source: git/external/TrackCovariance/SolTrack.cc@ 6f004b5

#include <iostream>

#include <TString.h>
#include <TMath.h>
#include <TMatrixD.h>
#include <TMatrixDSym.h>
#include <TDecompChol.h>
#include <TMatrixDSymEigen.h>

#include "SolGeom.h"
#include "SolTrack.h"

using namespace std;

SolTrack::SolTrack(Double_t *x, Double_t *p, SolGeom *G)
{
  fG = G;
  // Store momentum
  fp[0] = p[0]; fp[1] = p[1]; fp[2] = p[2];
  Double_t px = p[0]; Double_t py = p[1]; Double_t pz = p[2];
  fx[0] = x[0]; fx[1] = x[1]; fx[2] = x[2];
  Double_t xx = x[0]; Double_t yy = x[1]; Double_t zz = x[2];
  // Store parameters
  Double_t pt = TMath::Sqrt(px*px + py*py);
  Double_t Charge = 1.0;            // Don't worry about charge for now
  Double_t a = -Charge*G->B()*0.2998;     // Normalized speed of light
  Double_t C = a / (2 * pt);          // pt in GeV, B in Tesla, C in meters
  Double_t r2 = xx*xx + yy*yy;
  Double_t cross = xx*py - yy*px;
  Double_t T = TMath::Sqrt(pt*pt - 2 * a*cross + a*a*r2);
  Double_t phi0 = TMath::ATan2((py - a*xx) / T, (px + a*yy) / T);
  Double_t D;
  if (pt < 10.0) D = (T - pt) / a;
  else D = (-2 * cross + a*r2) / (T + pt);
  Double_t B = C*TMath::Sqrt((r2 - D*D) / (1 + 2 * C*D));
  Double_t st = TMath::ASin(B) / C;
  Double_t ct = pz / pt;
  Double_t z0 = zz - ct*st;
  fpar[0] = D;
  fpar[1] = phi0;
  fpar[2] = C;
  fpar[3] = z0;
  fpar[4] = ct;
  // Init covariances
  fCov.ResizeTo(5, 5);
}

SolTrack::SolTrack(Double_t D, Double_t phi0, Double_t C, Double_t z0, Double_t ct, SolGeom *G)
{
  fG = G;
  // Store parameters
  fpar[0] = D;
  fpar[1] = phi0;
  fpar[2] = C;
  fpar[3] = z0;
  fpar[4] = ct;
  // Store momentum
  Double_t pt = G->B()*0.2998 / TMath::Abs(2 * C);
  Double_t px = pt*TMath::Cos(phi0);
  Double_t py = pt*TMath::Sin(phi0);
  Double_t pz = pt*ct;

  fp[0] = px; fp[1] = py; fp[2] = pz;
  fx[0] = -D*TMath::Sin(phi0); fx[1] = D*TMath::Cos(phi0);  fx[2] = z0;
  // Init covariances
  fCov.ResizeTo(5, 5);
}
// Destructor
SolTrack::~SolTrack()
{
  fCov.Clear();
}
// Calculate intersection with given layer
Bool_t SolTrack::HitLayer(Int_t il, Double_t &R, Double_t &phi, Double_t &zz)
{
  Double_t Di = D();
  Double_t phi0i = phi0();
  Double_t Ci = C();
  Double_t z0i = z0();
  Double_t cti = ct();

  R = 0; phi = 0; zz = 0;

  Bool_t val = kFALSE;
  if (fG->lTyp(il) == 1)      // Cylinder: layer at constant R
  {
    R = fG->lPos(il);
    Double_t argph = (Ci*R + (1 + Ci*Di)*Di / R) / (1. + 2.*Ci*Di);
    if (TMath::Abs(argph) < 1.0)
    {
      Double_t argz = Ci*TMath::Sqrt((R*R - Di*Di) / (1 + 2 * Ci*Di));
      if (TMath::Abs(argz) < 1.0)
      {
        zz = z0i + cti*TMath::ASin(argz) / Ci;
        if (zz > fG->lxMin(il) && zz < fG->lxMax(il))
        {
          phi = phi0i + TMath::ASin(argph);
          val = kTRUE;
        }
      }
    }
  }
  else if (fG->lTyp(il) == 2)   // disk: layer at constant z
  {
    zz = fG->lPos(il);
    Double_t arg = Ci*(zz - z0i) / cti;
    if (TMath::Abs(arg) < 1.0 && (zz - z0i) / cti > 0)
    {
      R = TMath::Sqrt(Di*Di + (1. + 2.*Ci*Di)*pow(TMath::Sin(arg), 2) / (Ci*Ci));
      if (R > fG->lxMin(il) && R < fG->lxMax(il))
      {
        Double_t arg1 = (Ci*R + (1 + Ci*Di)*Di / R) / (1. + 2.*Ci*Di);
        if (TMath::Abs(arg1) < 1.0)
        {
          phi = phi0i + TMath::ASin(arg1);
          val = kTRUE;
        }
      }
    }
  }
  //
  return val;
}
// # of layers hit
Int_t SolTrack::nHit()
{
  Int_t kh = 0;
  Double_t R; Double_t phi; Double_t zz;
  for (Int_t i = 0; i < fG->Nl(); i++)
  if (HitLayer(i, R, phi, zz))kh++;

  return kh;
}
// List of layers hit with intersections
Int_t SolTrack::HitList(Int_t *&ihh, Double_t *&rhh, Double_t *&zhh)
{
  // Return lists of hits associated to a track including all scattering layers.
  // Return value is the total number of measurement hits
  // kmh = total number of measurement layers hit for given type
  // ihh = pointer to layer number
  // rhh = radius of hit
  // zhh = z of hit

  // ***** NB: double layers with stereo on lower layer not included

  Int_t kh = 0; // Number of layers hit
  Int_t kmh = 0; // Number of measurement layers of given type
  for (Int_t i = 0; i < fG->Nl(); i++)
  {
    Double_t R; Double_t phi; Double_t zz;
    if (HitLayer(i, R, phi, zz)) // Only barrel type layers
    {
      zhh[kh] = zz;
      rhh[kh] = R;
      ihh[kh] = i;
      if (fG->isMeasure(i))kmh++;
      kh++;
    }
  }

  return kmh;
}
// Covariance matrix estimation
void SolTrack::CovCalc(Bool_t Res, Bool_t MS)
{
  // Input flags:
  //        Res = .TRUE. turn on resolution effects/Use standard resolutions
  //            .FALSE. set all resolutions to 0
  //        MS  = .TRUE. include Multiple Scattering
  // Assumptions:
  // 1. Measurement layers can do one or two measurements
  // 2. On disks at constant z:
  //    - Upper side measurement is phi
  //    - Lower side measurement is R

  // Fill list of layers hit
  Int_t ntry = 0;
  Int_t ntrymax = 0;
  Int_t Nhit = nHit(); // Total number of layers hit
  Double_t *zhh = new Double_t[Nhit]; // z of hit
  Double_t *rhh = new Double_t[Nhit]; // r of hit
  Double_t *dhh = new Double_t[Nhit]; // distance of hit from origin
  Int_t    *ihh = new Int_t[Nhit];    // true index of layer
  Int_t kmh; // Number of measurement layers hit

  kmh = HitList(ihh, rhh, zhh); // hit layer list
  Int_t mTot = 0; // Total number of measurements
  for (Int_t i = 0; i < Nhit; i++)
  {
    dhh[i] = TMath::Sqrt(rhh[i] * rhh[i] + zhh[i] * zhh[i]);
    if (fG->isMeasure(ihh[i])) mTot += fG->lND(ihh[i]); // Count number of measurements
  }
  // Order hit list by increasing distance from origin
  Int_t *hord = new Int_t[Nhit]; // hit order by increasing distance from origin
  TMath::Sort(Nhit, dhh, hord, kFALSE); // Order by increasing distance from origin
  Double_t *zh = new Double_t[Nhit]; // d-ordered z of hit
  Double_t *rh = new Double_t[Nhit]; // d-ordered r of hit
  Int_t    *ih = new Int_t[Nhit];    // d-ordered true index of layer
  for (Int_t i = 0; i < Nhit; i++)
  {
    Int_t il = hord[i]; // Hit layer numbering
    zh[i] = zhh[il];
    rh[i] = rhh[il];
    ih[i] = ihh[il];
  }
  // Store interdistances and multiple scattering angles
  Double_t sn2t = 1.0 / (1 + ct()*ct()); //sin^2 theta of track
  Double_t cs2t = 1.0 - sn2t;            //cos^2 theta
  Double_t snt = TMath::Sqrt(sn2t);      // sin theta
  Double_t cst = TMath::Sqrt(cs2t);      // cos theta
  Double_t px0 = pt() * TMath::Cos(phi0()); // Momentum at minimum approach
  Double_t py0 = pt() * TMath::Sin(phi0());
  Double_t pz0 = pt() * ct();
  TMatrixDSym dik(Nhit);  dik.Zero(); // Distances between layers
  Double_t *thms = new Double_t[Nhit]; // Scattering angles/plane
  Double_t *cs = new Double_t[Nhit]; // Cosine of angle with layer normal
  for (Int_t ii = 0; ii < Nhit; ii++) // Hit layer loop
  {
    Int_t i = ih[ii]; // Get true layer number
    Double_t B = C()*TMath::Sqrt((rh[ii] * rh[ii] - D()*D()) / (1 + 2 * C()*D()));
    Double_t pxi = px0*(1-2*B*B)-2*py0*B*TMath::Sqrt(1-B*B); // Momentum at scattering layer
    Double_t pyi = py0*(1-2*B*B)+2*px0*B*TMath::Sqrt(1-B*B);
    Double_t pzi = pz0;
    Double_t ArgRp = (rh[ii]*C() + (1 + C() * D())*D() / rh[ii]) / (1 + 2 * C()*D());
    Double_t phi = phi0() + TMath::ASin(ArgRp);
    Double_t nx = TMath::Cos(phi); // Barrel layer normal
    Double_t ny = TMath::Sin(phi);
    Double_t nz = 0.0;
    if (fG->lTyp(i) == 2) // this is Z layer
    {
      nx = 0.0;
      ny = 0.0;
      nz = 1.0;
    }
    Double_t corr = (pxi*nx + pyi * ny + pzi * nz) / p();
    cs[ii] = corr;
    Double_t Rlf = fG->lTh(i) / (corr*fG->lX0(i)); // Rad. length fraction
    thms[ii] = 0.0136*TMath::Sqrt(Rlf)*(1.0 + 0.038*TMath::Log(Rlf)) / p(); // MS angle
    if (!MS)thms[ii] = 0;
    //
    for (Int_t kk = 0; kk < ii; kk++) // Fill distances between layers
    {
      Double_t Ci = C();
      dik(ii, kk) = (TMath::ASin(Ci*rh[ii])-TMath::ASin(Ci*rh[kk]))/(Ci*snt);
      dik(kk, ii) = dik(ii, kk);
    }
    // Store momentum components for resolution correction cosines
    Double_t *pRi = new Double_t[Nhit];
    pRi[ii] = TMath::Abs(pxi * TMath::Cos(phi) + pyi * TMath::Sin(phi)); // Radial component
    Double_t *pPhi = new Double_t[Nhit];
    pPhi[ii] = TMath::Abs(pxi * TMath::Sin(phi) - pyi * TMath::Cos(phi)); // Phi component
  }
  // Fill measurement covariance
  Int_t *mTl = new Int_t[mTot]; // Pointer from measurement number to true layer number
  TMatrixDSym Sm(mTot); Sm.Zero(); // Measurement covariance
  TMatrixD Rm(mTot, 5); // Derivative matrix
  Int_t im = 0;
  // Fill derivatives and error matrix with MS
  Double_t AngMax = 90.; Double_t AngMx = AngMax * TMath::Pi() / 180.;
  Double_t csMin = TMath::Cos(AngMx); // Set maximum angle wrt normal
  //
  for (Int_t ii = 0; ii < Nhit; ii++)
  {
    Int_t i = ih[ii]; // True layer number
    Int_t ityp  = fG->lTyp(i); // Layer type Barrel or Z
    Int_t nmeai = fG->lND(i); // # measurements in layer
    if (fG->isMeasure(i) && nmeai >0 && cs[ii] > csMin)
    {
      Double_t Di    = D(); // Get true track parameters
      Double_t phi0i = phi0();
      Double_t Ci    = C();
      Double_t z0i   = z0();
      Double_t cti   = ct();
      //
      Double_t Ri    = rh[ii];
      Double_t ArgRp = (Ri*Ci + (1 + Ci * Di)*Di / Ri) / (1 + 2 * Ci*Di);
      Double_t ArgRz = Ci * TMath::Sqrt((Ri*Ri - Di * Di) / (1 + 2 * Ci*Di));
      TVectorD dRphi(5); dRphi.Zero(); // R-phi derivatives @ const. R
      TVectorD dRz(5); dRz.Zero(); // z derivatives @ const. R
      // Derivative overflow protection
      Double_t dMin = 0.8;
      dRphi(0) = (1 - 2 * Ci*Ci*Ri*Ri) /
        TMath::Max(dMin,TMath::Sqrt(1 - ArgRp * ArgRp)); // D derivative
      dRphi(1) = Ri; // phi0 derivative
      dRphi(2) = Ri * Ri /
        TMath::Max(dMin,TMath::Sqrt(1 - ArgRp * ArgRp)); // C derivative
      dRphi(3) = 0.0; // z0 derivative
      dRphi(4) = 0.0; // cot(theta) derivative

