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CMSMonopolePhysics.cc
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1 #include "SimG4Core/PhysicsLists/interface/CMSMonopolePhysics.h"
2 #include "SimG4Core/MagneticField/interface/ChordFinderSetter.h"
3 #include "FWCore/MessageLogger/interface/MessageLogger.h"
4 
5 #include "G4ParticleDefinition.hh"
6 #include "G4ProcessManager.hh"
7 
8 #include "G4StepLimiter.hh"
9 #include "G4Transportation.hh"
10 #include "G4MonopoleTransportation.hh"
11 #include "G4mplIonisation.hh"
12 #include "G4mplIonisationWithDeltaModel.hh"
13 #include "G4hMultipleScattering.hh"
14 #include "G4hIonisation.hh"
15 #include "G4hhIonisation.hh"
16 
17 #include "CLHEP/Units/GlobalSystemOfUnits.h"
18 
19 CMSMonopolePhysics::CMSMonopolePhysics(const HepPDT::ParticleDataTable * pdt,
20  sim::ChordFinderSetter * cfs_,
21  const edm::ParameterSet & p) :
22  G4VPhysicsConstructor("Monopole Physics"), chordFinderSetter(cfs_) {
23 
24  verbose = p.getUntrackedParameter<int>("Verbosity",0);
25  magCharge = p.getUntrackedParameter<int>("MonopoleCharge",1);
26  deltaRay = p.getUntrackedParameter<bool>("MonopoleDeltaRay",true);
27  multiSc = p.getUntrackedParameter<bool>("MonopoleMultiScatter",false);
28  transport = p.getUntrackedParameter<bool>("MonopoleTransport",true);
29  double mass = p.getUntrackedParameter<double>("MonopoleMass",200);
30  if (pdt && mass > 0.0) {
31  int ii=0;
32  for (HepPDT::ParticleDataTable::const_iterator p=pdt->begin();
33  p != pdt->end(); ++p,++ii) {
34  HepPDT::ParticleData particle = (p->second);
35  std::string particleName = (particle.name()).substr(0,8);
36  if (strcmp(particleName.c_str(),"Monopole") == 0) {
37  names.push_back(particle.name());
38  masses.push_back(mass*CLHEP::GeV);
39  elCharges.push_back((int)(particle.charge()));
40  pdgEncodings.push_back(particle.pid());
41  monopoles.push_back(0);
42  //std::cout << "CMSMonopolePhysics: Monopole[" << ii
43  if (verbose > 0) G4cout << "CMSMonopolePhysics: Monopole[" << ii
44  << "] " << particleName << " Mass "
45  << particle.mass() << " GeV, Magnetic Charge "
46  << magCharge << ", Electric Charge "
47  << particle.charge() << G4endl;
48  } else if(strcmp(particleName.c_str(),"AntiMono") == 0) {
49  names.push_back(particle.name());
50  masses.push_back(mass*CLHEP::GeV);
51  elCharges.push_back((int)(particle.charge()));
52  pdgEncodings.push_back(particle.pid());
53  monopoles.push_back(0);
54  //std::cout << "CMSMonopolePhysics: Monopole[" << ii
55  if (verbose > 0) G4cout << "CMSMonopolePhysics: Monopole[" << ii
56  << "] " << particleName << " Mass "
57  << particle.mass() << " GeV, Magnetic Charge "
58  << magCharge << ", Electric Charge "
59  << particle.charge() << G4endl;
60  }
61  }
62  }
63  // std::cout << "CMSMonopolePhysics has " << names.size()
64  if (verbose > 0) G4cout << "CMSMonopolePhysics has " << names.size()
65  << " monopole candidates and delta Ray option "
66  << deltaRay << G4endl;
67 }
68 
69 CMSMonopolePhysics::~CMSMonopolePhysics() {}
70 
71 void CMSMonopolePhysics::ConstructParticle() {
72 
73  for (unsigned int ii=0; ii<names.size(); ++ii) {
74  if (!monopoles[ii]) {
75  G4Monopole* mpl = new G4Monopole(names[ii], pdgEncodings[ii],
76  masses[ii], ((pdgEncodings[ii] > 0 ) ? magCharge : -magCharge), elCharges[ii]);;
77  monopoles[ii] = mpl;
78  //std::cout << "Create G4Monopole " << names[ii]
79  if (verbose > 0) G4cout << "Create G4Monopole " << names[ii]
80  << " of mass " << masses[ii]/CLHEP::GeV
81  << " GeV, magnetic charge " << ((pdgEncodings[ii] > 0) ? magCharge : -magCharge)
82  << ", electric charge " << elCharges[ii]
83  << " and PDG encoding " << pdgEncodings[ii]
84  << " at " << monopoles[ii] << G4endl;
85  }
86  }
87 }
88 
89 void CMSMonopolePhysics::ConstructProcess() {
90  // Add standard EM Processes
91 
92  if (verbose > 0)
93  G4cout << "### CMSMonopolePhysics ConstructProcess()" << G4endl;
94  for (unsigned int ii=0; ii<monopoles.size(); ++ii) {
95  if (monopoles[ii]) {
96  G4Monopole* mpl = monopoles[ii];
97  G4ProcessManager* pmanager = new G4ProcessManager(mpl);
