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#include <HICFTSfromL1orL2.h>
Public Member Functions | |
| std::vector< FreeTrajectoryState > | createFTSfromL1 (std::vector< L1MuGMTExtendedCand > &) |
| std::vector< FreeTrajectoryState > | createFTSfromL1orL2 (std::vector< L1MuGMTExtendedCand > &gmt, const reco::RecoChargedCandidateCollection &recmuons) |
| std::vector< FreeTrajectoryState > | createFTSfromL2 (const reco::RecoChargedCandidateCollection &rc) |
| std::vector< FreeTrajectoryState > | createFTSfromL2 (const reco::TrackCollection &rc) |
| std::vector< FreeTrajectoryState > | createFTSfromStandAlone (const reco::TrackCollection &rc) |
| HICFTSfromL1orL2 (const MagneticField *mf) | |
| virtual | ~HICFTSfromL1orL2 () |
Private Member Functions | |
| FreeTrajectoryState | FTSfromL1 (const L1MuGMTExtendedCand &gmt) |
| FreeTrajectoryState | FTSfromL2 (const reco::RecoChargedCandidate &gmt) |
| FreeTrajectoryState | FTSfromStandAlone (const reco::Track &gmt) |
Private Attributes | |
| const MagneticField * | field |
Definition at line 40 of file HICFTSfromL1orL2.h.
| cms::HICFTSfromL1orL2::HICFTSfromL1orL2 | ( | const MagneticField * | mf | ) | [inline] |
| virtual cms::HICFTSfromL1orL2::~HICFTSfromL1orL2 | ( | ) | [inline, virtual] |
Definition at line 46 of file HICFTSfromL1orL2.h.
{}
| vector< FreeTrajectoryState > cms::HICFTSfromL1orL2::createFTSfromL1 | ( | std::vector< L1MuGMTExtendedCand > & | ) |
Definition at line 12 of file HICFTSfromL1orL2.cc.
References gather_cfg::cout.
{
// ========================================================================================
//
// Switch on L1 muon trigger.
//
vector<FreeTrajectoryState> ftsL1;
int ngmt = gmt.size();
#ifdef DEBUG
cout << "Number of muons found by the L1 Global Muon TRIGGER : "
<< ngmt << endl;
#endif
if(ngmt<0) {
return ftsL1;
}
for ( vector<L1MuGMTExtendedCand>::const_iterator gmt_it = gmt.begin(); gmt_it != gmt.end(); gmt_it++ )
{
ftsL1.push_back(FTSfromL1((*gmt_it)));
}
return ftsL1;
} // end createFTSfromL1
| vector< FreeTrajectoryState > cms::HICFTSfromL1orL2::createFTSfromL1orL2 | ( | std::vector< L1MuGMTExtendedCand > & | gmt, |
| const reco::RecoChargedCandidateCollection & | recmuons | ||
| ) |
Definition at line 117 of file HICFTSfromL1orL2.cc.
References abs, gather_cfg::cout, spr::find(), pi, and mathSSE::sqrt().
{
double pi=4.*atan(1.);
double twopi=8.*atan(1.);
vector<FreeTrajectoryState> ftsL1orL2;
vector<FreeTrajectoryState> ftsL1 = createFTSfromL1(gmt);
vector<FreeTrajectoryState> ftsL2 = createFTSfromL2(recmuons);
//
// Clean candidates if L1 and L2 pointed to one muon.
//
vector<FreeTrajectoryState*>::iterator itused;
vector<FreeTrajectoryState*> used;
for(vector<FreeTrajectoryState>::iterator tl1 = ftsL1.begin(); tl1 != ftsL1.end(); tl1++)
{
// float ptL1 = (*tl1).parameters().momentum().perp();
float etaL1 = (*tl1).parameters().momentum().eta();
float phiL1 = (*tl1).parameters().momentum().phi();
if( phiL1 < 0.) phiL1 = twopi + phiL1;
// int chargeL1 = (*tl1).charge();
int L2 = 0; // there is no L2 muon.
