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ClosestApproachInRPhi Class Reference

#include <ClosestApproachInRPhi.h>

Inheritance diagram for ClosestApproachInRPhi:
ClosestApproachOnHelices

Public Member Functions

virtual bool calculate (const TrajectoryStateOnSurface &sta, const TrajectoryStateOnSurface &stb)
 
virtual bool calculate (const FreeTrajectoryState &sta, const FreeTrajectoryState &stb)
 
virtual ClosestApproachInRPhiclone () const
 
 ClosestApproachInRPhi ()
 
virtual GlobalPoint crossingPoint () const
 
virtual float distance () const
 
virtual std::pair< GlobalPoint,
GlobalPoint
points () const
 
virtual bool status () const
 
std::pair
< GlobalTrajectoryParameters,
GlobalTrajectoryParameters
trajectoryParameters () const
 
 ~ClosestApproachInRPhi ()
 
- Public Member Functions inherited from ClosestApproachOnHelices
 ClosestApproachOnHelices ()
 
virtual ~ClosestApproachOnHelices ()
 

Private Member Functions

bool compute (const TrackCharge &chargeA, const GlobalVector &momentumA, const GlobalPoint &positionA, const TrackCharge &chargeB, const GlobalVector &momentumB, const GlobalPoint &positionB)
 

Static Private Member Functions

static void circleParameters (const TrackCharge &charge, const GlobalVector &momemtum, const GlobalPoint &position, double &xc, double &yc, double &r, double bz)
 
static GlobalTrajectoryParameters newTrajectory (const GlobalPoint &newpt, const GlobalTrajectoryParameters &oldpar, double bz)
 
static int transverseCoord (double cxa, double cya, double ra, double cxb, double cyb, double rb, double &xg1, double &yg1, double &xg2, double &yg2)
 
static double zCoord (const GlobalVector &mom, const GlobalPoint &pos, double r, double xc, double yc, double xg, double yg)
 

Private Attributes

double bz
 
GlobalTrajectoryParameters paramA
 
GlobalTrajectoryParameters paramB
 
GlobalPoint posA
 
GlobalPoint posB
 
bool status_
 

Detailed Description

Given two trajectory states, computes the two points of closest approach in the transverse plane for the helices extrapolated from these states. 1) computes the intersections of the circles in transverse plane. Two cases: - circles have one or two intersection points;

Definition at line 18 of file ClosestApproachInRPhi.h.

Constructor & Destructor Documentation

ClosestApproachInRPhi::ClosestApproachInRPhi ( )
inline

Definition at line 22 of file ClosestApproachInRPhi.h.

References status_.

Referenced by clone().

ClosestApproachInRPhi::~ClosestApproachInRPhi ( )
inline

Definition at line 23 of file ClosestApproachInRPhi.h.

23 {}

Member Function Documentation

bool ClosestApproachInRPhi::calculate ( const TrajectoryStateOnSurface sta,
const TrajectoryStateOnSurface stb 
)
virtual

Implements ClosestApproachOnHelices.

Definition at line 8 of file ClosestApproachInRPhi.cc.

References TrajectoryStateOnSurface::charge(), bookConverter::compute(), TrajectoryStateOnSurface::freeState(), TrajectoryStateOnSurface::globalMomentum(), TrajectoryStateOnSurface::globalParameters(), TrajectoryStateOnSurface::globalPosition(), MagneticField::inTesla(), GlobalTrajectoryParameters::magneticField(), FreeTrajectoryState::parameters(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by HLTMuon::analyze(), NuclearVertexBuilder::closestApproach(), V0Fitter::fitAll(), HLTDiMuonGlbTrkFilter::hltFilter(), HLTMuonTrackMassFilter::hltFilter(), HLTMuonDimuonL3Filter::hltFilter(), HLTMuonTrimuonL3Filter::hltFilter(), and ConversionProducer::preselectTrackPair().

10 {
11  TrackCharge chargeA = sta.charge(); TrackCharge chargeB = stb.charge();
12  GlobalVector momentumA = sta.globalMomentum();
13  GlobalVector momentumB = stb.globalMomentum();
14  GlobalPoint positionA = sta.globalPosition();
15  GlobalPoint positionB = stb.globalPosition();
16  paramA = sta.globalParameters();
17  paramB = stb.globalParameters();
18  // compute magnetic field ONCE
19  bz = sta.freeState()->parameters().magneticField().inTesla(positionA).z() * 2.99792458e-3;
20 
21  return compute(chargeA, momentumA, positionA, chargeB, momentumB, positionB);
22 
23 }
const GlobalTrajectoryParameters & parameters() const
GlobalTrajectoryParameters paramB
virtual GlobalVector inTesla(const GlobalPoint &gp) const =0
Field value ad specified global point, in Tesla.
GlobalPoint globalPosition() const
GlobalTrajectoryParameters paramA
bool compute(const TrackCharge &chargeA, const GlobalVector &momentumA, const GlobalPoint &positionA, const TrackCharge &chargeB, const GlobalVector &momentumB, const GlobalPoint &positionB)
int TrackCharge
Definition: TrackCharge.h:4
FreeTrajectoryState const * freeState(bool withErrors=true) const
T z() const
Definition: PV3DBase.h:64
const GlobalTrajectoryParameters & globalParameters() const
GlobalVector globalMomentum() const
const MagneticField & magneticField() const
bool ClosestApproachInRPhi::calculate ( const FreeTrajectoryState sta,
const FreeTrajectoryState stb 
)
virtual

Implements ClosestApproachOnHelices.

Definition at line 26 of file ClosestApproachInRPhi.cc.

References FreeTrajectoryState::charge(), bookConverter::compute(), MagneticField::inTesla(), GlobalTrajectoryParameters::magneticField(), FreeTrajectoryState::momentum(), FreeTrajectoryState::parameters(), FreeTrajectoryState::position(), and PV3DBase< T, PVType, FrameType >::z().

28 {
29  TrackCharge chargeA = sta.charge(); TrackCharge chargeB = stb.charge();
30  GlobalVector momentumA = sta.momentum();
31  GlobalVector momentumB = stb.momentum();
32  GlobalPoint positionA = sta.position();
33  GlobalPoint positionB = stb.position();
34  paramA = sta.parameters();
35  paramB = stb.parameters();
36  // compute magnetic field ONCE
37  bz = sta.parameters().magneticField().inTesla(positionA).z() * 2.99792458e-3;
38 
39  return compute(chargeA, momentumA, positionA, chargeB, momentumB, positionB);
40 
41 }
const GlobalTrajectoryParameters & parameters() const
GlobalTrajectoryParameters paramB
virtual GlobalVector inTesla(const GlobalPoint &gp) const =0
Field value ad specified global point, in Tesla.
TrackCharge charge() const
GlobalTrajectoryParameters paramA
bool compute(const TrackCharge &chargeA, const GlobalVector &momentumA, const GlobalPoint &positionA, const TrackCharge &chargeB, const GlobalVector &momentumB, const GlobalPoint &positionB)
int TrackCharge
Definition: TrackCharge.h:4
T z() const
Definition: PV3DBase.h:64
GlobalVector momentum() const
GlobalPoint position() const
const MagneticField & magneticField() const
void ClosestApproachInRPhi::circleParameters ( const TrackCharge charge,
const GlobalVector momemtum,
const GlobalPoint position,
double &  xc,
double &  yc,
double &  r,
double  bz 
)
staticprivate

temporary code, to be replaced by call to curvature() when bug is fixed.

end of temporary code

Definition at line 174 of file ClosestApproachInRPhi.cc.

