| 1 | #include <TMath.h>
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| 2 | #include <TVector3.h>
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| 3 | #include <TMatrixD.h>
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| 4 | #include <TMatrixDSym.h>
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| 5 | #include <TDecompChol.h>
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| 6 | #include <TRandom.h>
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| 7 | #include <iostream>
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| 8 | #include "SolGridCov.h"
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| 9 | #include "ObsTrk.h"
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| 10 | //
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| 11 | // Constructors
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| 12 | // x(3) track origin, p(3) track momentum at origin, Q charge, B magnetic field in Tesla
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| 13 | ObsTrk::ObsTrk(TVector3 x, TVector3 p, Double_t Q, Double_t B, SolGridCov *GC)
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| 14 | {
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| 15 | fGC = GC;
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| 16 | fGenX = x;
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| 17 | fGenP = p;
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| 18 | fGenQ = Q;
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| 19 | fB = B;
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| 20 | fGenPar.ResizeTo(5);
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| 21 | fGenParACTS.ResizeTo(6);
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| 22 | fGenParILC.ResizeTo(5);
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| 23 | fObsPar.ResizeTo(5);
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| 24 | fObsParACTS.ResizeTo(6);
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| 25 | fObsParILC.ResizeTo(5);
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| 26 | fCov.ResizeTo(5, 5);
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| 27 | fCovACTS.ResizeTo(6, 6);
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| 28 | fCovILC.ResizeTo(5, 5);
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| 29 | fGenPar = XPtoPar(x,p,Q);
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| 30 | fGenParACTS = ParToACTS(fGenPar);
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| 31 | fGenParILC = ParToILC(fGenPar);
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| 32 | /*
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| 33 | std::cout << "ObsTrk::ObsTrk: fGenPar";
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| 34 | for (Int_t i = 0; i < 5; i++)std::cout << fGenPar(i) << ", ";
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| 35 | std::cout << std::endl;
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| 36 | */
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| 37 | fObsPar = GenToObsPar(fGenPar, fGC);
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| 38 | fObsParACTS = ParToACTS(fObsPar);
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| 39 | fObsParILC = ParToILC(fObsPar);
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| 40 | fObsX = ParToX(fObsPar);
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| 41 | fObsP = ParToP(fObsPar);
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| 42 | fObsQ = ParToQ(fObsPar);
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| 43 | fCovACTS = CovToACTS(fCov);
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| 44 | fCovILC = CovToILC(fCov);
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| 45 | }
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| 46 | //
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| 47 | // Destructor
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| 48 | ObsTrk::~ObsTrk()
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| 49 | {
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| 50 | fGenX.Clear();
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| 51 | fGenP.Clear();
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| 52 | fGenPar.Clear();
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| 53 | fGenParACTS.Clear();
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| 54 | fObsX.Clear();
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| 55 | fObsP.Clear();
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| 56 | fObsPar.Clear();
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| 57 | fObsParACTS.Clear();
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| 58 | fCov.Clear();
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| 59 | fCovACTS.Clear();
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| 60 | }
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| 61 | TVectorD ObsTrk::XPtoPar(TVector3 x, TVector3 p, Double_t Q)
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| 62 | {
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| 63 | //
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| 64 | TVectorD Par(5);
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| 65 | // Transverse parameters
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| 66 | Double_t a = -Q*fB*0.2998; // Units are Tesla, GeV and meters
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| 67 | Double_t pt = p.Pt();
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| 68 | Double_t C = a / (2 * pt); // Half curvature
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| 69 | //std::cout << "ObsTrk::XPtoPar: fB = " << fB << ", a = " << a << ", pt = " << pt << ", C = " << C << std::endl;
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| 70 | Double_t r2 = x.Perp2();
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| 71 | Double_t cross = x(0)*p(1) - x(1)*p(0);
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| 72 | Double_t T = TMath::Sqrt(pt*pt - 2 * a*cross + a*a*r2);
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| 73 | Double_t phi0 = TMath::ATan2((p(1) - a*x(0)) / T, (p(0) + a*x(1)) / T); // Phi0
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| 74 | Double_t D; // Impact parameter D
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| 75 | if (pt < 10.0) D = (T - pt) / a;
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| 76 | else D = (-2 * cross + a*r2) / (T + pt);
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| 77 | //
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| 78 | Par(0) = D; // Store D
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| 79 | Par(1) = phi0; // Store phi0
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| 80 | Par(2) = C; // Store C
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| 81 | //Longitudinal parameters
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| 82 | Double_t B = C*TMath::Sqrt(TMath::Max(r2 - D*D,0.0) / (1 + 2 * C*D));
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| 83 | Double_t st = TMath::ASin(B) / C;
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| 84 | Double_t ct = p(2) / pt;
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| 85 | Double_t z0 = x(2) - ct*st;
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| 86 | //
