d2/d48/TKinFitter_8cc_source.html

 // Classname: TKinFitter

 // Author: Jan E. Sundermann, Verena Klose (TU Dresden)


 //________________________________________________________________

 //

 // TKinFitter::

 // --------------------

 //

 // Class to perform kinematic fit with non-linear constraints

 //


 #include <iostream>

 #include <iomanip>

 #include "FWCore/MessageLogger/interface/MessageLogger.h"

 #include "PhysicsTools/KinFitter/interface/TKinFitter.h"

 #include "PhysicsTools/KinFitter/interface/TAbsFitParticle.h"

 #include "PhysicsTools/KinFitter/interface/TAbsFitConstraint.h"


 TKinFitter::TKinFitter():

   TNamed("UnNamed", "UnTitled"),

   _A(1, 1),

   _AT(1, 1),

   _B(1, 1),

   _BT(1, 1),

   _V(1, 1),

   _Vinv(1, 1),

   _VB(1, 1),

   _VBinv(1, 1),

   _VA(1, 1),

   _VAinv(1, 1),

   _c(1, 1),

   _C11(1, 1),

   _C11T(1, 1),

   _C21(1, 1),

   _C21T(1, 1),

   _C22(1, 1),

   _C22T(1, 1),

   _C31(1, 1),

   _C31T(1, 1),

   _C32(1, 1),

   _C32T(1, 1),

   _C33(1, 1),

   _C33T(1, 1),

   _deltaA(1, 1),

   _deltaY(1, 1),

   _deltaAstar(1, 1),

   _deltaYstar(1, 1),

   _lambda(1, 1),

   _lambdaT(1, 1),

   _lambdaVFit(1, 1),

   _yaVFit(1, 1),

   _constraints(0),

   _measParticles(0),

   _unmeasParticles(0)

 {


   reset();


 }


 TKinFitter::TKinFitter(const TString &name, const TString &title):

   TNamed(name, title),

   _A(1, 1),

   _AT(1, 1),

   _B(1, 1),

   _BT(1, 1),

   _V(1, 1),

   _Vinv(1, 1),

   _VB(1, 1),

   _VBinv(1, 1),

   _VA(1, 1),

   _VAinv(1, 1),

   _c(1, 1),

   _C11(1, 1),

   _C11T(1, 1),

   _C21(1, 1),

   _C21T(1, 1),

   _C22(1, 1),

   _C22T(1, 1),

   _C31(1, 1),

   _C31T(1, 1),

   _C32(1, 1),

   _C32T(1, 1),

   _C33(1, 1),

   _C33T(1, 1),

   _deltaA(1, 1),

   _deltaY(1, 1),

   _deltaAstar(1, 1),

   _deltaYstar(1, 1),

   _lambda(1, 1),

   _lambdaT(1, 1),

   _lambdaVFit(1, 1),

   _yaVFit(1, 1),

   _constraints(0),

   _measParticles(0),

   _unmeasParticles(0)

 {


   reset();


 }


 void TKinFitter::reset() {

   // reset all internal parameters of the fitter


   _status = -1;

   _nbIter = 0;

   _nParA = 0;

   _nParB = 0;

   _verbosity = 1;

   _A.ResizeTo(1, 1);

   _AT.ResizeTo(1, 1);

   _B.ResizeTo(1, 1);

   _BT.ResizeTo(1, 1);

   _V.ResizeTo(1, 1);

   _Vinv.ResizeTo(1, 1);

   _VB.ResizeTo(1, 1);

   _VBinv.ResizeTo(1, 1);

   _VA.ResizeTo(1, 1);

   _VAinv.ResizeTo(1, 1);

   _c.ResizeTo(1, 1);

   _C11.ResizeTo(1, 1);

   _C11T.ResizeTo(1, 1);

   _C21.ResizeTo(1, 1);

   _C21T.ResizeTo(1, 1);

   _C22.ResizeTo(1, 1);

   _C22T.ResizeTo(1, 1);

   _C31.ResizeTo(1, 1);

   _C31T.ResizeTo(1, 1);

   _C32.ResizeTo(1, 1);

   _C32T.ResizeTo(1, 1);

   _C33.ResizeTo(1, 1);

   _C33T.ResizeTo(1, 1);

   _deltaA.ResizeTo(1, 1);

   _deltaY.ResizeTo(1, 1);

   _deltaAstar.ResizeTo(1, 1);

   _deltaYstar.ResizeTo(1, 1);

   _lambda.ResizeTo(1, 1);

   _lambdaT.ResizeTo(1, 1);

   _lambdaVFit.ResizeTo(1, 1);

   _yaVFit.ResizeTo(1, 1);


   _constraints.clear();

   _measParticles.clear();

   _unmeasParticles.clear();


   // Set to default values

   _maxNbIter = 50;

   _maxDeltaS = 5e-3;

   _maxF =  1e-4;


 }


 void TKinFitter::resetStatus() {

   // reset status of the fit


   _status = -1;

   _nbIter = 0;


 }


 void TKinFitter::resetParams() {

   // reset all particles to their initial parameters


   for (unsigned int iP = 0; iP < _measParticles.size(); iP++) {

     TAbsFitParticle* particle = _measParticles[iP];

     particle->reset();

   }

   for (unsigned int iP = 0; iP < _unmeasParticles.size(); iP++) {

     TAbsFitParticle* particle = _unmeasParticles[iP];

     particle->reset();

   }

   for (unsigned int iC = 0; iC < _constraints.size(); iC++) {

     TAbsFitConstraint* constraint = _constraints[iC];

     constraint->reset();

   }


 }


 TKinFitter::~TKinFitter() {


 }


 void TKinFitter::countMeasParams() {

   // count number of measured parameters


   _nParB = 0;

   for (unsigned int indexParticle = 0; indexParticle < _measParticles.size(); indexParticle++) {

     _nParB += _measParticles[indexParticle]->getNPar();

   }

   for (unsigned int indexConstraint = 0; indexConstraint < _constraints.size(); indexConstraint++) {

     _nParB += _constraints[indexConstraint]->getNPar();

   }


 }


 void TKinFitter::countUnmeasParams() {

   // count number of unmeasured parameters


   _nParA = 0;

   for (unsigned int indexParticle = 0; indexParticle < _unmeasParticles.size(); indexParticle++) {

     _nParA += _unmeasParticles[indexParticle]->getNPar();

   }


 }


 void TKinFitter::addMeasParticle( TAbsFitParticle* particle ) {

   // add one measured particle


   resetStatus();


   if ( particle != 0 ) {

     _measParticles.push_back( particle );

