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TSCPBuilderNoMaterial.cc
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10 
13  const GlobalPoint& referencePoint) const
14 {
15  if (positionEqual(referencePoint, originalFTS.position()))
16  return constructTSCP(originalFTS, referencePoint);
17 
18  // Now do the propagation or whatever...
19 
20  PairBoolFTS newStatePair =
21  createFTSatTransverseImpactPoint(originalFTS, referencePoint);
22  if (newStatePair.first) {
23  return constructTSCP(newStatePair.second, referencePoint);
24  } else {
26  }
27 }
28 
31  const GlobalPoint& referencePoint) const
32 {
33  if (positionEqual(referencePoint, originalTSOS.globalPosition()))
34  return constructTSCP(*originalTSOS.freeState(), referencePoint);
35 
36  // Now do the propagation
37 
38  PairBoolFTS newStatePair =
39  createFTSatTransverseImpactPoint(*originalTSOS.freeState(), referencePoint);
40  if (newStatePair.first) {
41  return constructTSCP(newStatePair.second, referencePoint);
42  } else {
44  }
45 }
46 
49  const FTS& originalFTS, const GlobalPoint& referencePoint) const
50 {
51  //
52  // Straight line approximation? |rho|<1.e-10 equivalent to ~ 1um
53  // difference in transversal position at 10m.
54  //
55  if( fabs(originalFTS.transverseCurvature())<1.e-10 ) {
56  return createFTSatTransverseImpactPointNeutral(originalFTS, referencePoint);
57  } else {
58  return createFTSatTransverseImpactPointCharged(originalFTS, referencePoint);
59  }
60 }
61 
64  const FTS& originalFTS, const GlobalPoint& referencePoint) const
65 {
66 
67  GlobalVector pvecOrig = originalFTS.momentum();
68  GlobalPoint xvecOrig = originalFTS.position();
69  double kappa = originalFTS.transverseCurvature();
70  double pxOrig = pvecOrig.x();
71  double pyOrig = pvecOrig.y();
72  double pzOrig = pvecOrig.z();
73  double xOrig = xvecOrig.x();
74  double yOrig = xvecOrig.y();
75  double zOrig = xvecOrig.z();
76 
77 // double fac = 1./originalFTS.charge()/MagneticField::inInverseGeV(referencePoint).z();
78  double fac = 1./originalFTS.charge()/
79  (originalFTS.parameters().magneticField().inInverseGeV(referencePoint).z());
80  GlobalVectorDouble xOrig2Centre = GlobalVectorDouble(fac * pyOrig, -fac * pxOrig, 0.);
81  GlobalVectorDouble xOrigProj = GlobalVectorDouble(xOrig, yOrig, 0.);
82  GlobalVectorDouble xRefProj = GlobalVectorDouble(referencePoint.x(), referencePoint.y(), 0.);
83  GlobalVectorDouble deltax = xRefProj-xOrigProj-xOrig2Centre;
84  GlobalVectorDouble ndeltax = deltax.unit();
85 
87  Surface::PositionType pos(referencePoint);
88  // Need to define plane with orientation as the
89  // ImpactPointSurface
90  GlobalVector X(ndeltax.x(), ndeltax.y(), ndeltax.z());
91  GlobalVector Y(0.,0.,1.);
93  BoundPlane* plane = new BoundPlane(pos,rot);
94  // Using Teddy's HelixBarrelPlaneCrossingByCircle for general barrel planes.
95  // A large variety of other,
96  // direct solutions turned out to be not so stable numerically.
98  planeCrossing(HelixPlaneCrossing::PositionType(xOrig, yOrig, zOrig),
99  HelixPlaneCrossing::DirectionType(pxOrig, pyOrig, pzOrig),
100  kappa, direction);
101  std::pair<bool,double> propResult = planeCrossing.pathLength(*plane);
102  if ( !propResult.first ) {
103  edm::LogWarning ("TSCPBuilderNoMaterial") << "Propagation to perigee plane failed!";
104  return PairBoolFTS(false, FreeTrajectoryState() );
105  }
106  double s = propResult.second;
107  HelixPlaneCrossing::PositionType xGen = planeCrossing.position(s);
108  GlobalPoint xPerigee = GlobalPoint(xGen.x(),xGen.y(),xGen.z());
109  // direction (reconverted to GlobalVector, renormalised)
110  HelixPlaneCrossing::DirectionType pGen = planeCrossing.direction(s);
111  pGen *= pvecOrig.mag()/pGen.mag();
112  GlobalVector pPerigee = GlobalVector(pGen.x(),pGen.y(),pGen.z());
113  delete plane;
114 
115  if (originalFTS.hasError()) {
116  const AlgebraicSymMatrix55 &errorMatrix = originalFTS.curvilinearError().matrix();
117  AnalyticalCurvilinearJacobian curvilinJacobian(originalFTS.parameters(), xPerigee,
118  pPerigee, s);
119  const AlgebraicMatrix55 &jacobian = curvilinJacobian.jacobian();
120  CurvilinearTrajectoryError cte( ROOT::Math::Similarity(jacobian, errorMatrix) );
121 
122  return PairBoolFTS(true,
123  FreeTrajectoryState(GlobalTrajectoryParameters(xPerigee, pPerigee, originalFTS.charge(),
