source: git/external/TrackCovariance/SolTrack.h@ 3a105e5

//
#ifndef G__SOLTRK_H
#define G__SOLTRK_H
//
#include <TMath.h>
#include <TVector3.h>
#include <TMatrixDSym.h>
#include "SolGeom.h"
#include "TrkUtil.h"
#include <TGraph.h>
//
//
// Class to store track information
// Assumes that the geometry has been initialized
//
class SolTrack: public TrkUtil
{
        // 
        // Track handling class
        // Assume tracks originate from (0,0) for the time being
        //
private:
        Int_t fNl;      // Actual number of layers
        SolGeom *fG;    // Geometry
        Double_t fp[3]; // px, py, pz momentum 
        Double_t fx[3]; //  x,  y,  z track origin 
        Double_t fpar[5];       // D, phi0, C, z0, cot(theta)
        //
        TMatrixDSym fCov;               // Full covariance matrix
        //
        //
public:
        //
        // Constructors
        SolTrack(Double_t *x, Double_t *p, SolGeom *G);
        SolTrack(TVector3 x, TVector3 p, SolGeom* G);
        SolTrack(Double_t D, Double_t phi0, Double_t C, Double_t z0, Double_t ct, SolGeom *G);
        // Destructor
        ~SolTrack();
        // Accessors
        // Position (at minimum approach)
        Double_t x() { return fx[0]; }
        Double_t y() { return fx[1]; }
        Double_t z() { return fx[2]; }
        // Momentum  (at minimum approach)
        Double_t px() { return fp[0]; }
        Double_t py() { return fp[1]; }
        Double_t pz() { return fp[2]; }
        Double_t pt() { return TMath::Sqrt(fp[0] * fp[0] + fp[1] * fp[1]); }
        Double_t p()  { return TMath::Sqrt(fp[0] * fp[0] + fp[1] * fp[1] + fp[2] * fp[2]); }
        // Track parameters
        Double_t D()    { return fpar[0]; }
        Double_t phi0() { return fpar[1]; }
        Double_t C()    { return fpar[2]; }
        Double_t z0()   { return fpar[3]; }
        Double_t ct()   { return fpar[4]; }
        // Covariance
        TMatrixDSym Cov()               { return fCov; }
        // Track parameter covariance calculation
        void CovCalc(Bool_t Res, Bool_t MS);
        // Parameter errors
        Double_t s_D()    { return TMath::Sqrt(fCov(0, 0)); }
        Double_t s_phi0() { return TMath::Sqrt(fCov(1, 1)); }
        Double_t s_C()    { return TMath::Sqrt(fCov(2, 2)); }
        Double_t s_pt()   { return 2 * s_C()*pt() / (0.2998*fG->B()); } // Dpt/pt
        Double_t s_z0()   { return TMath::Sqrt(fCov(3, 3)); }
        Double_t s_ct()   { return TMath::Sqrt(fCov(4, 4)); }
        //
        // Track hit management
        Int_t nHit();
        Int_t nmHit();
        Bool_t HitLayer(Int_t Layer, Double_t &R, Double_t &phi, Double_t &zz);
        Int_t HitList(Int_t *&ihh, Double_t *&rhh, Double_t *&zhh);
        Int_t HitListXYZ(Int_t *&ihh, Double_t *&Xh, Double_t *&Yh, Double_t *&Zh);
        Int_t FirstHit(Double_t &Xfirst, Double_t &Yfirst, Double_t &Zfirst);   // First hit position
        //
        // Track graph
        TGraph *TrkPlot();      // Graph with R-z plot of track trajectory
        //
        // Make normalized matrix positive definite
        TMatrixDSym MakePosDef(TMatrixDSym NormMat);
};
//
#endif