#include <TwoTrackMassKinematicConstraint.h>

Inheritance diagram for TwoTrackMassKinematicConstraint:

Public Member Functions
virtual TwoTrackMassKinematicConstraint *	clone () const

virtual int	numberOfEquations () const

virtual AlgebraicMatrix	parametersDerivative (const std::vector< KinematicState > states, const GlobalPoint &point) const

virtual AlgebraicMatrix	positionDerivative (const std::vector< KinematicState > states, const GlobalPoint &point) const

	TwoTrackMassKinematicConstraint (ParticleMass &ms)

virtual AlgebraicVector	value (const std::vector< KinematicState > states, const GlobalPoint &point) const

Public Member Functions inherited from MultiTrackKinematicConstraint
	MultiTrackKinematicConstraint ()

virtual	~MultiTrackKinematicConstraint ()

Private Attributes
ParticleMass	mass

Detailed Description

Class implementing the total mass of 2 tracks constraint. I.e. 2 first particles out of four passed form a given mass

Warning: the tracks to constraint should be 1st and 2nd from the beginning of the vector.

Definition at line 21 of file TwoTrackMassKinematicConstraint.h.

Constructor & Destructor Documentation

TwoTrackMassKinematicConstraint::TwoTrackMassKinematicConstraint ( ParticleMass & ms )

inline

Definition at line 24 of file TwoTrackMassKinematicConstraint.h.

Referenced by clone().

24 :mass(ms)

25 {}

TwoTrackMassKinematicConstraint::mass

ParticleMass mass

Definition: TwoTrackMassKinematicConstraint.h:63

Member Function Documentation

virtual TwoTrackMassKinematicConstraint* TwoTrackMassKinematicConstraint::clone ( void ) const

inlinevirtual

Implements MultiTrackKinematicConstraint.

Definition at line 58 of file TwoTrackMassKinematicConstraint.h.

References TwoTrackMassKinematicConstraint().

59 {return new TwoTrackMassKinematicConstraint(*this);}

TwoTrackMassKinematicConstraint::TwoTrackMassKinematicConstraint

TwoTrackMassKinematicConstraint(ParticleMass &ms)

Definition: TwoTrackMassKinematicConstraint.h:24

int TwoTrackMassKinematicConstraint::numberOfEquations ( ) const

virtual

Number of equations per track used for the fit

Implements MultiTrackKinematicConstraint.

Definition at line 128 of file TwoTrackMassKinematicConstraint.cc.

129 {return 1;}

AlgebraicMatrix TwoTrackMassKinematicConstraint::parametersDerivative	(	const std::vector< KinematicState >	states,
		const GlobalPoint &	point
	)		const

virtual

Returns a matrix of derivatives of constraint equations w.r.t. particle parameters

Implements MultiTrackKinematicConstraint.

Definition at line 39 of file TwoTrackMassKinematicConstraint.cc.

References p1, p2, mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

 {
  int n_st = states.size();
  if(n_st<2) throw VertexException("TwoTrackMassKinematicConstraint::<2 states passed");
 
  AlgebraicMatrix res(1,n_st*7,0);
  
   double a_1 = -states[0].particleCharge() * states[0].magneticField()->inInverseGeV(states[0].globalPosition()).z();
   double a_2 = -states[1].particleCharge() * states[1].magneticField()->inInverseGeV(states[1].globalPosition()).z();
  
  AlgebraicVector7 p1 = states[0].kinematicParameters().vector();
  AlgebraicVector7 p2 = states[1].kinematicParameters().vector();
  
  double p1vx = p1(3) - a_1*(point.y() - p1(1));
  double p1vy = p1(4) + a_1*(point.x() - p1(0));
  double p1vz = p1(5);
  ParticleMass m1 = p1(6);
  
  double p2vx = p2(3) - a_2*(point.y() - p2(1));
  double p2vy = p2(4) + a_2*(point.x() - p2(0)); 
  double p2vz = p2(5);
  ParticleMass m2 = p2(6);
  
  double e1 = sqrt(p1(3)*p1(3)+p1(4)*p1(4)+p1(5)*p1(5)+m1*m1);
  double e2 = sqrt(p2(3)*p2(3)+p2(4)*p2(4)+p2(5)*p2(5)+m2*m2);
 
 
 //x1 and x2 derivatives: 1st and 8th elements 
  res(1,1) = 2*a_1*(p2vy + p1vy);
  res(1,8) = 2*a_2*(p2vy + p1vy);
 
 //y1 and y2 derivatives: 2nd and 9th elements:
  res(1,2) = -2*a_1*(p1vx + p2vx);
  res(1,9) = -2*a_2*(p2vx + p1vx);
  
 //z1 and z2 components: 3d and 10th elmnets stay 0:
  res(1,3)  = 0.;
  res(1,10) = 0.;
  
