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TwoBodyDecayDerivatives Class Reference

#include <TwoBodyDecayDerivatives.h>

Public Types

enum  { dimension = 6 }
 
enum  DerivativeParameterName {
  px = 1, py = 2, pz = 3, theta = 4,
  phi = 5, mass = 6
}
 

Public Member Functions

const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
derivatives (const TwoBodyDecay &tbd) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
derivatives (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
selectedDerivatives (const TwoBodyDecay &tbd, const std::vector< bool > &selector) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
selectedDerivatives (const TwoBodyDecayParameters &param, const std::vector< bool > &selector) const
 
 TwoBodyDecayDerivatives (double mPrimary=91.1876, double mSecondary=0.105658)
 
 ~TwoBodyDecayDerivatives ()
 

Private Member Functions

const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdm (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdphi (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdpx (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdpy (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdpz (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdtheta (const TwoBodyDecayParameters &param) const
 
const std::pair
< AlgebraicMatrix,
AlgebraicMatrix
dqsdzi (const TwoBodyDecayParameters &param, const DerivativeParameterName &i) const
 

Private Attributes

double thePrimaryMass
 
double theSecondaryMass
 

Detailed Description

/class TwoBodyDecayDerivatives

This class provides the derivatives matrices need by the class TwoBodyDecayEstimator.

/author Edmund Widl

Definition at line 14 of file TwoBodyDecayDerivatives.h.

Member Enumeration Documentation

anonymous enum
Enumerator
dimension 

Definition at line 19 of file TwoBodyDecayDerivatives.h.

Constructor & Destructor Documentation

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

Definition at line 9 of file TwoBodyDecayDerivatives.cc.

9  :
10  thePrimaryMass( mPrimary ), theSecondaryMass( mSecondary ) {}
TwoBodyDecayDerivatives::~TwoBodyDecayDerivatives ( )

Definition at line 13 of file TwoBodyDecayDerivatives.cc.

13 {}

Member Function Documentation

const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::derivatives ( const TwoBodyDecay tbd) const

Derivatives of the lab frame momenta (in cartesian representation) of the secondaries w.r.t. z=(px,py,pz,theta,phi,m).

Definition at line 17 of file TwoBodyDecayDerivatives.cc.

References TwoBodyDecay::decayParameters().

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

18 {
19  return derivatives( tbd.decayParameters() );
20 }
const std::pair< AlgebraicMatrix, AlgebraicMatrix > derivatives(const TwoBodyDecay &tbd) const
const TwoBodyDecayParameters & decayParameters(void) const
Definition: TwoBodyDecay.h:34
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::derivatives ( const TwoBodyDecayParameters param) const

Derivatives of the lab frame momenta (in cartesian representation) of the secondaries w.r.t. z=(px,py,pz,theta,phi,m).

Definition at line 23 of file TwoBodyDecayDerivatives.cc.

References dimension, dqsdm(), dqsdphi(), dqsdpx(), dqsdpy(), dqsdpz(), dqsdtheta(), mass, phi, px, py, pz, and theta.

24 {
25  // get the derivatives with respect to all parameters
26  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpx = this->dqsdpx( param );
27  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpy = this->dqsdpy( param );
28  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpz = this->dqsdpz( param );
29  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdtheta = this->dqsdtheta( param );
30  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdphi = this->dqsdphi( param );
31  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdm = this->dqsdm( param );
32 
33  AlgebraicMatrix dqplusdz( 3, dimension );
34  dqplusdz.sub( 1, px, dqsdpx.first );
35  dqplusdz.sub( 1, py, dqsdpy.first );
36  dqplusdz.sub( 1, pz, dqsdpz.first );
37  dqplusdz.sub( 1, theta, dqsdtheta.first );
38  dqplusdz.sub( 1, phi, dqsdphi.first );
39  dqplusdz.sub( 1, mass, dqsdm.first );
40 
41  AlgebraicMatrix dqminusdz( 3, dimension );
42  dqminusdz.sub( 1, px, dqsdpx.second );
43  dqminusdz.sub( 1, py, dqsdpy.second );
44  dqminusdz.sub( 1, pz, dqsdpz.second );
45  dqminusdz.sub( 1, theta, dqsdtheta.second );
46  dqminusdz.sub( 1, phi, dqsdphi.second );
47  dqminusdz.sub( 1, mass, dqsdm.second );
48 
49  return std::make_pair( dqplusdz, dqminusdz );
50 }
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpx(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdphi(const TwoBodyDecayParameters &param) const
CLHEP::HepMatrix AlgebraicMatrix
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdm(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpz(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdtheta(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpy(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdm ( const TwoBodyDecayParameters param) const
private

