/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id$*/ #include "TFlukaConfigOption.h" #include "TFlukaMCGeometry.h" #include "TFluka.h" #include "TFlukaCerenkov.h" #include #include #include #include Float_t TFlukaConfigOption::fgMatMin(-1.); Float_t TFlukaConfigOption::fgMatMax(-1.); FILE* TFlukaConfigOption::fgFile(0x0); TFlukaMCGeometry* TFlukaConfigOption::fgGeom(0x0); Double_t TFlukaConfigOption::fgDCutValue[11]; Int_t TFlukaConfigOption::fgDProcessFlag[15]; ClassImp(TFlukaConfigOption) TFlukaConfigOption::TFlukaConfigOption() { // Default constructor fMedium = -1; fCMatMin = -1.; fCMatMax = -1.; Int_t i; for (i = 0; i < 11; i++) fCutValue[i] = -1.; for (i = 0; i < 15; i++) fProcessFlag[i] = -1; } TFlukaConfigOption::TFlukaConfigOption(Int_t medium) { // Constructor fMedium = medium; fCMatMin = -1.; fCMatMax = -1.; Int_t i; for (i = 0; i < 11; i++) fCutValue[i] = -1.; for (i = 0; i < 15; i++) fProcessFlag[i] = -1; } void TFlukaConfigOption::SetCut(const char* flagname, Double_t val) { // Set a cut value const TString cuts[11] = {"CUTGAM", "CUTELE", "CUTNEU", "CUTHAD", "CUTMUO", "BCUTE", "BCUTM", "DCUTE", "DCUTM", "PPCUTM", "TOFMAX"}; Int_t i; for (i = 0; i < 11; i++) { if (cuts[i].CompareTo(flagname) == 0) { fCutValue[i] = val; if (fMedium == -1) fgDCutValue[i] = val; break; } } } void TFlukaConfigOption::SetProcess(const char* flagname, Int_t flag) { // Set a process flag const TString process[15] = {"DCAY", "PAIR", "COMP", "PHOT", "PFIS", "DRAY", "ANNI", "BREM", "MUNU", "CKOV", "HADR", "LOSS", "MULS", "RAYL", "STRA"}; Int_t i; for (i = 0; i < 15; i++) { if (process[i].CompareTo(flagname) == 0) { fProcessFlag[i] = flag; if (fMedium == -1) fgDProcessFlag[i] = flag; break; } } } void TFlukaConfigOption::WriteFlukaInputCards() { // Write the FLUKA input cards for the set of process flags and cuts // // if (fMedium > -1) { TFluka* fluka = (TFluka*) gMC; TObjArray *matList = fluka->GetFlukaMaterials(); Int_t nmaterial = matList->GetEntriesFast(); TGeoMaterial* material = 0; for (Int_t im = 0; im < nmaterial; im++) { material = dynamic_cast (matList->At(im)); Int_t idmat = material->GetIndex(); if (idmat == fMedium) break; } // // Check if global option fprintf(fgFile,"*\n*Material specific process and cut settings for #%8d %s\n", fMedium, material->GetName()); fCMatMin = fMedium; fCMatMax = fMedium; } else { fprintf(fgFile,"*\n*Global process and cut settings \n"); fCMatMin = fgMatMin; fCMatMax = fgMatMax; } // // Handle Process Flags // if (fProcessFlag[kDCAY] != -1) ProcessDCAY(); if (fProcessFlag[kPAIR] != -1) ProcessPAIR(); if (fProcessFlag[kBREM] != -1) ProcessBREM(); if (fProcessFlag[kCOMP] != -1) ProcessCOMP(); if (fProcessFlag[kPHOT] != -1) ProcessPHOT(); if (fProcessFlag[kPFIS] != -1) ProcessPFIS(); if (fProcessFlag[kANNI] != -1) ProcessANNI(); if (fProcessFlag[kMUNU] != -1) ProcessMUNU(); if (fProcessFlag[kHADR] != -1) ProcessHADR(); if (fProcessFlag[kMULS] != -1) ProcessMULS(); if (fProcessFlag[kRAYL] != -1) ProcessRAYL(); if (fProcessFlag[kLOSS] != -1 || fProcessFlag[kDRAY] != -1) ProcessLOSS(); if ((fMedium == -1 && fProcessFlag[kCKOV] > 0) || (fMedium > -1 && fProcessFlag[kCKOV] != -1)) ProcessCKOV(); // // Handle Cuts // if (fCutValue[kCUTGAM] >= 0.) ProcessCUTGAM(); if (fCutValue[kCUTELE] >= 0.) ProcessCUTELE(); if (fCutValue[kCUTNEU] >= 