source: trunk/examples/extended/field/field02/src/F02DetectorConstruction.cc @ 1287

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// $Id: F02DetectorConstruction.cc,v 1.13 2009/11/05 01:08:51 gum Exp $
// GEANT4 tag $Name: geant4-09-03-cand-01 $
//
// 

#include "F02DetectorConstruction.hh"
#include "F02DetectorMessenger.hh"

#include "F02CalorimeterSD.hh"
#include "F02ElectricFieldSetup.hh"


#include "G4Material.hh"
#include "G4Tubs.hh"
#include "G4LogicalVolume.hh"
#include "G4PVPlacement.hh"
#include "G4UniformMagField.hh"
#include "G4FieldManager.hh"
#include "G4TransportationManager.hh"
#include "G4SDManager.hh"
#include "G4RunManager.hh"

#include "G4GeometryManager.hh"
#include "G4PhysicalVolumeStore.hh"
#include "G4LogicalVolumeStore.hh"
#include "G4SolidStore.hh"

#include "G4ios.hh"

/////////////////////////////////////////////////////////////////////////////
//
//

F02DetectorConstruction::F02DetectorConstruction()
 : solidWorld(0), logicWorld(0), physiWorld(0),
   solidAbsorber(0),logicAbsorber(0), physiAbsorber(0),
   fEmFieldSetup(0), calorimeterSD(0),
   AbsorberMaterial(0), worldchanged(false), WorldMaterial(0)
{
  // default parameter values of the calorimeter

  WorldSizeZ = 80.*cm;
  WorldSizeR = 20.*cm;

  AbsorberThickness = 40.0*mm;

  AbsorberRadius   = 10.*cm;
  zAbsorber = 36.*cm ;

  // create commands for interactive definition of the calorimeter  

  detectorMessenger = new F02DetectorMessenger(this);
  
  DefineMaterials();

  fEmFieldSetup = new F02ElectricFieldSetup() ;
}

//////////////////////////////////////////////////////////////////////////
//
//

F02DetectorConstruction::~F02DetectorConstruction()
{ 
  delete detectorMessenger;
  delete fEmFieldSetup ;
}

//////////////////////////////////////////////////////////////////////////
//
//

G4VPhysicalVolume* F02DetectorConstruction::Construct()
{
  return ConstructCalorimeter();
}

//////////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::DefineMaterials()
{ 
 //This function illustrates the possible ways to define materials
 
  G4String name, symbol ;             // a=mass of a mole;
  G4double a, z, density ;            // z=mean number of protons;  
  G4int nel;
  G4int ncomponents;
  G4double fractionmass, pressure, temperature;

//
// define Elements
//

  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 = 14.01*g/mole;
  G4Element* elN  = new G4Element(name="Nitrogen",symbol="N" , z= 7., a);

  a = 16.00*g/mole;
  G4Element* elO  = new G4Element(name="Oxygen"  ,symbol="O" , z= 8., a);

  a = 39.948*g/mole;
  G4Element* elAr = new G4Element(name="Argon", symbol="Ar", z=18., a);

//
// define simple materials
//

  // Mylar

  density = 1.39*g/cm3;
  G4Material* Mylar = new G4Material(name="Mylar", density, nel=3);
  Mylar->AddElement(elO,2);
  Mylar->AddElement(elC,5);
  Mylar->AddElement(elH,4);

  // Polypropelene

  G4Material* CH2 = new G4Material ("Polypropelene" , 0.91*g/cm3, 2);
  CH2->AddElement(elH,2);
  CH2->AddElement(elC,1);

  // Krypton as detector gas, STP

  density = 3.700*mg/cm3 ;
  a = 83.80*g/mole ;
  G4Material* Kr  = new G4Material(name="Kr",z=36., a, density );

