示例#1
0
void commonConfig(ConfigVersion_t configVersion = kConfigV0)
{
  cout << "Running commonConfig.C ... " << endl;

    // Set Random Number seed
  gRandom->SetSeed(123456); // Set 0 to use the currecnt time
  IlcLog::Message(IlcLog::kInfo, Form("Seed for random number generation = %d",gRandom->GetSeed()), "Config.C", "Config.C", "Config()","Config.C", __LINE__);


  //=======================================================================
  // Load Pythia libraries
  //=======================================================================

  LoadPythia();

  //=======================================================================
  // ILC steering object (IlcRunLoader)
  //=======================================================================

  IlcRunLoader* rl 
    = IlcRunLoader::Open("gilc.root",
			  IlcConfig::GetDefaultEventFolderName(),
			  "recreate");
  if ( ! rl ) {
    gIlc->Fatal("Config.C","Can not instatiate the Run Loader");
    return;
  }
  rl->SetCompressionLevel(2);
  rl->SetNumberOfEventsPerFile(3);
  gIlc->SetRunLoader(rl);
  
  //======================================================================
  // Trigger configuration
  //=======================================================================

  IlcSimulation::Instance()->SetTriggerConfig(pprTrigConfName[strig]);
  cout << "Trigger configuration is set to  " << pprTrigConfName[strig] << endl;

  // ============================= 
  // Magnetic field
  // ============================= 

  // Field (L3 0.5 T)
  IlcMagF* field = new IlcMagF("Maps","Maps", -1., -1., IlcMagF::k5kG);
  TGeoGlobalMagField::Instance()->SetField(field);

  printf("\n \n Comment: %s \n \n", comment.Data());

  // ============================= 
  // Modules
  // ============================= 

  rl->CdGAFile();

  Int_t   iABSO  =  1;
  Int_t   iDIPO  =  1;
  Int_t   iFMD   =  1;
  Int_t   iFRAME =  1;
  Int_t   iHALL  =  1;
  Int_t   iITS   =  1;
  Int_t   iMAG   =  1;
  Int_t   iMUON  =  1;
  Int_t   iPHOS  =  1;
  Int_t   iPIPE  =  1;
  Int_t   iPMD   =  1;
  Int_t   iHMPID =  1;
  Int_t   iSHIL  =  1;
  Int_t   iT0    =  1;
  Int_t   iTOF   =  1;
  Int_t   iTPC   =  1;
  Int_t   iTRD   =  1;
  Int_t   iZDC   =  1;
  Int_t   iEMCAL =  1;
  Int_t   iACORDE = 1;
  Int_t   iVZERO =  1;

  rl->CdGAFile();
  //=================== Ilc BODY parameters =============================
  IlcBODY *BODY = new IlcBODY("BODY", "Ilc envelop");

  if (iMAG)
  {
      //=================== MAG parameters ============================
      // --- Start with Magnet since detector layouts may be depending ---
      // --- on the selected Magnet dimensions ---
      IlcMAG *MAG = new IlcMAG("MAG", "Magnet");
  }


  if (iABSO)
  {
      //=================== ABSO parameters ============================
      IlcABSO *ABSO = new IlcABSOv3("ABSO", "Muon Absorber");
  }

  if (iDIPO)
  {
      //=================== DIPO parameters ============================

      IlcDIPO *DIPO = new IlcDIPOv3("DIPO", "Dipole version 3");
  }

  if (iHALL)
  {
      //=================== HALL parameters ============================

      IlcHALL *HALL = new IlcHALLv3("HALL", "Ilc Hall");
  }


  if (iFRAME)
  {
      //=================== FRAME parameters ============================

      IlcFRAMEv2 *FRAME = new IlcFRAMEv2("FRAME", "Space Frame");
      FRAME->SetHoles(1);
  }

  if (iSHIL)
  {
      //=================== SHIL parameters ============================

      IlcSHIL *SHIL = new IlcSHILv3("SHIL", "Shielding Version 3");
  }


  if (iPIPE)
  {
      //=================== PIPE parameters ============================

      IlcPIPE *PIPE = new IlcPIPEv3("PIPE", "Beam Pipe");
  }
 
  if (iITS)
  {
      //=================== ITS parameters ============================

      IlcITS *ITS  = new IlcITSv11("ITS","ITS v11");
  }

  if (iTPC)
  {
      //============================ TPC parameters ===================
      IlcTPC *TPC = new IlcTPCv2("TPC", "Default");
  }


  if (iTOF) {
      //=================== TOF parameters ============================
      IlcTOF *TOF = new IlcTOFv6T0("TOF", "normal TOF");
  }


  if (iHMPID)
  {
      //=================== HMPID parameters ===========================
      IlcHMPID *HMPID = new IlcHMPIDv3("HMPID", "normal HMPID");

  }


  if (iZDC)
  {
      //=================== ZDC parameters ============================

      IlcZDC *ZDC = new IlcZDCv3("ZDC", "normal ZDC");
  }

  if (iTRD)
  {
      //=================== TRD parameters ============================

      IlcTRD *TRD = new IlcTRDv1("TRD", "TRD slow simulator");
      if ( configVersion == kConfigV1 ) {
        IlcTRDgeometry *geoTRD = TRD->GetGeometry();
        // Partial geometry: modules at 0,1,7,8,9,16,17
        // starting at 3h in positive direction
        geoTRD->SetSMstatus(2,0);
        geoTRD->SetSMstatus(3,0);
        geoTRD->SetSMstatus(4,0);
        geoTRD->SetSMstatus(5,0);
        geoTRD->SetSMstatus(6,0);
        geoTRD->SetSMstatus(11,0);
        geoTRD->SetSMstatus(12,0);
        geoTRD->SetSMstatus(13,0);
        geoTRD->SetSMstatus(14,0);
        geoTRD->SetSMstatus(15,0);
        geoTRD->SetSMstatus(16,0);
      }
  }

  if (iFMD)
  {
      //=================== FMD parameters ============================
      IlcFMD *FMD = new IlcFMDv1("FMD", "normal FMD");
  }

  if (iMUON)
  {
      //=================== MUON parameters ===========================
      // New MUONv1 version (geometry defined via builders)
      IlcMUON *MUON = new IlcMUONv1("MUON", "default");
  }
  //=================== PHOS parameters ===========================

  if (iPHOS)
  {
     if ( configVersion == kConfigV0 ) 
       IlcPHOS *PHOS = new IlcPHOSv1("PHOS", "IHEP");
     else if ( configVersion == kConfigV1 )  
       IlcPHOS *PHOS = new IlcPHOSv1("PHOS", "noCPV_Modules123"); 
  }


  if (iPMD)
  {
      //=================== PMD parameters ============================
      IlcPMD *PMD = new IlcPMDv1("PMD", "normal PMD");
  }

  if (iT0)
  {
      //=================== T0 parameters ============================
      IlcT0 *T0 = new IlcT0v1("T0", "T0 Detector");
  }

  if (iEMCAL)
  {
      //=================== EMCAL parameters ============================
    if ( configVersion == kConfigV0 ) 
      IlcEMCAL *EMCAL = new IlcEMCALv2("EMCAL", "EMCAL_COMPLETEV1");
    else if ( configVersion == kConfigV1 )  
      IlcEMCAL *EMCAL = new IlcEMCALv2("EMCAL", "EMCAL_FIRSTYEARV1");
  }

   if (iACORDE)
  {
      //=================== ACORDE parameters ============================
      IlcACORDE *ACORDE = new IlcACORDEv1("ACORDE", "normal ACORDE");
  }

   if (iVZERO)
  {
      //=================== VZERO parameters ============================
      IlcVZERO *VZERO = new IlcVZEROv7("VZERO", "normal VZERO");
  }