0.) ProcessCUTNEU(); if (fCutValue[kCUTHAD] >= 0.) ProcessCUTHAD(); if (fCutValue[kCUTMUO] >= 0.) ProcessCUTMUO(); if (fCutValue[kTOFMAX] >= 0.) ProcessTOFMAX(); } void TFlukaConfigOption::ProcessDCAY() { // Process DCAY option fprintf(fgFile,"*\n* --- DCAY --- Decays. Flag = %5d\n", fProcessFlag[kDCAY]); if (fProcessFlag[kDCAY] == 0) { printf("Decays cannot be switched off \n"); } else { fprintf(fgFile, "* Decays are on by default\n"); } } void TFlukaConfigOption::ProcessPAIR() { // Process PAIR option fprintf(fgFile,"*\n* --- PAIR --- Pair production by gammas, muons and hadrons. Flag = %5d, PPCUTM = %13.4g \n", fProcessFlag[kPAIR], fCutValue[kPPCUTM]); // // gamma -> e+ e- // if (fProcessFlag[kPAIR] > 0) { fprintf(fgFile,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",0., 0., 0., fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"EMFCUT %10.1f%10.1f%10.4g%10.1f%10.1f%10.1fPHOT-THR\n",0., 0., 1e10, fCMatMin, fCMatMax, 1.); } // // Direct pair production by Muons and Hadrons // // // Attention ! This card interferes with BREM // if (fProcessFlag[kBREM] == -1 ) fProcessFlag[kBREM] = fgDProcessFlag[kBREM]; if (fCutValue[kBCUTM] == -1.) fCutValue[kBCUTM] = fgDCutValue[kBCUTM]; Float_t flag = -3.; if (fProcessFlag[kPAIR] > 0 && fProcessFlag[kBREM] == 0) flag = 1.; if (fProcessFlag[kPAIR] == 0 && fProcessFlag[kBREM] > 0) flag = 2.; if (fProcessFlag[kPAIR] > 0 && fProcessFlag[kBREM] > 0) flag = 3.; if (fProcessFlag[kPAIR] == 0 && fProcessFlag[kBREM] == 0) flag = -3.; // Flag BREM card as handled fProcessFlag[kBREM] = -1; // // Energy cut for pair prodution // Float_t cutP = fCutValue[kPPCUTM]; if (fCutValue[kPPCUTM] == -1.) cutP = fgDCutValue[kPPCUTM]; // In G3 this is the cut on the total energy of the e+e- pair // In FLUKA the cut is on the kinetic energy of the electron and poistron cutP = cutP / 2. - 0.51099906e-3; if (cutP < 0.) cutP = 0.; // No explicite generation of e+/e- if (fProcessFlag[kPAIR] == 2) cutP = -1.; // // Energy cut for bremsstrahlung // Float_t cutB = 0.; if (flag > 1.) { fprintf(fgFile,"*\n* +++ BREM --- Bremsstrahlung by muons/hadrons. Flag = %5d, BCUTM = %13.4g \n", fProcessFlag[kBREM], fCutValue[kBCUTM]); cutB = fCutValue[kBCUTM]; // No explicite production of gammas if (fProcessFlag[kBREM] == 2) cutB = -1.; } fprintf(fgFile,"PAIRBREM %10.1f%10.4g%10.4g%10.1f%10.1f\n",flag, cutP, cutB, fCMatMin, fCMatMax); } void TFlukaConfigOption::ProcessBREM() { // Process BREM option fprintf(fgFile,"*\n* --- BREM --- Bremsstrahlung by e+/- and muons/hadrons. Flag = %5d, BCUTE = %13.4g, BCUTM = %13.4g \n", fProcessFlag[kBREM], fCutValue[kBCUTE], fCutValue[kBCUTM]); // // e+/- -> e+/- gamma // Float_t cutB = fCutValue[kBCUTE]; if (fCutValue[kBCUTE] == -1.) cutB = fgDCutValue[kBCUTE]; if (fProcessFlag[kBREM] > 0) { fprintf(fgFile,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f%10.1fELPO-THR\n",cutB, 0., 0., fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f%10.1fELPO-THR\n",1.e10, 0., 0., fCMatMin, fCMatMax, 1.); } // // Bremsstrahlung by muons and hadrons // cutB = fCutValue[kBCUTM]; if (fCutValue[kBCUTM] == -1.) cutB = fgDCutValue[kBCUTM]; if (fProcessFlag[kBREM] == 2) cutB = -1.; Float_t flag = 2.; if (fProcessFlag[kBREM] == 0) flag = -2.; fprintf(fgFile,"PAIRBREM %10.1f%10.4g%10.4g%10.1f%10.1f\n", flag, 0., cutB, fCMatMin, fCMatMax); } void TFlukaConfigOption::ProcessCOMP() { // Process COMP option fprintf(fgFile,"*\n* --- COMP --- Compton scattering Flag = %5d \n", fProcessFlag[kCOMP]); // // Compton scattering // if (fProcessFlag[kCOMP] > 0) { fprintf(fgFile,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",0. , 0., 0., fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",1.e10, 0., 0., fCMatMin, fCMatMax, 1.); } } void TFlukaConfigOption::ProcessPHOT() { // Process PHOS option fprintf(fgFile,"*\n* --- PHOT --- Photoelectric effect. Flag = %5d\n", fProcessFlag[kPHOT]); // // Photoelectric effect // if (fProcessFlag[kPHOT] > 0) { fprintf(fgFile,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",0. , 0., 0., fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"EMFCUT %10.1f%10.4g%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",0., 1.e10, 0., fCMatMin, fCMatMax, 1.); } } void TFlukaConfigOption::ProcessANNI() { // Process ANNI option fprintf(fgFile,"*\n* --- ANNI --- Positron annihilation. Flag = %5d \n", fProcessFlag[kANNI]); // // Positron annihilation // if (fProcessFlag[kANNI] > 0) { fprintf(fgFile,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fANNH-THR\n",0. , 0., 0., fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f%10.1fANNH-THR\n",1.e10, 0., 0., fCMatMin, fCMatMax, 1.); } } void TFlukaConfigOption::ProcessPFIS() { // Process PFIS option fprintf(fgFile,"*\n* --- PFIS --- Photonuclear interaction Flag = %5d\n", fProcessFlag[kPFIS]); // // Photonuclear interactions // if (fProcessFlag[kPFIS] > 0) { fprintf(fgFile,"PHOTONUC %10.1f%10.1f%10.1f%10.1f%10.1f%10.1f\n",(Float_t) fProcessFlag[kPFIS], 0., 0., fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"PHOTONUC %10.1f%10.1f%10.1f%10.1f%10.1f%10.1f\n",-1. , 0., 0., fCMatMin, fCMatMax, 1.); } } void TFlukaConfigOption::ProcessMUNU() { // Process MUNU option fprintf(fgFile,"*\n* --- MUNU --- Muon nuclear interaction. Flag = %5d\n", fProcessFlag[kMUNU]); // // Muon nuclear interactions // if (fProcessFlag[kMUNU] > 0) { fprintf(fgFile,"MUPHOTON %10.1f%10.3f%10.3f%10.1f%10.1f%10.1f\n",(Float_t )fProcessFlag[kMUNU], 0.25, 0.75, fCMatMin, fCMatMax, 1.); } else { fprintf(fgFile,"MUPHOTON %10.1f%10.1f%10.1f%10.1f%10.1f%10.1f\n",-1. , 0., 0., fCMatMin, fCMatMax, 1.); } } void TFlukaConfigOption::ProcessRAYL() { // Process RAYL option fprintf(fgFile,"*\n* --- RAYL --- Rayleigh Scattering. Flag = %5d\n", fProcessFlag[kRAYL]); // // Rayleigh scattering // Int_t nreg; Int_t* reglist = fgGeom->GetMaterialList(fMedium, nreg); // // Loop over regions of a given material for (Int_t k = 0; k < nreg; k++) { Float_t ireg = reglist[k]; if (fProcessFlag[kRAYL] > 0) { fprintf(fgFile,"EMFRAY %10.1f%10.1f%10.1f%10.1f\n", 1., ireg, ireg, 1.); } else { fprintf(fgFile,"EMFRAY %10.1f%10.1f%10.1f%10.1f\n", 3., ireg, ireg, 1.); } } } void TFlukaConfigOption::ProcessCKOV() { // Process CKOV option fprintf(fgFile,"*\n* --- CKOV --- Cerenkov Photon production. %5d\n", fProcessFlag[kCKOV]); // // Cerenkov photon production // TFluka* fluka = (TFluka*) gMC; TObjArray *matList = fluka->GetFlukaMaterials(); Int_t nmaterial = matList->GetEntriesFast(); for (Int_t im = 0; im < nmaterial; im++) { TGeoMaterial* material = dynamic_cast (matList->At(im)); Int_t idmat = material->GetIndex(); // // Check if global option if (fMedium != -1 && idmat != fMedium) continue; TFlukaCerenkov* cerenkovProp; if (!