source: trunk/source/processes/electromagnetic/polarisation/src/G4VPolarizedCrossSection.cc @ 1055

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// $Id: G4VPolarizedCrossSection.cc,v 1.4 2007/11/01 17:32:34 schaelic Exp $
// GEANT4 tag $Name: geant4-09-02 $
// File name:     G4VPolarizedCrossSection
//
// Author:        Andreas Schaelicke
//
// Creation date: 15.05.2005
//
// Modifications:
//
// Class Description:
//   (pure virtual) interface class
//
//   provides readable but efficient routines to determine 
//   polarization for the final state of a given process
//   empoying the differential cross section
//

#include "G4VPolarizedCrossSection.hh"
#include "Randomize.hh"

G4VPolarizedCrossSection::G4VPolarizedCrossSection() :
  fXmin(0), fXmax(1.), fYmin(1.), theA(1), theZ(1), fCoul(0.)
{
}

G4VPolarizedCrossSection::~G4VPolarizedCrossSection()
{
}

void G4VPolarizedCrossSection::Initialize(G4double, G4double, G4double,
                                          const G4StokesVector &,
                                          const G4StokesVector &,
                                          G4int ) 
{
} 
 
G4StokesVector G4VPolarizedCrossSection::GetPol2()
{
  // neglects correlation effects! 

  G4double invXsecTotal=1./XSection(G4StokesVector::ZERO,G4StokesVector::ZERO);
  G4double xsPol1=XSection(G4StokesVector::P1,G4StokesVector::ZERO);
  G4double xsPol2=XSection(G4StokesVector::P2,G4StokesVector::ZERO);
  G4double xsPol3=XSection(G4StokesVector::P3,G4StokesVector::ZERO);
  return G4ThreeVector(invXsecTotal*xsPol1,invXsecTotal*xsPol2,invXsecTotal*xsPol3);
}

G4StokesVector G4VPolarizedCrossSection::GetPol3()
{
  // neglects correlation effects! 

  G4double invXsecTotal=1./XSection(G4StokesVector::ZERO,G4StokesVector::ZERO);
  G4double xsPol1=XSection(G4StokesVector::ZERO,G4StokesVector::P1); 
  G4double xsPol2=XSection(G4StokesVector::ZERO,G4StokesVector::P2); 
  G4double xsPol3=XSection(G4StokesVector::ZERO,G4StokesVector::P3); 
  return G4ThreeVector(invXsecTotal*xsPol1,invXsecTotal*xsPol2,invXsecTotal*xsPol3); 
}
// minimal energy fraction in TotalXSection
G4double G4VPolarizedCrossSection::GetXmin(G4double /*y*/)
{
  return fXmin;
}

// maximal energy fraction in TotalXSection
G4double G4VPolarizedCrossSection::GetXmax(G4double /*y*/)
{
  return fXmax;
}


/*
void G4VPolarizedCrossSection::DicePolarization() 
{
  // can respect correlation effects, but is limited to 
  // one quantization axis!
  G4double sigma[4];
  sigma[0]=XSection(G4StokesVector::P3,G4StokesVector::P3);
  sigma[1]=XSection(G4StokesVector::P3,G4StokesVector::M3);
  sigma[2]=XSection(G4StokesVector::M3,G4StokesVector::P3);
  sigma[3]=XSection(G4StokesVector::M3,G4StokesVector::M3);

  G4double sigma_max = 4. * XSection(G4StokesVector::ZERO,G4StokesVector::ZERO);

  for (G4int i=0;i<4;++i) {
    G4cout<<"sigma="<<sigma[i]<<" vs."<<(.25*sigma_max)<<G4endl;
    if (sigma[i]<0 || sigma[i]>sigma_max) {
      G4cout<<"ERROR G4VPolarizedCrossSection::DicePolarization(["<<i<<"]):  "
            <<sigma[i]<<" vs."<<sigma_max<<G4endl;
    }
    if (i>0) sigma[i]+=sigma[i-1];
  }

  G4int k = 0;
  G4double disc = sigma[3]*G4UniformRand();
  while (sigma[k]<disc && k<4) {
    ++k;
  }

  if ((k&2)==0) pol2=G4StokesVector::P3;
  else          pol2=G4StokesVector::M3;
  if ((k&1)==0) pol3=G4StokesVector::P3;
  else          pol3=G4StokesVector::M3;

}
*/

/*
G4StokesVector G4VPolarizedCrossSection::DicedPol2()
{
  return pol2;
}

G4StokesVector G4VPolarizedCrossSection::DicedPol3()
{
  return pol3;
}
*/

G4double G4VPolarizedCrossSection::TotalXSection(const G4double, const G4double, const G4double,
                                                 const G4StokesVector &,const G4StokesVector &)
{
  G4cout << "WARNING virtual function G4VPolarizedCrossSection::TotalXSection() called" << G4endl;
  return 0.;
}