   } else {

     edm::LogError ("NullPointer") << "Measured particle points to NULL. It will not be added to the KinFitter.";

   }


   countMeasParams();


 }


 void TKinFitter::addMeasParticles( TAbsFitParticle* p1, TAbsFitParticle* p2, TAbsFitParticle* p3,

                   TAbsFitParticle* p4, TAbsFitParticle* p5, TAbsFitParticle* p6,

                   TAbsFitParticle* p7, TAbsFitParticle* p8, TAbsFitParticle* p9) {

   // add many measured particles


   resetStatus();


   if ( p1 != 0 ) _measParticles.push_back( p1 );

   if ( p2 != 0 ) _measParticles.push_back( p2 );

   if ( p3 != 0 ) _measParticles.push_back( p3 );

   if ( p4 != 0 ) _measParticles.push_back( p4 );

   if ( p5 != 0 ) _measParticles.push_back( p5 );

   if ( p6 != 0 ) _measParticles.push_back( p6 );

   if ( p7 != 0 ) _measParticles.push_back( p7 );

   if ( p8 != 0 ) _measParticles.push_back( p8 );

   if ( p9 != 0 ) _measParticles.push_back( p9 );


   countMeasParams();


 }


 void TKinFitter::addUnmeasParticle( TAbsFitParticle* particle ) {

   // add one unmeasured particle


   resetStatus();


   if ( particle != 0 ) {

     _unmeasParticles.push_back( particle );

   } else {

     edm::LogError ("NullPointer") << "Unmeasured particle points to NULL. It will not be added to the KinFitter.";

   }


   countUnmeasParams();


 }


 void TKinFitter::addUnmeasParticles( TAbsFitParticle* p1, TAbsFitParticle* p2, TAbsFitParticle* p3,

                      TAbsFitParticle* p4, TAbsFitParticle* p5, TAbsFitParticle* p6,

                      TAbsFitParticle* p7, TAbsFitParticle* p8, TAbsFitParticle* p9) {

   // add many unmeasured particles


   resetStatus();


   if ( p1 != 0 ) _unmeasParticles.push_back( p1 );

   if ( p2 != 0 ) _unmeasParticles.push_back( p2 );

   if ( p3 != 0 ) _unmeasParticles.push_back( p3 );

   if ( p4 != 0 ) _unmeasParticles.push_back( p4 );

   if ( p5 != 0 ) _unmeasParticles.push_back( p5 );

   if ( p6 != 0 ) _unmeasParticles.push_back( p6 );

   if ( p7 != 0 ) _unmeasParticles.push_back( p7 );

   if ( p8 != 0 ) _unmeasParticles.push_back( p8 );

   if ( p9 != 0 ) _unmeasParticles.push_back( p9 );


   countUnmeasParams();


 }


 void TKinFitter::addConstraint( TAbsFitConstraint* constraint ) {

   // add a constraint


   resetStatus();


   if ( constraint != 0 ) {

     _constraints.push_back( constraint );

   }


   countMeasParams();


 }


 void TKinFitter::setVerbosity( Int_t verbosity ) {

   // Set verbosity of the fitter:

   // 0: quiet

   // 1: print information before and after the fit

   // 2: print output for every iteration of the fit

   // 3: print debug information


   if ( verbosity < 0 ) verbosity = 0;

   if ( verbosity > 3 ) verbosity = 3;

   _verbosity = verbosity;


 }


 Int_t TKinFitter::fit() {

   // Perform the fit

   // Returns:

   // 0: converged

   // 1: not converged


   resetParams();

   resetStatus();


   _nbIter = 0;

   Bool_t isConverged = false;

   Double_t prevF;

   Double_t currF = getF();

   Double_t prevS;

   Double_t currS = 0.;


   // Calculate covariance matrix V

   calcV();


   // print status

   if ( _verbosity >= 1 ) {

     print();

   }


   do {


     // Reset status to "RUNNING"

     // (if it was not aborted already due to singular covariance matrix)

     if ( _status != -10 ) {

       _status = 10;

     }


     // Calculate matrices

     calcB();

     calcVB();

     if ( _nParA > 0 ) {

       calcA();

       calcVA();

       calcC32();

     }

     calcC31();

     calcC33();

     calcC();


     // Calculate corretion for a, y, and lambda

     if ( _nParA > 0 ){

       calcDeltaA();

     }

     calcDeltaY();

     calcLambda();


     if( _verbosity >= 3 ) {

       printMatrix( _A      , "A"      );

       printMatrix( _B      , "B"      );

       printMatrix( _VBinv  , "VBinv"  );

       printMatrix( _VB     , "VB"     );

       printMatrix( _V      , "V"      );

       printMatrix( _deltaY , "deltaY" );

       printMatrix( _deltaA , "deltaA" );

       printMatrix( _C32T   , "C32T"   );

       printMatrix( _c      , "C"      );

     }


     if( _verbosity >= 2 ) {

       print();

     }


     // Apply calculated corrections to measured and unmeasured particles

     if ( _nParA > 0 ) {

       applyDeltaA();

     }

     applyDeltaY();


     _nbIter++;


     //calculate F and S

     prevF = currF;

     currF = getF();

     prevS = currS;

     currS = getS();


     if( TMath::IsNaN(currF) ) {

       edm::LogInfo ("KinFitter") << "The current value of F is NaN. Fit will be aborted.";

       _status = -10;

     }

     if( TMath::IsNaN(currS) ) {

       edm::LogInfo ("KinFitter") << "The current value of S is NaN. Fit will be aborted.";

       _status = -10;

     }


     // Reduce step width if F is not getting smaller

     Int_t nstep = 0;

     while (currF >= prevF) {

       nstep++;

       if (nstep == 10) break;

       if (_nParA > 0) _deltaA -= (0.5) * (_deltaA - _deltaAstar);

       _deltaY -= (0.5) * (_deltaY - _deltaYstar);

       _lambda *= 0.5;

       _lambdaT *= 0.5;

       if (_nParA > 0) applyDeltaA();

       applyDeltaY();

       currF = getF();

       currS = getS();

     }


     // Test convergence

     isConverged = converged(currF, prevS, currS);


   } while ( (! isConverged) && (_nbIter < _maxNbIter) && (_status != -10) );


   // Calculate covariance matrices

   calcB();

   calcVB();


   if ( _nParA > 0 ) {

     calcA();

     calcVA();

     calcC21();

     calcC22();

     calcC32();

   }

   calcC11();

   calcC31();

   calcC33();

   calcVFit();

   applyVFit();


   // Set status information

   if (isConverged) {

     _status = 0;

