#include <MuonTrajectoryCleaner.h>
Public Types | |
typedef MuonCandidate::CandidateContainer | CandidateContainer |
typedef MuonCandidate::TrajectoryContainer | TrajectoryContainer |
Public Member Functions | |
void | clean (TrajectoryContainer &muonTrajectories, edm::Event &evt) |
Clean the trajectories container, erasing the (worst) clone trajectory. | |
void | clean (CandidateContainer &muonTrajectories) |
Clean the candidates container, erasing the (worst) clone trajectory. | |
MuonTrajectoryCleaner (bool reportGhosts) | |
Constructor for L2 muons (enable reportGhosts) | |
MuonTrajectoryCleaner () | |
Constructor. | |
virtual | ~MuonTrajectoryCleaner () |
Destructor. | |
Private Attributes | |
bool | reportGhosts_ |
No description available.
Definition at line 18 of file MuonTrajectoryCleaner.h.
Definition at line 21 of file MuonTrajectoryCleaner.h.
Definition at line 20 of file MuonTrajectoryCleaner.h.
MuonTrajectoryCleaner::MuonTrajectoryCleaner | ( | ) | [inline] |
MuonTrajectoryCleaner::MuonTrajectoryCleaner | ( | bool | reportGhosts | ) | [inline] |
Constructor for L2 muons (enable reportGhosts)
Definition at line 28 of file MuonTrajectoryCleaner.h.
: reportGhosts_(reportGhosts) {}
virtual MuonTrajectoryCleaner::~MuonTrajectoryCleaner | ( | ) | [inline, virtual] |
void MuonTrajectoryCleaner::clean | ( | TrajectoryContainer & | muonTrajectories, |
edm::Event & | evt | ||
) |
Clean the trajectories container, erasing the (worst) clone trajectory.
Definition at line 22 of file MuonTrajectoryCleaner.cc.
References abs, begin, MuonTransientTrackingRecHitBreaker::breakInSubRecHits(), edm::RefToBase< T >::castTo(), alignCSCRings::e, end, i, j, LogTrace, mag(), match(), metname, gsfElectronCkfTrackCandidateMaker_cff::minPt, and query::result.
Referenced by MuonTrackFinder::reconstruct().
{ const std::string metname = "Muon|RecoMuon|MuonTrajectoryCleaner"; LogTrace(metname) << "Muon Trajectory Cleaner called" << endl; TrajectoryContainer::iterator iter, jter; Trajectory::DataContainer::const_iterator m1, m2; if ( trajC.size() < 1 ) return; LogTrace(metname) << "Number of trajectories in the container: " <<trajC.size()<< endl; int i(0), j(0); int match(0); int nTot1DHits_i(0), nTot1DHits_j(0); // tot number of 1D/2D hits (including invalid) // Map between chosen seed and ghost seeds (for trigger) map<int, vector<int> > seedmap; // CAVEAT: vector<bool> is not a vector, its elements are not addressable! // This is fine as long as only operator [] is used as in this case. // cf. par 16.3.11 vector<bool> mask(trajC.size(),true); TrajectoryContainer result; for ( iter = trajC.begin(); iter != trajC.end(); iter++ ) { if ( !mask[i] ) { i++; continue; } if ( !(*iter)->isValid() || (*iter)->empty() ) {mask[i] = false; i++; continue; } if(seedmap.count(i)==0) seedmap[i].push_back(i); const Trajectory::DataContainer& meas1 = (*iter)->measurements(); j = i+1; bool skipnext=false; for ( jter = iter+1; jter != trajC.end(); jter++ ) { if ( !mask[j] ) { j++; continue; } if(seedmap.count(j)==0) seedmap[j].push_back(j); const Trajectory::DataContainer& meas2 = (*jter)->measurements(); match = 0; nTot1DHits_i = 0; for( m1 = meas1.begin(); m1 != meas1.end(); m1++ ) { TransientTrackingRecHit::ConstRecHitContainer trhC1; if((*m1).recHit()->dimension()==4) trhC1 = MuonTransientTrackingRecHitBreaker::breakInSubRecHits((*m1).recHit(), 2); else trhC1.push_back((*m1).recHit()); for( TransientTrackingRecHit::ConstRecHitContainer::const_iterator trh1=trhC1.begin(); trh1!