#include <RecoVertex/KineExample/src/KineExample.cc>
Public Member Functions | |
virtual void | analyze (const edm::Event &, const edm::EventSetup &) |
virtual void | beginJob () |
virtual void | endJob () |
KineExample (const edm::ParameterSet &) | |
~KineExample () | |
Private Member Functions | |
TrackingVertex | getSimVertex (const edm::Event &iEvent) const |
void | printout (const RefCountedKinematicParticle &myParticle) const |
void | printout (const RefCountedKinematicTree &myTree) const |
void | printout (const RefCountedKinematicVertex &myVertex) const |
Private Attributes | |
TrackAssociatorByChi2 * | associatorForParamAtPca |
edm::ParameterSet | kvfPSet |
std::string | outputFile_ |
edm::ParameterSet | theConfig |
std::string | trackLabel_ |
This is a very simple test analyzer mean to test the KalmanVertexFitter
Description: steers tracker primary vertex reconstruction and storage
Implementation: <Notes on="" implementation>="">
Definition at line 46 of file KineExample.h.
KineExample::KineExample | ( | const edm::ParameterSet & | iConfig | ) | [explicit] |
Definition at line 36 of file KineExample.cc.
References edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), kvfPSet, outputFile_, and trackLabel_.
: theConfig(iConfig) { trackLabel_ = iConfig.getParameter<std::string>("TrackLabel"); outputFile_ = iConfig.getUntrackedParameter<std::string>("outputFile"); kvfPSet = iConfig.getParameter<edm::ParameterSet>("KVFParameters"); // rootFile_ = TFile::Open(outputFile_.c_str(),"RECREATE"); edm::LogInfo("RecoVertex/KineExample") << "Initializing KVF TEST analyser - Output file: " << outputFile_ <<"\n"; }
KineExample::~KineExample | ( | ) |
Definition at line 48 of file KineExample.cc.
{
// delete rootFile_;
}
void KineExample::analyze | ( | const edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [virtual] |
Implements edm::EDAnalyzer.
Definition at line 70 of file KineExample.cc.
References gather_cfg::cout, exception, KinematicConstrainedVertexFitter::fit(), KinematicParticleVertexFitter::fit(), KinematicParticleFitter::fit(), edm::EventSetup::get(), edm::Event::getByLabel(), edm::EventBase::id(), edm::HandleBase::isValid(), TransientVertex::isValid(), KinematicParticleFactoryFromTransientTrack::particle(), TransientVertex::position(), printout(), trackLabel_, and KalmanVertexFitter::vertex().
{ try { cout << "Reconstructing event number: " << iEvent.id() << "\n"; // get RECO tracks from the event // `tks` can be used as a ptr to a reco::TrackCollection edm::Handle<reco::TrackCollection> tks; iEvent.getByLabel(trackLabel_, tks); if (!tks.isValid()) { cout << "Couln't find track collection: " << iEvent.id() << "\n"; } else { edm::LogInfo("RecoVertex/KineExample") << "Found: " << (*tks).size() << " reconstructed tracks" << "\n"; cout << "got " << (*tks).size() << " tracks " << endl; // Transform Track to TransientTrack //get the builder: edm::ESHandle<TransientTrackBuilder> theB; iSetup.get<TransientTrackRecord>().get("TransientTrackBuilder",theB); //do the conversion: vector<TransientTrack> t_tks = (*theB).build(tks); cout << "Found: " << t_tks.size() << " reconstructed tracks" << "\n"; // Do a KindFit, if >= 4 tracks. if (t_tks.size() > 3) { // For a first test, suppose that the first four tracks are the 2 muons, // then the 2 kaons. Since this will not be true, the result of the fit // will not be meaningfull, but at least you will get the idea of how to // do such a fit. //First, to get started, a simple vertex fit: vector<TransientTrack> ttv; ttv.push_back(t_tks[0]); ttv.push_back(t_tks[1]); ttv.push_back(t_tks[2]);ttv.push_back(t_tks[3]); KalmanVertexFitter kvf(false); TransientVertex tv = kvf.vertex(ttv); if (!tv.isValid()) cout << "KVF failed\n"; else std::cout << "KVF fit Position: " << Vertex::Point(tv.position()) << "\n"; TransientTrack ttMuPlus = t_tks[0]; TransientTrack ttMuMinus = t_tks[1]; TransientTrack ttKPlus = t_tks[2]; TransientTrack