  IlcLog::Message(IlcLog::kInfo, "End of Config", "Config.C", "Config.C", "Config()"," Config.C", __LINE__);

  cout << "Running commonConfig.C finished ... " << endl;
}
示例#2
0
void Config()
{

  cout << "==> Config.C..." << endl;
  
  // Set Random Number seed
  UInt_t at = (UInt_t) gSystem->Now() ;
  UInt_t seed = ((gSystem->GetPid()*111)%at)*137 ;
//  gRandom->SetSeed(seed);
  gRandom->SetSeed(12345);
  printf("MySeed: %d\n",seed) ;
  cout<<"Seed for random number generation= "<<gRandom->GetSeed()<<endl;

  
  
  // libraries required by fluka21

  Bool_t isFluka = kFALSE;
  if (isFluka) {
    gSystem->Load("libGeom");
    cout << "\t* Loading TFluka..." << endl;  
    gSystem->Load("libTFluka");    
    
    cout << "\t* Instantiating TFluka..." << endl;
    new  TFluka("C++ Interface to Fluka", 0/*verbositylevel*/);
  }
  else {
    cout << "\t* Loading Geant3..." << endl;  
    gSystem->Load("libgeant321");
    
    cout << "\t* Instantiating Geant3TGeo..." << endl;
    new     TGeant3TGeo("C++ Interface to Geant3");
  }
  
  IlcRunLoader* rl=0x0;
                                                                                
  cout<<"Config.C: Creating Run Loader ..."<<endl;
  rl = IlcRunLoader::Open("gilc.root",
			    IlcConfig::GetDefaultEventFolderName(),
			    "recreate");
  if (rl == 0x0)
    {
      gIlc->Fatal("Config.C","Can not instatiate the Run Loader");
      return;
    }
  rl->SetCompressionLevel(2);
  rl->SetNumberOfEventsPerFile(1000);
  gIlc->SetRunLoader(rl);
                                                                                
  //
  // Set External decayer
  IlcDecayer *decayer = new IlcDecayerPythia();
                                                                               
  decayer->SetForceDecay(kAll);
  decayer->Init();
  gMC->SetExternalDecayer(decayer);

  //
  //
  //
  // Physics process control

  gMC->SetProcess("DCAY",1);
  gMC->SetProcess("PAIR",1);
  gMC->SetProcess("COMP",1);
  gMC->SetProcess("PHOT",1);
  gMC->SetProcess("PFIS",0);
  gMC->SetProcess("DRAY",0); //AZ 1);
  gMC->SetProcess("ANNI",1);
  gMC->SetProcess("BREM",1);
  gMC->SetProcess("MUNU",1);
  gMC->SetProcess("CKOV",1); 
  gMC->SetProcess("HADR",1);
  gMC->SetProcess("LOSS",2);
  gMC->SetProcess("MULS",1);
  gMC->SetProcess("RAYL",1);
                                                                                
  Float_t cut = 1.e-3;        // 1MeV cut by default
  Float_t tofmax = 1.e10;
                                                                                
  gMC->SetCut("CUTGAM", cut);
  gMC->SetCut("CUTELE", cut);
  gMC->SetCut("CUTNEU", cut);
  gMC->SetCut("CUTHAD", cut);
  gMC->SetCut("CUTMUO", cut);
  gMC->SetCut("BCUTE",  cut);
  gMC->SetCut("BCUTM",  cut);
  gMC->SetCut("DCUTE",  cut);
  gMC->SetCut("DCUTM",  cut);
  gMC->SetCut("PPCUTM", cut);
  gMC->SetCut("TOFMAX", tofmax);

  ((IlcMC*)gMC)->SetTransPar("./gilc.cuts") ;
  //
  //=======================================================================
  // ************* STEERING parameters FOR ILC SIMULATION **************
  // --- Specify event type to be tracked through the ILC setup
  // --- All positions are in cm, angles in degrees, and P and E in GeV
 
    IlcGenBox *gener = new IlcGenBox(5);
    gener->SetMomentumRange(0.5, 5.);
    gener->SetPhiRange(260., 280.);
    gener->SetThetaRange(82.,98.);
    gener->SetPart(kGamma);

    gener->SetOrigin(0, 0, 0);  //vertex position
    gener->SetSigma(0, 0, 0);   //Sigma in (X,Y,Z) (cm) on IP position
    gener->Init() ;
 
  // 
  // Activate this line if you want the vertex smearing to happen
  // track by track
  //
  //  gener->SetVertexSmear(kPerEvent) ;
 


    if (smag == IlcMagF::k2kG) {
        comment = comment.Append(" | L3 field 0.2 T");
    } else if (smag == IlcMagF::k5kG) {
        comment = comment.Append(" | L3 field 0.5 T");
    }
                                                                                
                                                                                
    if (srad == kGluonRadiation)
    {
        comment = comment.Append(" | Gluon Radiation On");
                                                                                
    } else {
        comment = comment.Append(" | Gluon Radiation Off");
    }
                                                                                
    if (sgeo == kHoles)
    {
        comment = comment.Append(" | Holes for PVBAR/RICH");
                                                                                
    } else {
        comment = comment.Append(" | No holes for PVBAR/RICH");
    }
                                                                                
    printf("\n \n Comment: %s \n \n", comment.Data());
                                                                                
                                                                                
// Field (L3 0.4 T)
    //Zero magnetic field
    IlcMagF* field = new IlcMagF("Maps","Maps", 0., 0., IlcMagF::k5kGUniform);
    //    IlcMagF* field = new IlcMagF("Maps","Maps", 2, -1., -1., 10., smag);
    TGeoGlobalMagField::Instance()->SetField(field);

    rl->CdGAFile();
 
  Int_t   iABSO  = 0; 
  Int_t   iCRT   = 0; 
  Int_t   iDIPO  = 0; 
  Int_t   iFMD   = 0; 
  Int_t   iFRAME = 0; 
  Int_t   iHALL  = 0; 
  Int_t   iITS   = 0; 
  Int_t   iMAG   = 0; 
  Int_t   iMUON  = 0; 
  Int_t   iPVBAR  = 1; 
  Int_t   iPIPE  = 0; 
  Int_t   iPMD   = 0; 
  Int_t   iRICH  = 0; 
  Int_t   iSHIL  = 0; 
  Int_t   iSTART = 0; 
  Int_t   iTOF   = 0; 
  Int_t   iTPC   = 0;
  Int_t   iTRD   = 0; 
  Int_t   iZDC   = 0; 
  Int_t   iEMCAL = 0; 
  Int_t   iVZERO = 0;
 
  cout << "\t* Creating the detectors ..." << endl;
  //=================== Ilc BODY parameters =============================
    //=================== Ilc BODY parameters =============================
    IlcBODY *BODY = new IlcBODY("BODY", "Ilc envelop");
                                                                                
