G4PenelopeBremsstrahlungAngular Class Reference

#include <G4PenelopeBremsstrahlungAngular.hh>

Inheritance diagram for G4PenelopeBremsstrahlungAngular:

Public Member Functions
	G4PenelopeBremsstrahlungAngular ()
	~G4PenelopeBremsstrahlungAngular ()
G4ThreeVector &	SampleDirection (const G4DynamicParticle *dp, G4double out_energy, G4int Z, const G4Material *mat=nullptr) override
	Samples the direction of the outgoing photon (in global coordinates).
void	SetVerbosityLevel (G4int vl)
	Set/Get Verbosity level.
G4int	GetVerbosityLevel ()
void	Initialize ()
void	PrepareTables (const G4Material *material, G4bool isMaster)
	Reserved for Master Model.
Public Member Functions inherited from G4VEmAngularDistribution
	G4VEmAngularDistribution (const G4String &name)
virtual	~G4VEmAngularDistribution ()
virtual G4ThreeVector &	SampleDirectionForShell (const G4DynamicParticle *dp, G4double finalTotalEnergy, G4int Z, G4int shellID, const G4Material *)
virtual void	SamplePairDirections (const G4DynamicParticle *dp, G4double elecKinEnergy, G4double posiKinEnergy, G4ThreeVector &dirElectron, G4ThreeVector &dirPositron, G4int Z=0, const G4Material *mat=nullptr)
virtual void	PrintGeneratorInformation () const
const G4String &	GetName () const
G4VEmAngularDistribution &	operator= (const G4VEmAngularDistribution &right)=delete
	G4VEmAngularDistribution (const G4VEmAngularDistribution &)=delete

Additional Inherited Members
Protected Attributes inherited from G4VEmAngularDistribution
G4ThreeVector	fLocalDirection
G4bool	fPolarisation

Detailed Description

Definition at line 55 of file G4PenelopeBremsstrahlungAngular.hh.

Constructor & Destructor Documentation

G4PenelopeBremsstrahlungAngular()

G4PenelopeBremsstrahlungAngular::G4PenelopeBremsstrahlungAngular ( )

explicit

Definition at line 60 of file G4PenelopeBremsstrahlungAngular.cc.

                                                                 :
  G4VEmAngularDistribution("Penelope"), fEffectiveZSq(nullptr),
  fLorentzTables1(nullptr),fLorentzTables2(nullptr)
 
{
  fDataRead = false;
  fVerbosityLevel = 0;
}

~G4PenelopeBremsstrahlungAngular()

G4PenelopeBremsstrahlungAngular::~G4PenelopeBremsstrahlungAngular

(

)

Definition at line 71 of file G4PenelopeBremsstrahlungAngular.cc.

{
  ClearTables();
}

Member Function Documentation

GetVerbosityLevel()

G4int G4PenelopeBremsstrahlungAngular::GetVerbosityLevel ( )

inline

Definition at line 69 of file G4PenelopeBremsstrahlungAngular.hh.

{return fVerbosityLevel;};

Initialize()

void G4PenelopeBremsstrahlungAngular::Initialize

(

)

Reserved for Master Model The Initialize() method forces the cleaning of tables

Definition at line 78 of file G4PenelopeBremsstrahlungAngular.cc.

{
  ClearTables();
}

Referenced by G4PenelopeBremsstrahlungModel::Initialise(), and G4PenelopeBremsstrahlungModel::InitialiseLocal().

PrepareTables()

void G4PenelopeBremsstrahlungAngular::PrepareTables	(	const G4Material *	material,
		G4bool	isMaster )

Reserved for Master Model.

Definition at line 174 of file G4PenelopeBremsstrahlungAngular.cc.

{
  //Unused at the moment: the G4PenelopeBremsstrahlungAngular is thread-local, so each worker
  //builds its own version of the tables.
  