   }

   else if (_status != -10) {

     _status = 1;

   }


   // print status

   if ( _verbosity >= 1 ) {

     print();

   }


   return _status;


 }


 void TKinFitter::setCovMatrix( TMatrixD &V ) {

   // Set the covariance matrix of the measured particles


   if ( (V.GetNrows() != _nParB) || (V.GetNcols() != _nParB) ) {

     edm::LogError ("WrongMatrixSize")

       << "Covariance matrix of measured particles needs to be a " << _nParB << "x" << _nParB << " matrix.";

   } else {

     _V.ResizeTo( V );

     _V = V;

   }


 }


 Bool_t TKinFitter::calcV() {

   // Combines the covariance matrices of all measured particles


   _V.ResizeTo( _nParB, _nParB );

   _V.Zero();


   Int_t offsetP = 0;

   for (unsigned int iP = 0; iP < _measParticles.size(); iP++) {

     TAbsFitParticle* particle = _measParticles[iP];

     Int_t nParP = particle->getNPar();

     const TMatrixD* covMatrix =  particle->getCovMatrix();


     for (int iX = offsetP; iX < offsetP + nParP; iX++) {

       for (int iY = offsetP; iY < offsetP + nParP; iY++) {


     _V(iX, iY) = (*covMatrix)(iX-offsetP, iY-offsetP);


       }

     }


     offsetP += nParP;

   }


   for (unsigned int iC = 0; iC < _constraints.size(); iC++) {

     TAbsFitConstraint* constraint = _constraints[iC];

     Int_t nParP = constraint->getNPar();

     const TMatrixD* covMatrix =  constraint->getCovMatrix();


     for (int iX = offsetP; iX < offsetP + nParP; iX++) {

       for (int iY = offsetP; iY < offsetP + nParP; iY++) {


     _V(iX, iY) = (*covMatrix)(iX-offsetP, iY-offsetP);


       }

     }


     offsetP += nParP;

   }


   _Vinv.ResizeTo( _V );

   _Vinv = _V;

   try {

     _Vinv.Invert();

   } catch (cms::Exception& e) {

     edm::LogInfo ("KinFitter") << "Failed to invert covariance matrix V. Fit will be aborted.";

     _status = -10;

   }


   return true;


 }


 Bool_t TKinFitter::calcA() {

   // Calculate the Jacobi matrix of unmeasured parameters df_i/da_i

   // Row i contains the derivatives of constraint f_i. Column q contains

   // the derivative wrt. a_q.


   _A.ResizeTo( _constraints.size(), _nParA );


   for (unsigned int indexConstr = 0; indexConstr < _constraints.size(); indexConstr++) {


     int offsetParam = 0;

     for (unsigned int indexParticle = 0; indexParticle < _unmeasParticles.size(); indexParticle++) {


       // Calculate matrix product  df/dP * dP/dy = (df/dr, df/dtheta, df/dphi, ...)


       TAbsFitParticle* particle = _unmeasParticles[indexParticle];

       TMatrixD* derivParticle = particle->getDerivative();

       TMatrixD* derivConstr = _constraints[indexConstr]->getDerivative( particle );

       TMatrixD deriv( *derivConstr, TMatrixD::kMult, *derivParticle );


       for (int indexParam = 0; indexParam < deriv.GetNcols(); indexParam++) {

     _A(indexConstr,indexParam+offsetParam) = deriv(0, indexParam);

       }

       offsetParam += deriv.GetNcols();


       delete derivParticle;

       delete derivConstr;


     }

   }


   // Calculate transposed matrix

   TMatrixD AT(TMatrixD::kTransposed, _A);

   _AT.ResizeTo( AT );

   _AT = AT;


   return true;


 }


 Bool_t TKinFitter::calcB() {

   // Calculate the Jacobi matrix of measured parameters df_i/da_i

   // Row i contains the derivatives of constraint f_i. Column q contains

   // the derivative wrt. a_q.


   _B.ResizeTo( _constraints.size(), _nParB );


   int offsetParam = 0;

   for (unsigned int indexConstr = 0; indexConstr < _constraints.size(); indexConstr++) {


     offsetParam = 0;

     for (unsigned int indexParticle = 0; indexParticle < _measParticles.size(); indexParticle++) {


       // Calculate matrix product  df/dP * dP/dy = (df/dr, df/dtheta, df/dphi, ...)

       TAbsFitParticle* particle = _measParticles[indexParticle];

       TMatrixD* derivParticle = particle->getDerivative();

       TMatrixD* derivConstr = _constraints[indexConstr]->getDerivative( particle );

       TMatrixD deriv( *derivConstr,  TMatrixD::kMult, *derivParticle );

       if (_verbosity >= 3) {

     TString matrixName = "B deriv: Particle -> ";

     matrixName += particle->GetName();

     printMatrix( *derivParticle, matrixName );

     matrixName = "B deriv: Constraint -> ";

     matrixName += _constraints[indexConstr]->GetName();

     matrixName += " , Particle -> ";

     matrixName += particle->GetName();

     printMatrix( *derivConstr, matrixName );

       }

       for (int indexParam = 0; indexParam < deriv.GetNcols(); indexParam++) {

     _B(indexConstr,indexParam+offsetParam) = deriv(0, indexParam);

       }

       offsetParam += deriv.GetNcols();


       delete derivParticle;

       delete derivConstr;


     }

   }


   for (unsigned int iC = 0; iC < _constraints.size(); iC++) {


     TAbsFitConstraint* constraint = _constraints[iC];

     TMatrixD* deriv = constraint->getDerivativeAlpha();


     if (deriv != 0) {


       if (_verbosity >= 3) {

     TString matrixName = "B deriv alpha: Constraint -> ";

     matrixName += constraint->GetName();

     printMatrix( *deriv, matrixName );

       }

       for (int indexParam = 0; indexParam < deriv->GetNcols(); indexParam++) {

     _B( iC, indexParam+offsetParam ) = (*deriv)(0, indexParam);

       }

       offsetParam += deriv->GetNcols();


       delete deriv;

     }

   }


   TMatrixD BT( TMatrixD::kTransposed,  _B );

   _BT.ResizeTo( BT );

   _BT = BT;


   return true;


 }


 Bool_t TKinFitter::calcVB() {

   // Calculate the matrix V_B = (B*V*B^T)^-1


   TMatrixD BV( _B, TMatrixD::kMult, _V );

   TMatrixD VBinv( BV, TMatrixD::kMult, _BT );

   _VBinv.ResizeTo( VBinv );

   _VBinv = VBinv;