References funct::abs(), PV3DBase< T, PVType, FrameType >::transverse(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

179 {
180 
181  // compute radius of circle
185 // double bz = MagneticField::inInverseGeV(position).z();
186 
187  // signed_r directed towards circle center, along F_Lorentz = q*v X B
188  double qob = charge/bz;
189  double signed_r = qob*momentum.transverse();
190  r = abs(signed_r);
194  // compute centre of circle
195  // double phi = momentum.phi();
196  // xc = signed_r*sin(phi) + position.x();
197  // yc = -signed_r*cos(phi) + position.y();
198  xc = position.x() + qob * momentum.y();
199  yc = position.y() - qob * momentum.x();
200 
201 }
T y() const
Definition: PV3DBase.h:63
double charge(const std::vector< uint8_t > &Ampls)
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
T x() const
Definition: PV3DBase.h:62
virtual ClosestApproachInRPhi* ClosestApproachInRPhi::clone ( void  ) const
inlinevirtual

Clone method

Implements ClosestApproachOnHelices.

Definition at line 52 of file ClosestApproachInRPhi.h.

References ClosestApproachInRPhi().

52  {
53  return new ClosestApproachInRPhi(* this);
54  }
bool ClosestApproachInRPhi::compute ( const TrackCharge chargeA,
const GlobalVector momentumA,
const GlobalPoint positionA,
const TrackCharge chargeB,
const GlobalVector momentumB,
const GlobalPoint positionB 
)
private

Definition at line 69 of file ClosestApproachInRPhi.cc.

References funct::abs(), and archive::flag.

75 {
76 
77 
78  // centres and radii of track circles
79  double xca, yca, ra;
80  circleParameters(chargeA, momentumA, positionA, xca, yca, ra, bz);
81  double xcb, ycb, rb;
82  circleParameters(chargeB, momentumB, positionB, xcb, ycb, rb, bz);
83 
84  // points of closest approach in transverse plane
85  double xg1, yg1, xg2, yg2;
86  int flag = transverseCoord(xca, yca, ra, xcb, ycb, rb, xg1, yg1, xg2, yg2);
87  if (flag == 0) {
88  status_ = false;
89  return false;
90  }
91 
92  double xga, yga, zga, xgb, ygb, zgb;
93 
94  if (flag == 1) {
95  // two crossing points on each track in transverse plane
96  // select point for which z-coordinates on the 2 tracks are the closest
97  double za1 = zCoord(momentumA, positionA, ra, xca, yca, xg1, yg1);
98  double zb1 = zCoord(momentumB, positionB, rb, xcb, ycb, xg1, yg1);
99  double za2 = zCoord(momentumA, positionA, ra, xca, yca, xg2, yg2);
100  double zb2 = zCoord(momentumB, positionB, rb, xcb, ycb, xg2, yg2);
101 
102  if (abs(zb1 - za1) < abs(zb2 - za2)) {
103  xga = xg1; yga = yg1; zga = za1; zgb = zb1;
104  }
105  else {
106  xga = xg2; yga = yg2; zga = za2; zgb = zb2;
107  }
108  xgb = xga; ygb = yga;
109  }
110  else {
111  // one point of closest approach on each track in transverse plane
112  xga = xg1; yga = yg1;
113  zga = zCoord(momentumA, positionA, ra, xca, yca, xga, yga);
114  xgb = xg2; ygb = yg2;
115  zgb = zCoord(momentumB, positionB, rb, xcb, ycb, xgb, ygb);
116  }
117 
118  posA = GlobalPoint(xga, yga, zga);
119  posB = GlobalPoint(xgb, ygb, zgb);
120  status_ = true;
121  return true;
122 }
static int transverseCoord(double cxa, double cya, double ra, double cxb, double cyb, double rb, double &xg1, double &yg1, double &xg2, double &yg2)
static void circleParameters(const TrackCharge &charge, const GlobalVector &momemtum, const GlobalPoint &position, double &xc, double &yc, double &r, double bz)
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
static double zCoord(const GlobalVector &mom, const GlobalPoint &pos, double r, double xc, double yc, double xg, double yg)
GlobalPoint ClosestApproachInRPhi::crossingPoint ( ) const
virtual

arithmetic mean of the two points of closest approach

Implements ClosestApproachOnHelices.

Definition at line 52 of file ClosestApproachInRPhi.cc.

References edm::hlt::Exception.

Referenced by NuclearVertexBuilder::FillVertexWithCrossingPoint(), V0Fitter::fitAll(), NuclearVertexBuilder::isGoodSecondaryTrack(), and ConversionProducer::preselectTrackPair().

53 {
54  if (!status_)
55  throw cms::Exception("TrackingTools/PatternTools","ClosestApproachInRPhi::could not compute track crossing. Check status before calling this method!");
56  return GlobalPoint(0.5*(posA.basicVector() + posB.basicVector()));
57 
58 }
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
const BasicVectorType & basicVector() const
Definition: PV3DBase.h:56
float ClosestApproachInRPhi::distance ( ) const
virtual

distance between the two points of closest approach in 3D

Implements ClosestApproachOnHelices.

Definition at line 61 of file ClosestApproachInRPhi.cc.

References edm::hlt::Exception.

Referenced by HLTMuon::analyze(), V0Fitter::fitAll(), HLTDiMuonGlbTrkFilter::hltFilter(), HLTMuonTrackMassFilter::hltFilter(), HLTMuonDimuonL3Filter::hltFilter(), HLTMuonTrimuonL3Filter::hltFilter(), NuclearVertexBuilder::isGoodSecondaryTrack(), and print().

62 {
63  if (!status_)
64  throw cms::Exception("TrackingTools/PatternTools","ClosestApproachInRPhi::could not compute track crossing. Check status before calling this method!");
65  return (posB - posA).mag();
66 }
GlobalTrajectoryParameters ClosestApproachInRPhi::newTrajectory ( const GlobalPoint newpt,
const GlobalTrajectoryParameters oldpar,
double  bz 
)
staticprivate

Definition at line 136 of file ClosestApproachInRPhi.cc.

References GlobalTrajectoryParameters::charge(), GlobalTrajectoryParameters::magneticField(), GlobalTrajectoryParameters::momentum(), GlobalTrajectoryParameters::position(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

137 {
138  // First we need the centers of the circles.
139  double qob = oldgtp.charge()/bz;
140  double xc = oldgtp.position().x() + qob * oldgtp.momentum().y();
141  double yc = oldgtp.position().y() - qob * oldgtp.momentum().x();
142 
143  // and of course....
144  double npx = (newpt.y()-yc)*(bz/oldgtp.charge());
145  double npy = (xc-newpt.x())*(bz/oldgtp.charge());
146 
147  /*
148  * old code: slow and wrong
149  *
150  // now we do a translation, move the center of circle to (0,0,0).
151  double dx1 = oldgtp.position().x() - xc;
152  double dy1 = oldgtp.position().y() - yc;
153  double dx2 = newpt.x() - xc;
154  double dy2 = newpt.y() - yc;
155 
156  // now for the angles:
157  double cosphi = ( dx1 * dx2 + dy1 * dy2 ) /
158  ( sqrt ( dx1 * dx1 + dy1 * dy1 ) * sqrt ( dx2 * dx2 + dy2 * dy2 ));
159  double sinphi = - oldgtp.charge() * sqrt ( 1 - cosphi * cosphi );
160 
161  // Finally, the new momenta:
162  double px = cosphi * oldgtp.momentum().x() - sinphi * oldgtp.momentum().y();
163  double py = sinphi * oldgtp.momentum().x() + cosphi * oldgtp.momentum().y();
164 
165  std::cout << px-npx << " " << py-npy << ", " << oldgtp.charge() << std::endl;
166  */
167 
168  GlobalVector vta ( npx, npy, oldgtp.momentum().z() );
169  GlobalTrajectoryParameters gta( newpt , vta , oldgtp.charge(), &(oldgtp.magneticField()) );
170  return gta;
171 }
T y() const
Definition: PV3DBase.h:63
T x() const
Definition: PV3DBase.h:62
pair< GlobalPoint, GlobalPoint > ClosestApproachInRPhi::points ( ) const
virtual

Returns the two PCA on the trajectories.

Implements ClosestApproachOnHelices.

Definition at line 43 of file ClosestApproachInRPhi.cc.

References edm::hlt::Exception.

44 {
45  if (!status_)
46  throw cms::Exception("TrackingTools/PatternTools","ClosestApproachInRPhi::could not compute track crossing. Check status before calling this method!");
47  return pair<GlobalPoint, GlobalPoint> (posA, posB);
48 }
virtual bool ClosestApproachInRPhi::status ( void  ) const
inlinevirtual
pair< GlobalTrajectoryParameters, GlobalTrajectoryParameters > ClosestApproachInRPhi::trajectoryParameters ( ) const

Returns not only the points, but the full GlobalTrajectoryParemeters at the points of closest approach

Definition at line 125 of file ClosestApproachInRPhi.cc.

References edm::hlt::Exception, and run_regression::ret.

126 {
127  if (!status_)
128  throw cms::Exception("TrackingTools/PatternTools","ClosestApproachInRPhi::could not compute track crossing. Check status before calling this method!");
129  pair <GlobalTrajectoryParameters, GlobalTrajectoryParameters>
131  newTrajectory( posB, paramB, bz) );
132  return ret;
133 }
GlobalTrajectoryParameters paramB
GlobalTrajectoryParameters paramA
static GlobalTrajectoryParameters newTrajectory(const GlobalPoint &newpt, const GlobalTrajectoryParameters &oldpar, double bz)
int ClosestApproachInRPhi::transverseCoord ( double  cxa,
double  cya,
double  ra,
double  cxb,
double  cyb,
double  rb,
double &  xg1,
double &  yg1,
double &  xg2,
double &  yg2 
)
staticprivate

Definition at line 205 of file ClosestApproachInRPhi.cc.

References funct::abs(), archive::flag, mathSSE::sqrt(), and findQualityFiles::v.

209 {
210  int flag = 0;
211  double x1, y1, x2, y2;
212 
213  // new reference frame with origin in (cxa, cya) and x-axis
214  // directed from (cxa, cya) to (cxb, cyb)
215 
216  double d_ab = sqrt((cxb - cxa)*(cxb - cxa) + (cyb - cya)*(cyb - cya));
217  if (d_ab == 0) { // concentric circles
218  return 0;
219  }
220  // elements of rotation matrix
221  double u = (cxb - cxa) / d_ab;
222  double v = (cyb - cya) / d_ab;
223 
224  // conditions for circle intersection
225  if (d_ab <= ra + rb && d_ab >= abs(rb - ra)) {
226 
227  // circles cross each other
228  flag = 1;
229 
230  // triangle (ra, rb, d_ab)
231  double cosphi = (ra*ra - rb*rb + d_ab*d_ab) / (2*ra*d_ab);
232  double sinphi2 = 1. - cosphi*cosphi;
233  if (sinphi2 < 0.) { sinphi2 = 0.; cosphi = 1.; }
234 
235  // intersection points in new frame
236  double sinphi = sqrt(sinphi2);
237  x1 = ra*cosphi; y1 = ra*sinphi; x2 = x1; y2 = -y1;
238  }
239  else if (d_ab > ra + rb) {
240 
241  // circles are external to each other
242  flag = 2;
243 
244  // points of closest approach in new frame
245  // are on line between 2 centers
246  x1 = ra; y1 = 0; x2 = d_ab - rb; y2 = 0;
247  }
248  else if (d_ab < abs(rb - ra)) {
249 
250  // circles are inside each other
251  flag = 2;
252 
253  // points of closest approach in new frame are on line between 2 centers
254  // choose 2 closest points
255  double sign = 1.;
256  if (ra <= rb) sign = -1.;
257  x1 = sign*ra; y1 = 0; x2 = d_ab + sign*rb; y2 = 0;
258  }
259  else {
260  return 0;
261  }
262 
263  // intersection points in global frame, transverse plane
264  xg1 = u*x1 - v*y1 + cxa; yg1 = v*x1 + u*y1 + cya;
265  xg2 = u*x2 - v*y2 + cxa; yg2 = v*x2 + u*y2 + cya;
266 
267  return flag;
268 }
T sqrt(T t)
Definition: SSEVec.h:48
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double ClosestApproachInRPhi::zCoord ( const GlobalVector mom,
const GlobalPoint pos,
double  r,
double  xc,
double  yc,
double  xg,
double  yg 
)
staticprivate

Definition at line 272 of file ClosestApproachInRPhi.cc.

References funct::abs(), phi, alignCSCRings::r, mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::transverse(), x, PV3DBase< T, PVType, FrameType >::x(), detailsBasic3DVector::y, PV3DBase< T, PVType, FrameType >::y(), detailsBasic3DVector::z, and PV3DBase< T, PVType, FrameType >::z().

276 {
277 
278  // starting point
279  double x = pos.x(); double y = pos.y(); double z = pos.z();
280 
281  double px = mom.x(); double py = mom.y(); double pz = mom.z();
282 
283  // rotation angle phi from starting point to crossing point (absolute value)
284  // -- compute sin(phi/2) if phi smaller than pi/4,
285  // -- cos(phi) if phi larger than pi/4
286  double phi = 0.;
287  double sinHalfPhi = sqrt((x-xg)*(x-xg) + (y-yg)*(y-yg))/(2*r);
288  if (sinHalfPhi < 0.383) { // sin(pi/8)
289  phi = 2*asin(sinHalfPhi);
290  }
291  else {
292  double cosPhi = ((x-xc)*(xg-xc) + (y-yc)*(yg-yc))/(r*r);
293  if (std::abs(cosPhi) > 1) cosPhi = (cosPhi > 0 ? 1 : -1);
294  phi = abs(acos(cosPhi));
295  }
296  // -- sign of phi
297  double signPhi = ((x - xc)*(yg - yc) - (xg - xc)*(y - yc) > 0) ? 1. : -1.;
298 
299  // sign of track angular momentum
300  // if rotation is along angular momentum, delta z is along pz
301  double signOmega = ((x - xc)*py - (y - yc)*px > 0) ? 1. : -1.;
302 
303  // delta z
304  // -- |dz| = |cos(theta) * path along helix|
305  // = |cos(theta) * arc length along circle / sin(theta)|
306  double dz = signPhi*signOmega*(pz/mom.transverse())*phi*r;
307 
308  return z + dz;
309 }
T y() const
Definition: PV3DBase.h:63
float float float z
T transverse() const
Definition: PV3DBase.h:73
T sqrt(T t)
Definition: SSEVec.h:48
T z() const
Definition: PV3DBase.h:64
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
Definition: DDAxes.h:10
T x() const
Definition: PV3DBase.h:62
Definition: DDAxes.h:10

Member Data Documentation

double ClosestApproachInRPhi::bz
private

Definition at line 100 of file ClosestApproachInRPhi.h.

GlobalTrajectoryParameters ClosestApproachInRPhi::paramA
private

Definition at line 99 of file ClosestApproachInRPhi.h.

GlobalTrajectoryParameters ClosestApproachInRPhi::paramB
private

Definition at line 99 of file ClosestApproachInRPhi.h.

GlobalPoint ClosestApproachInRPhi::posA
private

Definition at line 98 of file ClosestApproachInRPhi.h.

GlobalPoint ClosestApproachInRPhi::posB
private

Definition at line 98 of file ClosestApproachInRPhi.h.

bool ClosestApproachInRPhi::status_
private

Definition at line 101 of file ClosestApproachInRPhi.h.

Referenced by ClosestApproachInRPhi(), and status().