=trhC1.end(); ++trh1, ++nTot1DHits_i) { nTot1DHits_j = 0; for( m2 = meas2.begin(); m2 != meas2.end(); m2++ ) { TransientTrackingRecHit::ConstRecHitContainer trhC2; if((*m2).recHit()->dimension()==4) trhC2 = MuonTransientTrackingRecHitBreaker::breakInSubRecHits((*m2).recHit(), 2); else trhC2.push_back((*m2).recHit()); for( TransientTrackingRecHit::ConstRecHitContainer::const_iterator trh2=trhC2.begin(); trh2!=trhC2.end(); ++trh2, ++nTot1DHits_j) { if( ( (*trh1)->globalPosition() - (*trh2)->globalPosition()).mag() < 10e-5 ) match++; // if ( ( (*m1).recHit()->globalPosition() - (*m2).recHit()->globalPosition()).mag()< 10e-5 ) match++; } // end for( trh2 ... ) } // end for( m2 ... ) } // end for( trh1 ... ) } // end for( m1 ... ) int nTotHits_i = (*iter)->measurements().size(); int nTotHits_j = (*jter)->measurements().size(); // FIXME Set Boff/on via cfg! double chi2_dof_i = (*iter)->ndof() > 0 ? (*iter)->chiSquared()/(*iter)->ndof() : (*iter)->chiSquared()/1e-10; double chi2_dof_j = (*jter)->ndof() > 0 ? (*jter)->chiSquared()/(*jter)->ndof() : (*jter)->chiSquared()/1e-10; LogTrace(metname) << " MuonTrajectoryCleaner:"; LogTrace(metname) << " * trajC " << i << " (pT="<<(*iter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) - chi2/nDOF = " << (*iter)->chiSquared() << "/" << (*iter)->ndof() << " = " << chi2_dof_i; LogTrace(metname) << " - valid RH = " << (*iter)->foundHits() << " / total RH = " << nTotHits_i << " / total 1D RH = " << nTot1DHits_i; LogTrace(metname) << " * trajC " << j << " (pT="<<(*jter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) - chi2/nDOF = " << (*jter)->chiSquared() << "/" << (*jter)->ndof() << " = " << chi2_dof_j; LogTrace(metname) << " - valid RH = " << (*jter)->foundHits() << " / total RH = " << nTotHits_j << " / total 1D RH = " << nTot1DHits_j; LogTrace(metname) << " *** Shared 1D RecHits: " << match; int hit_diff = (*iter)->foundHits() - (*jter)->foundHits() ; // If there are matches, reject the worst track if ( match > 0 ) { // If the difference of # of rechits is less than 4, compare the chi2/ndf if ( abs(hit_diff) <= 4 ) { double minPt = 3.5; double dPt = 7.; // i.e. considering 10% (conservative!) resolution at minPt it is ~ 10 sigma away from the central value double maxFraction = 0.95; double fraction = (2.*match)/((*iter)->measurements().size()+(*jter)->measurements().size()); int belowLimit = 0; int above = 0; if((*jter)->lastMeasurement().updatedState().globalMomentum().perp() <= minPt) ++belowLimit; if((*iter)->lastMeasurement().updatedState().globalMomentum().perp() <= minPt) ++belowLimit; if((*jter)->lastMeasurement().updatedState().globalMomentum().perp() >= dPt) ++above; if((*iter)->lastMeasurement().updatedState().globalMomentum().perp() >= dPt) ++above; if(fraction >= maxFraction && belowLimit == 1 && above == 1){ if((*iter)->lastMeasurement().updatedState().globalMomentum().perp() < minPt){ mask[i] = false; skipnext=true; seedmap[j].insert(seedmap[j].end(), seedmap[i].begin(), seedmap[i].end()); seedmap.erase(i); LogTrace(metname) << "Trajectory # " << i << " (pT="<<(*iter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) rejected because