(cerenkovProp = dynamic_cast(material->GetCerenkovProperties()))) continue; // // This medium has Cerenkov properties // // if (fMedium == -1 || (fMedium != -1 && fProcessFlag[kCKOV] > 0)) { // Write OPT-PROD card for each medium Float_t emin = cerenkovProp->GetMinimumEnergy(); Float_t emax = cerenkovProp->GetMaximumEnergy(); fprintf(fgFile, "OPT-PROD %10.4g%10.4g%10.4g%10.4g%10.4g%10.4gCERENKOV\n", emin, emax, 0., Float_t(idmat), Float_t(idmat), 0.); // // Write OPT-PROP card for each medium // Forcing FLUKA to call user routines (queffc.cxx, rflctv.cxx, rfrndx.cxx) // fprintf(fgFile, "OPT-PROP %10.4g%10.4g%10.4g%10.1f%10.1f%10.1fWV-LIMIT\n", cerenkovProp->GetMinimumWavelength(), cerenkovProp->GetMaximumWavelength(), cerenkovProp->GetMaximumWavelength(), Float_t(idmat), Float_t(idmat), 0.0); fprintf(fgFile, "OPT-PROP %10.1f%10.1f%10.1f%10.1f%10.1f%10.1f\n", -100., -100., -100., Float_t(idmat), Float_t(idmat), 0.0); for (Int_t j = 0; j < 3; j++) { fprintf(fgFile, "OPT-PROP %10.1f%10.1f%10.1f%10.1f%10.1f%10.1f&\n", -100., -100., -100., Float_t(idmat), Float_t(idmat), 0.0); } // Photon detection efficiency user defined if (cerenkovProp->IsSensitive()) fprintf(fgFile, "OPT-PROP %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fSENSITIV\n", -100., -100., -100., Float_t(idmat), Float_t(idmat), 0.0); // Material has a reflective surface if (cerenkovProp->IsMetal()) fprintf(fgFile, "OPT-PROP %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fMETAL\n", -100., -100., -100., Float_t(idmat), Float_t(idmat), 0.0); } else { fprintf(fgFile,"OPT-PROD %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fCERE-OFF\n",0., 0., 0., fCMatMin, fCMatMax, 1.); } } } void TFlukaConfigOption::ProcessHADR() { // Process HADR option fprintf(fgFile,"*\n* --- HADR --- Hadronic interactions. Flag = %5d\n", fProcessFlag[kHADR]); if (fProcessFlag[kHADR] > 0) { fprintf(fgFile,"*\n*Hadronic interaction is ON by default in FLUKA\n"); } else { if (fMedium != -1) printf("Hadronic interactions cannot be switched off material by material !\n"); fprintf(fgFile,"THRESHOL %10.1f%10.1f%10.1f%10.1e%10.1f\n",0., 0., 0., 1.e10, 0.); } } void TFlukaConfigOption::ProcessMULS() { // Process MULS option fprintf(fgFile,"*\n* --- MULS --- Muliple Scattering. Flag = %5d\n", fProcessFlag[kMULS]); // // Multiple scattering // if (fProcessFlag[kMULS] > 0) { fprintf(fgFile,"*\n*Multiple scattering is ON by default in FLUKA\n"); } else { fprintf(fgFile,"MULSOPT %10.1f%10.1f%10.1f%10.1f%10.1f\n",0., 3., 3., fCMatMin, fCMatMax); } } void TFlukaConfigOption::ProcessLOSS() { // Process LOSS option fprintf(fgFile,"*\n* --- LOSS --- Ionisation energy loss. Flags: LOSS = %5d, DRAY = %5d, STRA = %5d; Cuts: DCUTE = %13.4g, DCUTM = %13.4g \n", fProcessFlag[kLOSS], fProcessFlag[kDRAY], fProcessFlag[kSTRA], fCutValue[kDCUTE], fCutValue[kDCUTM]); // // Ionisation energy loss // // // Impose consistency if (fProcessFlag[kLOSS] == 1 || fProcessFlag[kLOSS] == 3) { fProcessFlag[kDRAY] = 1; } else if (fProcessFlag[kLOSS] == 2) { fProcessFlag[kDRAY] = 0; fCutValue[kDCUTE] = 1.e10; fCutValue[kDCUTM] = 1.e10; } else { if (fProcessFlag[kDRAY] == 1) { fProcessFlag[kLOSS] = 1; } else if (fProcessFlag[kDRAY] == 0) { fProcessFlag[kLOSS] = 2; fCutValue[kDCUTE] = 1.e10; fCutValue[kDCUTM] = 