#include <B01DetectorConstruction.hh>

Inheritance diagram for B01DetectorConstruction:

Collaboration diagram for B01DetectorConstruction:

Public Member Functions
	B01DetectorConstruction ()

	~B01DetectorConstruction ()

virtual G4VPhysicalVolume *	Construct ()

G4VIStore *	CreateImportanceStore ()

G4VWeightWindowStore *	CreateWeightWindowStore ()

G4String	GetCellName (G4int i)

G4VPhysicalVolume *	GetWorldVolume ()

void	SetSensitive ()

virtual void	ConstructSDandField ()

Public Member Functions inherited from G4VUserDetectorConstruction
	G4VUserDetectorConstruction ()

virtual	~G4VUserDetectorConstruction ()

virtual void	CloneSD ()

virtual void	CloneF ()

void	RegisterParallelWorld (G4VUserParallelWorld *)

G4int	ConstructParallelGeometries ()

void	ConstructParallelSD ()

G4int	GetNumberOfParallelWorld () const

G4VUserParallelWorld *	GetParallelWorld (G4int i) const

Private Attributes
std::vector< G4LogicalVolume *>	fLogicalVolumeVector

std::vector< G4VPhysicalVolume *>	fPhysicalVolumeVector

G4VPhysicalVolume *	fWorldVolume

Additional Inherited Members
Protected Member Functions inherited from G4VUserDetectorConstruction
void	SetSensitiveDetector (const G4String &logVolName, G4VSensitiveDetector *aSD, G4bool multi=false)

void	SetSensitiveDetector (G4LogicalVolume logVol, G4VSensitiveDetector aSD)

Detailed Description

Definition at line 44 of file B01DetectorConstruction.hh.

Constructor & Destructor Documentation

◆ B01DetectorConstruction()

B01DetectorConstruction::B01DetectorConstruction ( )

Definition at line 68 of file B01DetectorConstruction.cc.

                                                  :
   G4VUserDetectorConstruction(),
   fLogicalVolumeVector(),fPhysicalVolumeVector()
 {;}

◆ ~B01DetectorConstruction()

B01DetectorConstruction::~B01DetectorConstruction ( )

Definition at line 75 of file B01DetectorConstruction.cc.

 {
   fLogicalVolumeVector.clear();
   fPhysicalVolumeVector.clear();
 }

Member Function Documentation

◆ Construct()

G4VPhysicalVolume * B01DetectorConstruction::Construct ( void )

virtual

Implements G4VUserDetectorConstruction.

Definition at line 83 of file B01DetectorConstruction.cc.

 {
   G4double pos_x;
   G4double pos_y;
   G4double pos_z; 
 
   G4double density, pressure, temperature;
   G4double A;
   G4int Z;
 
   G4String name, symbol;
   G4double z;
   G4double fractionmass;
 
   A = 1.01*g/mole;
   G4Element* elH  = new G4Element(name="Hydrogen",symbol="H" , Z= 1, A);
 
   A = 12.01*g/mole;
   G4Element* elC  = new G4Element(name="Carbon"  ,symbol="C" , Z = 6, A);
 
   A = 16.00*g/mole;
   G4Element* elO  = new G4Element(name="Oxygen"  ,symbol="O" , Z= 8, A);
 
   A = 22.99*g/mole; 
   G4Element* elNa  = new G4Element(name="Natrium"  ,symbol="Na" , Z=11 , A);
 
   A = 200.59*g/mole; 
   G4Element* elHg  = new G4Element(name="Hg"  ,symbol="Hg" , Z=80, A);
 
   A = 26.98*g/mole; 
   G4Element* elAl  = new G4Element(name="Aluminium"  ,symbol="Al" , Z=13, A);
 
   A = 28.09*g/mole;
   G4Element* elSi  = new G4Element(name="Silicon", symbol="Si", Z=14, A);
 
   A = 39.1*g/mole; 
   G4Element* elK  = new G4Element(name="K"  ,symbol="K" , Z=19 , A);
 
   A = 69.72*g/mole; 
   G4Element* elCa  = new G4Element(name="Calzium"  ,symbol="Ca" , Z=31 , A);
 
