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// $Id: G4AdjointPosOnPhysVolGenerator.hh,v 1.2 2009/11/18 17:57:59 gcosmo Exp $
// GEANT4 tag $Name: geant4-09-03 $
//
/////////////////////////////////////////////////////////////////////////////////
// Class Name: G4AdjointPosOnPhysVolGenerator
// Author: L. Desorgher
// Organisation: SpaceIT GmbH
// Contract: ESA contract 21435/08/NL/AT
// Customer: ESA/ESTEC
/////////////////////////////////////////////////////////////////////////////////
//
// CHANGE HISTORY
// --------------
// ChangeHistory:
// 1st June 2006 creation by L. Desorgher
//
//-------------------------------------------------------------
// Documentation:
// This class is responsible for the generation of primary adjoint particle on the external surface of a user selected volume.
// The particle are generated uniformly on the surface with the angular distribution set to a cosine law relative to normal of the surface.
// It is equivalent to the flux going in from the surface if an isotropic flux is considered outside.
// It uses ray tracking technique and can be applied to all kind of convex volume. Uisng the ray tracking technique the area
// of the external surface is also computed. The area is needed to fix the weight of the primary adjoint particle.
// At the time of the development of this class, generation of particle on volume surface and computation of surface was limited in G4,
// therfore the general ray tracking technique was adopted. It could be now (2009) that direct method of G4VSolid could be used instead. To be checked!
//
//
//
#ifndef G4AdjointPosOnPhysVolGenerator_h
#define G4AdjointPosOnPhysVolGenerator_h 1
#include "G4VPhysicalVolume.hh"
#include "G4AffineTransform.hh"
#include "G4ThreeVector.hh"
class G4VSolid;
class G4AdjointPosOnPhysVolGenerator
///////////////////////
{
//--------
public: //without description
//--------
static G4AdjointPosOnPhysVolGenerator* GetInstance();
//--------
public: //public methods
//--------
G4VPhysicalVolume* DefinePhysicalVolume(const G4String& aName);
void DefinePhysicalVolume1(const G4String& aName);
G4double ComputeAreaOfExtSurface();
G4double ComputeAreaOfExtSurface(G4int NStat);
G4double ComputeAreaOfExtSurface(G4double epsilon);
G4double ComputeAreaOfExtSurface(G4VSolid* aSolid);
G4double ComputeAreaOfExtSurface(G4VSolid* aSolid,G4int NStat);
G4double ComputeAreaOfExtSurface(G4VSolid* aSolid,G4double epsilon);
void GenerateAPositionOnTheExtSurfaceOfASolid(G4VSolid* aSolid,G4ThreeVector& p, G4ThreeVector& direction);
void GenerateAPositionOnTheExtSurfaceOfTheSolid(G4ThreeVector& p, G4ThreeVector& direction);
void GenerateAPositionOnTheExtSurfaceOfThePhysicalVolume(G4ThreeVector& p, G4ThreeVector& direction);
void GenerateAPositionOnTheExtSurfaceOfThePhysicalVolume(G4ThreeVector& p, G4ThreeVector& direction,
G4double& costh_to_normal);
//inline public methods
inline void SetSolid(G4VSolid* aSolid){theSolid=aSolid;}
inline G4double GetAreaOfExtSurfaceOfThePhysicalVolume(){return AreaOfExtSurfaceOfThePhysicalVolume;}
inline G4double GetCosThDirComparedToNormal(){return CosThDirComparedToNormal;}
//---------
private: //private methods
//---------
G4AdjointPosOnPhysVolGenerator();
~G4AdjointPosOnPhysVolGenerator();
G4double ComputeAreaOfExtSurfaceStartingFromSphere(G4VSolid* aSolid,G4int NStat);
G4double ComputeAreaOfExtSurfaceStartingFromBox(G4VSolid* aSolid,G4int NStat);
void GenerateAPositionOnASolidBoundary(G4VSolid* aSolid,G4ThreeVector& p, G4ThreeVector& direction);
G4double GenerateAPositionOnASphereBoundary(G4VSolid* aSolid,G4ThreeVector& p, G4ThreeVector& direction);
G4double GenerateAPositionOnABoxBoundary(G4VSolid* aSolid,G4ThreeVector& p, G4ThreeVector& direction);
void ComputeTransformationFromPhysVolToWorld();
//---------
private: //attributes
//---------
static G4AdjointPosOnPhysVolGenerator* theInstance;
G4VSolid* theSolid;
G4VPhysicalVolume* thePhysicalVolume;
G4int NStat;
G4double epsilon;
G4bool UseSphere;
G4String ModelOfSurfaceSource;
G4double ExtSourceRadius;
G4double ExtSourceDx,ExtSourceDy,ExtSourceDz ;
G4AffineTransform theTransformationFromPhysVolToWorld;
G4double AreaOfExtSurfaceOfThePhysicalVolume;
G4double CosThDirComparedToNormal;
};
#endif