Based on a class from : V. Roberfroid, February 2008. More...
#include <PFCandConnector.h>
Public Member Functions | |
std::auto_ptr < reco::PFCandidateCollection > | connect (std::auto_ptr< reco::PFCandidateCollection > &pfCand) |
PFCandConnector () | |
void | setDebug (bool debug) |
void | setParameters (bool bCorrect, bool bCalibPrimary, double dptRel_PrimaryTrack, double dptRel_MergedTrack, double ptErrorSecondary, std::vector< double > nuclCalibFactors) |
void | setParameters (const edm::ParameterSet &iCfgCandConnector) |
Private Member Functions | |
void | analyseNuclearWPrim (std::auto_ptr< reco::PFCandidateCollection > &, unsigned int) |
Analyse nuclear interactions where a primary or merged track is present. | |
void | analyseNuclearWSec (std::auto_ptr< reco::PFCandidateCollection > &, unsigned int) |
Analyse nuclear interactions where a secondary track is present. | |
bool | isPrimaryNucl (const reco::PFCandidate &pf) const |
bool | isSecondaryNucl (const reco::PFCandidate &pf) const |
double | rescaleFactor (const double pt, const double cFrac) const |
Return a calibration factor for a reconstructed nuclear interaction. | |
Private Attributes | |
bool | bCalibPrimary_ |
Calibration parameters for the reconstructed nuclear interactions. | |
bool | bCorrect_ |
std::vector< bool > | bMask_ |
A mask to define the candidates which shall not be transmitted. | |
bool | debug_ |
Parameters. | |
double | dptRel_MergedTrack_ |
double | dptRel_PrimaryTrack_ |
std::vector< double > | fConst_ |
std::vector< double > | fExp_ |
std::vector< double > | fNorm_ |
std::auto_ptr < reco::PFCandidateCollection > | pfC_ |
Collection of primary PFCandidates to be transmitted to the Event. | |
double | ptErrorSecondary_ |
Static Private Attributes | |
static const reco::PFCandidate::Flags | fT_FROM_DISP_ = PFCandidate::T_FROM_DISP |
static const reco::PFCandidate::Flags | fT_TO_DISP_ = PFCandidate::T_TO_DISP |
static const double | pion_mass2 = 0.0194 |
Useful constants. |
Based on a class from : V. Roberfroid, February 2008.
Definition at line 16 of file PFCandConnector.h.
PFCandConnector::PFCandConnector | ( | ) | [inline] |
Definition at line 20 of file PFCandConnector.h.
References bCalibPrimary_, bCorrect_, debug_, dptRel_MergedTrack_, dptRel_PrimaryTrack_, fConst_, fExp_, fNorm_, pfC_, and ptErrorSecondary_.
{ pfC_ = std::auto_ptr<reco::PFCandidateCollection>(new reco::PFCandidateCollection); debug_ = false; bCorrect_ = false; bCalibPrimary_ = false; fConst_.push_back(1), fConst_.push_back(0); fNorm_.push_back(0), fNorm_.push_back(0); fExp_.push_back(0); dptRel_PrimaryTrack_ = 0.; dptRel_MergedTrack_ = 0.; ptErrorSecondary_ = 0.; }
void PFCandConnector::analyseNuclearWPrim | ( | std::auto_ptr< reco::PFCandidateCollection > & | , |
unsigned | int | ||
) | [private] |
Analyse nuclear interactions where a primary or merged track is present.
Definition at line 157 of file PFCandConnector.cc.
References gather_cfg::cout, reco::PFCandidate::displacedVertexRef(), alignCSCRings::e, reco::PFCandidate::ecalEnergy(), first, reco::PFCandidate::hcalEnergy(), edm::Ref< C, T, F >::isNonnull(), reco::LeafCandidate::p4(), p4, edm::second(), and mathSSE::sqrt().