   A = 55.85*g/mole;
   G4Element* elFe = new G4Element(name="Iron"    ,symbol="Fe", Z=26, A);
 
   density     = universe_mean_density;            //from PhysicalConstants.h
   pressure    = 3.e-18*pascal;
   temperature = 2.73*kelvin;
   G4Material *Galactic = 
     new G4Material(name="Galactic", z=1., A=1.01*g/mole, density,
                    kStateGas,temperature,pressure);
 
   density = 2.03*g/cm3;
   G4Material* Concrete = new G4Material("Concrete", density, 10);
   Concrete->AddElement(elH , fractionmass= 0.01);
   Concrete->AddElement(elO , fractionmass= 0.529);
   Concrete->AddElement(elNa , fractionmass= 0.016);
   Concrete->AddElement(elHg , fractionmass= 0.002);
   Concrete->AddElement(elAl , fractionmass= 0.034);
   Concrete->AddElement(elSi , fractionmass= 0.337);
   Concrete->AddElement(elK , fractionmass= 0.013);
   Concrete->AddElement(elCa , fractionmass= 0.044);
   Concrete->AddElement(elFe , fractionmass= 0.014);
   Concrete->AddElement(elC , fractionmass= 0.001);
 
   // world cylinder volume
 
   // world solid
 
   G4double innerRadiusCylinder = 0*cm;
   G4double outerRadiusCylinder = 100*cm; 
   G4double heightCylinder       = 100*cm;
   G4double startAngleCylinder  = 0*deg;
   G4double spanningAngleCylinder    = 360*deg;
 
   G4Tubs *worldCylinder = new G4Tubs("worldCylinder",
                                      innerRadiusCylinder,
                                      outerRadiusCylinder,
                                      heightCylinder,
                                      startAngleCylinder,
                                      spanningAngleCylinder);
 
   // logical world
 
   G4LogicalVolume *worldCylinder_log = 
     new G4LogicalVolume(worldCylinder, Galactic, "worldCylinder_log");
   fLogicalVolumeVector.push_back(worldCylinder_log); 
 
   name = "shieldWorld";
   fWorldVolume = new 
     G4PVPlacement(0, G4ThreeVector(0,0,0), worldCylinder_log,
                   name, 0, false, 0);
 
 
   fPhysicalVolumeVector.push_back(fWorldVolume);
 
   // creating 18 slabs of 10 cm thick concrete
 
   G4double innerRadiusShield = 0*cm;
   G4double outerRadiusShield = 100*cm;
   G4double heightShield       = 5*cm;
   G4double startAngleShield  = 0*deg;
   G4double spanningAngleShield    = 360*deg;
 
   G4Tubs *aShield = new G4Tubs("aShield",
                                innerRadiusShield,
                                outerRadiusShield,
                                heightShield,
                                startAngleShield,
                                spanningAngleShield);
   
   // logical shield
 
   G4LogicalVolume *aShield_log =
     new G4LogicalVolume(aShield, Concrete, "aShield_log");
   fLogicalVolumeVector.push_back(aShield_log);
 
   G4VisAttributes* pShieldVis = new G4VisAttributes(G4Colour(0.0,0.0,1.0));
   pShieldVis->SetForceSolid(true);
   aShield_log->SetVisAttributes(pShieldVis);
 
   // physical shields
 
   G4int i;
   G4double startz = -85*cm; 
   for (i=1; i<=18; i++)
   {
     name = GetCellName(i);
     pos_x = 0*cm;
     pos_y = 0*cm;
     pos_z = startz + (i-1) * (2*heightShield);
     G4VPhysicalVolume *pvol = 
       new G4PVPlacement(0, 
                         G4ThreeVector(pos_x, pos_y, pos_z),
                         aShield_log, 
                         name, 
                         worldCylinder_log, 
                         false, 
                         i); 
     fPhysicalVolumeVector.push_back(pvol);
   }
 
   // filling the rest of the world volume behind the concrete with
   // another slab which should get the same importance value 
   // or lower weight bound as the last slab
   //
   innerRadiusShield = 0*cm;
   outerRadiusShield = 100*cm;
   heightShield       = 5*cm;
   startAngleShield  = 0*deg;
   spanningAngleShield    = 360*deg;
 
   G4Tubs *aRest = new G4Tubs("Rest",
                              innerRadiusShield,
                              outerRadiusShield,
                              heightShield,
                              startAngleShield,
                              spanningAngleShield);
   
   G4LogicalVolume *aRest_log =
     new G4LogicalVolume(aRest, Galactic, "aRest_log");
   fLogicalVolumeVector.push_back(aRest_log);
   name = "rest";
     
   pos_x = 0*cm;
   pos_y = 0*cm;
   pos_z = 95*cm;
   G4VPhysicalVolume *pvol_rest = 
     new G4PVPlacement(0, 
                       G4ThreeVector(pos_x, pos_y, pos_z),
                       aRest_log, 
                       name, 
                       worldCylinder_log, 
                       false, 
                       19); // i=19
 
   fPhysicalVolumeVector.push_back(pvol_rest);
 
   SetSensitive();
   return fWorldVolume;
 }

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◆ ConstructSDandField()

void B01DetectorConstruction::ConstructSDandField ( )

virtual

Reimplemented from G4VUserDetectorConstruction.

