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#include <TwoBodyDecayLinearizationPointFinder.h>
Public Types | |
| typedef PerigeeLinearizedTrackState::RefCountedLinearizedTrackState | RefCountedLinearizedTrackState |
Public Member Functions | |
| virtual TwoBodyDecayLinearizationPointFinder * | clone (void) const |
| virtual const TwoBodyDecayParameters | getLinearizationPoint (const std::vector< RefCountedLinearizedTrackState > &tracks, const double primaryMass, const double secondaryMass) const |
| TwoBodyDecayLinearizationPointFinder (const edm::ParameterSet &config) | |
| virtual | ~TwoBodyDecayLinearizationPointFinder (void) |
Class TwoBodyDecayLinearizationPointFinder computes a rough estimate of the parameters of a decay. This serves as linearization point for TwoBodyDecayEstimator.
/author Edmund Widl
Definition at line 16 of file TwoBodyDecayLinearizationPointFinder.h.
| typedef PerigeeLinearizedTrackState::RefCountedLinearizedTrackState TwoBodyDecayLinearizationPointFinder::RefCountedLinearizedTrackState |
Definition at line 21 of file TwoBodyDecayLinearizationPointFinder.h.
| TwoBodyDecayLinearizationPointFinder::TwoBodyDecayLinearizationPointFinder | ( | const edm::ParameterSet & | config | ) | [inline] |
| virtual TwoBodyDecayLinearizationPointFinder::~TwoBodyDecayLinearizationPointFinder | ( | void | ) | [inline, virtual] |
Definition at line 25 of file TwoBodyDecayLinearizationPointFinder.h.
{}
| virtual TwoBodyDecayLinearizationPointFinder* TwoBodyDecayLinearizationPointFinder::clone | ( | void | ) | const [inline, virtual] |
Definition at line 32 of file TwoBodyDecayLinearizationPointFinder.h.
References TwoBodyDecayLinearizationPointFinder().
{ return new TwoBodyDecayLinearizationPointFinder( *this ); }
| const TwoBodyDecayParameters TwoBodyDecayLinearizationPointFinder::getLinearizationPoint | ( | const std::vector< RefCountedLinearizedTrackState > & | tracks, |
| const double | primaryMass, | ||
| const double | secondaryMass | ||
| ) | const [virtual] |
Definition at line 7 of file TwoBodyDecayLinearizationPointFinder.cc.
References TwoBodyDecayParameters::dimension, TwoBodyDecayParameters::mass, TrajectoryStateClosestToPoint::momentum(), L1TEmulatorMonitor_cff::p, p1, p2, perp2(), phi, pi, PerigeeLinearizedTrackState::predictedState(), TwoBodyDecayParameters::px, TwoBodyDecayParameters::py, TwoBodyDecayParameters::pz, TwoBodyDecayModel::rotationMatrix(), mathSSE::sqrt(), theta(), ExpressReco_HICollisions_FallBack::x, PV3DBase< T, PVType, FrameType >::x(), ExpressReco_HICollisions_FallBack::y, PV3DBase< T, PVType, FrameType >::y(), PV3DBase< T, PVType, FrameType >::z(), and z.