98  mpl->SetProcessManager(pmanager);
99 
100  G4String particleName = mpl->GetParticleName();
101  G4double magn = mpl->MagneticCharge();
102  G4double mass = mpl->GetPDGMass();
103  if (verbose > 1)
104  G4cout << "### CMSMonopolePhysics instantiates for " << particleName
105  << " at " << mpl << " Mass " << mass/CLHEP::GeV
106  << " GeV Mag " << magn << " Process manager " << pmanager
107  << G4endl;
108 
109  // defined monopole parameters and binning
110 
111  G4double emin = mass/20000.;
112  if(emin < CLHEP::keV) emin = CLHEP::keV;
113  G4double emax = std::max(10.*CLHEP::TeV, mass*100);
114  G4int nbin = G4int(std::log10(emax/emin));
115  if (nbin < 1) nbin = 1;
116  nbin *= 10;
117 
118  G4int idx = 1;
119  if (verbose > 1)
120  G4cout << "### Magnetic charge " << magn << " and electric charge "
121  << mpl->GetPDGCharge() <<"\n # of bins in dE/dx table = "
122  << nbin << " in the range " << emin << ":" << emax << G4endl;
123 
124  if (magn == 0.0 || (!transport)) {
125  pmanager->AddProcess( new G4Transportation(verbose), -1, 0, 0);
126  } else {
127  pmanager->AddProcess( new G4MonopoleTransportation(mpl,chordFinderSetter,verbose), -1, 0, 0);
128  }
129 
130  if (mpl->GetPDGCharge() != 0.0) {
131  if (multiSc) {
132  G4hMultipleScattering* hmsc = new G4hMultipleScattering();
133  pmanager->AddProcess(hmsc, -1, idx, idx);
134  ++idx;
135  }
136  if (deltaRay) {
137  G4hIonisation* hhioni = new G4hIonisation();
138  hhioni->SetDEDXBinning(nbin);
139  hhioni->SetMinKinEnergy(emin);
140  hhioni->SetMaxKinEnergy(emax);
141  pmanager->AddProcess(hhioni, -1, idx, idx);
142  } else {
143  G4hhIonisation* hhioni = new G4hhIonisation();
144  hhioni->SetDEDXBinning(nbin);
145  hhioni->SetMinKinEnergy(emin);
146  hhioni->SetMaxKinEnergy(emax);
147  pmanager->AddProcess(hhioni, -1, idx, idx);
148  }
149  ++idx;
150  }
151  if(magn != 0.0) {
152  G4mplIonisation* mplioni = new G4mplIonisation(magn);
153  mplioni->SetDEDXBinning(nbin);
154  mplioni->SetMinKinEnergy(emin);
155  mplioni->SetMaxKinEnergy(emax);
156  if (!deltaRay) {
157  G4mplIonisationWithDeltaModel* mod =
158  new G4mplIonisationWithDeltaModel(magn,"PAI");
159  mplioni->AddEmModel(0,mod,mod);
160  }
161  pmanager->AddProcess(mplioni, -1, idx, idx);
162  ++idx;
163  }
164  pmanager->AddProcess( new G4StepLimiter(), -1, -1, idx);
165  if (verbose > 1) pmanager->DumpInfo();
166  }
167  }
168 }
edm::ParameterSet::getUntrackedParameter
T getUntrackedParameter(std::string const &, T const &) const
CMSMonopolePhysics::pdgEncodings
std::vector< int > pdgEncodings
Definition: CMSMonopolePhysics.h:33
ParticleDataTable
HepPDT::ParticleDataTable ParticleDataTable
Definition: ParticleDataTable.h:8
cuy.ii
int ii
Definition: cuy.py:588
AlCaHLTBitMon_QueryRunRegistry.string
string string
Definition: AlCaHLTBitMon_QueryRunRegistry.py:255
max
const T & max(const T &a, const T &b)
Definition: MaterialBudgetTrackerHistos.cc:4
CMSMonopolePhysics::monopoles
std::vector< G4Monopole * > monopoles
Definition: CMSMonopolePhysics.h:34
CMSMonopolePhysics::CMSMonopolePhysics
CMSMonopolePhysics(const HepPDT::ParticleDataTable *table_, sim::ChordFinderSetter *cfs_, const edm::ParameterSet &p)
Definition: CMSMonopolePhysics.cc:19
CMSMonopolePhysics::elCharges
std::vector< int > elCharges
Definition: CMSMonopolePhysics.h:33
ParticleData
HepPDT::ParticleData ParticleData
Definition: ParticleDataTable.h:9
CMSMonopolePhysics::names
std::vector< std::string > names
Definition: CMSMonopolePhysics.h:31
customizeTrackingMonitorSeedNumber.idx
tuple idx
DEBUGGING if hasattr(process,&quot;trackMonIterativeTracking2012&quot;): print &quot;trackMonIterativeTracking2012 D...
Definition: customizeTrackingMonitorSeedNumber.py:15
CMSMonopolePhysics::chordFinderSetter
sim::ChordFinderSetter * chordFinderSetter
Definition: CMSMonopolePhysics.h:28
AlCaHLTBitMon_ParallelJobs.p
tuple p
Definition: AlCaHLTBitMon_ParallelJobs.py:152
CMSMonopolePhysics::masses
std::vector< double > masses
Definition: CMSMonopolePhysics.h:32
mod
T mod(const T &a, const T &b)
Definition: ecalDccMap.h:4
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