for(vector<FreeTrajectoryState>::iterator tl2 = ftsL2.begin(); tl2 != ftsL2.end(); tl2++)
{
itused = find(used.begin(),used.end(),&(*tl2));
// float ptL2 = (*tl2).parameters().momentum().perp();
float etaL2 = (*tl2).parameters().momentum().eta();
float phiL2 = (*tl2).parameters().momentum().phi();
if( phiL2 < 0.) phiL2 = twopi + phiL2;
// int chargeL2 = (*tl2).charge();
float dphi = abs(phiL1-phiL2);
if( dphi > pi ) dphi = twopi - dphi;
float dr = sqrt((etaL1 - etaL2)*(etaL1 - etaL2)+dphi*dphi);
#ifdef OK_DEBUG
cout<<" ===== Trigger Level 1 candidate: ptL1 "<<ptL1<<" EtaL1 "<<etaL1<<" PhiL1 "<<phiL1<<
" chargeL1 "<<chargeL1<<endl;
cout<<" ===== Trigger Level 2 candidate: ptL2 "<<ptL2<<" EtaL2 "<<etaL2<<" PhiL2 "<<phiL2<<
" chargeL2 "<<chargeL2<<endl;
cout<<" abs(EtaL1 - EtaL2) "<<abs(etaL1 - etaL2)<<" dphi "<<dphi<<" dr "<<dr<<
" dQ "<<chargeL1 - chargeL2
<<" the same muon or not L2 "<<L2<<endl;
#endif
if ( itused != used.end() ) {
// cout<<" L2 is already used in primary cycle"<<endl;
continue;
}
float drmax = 0.5;
if( abs(etaL1) > 1.9 ) drmax = 0.6;
#ifdef OK_DEBUG
cout<<" Drmax= "<<drmax<<endl;
#endif
L2 = 0;
if( dr < drmax )
{ // it is the same muon. Take L2 trigger.
// if ( chargeL1 == chargeL2 )
// { // The same muon. Take L2 candidate.
L2 = 1;
ftsL1orL2.push_back((*tl2));
used.push_back(&(*tl2));
// cout<<" add L2 for same muon"<<endl;
break;
// } // endif
// else
// { // Probably different muons in the same cell. Try to recover on L3.
// ftsL1orL2.push_back((*tl1));
// ftsL1orL2.push_back((*tl2));
// cout<<" add L2 for diff muon"<<endl;
// used.push_back(&(*tl2));
// } // endelse
} // endif
} // end for L2
if( L2 == 0 )
{
// cout<<" add L1 for no L2 muon"<<endl;
ftsL1orL2.push_back((*tl1)); // No L1 candidate. Take L1 candidate.
}
} // end for L1
// cout<<" Add the last L2 candidates that have not corresponding L1 "<<endl;
if( ftsL2.size() > 0 )
{ // just add the ramains L2 candidates
for(vector<FreeTrajectoryState>::iterator tl2 = ftsL2.begin(); tl2 != ftsL2.end(); tl2++)
{
itused = find(used.begin(),used.end(),&(*tl2));
if ( itused != used.end() )
{
// cout<<" L2 is already used in secondary cycle"<<endl;
continue;
}
ftsL1orL2.push_back((*tl2));
} // end for L2
}
// cout<<" The number of trajectories in muon stations "<<ftsL1orL2.size()<<endl;
return ftsL1orL2;
}
| vector< FreeTrajectoryState > cms::HICFTSfromL1orL2::createFTSfromL2 | ( | const reco::TrackCollection & | rc | ) |
Definition at line 88 of file HICFTSfromL1orL2.cc.
References gather_cfg::cout.
{
// ========================================================================================
//
// Switch on L2 muon trigger.
//
vector<FreeTrajectoryState> ftsL2;
// RecQuery q(localRecAlgo);
TrackCollection::const_iterator recmuon = recmuons.begin();
// int nrec = recmuons.size();
#ifdef DEBUG
cout << "Number of muons found by the StandAlone : "
<< nrec << endl;
#endif
for(recmuon=recmuons.begin(); recmuon!=recmuons.end(); recmuon++)
{
ftsL2.push_back(FTSfromStandAlone((*recmuon)));
} // endfor
return ftsL2;
} // end createFTSfromStandAlone
| vector< FreeTrajectoryState > cms::HICFTSfromL1orL2::createFTSfromL2 | ( | const reco::RecoChargedCandidateCollection & | rc | ) |
Definition at line 39 of file HICFTSfromL1orL2.cc.
References gather_cfg::cout.
