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Public Member Functions | Private Types | Private Member Functions | Private Attributes

FinalTreeBuilder Class Reference

#include <FinalTreeBuilder.h>

List of all members.

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

KinematicVertexFactorykvFactory
VirtualKinematicParticleFactorypFactory

Detailed Description

Class building a resulting output tree out of the information provided by KinematicParticleVertexFitter.

Definition at line 16 of file FinalTreeBuilder.h.


Member Typedef Documentation

Definition at line 29 of file FinalTreeBuilder.h.

Definition at line 30 of file FinalTreeBuilder.h.

Definition at line 28 of file FinalTreeBuilder.h.


Constructor & Destructor Documentation

FinalTreeBuilder::FinalTreeBuilder ( )

Definition at line 8 of file FinalTreeBuilder.cc.

References kvFactory, and pFactory.

FinalTreeBuilder::~FinalTreeBuilder ( )

Definition at line 15 of file FinalTreeBuilder.cc.

References kvFactory, and pFactory.

{
 delete kvFactory;
 delete pFactory;
}

Member Function Documentation

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();
}

Member Data Documentation

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().