{ PFDisplacedVertexRef ref1, ref2, ref1_bis; PFCandidate primaryCand = pfCand->at(ce1); // ------- look for the little friends -------- // math::XYZTLorentzVectorD momentumPrim = primaryCand.p4(); math::XYZTLorentzVectorD momentumSec; momentumSec = momentumPrim/momentumPrim.E()*(primaryCand.ecalEnergy() + primaryCand.hcalEnergy()); map<double, math::XYZTLorentzVectorD> candidatesWithTrackExcess; map<double, math::XYZTLorentzVectorD> candidatesWithoutCalo; ref1 = primaryCand.displacedVertexRef(fT_TO_DISP_); for( unsigned int ce2=0; ce2 < pfCand->size(); ++ce2) { if (ce2 != ce1 && isSecondaryNucl(pfCand->at(ce2))){ ref2 = (pfCand->at(ce2)).displacedVertexRef(fT_FROM_DISP_); if (ref1 == ref2) { if (debug_) cout << "\t here is a Secondary Candidate " << ce2 << " " << pfCand->at(ce2) << endl << "\t based on the Track " << pfCand->at(ce2).trackRef().key() << " w p = " << pfCand->at(ce2).trackRef()->p() << " w pT = " << pfCand->at(ce2).trackRef()->pt() << " #pm " << pfCand->at(ce2).trackRef()->ptError() << " %" << " ECAL = " << pfCand->at(ce2).ecalEnergy() << " HCAL = " << pfCand->at(ce2).hcalEnergy() << " dE(Trk-CALO) = " << pfCand->at(ce2).trackRef()->p()-pfCand->at(ce2).ecalEnergy()-pfCand->at(ce2).hcalEnergy() << " Nmissing hits = " << pfCand->at(ce2).trackRef()->trackerExpectedHitsOuter().numberOfHits() << endl; if(isPrimaryNucl(pfCand->at(ce2))){ if (debug_) cout << "\t\t but it is also a Primary Candidate " << ce2 << endl; ref1_bis = (pfCand->at(ce2)).displacedVertexRef(fT_TO_DISP_); if(ref1_bis.isNonnull()) analyseNuclearWPrim(pfCand, ce2); } // Take now the parameters of the secondary track that are relevant and use them to construct the NI candidate PFCandidate::ElementsInBlocks elementsInBlocks = pfCand->at(ce2).elementsInBlocks(); PFCandidate::ElementsInBlocks elementsAlreadyInBlocks = pfCand->at(ce1).elementsInBlocks(); for (unsigned blockElem = 0; blockElem < elementsInBlocks.size(); blockElem++){ bool isAlreadyHere = false; for (unsigned alreadyBlock = 0; alreadyBlock < elementsAlreadyInBlocks.size(); alreadyBlock++){ if (elementsAlreadyInBlocks[alreadyBlock].second == elementsInBlocks[blockElem].second) isAlreadyHere = true; } if (!isAlreadyHere) pfCand->at(ce1).addElementInBlock( elementsInBlocks[blockElem].first, elementsInBlocks[blockElem].second); } double caloEn = pfCand->at(ce2).ecalEnergy() + pfCand->at(ce2).hcalEnergy(); double deltaEn = pfCand->at(ce2).p4().E() - caloEn; int nMissOuterHits = pfCand->at(ce2).trackRef()->trackerExpectedHitsOuter().numberOfHits(); // Check if the difference Track Calo is not too large and if we can trust the track, ie it doesn't miss too much hits. if (deltaEn > 1 && nMissOuterHits > 1) { math::XYZTLorentzVectorD momentumToAdd = pfCand->at(ce2).p4()*caloEn/pfCand->at(ce2).p4().E(); momentumSec += momentumToAdd; if (debug_) cout << "The difference track-calo s really large and the track miss at least 2 hits. A secondary NI may have happened. Let's trust the calo energy" << endl << "add " << momentumToAdd << endl; } else { // Check if the difference Track Calo is not too large and if we can trust the track, ie it doesn't miss too much hits. if (caloEn > 0.01 && deltaEn > 1 && nMissOuterHits > 0) { math::XYZTLorentzVectorD momentumExcess = pfCand->at(ce2).p4()*deltaEn/pfCand->at(ce2).p4().E(); candidatesWithTrackExcess[pfCand->at(ce2).trackRef()->pt()/pfCand->at(ce2).trackRef()->ptError()] = momentumExcess; } else if(caloEn < 0.01) candidatesWithoutCalo[pfCand->at(ce2).trackRef()->pt()/pfCand->at(ce2).trackRef()->ptError()] = pfCand->at(ce2).p4(); momentumSec += (pfCand->at(ce2)).p4(); } bMask_[ce2] = true; } } } // We have more primary energy than secondary: reject all secondary tracks which have no calo energy attached. if (momentumPrim.E() < momentumSec.E()){ if(debug_) cout << "Size of 0 calo Energy secondary candidates" << candidatesWithoutCalo.size() << endl; for( map<double, math::XYZTLorentzVectorD>::iterator iter = candidatesWithoutCalo.begin(); iter != candidatesWithoutCalo.end() && momentumPrim.E() < momentumSec.E(); iter++) if (momentumSec.E() > iter->second.E()+0.1) { momentumSec -= iter->second; if(debug_) cout << "\t Remove a SecondaryCandidate with 0 calo energy " << iter->second << endl; if(debug_) cout << "momentumPrim.E() = " << momentumPrim.E() << " and momentumSec.E() = " << momentumSec.E() << endl; } } if (momentumPrim.E() < momentumSec.E()){ if(debug_) cout << "0 Calo Energy rejected but still not sufficient. Size of not enough calo Energy secondary candidates" << candidatesWithTrackExcess.size() << endl; for( map<double, math::XYZTLorentzVectorD>::iterator iter = candidatesWithTrackExcess.begin(); iter != candidatesWithTrackExcess.end() && momentumPrim.E() < momentumSec.E(); iter++) if (momentumSec.E() > iter->second.E()+0.1) momentumSec -= iter->second; } double dpt = pfCand->at(ce1).trackRef()->ptError()/pfCand->at(ce1).trackRef()->pt()*100; if (momentumSec.E() < 0.1) { bMask_[ce1] = true; return; } // Rescale the secondary candidates to account for the loss of energy, but only if we can trust the primary track: // if it has more energy than secondaries and is precise enough and secondary exist and was not eaten or rejected during the PFAlgo step. if( ( (ref1->isTherePrimaryTracks() && dpt<dptRel_PrimaryTrack_) || (ref1->isThereMergedTracks() && dpt<dptRel_MergedTrack_) ) && momentumPrim.E() > momentumSec.E() && momentumSec.E() > 0.1) { if (bCalibPrimary_){ double factor = rescaleFactor( momentumPrim.Pt(), momentumSec.E()/momentumPrim.E()); if (debug_) cout << "factor = " << factor << endl; if (factor*momentumPrim.Pt() < momentumSec.Pt()) momentumSec = momentumPrim; else momentumSec += (1-factor)*momentumPrim; } double px = momentumPrim.Px()*momentumSec.P()/momentumPrim.P(); double py = momentumPrim.Py()*momentumSec.P()/momentumPrim.P(); double pz = momentumPrim.Pz()*momentumSec.P()/momentumPrim.P(); double E = sqrt(px*px + py*py + pz*pz + pion_mass2); math::XYZTLorentzVectorD momentum(px, py, pz, E); pfCand->at(ce1).setP4(momentum); return; } else { math::XYZVector primDir = ref1->primaryDirection(); if (primDir.Mag2() < 0.1){ // It might be 0 but this situation should never happend. Throw a warning if it happens. edm::LogWarning("PFCandConnector") << "A Nuclear Interaction do not have primary direction" << std::endl; pfCand->at(ce1).setP4(momentumSec); return; } else { // rescale the primary direction to the optimal momentum. But take care of the factthat it shall not be completly 0 to avoid a warning if Jet Area. double momentumS = momentumSec.P(); if (momentumS < 1e-4) momentumS = 1e-4; double px = momentumS*primDir.x(); double py = momentumS*primDir.y(); double pz = momentumS*primDir.z(); double E = sqrt(px*px + py*py + pz*pz + pion_mass2); math::XYZTLorentzVectorD momentum(px, py, pz, E); pfCand->at(ce1).setP4(momentum); return; } } }
void PFCandConnector::analyseNuclearWSec | ( | std::auto_ptr< reco::PFCandidateCollection > & | , |
unsigned | int | ||
) | [private] |
Analyse nuclear interactions where a secondary track is present.
Definition at line 335 of file PFCandConnector.cc.
References asciidump::at, gather_cfg::cout, reco::PFCandidate::e, alignCSCRings::e, first, RPCpg::mu, reco::LeafCandidate::p4(), p4, edm::second(), and mathSSE::sqrt().
{ PFDisplacedVertexRef ref1, ref2; // Check if the track excess was not too large and track may miss some outer hits. This may point to a secondary NI. double caloEn = pfCand->at(ce1).ecalEnergy() + pfCand->at(ce1).hcalEnergy(); double deltaEn = pfCand->at(ce1).p4().E() - caloEn; int nMissOuterHits = pfCand->at(ce1).trackRef()->trackerExpectedHitsOuter().numberOfHits(); ref1 = pfCand->at(ce1).displacedVertexRef(fT_FROM_DISP_); // ------- check if an electron or a muon vas spotted as incoming track -------- // // ------- this mean probably that the NI was fake thus we do not correct it -------- / if (ref1->isTherePrimaryTracks() || ref1->isThereMergedTracks()){ std::vector<reco::Track> refittedTracks = ref1->refittedTracks(); for(unsigned it = 0; it < refittedTracks.size(); it++){ reco::TrackBaseRef primaryBaseRef = ref1->originalTrack(refittedTracks[it]); if (ref1->isIncomingTrack(primaryBaseRef)) if (debug_) cout << "There is a Primary track ref with pt = " << primaryBaseRef->pt()<< endl; for( unsigned int ce=0; ce < pfCand->size(); ++ce){ // cout << "PFCand Id = " << (pfCand->at(ce)).particleId() << endl; if ((pfCand->at(ce)).particleId() == reco::PFCandidate::e || (pfCand->at(ce)).particleId() == reco::PFCandidate::mu) { if (debug_) cout << " It is an electron and it has a ref to a track " << (pfCand->at(ce)).trackRef().isNonnull() << endl; if ( (pfCand->at(ce)).trackRef().isNonnull() ){ reco::TrackRef tRef = (pfCand->at(ce)).trackRef(); reco::TrackBaseRef bRef(tRef); if (debug_) cout << "With Track Ref pt = " << (pfCand->at(ce)).trackRef()->pt() << endl; if (bRef == primaryBaseRef) { if (debug_ && (pfCand->at(ce)).particleId() == reco::PFCandidate::e) cout << "It is a NI from electron. NI Discarded. Just release the candidate." << endl; if (debug_ && (pfCand->at(ce)).particleId() == reco::PFCandidate::mu) cout << "It is a NI from muon. NI Discarded. Just release the candidate" << endl; // release the track but take care of not overcounting bad tracks. In fact those tracks was protected against destruction in // PFAlgo. Now we treat them as if they was treated in PFAlgo if (caloEn < 0.1 && pfCand->at(ce1).trackRef()->ptError() > ptErrorSecondary_) { cout << "discarded track since no calo energy and ill measured" << endl; bMask_[ce1] = true; } if (caloEn > 0.1 && deltaEn >ptErrorSecondary_ && pfCand->at(ce1).trackRef()->ptError() > ptErrorSecondary_) { cout << "rescaled momentum of the track since no calo energy and ill measured" << endl; double factor = caloEn/pfCand->at(ce1).p4().E(); pfCand->at(ce1).rescaleMomentum(factor); } return; } } } } } } PFCandidate secondaryCand = pfCand->at(ce1); math::XYZTLorentzVectorD momentumSec = secondaryCand.p4(); if (deltaEn > ptErrorSecondary_ && nMissOuterHits > 1) { math::XYZTLorentzVectorD momentumToAdd = pfCand->at(ce1).p4()*caloEn/pfCand->at(ce1).p4().E(); momentumSec = momentumToAdd; if (debug_) cout << "The difference track-calo s really large and the track miss at least 2 hits. A secondary NI may have happened. Let's trust the calo