it has too low pt"; } else { mask[j] = false; seedmap[i].insert(seedmap[i].end(), seedmap[j].begin(), seedmap[j].end()); seedmap.erase(j); LogTrace(metname) << "Trajectory # " << j << " (pT="<<(*jter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) rejected because it has too low pt"; } } else{ if (chi2_dof_i > chi2_dof_j) { mask[i] = false; skipnext=true; seedmap[j].insert(seedmap[j].end(), seedmap[i].begin(), seedmap[i].end()); seedmap.erase(i); LogTrace(metname) << "Trajectory # " << i << " (pT="<<(*iter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) rejected"; } else{ mask[j] = false; seedmap[i].insert(seedmap[i].end(), seedmap[j].begin(), seedmap[j].end()); seedmap.erase(j); LogTrace(metname) << "Trajectory # " << j << " (pT="<<(*jter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) rejected"; } } } else { // different number of hits if ( hit_diff < 0 ) { mask[i] = false; skipnext=true; seedmap[j].insert(seedmap[j].end(), seedmap[i].begin(), seedmap[i].end()); seedmap.erase(i); LogTrace(metname) << "Trajectory # " << i << " (pT="<<(*iter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) rejected"; } else { mask[j] = false; seedmap[i].insert(seedmap[i].end(), seedmap[j].begin(), seedmap[j].end()); seedmap.erase(j); LogTrace(metname) << "Trajectory # " << j << " (pT="<<(*jter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV) rejected"; } } } if(skipnext) break; j++; } i++; if(skipnext) continue; } // Association map between the seed of the chosen trajectory and the seeds of the discarded trajectories if(reportGhosts_) { LogTrace(metname) << " Creating map between chosen seed and ghost seeds." << std::endl; auto_ptr<L2SeedAssoc> seedToSeedsMap(new L2SeedAssoc); int seedcnt(0); for(map<int, vector<int> >::iterator itmap=seedmap.begin(); itmap!=seedmap.end(); ++itmap, ++seedcnt) { edm::RefToBase<TrajectorySeed> tmpSeedRef1 = trajC[(*itmap).first]->seedRef(); edm::Ref<L2MuonTrajectorySeedCollection> tmpL2SeedRef1 = tmpSeedRef1.castTo<edm::Ref<L2MuonTrajectorySeedCollection> >(); int tmpsize=(*itmap).second.size(); for(int cnt=0; cnt!=tmpsize; ++cnt) { edm::RefToBase<TrajectorySeed> tmpSeedRef2 = trajC[(*itmap).second[cnt]]->seedRef(); edm::Ref<L2MuonTrajectorySeedCollection> tmpL2SeedRef2 = tmpSeedRef2.castTo<edm::Ref<L2MuonTrajectorySeedCollection> >(); seedToSeedsMap->insert(tmpL2SeedRef1, tmpL2SeedRef2); } } event.put(seedToSeedsMap, ""); } // end if(reportGhosts_) i = 0; for ( iter = trajC.begin(); iter != trajC.end(); iter++ ) { if ( mask[i] ){ result.push_back(*iter); LogTrace(metname) << "Keep trajectory with pT = " << (*iter)->lastMeasurement().updatedState().globalMomentum().perp() << " GeV"; } else delete *iter; i++; } trajC.clear(); trajC = result; }
void MuonTrajectoryCleaner::clean | ( | CandidateContainer & | muonTrajectories | ) |
Clean the candidates container, erasing the (worst) clone trajectory.
Definition at line 217 of file MuonTrajectoryCleaner.cc.
References alongMomentum, HLTFastRecoForTau_cff::deltaEta, SiPixelRawToDigiRegional_cfi::deltaPhi, alignCSCRings::e, PV3DBase< T, PVType, FrameType >::eta(), TrajectoryStateOnSurface::globalMomentum(), i, TrajectoryStateOnSurface::isValid(), j, LogTrace, mag(), match(), metname, oppositeToMomentum, PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::phi(), and query::result.
