PatternTools/interface/ClosestApproachInRPhi.h

#ifndef _ClosestApproachInRPhi_H_
#define _ClosestApproachInRPhi_H_

#include "TrackingTools/PatternTools/interface/ClosestApproachOnHelices.h"
#include "TrackingTools/TrajectoryState/interface/FreeTrajectoryState.h" 

/** 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; 
 *                - circles do not cross; the points used are 
 *                  the points of closest approach of the two circles. 
 *  2) computes the corresponding z-coordinates. In the case where 
 *     the circles have two intersections, the point for which 
 *     the z-coordinates on the 2 tracks are the closest is chosen. 
 */

class ClosestApproachInRPhi : public ClosestApproachOnHelices {

public:

  ClosestApproachInRPhi() {status_ = false;}

  virtual bool calculate(const TrajectoryStateOnSurface & sta, 
                         const TrajectoryStateOnSurface & stb);

  virtual bool calculate(const FreeTrajectoryState & sta,
                         const FreeTrajectoryState & stb);

  virtual bool status() const {return status_;}

  /**
   * Returns the two PCA on the trajectories.
   */
  virtual std::pair<GlobalPoint, GlobalPoint> points() const;

  /** Returns not only the points, but the full GlobalTrajectoryParemeters 
   *  at the points of closest approach */
  std::pair <GlobalTrajectoryParameters, GlobalTrajectoryParameters >
  trajectoryParameters () const;

  /** arithmetic mean of the two points of closest approach */
  virtual GlobalPoint crossingPoint() const;

  /** distance between the two points of closest approach in 3D */
  virtual float distance() const;

  /**
   *  Clone method
   */
  virtual ClosestApproachInRPhi * clone() const {
    return new ClosestApproachInRPhi(* this);
  }

private:

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

  // given the old Parameters, and a new GlobalPoint,
  // we return the full new GlobalTrajectoryParameters at the
  // Point.
  static GlobalTrajectoryParameters
  newTrajectory( const GlobalPoint & newpt,
                 const GlobalTrajectoryParameters & oldpar, double bz);

  // Computes center coordinates and unsigned radius of circle;
  static void circleParameters(const TrackCharge& charge, 
                               const GlobalVector& momemtum, 
                               const GlobalPoint& position, 
                               double& xc, double& yc, double& r,
                               double bz);

  // Computes crossing points of 2 circles with centres (cx_i, cy_i) 
  // and unsigned radii r_i. 
  // Two cases: - circles have one or two intersection points; 
  //              return value = 1; 
  //            - circles do not cross; computes point of closest approach 
  //              on each circle; return value = 2;
  // if the calculation fails (e.g. concentric circles), return value = 0;

  static int transverseCoord(double cxa, double cya, double ra, 
                             double cxb, double cyb, double rb, 
                             double & xg1, double & yg1, 
                             double & xg2, double & yg2);

  // Computes z-coordinate on helix at given transverse coordinates
  static double zCoord(const GlobalVector& mom, const GlobalPoint& pos, 
                       double r, double xc, double yc, double xg, double yg);


private:
  GlobalPoint posA, posB;
  GlobalTrajectoryParameters paramA, paramB;
  double bz;
  bool status_;
  
};

#endif
Revision:	1.1
Committed:	Fri Nov 25 16:38:23 2011 UTC (13 years, 5 months ago) by econte
Content type:	text/plain
Branch:	MAIN
CVS Tags:	TBD2011, TBD_2011, HEAD
Log Message:	new IPHC alignment
#	User	Rev	Content
1	econte	1.1	#ifndef _ClosestApproachInRPhi_H_
2			#define _ClosestApproachInRPhi_H_
3
4			#include "TrackingTools/PatternTools/interface/ClosestApproachOnHelices.h"
5			#include "TrackingTools/TrajectoryState/interface/FreeTrajectoryState.h"
6
7			/** Given two trajectory states, computes the two points of closest approach
8			* in the transverse plane for the helices extrapolated from these states.
9			* 1) computes the intersections of the circles in transverse plane.
10			* Two cases: - circles have one or two intersection points;
11			* - circles do not cross; the points used are
12			* the points of closest approach of the two circles.
13			* 2) computes the corresponding z-coordinates. In the case where
14			* the circles have two intersections, the point for which
15			* the z-coordinates on the 2 tracks are the closest is chosen.
16			*/
17
18			class ClosestApproachInRPhi : public ClosestApproachOnHelices {
19
20			public:
21
22			ClosestApproachInRPhi() {status_ = false;}
23
24			virtual bool calculate(const TrajectoryStateOnSurface & sta,
25			const TrajectoryStateOnSurface & stb);
26
27			virtual bool calculate(const FreeTrajectoryState & sta,
28			const FreeTrajectoryState & stb);
29
30			virtual bool status() const {return status_;}
31
32			/**
33			* Returns the two PCA on the trajectories.
34			*/
35			virtual std::pair<GlobalPoint, GlobalPoint> points() const;
36
37			/** Returns not only the points, but the full GlobalTrajectoryParemeters
38			* at the points of closest approach */
39			std::pair <GlobalTrajectoryParameters, GlobalTrajectoryParameters >
40			trajectoryParameters () const;
41
42			/** arithmetic mean of the two points of closest approach */
43			virtual GlobalPoint crossingPoint() const;
44
45			/** distance between the two points of closest approach in 3D */
46			virtual float distance() const;
47
48			/**
49			* Clone method
50			*/
51			virtual ClosestApproachInRPhi * clone() const {
52			return new ClosestApproachInRPhi(* this);
53			}
54
55			private:
56
57			bool compute(const TrackCharge & chargeA,
58			const GlobalVector & momentumA,
59			const GlobalPoint & positionA,
60			const TrackCharge & chargeB,
61			const GlobalVector & momentumB,
62			const GlobalPoint & positionB);
63
64			// given the old Parameters, and a new GlobalPoint,
65			// we return the full new GlobalTrajectoryParameters at the
66			// Point.
67			static GlobalTrajectoryParameters
68			newTrajectory( const GlobalPoint & newpt,
69			const GlobalTrajectoryParameters & oldpar, double bz);
70
71			// Computes center coordinates and unsigned radius of circle;
72			static void circleParameters(const TrackCharge& charge,
73			const GlobalVector& momemtum,
74			const GlobalPoint& position,
75			double& xc, double& yc, double& r,
76			double bz);
77
78			// Computes crossing points of 2 circles with centres (cx_i, cy_i)
79			// and unsigned radii r_i.
80			// Two cases: - circles have one or two intersection points;
81			// return value = 1;
82			// - circles do not cross; computes point of closest approach
83			// on each circle; return value = 2;
84			// if the calculation fails (e.g. concentric circles), return value = 0;
85
86			static int transverseCoord(double cxa, double cya, double ra,
87			double cxb, double cyb, double rb,
88			double & xg1, double & yg1,
89			double & xg2, double & yg2);
90
91			// Computes z-coordinate on helix at given transverse coordinates
92			static double zCoord(const GlobalVector& mom, const GlobalPoint& pos,
93			double r, double xc, double yc, double xg, double yg);
94
95
96			private:
97			GlobalPoint posA, posB;
98			GlobalTrajectoryParameters paramA, paramB;
99			double bz;
100			bool status_;
101
102			};
103
104			#endif