  //Check if data file has already been read
  if (!fDataRead)
    {
      ReadDataFile();
      if (!fDataRead)
    G4Exception("G4PenelopeBremsstrahlungAngular::PrepareInterpolationTables()",
            "em2001",FatalException,"Unable to build interpolation table");
    }
 
  if (!fLorentzTables1)
      fLorentzTables1 = new std::map<G4double,G4PhysicsTable*>;
  if (!fLorentzTables2)
    fLorentzTables2 = new std::map<G4double,G4PhysicsTable*>;
 
  G4double Zmat = CalculateEffectiveZ(material);
 
  const G4int reducedEnergyGrid=21;
  //Support arrays.
  G4double betas[fNumberofEPoints]; //betas for interpolation
  //tables for interpolation
  G4double Q1[fNumberofEPoints][fNumberofKPoints];
  G4double Q2[fNumberofEPoints][fNumberofKPoints];
  //expanded tables for interpolation
  G4double Q1E[fNumberofEPoints][reducedEnergyGrid];
  G4double Q2E[fNumberofEPoints][reducedEnergyGrid];
  G4double pZ[fNumberofZPoints] = {2.0,8.0,13.0,47.0,79.0,92.0};
 
  G4int i=0,j=0,k=0; // i=index for Z, j=index for E, k=index for K
  //Interpolation in Z
  for (i=0;i<fNumberofEPoints;i++)
    {
      for (j=0;j<fNumberofKPoints;j++)
    {
      G4PhysicsFreeVector* QQ1vector = 
        new G4PhysicsFreeVector(fNumberofZPoints,/*spline =*/true);
      G4PhysicsFreeVector* QQ2vector = 
        new G4PhysicsFreeVector(fNumberofZPoints,/*spline =*/true);
 
      //fill vectors
      for (k=0;k<fNumberofZPoints;k++)
        {
          QQ1vector->PutValues(k,pZ[k],G4Log(fQQ1[k][i][j]));
          QQ2vector->PutValues(k,pZ[k],fQQ2[k][i][j]);
        }
      //Filled: now calculate derivatives
      QQ1vector->FillSecondDerivatives();
      QQ2vector->FillSecondDerivatives();
 
      Q1[i][j]= G4Exp(QQ1vector->Value(Zmat));
      Q2[i][j]=QQ2vector->Value(Zmat);
      delete QQ1vector;
      delete QQ2vector;
    }
    }
  G4double pE[fNumberofEPoints] = {1.0e-03*MeV,5.0e-03*MeV,1.0e-02*MeV,5.0e-02*MeV,
                  1.0e-01*MeV,5.0e-01*MeV};
  G4double pK[fNumberofKPoints] = {0.0,0.6,0.8,0.95};
  G4double ppK[reducedEnergyGrid];
 
  for(i=0;i<reducedEnergyGrid;i++)
    ppK[i]=((G4double) i) * 0.05;
 
 
  for(i=0;i<fNumberofEPoints;i++)
    betas[i]=std::sqrt(pE[i]*(pE[i]+2*electron_mass_c2))/(pE[i]+electron_mass_c2);
 
 
  for (i=0;i<fNumberofEPoints;i++)
    {
      for (j=0;j<fNumberofKPoints;j++)
    Q1[i][j]=Q1[i][j]/Zmat;
    }
 
  //Expanded table of distribution parameters
  for (i=0;i<fNumberofEPoints;i++)
    {
      G4PhysicsFreeVector* Q1vector = new G4PhysicsFreeVector(fNumberofKPoints);
      G4PhysicsFreeVector* Q2vector = new G4PhysicsFreeVector(fNumberofKPoints);
 
      for (j=0;j<fNumberofKPoints;j++)
    {
      Q1vector->PutValues(j,pK[j],G4Log(Q1[i][j])); //logarithmic
      Q2vector->PutValues(j,pK[j],Q2[i][j]);
    }
 