Referenced by cms::HITrackVertexMaker::produceTracks().
{
// ========================================================================================
//
// Switch on L2 muon trigger.
//
vector<FreeTrajectoryState> ftsL2;
// RecQuery q(localRecAlgo);
RecoChargedCandidateCollection::const_iterator recmuon = recmuons.begin();
// int nrec = recmuons.size();
#ifdef DEBUG
cout << "Number of muons found by the L2 TRIGGER : "
<< nrec << endl;
#endif
for(recmuon=recmuons.begin(); recmuon!=recmuons.end(); recmuon++)
{
ftsL2.push_back(FTSfromL2((*recmuon)));
} // endfor
return ftsL2;
} // end createFTSfromL2
| vector< FreeTrajectoryState > cms::HICFTSfromL1orL2::createFTSfromStandAlone | ( | const reco::TrackCollection & | rc | ) |
Definition at line 64 of file HICFTSfromL1orL2.cc.
References gather_cfg::cout.
{
// ========================================================================================
//
// Switch on L2 muon trigger.
//
vector<FreeTrajectoryState> ftsL2;
// RecQuery q(localRecAlgo);
TrackCollection::const_iterator recmuon = recmuons.begin();
// int nrec = recmuons.size();
#ifdef DEBUG
cout << "Number of muons found by the StandAlone : "
<< nrec << endl;
#endif
for(recmuon=recmuons.begin(); recmuon!=recmuons.end(); recmuon++)
{
ftsL2.push_back(FTSfromStandAlone((*recmuon)));
} // endfor
return ftsL2;
} // end createFTSfromStandAlone
| FreeTrajectoryState cms::HICFTSfromL1orL2::FTSfromL1 | ( | const L1MuGMTExtendedCand & | gmt | ) | [private] |
Definition at line 223 of file HICFTSfromL1orL2.cc.
References abs, Reference_intrackfit_cff::barrel, L1MuGMTCand::charge(), DeDxDiscriminatorTools::charge(), funct::cos(), eta(), L1MuGMTCand::etaValue(), create_public_lumi_plots::exp, L1MuGMTExtendedCand::isFwd(), m, phi, L1MuGMTCand::phiValue(), pi, L1MuGMTCand::ptValue(), CosmicsPD_Skims::radius, funct::sin(), funct::tan(), theta(), x, detailsBasic3DVector::y, and z.
{
double pi=4.*atan(1.);
unsigned int det = gmt.isFwd();
double px,py,pz,x,y,z;
float pt = gmt.ptValue();
float eta = gmt.etaValue();
float theta = 2*atan(exp(-eta));
float phi = gmt.phiValue();
int charge = gmt.charge();
bool barrel = true;
if(det) barrel = false;
//
// Take constant radius for barrel = 513 cm and constant z for endcap = 800 cm.
// hardcodded.
//
float radius = 513.;
if ( !barrel ) {
radius = 800.;
if(eta<0.) radius=-1.*radius;
}
if ( barrel && pt < 3.5 ) pt = 3.5;
if ( !barrel && pt < 1.0 ) pt = 1.0;
// Calculate FTS for barrel and endcap
if(barrel){
// barrel
if(abs(theta-pi/2.)<0.00001){
pz=0.;
z=0.;
}else{
pz=pt/tan(theta);
z=radius/tan(theta);
}
x=radius*cos(phi);
y=radius*sin(phi);
} else {
// endcap
pz=pt/tan(theta);
z=radius;
x=z*tan(theta)*cos(phi);
y=z*tan(theta)*sin(phi);
}
px=pt*cos(phi);
py=pt*sin(phi);
// cout<<" CreateFts:x,y,x,px,py,pz "<<x<< " "<<y<<" "<<z<<" "<<px<<" "<<py<<" "<<pz<<endl;
GlobalPoint aX(x,y,z);
GlobalVector aP(px,py,pz);
GlobalTrajectoryParameters gtp(aX,aP,charge,field);
AlgebraicSymMatrix55 m;
m(0,0)=0.6*pt; m(1,1)=1.; m(2,2)=1.;
m(3,3)=1.;m(4,4)=0.;
CurvilinearTrajectoryError cte(m);
FreeTrajectoryState fts(gtp,cte);
return fts;
}
| FreeTrajectoryState cms::HICFTSfromL1orL2::FTSfromL2 | ( | const reco::RecoChargedCandidate & | gmt | ) | [private] |
Definition at line 296 of file HICFTSfromL1orL2.cc.