  // Dry air (average composition)

  density = 1.7836*mg/cm3 ;       // STP
  G4Material* Argon = new G4Material(name="Argon"  , density, ncomponents=1);
  Argon->AddElement(elAr, 1);

  density = 1.25053*mg/cm3 ;       // STP
  G4Material* Nitrogen = new G4Material(name="N2"  , density, ncomponents=1);
  Nitrogen->AddElement(elN, 2);

  density = 1.4289*mg/cm3 ;       // STP
  G4Material* Oxygen = new G4Material(name="O2"  , density, ncomponents=1);
  Oxygen->AddElement(elO, 2);


  density = 1.2928*mg/cm3 ;       // STP

  temperature = STP_Temperature;
  pressure = 1.0e-0*STP_Pressure;

  G4Material* Air = new G4Material(name="Air"  , density, ncomponents=3,
                                   kStateGas,temperature,pressure);
  Air->AddMaterial( Nitrogen, fractionmass = 0.7557 ) ;
  Air->AddMaterial( Oxygen,   fractionmass = 0.2315 ) ;
  Air->AddMaterial( Argon,    fractionmass = 0.0128 ) ;

  // Xenon as detector gas, STP

  density = 5.858*mg/cm3 ;
  a = 131.29*g/mole ;
  G4Material* Xe  = new G4Material(name="Xenon",z=54., a, density );

  // Carbon dioxide, STP

  density = 1.842*mg/cm3;
  G4Material* CarbonDioxide = new G4Material(name="CO2", density, nel=2);
  CarbonDioxide->AddElement(elC,1);
  CarbonDioxide->AddElement(elO,2);

  // 80% Xe + 20% CO2, STP

  density = 5.0818*mg/cm3 ;      
  G4Material* Xe20CO2 = new G4Material(name="Xe20CO2"  , density, ncomponents=2);
  Xe20CO2->AddMaterial( Xe,              fractionmass = 0.922 ) ;
  Xe20CO2->AddMaterial( CarbonDioxide,   fractionmass = 0.078 ) ;

  // 80% Kr + 20% CO2, STP

  density = 3.601*mg/cm3 ;      
  G4Material* Kr20CO2 = new G4Material(name="Kr20CO2"  , density, 
                                                             ncomponents=2);
  Kr20CO2->AddMaterial( Kr,              fractionmass = 0.89 ) ;
  Kr20CO2->AddMaterial( CarbonDioxide,   fractionmass = 0.11 ) ;


  G4cout << *(G4Material::GetMaterialTable()) << G4endl;

  AbsorberMaterial = Kr20CO2 ;   // XeCO2CF4  ; 

  WorldMaterial    = Air ;
}

/////////////////////////////////////////////////////////////////////////
//
//
  
G4VPhysicalVolume* F02DetectorConstruction::ConstructCalorimeter()
{
  // complete the Calor parameters definition and Print 

  ComputeCalorParameters();
  PrintCalorParameters();
      
  // Cleanup old geometry

  if (physiWorld)
  {
    G4GeometryManager::GetInstance()->OpenGeometry();
    G4PhysicalVolumeStore::GetInstance()->Clean();
    G4LogicalVolumeStore::GetInstance()->Clean();
    G4SolidStore::GetInstance()->Clean();
  }

  // World
  
  solidWorld = new G4Tubs("World",                              //its name
                   0.,WorldSizeR,WorldSizeZ/2.,0.,twopi);       //its size
                         
  logicWorld = new G4LogicalVolume(solidWorld,          //its solid
                                   WorldMaterial,       //its material
                                   "World");            //its name
                                   
  physiWorld = new G4PVPlacement(0,                     //no rotation
                                 G4ThreeVector(),       //at (0,0,0)
                                 "World",               //its name
                                 logicWorld,            //its logical volume
                                 0,                     //its mother  volume
                                 false,                 //no boolean operation
                                 0);                    //copy number                             
  // Absorber

  if (AbsorberThickness > 0.) 
  { 
      solidAbsorber = new G4Tubs("Absorber",            
                          0.,AbsorberRadius,AbsorberThickness/2.,0.,twopi); 
                          
      logicAbsorber = new G4LogicalVolume(solidAbsorber,    
                                          AbsorberMaterial, 
                                          "Absorber");     
                                          
      physiAbsorber = new G4PVPlacement(0,                 
                    G4ThreeVector(0.,0.,zAbsorber),        
                                        "Absorber",        
                                        logicAbsorber,     
                                        physiWorld,       
                                        false,             
                                        0);                
  }
                                 
  // Sensitive Detectors: Absorber 
  
  G4SDManager* SDman = G4SDManager::GetSDMpointer();

  if(!calorimeterSD)
  {
    calorimeterSD = new F02CalorimeterSD("CalorSD",this);
    SDman->AddNewDetector( calorimeterSD );
  }
  if (logicAbsorber)  logicAbsorber->SetSensitiveDetector(calorimeterSD);

  return physiWorld;
}

////////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::PrintCalorParameters()
{
  G4cout << "\n The  WORLD   is made of " 
       << WorldSizeZ/mm << "mm of " << WorldMaterial->GetName() ;
  G4cout << ", the transverse size (R) of the world is " << WorldSizeR/mm << " mm. " << G4endl;
  G4cout << " The ABSORBER is made of " 
       << AbsorberThickness/mm << "mm of " << AbsorberMaterial->GetName() ;
  G4cout << ", the transverse size (R) is " << AbsorberRadius/mm << " mm. " << G4endl;
  G4cout << " Z position of the (middle of the) absorber " << zAbsorber/mm << "  mm." << G4endl;
  G4cout << G4endl;
}

///////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetAbsorberMaterial(G4String materialChoice)
{
  // get the pointer to the material table
  const G4MaterialTable* theMaterialTable = G4Material::GetMaterialTable();

  // search the material by its name   
  G4Material* pttoMaterial;
  for (size_t J=0 ; J<theMaterialTable->size() ; J++)
   { pttoMaterial = (*theMaterialTable)[J];     
     if(pttoMaterial->GetName() == materialChoice)
        {
          AbsorberMaterial = pttoMaterial;
          logicAbsorber->SetMaterial(pttoMaterial); 
        }             
   }
}

////////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetWorldMaterial(G4String materialChoice)
{
  // get the pointer to the material table
  const G4MaterialTable* theMaterialTable = G4Material::GetMaterialTable();

  // search the material by its name   
  G4Material* pttoMaterial;
  for (size_t J=0 ; J<theMaterialTable->size() ; J++)
   { pttoMaterial = (*theMaterialTable)[J];     
     if(pttoMaterial->GetName() == materialChoice)
        {
          WorldMaterial = pttoMaterial;
          logicWorld->SetMaterial(pttoMaterial); 
        }             
   }
}

///////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetAbsorberThickness(G4double val)
{
  // change Absorber thickness and recompute the calorimeter parameters
  AbsorberThickness = val;
  ComputeCalorParameters();
}  

/////////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetAbsorberRadius(G4double val)
{
  // change the transverse size and recompute the calorimeter parameters
  AbsorberRadius = val;
  ComputeCalorParameters();
}  

////////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetWorldSizeZ(G4double val)
{
  worldchanged=true;
  WorldSizeZ = val;
  ComputeCalorParameters();
}  

///////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetWorldSizeR(G4double val)
{
  worldchanged=true;
  WorldSizeR = val;
  ComputeCalorParameters();
}  

//////////////////////////////////////////////////////////////////////////////
//
//

void F02DetectorConstruction::SetAbsorberZpos(G4double val)
{
  zAbsorber  = val;
  ComputeCalorParameters();
}  


////////////////////////////////////////////////////////////////////////////
//
//
  
void F02DetectorConstruction::UpdateGeometry()
{
  G4RunManager::GetRunManager()->DefineWorldVolume(ConstructCalorimeter());
}

//
//
////////////////////////////////////////////////////////////////////////////