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| 87 | Par(3) = z0; // Store z0
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| 88 | Par(4) = ct; // Store cot(theta)
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| 89 | //
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| 90 | return Par;
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| 91 | }
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| 92 | //
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| 93 | TVector3 ObsTrk::ParToX(TVectorD Par)
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| 94 | {
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| 95 | Double_t D = Par(0);
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| 96 | Double_t phi0 = Par(1);
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| 97 | Double_t z0 = Par(3);
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| 98 | //
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| 99 | TVector3 Xval;
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| 100 | Xval(0) = -D*TMath::Sin(phi0);
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| 101 | Xval(1) = D*TMath::Cos(phi0);
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| 102 | Xval(2) = z0;
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| 103 | //
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| 104 | return Xval;
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| 105 | }
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| 106 | //
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| 107 | TVector3 ObsTrk::ParToP(TVectorD Par)
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| 108 | {
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| 109 | Double_t C = Par(2);
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| 110 | Double_t phi0 = Par(1);
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| 111 | Double_t ct = Par(4);
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| 112 | //
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| 113 | TVector3 Pval;
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| 114 | Double_t pt = fB*0.2998 / TMath::Abs(2 * C);
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| 115 | Pval(0) = pt*TMath::Cos(phi0);
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| 116 | Pval(1) = pt*TMath::Sin(phi0);
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| 117 | Pval(2) = pt*ct;
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| 118 | //
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| 119 | return Pval;
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| 120 | }
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| 121 | //
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| 122 |
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| 123 | Double_t ObsTrk::ParToQ(TVectorD Par)
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| 124 | {
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| 125 | return TMath::Sign(1.0, -Par(2));
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| 126 | }
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| 127 | //
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| 128 | TVectorD ObsTrk::GenToObsPar(TVectorD gPar, SolGridCov *GC)
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| 129 | {
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| 130 | TVector3 p = ParToP(gPar);
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| 131 | Double_t pt = p.Pt();
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| 132 | Double_t tanTh = 1.0 / TMath::Abs(gPar(4));
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| 133 | Double_t angd = TMath::ATan(tanTh)*180. / TMath::Pi();
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| 134 | //
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| 135 | // Check ranges
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| 136 | Double_t minPt = GC->GetMinPt ();
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| 137 | if (pt < minPt) std::cout << "Warning ObsTrk::GenToObsPar: pt " << pt << " is below grid range of " << minPt << std::endl;
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| 138 | Double_t maxPt = GC->GetMaxPt();
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| 139 | if (pt > maxPt) std::cout << "Warning ObsTrk::GenToObsPar: pt " << pt << " is above grid range of " << maxPt << std::endl;
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| 140 | Double_t minAn = GC->GetMinAng();
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| 141 | if (angd < minAn) std::cout << "Warning ObsTrk::GenToObsPar: angle " << angd
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| 142 | << " is below grid range of " << minAn << std::endl;
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| 143 | Double_t maxAn = GC->GetMaxAng();
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| 144 | if (angd > maxAn) std::cout << "Warning ObsTrk::GenToObsPar: angle " << angd
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| 145 | << " is above grid range of " << maxAn << std::endl;
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| 146 | //
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| 147 | TMatrixDSym Cov = GC->GetCov(pt, angd);
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| 148 | fCov = Cov;
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| 149 | //
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| 150 | // Now do Choleski decomposition and random number extraction, with appropriate stabilization
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| 151 | //
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| 152 | TMatrixDSym CvN = Cov;
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| 153 | TMatrixDSym DCv(5); DCv.Zero();
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| 154 | TMatrixDSym DCvInv(5); DCvInv.Zero();
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| 155 | for (Int_t id = 0; id < 5; id++)
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| 156 | {
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| 157 | Double_t dVal = TMath::Sqrt(Cov(id, id));
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| 158 | DCv (id, id) = dVal;
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| 159 | DCvInv(id, id) = 1.0 / dVal;
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| 160 | }
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| 161 | CvN.Similarity(DCvInv); // Normalize diagonal to 1
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| 162 | TDecompChol Chl(CvN);
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| 163 | Bool_t OK = Chl.Decompose(); // Choleski decomposition of normalized matrix
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| 164 | TMatrixD U = Chl.GetU(); // Get Upper triangular matrix
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| 165 | TMatrixD Ut(TMatrixD::kTransposed, U); // Transposed of U (lower triangular)
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| 166 | TVectorD r(5);
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| 167 | for (Int_t i = 0; i < 5; i++)r(i) = gRandom->Gaus(0.0, 1.0); // Array of normal random numbers
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| 168 | TVectorD oPar = gPar + DCv*(Ut*r); // Observed parameter vector
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| 169 | //
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| 170 | return oPar;
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| 171 | }
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| 172 | // Parameter conversion to ACTS format
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| 173 | TVectorD ObsTrk::ParToACTS(TVectorD Par)
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| 174 | {
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| 175 | TVectorD pACTS(6); // Return vector
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| 176 | //
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| 177 | Double_t b = -0.29988*fB / 2.;
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| 178 | pACTS(0) = 1000*Par(0); // D from m to mm
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| 179 | pACTS(1) = 1000 * Par(3); // z0 from m to mm
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| 180 | pACTS(2) = Par(1); // Phi0 is unchanged
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| 181 | pACTS(3) = TMath::ATan(1.0 / Par(4)) + TMath::PiOver2(); // Theta in [0, pi] range
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| 182 | pACTS(4) = Par(2) / (b*TMath::Sqrt(1 + Par(4)*Par(4))); // q/p in GeV
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| 183 | pACTS(5) = 0.0; // Time: currently undefined
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| 184 | //
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| 185 | return pACTS;
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| 186 | }
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| 187 | // Covariance conversion to ACTS format
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| 188 | TMatrixDSym ObsTrk::CovToACTS(TMatrixDSym Cov)
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| 189 | {
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| 190 | TMatrixDSym cACTS(6); cACTS.Zero();
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| 191 | Double_t b = -0.29988*fB / 2.;
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| 192 | //
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| 193 | // Fill derivative matrix
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| 194 | TMatrixD A(5, 5); A.Zero();
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| 195 | Double_t ct = fGenPar(4); // cot(theta)
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| 196 | Double_t C = fGenPar(2); // half curvature
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| 197 | A(0, 0) = 1000.; // D-D conversion to mm
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| 198 | A(1, 2) = 1.0; // phi0-phi0
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| 199 | A(2, 4) = 1.0/(TMath::Sqrt(1.0 + ct*ct) * b); // q/p-C
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| 200 | A(3, 1) = 1000.; // z0-z0 conversion to mm
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| 201 | A(4, 3) = -1.0 / (1.0 + ct*ct); // theta - cot(theta)
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| 202 | A(4, 4) = -C*ct / (b*pow(1.0 + ct*ct,3.0/2.0)); // q/p-cot(theta)
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| 203 | //
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| 204 | TMatrixDSym Cv = Cov;
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| 205 | TMatrixD At(5, 5);
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| 206 | At.Transpose(A);
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| 207 | Cv.Similarity(At);
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| 208 | TMatrixDSub(cACTS, 0, 4, 0, 4) = Cv;
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| 209 | cACTS(5, 5) = 0.1; // Currently undefined: set to arbitrary value to avoid crashes
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| 210 | //
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| 211 | return cACTS;
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| 212 | }
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| 213 |
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| 214 | // Parameter conversion to ILC format
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| 215 | TVectorD ObsTrk::ParToILC(TVectorD Par)
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| 216 | {
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| 217 | TVectorD pILC(5); // Return vector
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| 218 | //
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| 219 | pILC(0) = Par(0)*1.0e3; // d0 in mm
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| 220 | pILC(1) = Par(1); // phi0 is unchanged
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| 221 | pILC(2) = -2 * Par(2)*1.0e-3; // w in mm^-1
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| 222 | pILC(3) = Par(3)*1.0e3; // z0 in mm
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| 223 | pILC(4) = Par(4); // tan(lambda) = cot(theta)
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| 224 | //
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| 225 | return pILC;
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| 226 | }
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| 227 | // Covariance conversion to ILC format
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| 228 | TMatrixDSym ObsTrk::CovToILC(TMatrixDSym Cov)
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| 229 | {
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| 230 | TMatrixDSym cILC(5); cILC.Zero();
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| 231 | //
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| 232 | // Fill derivative matrix
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| 233 | TMatrixD A(5, 5); A.Zero();
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| 234 | //
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| 235 | A(0, 0) = 1.0e3; // D-d0 in mm
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| 236 | A(1, 1) = 1.0; // phi0-phi0
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| 237 | A(2, 2) = -2.0e-3; // w-C
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| 238 | A(3, 3) = 1.0e3; // z0-z0 conversion to mm
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| 239 | A(4, 4) = 1.0; // tan(lambda) - cot(theta)
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| 240 | //
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| 241 | TMatrixDSym Cv = Cov;
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| 242 | TMatrixD At(5, 5);
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| 243 | At.Transpose(A);
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| 244 | Cv.Similarity(At);
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| 245 | cILC = Cv;
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| 246 | //
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| 247 | return cILC;
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| 248 | }
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| 249 |
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| 250 |
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| 251 |
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| 252 |
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