References abs, corr, reco::LeafCandidate::get(), m, pos, createTree::pp, mathSSE::sqrt(), funct::tan(), and theta().
{
TrackRef tk1 = gmt.get<TrackRef>();
const math::XYZPoint pos0 = tk1->innerPosition();
const math::XYZVector mom0 = tk1->innerMomentum();
double pp = sqrt(mom0.x()*mom0.x()+mom0.y()*mom0.y()+mom0.z()*mom0.z());
double pt = sqrt(mom0.x()*mom0.x()+mom0.y()*mom0.y());
double theta = mom0.theta();
double pz = mom0.z();
GlobalVector mom(mom0.x(),mom0.y(),mom0.z());
if( pt < 4.)
{
pt = 4.; if (abs(pz) > 0. ) pz = pt/tan(theta);
double corr = sqrt( pt*pt + pz*pz )/pp;
GlobalVector mom1( corr*mom0.x(), corr*mom0.y(), corr*mom0.z() );
mom = mom1;
}
// cout<<" L2::Innermost state "<<pos0<<" new momentum "<<mom<<" old momentum "<<mom0<<endl;
AlgebraicSymMatrix55 m;
/*
double error;
if( abs(mom.eta()) < 1. )
{
error = 0.6*mom.perp();
}
else
{
error = 0.6*abs(mom.z());
}
*/
m(0,0)=0.6*mom.perp(); m(1,1)=1.; m(2,2)=1.;
m(3,3)=1.;m(4,4)=0.;
CurvilinearTrajectoryError cte(m);
GlobalPoint pos(pos0.x(),pos0.y(),pos0.z());
GlobalTrajectoryParameters gtp(pos,mom,tk1->charge(), field);
FreeTrajectoryState fts(gtp,cte);
return fts;
}
| FreeTrajectoryState cms::HICFTSfromL1orL2::FTSfromStandAlone | ( | const reco::Track & | gmt | ) | [private] |
Definition at line 346 of file HICFTSfromL1orL2.cc.
References abs, reco::TrackBase::charge(), corr, reco::Track::innerMomentum(), reco::Track::innerPosition(), m, pos, createTree::pp, mathSSE::sqrt(), funct::tan(), and theta().
{
// TrackRef tk1 = gmt.get<TrackRef>();
const math::XYZPoint pos0 = tk1.innerPosition();
const math::XYZVector mom0 = tk1.innerMomentum();
double pp = sqrt(mom0.x()*mom0.x()+mom0.y()*mom0.y()+mom0.z()*mom0.z());
double pt = sqrt(mom0.x()*mom0.x()+mom0.y()*mom0.y());
double theta = mom0.theta();
double pz = mom0.z();
GlobalVector mom(mom0.x(),mom0.y(),mom0.z());
if( pt < 4.)
{
pt = 4.; if (abs(pz) > 0. ) pz = pt/tan(theta);
double corr = sqrt( pt*pt + pz*pz )/pp;
GlobalVector mom1( corr*mom0.x(), corr*mom0.y(), corr*mom0.z() );
mom = mom1;
}
//cout<<" StandAlone::Innermost state "<<pos0<<" new momentum "<<mom<<" old momentum "<<mom0<<endl;
AlgebraicSymMatrix55 m;
/*
double error;
if( abs(mom.eta()) < 1. )
{
error = 0.6*mom.perp();
}
else
{
error = 0.6*abs(mom.z());
}
*/
m(0,0)=0.6*mom.perp(); m(1,1)=1.; m(2,2)=1.;
m(3,3)=1.;m(4,4)=0.;
CurvilinearTrajectoryError cte(m);
GlobalPoint pos(pos0.x(),pos0.y(),pos0.z());
GlobalTrajectoryParameters gtp(pos,mom,tk1.charge(), field);
FreeTrajectoryState fts(gtp,cte);
return fts;
}
const MagneticField* cms::HICFTSfromL1orL2::field [private] |
Definition at line 58 of file HICFTSfromL1orL2.h.
Referenced by HICFTSfromL1orL2().
1.7.3