   _VB.ResizeTo( _VBinv );

   _VB = _VBinv;

   try {

     _VB.Invert();

   } catch (cms::Exception& e) {

     edm::LogInfo ("KinFitter") << "Failed to invert matrix VB. Fit will be aborted.";

     _status = -10;

   }


   return true;


 }


 Bool_t TKinFitter::calcVA() {

   // Calculate the matrix VA = (A^T*VB*A)


   TMatrixD ATVB( _AT, TMatrixD::kMult, _VB );

   TMatrixD VA(ATVB, TMatrixD::kMult, _A);

   _VA.ResizeTo( VA );

   _VA = VA;


   _VAinv.ResizeTo( _VA );

   _VAinv = _VA;

   try {

     _VAinv.Invert();

   } catch (cms::Exception& e) {

     edm::LogInfo ("KinFitter") << "Failed to invert matrix VA. Fit will be aborted.";

     _status = -10;

   }


   return true;


 }


 Bool_t TKinFitter::calcC11() {

   // Calculate the matrix C11 = V^(-1) - V^(-1)*BT*VB*B*V^(-1) + V^(-1)*BT*VB*A*VA^(-1)*AT*VB*B*V^(-1)


   TMatrixD VBT( _V, TMatrixD::kMult, _BT );

   TMatrixD VBB( _VB, TMatrixD::kMult, _B );

   TMatrixD VBTVBB( VBT, TMatrixD::kMult, VBB );

   TMatrixD m2( VBTVBB,  TMatrixD::kMult, _V );


   _C11.ResizeTo( _V );

   _C11 = _V;

   _C11 -= m2;


   if ( _nParA > 0 ) {

     TMatrixD VBA( _VB, TMatrixD::kMult, _A );

     TMatrixD VBTVBA( VBT, TMatrixD::kMult, VBA );

     TMatrixD VAinvAT( _VAinv, TMatrixD::kMult, _AT );

     TMatrixD VBTVBAVAinvAT( VBTVBA, TMatrixD::kMult, VAinvAT );

     TMatrixD VBTVBAVAinvATVBB( VBTVBAVAinvAT, TMatrixD::kMult, VBB );

     TMatrixD m3( VBTVBAVAinvATVBB, TMatrixD::kMult, _V );

     _C11 += m3;

   }


   TMatrixD C11T( TMatrixD::kTransposed,  _C11 );

   _C11T.ResizeTo( C11T );

   _C11T = C11T;


   return true;


 }


 Bool_t TKinFitter::calcC21() {

   // Calculate the matrix  C21 = -VA^(-1)*AT*VB*B*V^(-1)


   TMatrixD VAinvAT( _VAinv, TMatrixD::kMult, _AT );

   TMatrixD VBB( _VB, TMatrixD::kMult, _B );

   TMatrixD VAinvATVBB( VAinvAT, TMatrixD::kMult, VBB );

   TMatrixD C21( VAinvATVBB, TMatrixD::kMult, _V );

   C21 *= -1.;

   _C21.ResizeTo( C21 );

   _C21 = C21;


   TMatrixD C21T( TMatrixD::kTransposed,  _C21 );

   _C21T.ResizeTo( C21T );

   _C21T = C21T;


   return true;


 }


 Bool_t TKinFitter::calcC22() {

   //  Calculate the matrix C22 = VA^(-1)


   _C22.ResizeTo( _VAinv );

   _C22 = _VAinv;


   TMatrixD C22T( TMatrixD::kTransposed,  _C22 );

   _C22T.ResizeTo( C22T );

   _C22T = C22T;


   return true;


 }


 Bool_t TKinFitter::calcC31() {

   // Calculate the matrix  C31 = VB*B*V^(-1) - VB*A*VA^(-1)*AT*VB*B*V^(-1)


   TMatrixD VbB(_VB, TMatrixD::kMult, _B);

   TMatrixD m1( VbB, TMatrixD::kMult, _V );


   _C31.ResizeTo( m1 );

   _C31 = m1;


   if ( _nParA > 0 ) {

     TMatrixD VbA(_VB, TMatrixD::kMult, _A);

     TMatrixD VAinvAT( _VAinv, TMatrixD::kMult, _AT );

     TMatrixD VbBV( VbB,  TMatrixD::kMult, _V );

     TMatrixD VbAVAinvAT(VbA, TMatrixD::kMult, VAinvAT);

     TMatrixD m2(VbAVAinvAT, TMatrixD::kMult, VbBV);


     _C31 -= m2;

   }


   TMatrixD C31T( TMatrixD::kTransposed,  _C31 );

   _C31T.ResizeTo( C31T );

   _C31T = C31T;


   return true;


 }


 Bool_t TKinFitter::calcC32() {

   // Calculate the matrix  C32 = VB*A*VA^(-1)


   TMatrixD VbA( _VB, TMatrixD::kMult, _A );

   TMatrixD C32( VbA, TMatrixD::kMult, _VAinv );

   _C32.ResizeTo( C32 );

   _C32 = C32;


   TMatrixD C32T( TMatrixD::kTransposed,  _C32 );

   _C32T.ResizeTo( C32T );

   _C32T = C32T;


   return true;


 }


 Bool_t TKinFitter::calcC33() {

   // Calculate the matrix C33 = -VB + VB*A*VA^(-1)*AT*VB


   _C33.ResizeTo( _VB );

   _C33 = _VB;

   _C33 *= -1.;


   if ( _nParA > 0 ) {

     TMatrixD VbA(_VB, TMatrixD::kMult, _A );

     TMatrixD VAinvAT( _VAinv, TMatrixD::kMult, _AT );

     TMatrixD VbAVAinvAT( VbA, TMatrixD::kMult, VAinvAT );

     TMatrixD C33( VbAVAinvAT,  TMatrixD::kMult, _VB );

     _C33 += C33;

   }


   TMatrixD C33T( TMatrixD::kTransposed,  _C33 );

   _C33T.ResizeTo( C33T );

   _C33T = C33T;


   return true;

 }


 Bool_t TKinFitter::calcC() {

   // Calculate the matrix c = A*deltaAStar + B*deltaYStar - fStar


   int offsetParam = 0;


   // calculate delta(a*), = 0 in the first iteration

   TMatrixD deltaastar( 1, 1 );

   if ( _nParA > 0 ) {


     deltaastar.ResizeTo( _nParA, 1 );

     for (unsigned int indexParticle = 0; indexParticle < _unmeasParticles.size(); indexParticle++) {


       TAbsFitParticle* particle = _unmeasParticles[indexParticle];

       const TMatrixD* astar = particle->getParCurr();

       const TMatrixD* a = particle->getParIni();