Derivatives of the lab frame momenta of the secondaries w.r.t. the mass of the primary

Definition at line 393 of file TwoBodyDecayDerivatives.cc.

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

Referenced by derivatives(), and dqsdzi().

394 {
395  double px = param[TwoBodyDecayParameters::px];
396  double py = param[TwoBodyDecayParameters::py];
397  double pz = param[TwoBodyDecayParameters::pz];
398  double theta = param[TwoBodyDecayParameters::theta];
399  double phi = param[TwoBodyDecayParameters::phi];
400 
401  double pT2 = px*px + py*py;
402  double p2 = pT2 + pz*pz;
403 
404  double sphi = sin( phi );
405  double cphi = cos( phi );
406  double ctheta = cos( theta );
407  double stheta = sin( theta );
408 
409  // some constants from kinematics
410  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
411  double c2 = 1./sqrt( c1*c1 - 1. );
412  double m2 = thePrimaryMass*thePrimaryMass;
413 
414  // derivative of the momentum of particle 1 in the primary's rest frame w.r.t. the primary's mass
415  AlgebraicMatrix dpplusdm( 3, 1 );
416  dpplusdm[0][0] = c2*0.5*c1*stheta*cphi;
417  dpplusdm[1][0] = c2*0.5*c1*stheta*sphi;
418  dpplusdm[2][0] = c2*theSecondaryMass*( c1*c1 + p2/m2 )/sqrt( p2 + m2 )*ctheta;
419 
420  // derivative of the momentum of particle 2 in the primary's rest frame w.r.t. the primary's mass
421  AlgebraicMatrix dpminusdm( 3, 1 );
422  dpminusdm[0][0] = -dpplusdm[0][0];
423  dpminusdm[1][0] = -dpplusdm[1][0];
424  dpminusdm[2][0] = -dpplusdm[2][0];
425 
426  TwoBodyDecayModel decayModel;
427  AlgebraicMatrix rotMat = decayModel.rotationMatrix( px, py, pz );
428 
429  AlgebraicMatrix dqplusdm = rotMat*dpplusdm;
430  AlgebraicMatrix dqminusdm = rotMat*dpminusdm;
431 
432  return std::make_pair( dqplusdm, dqminusdm );
433 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
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
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdphi ( const TwoBodyDecayParameters param) const
private

Derivatives of the lab frame momenta of the secondaries w.r.t. the decay angle phi in the primary's rest frame.

Definition at line 355 of file TwoBodyDecayDerivatives.cc.

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

Referenced by derivatives(), and dqsdzi().