energy" << endl << "add " << momentumToAdd << endl; } // ------- look for the little friends -------- // for( unsigned int ce2=ce1+1; ce2 < pfCand->size(); ++ce2) { if (isSecondaryNucl(pfCand->at(ce2))){ ref2 = (pfCand->at(ce2)).displacedVertexRef(fT_FROM_DISP_); if (ref1 == ref2) { if (debug_) cout << "\t here is a Secondary Candidate " << ce2 << " " << pfCand->at(ce2) << endl << "\t based on the Track " << pfCand->at(ce2).trackRef().key() << " w pT = " << pfCand->at(ce2).trackRef()->pt() << " #pm " << pfCand->at(ce2).trackRef()->ptError() << " %" << " ECAL = " << pfCand->at(ce2).ecalEnergy() << " HCAL = " << pfCand->at(ce2).hcalEnergy() << " dE(Trk-CALO) = " << pfCand->at(ce2).trackRef()->p()-pfCand->at(ce2).ecalEnergy()-pfCand->at(ce2).hcalEnergy() << " Nmissing hits = " << pfCand->at(ce2).trackRef()->trackerExpectedHitsOuter().numberOfHits() << endl; // Take now the parameters of the secondary track that are relevant and use them to construct the NI candidate PFCandidate::ElementsInBlocks elementsInBlocks = pfCand->at(ce2).elementsInBlocks(); PFCandidate::ElementsInBlocks elementsAlreadyInBlocks = pfCand->at(ce1).elementsInBlocks(); for (unsigned blockElem = 0; blockElem < elementsInBlocks.size(); blockElem++){ bool isAlreadyHere = false; for (unsigned alreadyBlock = 0; alreadyBlock < elementsAlreadyInBlocks.size(); alreadyBlock++){ if (elementsAlreadyInBlocks[alreadyBlock].second == elementsInBlocks[blockElem].second) isAlreadyHere = true; } if (!isAlreadyHere) pfCand->at(ce1).addElementInBlock( elementsInBlocks[blockElem].first, elementsInBlocks[blockElem].second); } double caloEn = pfCand->at(ce2).ecalEnergy() + pfCand->at(ce2).hcalEnergy(); double deltaEn = pfCand->at(ce2).p4().E() - caloEn; int nMissOuterHits = pfCand->at(ce2).trackRef()->trackerExpectedHitsOuter().numberOfHits(); if (deltaEn > ptErrorSecondary_ && nMissOuterHits > 1) { math::XYZTLorentzVectorD momentumToAdd = pfCand->at(ce2).p4()*caloEn/pfCand->at(ce2).p4().E(); momentumSec += momentumToAdd; if (debug_) cout << "The difference track-calo s really large and the track miss at least 2 hits. A secondary NI may have happened. Let's trust the calo energy" << endl << "add " << momentumToAdd << endl; } else { momentumSec += (pfCand->at(ce2)).p4(); } bMask_[ce2] = true; } } } math::XYZVector primDir = ref1->primaryDirection(); if (primDir.Mag2() < 0.1){ // It might be 0 but this situation should never happend. Throw a warning if it happens. pfCand->at(ce1).setP4(momentumSec); edm::LogWarning("PFCandConnector") << "A Nuclear Interaction do not have primary direction" << std::endl; return; } else { // rescale the primary direction to the optimal momentum. But take care of the factthat it shall not be completly 0 to avoid a warning if Jet Area. double momentumS = momentumSec.P(); if (momentumS < 1e-4) momentumS = 1e-4; double px = momentumS*primDir.x(); double py = momentumS*primDir.y(); double pz = momentumS*primDir.z(); double E = sqrt(px*px + py*py + pz*pz + pion_mass2); math::XYZTLorentzVectorD momentum(px, py, pz, E); pfCand->at(ce1).setP4(momentum); return; } }
std::auto_ptr<reco::PFCandidateCollection> PFCandConnector::connect | ( | std::auto_ptr< reco::PFCandidateCollection > & | pfCand | ) |
Referenced by PFAlgo::transferCandidates().