      for (j=0;j<reducedEnergyGrid;j++)
    {
      Q1E[i][j]=Q1vector->Value(ppK[j]);
      Q2E[i][j]=Q2vector->Value(ppK[j]);
    }
      delete Q1vector;
      delete Q2vector;
    }
  //
  //TABLES to be stored
  //
  G4PhysicsTable* theTable1 = new G4PhysicsTable();
  G4PhysicsTable* theTable2 = new G4PhysicsTable();
  // the table will contain reducedEnergyGrid G4PhysicsFreeVectors with different
  // values of k,
  // Each of the G4PhysicsFreeVectors has a profile of
  // y vs. E
  //
  //reserve space of the vectors.
  for (j=0;j<reducedEnergyGrid;j++)
    {
      G4PhysicsFreeVector* thevec = new G4PhysicsFreeVector(fNumberofEPoints,/*spline=*/true);
      theTable1->push_back(thevec);
      G4PhysicsFreeVector* thevec2 = new G4PhysicsFreeVector(fNumberofEPoints,/*spline=*/true);
      theTable2->push_back(thevec2);
    }
 
  for (j=0;j<reducedEnergyGrid;j++)
    {
      G4PhysicsFreeVector* thevec = (G4PhysicsFreeVector*) (*theTable1)[j];
      G4PhysicsFreeVector* thevec2 = (G4PhysicsFreeVector*) (*theTable2)[j];
      for (i=0;i<fNumberofEPoints;i++)
    {
      thevec->PutValues(i,betas[i],Q1E[i][j]);
      thevec2->PutValues(i,betas[i],Q2E[i][j]);
    }
      //Vectors are filled: calculate derivatives
      thevec->FillSecondDerivatives();
      thevec2->FillSecondDerivatives();
    }
 
  if (fLorentzTables1 && fLorentzTables2)
    {
      fLorentzTables1->insert(std::make_pair(Zmat,theTable1));
      fLorentzTables2->insert(std::make_pair(Zmat,theTable2));
    }
  else
    {
      G4ExceptionDescription ed;
      ed << "Unable to create tables of Lorentz coefficients for " << G4endl;
      ed << "<Z>= "  << Zmat << " in G4PenelopeBremsstrahlungAngular" << G4endl;
      delete theTable1;
      delete theTable2;
      G4Exception("G4PenelopeBremsstrahlungAngular::PrepareInterpolationTables()",
          "em2005",FatalException,ed);
    }
 
  return;
}

Referenced by G4PenelopeBremsstrahlungModel::Initialise(), and G4PenelopeBremsstrahlungModel::InitialiseLocal().

SampleDirection()

G4ThreeVector & G4PenelopeBremsstrahlungAngular::SampleDirection ( const G4DynamicParticle * dp, G4double out_energy, G4int Z, const G4Material * mat = nullptr )

overridevirtual

Samples the direction of the outgoing photon (in global coordinates).

Implements G4VEmAngularDistribution.

Definition at line 326 of file G4PenelopeBremsstrahlungAngular.cc.

{
  if (!material)
    {
      G4Exception("G4PenelopeBremsstrahlungAngular::SampleDirection()",
          "em2040",FatalException,"The pointer to G4Material* is nullptr");
      return fLocalDirection;
    }
 
  //Retrieve the effective Z
  G4double Zmat = 0;
 
  if (!fEffectiveZSq)
    {
      G4Exception("G4PenelopeBremsstrahlungAngular::SampleDirection()",
          "em2040",FatalException,"EffectiveZ table not available");
      return fLocalDirection;
    }
 
  //found in the table: return it
  if (fEffectiveZSq->count(material))
    Zmat = fEffectiveZSq->find(material)->second;
  else
    {
      G4Exception("G4PenelopeBremsstrahlungAngular::SampleDirection()",
          "em2040",FatalException,"Material not found in the effectiveZ table");
      return fLocalDirection;
    }
 
  if (fVerbosityLevel > 0)
    {
      G4cout << "Effective <Z> for material : " << material->GetName() <<
    " = " << Zmat << G4endl;
    }
 
  G4double ePrimary = dp->GetKineticEnergy();
 
  G4double beta = std::sqrt(ePrimary*(ePrimary+2*electron_mass_c2))/
    (ePrimary+electron_mass_c2);
  G4double cdt = 0;
  G4double sinTheta = 0;
  G4double phi = 0;
 
  //Use a pure dipole distribution for energy above 500 keV
  if (ePrimary > 500*keV)
    {
      cdt = 2.0*G4UniformRand() - 1.0;
      if (G4UniformRand() > 0.75)
    {
      if (cdt<0)
        cdt = -1.0*std::pow(-cdt,1./3.);
      else
        cdt = std::pow(cdt,1./3.);
    }
      cdt = (cdt+beta)/(1.0+beta*cdt);
      //Get primary kinematics
      sinTheta = std::sqrt(1. - cdt*cdt);
      phi  = twopi * G4UniformRand();
      fLocalDirection.set(sinTheta* std::cos(phi),
              sinTheta* std::sin(phi),
              cdt);
      //rotate
      fLocalDirection.rotateUz(dp->GetMomentumDirection());
      //return
      return fLocalDirection;
    }
 
  if (!(fLorentzTables1->count(Zmat)) || !(fLorentzTables2->count(Zmat)))
    {
      G4ExceptionDescription ed;
      ed << "Unable to retrieve Lorentz tables for Z= " << Zmat << G4endl;
      G4Exception("G4PenelopeBremsstrahlungAngular::SampleDirection()",
          "em2006",FatalException,ed);
    }
 
  //retrieve actual tables
  const G4PhysicsTable* theTable1 = fLorentzTables1->find(Zmat)->second;
  const G4PhysicsTable* theTable2 = fLorentzTables2->find(Zmat)->second;
 
  G4double RK=20.0*eGamma/ePrimary;
  G4int ik=std::min((G4int) RK,19);
 
  G4double P10=0,P11=0,P1=0;
  G4double P20=0,P21=0,P2=0;
 
  //First coefficient
  const G4PhysicsFreeVector* v1 = (G4PhysicsFreeVector*) (*theTable1)[ik];
  const G4PhysicsFreeVector* v2 = (G4PhysicsFreeVector*) (*theTable1)[ik+1];
  P10 = v1->Value(beta);
  P11 = v2->Value(beta);
  P1=P10+(RK-(G4double) ik)*(P11-P10);
 
  //Second coefficient
  const G4PhysicsFreeVector* v3 = (G4PhysicsFreeVector*) (*theTable2)[ik];
  const G4PhysicsFreeVector* v4 = (G4PhysicsFreeVector*) (*theTable2)[ik+1];
  P20=v3->Value(beta);
  P21=v4->Value(beta);
  P2=P20+(RK-(G4double) ik)*(P21-P20);
 
  //Sampling from the Lorenz-trasformed dipole distributions
  P1=std::min(G4Exp(P1)/beta,1.0);
  G4double betap = std::min(std::max(beta*(1.0+P2/beta),0.0),0.9999);
 
  G4double testf=0;
 
  if (G4UniformRand() < P1)
    {
      do{
    cdt = 2.0*G4UniformRand()-1.0;
    testf=2.0*G4UniformRand()-(1.0+cdt*cdt);
      }while(testf>0);
    }
  else
    {
      do{
    cdt = 2.0*G4UniformRand()-1.0;
    testf=G4UniformRand()-(1.0-cdt*cdt);
      }while(testf>0);
    }
  cdt = (cdt+betap)/(1.0+betap*cdt);
 
  //Get primary kinematics
  sinTheta = std::sqrt(1. - cdt*cdt);
  phi  = twopi * G4UniformRand();
  fLocalDirection.set(sinTheta* std::cos(phi),
              sinTheta* std::sin(phi),
              cdt);
  //rotate
  fLocalDirection.rotateUz(dp->GetMomentumDirection());
  //return
  return fLocalDirection;
 
}

Referenced by G4PenelopeBremsstrahlungModel::SampleSecondaries().

SetVerbosityLevel()

void G4PenelopeBremsstrahlungAngular::SetVerbosityLevel ( G4int vl )

inline

Set/Get Verbosity level.

Definition at line 68 of file G4PenelopeBremsstrahlungAngular.hh.

{fVerbosityLevel = vl;};

---

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

• G4PenelopeBremsstrahlungAngular.hh
• G4PenelopeBremsstrahlungAngular.cc