356 {
357  double px = param[TwoBodyDecayParameters::px];
358  double py = param[TwoBodyDecayParameters::py];
359  double pz = param[TwoBodyDecayParameters::pz];
360  double theta = param[TwoBodyDecayParameters::theta];
361  double phi = param[TwoBodyDecayParameters::phi];
362 
363  double sphi = sin( phi );
364  double cphi = cos( phi );
365  double stheta = sin( theta );
366 
367  // some constants from kinematics
368  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
369  double c2 = sqrt( c1*c1 - 1. );
370 
371  // derivative of the momentum of particle 1 in the primary's rest frame w.r.t. phi
372  AlgebraicMatrix dpplusdphi( 3, 1 );
373  dpplusdphi[0][0] = -theSecondaryMass*c2*stheta*sphi;
374  dpplusdphi[1][0] = theSecondaryMass*c2*stheta*cphi;
375  dpplusdphi[2][0] = 0.;
376 
377  // derivative of the momentum of particle 2 in the primary's rest frame w.r.t. phi
378  AlgebraicMatrix dpminusdphi( 3, 1 );
379  dpminusdphi[0][0] = theSecondaryMass*c2*stheta*sphi;
380  dpminusdphi[1][0] = -theSecondaryMass*c2*stheta*cphi;
381  dpminusdphi[2][0] = 0.;
382 
383  TwoBodyDecayModel decayModel;
384  AlgebraicMatrix rotMat = decayModel.rotationMatrix( px, py, pz );
385 
386  AlgebraicMatrix dqplusdphi = rotMat*dpplusdphi;
387  AlgebraicMatrix dqminusdphi = rotMat*dpminusdphi;
388 
389  return std::make_pair( dqplusdphi, dqminusdphi );
390 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
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
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdpx ( const TwoBodyDecayParameters param) const
private

Derivatives of the lab frame momenta of the secondaries w.r.t. px of the primary particle.

Definition at line 91 of file TwoBodyDecayDerivatives.cc.

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

Referenced by derivatives(), and dqsdzi().

92 {
93  double px = param[TwoBodyDecayParameters::px];
94  double py = param[TwoBodyDecayParameters::py];
95  double pz = param[TwoBodyDecayParameters::pz];
96  double theta = param[TwoBodyDecayParameters::theta];
97  double phi = param[TwoBodyDecayParameters::phi];
98 
99  // compute transverse and absolute momentum
100  double pT2 = px*px + py*py;
101  double p2 = pT2 + pz*pz;
102  double pT = sqrt( pT2 );
103  double p = sqrt( p2 );
104 
105  double sphi = sin( phi );
106  double cphi = cos( phi );
107  double stheta = sin( theta );
108  double ctheta = cos( theta );
109 
110  // some constants from kinematics
111  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
112  double c2 = sqrt( c1*c1 - 1. );
113  double c3 = 0.5*c2*ctheta/c1;
114  double c4 = sqrt( p2 + thePrimaryMass*thePrimaryMass );
115 
116  // momentum of decay particle 1 in the primary's boosted frame
117  AlgebraicMatrix pplus( 3, 1 );
118  pplus[0][0] = theSecondaryMass*c2*stheta*cphi;
119  pplus[1][0] = theSecondaryMass*c2*stheta*sphi;
120  pplus[2][0] = 0.5*p + c3*c4;
121 
122  // momentum of decay particle 2 in the primary's boosted frame
123  AlgebraicMatrix pminus( 3, 1 );
124  pminus[0][0] = -pplus[0][0];
125  pminus[1][0] = -pplus[1][0];
126  pminus[2][0] = 0.5*p - c3*c4;
127 
128  // derivative of rotation matrix w.r.t. px
129  AlgebraicMatrix dRotMatdpx( 3, 3 );
130 
131  dRotMatdpx[0][0] = pz/(pT*p)*(1.-px*px*(1./pT2+1./p2));
132  dRotMatdpx[0][1] = px*py/(pT*pT2);
133  dRotMatdpx[0][2] = (1.-px*px/p2)/p;
134 
135  dRotMatdpx[1][0] = -px*py*pz/(pT*p)*(1./pT2+1./p2);
136  dRotMatdpx[1][1] = (1.-px*px/pT2)/pT;
137  dRotMatdpx[1][2] = -px*py/(p*p2);
138 
139  dRotMatdpx[2][0] = -(1./pT-pT/p2)*px/p;
140  dRotMatdpx[2][1] = 0.;
141  dRotMatdpx[2][2] = -px*pz/(p*p2);
142 
143  // derivative of the momentum of particle 1 in the lab frame w.r.t. px
144  double dpplusdpx = px*( 0.5/p + c3/c4 );
145 
146  AlgebraicMatrix dqplusdpx = dRotMatdpx*pplus;
147  dqplusdpx[0][0] += px*dpplusdpx/p;
148  dqplusdpx[1][0] += py*dpplusdpx/p;
149  dqplusdpx[2][0] += pz*dpplusdpx/p;
150 
151  // derivative of the momentum of particle 2 in the lab frame w.r.t. px
152  double dpminusdpx = px*( 0.5/p - c3/c4 );
153 
154  AlgebraicMatrix dqminusdpx = dRotMatdpx*pminus;
155  dqminusdpx[0][0] += px*dpminusdpx/p;
156  dqminusdpx[1][0] += py*dpminusdpx/p;
157  dqminusdpx[2][0] += pz*dpminusdpx/p;
158 
159  // return result
160  return std::make_pair( dqplusdpx, dqminusdpx );
161 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
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
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdpy ( const TwoBodyDecayParameters param) const
private