{ const std::string metname = "Muon|RecoMuon|MuonTrajectoryCleaner"; LogTrace(metname) << "Muon Trajectory Cleaner called" << endl; if ( candC.size() < 2 ) return; CandidateContainer::iterator iter, jter; Trajectory::DataContainer::const_iterator m1, m2; const float deltaEta = 0.01; const float deltaPhi = 0.01; const float deltaPt = 1.0; LogTrace(metname) << "Number of muon candidates in the container: " <<candC.size()<< endl; int i(0), j(0); int match(0); //unused bool directionMatch = false; // CAVEAT: vector<bool> is not a vector, its elements are not addressable! // This is fine as long as only operator [] is used as in this case. // cf. par 16.3.11 vector<bool> mask(candC.size(),true); CandidateContainer result; for ( iter = candC.begin(); iter != candC.end(); iter++ ) { if ( !mask[i] ) { i++; continue; } const Trajectory::DataContainer& meas1 = (*iter)->trajectory()->measurements(); j = i+1; bool skipnext=false; TrajectoryStateOnSurface innerTSOS; if ((*iter)->trajectory()->direction() == alongMomentum) { innerTSOS = (*iter)->trajectory()->firstMeasurement().updatedState(); } else if ((*iter)->trajectory()->direction() == oppositeToMomentum) { innerTSOS = (*iter)->trajectory()->lastMeasurement().updatedState(); } if ( !(innerTSOS.isValid()) ) continue; float pt1 = innerTSOS.globalMomentum().perp(); float eta1 = innerTSOS.globalMomentum().eta(); float phi1 = innerTSOS.globalMomentum().phi(); for ( jter = iter+1; jter != candC.end(); jter++ ) { if ( !mask[j] ) { j++; continue; } //UNUSED: directionMatch = false; const Trajectory::DataContainer& meas2 = (*jter)->trajectory()->measurements(); match = 0; for ( m1 = meas1.begin(); m1 != meas1.end(); m1++ ) { for ( m2 = meas2.begin(); m2 != meas2.end(); m2++ ) { if ( (*m1).recHit()->isValid() && (*m2).recHit()->isValid() ) if ( ( (*m1).recHit()->globalPosition() - (*m2).recHit()->globalPosition()).mag()< 10e-5 ) match++; } } LogTrace(metname) << " MuonTrajectoryCleaner: candC " << i << " chi2/nRH = " << (*iter)->trajectory()->chiSquared() << "/" << (*iter)->trajectory()->foundHits() << " vs trajC " << j << " chi2/nRH = " << (*jter)->trajectory()->chiSquared() << "/" << (*jter)->trajectory()->foundHits() << " Shared RecHits: " << match; TrajectoryStateOnSurface innerTSOS2; if ((*jter)->trajectory()->direction() == alongMomentum) { innerTSOS2 = (*jter)->trajectory()->firstMeasurement().updatedState(); } else if ((*jter)->trajectory()->direction() == oppositeToMomentum) { innerTSOS2 = (*jter)->trajectory()->lastMeasurement().updatedState(); } if ( !(innerTSOS2.isValid()) ) continue; float pt2 = innerTSOS2.globalMomentum().perp(); float eta2 = innerTSOS2.globalMomentum().eta(); float phi2 = innerTSOS2.globalMomentum().phi(); float deta(fabs(eta1-eta2)); float dphi(fabs(Geom::Phi<float>(phi1)-Geom::Phi<float>(phi2))); float dpt(fabs(pt1-pt2)); if ( dpt < deltaPt && deta < deltaEta && dphi < deltaPhi ) { //UNUSED: directionMatch = true; LogTrace(metname) << " MuonTrajectoryCleaner: candC " << i<<" and "<<j<< " direction matched: " <<innerTSOS.globalMomentum()<<" and " <<innerTSOS2.globalMomentum(); } // If there are matches, reject the worst track bool hitsMatch = ((match > 0) && ((match/((*iter)->trajectory()->foundHits()) > 0.25) || (match/((*jter)->trajectory()->foundHits()) > 0.25))) ? true : false; bool tracksMatch = ( ( (*iter)->trackerTrack() == (*jter)->trackerTrack() ) && ( deltaR<double>((*iter)->muonTrack()->eta(),(*iter)->muonTrack()->phi(), (*jter)->muonTrack()->eta(),(*jter)->muonTrack()->phi()) < 0.2) ); //if ( ( tracksMatch ) || (hitsMatch > 0) || directionMatch ) { if ( ( tracksMatch ) || (hitsMatch > 0) ) { if ( (*iter)->trajectory()->foundHits() == (*jter)->trajectory()->foundHits() ) { if ( (*iter)->trajectory()->chiSquared() > (*jter)->trajectory()->chiSquared() ) { mask[i] = false; skipnext=true; } else mask[j] = false; } else { // different number of hits if ( (*iter)->trajectory()->foundHits() < (*jter)->trajectory()->foundHits() ) { mask[i] = false; skipnext=true; } else mask[j] = false; } } if(skipnext) break; j++; } i++; if(skipnext) continue; } i = 0; for ( iter = candC.begin(); iter != candC.end(); iter++ ) { if ( mask[i] ) { result.push_back(*iter); } else { delete (*iter)->trajectory(); delete (*iter)->trackerTrajectory(); delete *iter; } i++; } candC.clear(); candC = result; }
bool MuonTrajectoryCleaner::reportGhosts_ [private] |
Definition at line 44 of file MuonTrajectoryCleaner.h.