ttKMinus = t_tks[3]; //the final state muons and kaons from the Bs->J/PsiPhi->mumuKK decay //Creating a KinematicParticleFactory KinematicParticleFactoryFromTransientTrack pFactory; //The mass of a muon and the insignificant mass sigma to avoid singularities in the covariance matrix. ParticleMass muon_mass = 0.1056583; ParticleMass kaon_mass = 0.493677; float muon_sigma = 0.0000001; float kaon_sigma = 0.000016; //initial chi2 and ndf before kinematic fits. The chi2 of the reconstruction is not considered float chi = 0.; float ndf = 0.; //making particles vector<RefCountedKinematicParticle> muonParticles; vector<RefCountedKinematicParticle> phiParticles; vector<RefCountedKinematicParticle> allParticles; muonParticles.push_back(pFactory.particle (ttMuPlus,muon_mass,chi,ndf,muon_sigma)); muonParticles.push_back(pFactory.particle (ttMuMinus,muon_mass,chi,ndf,muon_sigma)); allParticles.push_back(pFactory.particle (ttMuPlus,muon_mass,chi,ndf,muon_sigma)); allParticles.push_back(pFactory.particle (ttMuMinus,muon_mass,chi,ndf,muon_sigma)); phiParticles.push_back(pFactory.particle (ttKPlus,kaon_mass,chi,ndf,kaon_sigma)); phiParticles.push_back(pFactory.particle (ttKMinus,kaon_mass,chi,ndf,kaon_sigma)); allParticles.push_back(pFactory.particle (ttKPlus,kaon_mass,chi,ndf,kaon_sigma)); allParticles.push_back(pFactory.particle (ttKMinus,kaon_mass,chi,ndf,kaon_sigma)); /* Example of a simple vertex fit, without other constraints * The reconstructed decay tree is a result of the kinematic fit * The KinematicParticleVertexFitter fits the final state particles to their vertex and * reconstructs the decayed state */ KinematicParticleVertexFitter fitter; cout <<"Simple vertex fit with KinematicParticleVertexFitter:\n"; RefCountedKinematicTree vertexFitTree = fitter.fit(allParticles); printout(vertexFitTree); //creating the constraint for the J/Psi mass ParticleMass jpsi = 3.09687; //creating the two track mass constraint MultiTrackKinematicConstraint * j_psi_c = new TwoTrackMassKinematicConstraint(jpsi); //creating the fitter KinematicConstrainedVertexFitter kcvFitter; //obtaining the resulting tree RefCountedKinematicTree myTree = kcvFitter.fit(allParticles, j_psi_c); cout << "\nGlobal fit done:\n"; printout(myTree); //creating the vertex fitter KinematicParticleVertexFitter kpvFitter; //reconstructing a J/Psi decay RefCountedKinematicTree jpTree = kpvFitter.fit(muonParticles); //creating the particle fitter KinematicParticleFitter csFitter; // creating the constraint float jp_m_sigma = 0.00004; KinematicConstraint * jpsi_c2 = new MassKinematicConstraint(jpsi,jp_m_sigma); //the constrained fit: jpTree = csFitter.fit(jpsi_c2,jpTree); //getting the J/Psi KinematicParticle and putting it together with the kaons. //The J/Psi KinematicParticle has a pointer to the tree it belongs to jpTree->movePointerToTheTop(); RefCountedKinematicParticle jpsi_part = jpTree->currentParticle(); phiParticles.push_back(jpsi_part); //making a vertex fit and thus reconstructing the Bs parameters // the resulting tree includes all the final state tracks, the J/Psi meson, // its decay vertex, the Bs meson and its decay vertex. RefCountedKinematicTree bsTree = kpvFitter.fit(phiParticles); cout << "Sequential fit done:\n"; printout(bsTree); // // For the analysis: compare to your SimVertex // TrackingVertex sv = getSimVertex(iEvent); // edm::Handle<TrackingParticleCollection> TPCollectionH ; // iEvent.getByLabel("trackingtruth","TrackTruth",TPCollectionH); // const TrackingParticleCollection tPC = *(TPCollectionH.product()); // reco::RecoToSimCollection recSimColl=associatorForParamAtPca->associateRecoToSim(tks, // TPCollectionH, // &iEvent); // // tree->fill(tv, &sv, &recSimColl); // } } } } catch (std::exception & err) { cout << "Exception during event number: " << iEvent.id() << "\n" << err.what() << "\n"; } }
void KineExample::beginJob | ( | void | ) | [virtual] |
Reimplemented from edm::EDAnalyzer.
Definition at line 52 of file KineExample.cc.
References associatorForParamAtPca, edm::ESHandle< T >::product(), and HcalObjRepresent::setup().
{ edm::ESHandle<TrackAssociatorBase> theAssociatorForParamAtPca; setup.get<TrackAssociatorRecord>().get("TrackAssociatorByChi2",theAssociatorForParamAtPca); associatorForParamAtPca = (TrackAssociatorByChi2 *) theAssociatorForParamAtPca.product(); // tree = new SimpleVertexTree("VertexFitter", associatorForParamAtPca); }
void KineExample::endJob | ( | void | ) | [virtual] |
Reimplemented from edm::EDAnalyzer.
Definition at line 61 of file KineExample.cc.
{
// delete tree;
}
TrackingVertex KineExample::getSimVertex | ( | const edm::Event & | iEvent | ) | const [private] |
Definition at line 288 of file KineExample.cc.
References edm::Event::getByLabel(), and edm::Handle< T >::product().
{ // get the simulated vertices edm::Handle<TrackingVertexCollection> TVCollectionH ; iEvent.getByLabel("trackingtruth","VertexTruth",TVCollectionH); const TrackingVertexCollection tPC = *(TVCollectionH.product()); // Handle<edm::SimVertexContainer> simVtcs; // iEvent.getByLabel("g4SimHits", simVtcs); // std::cout << "SimVertex " << simVtcs->size() << std::endl; // for(edm::SimVertexContainer::const_iterator v=simVtcs->begin(); // v!=simVtcs->end(); ++v){ // std::cout << "simvtx " // << v->position().x() << " " // << v->position().y() << " " // << v->position().z() << " " // << v->parentIndex() << " " // << v->noParent() << " " // << std::endl; // } return *(tPC.begin()); }
void KineExample::printout | ( | const RefCountedKinematicVertex & | myVertex | ) | const [private] |
Definition at line 232 of file KineExample.cc.
References gather_cfg::cout.
Referenced by analyze(), and printout().
void KineExample::printout | ( | const RefCountedKinematicTree & | myTree | ) | const [private] |
Definition at line 251 of file KineExample.cc.
References gather_cfg::cout, i, and printout().
{ if (!myTree->isValid()) { cout <<"Tree is invalid. Fit failed.\n"; return; } //accessing the tree components, move pointer to top myTree->movePointerToTheTop(); //We are now at the top of the decay tree getting the B_s reconstructed KinematicPartlcle RefCountedKinematicParticle b_s = myTree->currentParticle(); printout(b_s); // The B_s decay vertex RefCountedKinematicVertex b_dec_vertex = myTree->currentDecayVertex(); printout(b_dec_vertex); // Get all the children of Bs: //In this way, the pointer is not moved vector< RefCountedKinematicParticle > bs_children = myTree->finalStateParticles(); for (unsigned int i=0;i< bs_children.size();++i) { printout(bs_children[i]); } //Now navigating down the tree , pointer is moved: bool child = myTree->movePointerToTheFirstChild(); if(child) while (myTree->movePointerToTheNextChild()) { RefCountedKinematicParticle aChild = myTree->currentParticle(); printout(aChild); } }
void KineExample::printout | ( | const RefCountedKinematicParticle & | myParticle | ) | const [private] |
Definition at line 239 of file KineExample.cc.
References gather_cfg::cout.
{ cout << "Particle: \n"; //accessing the reconstructed Bs meson parameters: AlgebraicVector7 bs_par = myParticle->currentState().kinematicParameters().vector(); //and their joint covariance matrix: AlgebraicSymMatrix77 bs_er = myParticle->currentState().kinematicParametersError().matrix(); cout << "Momentum at vertex: " << myParticle->currentState().globalMomentum ()<<endl; cout << "Parameters at vertex: " << myParticle->currentState().kinematicParameters().vector()<<endl; }
Definition at line 66 of file KineExample.h.
Referenced by beginJob().
edm::ParameterSet KineExample::kvfPSet [private] |
Definition at line 65 of file KineExample.h.
Referenced by KineExample().
std::string KineExample::outputFile_ [private] |
Definition at line 70 of file KineExample.h.
Referenced by KineExample().
edm::ParameterSet KineExample::theConfig [private] |
Definition at line 64 of file KineExample.h.
std::string KineExample::trackLabel_ [private] |
Definition at line 71 of file KineExample.h.
Referenced by analyze(), and KineExample().