bool PFCandConnector::isPrimaryNucl | ( | const reco::PFCandidate & | pf | ) | const [private] |
Definition at line 498 of file PFCandConnector.cc.
References reco::PFCandidate::displacedVertexRef(), reco::PFCandidate::flag(), and edm::Ref< C, T, F >::isNonnull().
{ PFDisplacedVertexRef ref1; // nuclear if( pf.flag( fT_TO_DISP_ ) ) { ref1 = pf.displacedVertexRef(fT_TO_DISP_); //ref1->Dump(); if (!ref1.isNonnull()) return false; else if (ref1->isNucl()|| ref1->isNucl_Loose() || ref1->isNucl_Kink()) return true; } return false; }
bool PFCandConnector::isSecondaryNucl | ( | const reco::PFCandidate & | pf | ) | const [private] |
Definition at line 482 of file PFCandConnector.cc.
References reco::PFCandidate::displacedVertexRef(), reco::PFCandidate::flag(), and edm::Ref< C, T, F >::isNonnull().
{ PFDisplacedVertexRef ref1; // nuclear if( pf.flag( fT_FROM_DISP_ ) ) { ref1 = pf.displacedVertexRef(fT_FROM_DISP_); // ref1->Dump(); if (!ref1.isNonnull()) return false; else if (ref1->isNucl() || ref1->isNucl_Loose() || ref1->isNucl_Kink()) return true; } return false; }
double PFCandConnector::rescaleFactor | ( | const double | pt, |
const double | cFrac | ||
) | const [private] |
Return a calibration factor for a reconstructed nuclear interaction.
Definition at line 517 of file PFCandConnector.cc.
References funct::exp().
{ /* LOG NORMAL FIT FCN=35.8181 FROM MIGRAD STATUS=CONVERGED 257 CALLS 258 TOTAL EDM=8.85763e-09 STRATEGY= 1 ERROR MATRIX ACCURATE EXT PARAMETER STEP FIRST NO. NAME VALUE ERROR SIZE DERIVATIVE 1 p0 7.99434e-01 2.77264e-02 6.59108e-06 9.80247e-03 2 p1 1.51303e-01 2.89981e-02 1.16775e-05 6.99035e-03 3 p2 -5.03829e-01 2.87929e-02 1.90070e-05 1.37015e-03 4 p3 4.54043e-01 5.00908e-02 3.17625e-05 3.86622e-03 5 p4 -4.61736e-02 8.07940e-03 3.25775e-06 -1.37247e-02 */ /* FCN=34.4051 FROM MIGRAD STATUS=CONVERGED 221 CALLS 222 TOTAL EDM=1.02201e-09 STRATEGY= 1 ERROR MATRIX UNCERTAINTY 2.3 per cent fConst 1 p0 7.99518e-01 2.23519e-02 1.41523e-06 4.05975e-04 2 p1 1.44619e-01 2.39398e-02 -7.68117e-07 -2.55775e-03 fNorm 3 p2 -5.16571e-01 3.12362e-02 5.74932e-07 3.42292e-03 4 p3 4.69055e-01 5.09665e-02 1.94353e-07 1.69031e-03 fExp 5 p4 -5.18044e-02 8.13458e-03 4.29815e-07 -1.07624e-02 */ double fConst, fNorm, fExp; fConst = fConst_[0] + fConst_[1]*cFrac; fNorm = fNorm_[0] - fNorm_[1]*cFrac; fExp = fExp_[0]; double factor = fConst - fNorm*exp( -fExp*pt ); return factor; }
void PFCandConnector::setDebug | ( | bool | debug | ) | [inline] |
Definition at line 64 of file PFCandConnector.h.