Derivatives of the lab frame momenta of the secondaries w.r.t. py of the primary particle.

Definition at line 164 of file TwoBodyDecayDerivatives.cc.

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

Referenced by derivatives(), and dqsdzi().

165 {
166  double px = param[TwoBodyDecayParameters::px];
167  double py = param[TwoBodyDecayParameters::py];
168  double pz = param[TwoBodyDecayParameters::pz];
169  double theta = param[TwoBodyDecayParameters::theta];
170  double phi = param[TwoBodyDecayParameters::phi];
171 
172  // compute transverse and absolute momentum
173  double pT2 = px*px + py*py;
174  double p2 = pT2 + pz*pz;
175  double pT = sqrt( pT2 );
176  double p = sqrt( p2 );
177 
178  double sphi = sin( phi );
179  double cphi = cos( phi );
180  double stheta = sin( theta );
181  double ctheta = cos( theta );
182 
183  // some constants from kinematics
184  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
185  double c2 = sqrt( c1*c1 - 1. );
186  double c3 = 0.5*c2*ctheta/c1;
187  double c4 = sqrt( p2 + thePrimaryMass*thePrimaryMass );
188 
189  // momentum of decay particle 1 in the rest frame of the primary
190  AlgebraicMatrix pplus( 3, 1 );
191  pplus[0][0] = theSecondaryMass*c2*stheta*cphi;
192  pplus[1][0] = theSecondaryMass*c2*stheta*sphi;
193  pplus[2][0] = 0.5*p + c3*c4;
194 
195  // momentum of decay particle 2 in the rest frame of the primary
196  AlgebraicMatrix pminus( 3, 1 );
197  pminus[0][0] = -pplus[0][0];
198  pminus[1][0] = -pplus[1][0];
199  pminus[2][0] = 0.5*p - c3*c4;
200 
201  // derivative of rotation matrix w.r.t. py
202  AlgebraicMatrix dRotMatdpy( 3, 3 );
203 
204  dRotMatdpy[0][0] = -px*py*pz/(pT*p)*(1./pT2+1./p2);
205  dRotMatdpy[0][1] = (py*py/pT2-1.)/pT;
206  dRotMatdpy[0][2] = -px*py/(p*p2);
207 
208  dRotMatdpy[1][0] = pz/(pT*p)*(1.-py*py*(1./pT2+1./p2));
209  dRotMatdpy[1][1] = -px*py/(pT*pT2);
210  dRotMatdpy[1][2] = (1.-py*py/p2)/p;
211 
212  dRotMatdpy[2][0] = -(1./pT-pT/p2)*py/p;
213  dRotMatdpy[2][1] = 0.;
214  dRotMatdpy[2][2] = -py*pz/(p*p2);
215 
216  // derivative of the momentum of particle 1 in the lab frame w.r.t. py
217  double dpplusdpy = py*( 0.5/p + c3/c4 );
218 
219  AlgebraicMatrix dqplusdpy = dRotMatdpy*pplus;
220  dqplusdpy[0][0] += px*dpplusdpy/p;
221  dqplusdpy[1][0] += py*dpplusdpy/p;
222  dqplusdpy[2][0] += pz*dpplusdpy/p;
223 
224  // derivative of the momentum of particle 2 in the lab frame w.r.t. py
225  double dpminusdpy = py*( 0.5/p - c3/c4 );
226 
227  AlgebraicMatrix dqminusdpy = dRotMatdpy*pminus;
228  dqminusdpy[0][0] += px*dpminusdpy/p;
229  dqminusdpy[1][0] += py*dpminusdpy/p;
230  dqminusdpy[2][0] += pz*dpminusdpy/p;
231 
232  // return result
233  return std::make_pair( dqplusdpy, dqminusdpy );
234 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
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
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdpz ( const TwoBodyDecayParameters param) const
private

