RE02DetectorConstruction.cc

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// $Id: RE02DetectorConstruction.cc 75682 2013-11-05 09:11:19Z gcosmo $
//
 
#include "RE02DetectorConstruction.hh"

#include "G4PSEnergyDeposit3D.hh"
#include "G4PSNofStep3D.hh"
#include "G4PSCellFlux3D.hh"
#include "G4PSPassageCellFlux3D.hh"
#include "G4PSFlatSurfaceFlux3D.hh"
#include "G4PSFlatSurfaceCurrent3D.hh"

#include "G4SDParticleWithEnergyFilter.hh"
#include "G4SDParticleFilter.hh"
#include "G4SDChargedFilter.hh"

#include "G4NistManager.hh"
#include "G4Material.hh"
#include "G4Box.hh"
#include "G4LogicalVolume.hh"
#include "G4PVPlacement.hh"
#include "G4SDManager.hh"

#include "G4PVParameterised.hh"
#include "RE02NestedPhantomParameterisation.hh"

#include "G4VisAttributes.hh"
#include "G4Colour.hh"

#include "G4SystemOfUnits.hh"    
#include "G4ios.hh"

//=======================================================================
//  RE02DetectorConstruction
//
//  (Description)
//
//     Detector construction for example RE02.
//    
//   [Geometry] 
//     The world volume is defined as 200 cm x 200 cm x 200 cm box with Air.
//   Water phantom is defined as  200 mm x 200 mm x 400 mm box with Water.
//   The water phantom is divided into 100 segments in x,y plane using
//   replication,
//   and then divided into 200 segments perpendicular to z axis using nested 
//   parameterised volume.  
//    These values are defined at constructor,
//    e.g. the size of water phantom (fPhantomSize), and number of segmentation
//   of water phantom (fNx, fNy, fNz).
//
//   By default, lead plates are inserted into the position of even order 
//   segments.
//   NIST database is used for materials.
//
//
//   [Scorer]
//    Assignment of G4MultiFunctionalDetector and G4PrimitiveScorer 
//   is demonstrated in this example.
//       -------------------------------------------------
//       The collection names of defined Primitives are
//        0       PhantomSD/totalEDep 
//        1       PhantomSD/protonEDep
//        2       PhantomSD/protonNStep
//        3       PhantomSD/chargedPassCellFlux
//        4       PhantomSD/chargedCellFlux 
//        5       PhantomSD/chargedSurfFlux 
//        6       PhantomSD/gammaSurfCurr000
//        7       PhantomSD/gammaSurfCurr001
//        9       PhantomSD/gammaSurdCurr002
//       10       PhantomSD/gammaSurdCurr003
//      -------------------------------------------------
//      Please see README for detail description.
//
//=======================================================================

//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
RE02DetectorConstruction::RE02DetectorConstruction()
 : G4VUserDetectorConstruction() 
{
  // Default size of water phantom,and segmentation.
    fPhantomSize.setX(200.*mm);
    fPhantomSize.setY(200.*mm);
    fPhantomSize.setZ(400.*mm);
    fNx = fNy = fNz = 100;
    fInsertLead = TRUE;
}

//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
RE02DetectorConstruction::~RE02DetectorConstruction()
{;}

//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 G4VPhysicalVolume* RE02DetectorConstruction::Construct()
{
  //=====================
  // Material Definitions
  //=====================
  //  
  //-------- NIST Materials ----------------------------------------------------
  //  Material Information imported from NIST database.
  //
  G4NistManager* NISTman = G4NistManager::Instance();
  G4Material* air  = NISTman->FindOrBuildMaterial("G4_AIR");
  G4Material* water  = NISTman->FindOrBuildMaterial("G4_WATER");
  G4Material* lead = NISTman->FindOrBuildMaterial("G4_Pb");

  //
  // Print all the materials defined.
  G4cout << G4endl << "The materials defined are : " << G4endl << G4endl;
  G4cout << *(G4Material::GetMaterialTable()) << G4endl;