       TMatrixD deltaastarpart(*astar);

       deltaastarpart -= *a;


       for (int indexParam = 0; indexParam < deltaastarpart.GetNrows(); indexParam++) {

     deltaastar(indexParam+offsetParam, 0) = deltaastarpart(indexParam, 0);

       }

       offsetParam += deltaastarpart.GetNrows();


     }


     if ( _verbosity >= 3 ) {

       printMatrix( deltaastar, "deltaastar" );

     }


   }


   // calculate delta(y*), = 0 in the first iteration

   TMatrixD deltaystar( _nParB, 1 );

   offsetParam = 0;

   for (unsigned int indexParticle = 0; indexParticle < _measParticles.size(); indexParticle++) {


     TAbsFitParticle* particle = _measParticles[indexParticle];

     const TMatrixD* ystar = particle->getParCurr();

     const TMatrixD* y = particle->getParIni();

     TMatrixD deltaystarpart(*ystar);

     deltaystarpart -= *y;


     for (int indexParam = 0; indexParam < deltaystarpart.GetNrows(); indexParam++) {

       deltaystar(indexParam+offsetParam, 0) = deltaystarpart(indexParam, 0);

     }

     offsetParam += deltaystarpart.GetNrows();


   }


   for (unsigned int iC = 0; iC < _constraints.size(); iC++) {


     TAbsFitConstraint* constraint = _constraints[iC];


     if ( constraint->getNPar() > 0 ) {


       const TMatrixD* alphastar = constraint->getParCurr();

       const TMatrixD* alpha = constraint->getParIni();


       TMatrixD deltaalphastarpart(*alphastar);

       deltaalphastarpart -= *alpha;


       for (int indexParam = 0; indexParam < deltaalphastarpart.GetNrows(); indexParam++) {

     deltaystar(indexParam+offsetParam, 0) = deltaalphastarpart(indexParam, 0);

       }

       offsetParam += deltaalphastarpart.GetNrows();


     }

   }


   if ( _verbosity >= 3 ) {

     printMatrix( deltaystar, "deltaystar" );

   }


   // calculate f*

   TMatrixD fstar( _constraints.size(), 1 );

   for (unsigned int indexConstr = 0; indexConstr < _constraints.size(); indexConstr++) {

     fstar( indexConstr, 0 ) = _constraints[indexConstr]->getCurrentValue();

   }


   // calculate c

   _c.ResizeTo( fstar );

   _c = fstar;

   _c *= (-1.);

   TMatrixD Bdeltaystar( _B, TMatrixD::kMult, deltaystar );

   _c += Bdeltaystar;

   if ( _nParA ) {

     TMatrixD Adeltaastar( _A, TMatrixD::kMult, deltaastar );

     _c += Adeltaastar;

   }


   return true;


 }


 Bool_t TKinFitter::calcDeltaA() {

   // Calculate the matrix deltaA = C32T * c

   // (corrections to unmeasured parameters)


   TMatrixD deltaA( _C32T, TMatrixD::kMult, _c );

   _deltaA.ResizeTo( deltaA );


   if (_nbIter == 0) {

     _deltaAstar.ResizeTo(deltaA);

     _deltaAstar.Zero();

   } else

     _deltaAstar = _deltaA;


   _deltaA = deltaA;


   return true;


 }


 Bool_t TKinFitter::calcDeltaY() {

   // Calculate the matrix deltaY = C31T * c

   // (corrections to measured parameters)


   TMatrixD deltaY( _C31T, TMatrixD::kMult, _c );

   _deltaY.ResizeTo( deltaY );


   if (_nbIter == 0) {

     _deltaYstar.ResizeTo(deltaY);

     _deltaYstar.Zero();

   } else

     _deltaYstar = _deltaY;


   _deltaY = deltaY;


   return true;


 }


 Bool_t TKinFitter::calcLambda() {

   // Calculate the matrix Lambda = C33 * c

   // (Lagrange Multipliers)


   TMatrixD lambda( _C33,  TMatrixD::kMult, _c );

   _lambda.ResizeTo( lambda );

   _lambda = lambda;


   TMatrixD lambdaT( TMatrixD::kTransposed,  _lambda );

   _lambdaT.ResizeTo( lambdaT );

   _lambdaT = lambdaT;


   return true;


 }


 Bool_t TKinFitter::calcVFit() {

   // Calculate the covariance matrix of fitted parameters

   //

   // Vfit(y) = ( C11  C21T )

   //     (a)   ( C21  C22  )

   //

   // Vfit(lambda) = (-C33)


   // Calculate covariance matrix of lambda

   _lambdaVFit.ResizeTo( _C33 );

   _lambdaVFit = _C33;

   _lambdaVFit *= -1.;


   // Calculate combined covariance matrix of y and a

   Int_t nbRows = _C11.GetNrows();

   Int_t nbCols = _C11.GetNcols();

   if ( _nParA > 0 ) {

     nbRows += _C21.GetNrows();

     nbCols += _C21T.GetNcols();

   }

   _yaVFit.ResizeTo( nbRows, nbCols );


   for (int iRow = 0; iRow < nbRows; iRow++) {

     for (int iCol = 0; iCol < nbCols; iCol++) {


       if (iRow >= _C11.GetNrows()) {

     if (iCol >= _C11.GetNcols()) {

       _yaVFit(iRow, iCol) = _C22(iRow-_C11.GetNrows(), iCol-_C11.GetNcols());

     } else {

       _yaVFit(iRow, iCol) = _C21(iRow-_C11.GetNrows(), iCol);

     }

       } else {

     if (iCol >= _C11.GetNcols()) {

       _yaVFit(iRow, iCol) = _C21T(iRow, iCol-_C11.GetNcols());

     } else {

       _yaVFit(iRow, iCol) = _C11(iRow, iCol);

     }

       }


     }

   }


   return true;


 }


 void TKinFitter::applyVFit() {

   // apply fit covariance matrix to measured and unmeasured  particles


   int offsetParam = 0;

   for (unsigned int indexParticle = 0; indexParticle < _measParticles.size(); indexParticle++) {

     TAbsFitParticle* particle = _measParticles[indexParticle];

     Int_t nbParams = particle->getNPar();

     TMatrixD vfit( nbParams, nbParams );

     for (Int_t c = 0; c < nbParams; c++) {

       for (Int_t r = 0; r < nbParams; r++) {

     vfit(r, c) = _yaVFit(r + offsetParam, c + offsetParam);

       }

     }

     particle->setCovMatrixFit( &vfit );

     offsetParam += nbParams;

   }


   for (unsigned int indexConstraint = 0; indexConstraint < _constraints.size(); indexConstraint++) {

     TAbsFitConstraint* constraint = _constraints[indexConstraint];

     Int_t nbParams = constraint->getNPar();

     if (nbParams > 0) {

       TMatrixD vfit( nbParams, nbParams );

       for (Int_t c = 0; c < nbParams; c++) {

     for (Int_t r = 0; r < nbParams; r++) {

       vfit(r, c) = _yaVFit(r + offsetParam, c + offsetParam);

     }

       }

       constraint->setCovMatrixFit( &vfit );

       offsetParam += nbParams;

     }

   }


   for (unsigned int indexParticle = 0; indexParticle < _unmeasParticles.size(); indexParticle++) {

     TAbsFitParticle* particle = _unmeasParticles[indexParticle];

     Int_t nbParams = particle->getNPar();

     TMatrixD vfit( nbParams, nbParams );

     for (Int_t c = 0; c < nbParams; c++) {

       for (Int_t r = 0; r < nbParams; r++) {

     vfit(r, c) = _yaVFit(r + offsetParam, c + offsetParam);

       }

     }

     particle->setCovMatrixFit( &vfit );

     offsetParam += nbParams;

   }


 }


 Bool_t TKinFitter::applyDeltaA() {

   //apply corrections to unmeasured particles


   int offsetParam = 0;

   for (unsigned int indexParticle = 0; indexParticle < _unmeasParticles.size(); indexParticle++) {


     TAbsFitParticle* particle = _unmeasParticles[indexParticle];

     Int_t nbParams = particle->getNPar();

     TMatrixD params( nbParams, 1 );

     for (Int_t index = 0; index < nbParams; index++) {

       params(index, 0) = _deltaA(index+offsetParam, 0);

     }

     particle->applycorr( &params );

     offsetParam+=nbParams;


   }


   return true;


 }


 Bool_t TKinFitter::applyDeltaY() {

   //apply corrections to measured particles


   int offsetParam = 0;

   for (unsigned int indexParticle = 0; indexParticle < _measParticles.size(); indexParticle++) {


     TAbsFitParticle* particle = _measParticles[indexParticle];

     Int_t nbParams = particle->getNPar();

     TMatrixD params( nbParams, 1 );

     for (Int_t index = 0; index < nbParams; index++) {

       params(index, 0) = _deltaY(index+offsetParam, 0);

     }

     particle->applycorr( &params );

     offsetParam+=nbParams;


   }


   for (unsigned int indexConstraint = 0; indexConstraint < _constraints.size(); indexConstraint++) {


     TAbsFitConstraint* constraint = _constraints[indexConstraint];

     Int_t nbParams = constraint->getNPar();

     if ( nbParams > 0 ) {

       TMatrixD params( nbParams, 1 );

       for (Int_t index = 0; index < nbParams; index++) {

     params(index, 0) = _deltaY(index+offsetParam, 0);

       }

       constraint->applyDeltaAlpha( &params );

       offsetParam+=nbParams;

     }


   }


   return true;


 }


 Double_t TKinFitter::getF() {

   // calculate current absolut value of constraints

   // F = Sum[ Abs(f_k( aStar, yStar)) ]


   Double_t F = 0.;

   for (unsigned int indexConstr = 0; indexConstr < _constraints.size(); indexConstr++) {

     F += TMath::Abs( _constraints[indexConstr]->getCurrentValue() );

   }


   return F;


 }


 Double_t TKinFitter::getS() {

   // calculate current value of Chi2

   // S = deltaYT * V^-1 * deltaY


   Double_t S = 0.;


   if ( _nbIter > 0 ) {


     TMatrixD deltaYTVinv(_deltaY, TMatrixD::kTransposeMult, _Vinv);

     TMatrixD S2(deltaYTVinv, TMatrixD::kMult, _deltaY);

     S = S2(0,0);


   }


   return S;


 }


 Bool_t TKinFitter::converged( Double_t F, Double_t prevS, Double_t currS ) {

   // check whether convergence criteria are fulfilled


   Bool_t isConverged = false;


   // calculate F, delta(a) and delta(y) already applied

   isConverged = (F < _maxF);


   // Calculate current Chi^2 and delta(S)

   Double_t deltaS = currS - prevS;

   isConverged = isConverged && (TMath::Abs(deltaS) < _maxDeltaS);


   return isConverged;


 }


 TString TKinFitter::getStatusString() {


   TString statusstring = "";


   switch ( _status ) {


     case -1: {

       statusstring = "NO FIT PERFORMED";

       break;

     }

     case 10: {

       statusstring = "RUNNING";

       break;

     }

     case -10: {

       statusstring = "ABORTED";

       break;

     }

     case 0: {

       statusstring = "CONVERGED";

       break;

     }

     case 1: {

       statusstring = "NOT CONVERGED";

       break;

     }

   }


   return statusstring;


 }


 void TKinFitter::print() {


   edm::LogVerbatim log("KinFitter");

   log << "\n"

       << "\n";

   // Print status of fit

   log << "Status: " << getStatusString()

       << "   F=" << getF() << "   S=" << getS() << "   N=" << _nbIter << "   NDF=" << getNDF() << "\n";

   // Print measured particles

   log << "measured particles: \n";

   Int_t parIndex = 0;

   for (unsigned int iP = 0; iP < _measParticles.size(); iP++) {

     TAbsFitParticle* particle = _measParticles[iP];

     Int_t nParP = particle->getNPar();

     const TMatrixD* par = particle->getParCurr();

     const TMatrixD* covP = particle->getCovMatrix();

     log << std::setw(3) << setiosflags(std::ios::right) << iP;

     log << std::setw(15) << setiosflags(std::ios::right) << particle->GetName();

     log << std::setw(3) << " ";

     for (int iPar = 0; iPar < nParP; iPar++) {

       if (iPar > 0) {

     log << setiosflags(std::ios::right) << std::setw(21) << " ";

       }

       TString colstr = "";

       colstr += parIndex;

       colstr += ":";

       log << std::setw(4) << colstr;

       log << std::setw(2) << " ";

       log << setiosflags(std::ios::left) << setiosflags(std::ios::scientific) << std::setprecision(3);

       log << std::setw(15) << (*par)(iPar, 0);

       if(_nbIter > 0 && _status < 10) {

     log << std::setw(15) << TMath::Sqrt( _yaVFit(iPar, iPar) );

       } else {

     log << std::setw(15) << " ";

       }

       log << std::setw(15) << TMath::Sqrt( (*covP)(iPar, iPar) );

       log << "\n";

       parIndex++;

     }

     log << particle->getInfoString();

   }

   // Print unmeasured particles

   log << "unmeasured particles: \n";

   parIndex = 0;

   for (unsigned int iP = 0; iP < _unmeasParticles.size(); iP++) {

     TAbsFitParticle* particle = _unmeasParticles[iP];

     Int_t nParP = particle->getNPar();

     const TMatrixD* par = particle->getParCurr();

     log << std::setw(3) << setiosflags(std::ios::right) << iP;

     log << std::setw(15) << particle->GetName();

     log << std::setw(3) << " ";

     for (int iPar = 0; iPar < nParP; iPar++) {

       if (iPar > 0) {

     log << setiosflags(std::ios::right) << std::setw(21) << " ";

       }

       TString colstr = "";

       colstr += parIndex;

       colstr += ":";

       log << std::setw(4) << colstr;

       log << std::setw(2) << " ";

       log << setiosflags(std::ios::left) << setiosflags(std::ios::scientific) << std::setprecision(3);

       log << std::setw(15) << (*par)(iPar, 0);

       if(_nbIter > 0 && _status < 10) {

     log << std::setw(15) << TMath::Sqrt( _yaVFit(iPar+_nParB, iPar+_nParB) );

       } else {

     log << std::setw(15) << " ";

       }

       log << "\n";

       parIndex++;

     }

     log << particle->getInfoString();

   }

   log << "\n";

   // Print constraints

   log << "constraints: \n";

   for (unsigned int indexConstr = 0; indexConstr < _constraints.size(); indexConstr++) {

     log << _constraints[indexConstr]->getInfoString();

   }

   log << "\n";


 }


 void TKinFitter::printMatrix(const TMatrixD &matrix, const TString& name) {

   // produce a tabular printout for matrices

   // this function is a modified version of Root's TMatrixTBase<Element>::Print method

   // which could not be used together with the MessageLogger


   if (!matrix.IsValid()) {

     edm::LogWarning ("InvalidMatrix") << "Matrix " << name << " is invalid.";

     return;

   }


   edm::LogVerbatim log("KinFitter");


   const Int_t nCols  = matrix.GetNcols();

   const Int_t nRows  = matrix.GetNrows();

   const Int_t colsPerSheet = 5;

   char topbar[100];

   Int_t nk = 6+13*TMath::Min(colsPerSheet, nCols);

   for(Int_t i = 0; i < nk; i++) topbar[i] = '-';

   topbar[nk] = 0;


   Int_t sw = (70-name.Length())/2;


   log << std::setfill('=') << std::setw(sw) << "=  " << name << std::setw(sw) << std::left << "  ="  << "\n"

       << std::setfill(' ') << std::right << "\n";


   log << nRows << "x" << nCols << " matrix is as follows \n";


   for (Int_t iSheet = 0; iSheet < nCols; iSheet += colsPerSheet) {

     log << "\n"

     << "     |";

     for (Int_t iCol = iSheet; iCol < iSheet+colsPerSheet && iCol < nCols; iCol++)

       log << std::setw(8) << iCol << "    |";

     log << "\n"

     << topbar << " \n";

     for(Int_t iRow = 0; iRow < nRows; iRow++) {

       log << std::setw(4) << iRow << " |";

       for (Int_t iCol = iSheet; iCol < iSheet+colsPerSheet && iCol < nCols; iCol++)

     log << std::setw(12) << matrix(iRow, iCol) << " ";

       log << "\n";

     }

   }


 }

TKinFitter::_deltaY
TMatrixD _deltaY
Definition: TKinFitter.h:132

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title
Definition: indexGen.py:48

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virtual void applyDeltaAlpha(TMatrixD *corrMatrix)
Definition: TAbsFitConstraint.cc:101

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TKinFitter()
Definition: TKinFitter.cc:21

TKinFitter::_C11
TMatrixD _C11
Definition: TKinFitter.h:118

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int i
Definition: DBlmapReader.cc:9

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float alpha
Definition: AMPTWrapper.h:95

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list matrix
Definition: makeMuonMisalignmentScenario.py:139

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Bool_t calcC33()
Definition: TKinFitter.cc:774

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Bool_t calcV()
Definition: TKinFitter.cc:467

MessageLogger.h

TKinFitter::countMeasParams
void countMeasParams()
Definition: TKinFitter.cc:186

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Bool_t converged(Double_t F, Double_t prevS, Double_t currS)
Definition: TKinFitter.cc:1126

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Definition: TAbsFitConstraint.h:10

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virtual void reset()
Definition: TAbsFitConstraint.cc:48

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Bool_t calcVFit()
Definition: TKinFitter.cc:944

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std::vector< TAbsFitParticle * > _measParticles
Definition: TKinFitter.h:145

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Bool_t calcVB()
Definition: TKinFitter.cc:626

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Bool_t calcC11()
Definition: TKinFitter.cc:668

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virtual const TMatrixD * getCovMatrix() const
Definition: TAbsFitConstraint.h:29

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TString getInfoString()
Definition: TAbsFitParticle.cc:62

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Int_t fit()
Definition: TKinFitter.cc:309

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#define _B
Definition: LASProfileJudge.cc:8

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TString getStatusString()
Definition: TKinFitter.cc:1142

TKinFitter::_nParA
Int_t _nParA
Definition: TKinFitter.h:141

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TMatrixD _C33T
Definition: TKinFitter.h:129

TKinFitter::_lambda
TMatrixD _lambda
Definition: TKinFitter.h:135

TKinFitter::addMeasParticles
void addMeasParticles(TAbsFitParticle *p1, TAbsFitParticle *p2=0, TAbsFitParticle *p3=0, TAbsFitParticle *p4=0, TAbsFitParticle *p5=0, TAbsFitParticle *p6=0, TAbsFitParticle *p7=0, TAbsFitParticle *p8=0, TAbsFitParticle *p9=0)
Definition: TKinFitter.cc:224

TKinFitter::_C32T
TMatrixD _C32T
Definition: TKinFitter.h:127

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Bool_t calcC21()
Definition: TKinFitter.cc:698

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TMatrixD _V
Definition: TKinFitter.h:110

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void reset()
Definition: TKinFitter.cc:105

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Definition: MessageLogger.h:140

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Definition: TtSemiLepJetComb.h:24

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TMatrixD _C21T
Definition: TKinFitter.h:121

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virtual TMatrixD * getDerivativeAlpha()
Definition: TAbsFitConstraint.h:27

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TMatrixD _VB
Definition: TKinFitter.h:112

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virtual void reset()
Definition: TAbsFitParticle.cc:106

TKinFitter::_C31T
TMatrixD _C31T
Definition: TKinFitter.h:125

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T Min(T a, T b)
Definition: MathUtil.h:39

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tuple c
Definition: EnergyCorrector.py:43

TKinFitter.h

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string name
Definition: mergeVDriftHistosByStation.py:77

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void resetParams()
Definition: TKinFitter.cc:164

TKinFitter::_yaVFit
TMatrixD _yaVFit
Definition: TKinFitter.h:139

TKinFitter::_C32
TMatrixD _C32
Definition: TKinFitter.h:126

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string index
Definition: cmsHarvester.py:4379

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std::vector< TAbsFitParticle * > _unmeasParticles
Definition: TKinFitter.h:146

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Int_t getNPar()
Definition: TAbsFitConstraint.h:25

TKinFitter::_VA
TMatrixD _VA
Definition: TKinFitter.h:114

TKinFitter::getS
Double_t getS()
Definition: TKinFitter.cc:1108

TKinFitter::addUnmeasParticles
void addUnmeasParticles(TAbsFitParticle *p1, TAbsFitParticle *p2=0, TAbsFitParticle *p3=0, TAbsFitParticle *p4=0, TAbsFitParticle *p5=0, TAbsFitParticle *p6=0, TAbsFitParticle *p7=0, TAbsFitParticle *p8=0, TAbsFitParticle *p9=0)
Definition: TKinFitter.cc:260

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Definition: MessageLogger.h:164

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virtual void setCovMatrixFit(const TMatrixD *theCovMatrixFit)
Definition: TAbsFitConstraint.cc:72

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TMatrixD _deltaA
Definition: TKinFitter.h:131

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virtual TMatrixD * getDerivative()=0

TKinFitter::applyVFit
void applyVFit()
Definition: TKinFitter.cc:991

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Bool_t applyDeltaY()
Definition: TKinFitter.cc:1059

TKinFitter::_maxNbIter
Int_t _maxNbIter
Definition: TKinFitter.h:101

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Bool_t calcB()
Definition: TKinFitter.cc:558

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void print()
Definition: TKinFitter.cc:1174

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TMatrixD _C33
Definition: TKinFitter.h:128

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tuple log
Definition: dqm-mbProfile.py:17

TKinFitter::_deltaAstar
TMatrixD _deltaAstar
Definition: TKinFitter.h:133

TKinFitter::calcDeltaY
Bool_t calcDeltaY()
Definition: TKinFitter.cc:909

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double p4[4]
Definition: TauolaWrapper.h:92

TKinFitter::addConstraint
void addConstraint(TAbsFitConstraint *constraint)
Definition: TKinFitter.cc:281

TKinFitter::calcA
Bool_t calcA()
Definition: TKinFitter.cc:519

TKinFitter::calcLambda
Bool_t calcLambda()
Definition: TKinFitter.cc:928

TKinFitter::calcC31
Bool_t calcC31()
Definition: TKinFitter.cc:731

Abs
T Abs(T a)
Definition: MathUtil.h:49

TKinFitter::countUnmeasParams
void countUnmeasParams()
Definition: TKinFitter.cc:199

TKinFitter::~TKinFitter
~TKinFitter()
Definition: TKinFitter.cc:182

HLT_25ns10e33_v2_cff.constraint
tuple constraint
Definition: HLT_25ns10e33_v2_cff.py:9703

TKinFitter::_status
Int_t _status
Definition: TKinFitter.h:148

TKinFitter::_B
TMatrixD _B
Definition: TKinFitter.h:108

TKinFitter::_C22T
TMatrixD _C22T
Definition: TKinFitter.h:123

TKinFitter::addUnmeasParticle
void addUnmeasParticle(TAbsFitParticle *particle)
Definition: TKinFitter.cc:245

TKinFitter::_VAinv
TMatrixD _VAinv
Definition: TKinFitter.h:115

TAbsFitParticle::getNPar
Int_t getNPar() const
Definition: TAbsFitParticle.h:32

edm::LogVerbatim
Definition: MessageLogger.h:240

TKinFitter::getNDF
Int_t getNDF()
Definition: TKinFitter.h:35

TKinFitter::addMeasParticle
void addMeasParticle(TAbsFitParticle *particle)
Definition: TKinFitter.cc:209

TKinFitter::_C22
TMatrixD _C22
Definition: TKinFitter.h:122

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virtual void applycorr(TMatrixD *corrMatrix)
Definition: TAbsFitParticle.cc:186

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Definition: TauolaWrapper.h:90

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Definition: TKinFitter.h:116

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Definition: TKinFitter.h:102

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void setCovMatrix(TMatrixD &V)
Definition: TKinFitter.cc:454

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Definition: TKinFitter.h:106

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Definition: TAbsFitParticle.h:9

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Definition: TKinFitter.h:136

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Definition: TKinFitter.cc:294

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Definition: TAbsFitConstraint.h:37

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Definition: TKinFitter.cc:647

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Definition: TKinFitter.cc:1256

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Definition: TKinFitter.h:138

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Definition: Exception.h:68

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Definition: TKinFitter.h:124

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Definition: TKinFitter.cc:156

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Definition: TKinFitter.cc:1038

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TAbsFitConstraint.h

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Definition: TAbsFitParticle.h:37

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Definition: TKinFitter.h:144

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Definition: TKinFitter.h:134

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Definition: alignCSCRings.py:90

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Definition: TKinFitter.h:109

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Definition: TKinFitter.h:107

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Definition: TAbsFitParticle.h:26

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Definition: TKinFitter.h:149

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Definition: TauolaWrapper.h:89

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Definition: hdecay.h:121

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Definition: TKinFitter.cc:758

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Definition: TKinFitter.h:104

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Definition: TKinFitter.cc:1095

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Definition: HLT_25ns10e33_v2_cff.py:15320

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Definition: TKinFitter.h:113

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Definition: alignCSCRings.py:92

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Definition: TKinFitter.cc:717

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Definition: TKinFitter.cc:796

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Definition: TKinFitter.h:142

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Definition: TKinFitter.h:119

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Definition: TAbsFitParticle.cc:134

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Definition: blowfish.cc:281

TAbsFitParticle.h

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Definition: TAbsFitConstraint.h:40

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Definition: TKinFitter.h:120

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Definition: TKinFitter.h:111

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Definition: TKinFitter.cc:890

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Definition: TKinFitter.h:103

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Definition: TauolaWrapper.h:91