G4RKFieldIntegrator Class Reference

#include <G4RKFieldIntegrator.hh>

Inheritance diagram for G4RKFieldIntegrator:

Public Member Functions
	G4RKFieldIntegrator ()
	G4RKFieldIntegrator (const G4RKFieldIntegrator &)
	~G4RKFieldIntegrator ()
const G4RKFieldIntegrator &	operator= (const G4RKFieldIntegrator &)
G4bool	operator== (const G4RKFieldIntegrator &) const
G4bool	operator!= (const G4RKFieldIntegrator &) const
void	Transport (G4KineticTrackVector &theActive, const G4KineticTrackVector &theSpectators, G4double theTimeStep)
G4double	GetExcitationEnergy (G4int nHitNucleons, const G4KineticTrackVector &theParticles)
void	Init (G4int z, G4int a)
G4double	GetNeutronPotential (G4double radius)
G4double	GetNeutronPotential (G4ThreeVector &aPosition)
G4double	GetProtonPotential (G4double radius)
G4double	GetProtonPotential (G4ThreeVector &aPosition)
G4double	GetAntiprotonPotential (G4double radius)
G4double	GetAntiprotonPotential (G4ThreeVector &aPosition)
G4double	GetKaonPotential (G4double radius)
G4double	GetKaonPotential (G4ThreeVector &aPosition)
G4double	GetPionPotential (G4double radius)
G4double	GetPionPotential (G4ThreeVector &aPosition)
Public Member Functions inherited from G4FieldPropagation
	G4FieldPropagation ()
	G4FieldPropagation (const G4FieldPropagation &)
virtual	~G4FieldPropagation ()
virtual void	Transport (G4KineticTrackVector &theActive, const G4KineticTrackVector &theSpectators, G4double theTimeStep)=0
virtual G4double	GetExcitationEnergy (G4int nHit, const G4KineticTrackVector &theParticles)=0
virtual void	Init (G4int z, G4int a)=0
virtual G4double	GetNeutronPotential (G4double radius)=0
virtual G4double	GetNeutronPotential (G4ThreeVector &aPosition)=0
virtual G4double	GetProtonPotential (G4double radius)=0
virtual G4double	GetProtonPotential (G4ThreeVector &aPosition)=0
virtual G4double	GetAntiprotonPotential (G4double radius)=0
virtual G4double	GetAntiprotonPotential (G4ThreeVector &aPosition)=0
virtual G4double	GetKaonPotential (G4double radius)=0
virtual G4double	GetKaonPotential (G4ThreeVector &aPosition)=0
virtual G4double	GetPionPotential (G4double radius)=0
virtual G4double	GetPionPotential (G4ThreeVector &aPosition)=0

Detailed Description

Definition at line 31 of file G4RKFieldIntegrator.hh.

Constructor & Destructor Documentation

G4RKFieldIntegrator() [1/2]

G4RKFieldIntegrator::G4RKFieldIntegrator ( )

inline

Definition at line 34 of file G4RKFieldIntegrator.hh.

{}

G4RKFieldIntegrator() [2/2]

G4RKFieldIntegrator::G4RKFieldIntegrator ( const G4RKFieldIntegrator &  )

inline

Definition at line 35 of file G4RKFieldIntegrator.hh.

:G4FieldPropagation() {}

~G4RKFieldIntegrator()

G4RKFieldIntegrator::~G4RKFieldIntegrator ( )

inline

Definition at line 37 of file G4RKFieldIntegrator.hh.

{}

Member Function Documentation

GetAntiprotonPotential() [1/2]

G4double G4RKFieldIntegrator::GetAntiprotonPotential ( G4double  radius )

virtual

Implements G4FieldPropagation.

Definition at line 296 of file G4RKFieldIntegrator.cc.

{
   /*
   //G4double theM = G4NucleiProperties::GetAtomicMass(theA, theZ);
   G4double theM = theZ * G4Proton::Proton()->GetPDGMass()
      + (theA - theZ) * G4Neutron::Neutron()->GetPDGMass()
      + G4CreateNucleus::GetBindingEnergy(theZ, theA);
 
   const G4double Mp  = 938.27231 * MeV; // mass of proton
   G4double mu = (theM * Mp)/(theM + Mp);
 
   // antiproton's potential coefficient
   //   V = coeff_antiproton * nucleus_density
   G4double coeff_antiproton = -2.*pi/mu * (1. + Mp) * a_antiproton;
 
   G4VNuclearDensity *theDencity;
   if(theA < 17) theDencity = new G4NuclearShellModelDensity(theA, theZ);
   else          theDencity = new G4NuclearFermiDensity(theA, theZ);
 
   // GetDencity() accepts only G4ThreeVector so build it:
   G4ThreeVector aPosition(0.0, 0.0, radius);
   G4double density = theDencity->GetDensity(aPosition);
   delete theDencity;
 
   return coeff_antiproton * density;
   */
 
   return 0.0;
}

GetAntiprotonPotential() [2/2]

G4double G4RKFieldIntegrator::GetAntiprotonPotential ( G4ThreeVector &  aPosition )

inlinevirtual

Implements G4FieldPropagation.

Definition at line 61 of file G4RKFieldIntegrator.hh.

{return GetAntiprotonPotential(aPosition.mag());};

Referenced by GetAntiprotonPotential().

GetExcitationEnergy()

G4double G4RKFieldIntegrator::GetExcitationEnergy ( G4int  nHitNucleons, const G4KineticTrackVector &  theParticles  )

virtual

Implements G4FieldPropagation.

Definition at line 185 of file G4RKFieldIntegrator.cc.

{
   const G4double MeanE = 50;
   G4double Sum = 0;
   for(G4int c1 = 0; c1 < nHitNucleons; ++c1)
       {
       Sum += -MeanE*G4Log(G4UniformRand());
       }
   return Sum;
}

GetKaonPotential() [1/2]

G4double G4RKFieldIntegrator::GetKaonPotential ( G4double  radius )

virtual

Implements G4FieldPropagation.

Definition at line 326 of file G4RKFieldIntegrator.cc.

{
   /*
   //G4double theM = G4NucleiProperties::GetAtomicMass(theA, theZ);
   G4double theM = theZ * G4Proton::Proton()->GetPDGMass()
      + (theA - theZ) * G4Neutron::Neutron()->GetPDGMass()
      + G4CreateNucleus::GetBindingEnergy(theZ, theA);
 
   const G4double Mk  = 496. * MeV;      // mass of "kaon"
   G4double mu = (theM * Mk)/(theM + Mk);
 
   // kaon's potential coefficient
   //   V = coeff_kaon * nucleus_density
   G4double coeff_kaon = -2.*pi/mu * (1. + Mk/theM) * a_kaon;
 
   G4VNuclearDensity *theDencity;
   if(theA < 17) theDencity = new G4NuclearShellModelDensity(theA, theZ);
   else          theDencity = new G4NuclearFermiDensity(theA, theZ);
 
   // GetDencity() accepts only G4ThreeVector so build it:
   G4ThreeVector aPosition(0.0, 0.0, radius);
   G4double density = theDencity->GetDensity(aPosition);
   delete theDencity;
 
   return coeff_kaon * density;
   */
 
   return 0.0;
}

GetKaonPotential() [2/2]

G4double G4RKFieldIntegrator::GetKaonPotential ( G4ThreeVector &  aPosition )

inlinevirtual

Implements G4FieldPropagation.

Definition at line 64 of file G4RKFieldIntegrator.hh.

{return GetKaonPotential(aPosition.mag());}

Referenced by GetKaonPotential().

GetNeutronPotential() [1/2]

G4double G4RKFieldIntegrator::GetNeutronPotential ( G4double  radius )

virtual

Implements G4FieldPropagation.

Definition at line 239 of file G4RKFieldIntegrator.cc.

{
   /*
   const G4double Mn  = 939.56563 * MeV; // mass of nuetron
 
   G4VNuclearDensity *theDencity;
   if(theA < 17) theDencity = new G4NuclearShellModelDensity(theA, theZ);
   else          theDencity = new G4NuclearFermiDensity(theA, theZ);
 
   // GetDencity() accepts only G4ThreeVector so build it:
   G4ThreeVector aPosition(0.0, 0.0, radius);
   G4double density = theDencity->GetDensity(aPosition);
   delete theDencity;
 
   G4FermiMomentum *fm = new G4FermiMomentum();
   fm->Init(theA, theZ);
   G4double fermiMomentum = fm->GetFermiMomentum(density);
   delete fm;
 
   return sqr(fermiMomentum)/(2 * Mn)
      + G4CreateNucleus::GetBindingEnergy(theZ, theA)/theA;
      //+ G4NucleiProperties::GetBindingEnergy(theZ, theA)/theA;
   */
 
   return 0.0;
}

GetNeutronPotential() [2/2]

G4double G4RKFieldIntegrator::GetNeutronPotential ( G4ThreeVector &  aPosition )

inlinevirtual

Implements G4FieldPropagation.

Definition at line 55 of file G4RKFieldIntegrator.hh.

{return GetNeutronPotential(aPosition.mag());}

Referenced by GetNeutronPotential().

GetPionPotential() [1/2]

G4double G4RKFieldIntegrator::GetPionPotential ( G4double  radius )

virtual

Implements G4FieldPropagation.

Definition at line 356 of file G4RKFieldIntegrator.cc.

{
   /*
   //G4double theM = G4NucleiProperties::GetAtomicMass(theA, theZ);
   G4double theM = theZ * G4Proton::Proton()->GetPDGMass()
      + (theA - theZ) * G4Neutron::Neutron()->GetPDGMass()
      + G4CreateNucleus::GetBindingEnergy(theZ, theA);
 
   const G4double Mpi = 139. * MeV;      // mass of "pion"
   G4double mu = (theM * Mpi)/(theM + Mpi);
 
   // pion's potential coefficient
   //   V = coeff_pion * nucleus_density
   G4double coeff_pion = -2.*pi/mu * (1. + Mpi) * a_pion;
 
   G4VNuclearDensity *theDencity;
   if(theA < 17) theDencity = new G4NuclearShellModelDensity(theA, theZ);
   else          theDencity = new G4NuclearFermiDensity(theA, theZ);
 
   // GetDencity() accepts only G4ThreeVector so build it:
   G4ThreeVector aPosition(0.0, 0.0, radius);
   G4double density = theDencity->GetDensity(aPosition);
   delete theDencity;
 
   return coeff_pion * density;
   */
 
   return 0.0;
}

GetPionPotential() [2/2]

G4double G4RKFieldIntegrator::GetPionPotential ( G4ThreeVector &  aPosition )

inlinevirtual

Implements G4FieldPropagation.

Definition at line 67 of file G4RKFieldIntegrator.hh.

{return GetPionPotential(aPosition.mag());}

Referenced by GetPionPotential().

GetProtonPotential() [1/2]

G4double G4RKFieldIntegrator::GetProtonPotential ( G4double  radius )

virtual

Implements G4FieldPropagation.

Definition at line 266 of file G4RKFieldIntegrator.cc.

{
   /*
   // calculate Coulomb barrier value
   G4double theCoulombBarrier = coulomb * theZ/(1. + G4Pow::GetInstance()->Z13(theA));
   const G4double Mp  = 938.27231 * MeV; // mass of proton
 
   G4VNuclearDensity *theDencity;
   if(theA < 17) theDencity = new G4NuclearShellModelDensity(theA, theZ);
   else          theDencity = new G4NuclearFermiDensity(theA, theZ);
 
   // GetDencity() accepts only G4ThreeVector so build it:
   G4ThreeVector aPosition(0.0, 0.0, radius);
   G4double density = theDencity->GetDensity(aPosition);
   delete theDencity;
 
   G4FermiMomentum *fm = new G4FermiMomentum();
   fm->Init(theA, theZ);
   G4double fermiMomentum = fm->GetFermiMomentum(density);
   delete fm;
 
   return sqr(fermiMomentum)/ (2 * Mp)
      + G4CreateNucleus::GetBindingEnergy(theZ, theA)/theA;
      //+ G4NucleiProperties::GetBindingEnergy(theZ, theA)/theA
      + theCoulombBarrier;
   */
 
   return 0.0;
}

GetProtonPotential() [2/2]

G4double G4RKFieldIntegrator::GetProtonPotential ( G4ThreeVector &  aPosition )

inlinevirtual

Implements G4FieldPropagation.

Definition at line 58 of file G4RKFieldIntegrator.hh.

{return GetProtonPotential(aPosition.mag());}

Referenced by GetProtonPotential().

Init()

void G4RKFieldIntegrator::Init ( G4int  z, G4int  a  )

inlinevirtual

Implements G4FieldPropagation.

Definition at line 51 of file G4RKFieldIntegrator.hh.

{theZ = z;  theA = a;} // prepare potentials' functions

operator!=()

G4bool G4RKFieldIntegrator::operator!= ( const G4RKFieldIntegrator &  ) const

inline

Definition at line 43 of file G4RKFieldIntegrator.hh.

{return 1;}

operator=()

const G4RKFieldIntegrator & G4RKFieldIntegrator::operator= ( const G4RKFieldIntegrator &  )

inline

Definition at line 40 of file G4RKFieldIntegrator.hh.

{return *this;}

operator==()

G4bool G4RKFieldIntegrator::operator== ( const G4RKFieldIntegrator &  ) const

inline

Definition at line 42 of file G4RKFieldIntegrator.hh.

{return 1;}

Transport()

void G4RKFieldIntegrator::Transport ( G4KineticTrackVector &  theActive, const G4KineticTrackVector &  theSpectators, G4double  theTimeStep  )

virtual

Implements G4FieldPropagation.

Definition at line 45 of file G4RKFieldIntegrator.cc.

{
   (void)theActive;
   (void)theSpectators;
   (void)theTimeStep;
}

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

• G4RKFieldIntegrator.hh
• G4RKFieldIntegrator.cc