  //============================================================================
  //      Definitions of Solids, Logical Volumes, Physical Volumes 
  //============================================================================

  //-------------
  // World Volume 
  //-------------

  G4ThreeVector worldSize = G4ThreeVector(200*cm, 200*cm, 200*cm);
  
  G4Box * solidWorld
    = new G4Box("world", worldSize.x()/2., worldSize.y()/2., worldSize.z()/2.);
  G4LogicalVolume * logicWorld
    = new G4LogicalVolume(solidWorld, air, "World", 0, 0, 0);

  // 
  //  Must place the World Physical volume unrotated at (0,0,0).
  G4VPhysicalVolume * physiWorld
    = new G4PVPlacement(0,               // no rotation
                        G4ThreeVector(), // at (0,0,0)
                        logicWorld,      // its logical volume
                        "World",         // its name
                        0,               // its mother  volume
                        false,           // no boolean operations
                        0);              // copy number
                                 
  //---------------
  // Water Phantom
  //---------------

  //................................
  // Mother Volume of Water Phantom
  //................................

  //--  Default size of water phantom is defined at constructor.
  G4ThreeVector phantomSize = fPhantomSize; 
  
  G4Box * solidPhantom
    = new G4Box("phantom",
                phantomSize.x()/2., phantomSize.y()/2., phantomSize.z()/2.);
  G4LogicalVolume * logicPhantom
    = new G4LogicalVolume(solidPhantom, water, "Phantom", 0, 0, 0);  

  G4RotationMatrix* rot = new G4RotationMatrix();
  //rot->rotateY(30.*deg);
  G4ThreeVector positionPhantom;
  //G4VPhysicalVolume * physiPhantom =
  new G4PVPlacement(rot,             // no rotation
                    positionPhantom, // at (x,y,z)
                    logicPhantom,    // its logical volume
                    "Phantom",       // its name
                    logicWorld,      // its mother  volume
                    false,           // no boolean operations
                    0);              // copy number 

  //..............................................
  // Phantom segmentation using Parameterisation
  //..............................................
  //
  G4cout << "<-- RE02DetectorConstruction::Construct-------" <<G4endl;
  G4cout << "  Water Phantom Size " << fPhantomSize/mm       << G4endl;
  G4cout << "  Segmentation  ("<< fNx<<","<<fNy<<","<<fNz<<")"<< G4endl;
  G4cout << "  Lead plate at even copy # (0-False,1-True): " << IsLeadSegment()
         << G4endl;
  G4cout << "<---------------------------------------------"<< G4endl;
  // Number of segmentation.
  // - Default number of segmentation is defined at constructor.
  G4int nxCells = fNx;
  G4int nyCells = fNy;
  G4int nzCells = fNz;

  G4ThreeVector sensSize;
  sensSize.setX(phantomSize.x()/(G4double)nxCells);
  sensSize.setY(phantomSize.y()/(G4double)nyCells);
  sensSize.setZ(phantomSize.z()/(G4double)nzCells);
  // i.e Voxel size will be 2.0 x 2.0 x 2.0 mm3 cube by default.
  // 

  // Replication of Water Phantom Volume.
  // Y Slice
  G4String yRepName("RepY");
  G4VSolid* solYRep =
    new G4Box(yRepName,phantomSize.x()/2.,sensSize.y()/2.,phantomSize.z()/2.);
  G4LogicalVolume* logYRep =
    new G4LogicalVolume(solYRep,water,yRepName);
  //G4PVReplica* yReplica =
  new G4PVReplica(yRepName,logYRep,logicPhantom,kYAxis,fNy,sensSize.y());
  // X Slice
  G4String xRepName("RepX");
  G4VSolid* solXRep =
    new G4Box(xRepName,sensSize.x()/2.,sensSize.y()/2.,phantomSize.z()/2.);
  G4LogicalVolume* logXRep =
    new G4LogicalVolume(solXRep,water,xRepName);
  //G4PVReplica* xReplica =
  new G4PVReplica(xRepName,logXRep,logYRep,kXAxis,fNx,sensSize.x());

  //
  //..................................
  // Voxel solid and logical volumes
  //..................................
  // Z Slice
  G4String zVoxName("phantomSens");
  G4VSolid* solVoxel = 
    new G4Box(zVoxName,sensSize.x()/2.,sensSize.y()/2.,sensSize.z()/2.);
  fLVPhantomSens = new G4LogicalVolume(solVoxel,water,zVoxName);
  //
  //
  std::vector<G4Material*> phantomMat(2,water);
  if ( IsLeadSegment() ) phantomMat[1]=lead;
  //
  // Parameterisation for transformation of voxels.
  //  (voxel size is fixed in this example. 
  //  e.g. nested parameterisation handles material and transfomation of voxels.)
  RE02NestedPhantomParameterisation* paramPhantom
    = new RE02NestedPhantomParameterisation(sensSize/2.,nzCells,phantomMat);
  //G4VPhysicalVolume * physiPhantomSens =
    new G4PVParameterised("PhantomSens",     // their name
                          fLVPhantomSens,    // their logical volume
                          logXRep,           // Mother logical volume
                          kUndefined,        // Are placed along this axis 
                          nzCells,           // Number of cells
                          paramPhantom);     // Parameterisation.
  //   Optimization flag is avaiable for,
  //    kUndefined, kXAxis, kYAxis, kZAxis.
  //

  //=============================== 
  //   Visualization attributes 
  //===============================

  G4VisAttributes* boxVisAtt = new G4VisAttributes(G4Colour(1.0,1.0,1.0));
  logicWorld  ->SetVisAttributes(boxVisAtt);  
  //logicWorld->SetVisAttributes(G4VisAttributes::Invisible);  

  // Mother volume of WaterPhantom
  G4VisAttributes* phantomVisAtt = new G4VisAttributes(G4Colour(1.0,1.0,0.0));
  logicPhantom->SetVisAttributes(phantomVisAtt);
  
  // Replica
  G4VisAttributes* yRepVisAtt = new G4VisAttributes(G4Colour(0.0,1.0,0.0));
  logYRep->SetVisAttributes(yRepVisAtt);
  G4VisAttributes* xRepVisAtt = new G4VisAttributes(G4Colour(0.0,1.0,0.0));
  logXRep->SetVisAttributes(xRepVisAtt);
  
  // Skip the visualization for those voxels.
  fLVPhantomSens->SetVisAttributes(G4VisAttributes::Invisible);

  
  return physiWorld;
}

void RE02DetectorConstruction::ConstructSDandField() {

  //================================================
  // Sensitive detectors : MultiFunctionalDetector
  //================================================
  //
  //  Sensitive Detector Manager.
  G4SDManager* pSDman = G4SDManager::GetSDMpointer();
  //
  // Sensitive Detector Name
  G4String phantomSDname = "PhantomSD";
  
  //------------------------
  // MultiFunctionalDetector
  //------------------------
  //
  // Define MultiFunctionalDetector with name.
  G4MultiFunctionalDetector* mFDet
  = new G4MultiFunctionalDetector(phantomSDname);
  pSDman->AddNewDetector( mFDet );                // Register SD to SDManager.
  fLVPhantomSens->SetSensitiveDetector(mFDet);    // Assign SD to the logical volume.
  
  //---------------------------------------
  // SDFilter : Sensitive Detector Filters
  //---------------------------------------
  //
  // Particle Filter for Primitive Scorer with filter name(fltName)
  // and particle name(particleName),
  // or particle names are given by add("particle name"); method.
  //
  G4String fltName,particleName;
  //
  //-- proton filter
  G4SDParticleFilter* protonFilter =
  new G4SDParticleFilter(fltName="protonFilter", particleName="proton");
  //
  //-- electron filter
  G4SDParticleFilter* electronFilter =
  new G4SDParticleFilter(fltName="electronFilter");
  electronFilter->add(particleName="e+");   // accept electrons.
  electronFilter->add(particleName="e-");   // accept positorons.
  //
  //-- charged particle filter
  G4SDChargedFilter* chargedFilter =
  new G4SDChargedFilter(fltName="chargedFilter");
  
  //------------------------
  // PS : Primitive Scorers
  //------------------------
  // Primitive Scorers are used with SDFilters according to your purpose.
  //
  //
  //-- Primitive Scorer for Energy Deposit.
  //      Total, by protons, by electrons.
  G4String psName;
  G4PSEnergyDeposit3D * scorer0 = new G4PSEnergyDeposit3D(psName="totalEDep",
                                                          fNx,fNy,fNz);
  G4PSEnergyDeposit3D * scorer1 = new G4PSEnergyDeposit3D(psName="protonEDep",
                                                          fNx,fNy,fNz);
  scorer1->SetFilter(protonFilter);
  
  //
  //-- Number of Steps for protons
  G4PSNofStep3D * scorer2 =
  new G4PSNofStep3D(psName="protonNStep",fNx,fNy,fNz);
  scorer2->SetFilter(protonFilter);
  
  //
  //-- CellFlux for charged particles
  G4PSPassageCellFlux3D * scorer3 =
  new G4PSPassageCellFlux3D(psName="chargedPassCellFlux", fNx,fNy,fNz);
  G4PSCellFlux3D *        scorer4 =
  new G4PSCellFlux3D(psName="chargedCellFlux", fNx,fNy,fNz);
  G4PSFlatSurfaceFlux3D * scorer5 =
  new G4PSFlatSurfaceFlux3D(psName="chargedSurfFlux", fFlux_InOut,fNx,fNy,fNz);
  scorer3->SetFilter(chargedFilter);
  scorer4->SetFilter(chargedFilter);
  scorer5->SetFilter(chargedFilter);
  
  //
  //------------------------------------------------------------
  //  Register primitive scorers to MultiFunctionalDetector
  //------------------------------------------------------------
  mFDet->RegisterPrimitive(scorer0);
  mFDet->RegisterPrimitive(scorer1);
  mFDet->RegisterPrimitive(scorer2);
  mFDet->RegisterPrimitive(scorer3);
  mFDet->RegisterPrimitive(scorer4);
  mFDet->RegisterPrimitive(scorer5);
  
  //========================
  // More additional Primitive Scoreres
  //========================
  //
  //--- Surface Current for gamma with energy bin.
  // This example creates four primitive scorers.
  //  4 bins with energy   ---   Primitive Scorer Name
  //    1.     to  10 KeV,        gammaSurfCurr000
  //   10 keV  to 100 KeV,        gammaSurfCurr001
  //  100 keV  to   1 MeV,        gammaSurfCurr002
  //    1 MeV  to  10 MeV.        gammaSurfCurr003
  //
  char name[17];
  for ( G4int i = 0; i < 4; i++){
    std::sprintf(name,"gammaSurfCurr%03d",i);
    G4String psgName(name);
    G4double kmin = std::pow(10.,(G4double)i)*keV;
    G4double kmax = std::pow(10.,(G4double)(i+1))*keV;
    //-- Particle with kinetic energy filter.
    G4SDParticleWithEnergyFilter* pkinEFilter =
    new G4SDParticleWithEnergyFilter(fltName="gammaE filter",kmin,kmax);
    pkinEFilter->add("gamma");  // Accept only gamma.
    pkinEFilter->show();        // Show accepting condition to stdout.
    //-- Surface Current Scorer which scores  number of tracks in unit area.
    G4PSFlatSurfaceCurrent3D * scorer =
    new G4PSFlatSurfaceCurrent3D(psgName,fCurrent_InOut,fNx,fNy,fNz);
    scorer->SetFilter(pkinEFilter);    // Assign filter.
    mFDet->RegisterPrimitive(scorer);  // Register it to MultiFunctionalDetector.
  }

}