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TwoBodyDecayModel Class Reference

#include <TwoBodyDecayModel.h>

Public Member Functions

const std::pair
< AlgebraicVector,
AlgebraicVector
cartesianSecondaryMomenta (const AlgebraicVector &param)
 
const std::pair
< AlgebraicVector,
AlgebraicVector
cartesianSecondaryMomenta (const TwoBodyDecay &tbd)
 
const std::pair
< AlgebraicVector,
AlgebraicVector
cartesianSecondaryMomenta (const TwoBodyDecayParameters &tbdparam)
 
AlgebraicVector convertCurvilinearToCartesian (const AlgebraicVector &curv, double zMagField)
 
AlgebraicMatrix curvilinearToCartesianJacobian (double rho, double theta, double phi, double zMagField)
 
AlgebraicMatrix curvilinearToCartesianJacobian (const AlgebraicVector &curv, double zMagField)
 
AlgebraicMatrix rotationMatrix (double px, double py, double pz)
 
 TwoBodyDecayModel (double mPrimary=91.1876, double mSecondary=0.105658)
 
 ~TwoBodyDecayModel ()
 

Private Attributes

double thePrimaryMass
 
double theSecondaryMass
 

Detailed Description

/class TwoBodyDecayModel

This class provides useful methods needed for the two-body decay model used by implementations of e.g. class TwoBodyDecayEstimator or TwoBodyDecayLinearizationPointFinder.

/author Edmund Widl

Definition at line 16 of file TwoBodyDecayModel.h.

Constructor & Destructor Documentation

TwoBodyDecayModel::TwoBodyDecayModel ( double  mPrimary = 91.1876,
double  mSecondary = 0.105658 
)

Definition at line 5 of file TwoBodyDecayModel.cc.

5  :
6  thePrimaryMass( mPrimary ), theSecondaryMass( mSecondary ) {}
TwoBodyDecayModel::~TwoBodyDecayModel ( )

Definition at line 9 of file TwoBodyDecayModel.cc.

9 {}

Member Function Documentation

const std::pair< AlgebraicVector, AlgebraicVector > TwoBodyDecayModel::cartesianSecondaryMomenta ( const AlgebraicVector param)

Momenta of the secondaries in cartesian repraesentation.

Definition at line 88 of file TwoBodyDecayModel.cc.

References alignmentValidation::c1, counter::c2, funct::cos(), AlCaHLTBitMon_ParallelJobs::p, p2, phi, TwoBodyDecayParameters::phi, TwoBodyDecayParameters::px, TwoBodyDecayParameters::py, TwoBodyDecayParameters::pz, rotationMatrix(), funct::sin(), mathSSE::sqrt(), thePrimaryMass, theSecondaryMass, TwoBodyDecayParameters::theta, and theta().

Referenced by cartesianSecondaryMomenta(), TwoBodyDecayTrajectoryState::construct(), and TwoBodyDecayEstimator::constructMatrices().

89 {
90  double px = param[TwoBodyDecayParameters::px];
91  double py = param[TwoBodyDecayParameters::py];
92  double pz = param[TwoBodyDecayParameters::pz];
93  double theta = param[TwoBodyDecayParameters::theta];
94  double phi = param[TwoBodyDecayParameters::phi];
95 
96  // compute transverse and absolute momentum
97  double pT2 = px*px + py*py;
98  double p2 = pT2 + pz*pz;
99  double p = sqrt( p2 );
100 
101  double sphi = sin( phi );
102  double cphi = cos( phi );
103  double stheta = sin( theta );
104  double ctheta = cos( theta );
105 
106  // some constants from kinematics
107  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
108  double c2 = sqrt( c1*c1 - 1. );
109  double c3 = 0.5*c2*ctheta/c1;
110  double c4 = sqrt( p2 + thePrimaryMass*thePrimaryMass );
111 
112  // momentum of decay particle 1 in the primary's boosted frame
113  AlgebraicMatrix pplus( 3, 1 );
114  pplus[0][0] = theSecondaryMass*c2*stheta*cphi;
115  pplus[1][0] = theSecondaryMass*c2*stheta*sphi;
116  pplus[2][0] = 0.5*p + c3*c4;
117 
118  // momentum of decay particle 2 in the primary's boosted frame
119  AlgebraicMatrix pminus( 3, 1 );
120  pminus[0][0] = -pplus[0][0];
121  pminus[1][0] = -pplus[1][0];
122  pminus[2][0] = 0.5*p - c3*c4;
123 
124  AlgebraicMatrix rotMat = rotationMatrix( px, py, pz );
125 
126  return std::make_pair( rotMat*pplus, rotMat*pminus );
127 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
Geom::Theta< T > theta() const
AlgebraicMatrix rotationMatrix(double px, double py, double pz)
tuple c2
Definition: counter.py:145
CLHEP::HepMatrix AlgebraicMatrix
T sqrt(T t)
Definition: SSEVec.h:48
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
double p2[4]
Definition: TauolaWrapper.h:90
Definition: DDAxes.h:10
const std::pair< AlgebraicVector, AlgebraicVector > TwoBodyDecayModel::cartesianSecondaryMomenta ( const TwoBodyDecay tbd)

Momenta of the secondaries in cartesian repraesentation.

Definition at line 130 of file TwoBodyDecayModel.cc.

References cartesianSecondaryMomenta(), and TwoBodyDecay::parameters().

131 {
132  return cartesianSecondaryMomenta( tbd.parameters() );
133 }
const AlgebraicVector & parameters(void) const
Definition: TwoBodyDecay.h:36
const std::pair< AlgebraicVector, AlgebraicVector > cartesianSecondaryMomenta(const AlgebraicVector &param)
const std::pair< AlgebraicVector, AlgebraicVector > TwoBodyDecayModel::cartesianSecondaryMomenta ( const TwoBodyDecayParameters tbdparam)

Momenta of the secondaries in cartesian repraesentation.

Definition at line 135 of file TwoBodyDecayModel.cc.

References cartesianSecondaryMomenta(), and TwoBodyDecayParameters::parameters().

136 {
137  return cartesianSecondaryMomenta( tbdparam.parameters() );
138 }
const AlgebraicVector & parameters(void) const
Get decay parameters.
const std::pair< AlgebraicVector, AlgebraicVector > cartesianSecondaryMomenta(const AlgebraicVector &param)
AlgebraicVector TwoBodyDecayModel::convertCurvilinearToCartesian ( const AlgebraicVector curv,
double  zMagField 
)

Convert vector from curvilinear to cartesian coordinates (needs the z-component of magnetic field in inverse GeV as input).

Definition at line 75 of file TwoBodyDecayModel.cc.

References funct::cos(), funct::sin(), and funct::tan().

76 {
77  double rt = fabs( zMagField/curv[0] );
78 
79  AlgebraicVector cart( 3 );
80  cart[0] = rt*cos( curv[2] );
81  cart[1] = rt*sin( curv[2] );
82  cart[2] = rt/tan( curv[1] );
83 
84  return cart;
85 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
CLHEP::HepVector AlgebraicVector
AlgebraicMatrix TwoBodyDecayModel::curvilinearToCartesianJacobian ( double  rho,
double  theta,
double  phi,
double  zMagField 
)

Jacobian for transformation from curvilinear to cartesian representation (needs the z-component of magnetic field in inverse GeV as input).

Definition at line 39 of file TwoBodyDecayModel.cc.

References conv, funct::cos(), lumiQueryAPI::q, and funct::sin().

Referenced by curvilinearToCartesianJacobian().

40 {
41  double q = ( ( rho < 0 ) ? -1. : 1. );
42  double conv = q*zMagField;
43 
44  double stheta = sin( theta );
45  double ctheta = cos( theta );
46  double sphi = sin( phi );
47  double cphi = cos( phi );
48 
49  AlgebraicMatrix curv2cart( 3, 3 );
50 
51  curv2cart[0][0] = -rho*cphi;
52  curv2cart[0][1] = -rho*sphi;
53  curv2cart[0][2] = 0.;
54 
55  curv2cart[1][0] = cphi*stheta*ctheta;
56  curv2cart[1][1] = sphi*stheta*ctheta;
57  curv2cart[1][2] = -stheta*stheta;
58 
59  curv2cart[2][0] = -sphi;
60  curv2cart[2][1] = cphi;
61  curv2cart[2][2] = 0.;
62 
63  curv2cart *= rho/conv;
64 
65  return curv2cart;
66 }
static HepMC::IO_HEPEVT conv
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
Definition: DDAxes.h:10
Geom::Theta< T > theta() const
CLHEP::HepMatrix AlgebraicMatrix
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
Definition: DDAxes.h:10
AlgebraicMatrix TwoBodyDecayModel::curvilinearToCartesianJacobian ( const AlgebraicVector curv,
double  zMagField 
)

Jacobian for transformation from curvilinear to cartesian representation (needs the z-component of magnetic field in inverse GeV as input).

Definition at line 69 of file TwoBodyDecayModel.cc.

References curvilinearToCartesianJacobian().

70 {
71  return this->curvilinearToCartesianJacobian( curv[0], curv[1], curv[2], zMagField );
72 }
AlgebraicMatrix curvilinearToCartesianJacobian(double rho, double theta, double phi, double zMagField)
AlgebraicMatrix TwoBodyDecayModel::rotationMatrix ( double  px,
double  py,
double  pz 
)

Rotates a vector pointing in z-direction into the direction defined by p=(px,py,pz).

Definition at line 12 of file TwoBodyDecayModel.cc.

References AlCaHLTBitMon_ParallelJobs::p, p2, and mathSSE::sqrt().

Referenced by cartesianSecondaryMomenta(), TwoBodyDecayDerivatives::dqsdm(), TwoBodyDecayDerivatives::dqsdphi(), TwoBodyDecayDerivatives::dqsdtheta(), and TwoBodyDecayLinearizationPointFinder::getLinearizationPoint().

13 {
14  // compute transverse and absolute momentum
15  double pT2 = px*px + py*py;
16  double p2 = pT2 + pz*pz;
17  double pT = sqrt( pT2 );
18  double p = sqrt( p2 );
19 
20  AlgebraicMatrix rotMat( 3, 3 );
21 
22  // compute rotation matrix
23  rotMat[0][0] = px*pz/pT/p;
24  rotMat[0][1] = -py/pT;
25  rotMat[0][2] = px/p;
26 
27  rotMat[1][0] = py*pz/pT/p;
28  rotMat[1][1] = px/pT;
29  rotMat[1][2] = py/p;
30 
31  rotMat[2][0] = -pT/p;
32  rotMat[2][1] = 0.;
33  rotMat[2][2] = pz/p;
34 
35  return rotMat;
36 }
CLHEP::HepMatrix AlgebraicMatrix
T sqrt(T t)
Definition: SSEVec.h:48
double p2[4]
Definition: TauolaWrapper.h:90

Member Data Documentation

double TwoBodyDecayModel::thePrimaryMass
private

Definition at line 56 of file TwoBodyDecayModel.h.

Referenced by cartesianSecondaryMomenta().

double TwoBodyDecayModel::theSecondaryMass
private

Definition at line 57 of file TwoBodyDecayModel.h.

Referenced by cartesianSecondaryMomenta().