1.e10; } } if (fCutValue[kDCUTE] == -1.) fCutValue[kDCUTE] = fgDCutValue[kDCUTE]; if (fCutValue[kDCUTM] == -1.) fCutValue[kDCUTM] = fgDCutValue[kDCUTM]; Float_t cutM = fCutValue[kDCUTM]; if (fProcessFlag[kSTRA] == -1) fProcessFlag[kSTRA] = fgDProcessFlag[kSTRA]; if (fProcessFlag[kSTRA] == 0) fProcessFlag[kSTRA] = 1; Float_t stra = (Float_t) fProcessFlag[kSTRA]; if (fProcessFlag[kLOSS] == 1 || fProcessFlag[kLOSS] == 3) { // // Restricted energy loss fluctuations // fprintf(fgFile,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n", 1., 1., stra, fCMatMin, fCMatMax); fprintf(fgFile,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n", cutM, 0., 0., fCMatMin, fCMatMax, 1.); } else if (fProcessFlag[kLOSS] == 4) { // // No fluctuations // fprintf(fgFile,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",-1., -1., stra, fCMatMin, fCMatMax); fprintf(fgFile,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n", 1.e10, 0., 0., fCMatMin, fCMatMax, 1.); } else { // // Full fluctuations // fprintf(fgFile,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",1., 1., stra, fCMatMin, fCMatMax); fprintf(fgFile,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n", 1.e10, 0., 0., fCMatMin, fCMatMax, 1.); } } void TFlukaConfigOption::ProcessCUTGAM() { // Cut on gammas // fprintf(fgFile,"*\n*Cut for Gammas. CUTGAM = %13.4g\n", fCutValue[kCUTGAM]); if (fMedium == -1) { fprintf(fgFile,"EMFCUT %10.4g%10.4g%10.1f%10.1f%10.1f%10.1f\n", 0., fCutValue[kCUTGAM], 0., 0., Float_t(fgGeom->NofVolumes()), 1.); } else { Int_t nreg, *reglist; Float_t ireg; reglist = fgGeom->GetMaterialList(fMedium, nreg); // Loop over regions of a given material for (Int_t k = 0; k < nreg; k++) { ireg = reglist[k]; fprintf(fgFile,"EMFCUT %10.4g%10.4g%10.1f%10.1f%10.1f%10.1f\n", 0.,fCutValue[kCUTGAM], 0., ireg, ireg, 1.); } } fprintf(fgFile,"EMFCUT %10.4g%10.4g%10.1f%10.1f%10.1f%10.1fPROD-CUT\n", 0., fCutValue[kCUTGAM], 0., fCMatMin, fCMatMax, 1.); } void TFlukaConfigOption::ProcessCUTELE() { // Cut on e+/e- // fprintf(fgFile,"*\n*Cut for e+/e-. CUTELE = %13.4g\n", fCutValue[kCUTELE]); if (fMedium == -1) { fprintf(fgFile,"EMFCUT %10.4g%10.4g%10.1f%10.1f%10.1f%10.1f\n", -fCutValue[kCUTELE], 0., 0., 0., Float_t(fgGeom->NofVolumes()), 1.); } else { Int_t nreg, *reglist; Float_t ireg; reglist = fgGeom->GetMaterialList(fMedium, nreg); // Loop over regions of a given material for (Int_t k = 0; k < nreg; k++) { ireg = reglist[k]; fprintf(fgFile,"EMFCUT %10.4g%10.4g%10.1f%10.1f%10.1f%10.1f\n", -fCutValue[kCUTELE], 0., 0., ireg, ireg, 1.); } } fprintf(fgFile,"EMFCUT %10.4g%10.4g%10.1f%10.1f%10.1f%10.1fPROD-CUT\n", -fCutValue[kCUTELE], 0., 0., fCMatMin, fCMatMax, 1.); } void TFlukaConfigOption::ProcessCUTNEU() { // Cut on neutral hadrons fprintf(fgFile,"*\n*Cut for neutral hadrons. CUTNEU = %13.4g\n", fCutValue[kCUTNEU]); if (fMedium == -1) { Float_t cut = fCutValue[kCUTNEU]; // // 8.0 = Neutron // 9.0 = Antineutron // // If the cut is > 19.6 MeV it is assumed the low energy neutron transport is requested. // In this case the cut has to coincide with the upper limit of the first energy group. // Float_t neutronCut = cut; if (neutronCut < 0.0196) { neutronCut = 0.0196; printf("Cut on neutron lower than upper limit of first energy group.\n"); printf("Cut reset to 19.6 MeV !