                                                                                
    if (iMAG)
    {
        //=================== MAG parameters ============================
        // --- Start with Magnet since detector layouts may be depending ---
        // --- on the selected Magnet dimensions ---
        IlcMAG *MAG = new IlcMAG("MAG", "Magnet");
    }
                                                                                
                                                                                
    if (iABSO)
    {
        //=================== ABSO parameters ============================
        IlcABSO *ABSO = new IlcABSOv0("ABSO", "Muon Absorber");
    }
                                                                                
    if (iDIPO)
    {
        //=================== DIPO parameters ============================
                                                                                
        IlcDIPO *DIPO = new IlcDIPOv2("DIPO", "Dipole version 2");
    }
                                                                                
    if (iHALL)
    {
        //=================== HALL parameters ============================
                                                                                
        IlcHALL *HALL = new IlcHALL("HALL", "Ilc Hall");
    }
                                                                                
                                                                                
    if (iFRAME)
    {
        //=================== FRAME parameters ============================
                                                                                
        IlcFRAMEv2 *FRAME = new IlcFRAMEv2("FRAME", "Space Frame");
        if (sgeo == kHoles) {
            FRAME->SetHoles(1);
        } else {
            FRAME->SetHoles(0);
        }
    }
                                                                                
    if (iSHIL)
    {
        //=================== SHIL parameters ============================
                                                                                
        IlcSHIL *SHIL = new IlcSHILv2("SHIL", "Shielding Version 2");
    }
                                                                                
                                                                                
    if (iPIPE)
    {
        //=================== PIPE parameters ============================
                                                                                
        IlcPIPE *PIPE = new IlcPIPEv0("PIPE", "Beam Pipe");
    }
                                                                                
    if(iITS) {
                                                                                
    //=================== ITS parameters ============================
    //
    // As the innermost detector in ILC, the Inner Tracking System "impacts" on
    // almost all other detectors. This involves the fact that the ITS geometry
    // still has several options to be followed in parallel in order to determine
    // the best set-up which minimizes the induced background. All the geometries
    // available to date are described in the following. Read carefully the comments
    // and use the default version (the only one uncommented) unless you are making
    // comparisons and you know what you are doing. In this case just uncomment the
    // ITS geometry you want to use and run Ilcroot.
    //
    // Detailed geometries:
    //
    //
    //IlcITS *ITS  = new IlcITSv5symm("ITS","Updated ITS TDR detailed version with symmetric services");
    //
    //IlcITS *ITS  = new IlcITSv5asymm("ITS","Updates ITS TDR detailed version with asymmetric services");
    //
        IlcITSvPPRasymmFMD *ITS  = new IlcITSvPPRasymmFMD("ITS","New ITS PPR detailed version with asymmetric services");
        ITS->SetMinorVersion(2);  // don't touch this parameter if you're not an ITS developer
        ITS->SetReadDet(kTRUE);   // don't touch this parameter if you're not an ITS developer
    //    ITS->SetWriteDet("$ILC_ROOT/ITS/ITSgeometry_vPPRasymm2.det");  // don't touch this parameter if you're not an ITS developer
        ITS->SetThicknessDet1(200.);   // detector thickness on layer 1 must be in the range [100,300]
        ITS->SetThicknessDet2(200.);   // detector thickness on layer 2 must be in the range [100,300]
        ITS->SetThicknessChip1(200.);  // chip thickness on layer 1 must be in the range [150,300]
        ITS->SetThicknessChip2(200.);  // chip thickness on layer 2 must be in the range [150,300]
        ITS->SetRails(0);            // 1 --> rails in ; 0 --> rails out
        ITS->SetCoolingFluid(1);   // 1 --> water ; 0 --> freon
                                                                                
    // Coarse geometries (warning: no hits are produced with these coarse geometries and they unuseful
    // for reconstruction !):
    //
    //
    //IlcITSvPPRcoarseasymm *ITS  = new IlcITSvPPRcoarseasymm("ITS","New ITS PPR coarse version with asymmetric services");
    //ITS->SetRails(0);                // 1 --> rails in ; 0 --> rails out
    //ITS->SetSupportMaterial(0);      // 0 --> Copper ; 1 --> Aluminum ; 2 --> Carbon
    //
    //IlcITS *ITS  = new IlcITSvPPRcoarsesymm("ITS","New ITS PPR coarse version with symmetric services");
    //ITS->SetRails(0);                // 1 --> rails in ; 0 --> rails out
    //ITS->SetSupportMaterial(0);      // 0 --> Copper ; 1 --> Aluminum ; 2 --> Carbon
    //
    //
    //
    // Geant3 <-> EUCLID conversion
    // ============================
    //
    // SetEUCLID is a flag to output (=1) or not to output (=0) both geometry and
    // media to two ASCII files (called by default ITSgeometry.euc and
    // ITSgeometry.tme) in a format understandable to the CAD system EUCLID.
    // The default (=0) means that you dont want to use this facility.
    //
        ITS->SetEUCLID(0);
    }
                                                                                
    if (iTPC)
    {
        //============================ TPC parameters ================================
//        IlcTPC *TPC = new IlcTPCv0("TPC", "Default");
        IlcTPC *TPC = new IlcTPCv2("TPC", "Default");
    }
                                                                                
                                                                                
    if (iTOF) {
        //=================== TOF parameters ============================
        IlcTOF *TOF = new IlcTOFv4T0("TOF", "normal TOF");
    }
                                                                                
                                                                                
    if (iRICH)
    {
        //=================== RICH parameters ===========================
        IlcRICH *RICH = new IlcRICHv1("RICH", "normal RICH");
                                                                                
    }
                                                                                
                                                                                
    if (iZDC)
    {
        //=================== ZDC parameters ============================
                                                                                
        IlcZDC *ZDC = new IlcZDCv2("ZDC", "normal ZDC");
    }
                                                                                
    if (iTRD)
    {
        //=================== TRD parameters ============================
                                                                                
        IlcTRD *TRD = new IlcTRDv1("TRD", "TRD slow simulator");
                                                                                
        // Select the gas mixture (0: 97% Xe + 3% isobutane, 1: 90% Xe + 10% CO2)
        TRD->SetGasMix(1);
        if (sgeo == kHoles) {
            // With hole in front of PVBAR
            TRD->SetPVBARhole();
            // With hole in front of RICH
            TRD->SetRICHhole();
        }
            // Switch on TR
            IlcTRDsim *TRDsim = TRD->CreateTR();
    }
                                                                                
    if (iFMD)
    {
        //=================== FMD parameters ============================
        IlcFMD *FMD = new IlcFMDv1("FMD", "normal FMD");
   }
                                                                                
    if (iMUON)
    {
        //=================== MUON parameters ===========================
                                                                                
        IlcMUON *MUON = new IlcMUONv1("MUON", "default");
    }
    //=================== PVBAR parameters ===========================
                                                                                
    if (iPVBAR)
    {
       IlcPVBAR *PVBAR = new IlcPVBARv1("PVBAR", "ORKA");
//         IlcPVBAR *PVBAR = new IlcPVBARv1("PVBAR", "noCPV");
    }
                                                                                
                                                                                
    if (iPMD)
    {
        //=================== PMD parameters ============================
        IlcPMD *PMD = new IlcPMDv1("PMD", "normal PMD");
    }
                                                                                
    if (iSTART)
    {
        //=================== START parameters ============================
        IlcSTART *START = new IlcSTARTv1("START", "START Detector");
    }
                                                                                
    if (iEMCAL)
    {
        //=================== EMCAL parameters ============================
        IlcEMCAL *EMCAL = new IlcEMCALv2("EMCAL", "EMCAL_COMPLETEV1");
    }
                                                                                
     if (iCRT)
    {
        //=================== CRT parameters ============================
        IlcCRT *CRT = new IlcCRTv0("CRT", "normal ACORDE");
    }
                                                                                
     if (iVZERO)
    {
        //=================== CRT parameters ============================
        IlcVZERO *VZERO = new IlcVZEROv3("VZERO", "normal VZERO");
    }
                                                                                
                                                                                
}
示例#3
0
void Config()
{
    

  // Get settings from environment variables
  ProcessEnvironmentVars();

  gRandom->SetSeed(seed);
  cerr<<"Seed for random number generation= "<<seed<<endl; 

  // Libraries required by geant321
#if defined(__CINT__)
  gSystem->Load("liblhapdf");      // Parton density functions
  gSystem->Load("libEGPythia6");   // TGenerator interface
  gSystem->Load("libpythia6");     // Pythia
  gSystem->Load("libIlcPythia6");  // ILC specific implementations
  gSystem->Load("libgeant321");
#endif

  new TGeant3TGeo("C++ Interface to Geant3");

  //=======================================================================
  //  Create the output file

   
  IlcRunLoader* rl=0x0;

  cout<<"Config.C: Creating Run Loader ..."<<endl;
  rl = IlcRunLoader::Open("gilc.root",
			  IlcConfig::GetDefaultEventFolderName(),
			  "recreate");
  if (rl == 0x0)
    {
      gIlc->Fatal("Config.C","Can not instatiate the Run Loader");
      return;
    }
  rl->SetCompressionLevel(2);
  rl->SetNumberOfEventsPerFile(1000);
  gIlc->SetRunLoader(rl);
  // gIlc->SetGeometryFromFile("geometry.root");
  // gIlc->SetGeometryFromCDB();
  
  // Set the trigger configuration: proton-proton
  IlcSimulation::Instance()->SetTriggerConfig("p-p");

  //
  //=======================================================================
  // ************* STEERING parameters FOR ILC SIMULATION **************
  // --- Specify event type to be tracked through the ILC setup
  // --- All positions are in cm, angles in degrees, and P and E in GeV


    gMC->SetProcess("DCAY",1);
    gMC->SetProcess("PAIR",1);
    gMC->SetProcess("COMP",1);
    gMC->SetProcess("PHOT",1);
    gMC->SetProcess("PFIS",0);
    gMC->SetProcess("DRAY",0);
    gMC->SetProcess("ANNI",1);
    gMC->SetProcess("BREM",1);
    gMC->SetProcess("MUNU",1);
    gMC->SetProcess("CKOV",1);
    gMC->SetProcess("HADR",1);
    gMC->SetProcess("LOSS",2);
    gMC->SetProcess("MULS",1);
    gMC->SetProcess("RAYL",1);

    Float_t cut = 1.e-3;        // 1MeV cut by default
    Float_t tofmax = 1.e10;

    gMC->SetCut("CUTGAM", cut);
    gMC->SetCut("CUTELE", cut);
    gMC->SetCut("CUTNEU", cut);
    gMC->SetCut("CUTHAD", cut);
    gMC->SetCut("CUTMUO", cut);
    gMC->SetCut("BCUTE",  cut); 
    gMC->SetCut("BCUTM",  cut); 
    gMC->SetCut("DCUTE",  cut); 
    gMC->SetCut("DCUTM",  cut); 
    gMC->SetCut("PPCUTM", cut);
    gMC->SetCut("TOFMAX", tofmax); 




  //======================//
  // Set External decayer //
  //======================//
  TVirtualMCDecayer* decayer = new IlcDecayerPythia();
  decayer->SetForceDecay(kAll);
  decayer->Init();
  gMC->SetExternalDecayer(decayer);

  //=========================//
  // Generator Configuration //
  //=========================//
  // Create pileup generator
  IlcGenPileup *pileup = new IlcGenPileup();

  IlcGenerator* gener = 0x0;
  
  if (proc == kPythia6) {
      gener = MbPythia();
  } else if (proc == kPhojet) {
      gener = MbPhojet();
  }
  
  // Set the pileup interaction generator
  // The second argument is the pileup rate
  // in terms of event rate per bunch crossing
  pileup->SetGenerator(gener,0.01);
  // Set the beam time structure
  // Details on the syntax in STEER/IlcTriggerBCMask
  pileup->SetBCMask("72(1H1L)3420L");
  // Examples of the pileup rate and beam structure settings
  // Most of the information is taken from the LHC commissionning page
  // rate from 0.01 (at 900GeV) to 0.76 (at 14TeV)
  // 1 bunch/orbit     - bc-mask = "1H3563L"
  // 43 bunches/orbit  - bc-mask = "43(1H80L)81L"
  // 72 bunches/orbit  - bc-mask = "72(1H1L)3420L" (50ns mode)
  // Please note that most of these setting should be cross-checked because
  // for example the 43 bunches mode is taken at CMS IP and not the ILC one.

  // Generate the trigger interaction
  pileup->GenerateTrigInteraction(kTRUE);

  // PRIMARY VERTEX
  //
  pileup->SetOrigin(0., 0., 0.);    // vertex position
  //
  //
  // Size of the interaction diamond
  // Longitudinal
  Float_t sigmaz  = 5.4 / TMath::Sqrt(2.); // [cm]
  if (energy == 900)
    sigmaz  = 10.5 / TMath::Sqrt(2.); // [cm]
  //
  // Transverse
  Float_t betast  = 10;                 // beta* [m]
  Float_t eps     = 3.75e-6;            // emittance [m]
  Float_t gamma   = energy / 2.0 / 0.938272;  // relativistic gamma [1]
  Float_t sigmaxy = TMath::Sqrt(eps * betast / gamma) / TMath::Sqrt(2.) * 100.;  // [cm]
  printf("\n \n Diamond size x-y: %10.3e z: %10.3e\n \n", sigmaxy, sigmaz);
    
  pileup->SetSigma(sigmaxy, sigmaxy, sigmaz);      // Sigma in (X,Y,Z) (cm) on IP position
  pileup->SetCutVertexZ(3.);        // Truncate at 3 sigma
  pileup->SetVertexSmear(kPerEvent);

  pileup->Init();

  // FIELD
  //
  IlcMagF* field = 0x0;
  if (mag == kNoField) {
    comment = comment.Append(" | L3 field 0.0 T");
    field = new IlcMagF("Maps","Maps", 0., 0., IlcMagF::k5kGUniform);
  } else if (mag == k5kG) {
    comment = comment.Append(" | L3 field 0.5 T");
    field = new IlcMagF("Maps","Maps", -1., -1., IlcMagF::k5kG);
  }
  printf("\n \n Comment: %s \n \n", comment.Data());
  TGeoGlobalMagField::Instance()->SetField(field);
    
  rl->CdGAFile();

  Int_t iABSO  = 1;
  Int_t iACORDE= 0;
  Int_t iDIPO  = 1;
  Int_t iEMCAL = 0;
  Int_t iFMD   = 1;
  Int_t iFRAME = 1;
  Int_t iHALL  = 1;
  Int_t iITS   = 1;
  Int_t iMAG   = 1;
  Int_t iMUON  = 1;
  Int_t iPHOS  = 1;
  Int_t iPIPE  = 1;
  Int_t iPMD   = 0;
  Int_t iHMPID = 1;
  Int_t iSHIL  = 1;
  Int_t iT0    = 1;
  Int_t iTOF   = 1;
  Int_t iTPC   = 1;
  Int_t iTRD   = 1;
  Int_t iVZERO = 1;
  Int_t iZDC   = 1;
  

    //=================== Ilc BODY parameters =============================
    IlcBODY *BODY = new IlcBODY("BODY", "Ilc envelop");


    if (iMAG)
    {
        //=================== MAG parameters ============================
        // --- Start with Magnet since detector layouts may be depending ---
        // --- on the selected Magnet dimensions ---
        IlcMAG *MAG = new IlcMAG("MAG", "Magnet");
    }


    if (iABSO)
    {
        //=================== ABSO parameters ============================
        IlcABSO *ABSO = new IlcABSOv3("ABSO", "Muon Absorber");
    }

    if (iDIPO)
    {
        //=================== DIPO parameters ============================

        IlcDIPO *DIPO = new IlcDIPOv3("DIPO", "Dipole version 3");
    }

    if (iHALL)
    {
        //=================== HALL parameters ============================

        IlcHALL *HALL = new IlcHALLv3("HALL", "Ilc Hall");
    }


    if (iFRAME)
    {
        //=================== FRAME parameters ============================

        IlcFRAMEv2 *FRAME = new IlcFRAMEv2("FRAME", "Space Frame");
	FRAME->SetHoles(1);
    }

    if (iSHIL)
    {
        //=================== SHIL parameters ============================

        IlcSHIL *SHIL = new IlcSHILv3("SHIL", "Shielding Version 3");
    }


    if (iPIPE)
    {
        //=================== PIPE parameters ============================

        IlcPIPE *PIPE = new IlcPIPEv3("PIPE", "Beam Pipe");
    }
 
    if (iITS)
    {
        //=================== ITS parameters ============================

	IlcITS *ITS  = new IlcITSv11("ITS","ITS v11");
    }

    if (iTPC)
    {
      //============================ TPC parameters =====================

        IlcTPC *TPC = new IlcTPCv2("TPC", "Default");
    }


    if (iTOF) {
        //=================== TOF parameters ============================

	IlcTOF *TOF = new IlcTOFv6T0("TOF", "normal TOF");
    }


    if (iHMPID)
    {
        //=================== HMPID parameters ===========================

        IlcHMPID *HMPID = new IlcHMPIDv3("HMPID", "normal HMPID");

    }


    if (iZDC)
    {
        //=================== ZDC parameters ============================

        IlcZDC *ZDC = new IlcZDCv4("ZDC", "normal ZDC");
    }

    if (iTRD)
    {
        //=================== TRD parameters ============================

        IlcTRD *TRD = new IlcTRDv1("TRD", "TRD slow simulator");
        IlcTRDgeometry *geoTRD = TRD->GetGeometry();
	// Partial geometry: modules at 0,1,7,8,9,10,17
	// starting at 3h in positive direction
	geoTRD->SetSMstatus(2,0);
	geoTRD->SetSMstatus(3,0);
	geoTRD->SetSMstatus(4,0);
        geoTRD->SetSMstatus(5,0);
	geoTRD->SetSMstatus(6,0);
        geoTRD->SetSMstatus(11,0);
        geoTRD->SetSMstatus(12,0);
        geoTRD->SetSMstatus(13,0);
        geoTRD->SetSMstatus(14,0);
        geoTRD->SetSMstatus(15,0);
        geoTRD->SetSMstatus(16,0);
    }

    if (iFMD)
    {
        //=================== FMD parameters ============================

	IlcFMD *FMD = new IlcFMDv1("FMD", "normal FMD");
   }

    if (iMUON)
    {
        //=================== MUON parameters ===========================
        // New MUONv1 version (geometry defined via builders)

        IlcMUON *MUON = new IlcMUONv1("MUON", "default");
    }

    if (iPHOS)
    {
        //=================== PHOS parameters ===========================

        IlcPHOS *PHOS = new IlcPHOSv1("PHOS", "noCPV_Modules123");
    }


    if (iPMD)
    {
        //=================== PMD parameters ============================

        IlcPMD *PMD = new IlcPMDv1("PMD", "normal PMD");
    }

    if (iT0)
    {
        //=================== T0 parameters ============================
        IlcT0 *T0 = new IlcT0v1("T0", "T0 Detector");
    }

    if (iEMCAL)
    {
        //=================== EMCAL parameters ============================

        IlcEMCAL *EMCAL = new IlcEMCALv2("EMCAL", "EMCAL_FIRSTYEAR");
    }

     if (iACORDE)
    {
        //=================== ACORDE parameters ============================

        IlcACORDE *ACORDE = new IlcACORDEv1("ACORDE", "normal ACORDE");
    }

     if (iVZERO)
    {
        //=================== ACORDE parameters ============================

        IlcVZERO *VZERO = new IlcVZEROv7("VZERO", "normal VZERO");
    }
}
示例#4
0
void Config()
{
    

  // Get settings from environment variables
  ProcessEnvironmentVars();

  gRandom->SetSeed(seed);
  cerr<<"Seed for random number generation= "<<seed<<endl; 

  // Libraries required by geant321
#if defined(__CINT__)
  gSystem->Load("liblhapdf");      // Parton density functions
  gSystem->Load("libEGPythia6");   // TGenerator interface
  gSystem->Load("libpythia6");     // Pythia
  gSystem->Load("libIlcPythia6");  // ILC specific implementations
  gSystem->Load("libgeant321");
  gSystem->Load("libTTherminator");
#endif

  new TGeant3TGeo("C++ Interface to Geant3");

  //=======================================================================
  //  Create the output file

   
  IlcRunLoader* rl=0x0;

  cout<<"Config.C: Creating Run Loader ..."<<endl;
  rl = IlcRunLoader::Open("gilc.root",
			  IlcConfig::GetDefaultEventFolderName(),
			  "recreate");
    if (rl == 0x0)
    {
      gIlc->Fatal("Config.C","Can not instatiate the Run Loader");
      return;
    }
  rl->SetCompressionLevel(2);
  rl->SetNumberOfEventsPerFile(3);
  gIlc->SetRunLoader(rl);
  
  
  // Set the trigger configuration
  if ((embedrun == kBackground) || (embedrun == kMerged)) {
    IlcSimulation::Instance()->SetTriggerConfig("Pb-Pb");
    cout<<"Trigger configuration is set to  Pb-Pb"<<endl;
  }
  else {
    // Set the trigger configuration: proton-proton
    IlcSimulation::Instance()->SetTriggerConfig("p-p");
  }

  //
  // Set External decayer
  TVirtualMCDecayer *decayer = new IlcDecayerPythia();
  
  decayer->SetForceDecay(kAll);
  decayer->Init();
  gMC->SetExternalDecayer(decayer);
  //=======================================================================
  // ************* STEERING parameters FOR ILC SIMULATION **************
  // --- Specify event type to be tracked through the ILC setup
  // --- All positions are in cm, angles in degrees, and P and E in GeV
  
  
  gMC->SetProcess("DCAY",1);
  gMC->SetProcess("PAIR",1);
  gMC->SetProcess("COMP",1);
  gMC->SetProcess("PHOT",1);
  gMC->SetProcess("PFIS",0);
  gMC->SetProcess("DRAY",0);
  gMC->SetProcess("ANNI",1);
  gMC->SetProcess("BREM",1);
  gMC->SetProcess("MUNU",1);
  gMC->SetProcess("CKOV",1);
  gMC->SetProcess("HADR",1);
  gMC->SetProcess("LOSS",2);
  gMC->SetProcess("MULS",1);
  gMC->SetProcess("RAYL",1);
  
  Float_t cut = 1.e-3;        // 1MeV cut by default
  Float_t tofmax = 1.e10;
  
  gMC->SetCut("CUTGAM", cut);
  gMC->SetCut("CUTELE", cut);
  gMC->SetCut("CUTNEU", cut);
  gMC->SetCut("CUTHAD", cut);
  gMC->SetCut("CUTMUO", cut);
  gMC->SetCut("BCUTE",  cut); 
  gMC->SetCut("BCUTM",  cut); 
  gMC->SetCut("DCUTE",  cut); 
  gMC->SetCut("DCUTM",  cut); 
  gMC->SetCut("PPCUTM", cut);
  gMC->SetCut("TOFMAX", tofmax); 
  
  //======================//
  // Set External decayer //
  //======================//
  TVirtualMCDecayer* decayer = new IlcDecayerPythia();
  decayer->SetForceDecay(kAll);
  decayer->Init();
  gMC->SetExternalDecayer(decayer);
  
  if ((embedrun == kMerged) || (embedrun == kSignal)) {
    //=========================//
    // Generator Configuration //
    //=========================//
    IlcGenerator* gener = 0x0;
    
    if (proc == kPythia6) {
      gener = MbPythia();
    } else if (proc == kPhojet) {
      gener = MbPhojet();
    }
  }
  else {
    IlcGenCocktail *gener = new IlcGenCocktail();
    gener->SetPhiRange(0, 360);
    // Set pseudorapidity range from -8 to 8.
    Float_t thmin = EtaToTheta(1);   // theta min. <---> eta max
    Float_t thmax = EtaToTheta(-1);  // theta max. <---> eta min 
    gener->SetThetaRange(thmin,thmax);
    gener->SetProjectile("A",208,82);
    gener->SetTarget("A",208,82);

    IlcGenTherminator *genther = new IlcGenTherminator();
    genther->SetFileName("event.out");
    genther->SetEventNumberInFile(1);
    genther->SetTemperature(0.145);
    genther->SetMiuI(-0.0009);
    genther->SetMiuS(0.000);
    genther->SetMiuB(0.0008);
    genther->SetAlfaRange(8.0);
    genther->SetRapRange(4.0);
    genther->SetRhoMax(7.74);
    genther->SetTau(9.74);
    genther->SetModel("Lhyquid3D");
    genther->SetLhyquidSet("LHC500C2030");

    gener->AddGenerator(genther, "THERMINATOR LHYQUID3D", 1);
  }
  
  

  // PRIMARY VERTEX
  //
  gener->SetOrigin(0., 0., 0.);    // vertex position
  //
  //
  // Size of the interaction diamond
  // Longitudinal
  Float_t sigmaz;

  if (embedrun == kBackground) {
    sigmaz  = 7.55 / TMath::Sqrt(2.); // [cm]
  }
  else {
    Float_t sigmaz  = 5.4 / TMath::Sqrt(2.); // [cm]
    if (energy == 900)
      sigmaz  = 10.5 / TMath::Sqrt(2.); // [cm]
  }

  //
  // Transverse
  Float_t betast  = 10;                 // beta* [m]
  Float_t eps     = 3.75e-6;            // emittance [m]
  Float_t gamma   = energy / 2.0 / 0.938272;  // relativistic gamma [1]
  Float_t sigmaxy = TMath::Sqrt(eps * betast / gamma) / TMath::Sqrt(2.) * 100.;  // [cm]
  printf("\n \n Diamond size x-y: %10.3e z: %10.3e\n \n", sigmaxy, sigmaz);
    
  gener->SetSigma(sigmaxy, sigmaxy, sigmaz);      // Sigma in (X,Y,Z) (cm) on IP position
  gener->SetCutVertexZ(3.);        // Truncate at 3 sigma
  gener->SetVertexSmear(kPerEvent);

  gener->Init();

  // FIELD
  //
// Field

    //  IlcMagF* field = 0x0;
  if (mag == kNoField) {
    comment = comment.Append(" | L3 field 0.0 T");
    TGeoGlobalMagField::Instance()->SetField(new IlcMagF("Maps","Maps", 0., 0., IlcMagF::k5kGUniform));
  } else if (mag == k5kG) {
    comment = comment.Append(" | L3 field 0.5 T");
    TGeoGlobalMagField::Instance()->SetField(new IlcMagF("Maps","Maps", -1., -1., IlcMagF::k5kG));
  }
  printf("\n \n Comment: %s \n \n", comment.Data());
  //  TGeoGlobalMagField::Instance()->SetField(field);
    
  rl->CdGAFile();
  
  Int_t iABSO  = 1;
  Int_t iACORDE= 0;
  Int_t iDIPO  = 1;
  Int_t iEMCAL = 1;
  Int_t iFMD   = 1;
  Int_t iFRAME = 1;
  Int_t iHALL  = 1;
  Int_t iITS   = 1;
  Int_t iMAG   = 1;
  Int_t iMUON  = 1;
  Int_t iPHOS  = 1;
  Int_t iPIPE  = 1;
  Int_t iPMD   = 1;
  Int_t iHMPID = 1;
  Int_t iSHIL  = 1;
  Int_t iT0    = 1;
  Int_t iTOF   = 1;
  Int_t iTPC   = 1;
  Int_t iTRD   = 1;
  Int_t iVZERO = 1;
  Int_t iZDC   = 1;
  