Definition at line 409 of file B01DetectorConstruction.cc.

 {
 
   //  Sensitive Detector Manager.
   G4SDManager* SDman = G4SDManager::GetSDMpointer();
   // Sensitive Detector Name
   G4String concreteSDname = "ConcreteSD";
 
   //------------------------
   // MultiFunctionalDetector
   //------------------------
   //
   // Define MultiFunctionalDetector with name.
   G4MultiFunctionalDetector* MFDet = 
                          new G4MultiFunctionalDetector(concreteSDname);
   SDman->AddNewDetector( MFDet );                 // Register SD to SDManager
 
 
   G4String fltName,particleName;
   G4SDParticleFilter* neutronFilter = 
       new G4SDParticleFilter(fltName="neutronFilter", particleName="neutron");
 
   MFDet->SetFilter(neutronFilter);
 
 
   for (std::vector<G4LogicalVolume *>::iterator it = 
                                                 fLogicalVolumeVector.begin();
        it != fLogicalVolumeVector.end(); it++){
     //      (*it)->SetSensitiveDetector(MFDet);
       SetSensitiveDetector((*it)->GetName(), MFDet);
   }
 
   G4String psName;
   G4PSNofCollision*   scorer0 = new G4PSNofCollision(psName="Collisions");  
   MFDet->RegisterPrimitive(scorer0);
 
 
   G4PSNofCollision*   scorer1 = new G4PSNofCollision(psName="CollWeight");  
   scorer1->Weighted(true);
   MFDet->RegisterPrimitive(scorer1);
 
 
   G4PSPopulation*   scorer2 = new G4PSPopulation(psName="Population");  
   MFDet->RegisterPrimitive(scorer2);
 
   G4PSTrackCounter* scorer3 = new G4PSTrackCounter(psName="TrackEnter"
                                                   ,fCurrent_In);  
   MFDet->RegisterPrimitive(scorer3);
 
   G4PSTrackLength* scorer4 = new G4PSTrackLength(psName="SL");  
   MFDet->RegisterPrimitive(scorer4);
 
   G4PSTrackLength* scorer5 = new G4PSTrackLength(psName="SLW");  
   scorer5->Weighted(true);
   MFDet->RegisterPrimitive(scorer5);
 
   G4PSTrackLength* scorer6 = new G4PSTrackLength(psName="SLWE");  
   scorer6->Weighted(true);
   scorer6->MultiplyKineticEnergy(true);
   MFDet->RegisterPrimitive(scorer6);
 
   G4PSTrackLength* scorer7 = new G4PSTrackLength(psName="SLW_V");  
   scorer7->Weighted(true);
   scorer7->DivideByVelocity(true);
   MFDet->RegisterPrimitive(scorer7);
 
   G4PSTrackLength* scorer8 = new G4PSTrackLength(psName="SLWE_V");  
   scorer8->Weighted(true);
   scorer8->MultiplyKineticEnergy(true);
   scorer8->DivideByVelocity(true);
   MFDet->RegisterPrimitive(scorer8);
 
 }

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◆ CreateImportanceStore()

G4VIStore * B01DetectorConstruction::CreateImportanceStore ( )

Definition at line 268 of file B01DetectorConstruction.cc.

 {
   G4cout << " B01DetectorConstruction:: Creating Importance Store " << G4endl;
   if (!fPhysicalVolumeVector.size())
   {
     G4Exception("B01DetectorConstruction::CreateImportanceStore"
                ,"exampleB01_0001",RunMustBeAborted
                ,"no physical volumes created yet!");
   }
 
   fWorldVolume = fPhysicalVolumeVector[0];
 
   // creating and filling the importance store
   
   G4IStore *istore = G4IStore::GetInstance();
 
   G4int n = 0;
   G4double imp =1;
   istore->AddImportanceGeometryCell(1,  *fWorldVolume);
   for (std::vector<G4VPhysicalVolume *>::iterator
        it =  fPhysicalVolumeVector.begin();
        it != fPhysicalVolumeVector.end() - 1; it++)
   {
     if (*it != fWorldVolume)
     {
       imp = std::pow(2., n++);
       G4cout << "Going to assign importance: " << imp << ", to volume: " 
              << (*it)->GetName() << G4endl;
       istore->AddImportanceGeometryCell(imp, *(*it),n);
     }
   }
 
   // the remaining part pf the geometry (rest) gets the same
   // importance as the last conrete cell
   //
   istore->AddImportanceGeometryCell(imp, 
           *(fPhysicalVolumeVector[fPhysicalVolumeVector.size()-1]),++n);
   
   return istore;
 }

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