\n"); } fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -neutronCut, 8.0, 9.0); // // 12.0 = Kaon zero long fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 12.0, 12.0); // 17.0 = Lambda, 18.0 = Antilambda // 19.0 = Kaon zero short fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 17.0, 19.0); // 22.0 = Sigma zero, Pion zero, Kaon zero // 25.0 = Antikaon zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 22.0, 25.0); // 32.0 = Antisigma zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 32.0, 32.0); // 34.0 = Xi zero // 35.0 = AntiXi zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 34.0, 35.0); // 47.0 = D zero // 48.0 = AntiD zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 47.0, 48.0); // 53.0 = Xi_c zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 53.0, 53.0); // 55.0 = Xi'_c zero // 56.0 = Omega_c zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 55.0, 56.0); // 59.0 = AntiXi_c zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 59.0, 59.0); // 61.0 = AntiXi'_c zero // 62.0 = AntiOmega_c zero fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 61.0, 62.0); } else { printf("Cuts on neutral hadrons material by material not yet implemented !\n"); } } void TFlukaConfigOption::ProcessCUTHAD() { // Cut on charged hadrons fprintf(fgFile,"*\n*Cut for charge hadrons. CUTHAD = %13.4g\n", fCutValue[kCUTHAD]); if (fMedium == -1) { Float_t cut = fCutValue[kCUTHAD]; // 1.0 = Proton // 2.0 = Antiproton fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 1.0, 2.0); // 13.0 = Positive Pion, Negative Pion, Positive Kaon // 16.0 = Negative Kaon fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 13.0, 16.0); // 20.0 = Negative Sigma // 21.0 = Positive Sigma fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 20.0, 21.0); // 31.0 = Antisigma minus // 33.0 = Antisigma plus fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 31.0, 31.0); fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 33.0, 33.0); // 36.0 = Negative Xi, Positive Xi, Omega minus // 39.0 = Antiomega fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 36.0, 39.0); // 45.0 = D plus // 46.0 = D minus fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 45.0, 46.0); // 49.0 = D_s plus, D_s minus, Lambda_c plus // 52.0 = Xi_c plus fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 49.0, 52.0); // 54.0 = Xi'_c plus // 60.0 = AntiXi'_c minus fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 54.0, 54.0); fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 60.0, 60.0); // 57.0 = Antilambda_c minus // 58.0 = AntiXi_c minus fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n", -cut, 57.0, 58.0); } else { printf("Cuts on charged hadrons material by material not yet implemented !\n"); } } void TFlukaConfigOption::ProcessCUTMUO() { // Cut on muons fprintf(fgFile,"*\n*Cut for muons. CUTMUO = %13.4g\n", fCutValue[kCUTMUO]); Float_t cut = fCutValue[kCUTMUO]; if (fMedium == -1) { fprintf(fgFile,"PART-THR %10.4g%10.1f%10.1f\n",-cut, 10.0, 11.0); } else { printf("Cuts on muons material by material not yet implemented !\n"); } } void TFlukaConfigOption::ProcessTOFMAX() { // Cut time of flight Float_t cut = fCutValue[kTOFMAX]; fprintf(fgFile,"*\n*Cut on time of flight. TOFMAX = %13.4g\n", fCutValue[kTOFMAX]); fprintf(fgFile,"TIME-CUT %10.4g%10.1f%10.1f%10.1f%10.1f\n",cut*1.e9,0.,0.,-6.0,64.0); }