{
GlobalPoint linPoint = tracks[0]->linearizationPoint();
PerigeeLinearizedTrackState* linTrack1 = dynamic_cast<PerigeeLinearizedTrackState*>( tracks[0].get() );
GlobalVector firstMomentum = linTrack1->predictedState().momentum();
PerigeeLinearizedTrackState* linTrack2 = dynamic_cast<PerigeeLinearizedTrackState*>( tracks[1].get() );
GlobalVector secondMomentum = linTrack2->predictedState().momentum();
AlgebraicVector secondaryMomentum1( 3 );
secondaryMomentum1[0] = firstMomentum.x();
secondaryMomentum1[1] = firstMomentum.y();
secondaryMomentum1[2] = firstMomentum.z();
AlgebraicVector secondaryMomentum2( 3 );
secondaryMomentum2[0] = secondMomentum.x();
secondaryMomentum2[1] = secondMomentum.y();
secondaryMomentum2[2] = secondMomentum.z();
AlgebraicVector primaryMomentum = secondaryMomentum1 + secondaryMomentum2;
TwoBodyDecayModel decayModel( primaryMass, secondaryMass );
AlgebraicMatrix rotMat = decayModel.rotationMatrix( primaryMomentum[0], primaryMomentum[1], primaryMomentum[2] );
AlgebraicMatrix invRotMat = rotMat.T();
double p = primaryMomentum.norm();
double pSquared = p*p;
double gamma = sqrt( pSquared + primaryMass*primaryMass )/primaryMass;
double betaGamma = p/primaryMass;
AlgebraicSymMatrix lorentzTransformation( 4, 1 );
lorentzTransformation[0][0] = gamma;
lorentzTransformation[3][3] = gamma;
lorentzTransformation[0][3] = -betaGamma;
double p1 = secondaryMomentum1.norm();
AlgebraicVector boostedLorentzMomentum1( 4 );
boostedLorentzMomentum1[0] = sqrt( p1*p1 + secondaryMass*secondaryMass );
boostedLorentzMomentum1.sub( 2, invRotMat*secondaryMomentum1 );
AlgebraicVector restFrameLorentzMomentum1 = lorentzTransformation*boostedLorentzMomentum1;
AlgebraicVector restFrameMomentum1 = restFrameLorentzMomentum1.sub( 2, 4 );
double perp1 = sqrt( restFrameMomentum1[0]*restFrameMomentum1[0] + restFrameMomentum1[1]*restFrameMomentum1[1] );
double theta1 = atan2( perp1, restFrameMomentum1[2] );
double phi1 = atan2( restFrameMomentum1[1], restFrameMomentum1[0] );
double p2 = secondaryMomentum2.norm();
AlgebraicVector boostedLorentzMomentum2( 4 );
boostedLorentzMomentum2[0] = sqrt( p2*p2 + secondaryMass*secondaryMass );
boostedLorentzMomentum2.sub( 2, invRotMat*secondaryMomentum2 );
AlgebraicVector restFrameLorentzMomentum2 = lorentzTransformation*boostedLorentzMomentum2;
AlgebraicVector restFrameMomentum2 = restFrameLorentzMomentum2.sub( 2, 4 );
double perp2 = sqrt( restFrameMomentum2[0]*restFrameMomentum2[0] + restFrameMomentum2[1]*restFrameMomentum2[1] );
double theta2 = atan2( perp2, restFrameMomentum2[2] );
double phi2 = atan2( restFrameMomentum2[1], restFrameMomentum2[0] );
double pi = 3.141592654;
double relSign = -1.;
if ( phi1 < 0 ) phi1 += 2*pi;
if ( phi2 < 0 ) phi2 += 2*pi;
if ( phi1 > phi2 ) relSign = 1.;
double momentumSquared1 = secondaryMomentum1.normsq();
double energy1 = sqrt( secondaryMass*secondaryMass + momentumSquared1 );
double momentumSquared2 = secondaryMomentum2.normsq();
double energy2 = sqrt( secondaryMass*secondaryMass + momentumSquared2 );
double sumMomentaSquared = ( secondaryMomentum1 + secondaryMomentum2 ).normsq();
double sumEnergiesSquared = ( energy1 + energy2 )*( energy1 + energy2 );
double estimatedPrimaryMass = sqrt( sumEnergiesSquared - sumMomentaSquared );
AlgebraicVector linParam( TwoBodyDecayParameters::dimension, 0 );
linParam[TwoBodyDecayParameters::x] = linPoint.x();
linParam[TwoBodyDecayParameters::y] = linPoint.y();
linParam[TwoBodyDecayParameters::z] = linPoint.z();
linParam[TwoBodyDecayParameters::px] = primaryMomentum[0];
linParam[TwoBodyDecayParameters::py] = primaryMomentum[1];
linParam[TwoBodyDecayParameters::pz] = primaryMomentum[2];
linParam[TwoBodyDecayParameters::theta] = 0.5*( theta1 - theta2 + pi ) ;
linParam[TwoBodyDecayParameters::phi] = 0.5*( phi1 + phi2 + relSign*pi );
linParam[TwoBodyDecayParameters::mass] = estimatedPrimaryMass;
return TwoBodyDecayParameters( linParam );
}
1.7.3