124  &(originalFTS.parameters().magneticField())), cte) );
125  }
126  else {
127  return PairBoolFTS(true,
128  FreeTrajectoryState(GlobalTrajectoryParameters(xPerigee, pPerigee, originalFTS.charge(),
129  &(originalFTS.parameters().magneticField()))) );
130  }
131 
132 }
133 
134 
137  const GlobalPoint& referencePoint) const
138 {
139 
140  GlobalPoint xvecOrig = originalFTS.position();
141  double phi = originalFTS.momentum().phi();
142  double theta = originalFTS.momentum().theta();
143  double xOrig = xvecOrig.x();
144  double yOrig = xvecOrig.y();
145  double zOrig = xvecOrig.z();
146  double xR = referencePoint.x();
147  double yR = referencePoint.y();
148 
149  double s2D = (xR - xOrig) * cos(phi) + (yR - yOrig) * sin(phi);
150  double s = s2D / sin(theta);
151  double xGen = xOrig + s2D*cos(phi);
152  double yGen = yOrig + s2D*sin(phi);
153  double zGen = zOrig + s2D/tan(theta);
154  GlobalPoint xPerigee = GlobalPoint(xGen, yGen, zGen);
155 
156  GlobalVector pPerigee = originalFTS.momentum();
157 
158  if (originalFTS.hasError()) {
159  const AlgebraicSymMatrix55 &errorMatrix = originalFTS.curvilinearError().matrix();
160  AnalyticalCurvilinearJacobian curvilinJacobian(originalFTS.parameters(), xPerigee,
161  pPerigee, s);
162  const AlgebraicMatrix55 &jacobian = curvilinJacobian.jacobian();
163  CurvilinearTrajectoryError cte( ROOT::Math::Similarity(jacobian, errorMatrix) );
164 
165  return PairBoolFTS(true,
166  FreeTrajectoryState(GlobalTrajectoryParameters(xPerigee, pPerigee, originalFTS.charge(),
167  &(originalFTS.parameters().magneticField())), cte));
168  }
169  else {
170  return PairBoolFTS(true,
171  FreeTrajectoryState(GlobalTrajectoryParameters(xPerigee, pPerigee, originalFTS.charge(),
172  &(originalFTS.parameters().magneticField()))) );
173  }
174 
175 }
virtual PositionType position(double s) const
T y() const
Cartesian y coordinate.
T x() const
Cartesian x coordinate.
virtual TrajectoryStateClosestToPoint operator()(const FTS &originalFTS, const GlobalPoint &referencePoint) const
const GlobalTrajectoryParameters & parameters() const
const AlgebraicMatrix55 & jacobian() const
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
PairBoolFTS createFTSatTransverseImpactPointCharged(const FTS &originalFTS, const GlobalPoint &referencePoint) const
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
Geom::Theta< T > theta() const
T y() const
Definition: PV3DBase.h:63
#define X(str)
Definition: MuonsGrabber.cc:48
GlobalPoint globalPosition() const
ROOT::Math::SMatrix< double, 5, 5, ROOT::Math::MatRepSym< double, 5 > > AlgebraicSymMatrix55
PropagationDirection
TrackCharge charge() const
std::pair< bool, FreeTrajectoryState > PairBoolFTS
const CurvilinearTrajectoryError & curvilinearError() const
Geom::Theta< T > theta() const
Definition: PV3DBase.h:75
GlobalVector inInverseGeV(const GlobalPoint &gp) const
Field value ad specified global point, in 1/Gev.
Definition: MagneticField.h:39
static TrajectoryStateClosestToPoint constructTSCP(const FTS &originalFTS, const GlobalPoint &referencePoint)
static bool positionEqual(const GlobalPoint &ptB, const GlobalPoint &ptA)
T mag() const
Definition: PV3DBase.h:67
T z() const
Cartesian z coordinate.
FreeTrajectoryState const * freeState(bool withErrors=true) const
T z() const
Definition: PV3DBase.h:64
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
Vector3DBase< double, GlobalTag > GlobalVectorDouble
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
GlobalVector momentum() const
virtual std::pair< bool, double > pathLength(const Plane &)
Vector3DBase unit() const
Definition: Vector3DBase.h:57
GlobalPoint position() const
double transverseCurvature() const
const AlgebraicSymMatrix55 & matrix() const
const MagneticField & magneticField() const
PairBoolFTS createFTSatTransverseImpactPointNeutral(const FTS &originalFTS, const GlobalPoint &referencePoint) const
static const G4double kappa
T x() const
Definition: PV3DBase.h:62
ROOT::Math::SMatrix< double, 5, 5, ROOT::Math::MatRepStd< double, 5, 5 > > AlgebraicMatrix55
virtual DirectionType direction(double s) const
Global3DVector GlobalVector
Definition: GlobalVector.h:10
PairBoolFTS createFTSatTransverseImpactPoint(const FTS &originalFTS, const GlobalPoint &referencePoint) const
Definition: DDAxes.h:10