Referenced by PFAlgo::setDebug().
void PFCandConnector::setParameters | ( | const edm::ParameterSet & | iCfgCandConnector | ) | [inline] |
Flag to apply the correction procedure for nuclear interactions
Flag to calibrate the reconstructed nuclear interactions with primary or merged tracks
Definition at line 35 of file PFCandConnector.h.
References edm::ParameterSet::exists(), and edm::ParameterSet::getParameter().
Referenced by PFAlgo::setCandConnectorParameters().
{ bool bCorrect, bCalibPrimary; double dptRel_PrimaryTrack, dptRel_MergedTrack, ptErrorSecondary; std::vector<double> nuclCalibFactors; bCorrect = iCfgCandConnector.getParameter<bool>("bCorrect"); bCalibPrimary = iCfgCandConnector.getParameter<bool>("bCalibPrimary"); if(iCfgCandConnector.exists("dptRel_PrimaryTrack")) dptRel_PrimaryTrack = iCfgCandConnector.getParameter<double>("dptRel_PrimaryTrack"); else { edm::LogWarning("PFCandConnector") << "dptRel_PrimaryTrack doesn't exist. Setting a default safe value 0" << std::endl; dptRel_PrimaryTrack = 0;} if(iCfgCandConnector.exists("dptRel_MergedTrack")) dptRel_MergedTrack = iCfgCandConnector.getParameter<double>("dptRel_MergedTrack"); else { edm::LogWarning("PFCandConnector") << "dptRel_MergedTrack doesn't exist. Setting a default safe value 0" << std::endl; dptRel_MergedTrack = 0;} if(iCfgCandConnector.exists("ptErrorSecondary")) ptErrorSecondary = iCfgCandConnector.getParameter<double>("ptErrorSecondary"); else { edm::LogWarning("PFCandConnector") << "ptErrorSecondary doesn't exist. Setting a default safe value 0" << std::endl; ptErrorSecondary = 0;} if(iCfgCandConnector.exists("nuclCalibFactors")) nuclCalibFactors = iCfgCandConnector.getParameter<std::vector<double> >("nuclCalibFactors"); else { edm::LogWarning("PFCandConnector") << "nuclear calib factors doesn't exist the factor would not be applyed" << std::endl; } setParameters(bCorrect, bCalibPrimary, dptRel_PrimaryTrack, dptRel_MergedTrack, ptErrorSecondary, nuclCalibFactors); }
void PFCandConnector::setParameters | ( | bool | bCorrect, |
bool | bCalibPrimary, | ||
double | dptRel_PrimaryTrack, | ||
double | dptRel_MergedTrack, | ||
double | ptErrorSecondary, | ||
std::vector< double > | nuclCalibFactors | ||
) |
Definition at line 16 of file PFCandConnector.cc.
References AlCaHLTBitMon_QueryRunRegistry::string.
