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ClosestApproachInRPhi.cc
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5 
6 using namespace std;
7 
9  const TrajectoryStateOnSurface & stb)
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 }
24 
25 
27  const FreeTrajectoryState & stb)
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 }
42 
43 pair<GlobalPoint, GlobalPoint> ClosestApproachInRPhi::points() const
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 }
49 
50 
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 }
59 
60 
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 }
67 
68 
70  const GlobalVector & momentumA,
71  const GlobalPoint & positionA,
72  const TrackCharge & chargeB,
73  const GlobalVector & momentumB,
74  const GlobalPoint & positionB)
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 }
123 
124 pair <GlobalTrajectoryParameters, GlobalTrajectoryParameters>
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>
130  ret ( newTrajectory( posA, paramA, bz),
131  newTrajectory( posB, paramB, bz) );
132  return ret;
133 }
134 
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 }
172 
173 void
175  const GlobalVector& momentum,
176  const GlobalPoint& position,
177  double& xc, double& yc, double& r,
178  double bz)
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 }
202 
203 
204 int
205 ClosestApproachInRPhi::transverseCoord(double cxa, double cya, double ra,
206  double cxb, double cyb, double rb,
207  double & xg1, double & yg1,
208  double & xg2, double & yg2)
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 }
269 
270 
271 double
273  const GlobalPoint& pos,
274  double r, double xc, double yc,
275  double xg, double yg)
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 }
std::pair< GlobalTrajectoryParameters, GlobalTrajectoryParameters > trajectoryParameters() const
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)
const GlobalTrajectoryParameters & parameters() const
virtual GlobalVector inTesla(const GlobalPoint &gp) const =0
Field value ad specified global point, in Tesla.
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
T y() const
Definition: PV3DBase.h:63
GlobalPoint globalPosition() const
TrackCharge charge() const
double charge(const std::vector< uint8_t > &Ampls)
float float float z
virtual GlobalPoint crossingPoint() const
T transverse() const
Definition: PV3DBase.h:73
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
virtual std::pair< GlobalPoint, GlobalPoint > points() const
T sqrt(T t)
Definition: SSEVec.h:48
FreeTrajectoryState const * freeState(bool withErrors=true) const
T z() const
Definition: PV3DBase.h:64
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)
GlobalVector momentum() const
GlobalPoint position() const
virtual bool calculate(const TrajectoryStateOnSurface &sta, const TrajectoryStateOnSurface &stb)
const GlobalTrajectoryParameters & globalParameters() const
static GlobalTrajectoryParameters newTrajectory(const GlobalPoint &newpt, const GlobalTrajectoryParameters &oldpar, double bz)
GlobalVector globalMomentum() const
static int position[264][3]
Definition: ReadPGInfo.cc:509
const MagneticField & magneticField() const
Definition: DDAxes.h:10
virtual float distance() const
T x() const
Definition: PV3DBase.h:62
Definition: DDAxes.h:10