source: trunk/source/processes/electromagnetic/highenergy/include/G4mplIonisationModel.hh@ 1036

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// $Id: G4mplIonisationModel.hh,v 1.6 2007/11/13 18:36:29 vnivanch Exp $
// GEANT4 tag $Name: geant4-09-02 $
//
// -------------------------------------------------------------------
//
// GEANT4 Class header file
//
//
// File name:     G4mplIonisationModel
//
// Author:        Vladimir Ivanchenko 
//
// Creation date: 06.09.2005
//
// Modifications:
// 12.08.2007 ComputeDEDXAhlen function added (M. Vladymyrov)
//
// Class Description:
//
// Implementation of model of energy loss of the magnetic monopole

// -------------------------------------------------------------------
//

#ifndef G4mplIonisationModel_h
#define G4mplIonisationModel_h 1

#include "G4VEmModel.hh"
#include "G4VEmFluctuationModel.hh"

class G4ParticleChangeForLoss;

class G4mplIonisationModel : public G4VEmModel, public G4VEmFluctuationModel
{

public:

  G4mplIonisationModel(G4double mCharge, const G4String& nam = "mplIonisation");

  virtual ~G4mplIonisationModel();

  virtual void Initialise(const G4ParticleDefinition*, const G4DataVector&);

  virtual G4double ComputeDEDXPerVolume(const G4Material*,
                                        const G4ParticleDefinition*,
                                        G4double kineticEnergy,
                                        G4double cutEnergy);

  virtual void SampleSecondaries(std::vector<G4DynamicParticle*>*,
                                 const G4MaterialCutsCouple*,
                                 const G4DynamicParticle*,
                                 G4double tmin,
                                 G4double maxEnergy);


  virtual G4double SampleFluctuations(const G4Material*,
                                      const G4DynamicParticle*,
                                      G4double& tmax,
                                      G4double& length,
                                      G4double& meanLoss);

  virtual G4double Dispersion(const G4Material*,
                              const G4DynamicParticle*,
                              G4double& tmax,
                              G4double& length);

private:

  void SetParticle(const G4ParticleDefinition* p);
  G4double ComputeDEDXAhlen(const G4Material* material, G4double bg2);

  // hide assignment operator
  G4mplIonisationModel & operator=(const  G4mplIonisationModel &right);
  G4mplIonisationModel(const  G4mplIonisationModel&);

  const G4ParticleDefinition* monopole;
  G4ParticleChangeForLoss*    fParticleChange;

  G4double mass;
  G4double magCharge;
  G4double twoln10;
  G4double betalow;
  G4double betalim;
  G4double beta2lim;
  G4double bg2lim;
  G4double factlow;
  G4double chargeSquare;
  G4double dedxlim;
  G4int    nmpl;
  G4double pi_hbarc2_over_mc2;
  G4double approxConst;
};

#endif

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inline void G4mplIonisationModel::SampleSecondaries(std::vector<G4DynamicParticle*>*,
                                                    const G4MaterialCutsCouple*,
                                                    const G4DynamicParticle*,
                                                    G4double,
                                                    G4double)
{}

inline G4double G4mplIonisationModel::Dispersion(
                          const G4Material* material,
                          const G4DynamicParticle* dp,
                                G4double& tmax,
                                G4double& length)
{
  G4double siga = 0.0;
  G4double tau   = dp->GetKineticEnergy()/mass;
  if(tau > 0.0) { 
    G4double electronDensity = material->GetElectronDensity();
    G4double gam   = tau + 1.0;
    G4double invbeta2 = (gam*gam)/(tau * (tau+2.0));
    siga  = (invbeta2 - 0.5) * twopi_mc2_rcl2 * tmax * length
      * electronDensity * chargeSquare;
  }
  return siga;
}


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