#include <CollinearFitAtTM.h>

Public Types
enum	{ ParQpIn =0, ParQpOut, ParDxDz, ParDyDz, ParX, ParY }
	parameter indices in the result vector / covariance matrix More...

typedef ROOT::Math::SMatrix < double, 6, 6, ROOT::Math::MatRepSym < double, 6 > >	ResultMatrix

typedef ROOT::Math::SVector < double, 6 >	ResultVector

Public Member Functions
	CollinearFitAtTM ()

bool	fit (const TrajectoryMeasurement &tm, ResultVector &parameters, ResultMatrix &covariance, double &chi2)
	Fit for one TM. Return value "true" for success. More...

bool	fit (const AlgebraicVector5 &fwdParameters, const AlgebraicSymMatrix55 &fwdCovariance, const AlgebraicVector5 &bwdParameters, const AlgebraicSymMatrix55 &bwdCovariance, const LocalPoint &hitPosition, const LocalError &hitErrors, ResultVector &parameters, ResultMatrix &covariance, double &chi2)
	Fit with explicit input parameters. Return value "true" for success. More...

Private Attributes
ROOT::Math::SMatrix< double, 12, 6 >	jacobian_

ROOT::Math::SVector< double, 12 >	measurements_

ROOT::Math::SVector< double, 6 >	projectedMeasurements_

ROOT::Math::SMatrix< double, 12, 12, ROOT::Math::MatRepSym < double, 12 > >	weightMatrix_

Detailed Description

Constrained fit at a TrajectoryMeasurement assuming collinearity of incoming / outgoing momenta. The result of the fit is a vector of 6 variables: the first five correspond to local trajectory parameters for the incoming momentum, the 6th is the estimated remaining energy fraction (p_out / p_in). The NDF are 6 (4) for a valid (invalid) RecHit.

Definition at line 17 of file CollinearFitAtTM.h.

Member Typedef Documentation

typedef ROOT::Math::SMatrix<double,6,6,ROOT::Math::MatRepSym<double,6> > CollinearFitAtTM::ResultMatrix

Definition at line 25 of file CollinearFitAtTM.h.

typedef ROOT::Math::SVector<double,6> CollinearFitAtTM::ResultVector

Definition at line 24 of file CollinearFitAtTM.h.

Member Enumeration Documentation

anonymous enum

parameter indices in the result vector / covariance matrix

Enumerator
ParQpIn
ParQpOut
ParDxDz
ParDyDz
ParX
ParY

Definition at line 20 of file CollinearFitAtTM.h.

20 { ParQpIn=0, ParQpOut, ParDxDz, ParDyDz, ParX, ParY };

CollinearFitAtTM::ParY

Definition: CollinearFitAtTM.h:20

CollinearFitAtTM::ParDxDz

Definition: CollinearFitAtTM.h:20

CollinearFitAtTM::ParQpIn

Definition: CollinearFitAtTM.h:20

CollinearFitAtTM::ParDyDz

Definition: CollinearFitAtTM.h:20

CollinearFitAtTM::ParX

Definition: CollinearFitAtTM.h:20

CollinearFitAtTM::ParQpOut

Definition: CollinearFitAtTM.h:20

Constructor & Destructor Documentation

CollinearFitAtTM::CollinearFitAtTM ( )

Definition at line 4 of file CollinearFitAtTM.cc.

References i, j, jacobian_, ParQpIn, and ParQpOut.

 {
   //
   // Jacobian
   //
   for ( int i=0; i<12; ++i ) {
     for ( int j=0; j<6; ++j )  jacobian_(i,j) = 0;
   }
   for ( int i=1; i<5; ++i ) {
     jacobian_(i,ParQpOut+i) = jacobian_(i+5,ParQpOut+i) = 1;
   }
   jacobian_(0,ParQpIn) = 1.;
   jacobian_(5,ParQpOut) = 1.;
 }

Member Function Documentation

bool CollinearFitAtTM::fit	(	const TrajectoryMeasurement &	tm,
		ResultVector &	parameters,
		ResultMatrix &	covariance,
		double &	chi2
	)

Fit for one TM. Return value "true" for success.

Definition at line 20 of file CollinearFitAtTM.cc.

References TrajectoryMeasurement::backwardPredictedState(), TrajectoryMeasurement::forwardPredictedState(), TrajectoryStateOnSurface::isValid(), TrajectoryStateOnSurface::localError(), TrajectoryStateOnSurface::localParameters(), LocalTrajectoryError::matrix(), TrajectoryMeasurement::recHit(), TrajectoryMeasurement::updatedState(), and LocalTrajectoryParameters::vector().

Referenced by PFGsfHelper::PFGsfHelper().