 //px1 and px2 components: 4th and 11th elements: 
  res(1,4)  = 2*(1+e2/e1)*p1(3) - 2*(p1vx + p2vx);
  res(1,11) = 2*(1+e1/e2)*p2(3) - 2*(p1vx + p2vx);
 
 //py1 and py2 components: 5th and 12 elements:
   res(1,5)  = 2*(1+e2/e1)*p1(4) - 2*(p1vy + p2vy);
   res(1,12) = 2*(1+e1/e2)*p2(4) - 2*(p2vy + p1vy);
  
 //pz1 and pz2 components: 6th and 13 elements:
  res(1,6)  = 2*(1+e2/e1)*p1(5)- 2*(p1vz + p2vz);
  res(1,13) = 2*(1+e1/e2)*p2(5)- 2*(p2vz + p1vz);
  
 //mass components: 7th and 14th elements:
  res(1,7)  = 2*m1*(1+e2/e1);
  res(1,14) = 2*m2*(1+e1/e2);
 
   return res;
 }           

AlgebraicMatrix TwoTrackMassKinematicConstraint::positionDerivative	(	const std::vector< KinematicState >	states,
		const GlobalPoint &	point
	)		const

virtual

Returns a matrix of derivatives of constraint equations w.r.t. vertex position

Implements MultiTrackKinematicConstraint.

Definition at line 98 of file TwoTrackMassKinematicConstraint.cc.

References p1, p2, PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

 {
  AlgebraicMatrix res(1,3,0);
  if(states.size()<2) throw VertexException("TwoTrackMassKinematicConstraint::<2 states passed");
 
   double a_1 = -states[0].particleCharge() * states[0].magneticField()->inInverseGeV(states[0].globalPosition()).z();
   double a_2 = -states[1].particleCharge() * states[1].magneticField()->inInverseGeV(states[1].globalPosition()).z();
  
  AlgebraicVector7 p1 = states[0].kinematicParameters().vector();
  AlgebraicVector7 p2 = states[1].kinematicParameters().vector();
  
  double p1vx = p1(3) - a_1*(point.y() - p1(1));
  double p1vy = p1(4) + a_1*(point.x() - p1(0));
  
  double p2vx = p2(3) - a_2*(point.y() - p2(1));
  double p2vy = p2(4) + a_2*(point.x() - p2(0)); 
  
 //xv component
  res(1,1) = -2*(p1vy + p2vy)*(a_1+a_2);
 
 //yv component
  res(1,2) = 2*(p1vx + p2vx)*(a_1+a_2);
 
 //zv component 
  res(1,3) = 0.; 
  
  return res;
 }                   

AlgebraicVector TwoTrackMassKinematicConstraint::value	(	const std::vector< KinematicState >	states,
		const GlobalPoint &	point
	)		const

virtual

Returns a vector of values of constraint equations at the point where the input particles are defined.

Implements MultiTrackKinematicConstraint.

Definition at line 5 of file TwoTrackMassKinematicConstraint.cc.

References mass, p1, p2, mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

 { 
  if(states.size()<2) throw VertexException("TwoTrackMassKinematicConstraint::<2 states passed");
 
  AlgebraicVector res(1,0);
  
  double a_1 = -states[0].particleCharge() * states[0].magneticField()->inInverseGeV(states[0].globalPosition()).z();
  double a_2 = -states[1].particleCharge() * states[1].magneticField()->inInverseGeV(states[1].globalPosition()).z();
 
  AlgebraicVector7 p1 = states[0].kinematicParameters().vector();
  AlgebraicVector7 p2 = states[1].kinematicParameters().vector();
  
  double p1vx = p1(3) - a_1*(point.y() - p1(1));
  double p1vy = p1(4) + a_1*(point.x() - p1(0));
  double p1vz = p1(5);
  ParticleMass m1 = p1(6);
  
  double p2vx = p2(3) - a_2*(point.y() - p2(1));
  double p2vy = p2(4) + a_2*(point.x() - p2(0)); 
  double p2vz = p2(5);
  ParticleMass m2 = p2(6);
  
  double j_energy = sqrt(p1(3)*p1(3)+p1(4)*p1(4)+p1(5)*p1(5)+m1*m1)+
                   sqrt(p2(3)*p2(3)+p2(4)*p2(4)+p2(5)*p2(5)+m2*m2)  ;
  
                
  double j_m = (p1vx+p2vx)*(p1vx+p2vx) + (p1vy+p2vy)*(p1vy+p2vy) +
              (p1vz+p2vz)*(p1vz+p2vz);               
 
  res(1)  = j_energy*j_energy - j_m - mass*mass;
  return res;
 }           

Member Data Documentation

ParticleMass TwoTrackMassKinematicConstraint::mass

private

Definition at line 63 of file TwoTrackMassKinematicConstraint.h.

Referenced by value().

Public Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation