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/data/refman/pasoursint/CMSSW_5_3_0/src/RecoVertex/KinematicFit/src/TwoTrackMassKinematicConstraint.cc

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00001 #include "RecoVertex/KinematicFit/interface/TwoTrackMassKinematicConstraint.h"
00002 #include "RecoVertex/VertexPrimitives/interface/VertexException.h"
00003 
00004 
00005 AlgebraicVector  TwoTrackMassKinematicConstraint::value(const std::vector<KinematicState> states,
00006                         const GlobalPoint& point) const
00007 { 
00008  if(states.size()<2) throw VertexException("TwoTrackMassKinematicConstraint::<2 states passed");
00009 
00010  AlgebraicVector res(1,0);
00011  
00012  double a_1 = -states[0].particleCharge() * states[0].magneticField()->inInverseGeV(states[0].globalPosition()).z();
00013  double a_2 = -states[1].particleCharge() * states[1].magneticField()->inInverseGeV(states[1].globalPosition()).z();
00014 
00015  AlgebraicVector7 p1 = states[0].kinematicParameters().vector();
00016  AlgebraicVector7 p2 = states[1].kinematicParameters().vector();
00017  
00018  double p1vx = p1(3) - a_1*(point.y() - p1(1));
00019  double p1vy = p1(4) + a_1*(point.x() - p1(0));
00020  double p1vz = p1(5);
00021  ParticleMass m1 = p1(6);
00022  
00023  double p2vx = p2(3) - a_2*(point.y() - p2(1));
00024  double p2vy = p2(4) + a_2*(point.x() - p2(0)); 
00025  double p2vz = p2(5);
00026  ParticleMass m2 = p2(6);
00027  
00028  double j_energy = sqrt(p1(3)*p1(3)+p1(4)*p1(4)+p1(5)*p1(5)+m1*m1)+
00029                   sqrt(p2(3)*p2(3)+p2(4)*p2(4)+p2(5)*p2(5)+m2*m2)  ;
00030  
00031                        
00032  double j_m = (p1vx+p2vx)*(p1vx+p2vx) + (p1vy+p2vy)*(p1vy+p2vy) +
00033              (p1vz+p2vz)*(p1vz+p2vz);                   
00034 
00035  res(1)  = j_energy*j_energy - j_m - mass*mass;
00036  return res;
00037 }                       
00038                         
00039 AlgebraicMatrix TwoTrackMassKinematicConstraint::parametersDerivative(const std::vector<KinematicState> states,
00040                                       const GlobalPoint& point) const
00041 {
00042  int n_st = states.size();
00043  if(n_st<2) throw VertexException("TwoTrackMassKinematicConstraint::<2 states passed");
00044 
00045  AlgebraicMatrix res(1,n_st*7,0);
00046  
00047   double a_1 = -states[0].particleCharge() * states[0].magneticField()->inInverseGeV(states[0].globalPosition()).z();
00048   double a_2 = -states[1].particleCharge() * states[1].magneticField()->inInverseGeV(states[1].globalPosition()).z();
00049  
00050  AlgebraicVector7 p1 = states[0].kinematicParameters().vector();
00051  AlgebraicVector7 p2 = states[1].kinematicParameters().vector();
00052  
00053  double p1vx = p1(3) - a_1*(point.y() - p1(1));
00054  double p1vy = p1(4) + a_1*(point.x() - p1(0));
00055  double p1vz = p1(5);
00056  ParticleMass m1 = p1(6);
00057  
00058  double p2vx = p2(3) - a_2*(point.y() - p2(1));
00059  double p2vy = p2(4) + a_2*(point.x() - p2(0)); 
00060  double p2vz = p2(5);
00061  ParticleMass m2 = p2(6);
00062  
00063  double e1 = sqrt(p1(3)*p1(3)+p1(4)*p1(4)+p1(5)*p1(5)+m1*m1);
00064  double e2 = sqrt(p2(3)*p2(3)+p2(4)*p2(4)+p2(5)*p2(5)+m2*m2);
00065 
00066 
00067 //x1 and x2 derivatives: 1st and 8th elements 
00068  res(1,1) = 2*a_1*(p2vy + p1vy);
00069  res(1,8) = 2*a_2*(p2vy + p1vy);
00070 
00071 //y1 and y2 derivatives: 2nd and 9th elements:
00072  res(1,2) = -2*a_1*(p1vx + p2vx);
00073  res(1,9) = -2*a_2*(p2vx + p1vx);
00074  
00075 //z1 and z2 components: 3d and 10th elmnets stay 0:
00076  res(1,3)  = 0.;
00077  res(1,10) = 0.;
00078  
00079 //px1 and px2 components: 4th and 11th elements: 
00080  res(1,4)  = 2*(1+e2/e1)*p1(3) - 2*(p1vx + p2vx);
00081  res(1,11) = 2*(1+e1/e2)*p2(3) - 2*(p1vx + p2vx);
00082 
00083 //py1 and py2 components: 5th and 12 elements:
00084   res(1,5)  = 2*(1+e2/e1)*p1(4) - 2*(p1vy + p2vy);
00085   res(1,12) = 2*(1+e1/e2)*p2(4) - 2*(p2vy + p1vy);
00086  
00087 //pz1 and pz2 components: 6th and 13 elements:
00088  res(1,6)  = 2*(1+e2/e1)*p1(5)- 2*(p1vz + p2vz);
00089  res(1,13) = 2*(1+e1/e2)*p2(5)- 2*(p2vz + p1vz);
00090  
00091 //mass components: 7th and 14th elements:
00092  res(1,7)  = 2*m1*(1+e2/e1);
00093  res(1,14) = 2*m2*(1+e1/e2);
00094 
00095   return res;
00096 }                       
00097                                                                       
00098 AlgebraicMatrix TwoTrackMassKinematicConstraint::positionDerivative(const std::vector<KinematicState> states,
00099                                     const GlobalPoint& point) const
00100 {
00101  AlgebraicMatrix res(1,3,0);
00102  if(states.size()<2) throw VertexException("TwoTrackMassKinematicConstraint::<2 states passed");
00103 
00104   double a_1 = -states[0].particleCharge() * states[0].magneticField()->inInverseGeV(states[0].globalPosition()).z();
00105   double a_2 = -states[1].particleCharge() * states[1].magneticField()->inInverseGeV(states[1].globalPosition()).z();
00106  
00107  AlgebraicVector7 p1 = states[0].kinematicParameters().vector();
00108  AlgebraicVector7 p2 = states[1].kinematicParameters().vector();
00109  
00110  double p1vx = p1(3) - a_1*(point.y() - p1(1));
00111  double p1vy = p1(4) + a_1*(point.x() - p1(0));
00112  
00113  double p2vx = p2(3) - a_2*(point.y() - p2(1));
00114  double p2vy = p2(4) + a_2*(point.x() - p2(0)); 
00115  
00116 //xv component
00117  res(1,1) = -2*(p1vy + p2vy)*(a_1+a_2);
00118 
00119 //yv component
00120  res(1,2) = 2*(p1vx + p2vx)*(a_1+a_2);
00121 
00122 //zv component 
00123  res(1,3) = 0.; 
00124  
00125  return res;
00126 }                                   
00127                                                                     
00128 int TwoTrackMassKinematicConstraint::numberOfEquations() const
00129 {return 1;}