    //=================== Ilc BODY parameters =============================
    IlcBODY *BODY = new IlcBODY("BODY", "Ilc envelop");


    if (iMAG)
    {
        //=================== MAG parameters ============================
        // --- Start with Magnet since detector layouts may be depending ---
        // --- on the selected Magnet dimensions ---
        IlcMAG *MAG = new IlcMAG("MAG", "Magnet");
    }


    if (iABSO)
    {
        //=================== ABSO parameters ============================
        IlcABSO *ABSO = new IlcABSOv3("ABSO", "Muon Absorber");
    }

    if (iDIPO)
    {
        //=================== DIPO parameters ============================

        IlcDIPO *DIPO = new IlcDIPOv3("DIPO", "Dipole version 3");
    }

    if (iHALL)
    {
        //=================== HALL parameters ============================

        IlcHALL *HALL = new IlcHALLv3("HALL", "Ilc Hall");
    }


    if (iFRAME)
    {
        //=================== FRAME parameters ============================

        IlcFRAMEv2 *FRAME = new IlcFRAMEv2("FRAME", "Space Frame");
	FRAME->SetHoles(1);
    }

    if (iSHIL)
    {
        //=================== SHIL parameters ============================

        IlcSHIL *SHIL = new IlcSHILv3("SHIL", "Shielding Version 3");
    }


    if (iPIPE)
    {
        //=================== PIPE parameters ============================

        IlcPIPE *PIPE = new IlcPIPEv3("PIPE", "Beam Pipe");
    }
 
    if (iITS)
    {
        //=================== ITS parameters ============================

	IlcITS *ITS  = new IlcITSv11("ITS","ITS v11");
    }

    if (iTPC)
    {
      //============================ TPC parameters =====================

        IlcTPC *TPC = new IlcTPCv2("TPC", "Default");
    }


    if (iTOF) {
        //=================== TOF parameters ============================

	IlcTOF *TOF = new IlcTOFv6T0("TOF", "normal TOF");
    }


    if (iHMPID)
    {
        //=================== HMPID parameters ===========================

        IlcHMPID *HMPID = new IlcHMPIDv3("HMPID", "normal HMPID");

    }


    if (iZDC)
    {
        //=================== ZDC parameters ============================

        IlcZDC *ZDC = new IlcZDCv4("ZDC", "normal ZDC");
    }

    if (iTRD)
    {
        //=================== TRD parameters ============================

        IlcTRD *TRD = new IlcTRDv1("TRD", "TRD slow simulator");
    }

    if (iFMD)
    {
        //=================== FMD parameters ============================

	IlcFMD *FMD = new IlcFMDv1("FMD", "normal FMD");
   }

    if (iMUON)
    {
        //=================== MUON parameters ===========================
        // New MUONv1 version (geometry defined via builders)

        IlcMUON *MUON = new IlcMUONv1("MUON", "default");
    }

    if (iPHOS)
    {
        //=================== PHOS parameters ===========================
        IlcPHOS *PHOS = new IlcPHOSv1("PHOS", "IHEP");
    }


    if (iPMD)
    {
        //=================== PMD parameters ============================

        IlcPMD *PMD = new IlcPMDv1("PMD", "normal PMD");
    }

    if (iT0)
    {
        //=================== T0 parameters ============================
        IlcT0 *T0 = new IlcT0v1("T0", "T0 Detector");
    }

    if (iEMCAL)
    {
        //=================== EMCAL parameters ============================

        IlcEMCAL *EMCAL = new IlcEMCALv2("EMCAL", "EMCAL_COMPLETEV1");
    }

     if (iACORDE)
    {
        //=================== ACORDE parameters ============================

        IlcACORDE *ACORDE = new IlcACORDEv1("ACORDE", "normal ACORDE");
    }

     if (iVZERO)
    {
        //=================== ACORDE parameters ============================

        IlcVZERO *VZERO = new IlcVZEROv7("VZERO", "normal VZERO");
    }
}
示例#5
0
void Config()
{
    // ThetaRange is (0., 180.). It was (0.28,179.72) 7/12/00 09:00
    // Theta range given through pseudorapidity limits 22/6/2001

    // Set Random Number seed
    gRandom->SetSeed(sseed);
    cout<<"Seed for random number generation= "<<gRandom->GetSeed()<<endl; 
  


   // libraries required by geant321 and Pythia6
#if defined(__CINT__)
    gSystem->Load("liblhapdf.so");      // Parton density functions
    gSystem->Load("libEGPythia6.so");   // TGenerator interface
    gSystem->Load("libpythia6.so");     // Pythia
    gSystem->Load("libIlcPythia6.so");  // ILC specific implementations
    gSystem->Load("libgeant321");
#endif

    new     TGeant3TGeo("C++ Interface to Geant3");

    IlcRunLoader* rl=0x0;

    cout<<"Config.C: Creating Run Loader ..."<<endl;
    rl = IlcRunLoader::Open("gilc.root",
			    IlcConfig::GetDefaultEventFolderName(),
			    "recreate");
    if (rl == 0x0)
      {
	gIlc->Fatal("Config.C","Can not instatiate the Run Loader");
	return;
      }
    rl->SetCompressionLevel(2);
    rl->SetNumberOfEventsPerFile(100);
    gIlc->SetRunLoader(rl);

  // Set the trigger configuration
    IlcSimulation::Instance()->SetTriggerConfig(pprTrigConfName[strig]);
    cout<<"Trigger configuration is set to  "<<pprTrigConfName[strig]<<endl;


    //
    // Set External decayer
    IlcDecayer *decayer = new IlcDecayerPythia();
    decayer->SetForceDecay(kAll);
    decayer->Init();

    //forbid some decays
    IlcPythia * py= IlcPythia::Instance();
    py->SetMDME(737,1,0); //forbid D*+->D+ + pi0
    py->SetMDME(738,1,0);//forbid D*+->D+ + gamma

    for(Int_t d=747; d<=762; d++){ 
      py->SetMDME(d,1,0);
    }

    for(Int_t d=764; d<=807; d++){ 
      py->SetMDME(d,1,0);
    }


   
    gMC->SetExternalDecayer(decayer);
    //
    //
    //=======================================================================
    //
    //=======================================================================
    // ************* STEERING parameters FOR ILC SIMULATION **************
    // --- Specify event type to be tracked through the ILC setup
    // --- All positions are in cm, angles in degrees, and P and E in GeV

    gMC->SetProcess("DCAY",1);
    gMC->SetProcess("PAIR",1);
    gMC->SetProcess("COMP",1);
    gMC->SetProcess("PHOT",1);
    gMC->SetProcess("PFIS",0);
    gMC->SetProcess("DRAY",0);
    gMC->SetProcess("ANNI",1);
    gMC->SetProcess("BREM",1);
    gMC->SetProcess("MUNU",1);
    gMC->SetProcess("CKOV",1);
    gMC->SetProcess("HADR",1);
    gMC->SetProcess("LOSS",2);
    gMC->SetProcess("MULS",1);
    gMC->SetProcess("RAYL",1);

    Float_t cut = 1.e-3;        // 1MeV cut by default
    Float_t tofmax = 1.e10;

    gMC->SetCut("CUTGAM", cut);
    gMC->SetCut("CUTELE", cut);
    gMC->SetCut("CUTNEU", cut);
    gMC->SetCut("CUTHAD", cut);
    gMC->SetCut("CUTMUO", cut);
    gMC->SetCut("BCUTE",  cut); 
    gMC->SetCut("BCUTM",  cut); 
    gMC->SetCut("DCUTE",  cut); 
    gMC->SetCut("DCUTM",  cut); 
    gMC->SetCut("PPCUTM", cut);
    gMC->SetCut("TOFMAX", tofmax); 

    // Debug and log level
    //    IlcLog::SetGlobalDebugLevel(0);
    //    IlcLog::SetGlobalLogLevel(IlcLog::kError);

    // Generator Configuration
    IlcGenerator* gener = GeneratorFactory();
    gener->SetOrigin(0, 0, 0);    // vertex position
    gener->SetSigma(0, 0, 5.3);   // Sigma in (X,Y,Z) (cm) on IP position
    gener->SetCutVertexZ(1.);     // Truncate at 1 sigma
    gener->SetVertexSmear(kPerEvent); 
    gener->SetTrackingFlag(1);
    gener->Init();
    
    if (smag == IlcMagF::k2kG) {
	comment = comment.Append(" | L3 field 0.2 T");
    } else if (smag == IlcMagF::k5kG) {
	comment = comment.Append(" | L3 field 0.5 T");
    }
    
    
    if (srad == kGluonRadiation)
    {
	comment = comment.Append(" | Gluon Radiation On");
	
    } else {
	comment = comment.Append(" | Gluon Radiation Off");
    }


    printf("\n \n Comment: %s \n \n", comment.Data());
    
    
// Field (L3 0.4 T)
    IlcMagF* field = new IlcMagF("Maps","Maps",-1., -1., smag);
    TGeoGlobalMagField::Instance()->SetField(field);

    rl->CdGAFile();
    //
    Int_t   iABSO   = 1;
    Int_t   iDIPO   = 1;
    Int_t   iFMD    = 1;
    Int_t   iFRAME  = 1;
    Int_t   iHALL   = 1;
    Int_t   iITS    = 1;
    Int_t   iMAG    = 1;
    Int_t   iMUON   = 1;
    Int_t   iPHOS   = 1;
    Int_t   iPIPE   = 1;
    Int_t   iPMD    = 1;
    Int_t   iHMPID   = 1;
    Int_t   iSHIL   = 1;
    Int_t   iT0  = 1;
    Int_t   iTOF    = 1;
    Int_t   iTPC    = 1;
    Int_t   iTRD    = 1;
    Int_t   iZDC    = 1;
    Int_t   iEMCAL  = 1;
    Int_t   iVZERO  = 1;
    Int_t   iACORDE    = 0;

    //=================== Ilc BODY parameters =============================
    IlcBODY *BODY = new IlcBODY("BODY", "Ilc envelop");


    if (iMAG)
    {
        //=================== MAG parameters ============================
        // --- Start with Magnet since detector layouts may be depending ---
        // --- on the selected Magnet dimensions ---
        IlcMAG *MAG = new IlcMAG("MAG", "Magnet");
    }


    if (iABSO)
    {
        //=================== ABSO parameters ============================
        IlcABSO *ABSO = new IlcABSOv3("ABSO", "Muon Absorber");
    }

    if (iDIPO)
    {
        //=================== DIPO parameters ============================

        IlcDIPO *DIPO = new IlcDIPOv3("DIPO", "Dipole version 3");
    }

    if (iHALL)
    {
        //=================== HALL parameters ============================

        IlcHALL *HALL = new IlcHALLv3("HALL", "Ilc Hall");
    }


    if (iFRAME)
    {
        //=================== FRAME parameters ============================

        IlcFRAMEv2 *FRAME = new IlcFRAMEv2("FRAME", "Space Frame");
	FRAME->SetHoles(1);
    }

    if (iSHIL)
    {
        //=================== SHIL parameters ============================

        IlcSHIL *SHIL = new IlcSHILv3("SHIL", "Shielding Version 3");
    }


    if (iPIPE)
    {
        //=================== PIPE parameters ============================

        IlcPIPE *PIPE = new IlcPIPEv3("PIPE", "Beam Pipe");
    }
 
    if (iITS)
    {
        //=================== ITS parameters ============================

	IlcITS *ITS  = new IlcITSv11("ITS","ITS v11");
    }

    if (iTPC)
    {
      //============================ TPC parameters =====================
        IlcTPC *TPC = new IlcTPCv2("TPC", "Default");
    }


    if (iTOF) {
        //=================== TOF parameters ============================
	IlcTOF *TOF = new IlcTOFv6T0("TOF", "normal TOF");
    }


    if (iHMPID)
    {
        //=================== HMPID parameters ===========================
        IlcHMPID *HMPID = new IlcHMPIDv3("HMPID", "normal HMPID");

    }


    if (iZDC)
    {
        //=================== ZDC parameters ============================

        IlcZDC *ZDC = new IlcZDCv4("ZDC", "normal ZDC");
    }

    if (iTRD)
    {
        //=================== TRD parameters ============================

        IlcTRD *TRD = new IlcTRDv1("TRD", "TRD slow simulator");
    }

    if (iFMD)
    {
        //=================== FMD parameters ============================
	IlcFMD *FMD = new IlcFMDv1("FMD", "normal FMD");
   }

    if (iMUON)
    {
        //=================== MUON parameters ===========================
        // New MUONv1 version (geometry defined via builders)
        IlcMUON *MUON = new IlcMUONv1("MUON", "default");
    }
    //=================== PHOS parameters ===========================

    if (iPHOS)
    {
        IlcPHOS *PHOS = new IlcPHOSv1("PHOS", "IHEP");
    }


    if (iPMD)
    {
        //=================== PMD parameters ============================
        IlcPMD *PMD = new IlcPMDv1("PMD", "normal PMD");
    }

    if (iT0)
    {
        //=================== T0 parameters ============================
        IlcT0 *T0 = new IlcT0v1("T0", "T0 Detector");
    }

    if (iEMCAL)
    {
        //=================== EMCAL parameters ============================
        IlcEMCAL *EMCAL = new IlcEMCALv2("EMCAL", "EMCAL_COMPLETEV1");
    }

     if (iACORDE)
    {
        //=================== ACORDE parameters ============================
        IlcACORDE *ACORDE = new IlcACORDEv1("ACORDE", "normal ACORDE");
    }

     if (iVZERO)
    {
        //=================== VZERO parameters ============================
        IlcVZERO *VZERO = new IlcVZEROv7("VZERO", "normal VZERO");
    }
 
             
}