 {
   //
   // check input
   //
   if ( !tm.forwardPredictedState().isValid() ||
        !tm.backwardPredictedState().isValid() ||
        !tm.updatedState().isValid() ) {
     edm::LogWarning("CollinearFitAtTM") << "Invalid state in TrajectoryMeasurement";
     return false;
   }
   //
   // prepare fit
   //
   AlgebraicVector5 fwdPar = tm.forwardPredictedState().localParameters().vector();
   AlgebraicSymMatrix55 fwdCov = tm.forwardPredictedState().localError().matrix();
   AlgebraicVector5 bwdPar = tm.backwardPredictedState().localParameters().vector();
   AlgebraicSymMatrix55 bwdCov = tm.backwardPredictedState().localError().matrix();
 
   LocalPoint hitPos(0.,0.,0.);
   LocalError hitErr(-1.,-1.,-1.);
   if ( tm.recHit()->isValid() ) {
     hitPos = tm.recHit()->localPosition();
     hitErr = tm.recHit()->localPositionError();
   }
 
   return fit(fwdPar,fwdCov,bwdPar,bwdCov,
          hitPos,hitErr,
          parameters,covariance,chi2);
 }

bool CollinearFitAtTM::fit	(	const AlgebraicVector5 &	fwdParameters,
		const AlgebraicSymMatrix55 &	fwdCovariance,
		const AlgebraicVector5 &	bwdParameters,
		const AlgebraicSymMatrix55 &	bwdCovariance,
		const LocalPoint &	hitPosition,
		const LocalError &	hitErrors,
		ResultVector &	parameters,
		ResultMatrix &	covariance,
		double &	chi2
	)

Fit with explicit input parameters. Return value "true" for success.

Definition at line 55 of file CollinearFitAtTM.cc.

References i, j, jacobian_, measurements_, ParX, ParY, projectedMeasurements_, weightMatrix_, PV3DBase< T, PVType, FrameType >::x(), LocalError::xx(), LocalError::xy(), PV3DBase< T, PVType, FrameType >::y(), and LocalError::yy().

 {
 
   if ( hitErr.xx()>0 )
     jacobian_(10,ParX) = jacobian_(11,ParY) = 1;
   else
     jacobian_(10,ParX) = jacobian_(11,ParY) = 0;
 
   for ( int i=0; i<12; ++i ) {
     for ( int j=0; j<12; ++j )  weightMatrix_(i,j) = 0;
   }
 
   for ( int i=0; i<5; ++i )  measurements_(i) = fwdParameters(i);
   weightMatrix_.Place_at(fwdCovariance,0,0);
   for ( int i=0; i<5; ++i )  measurements_(i+5) = bwdParameters(i);
   weightMatrix_.Place_at(bwdCovariance,5,5);
   if ( hitErr.xx()>0 ) {
     measurements_(10) = hitPos.x();
     measurements_(11) = hitPos.y();
     weightMatrix_(10,10) = hitErr.xx();
     weightMatrix_(10,11) = weightMatrix_(11,10) = hitErr.xy();
     weightMatrix_(11,11) = hitErr.yy();
   }
   else {
     measurements_(10) = measurements_(11) = 0.;
     weightMatrix_(10,10) = weightMatrix_(11,11) = 1.;
     weightMatrix_(10,11) = weightMatrix_(11,10) = 0.;
   }
   //
   // invert covariance matrix
   //
   if ( !weightMatrix_.Invert() ) {
     edm::LogWarning("CollinearFitAtTM") << "Inversion of input covariance matrix failed";
     return false;
   }
 
   //
   projectedMeasurements_ = ROOT::Math::Transpose(jacobian_)*(weightMatrix_*measurements_);
   //
   // Fitted parameters and covariance matrix
   // 
   covariance = ROOT::Math::SimilarityT(jacobian_,weightMatrix_);
   if ( !covariance.Invert() ) {
     edm::LogWarning("CollinearFitAtTM") << "Inversion of resulting weight matrix failed";
     return false;
   }
 
   parameters = covariance*projectedMeasurements_;
 
   //
   // chi2
   //
   chi2 = ROOT::Math::Similarity(measurements_,weightMatrix_) -
     ROOT::Math::Similarity(projectedMeasurements_,covariance);
 
   return true;
 }

Member Data Documentation

ROOT::Math::SMatrix<double,12,6> CollinearFitAtTM::jacobian_

private

Definition at line 41 of file CollinearFitAtTM.h.

Referenced by CollinearFitAtTM(), and fit().

ROOT::Math::SVector<double,12> CollinearFitAtTM::measurements_

private

Definition at line 42 of file CollinearFitAtTM.h.

Referenced by fit().

ROOT::Math::SVector<double,6> CollinearFitAtTM::projectedMeasurements_

private

Definition at line 44 of file CollinearFitAtTM.h.

Referenced by fit().

ROOT::Math::SMatrix<double,12,12,ROOT::Math::MatRepSym<double,12> > CollinearFitAtTM::weightMatrix_

private

Definition at line 43 of file CollinearFitAtTM.h.

Referenced by fit().

Public Types

Public Member Functions

Private Attributes

Detailed Description

Member Typedef Documentation

Member Enumeration Documentation

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation