#include <FinalTreeBuilder.h>
Public Member Functions | |
RefCountedKinematicTree | buildTree (const CachingVertex< 6 > &vtx, std::vector< RefCountedKinematicParticle > input) const |
FinalTreeBuilder () | |
~FinalTreeBuilder () | |
Private Types | |
typedef ReferenceCountingPointer < LinearizedTrackState< 6 > > | RefCountedLinearizedTrackState |
typedef ReferenceCountingPointer < RefittedTrackState< 6 > > | RefCountedRefittedTrackState |
typedef ReferenceCountingPointer < VertexTrack< 6 > > | RefCountedVertexTrack |
Private Member Functions | |
AlgebraicMatrix | momentumPart (const CachingVertex< 6 > &vtx, const AlgebraicVector7 &par) const |
Private Attributes | |
KinematicVertexFactory * | kvFactory |
VirtualKinematicParticleFactory * | pFactory |
Class building a resulting output tree out of the information provided by KinematicParticleVertexFitter.
Definition at line 16 of file FinalTreeBuilder.h.
typedef ReferenceCountingPointer<LinearizedTrackState<6> > FinalTreeBuilder::RefCountedLinearizedTrackState [private] |
Definition at line 29 of file FinalTreeBuilder.h.
typedef ReferenceCountingPointer<RefittedTrackState<6> > FinalTreeBuilder::RefCountedRefittedTrackState [private] |
Definition at line 30 of file FinalTreeBuilder.h.
typedef ReferenceCountingPointer<VertexTrack<6> > FinalTreeBuilder::RefCountedVertexTrack [private] |
Definition at line 28 of file FinalTreeBuilder.h.
FinalTreeBuilder::FinalTreeBuilder | ( | ) |
Definition at line 8 of file FinalTreeBuilder.cc.
References kvFactory, and pFactory.
{ kvFactory = new KinematicVertexFactory(); KinematicStatePropagator * ksp = 0; pFactory = new VirtualKinematicParticleFactory(ksp); }
FinalTreeBuilder::~FinalTreeBuilder | ( | ) |
RefCountedKinematicTree FinalTreeBuilder::buildTree | ( | const CachingVertex< 6 > & | vtx, |
std::vector< RefCountedKinematicParticle > | input | ||
) | const |
Definition at line 21 of file FinalTreeBuilder.cc.
References CachingVertex< N >::degreesOfFreedom(), i, j, KinematicRefittedTrackState::kinematicMomentumVector(), KinematicRefittedTrackState::kinematicParameters(), KinematicRefittedTrackState::kinematicParametersCovariance(), kvFactory, LogDebug, momentumPart(), KinematicTree::movePointerToTheTop(), VirtualKinematicParticleFactory::particle(), pFactory, CachingVertex< N >::position(), KinematicTree::replaceCurrentParticle(), mathSSE::sqrt(), CachingVertex< N >::totalChiSquared(), CachingVertex< N >::tracks(), diffTreeTool::tree, KinematicVertexFactory::vertex(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().
Referenced by KinematicParticleVertexFitter::fit().
{ //creating resulting kinematic particle AlgebraicVector7 par; AlgebraicMatrix cov(7,7,0); par(0) = vtx.position().x(); par(1) = vtx.position().y(); par(2) = vtx.position().z(); double en = 0.; int ch = 0; //new particle momentum calculation and refitted kinematic states std::vector<KinematicRefittedTrackState *> rStates; std::vector<RefCountedVertexTrack> refTracks = vtx.tracks(); for(std::vector<RefCountedVertexTrack>::const_iterator i = refTracks.begin();i !=refTracks.end();++i) { KinematicRefittedTrackState * rs = dynamic_cast<KinematicRefittedTrackState *>(&(*((*i)->refittedState()))); AlgebraicVector4 f_mom = rs->kinematicMomentumVector(); par(3) += f_mom(0); par(4) += f_mom(1); par(5) += f_mom(2); en += sqrt(f_mom(1)*f_mom(1)+f_mom(2)*f_mom(2)+f_mom(3)*f_mom(3) + f_mom(0)*f_mom(0)); ch += (*i)->linearizedTrack()->charge(); rStates.push_back(rs); } //math precision check (numerical stability) double differ = en*en - (par(3)*par(3)+par(4)*par(4)+par(5)*par(5)); if(differ>0.) { par(6) = sqrt(differ); }else{ LogDebug("FinalTreeBuilder") << "Fit failed: Current precision does not allow to calculate the mass\n"; return ReferenceCountingPointer<KinematicTree>(new KinematicTree()); } // covariance matrix calculation: momentum-momentum components part (4x4) // and position-momentum components part: AlgebraicMatrix m_all = momentumPart(vtx,par); //position-position components part (3x3) // AlgebraicMatrix x_X = vtx.error().matrix(); //making new matrix itself cov.sub(1,1,m_all); //covariance sym matrix AlgebraicSymMatrix77 sCov; for(int i = 1; i<8; i++) { for(int j = 1; j<8; j++) { if(i<=j) sCov(i-1,j-1) = cov(i,j); } } //valid decay vertex for our resulting particle RefCountedKinematicVertex dVrt = kvFactory->vertex(vtx); //invalid production vertex for our resulting particle RefCountedKinematicVertex pVrt = kvFactory->vertex(); //new born kinematic particle KinematicParameters kPar(par); KinematicParametersError kEr(sCov); const MagneticField* field=input.front()->magneticField(); KinematicState nState(kPar, kEr, ch, field); //invalid previous particle and empty constraint: KinematicParticle * zp = 0; RefCountedKinematicParticle pPart = ReferenceCountingPointer<KinematicParticle>(zp); float vChi = vtx.totalChiSquared(); float vNdf = vtx.degreesOfFreedom(); RefCountedKinematicParticle nPart = pFactory->particle(nState, vChi, vNdf, pPart); //adding top particle to the tree RefCountedKinematicTree resTree = ReferenceCountingPointer<KinematicTree>(new KinematicTree()); resTree->addParticle(pVrt,dVrt,nPart); //making refitted kinematic particles and putting them to the tree std::vector<RefCountedKinematicParticle> rrP; std::vector<RefCountedKinematicParticle>::const_iterator j; std::vector<RefCountedVertexTrack>::const_iterator i; for(j=input.begin(), i=refTracks.begin(); j !=input.end(), i !=refTracks.end();++j, ++i) { RefCountedLinearizedTrackState lT = (*i)->linearizedTrack(); KinematicRefittedTrackState * rS= dynamic_cast<KinematicRefittedTrackState *>(&(*((*i)->refittedState()))); // RefCountedRefittedTrackState rS = (*i)->refittedState(); AlgebraicVector7 lPar = rS->kinematicParameters(); KinematicParameters lkPar(lPar); AlgebraicSymMatrix77 lCov = rS->kinematicParametersCovariance(); KinematicParametersError lkCov(lCov); TrackCharge lch = lT->charge(); KinematicState nState(lkPar,lkCov,lch, field); RefCountedKinematicParticle nPart = (*j)->refittedParticle(nState,vChi,vNdf); rrP.push_back(nPart); if((*j)->correspondingTree() != 0) { //here are the particles having trees after them KinematicTree * tree = (*j)->correspondingTree(); tree->movePointerToTheTop(); tree->replaceCurrentParticle(nPart); RefCountedKinematicVertex cdVertex = resTree->currentDecayVertex(); resTree->addTree(cdVertex, tree); }else{ //here are just particles fitted to this tree RefCountedKinematicVertex nV = kvFactory->vertex(); resTree->addParticle(dVrt,nV,nPart); } } return resTree; }
AlgebraicMatrix FinalTreeBuilder::momentumPart | ( | const CachingVertex< 6 > & | vtx, |
const AlgebraicVector7 & | par | ||
) | const [private] |
Definition at line 143 of file FinalTreeBuilder.cc.
References a, funct::cos(), Exception, phi, CachingVertex< N >::position(), rho, funct::sin(), findQualityFiles::size, mathSSE::sqrt(), funct::tan(), theta(), CachingVertex< N >::tkToTkCovariance(), CachingVertex< N >::tracks(), and z.
Referenced by buildTree().
{ std::vector<RefCountedVertexTrack> refTracks = vtx.tracks(); int size = refTracks.size(); AlgebraicMatrix cov(7+4*(size-1),7+4*(size-1)); AlgebraicMatrix jac(7,7+4*(size-1)); jac(1,1) = 1.; jac(2,2) = 1.; jac(3,3) = 1.; double energy_total = sqrt(par(3)*par(3)+par(6)*par(6) + par(5)*par(5)+par(4)*par(4)); std::vector<KinematicRefittedTrackState *>::const_iterator rs; std::vector<RefCountedVertexTrack>::const_iterator rt_i; int i_int = 0; for(rt_i = refTracks.begin(); rt_i != refTracks.end(); rt_i++) { double a; AlgebraicVector6 param = (**rt_i).refittedState()->parameters(); // rho, theta, phi,tr_im, z_im, mass double rho = param[0]; double theta = param[1]; double phi = param[2]; double mass = param[5]; if ((**rt_i).linearizedTrack()->charge()!=0) { a = -(**rt_i).refittedState()->freeTrajectoryState().parameters().magneticFieldInInverseGeV(vtx.position()).z() * (**rt_i).refittedState()->freeTrajectoryState().parameters ().charge(); if (a==0.) throw cms::Exception("FinalTreeBuilder", "Field is 0"); } else { a = 1; } AlgebraicMatrix jc_el(4,4,0); jc_el(1,1) = -a*cos(phi)/(rho*rho); //dpx/d rho jc_el(2,1) = -a*sin(phi)/(rho*rho); //dpy/d rho jc_el(3,1) = -a/(rho*rho*tan(theta)); //dpz/d rho jc_el(3,2) = -a/(rho*sin(theta)*sin(theta)); //dpz/d theta jc_el(1,3) = -a*sin(phi)/rho; //dpx/d phi jc_el(2,3) = a*cos(phi)/rho; //dpy/d //non-trival elements: mass correlations: double energy_local = sqrt(a*a/(rho*rho)*(1+1/(tan(theta)*tan(theta))) + mass*mass); jc_el(4,4) = energy_total*mass/(par(6)*energy_local); // dm/dm jc_el(4,1) = (-(energy_total/energy_local*a*a/(rho*rho*rho*sin(theta)*sin(theta)) ) + par(3)*a/(rho*rho)*cos(phi) + par(4)*a/(rho*rho)*sin(phi) + par(5)*a/(rho*rho*tan(theta)) )/par(6); //dm / drho jc_el(4,2) = (-(energy_total/energy_local*a*a/(rho*rho*sin(theta)*sin(theta)*tan(theta)) ) + par(5)*a/(rho*sin(theta)*sin(theta)) )/par(6);//dm d theta jc_el(4,3) = ( par(3)*sin(phi) - par(4)*cos(phi) )*a/(rho*par(6)); //dm/dphi jac.sub(4,i_int*4+4,jc_el); //top left corner elements if(i_int == 0) { cov.sub(1,1,asHepMatrix<7>((**rt_i).fullCovariance())); } else { //4-momentum corellatons: diagonal elements of the matrix AlgebraicMatrix fullCovMatrix(asHepMatrix<7>((**rt_i).fullCovariance())); AlgebraicMatrix m_m_cov = fullCovMatrix.sub(4,7,4,7); AlgebraicMatrix x_p_cov = fullCovMatrix.sub(1,3,4,7); AlgebraicMatrix p_x_cov = fullCovMatrix.sub(4,7,1,3); // cout << "Full covariance: \n"<< (**rt_i).fullCovariance()<<endl; // cout << "Full m_m_cov: "<< m_m_cov<<endl; // cout<<"p_x_cov"<< p_x_cov<<endl; // cout<<"x_p_cov"<< x_p_cov<<endl; //putting everything to the joint covariance matrix: //diagonal momentum-momentum elements: cov.sub(i_int*4 + 4, i_int*4 + 4,m_m_cov); //position momentum elements: cov.sub(1,i_int*4 + 4,x_p_cov); cov.sub(i_int*4 + 4,1,p_x_cov); //off diagonal elements: corellations // track momentum - track momentum } int j_int = 0; for(std::vector<RefCountedVertexTrack>::const_iterator rt_j = refTracks.begin(); rt_j != refTracks.end(); rt_j++) { if(i_int < j_int) { AlgebraicMatrix i_k_cov_m = asHepMatrix<4,4>(vtx.tkToTkCovariance((*rt_i),(*rt_j))); // cout<<"i_k_cov_m"<<i_k_cov_m <<endl; cov.sub(i_int*4 + 4, j_int*4 + 4,i_k_cov_m); cov.sub(j_int*4 + 4, i_int*4 + 4,i_k_cov_m.T()); } j_int++; } i_int++; } // cout<<"jac"<<jac<<endl; // cout<<"cov"<<cov<<endl; // cout << "final result new"<<jac*cov*jac.T()<<endl; return jac*cov*jac.T(); }
Definition at line 36 of file FinalTreeBuilder.h.
Referenced by buildTree(), FinalTreeBuilder(), and ~FinalTreeBuilder().
Definition at line 37 of file FinalTreeBuilder.h.
Referenced by buildTree(), FinalTreeBuilder(), and ~FinalTreeBuilder().