{ bCorrect_ = bCorrect; bCalibPrimary_ = bCalibPrimary; dptRel_PrimaryTrack_ = dptRel_PrimaryTrack; dptRel_MergedTrack_ = dptRel_MergedTrack; ptErrorSecondary_ = ptErrorSecondary; if (nuclCalibFactors.size() == 5) { fConst_[0] = nuclCalibFactors[0]; fConst_[1] = nuclCalibFactors[1]; fNorm_[0] = nuclCalibFactors[2]; fNorm_[1] = nuclCalibFactors[3]; fExp_[0] = nuclCalibFactors[4]; } else { edm::LogWarning("PFCandConnector") << "Wrong calibration factors for nuclear interactions. The calibration procedure would not be applyed." << std::endl; bCalibPrimary_ = false; } std::string sCorrect = bCorrect_ ? "On" : "Off"; edm::LogInfo("PFCandConnector") << " ====================== The PFCandConnector is switched " << sCorrect.c_str() << " ==================== " << std::endl; std::string sCalibPrimary = bCalibPrimary_ ? "used for calibration" : "not used for calibration"; if (bCorrect_) edm::LogInfo("PFCandConnector") << "Primary Tracks are " << sCalibPrimary.c_str() << std::endl; if (bCorrect_ && bCalibPrimary_) edm::LogInfo("PFCandConnector") << "Under the condition that the precision on the Primary track is better than " << dptRel_PrimaryTrack_ << " % "<< std::endl; if (bCorrect_ && bCalibPrimary_) edm::LogInfo("PFCandConnector") << " and on merged tracks better than " << dptRel_MergedTrack_ << " % "<< std::endl; if (bCorrect_ && bCalibPrimary_) edm::LogInfo("PFCandConnector") << " and secondary tracks in some cases more precise than " << ptErrorSecondary_ << " GeV"<< std::endl; if (bCorrect_ && bCalibPrimary_) edm::LogInfo("PFCandConnector") << "factor = (" << fConst_[0] << " + " << fConst_[1] << "*cFrac) - (" << fNorm_[0] << " - " << fNorm_[1] << "cFrac)*exp( " << -1*fExp_[0] << "*pT )"<< std::endl; edm::LogInfo("PFCandConnector") << " =========================================================== " << std::endl; }
bool PFCandConnector::bCalibPrimary_ [private] |
Calibration parameters for the reconstructed nuclear interactions.
Definition at line 97 of file PFCandConnector.h.
Referenced by PFCandConnector().
bool PFCandConnector::bCorrect_ [private] |
Definition at line 94 of file PFCandConnector.h.
Referenced by PFCandConnector().
std::vector<bool> PFCandConnector::bMask_ [private] |
A mask to define the candidates which shall not be transmitted.
Definition at line 90 of file PFCandConnector.h.
bool PFCandConnector::debug_ [private] |
Definition at line 93 of file PFCandConnector.h.
Referenced by PFCandConnector(), and setDebug().
double PFCandConnector::dptRel_MergedTrack_ [private] |
Definition at line 104 of file PFCandConnector.h.
Referenced by PFCandConnector().
double PFCandConnector::dptRel_PrimaryTrack_ [private] |
Definition at line 103 of file PFCandConnector.h.
Referenced by PFCandConnector().
std::vector< double > PFCandConnector::fConst_ [private] |
Definition at line 98 of file PFCandConnector.h.
Referenced by PFCandConnector().
std::vector< double > PFCandConnector::fExp_ [private] |
Definition at line 100 of file PFCandConnector.h.
Referenced by PFCandConnector().
std::vector< double > PFCandConnector::fNorm_ [private] |
Definition at line 99 of file PFCandConnector.h.
Referenced by PFCandConnector().
const reco::PFCandidate::Flags PFCandConnector::fT_FROM_DISP_ = PFCandidate::T_FROM_DISP [static, private] |
Definition at line 110 of file PFCandConnector.h.
const reco::PFCandidate::Flags PFCandConnector::fT_TO_DISP_ = PFCandidate::T_TO_DISP [static, private] |
Definition at line 109 of file PFCandConnector.h.
std::auto_ptr<reco::PFCandidateCollection> PFCandConnector::pfC_ [private] |
Collection of primary PFCandidates to be transmitted to the Event.
Definition at line 88 of file PFCandConnector.h.
Referenced by PFCandConnector().
const double PFCandConnector::pion_mass2 = 0.0194 [static, private] |
Useful constants.
Definition at line 108 of file PFCandConnector.h.
double PFCandConnector::ptErrorSecondary_ [private] |
Definition at line 105 of file PFCandConnector.h.
Referenced by PFCandConnector().