Derivatives of the lab frame momenta of the secondaries w.r.t. pz of the primary particle.

Definition at line 237 of file TwoBodyDecayDerivatives.cc.

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

Referenced by derivatives(), and dqsdzi().

238 {
239  double px = param[TwoBodyDecayParameters::px];
240  double py = param[TwoBodyDecayParameters::py];
241  double pz = param[TwoBodyDecayParameters::pz];
242  double theta = param[TwoBodyDecayParameters::theta];
243  double phi = param[TwoBodyDecayParameters::phi];
244 
245  // compute transverse and absolute momentum
246  double pT2 = px*px + py*py;
247  double p2 = pT2 + pz*pz;
248  double pT = sqrt( pT2 );
249  double p = sqrt( p2 );
250 
251  double sphi = sin( phi );
252  double cphi = cos( phi );
253  double stheta = sin( theta );
254  double ctheta = cos( theta );
255 
256  // some constants from kinematics
257  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
258  double c2 = sqrt( c1*c1 - 1. );
259  double c3 = 0.5*c2*ctheta/c1;
260  double c4 = sqrt( p2 + thePrimaryMass*thePrimaryMass );
261 
262  // momentum of decay particle 1 in the rest frame of the primary
263  AlgebraicMatrix pplus( 3, 1 );
264  pplus[0][0] = theSecondaryMass*c2*stheta*cphi;
265  pplus[1][0] = theSecondaryMass*c2*stheta*sphi;
266  pplus[2][0] = 0.5*p + c3*c4;
267 
268  // momentum of decay particle 2 in the rest frame of the primary
269  AlgebraicMatrix pminus( 3, 1 );
270  pminus[0][0] = -pplus[0][0];
271  pminus[1][0] = -pplus[1][0];
272  pminus[2][0] = 0.5*p - c3*c4;
273 
274  // derivative of rotation matrix w.r.t. py
275  AlgebraicMatrix dRotMatdpz( 3, 3 );
276 
277  dRotMatdpz[0][0] = px/(pT*p)*(1.-pz*pz/p2);
278  dRotMatdpz[0][1] = 0.;
279  dRotMatdpz[0][2] = -px*pz/(p*p2);
280 
281  dRotMatdpz[1][0] = py/(p*pT)*(1.-pz*pz/p2);
282  dRotMatdpz[1][1] = 0.;
283  dRotMatdpz[1][2] = -py*pz/(p*p2);
284 
285  dRotMatdpz[2][0] = pT*pz/(p*p2);
286  dRotMatdpz[2][1] = 0.;
287  dRotMatdpz[2][2] = (1.-pz*pz/p2)/p;
288 
289  // derivative of the momentum of particle 1 in the lab frame w.r.t. pz
290  double dpplusdpz = pz*( 0.5/p + c3/c4 );
291 
292  AlgebraicMatrix dqplusdpz = dRotMatdpz*pplus;
293  dqplusdpz[0][0] += px*dpplusdpz/p;
294  dqplusdpz[1][0] += py*dpplusdpz/p;
295  dqplusdpz[2][0] += pz*dpplusdpz/p;
296 
297  // derivative of the momentum of particle 2 in the lab frame w.r.t. pz
298  double dpminusdpz = pz*( 0.5/p - c3/c4 );
299 
300  AlgebraicMatrix dqminusdpz = dRotMatdpz*pminus;
301  dqminusdpz[0][0] += px*dpminusdpz/p;
302  dqminusdpz[1][0] += py*dpminusdpz/p;
303  dqminusdpz[2][0] += pz*dpminusdpz/p;
304 
305  // return result
306  return std::make_pair( dqplusdpz, dqminusdpz );
307 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
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
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdtheta ( const TwoBodyDecayParameters param) const
private

Derivatives of the lab frame momenta of the secondaries w.r.t. the decay angle theta in the primary's rest frame.

Definition at line 310 of file TwoBodyDecayDerivatives.cc.

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

Referenced by derivatives(), and dqsdzi().

311 {
312  double px = param[TwoBodyDecayParameters::px];
313  double py = param[TwoBodyDecayParameters::py];
314  double pz = param[TwoBodyDecayParameters::pz];
315  double theta = param[TwoBodyDecayParameters::theta];
316  double phi = param[TwoBodyDecayParameters::phi];
317 
318  // compute transverse and absolute momentum
319  double pT2 = px*px + py*py;
320  double p2 = pT2 + pz*pz;
321 
322  double sphi = sin( phi );
323  double cphi = cos( phi );
324  double stheta = sin( theta );
325  double ctheta = cos( theta );
326 
327  // some constants from kinematics
328  double c1 = 0.5*thePrimaryMass/theSecondaryMass;
329  double c2 = sqrt( c1*c1 - 1. );
330  double c3 = -0.5*c2*stheta/c1;
331  double c4 = sqrt( p2 + thePrimaryMass*thePrimaryMass );
332 
333  // derivative of the momentum of particle 1 in the primary's rest frame w.r.t. theta
334  AlgebraicMatrix dpplusdtheta( 3, 1 );
335  dpplusdtheta[0][0] = theSecondaryMass*c2*ctheta*cphi;
336  dpplusdtheta[1][0] = theSecondaryMass*c2*ctheta*sphi;
337  dpplusdtheta[2][0] = c3*c4;
338 
339  // derivative of the momentum of particle 2 in the primary's rest frame w.r.t. theta
340  AlgebraicMatrix dpminusdtheta( 3, 1 );
341  dpminusdtheta[0][0] = -theSecondaryMass*c2*ctheta*cphi;
342  dpminusdtheta[1][0] = -theSecondaryMass*c2*ctheta*sphi;
343  dpminusdtheta[2][0] = -c3*c4;
344 
345  TwoBodyDecayModel decayModel;
346  AlgebraicMatrix rotMat = decayModel.rotationMatrix( px, py, pz );
347 
348  AlgebraicMatrix dqplusdtheta = rotMat*dpplusdtheta;
349  AlgebraicMatrix dqminusdtheta = rotMat*dpminusdtheta;
350 
351  return std::make_pair( dqplusdtheta, dqminusdtheta );
352 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
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
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::dqsdzi ( const TwoBodyDecayParameters param,
const DerivativeParameterName i 
) const
private

Definition at line 437 of file TwoBodyDecayDerivatives.cc.

References dqsdm(), dqsdphi(), dqsdpx(), dqsdpy(), dqsdpz(), dqsdtheta(), Exception, mass, phi, px, py, pz, and theta.

Referenced by selectedDerivatives().

438 {
439  switch ( i )
440  {
442  return dqsdpx( param );
443  break;
445  return dqsdpy( param );
446  break;
448  return dqsdpz( param );
449  break;
451  return dqsdtheta( param );
452  break;
454  return dqsdphi( param );
455  break;
457  return dqsdm( param );
458  break;
459  default:
460  throw cms::Exception( "BadConfig" ) << "@SUB=TwoBodyDecayDerivatives::dqsdzi"
461  << "no decay parameter related to selector (" << i << ").";
462  };
463 
464  return std::make_pair( AlgebraicMatrix( 3, 1, 0 ), AlgebraicMatrix( 3, 1, 0 ) );
465 }
int i
Definition: DBlmapReader.cc:9
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpx(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdphi(const TwoBodyDecayParameters &param) const
CLHEP::HepMatrix AlgebraicMatrix
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdm(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpz(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdtheta(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdpy(const TwoBodyDecayParameters &param) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::selectedDerivatives ( const TwoBodyDecay tbd,
const std::vector< bool > &  selector 
) const

Derivatives of the lab frame momenta (in cartesian representation) of the secondaries w.r.t. the selected parameters.

Definition at line 54 of file TwoBodyDecayDerivatives.cc.

References TwoBodyDecay::decayParameters().

55 {
56  return selectedDerivatives( tbd.decayParameters(), selector );
57 }
const TwoBodyDecayParameters & decayParameters(void) const
Definition: TwoBodyDecay.h:34
const std::pair< AlgebraicMatrix, AlgebraicMatrix > selectedDerivatives(const TwoBodyDecay &tbd, const std::vector< bool > &selector) const
const std::pair< AlgebraicMatrix, AlgebraicMatrix > TwoBodyDecayDerivatives::selectedDerivatives ( const TwoBodyDecayParameters param,
const std::vector< bool > &  selector 
) const

Derivatives of the lab frame momenta (in cartesian representation) of the secondaries w.r.t. the selected parameters.

Definition at line 61 of file TwoBodyDecayDerivatives.cc.

References prof2calltree::count, dimension, dqsdzi(), Exception, i, and funct::true.

62 {
63  if ( selector.size() != dimension )
64  {
65  throw cms::Exception( "BadConfig" ) << "@SUB=TwoBodyDecayDerivatives::selectedDerivatives"
66  << "selector has bad dimension (size=" << selector.size() << ").";
67  }
68 
69  int nSelected = std::count( selector.begin(), selector.end(), true );
70  int iSelected = 1;
71 
72  AlgebraicMatrix dqplusdz( 3, nSelected );
73  AlgebraicMatrix dqminusdz( 3, nSelected );
74  std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdzi;
75 
76  for ( unsigned int i = 1; i <= dimension; i++ )
77  {
78  if ( selector[i] )
79  {
80  dqsdzi = this->dqsdzi( param, DerivativeParameterName(i) );
81  dqplusdz.sub( 1, iSelected, dqsdzi.first );
82  dqminusdz.sub( 1, iSelected, dqsdzi.second );
83  iSelected++;
84  }
85  }
86 
87  return std::make_pair( dqplusdz, dqminusdz );
88 }
int i
Definition: DBlmapReader.cc:9
const std::pair< AlgebraicMatrix, AlgebraicMatrix > dqsdzi(const TwoBodyDecayParameters &param, const DerivativeParameterName &i) const
CLHEP::HepMatrix AlgebraicMatrix

Member Data Documentation

double TwoBodyDecayDerivatives::thePrimaryMass
private

Definition at line 76 of file TwoBodyDecayDerivatives.h.

Referenced by dqsdm(), dqsdphi(), dqsdpx(), dqsdpy(), dqsdpz(), and dqsdtheta().

double TwoBodyDecayDerivatives::theSecondaryMass
private

Definition at line 77 of file TwoBodyDecayDerivatives.h.

Referenced by dqsdm(), dqsdphi(), dqsdpx(), dqsdpy(), dqsdpz(), and dqsdtheta().