithmMomentum(D)
  dlnP=(lPMax-lPMin)/nLast;// LogStep inTable (D)
  onlyCS=true;//Flag toCalculOnlyCS(not Si/Bi)(L)
  lastSIG=0.; //Last calculated cross section (L)
  lastLP=-10.;//LastLog(mom_of IncidentHadron)(L)
  lastTM=0.;  //Last t_maximum                (L)
  theSS=0.;   //TheLastSqSlope of 1st difr.Max(L)
  theS1=0.;   //TheLastMantissa of 1st difrMax(L)
  theB1=0.;   //TheLastSlope of 1st difructMax(L)
  theS2=0.;   //TheLastMantissa of 2nd difrMax(L)
  theB2=0.;   //TheLastSlope of 2nd difructMax(L)
  theS3=0.;   //TheLastMantissa of 3d difr.Max(L)
  theB3=0.;   //TheLastSlope of 3d difruct.Max(L)
  theS4=0.;   //TheLastMantissa of 4th difrMax(L)
  theB4=0.;   //TheLastSlope of 4th difructMax(L)
  lastTZ=0;   // Last atomic number of the target
  lastTN=0;   // Last # of neutrons in the target
  lastPIN=0.; // Last initialized max momentum
  lastCST=0;  // Elastic cross-section table
  lastPAR=0;  // ParametersForFunctionCalculation
  lastSST=0;  // E-dep ofSqardSlope of 1st difMax
  lastS1T=0;  // E-dep of mantissa of 1st dif.Max
  lastB1T=0;  // E-dep of the slope of 1st difMax
  lastS2T=0;  // E-dep of mantissa of 2nd difrMax
  lastB2T=0;  // E-dep of the slope of 2nd difMax
  lastS3T=0;  // E-dep of mantissa of 3d difr.Max
  lastB3T=0;  // E-dep of the slope of 3d difrMax
  lastS4T=0;  // E-dep of mantissa of 4th difrMax
  lastB4T=0;  // E-dep of the slope of 4th difMax
  lastN=0;    // The last N of calculated nucleus
  lastZ=0;    // The last Z of calculated nucleus
  lastP=0.;   // LastUsed inCrossSection Momentum
  lastTH=0.;  // Last threshold momentum
  lastCS=0.;  // Last value of the Cross Section
  lastI=0;    // The last position in the DAMDB
}

G4ChipsAntiBaryonElasticXS::~G4ChipsAntiBaryonElasticXS

(

)

Definition at line 99 of file G4ChipsAntiBaryonElasticXS.cc.

{
  std::vector<G4double*>::iterator pos;
  for (pos=CST.begin(); pos<CST.end(); pos++)
  { delete [] *pos; }
  CST.clear();
  for (pos=PAR.begin(); pos<PAR.end(); pos++)
  { delete [] *pos; }
  PAR.clear();
  for (pos=SST.begin(); pos<SST.end(); pos++)
  { delete [] *pos; }
  SST.clear();
  for (pos=S1T.begin(); pos<S1T.end(); pos++)
  { delete [] *pos; }
  S1T.clear();
  for (pos=B1T.begin(); pos<B1T.end(); pos++)
  { delete [] *pos; }
  B1T.clear();
  for (pos=S2T.begin(); pos<S2T.end(); pos++)
  { delete [] *pos; }
  S2T.clear();
  for (pos=B2T.begin(); pos<B2T.end(); pos++)
  { delete [] *pos; }
  B2T.clear();
  for (pos=S3T.begin(); pos<S3T.end(); pos++)
  { delete [] *pos; }
  S3T.clear();
  for (pos=B3T.begin(); pos<B3T.end(); pos++)
  { delete [] *pos; }
  B3T.clear();
  for (pos=S4T.begin(); pos<S4T.end(); pos++)
  { delete [] *pos; }
  S4T.clear();
  for (pos=B4T.begin(); pos<B4T.end(); pos++)
  { delete [] *pos; }
  B4T.clear();
}

Member Function Documentation

void G4ChipsAntiBaryonElasticXS::CrossSectionDescription ( std::ostream &  outFile ) const

virtual

Reimplemented from G4VCrossSectionDataSet.

Definition at line 138 of file G4ChipsAntiBaryonElasticXS.cc.

{
    outFile << "G4ChipsAntiBaryonElasticXS provides the elastic cross\n"
            << "section for anti-baryon nucleus scattering as a function of incident\n"
            << "momentum. The cross section is calculated using M. Kossov's\n"
            << "CHIPS parameterization of cross section data.\n";
}

static const char* G4ChipsAntiBaryonElasticXS::Default_Name ( )

inlinestatic

Definition at line 55 of file G4ChipsAntiBaryonElasticXS.hh.

{return "ChipsAntiBaryonElasticXS";}

Here is the caller graph for this function:

G4double G4ChipsAntiBaryonElasticXS::GetChipsCrossSection ( G4double  momentum, G4int  Z, G4int  N, G4int  pdg  )

virtual

!The slave functions must provide cross-sections in millibarns (mb) !! (not in IU)

Definition at line 206 of file G4ChipsAntiBaryonElasticXS.cc.

{
  G4bool fCS = false;

  G4double pEn=pMom;
  onlyCS=fCS;

  G4bool in=false;                   // By default the isotope must be found in the AMDB
  lastP   = 0.;                      // New momentum history (nothing to compare with)
  lastN   = tgN;                     // The last N of the calculated nucleus
  lastZ   = tgZ;                     // The last Z of the calculated nucleus
  lastI   = colN.size();             // Size of the Associative Memory DB in the heap
  if(lastI) for(G4int i=0; i<lastI; i++) // Loop over proj/tgZ/tgN lines of DB
  {                                  // The nucleus with projPDG is found in AMDB
    if(colN[i]==tgN && colZ[i]==tgZ) // Isotope is foind in AMDB
    {
      lastI=i;
      lastTH =colTH[i];              // Last THreshold (A-dependent)
      if(pEn<=lastTH)
      {
        return 0.;                   // Energy is below the Threshold value
      }
      lastP  =colP [i];              // Last Momentum  (A-dependent)
      lastCS =colCS[i];              // Last CrossSect (A-dependent)
      //  if(std::fabs(lastP/pMom-1.)<tolerance) //VI (do not use tolerance)
      if(lastP == pMom)              // Do not recalculate
      {
        CalculateCrossSection(fCS,-1,i,pPDG,lastZ,lastN,pMom); // Update param's only
        return lastCS*millibarn;     // Use theLastCS
      }
      in = true;                       // This is the case when the isotop is found in DB
      // Momentum pMom is in IU ! @@ Units
      lastCS=CalculateCrossSection(fCS,-1,i,pPDG,lastZ,lastN,pMom); // read & update
      if(lastCS<=0. && pEn>lastTH)    // Correct the threshold
      {
        lastTH=pEn;
      }
      break;                           // Go out of the LOOP with found lastI
    }
  } // End of attampt to find the nucleus in DB
  if(!in)                            // This nucleus has not been calculated previously
  {
    lastCS=CalculateCrossSection(fCS,0,lastI,pPDG,lastZ,lastN,pMom);//calculate&create
    if(lastCS<=0.)
    {
      lastTH = 0; // ThresholdEnergy(tgZ, tgN); // The Threshold Energy which is now the last
      if(pEn>lastTH)
      {
        lastTH=pEn;
      }
    }
    colN.push_back(tgN);
    colZ.push_back(tgZ);
    colP.push_back(pMom);
    colTH.push_back(lastTH);
    colCS.push_back(lastCS);
    return lastCS*millibarn;
  } // End of creation of the new set of parameters
  else
  {
    colP[lastI]=pMom;
    colCS[lastI]=lastCS;
  }
  return lastCS*millibarn;
}

Here is the caller graph for this function:

G4double G4ChipsAntiBaryonElasticXS::GetExchangeT	(	G4int	tZ,
		G4int	tN,
		G4int	pPDG
	)

Definition at line 644 of file G4ChipsAntiBaryonElasticXS.cc.

{
  static const G4double GeVSQ=gigaelectronvolt*gigaelectronvolt;
  static const G4double third=1./3.;
  static const G4double fifth=1./5.;
  static const G4double sevth=1./7.;

  if(PDG<-3334 || PDG>-1111)G4cout<<"*Warning*G4QAntiBaryonElCS::GetExT:PDG="<<PDG<<G4endl;
  if(onlyCS)G4cout<<"WarningG4ChipsAntiBaryonElasticXS::GetExchanT:onlyCS=1"<<G4endl;
  if(lastLP<-4.3) return lastTM*GeVSQ*G4UniformRand();// S-wave for p<14 MeV/c (kinE<.1MeV)
  G4double q2=0.;
  if(tgZ==1 && tgN==0)                // ===> p+p=p+p
  {
    G4double E1=lastTM*theB1;
    G4double R1=(1.-G4Exp(-E1));
    G4double E2=lastTM*theB2;
    G4double R2=(1.-G4Exp(-E2*E2*E2));
    G4double E3=lastTM*theB3;
    G4double R3=(1.-G4Exp(-E3));
    G4double I1=R1*theS1/theB1;
    G4double I2=R2*theS2;
    G4double I3=R3*theS3;
    G4double I12=I1+I2;
    G4double rand=(I12+I3)*G4UniformRand();
    if     (rand<I1 )
    {
      G4double ran=R1*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran)/theB1;
    }
    else if(rand<I12)
    {
      G4double ran=R2*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran);
      if(q2<0.) q2=0.;
      q2=G4Pow::GetInstance()->powA(q2,third)/theB2;
    }
    else
    {
      G4double ran=R3*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran)/theB3;
    }
  }
  else
  {
    G4double a=tgZ+tgN;
    G4double E1=lastTM*(theB1+lastTM*theSS);
    G4double R1=(1.-G4Exp(-E1));
    G4double tss=theSS+theSS; // for future solution of quadratic equation (imediate check)
    G4double tm2=lastTM*lastTM;
    G4double E2=lastTM*tm2*theB2;                   // power 3 for lowA, 5 for HighA (1st)
    if(a>6.5)E2*=tm2;                               // for heavy nuclei
    G4double R2=(1.-G4Exp(-E2));
    G4double E3=lastTM*theB3;
    if(a>6.5)E3*=tm2*tm2*tm2;                       // power 1 for lowA, 7 (2nd) for HighA
    G4double R3=(1.-G4Exp(-E3));
    G4double E4=lastTM*theB4;
    G4double R4=(1.-G4Exp(-E4));
    G4double I1=R1*theS1;
    G4double I2=R2*theS2;
    G4double I3=R3*theS3;
    G4double I4=R4*theS4;
    G4double I12=I1+I2;
    G4double I13=I12+I3;
    G4double rand=(I13+I4)*G4UniformRand();
    if(rand<I1)
    {
      G4double ran=R1*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran)/theB1;
      if(std::fabs(tss)>1.e-7) q2=(std::sqrt(theB1*(theB1+(tss+tss)*q2))-theB1)/tss;
    }
    else if(rand<I12)
    {
      G4double ran=R2*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran)/theB2;
      if(q2<0.) q2=0.;
      if(a<6.5) q2=G4Pow::GetInstance()->powA(q2,third);
      else      q2=G4Pow::GetInstance()->powA(q2,fifth);
    }
    else if(rand<I13)
    {
      G4double ran=R3*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran)/theB3;
      if(q2<0.) q2=0.;
      if(a>6.5) q2=G4Pow::GetInstance()->powA(q2,sevth);
    }
    else
    {
      G4double ran=R4*G4UniformRand();
      if(ran>1.) ran=1.;
      q2=-G4Log(1.-ran)/theB4;
      if(a<6.5) q2=lastTM-q2;                    // u reduced for lightA (starts from 0)
    }
  }
  if(q2<0.) q2=0.;
  if(!(q2>=-1.||q2<=1.))G4cout<<"*NAN*G4QaBElasticCrossSect::GetExchangeT:-t="<<q2<<G4endl;
  if(q2>lastTM)
  {
    q2=lastTM;
  }
  return q2*GeVSQ;
}

Here is the call graph for this function:

Here is the caller graph for this function:

G4double G4ChipsAntiBaryonElasticXS::GetIsoCrossSection ( const G4DynamicParticle *  Pt, G4int  tgZ, G4int  A, const G4Isotope *  iso = 0, const G4Element *  elm = 0, const G4Material *  mat = 0  )

virtual

Reimplemented from G4VCrossSectionDataSet.

Definition at line 194 of file G4ChipsAntiBaryonElasticXS.cc.

{
  G4double pMom=Pt->GetTotalMomentum();
  G4int tgN = A - tgZ;
  G4int pdg = Pt->GetDefinition()->GetPDGEncoding();
  
  return GetChipsCrossSection(pMom, tgZ, tgN, pdg);
}

Here is the call graph for this function:

G4bool G4ChipsAntiBaryonElasticXS::IsIsoApplicable ( const G4DynamicParticle *  Pt, G4int  Z, G4int  A, const G4Element *  elm, const G4Material *  mat  )

virtual

Reimplemented from G4VCrossSectionDataSet.

Definition at line 146 of file G4ChipsAntiBaryonElasticXS.cc.

{

  /*
  if(particle == G4AntiNeutron::AntiNeutron())
  {
    return true;
  }
  else if(particle == G4AntiProton::AntiProton())
  {
    return true;
  }
  else if(particle == G4AntiLambda::AntiLambda())
  {
    return true;
  }
  else if(particle == G4AntiSigmaPlus::AntiSigmaPlus())
  {
    return true;
  }
  else if(particle == G4AntiSigmaMinus::AntiSigmaMinus())
  {
    return true;
  }
  else if(particle == G4AntiSigmaZero::AntiSigmaZero())
  {
    return true;
  }
  else if(particle == G4AntiXiMinus::AntiXiMinus())
  {
    return true;
  }
  else if(particle == G4AntiXiZero::AntiXiZero())
  {
    return true;
  }
  else if(particle == G4AntiOmegaMinus::AntiOmegaMinus())
  {
    return true;
  }
  */
  return true;
}

---

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

• source/geant4.10.03.p02/source/processes/hadronic/cross_sections/include/G4ChipsAntiBaryonElasticXS.hh
• source/geant4.10.03.p02/source/processes/hadronic/cross_sections/src/G4ChipsAntiBaryonElasticXS.cc