      dRz(0) = -cti * Di /
        (Ri*TMath::Max(dMin,TMath::Sqrt(1 - Ci * Ci*Ri*Ri))); // D
      dRz(1) = 0.0; // Phi0
      dRz(2) = cti * (Ri*Ci / TMath::Sqrt(1-Ri*Ri*Ci*Ci) -
        TMath::ASin(Ri*Ci)) / (Ci*Ci); // C
      dRz(3) = 1.0; // Z0
      dRz(4) = TMath::ASin(ArgRz) / Ci; // Cot(theta)

      for (Int_t nmi = 0; nmi < nmeai; nmi++)
      {
        mTl[im] = i;
        Double_t stri = 0;
        Double_t sig = 0;
        if (nmi + 1 == 1) // Upper layer measurements
        {
          stri = fG->lStU(i); // Stereo angle
          Double_t csa = TMath::Cos(stri);
          Double_t ssa = TMath::Sin(stri);
          sig = fG->lSgU(i); // Resolution
          if (ityp == 1) // Barrel type layer (Measure R-phi, stereo or z at const. R)
          {
            // Almost exact solution (CD<<1, D<<R)
            Rm(im, 0) = csa * dRphi(0) - ssa * dRz(0); // D derivative
            Rm(im, 1) = csa * dRphi(1) - ssa * dRz(1); // phi0 derivative
            Rm(im, 2) = csa * dRphi(2) - ssa * dRz(2); // C derivative
            Rm(im, 3) = csa * dRphi(3) - ssa * dRz(3); // z0 derivative
            Rm(im, 4) = csa * dRphi(4) - ssa * dRz(4); // cot(theta) derivative
          }
          if (ityp == 2) // Z type layer (Measure phi at const. Z)
          {
            Rm(im, 0) = 1.0; // D derivative
            Rm(im, 1) = rh[ii]; // phi0 derivative
            Rm(im, 2) = rh[ii] * rh[ii]; // C derivative
            Rm(im, 3) = 0; // z0 derivative
            Rm(im, 4) = 0; // cot(theta) derivative
          }
        }
        if (nmi + 1 == 2) // Lower layer measurements
        {
          stri = fG->lStL(i); // Stereo angle
          Double_t csa = TMath::Cos(stri);
          Double_t ssa = TMath::Sin(stri);
          sig = fG->lSgL(i); // Resolution
          if (ityp == 1) // Barrel type layer (measure R-phi, stereo or z at const. R)
          {
            // Almost exact solution (CD<<1, D<<R)
            Rm(im, 0) = csa * dRphi(0) - ssa * dRz(0); // D derivative
            Rm(im, 1) = csa * dRphi(1) - ssa * dRz(1); // phi0 derivative
            Rm(im, 2) = csa * dRphi(2) - ssa * dRz(2); // C derivative
            Rm(im, 3) = csa * dRphi(3) - ssa * dRz(3); // z0 derivative
            Rm(im, 4) = csa * dRphi(4) - ssa * dRz(4); // cot(theta) derivative
          }
          if (ityp == 2) // Z type layer (Measure R at const. z)
          {
            Rm(im, 0) = 0; // D derivative
            Rm(im, 1) = 0; // phi0 derivative
            Rm(im, 2) = 0; // C derivative
            Rm(im, 3) = -1.0 / ct(); // z0 derivative
            Rm(im, 4) = -rh[ii] / ct(); // cot(theta) derivative
          }
        }
        // Derivative calculation completed
        // Now calculate measurement error matrix
        Int_t km = 0;
        for (Int_t kk = 0; kk <= ii; kk++)
        {
          Int_t k = ih[kk]; // True layer number
          Int_t ktyp = fG->lTyp(k); // Layer type Barrel or
          Int_t nmeak = fG->lND(k); // # measurements in layer
          if (fG->isMeasure(k) && nmeak > 0 &&cs[kk] > csMin)
          {
            for (Int_t nmk = 0; nmk < nmeak; nmk++)
            {
              Double_t strk = 0;
              if (nmk + 1 == 1) strk = fG->lStU(k); // Stereo angle
              if (nmk + 1 == 2) strk = fG->lStL(k); // Stereo angle
              if (im == km && Res) Sm(im, km) += sig*sig; // Detector resolution on diagonal
              //
              // Loop on all layers below for MS contributions
              for (Int_t jj = 0; jj < kk; jj++)
              {
                Double_t di = dik(ii, jj);
                Double_t dk = dik(kk, jj);
                Double_t ms = thms[jj];
                Double_t msk = ms; Double_t msi = ms;
                if (ityp == 1) msi = ms / snt; // Barrel
                else if (ityp == 2) msi = ms / cst; // Disk
                if (ktyp == 1) msk = ms / snt; // Barrel
                else if (ktyp == 2) msk = ms / cst; // Disk
                Double_t ci = TMath::Cos(stri); Double_t si = TMath::Sin(stri);
                Double_t ck = TMath::Cos(strk); Double_t sk = TMath::Sin(strk);
                Sm(im, km) += di*dk*(ci*ck*ms*ms + si*sk*msi*msk); // Ms contribution
              }
              Sm(km, im) = Sm(im, km);
              km++;
            }
          }
        }
        im++; mTot = im;
      }
    }
  }
  Sm.ResizeTo(mTot, mTot);
  Rm.ResizeTo(mTot, 5);

  // Calculate covariance from derivatives and measurement error matrix
  TMatrixDSym DSmInv(mTot); DSmInv.Zero();
  for (Int_t id = 0; id < mTot; id++) DSmInv(id, id) = 1.0 / TMath::Sqrt(Sm(id, id));
  TMatrixDSym SmN = Sm.Similarity(DSmInv);  // Normalize diagonal to 1
  // Protected matrix inversions
  TDecompChol Chl(SmN);
  TMatrixDSym SmNinv = SmN;
  if (Chl.Decompose())
  {
    Bool_t OK;
    SmNinv = Chl.Invert(OK);
  }
  else
  {
    cout << "SolTrack::CovCalc: Error matrix not positive definite. Recovering ...." << endl;
    if (ntry < ntrymax)
    {
      SmNinv.Print();
      ntry++;
    }
    TMatrixDSym rSmN = MakePosDef(SmN); SmN = rSmN;
    TDecompChol rChl(SmN);
    SmNinv = SmN;
    Bool_t OK = rChl.Decompose();
    SmNinv    = rChl.Invert(OK);
  }
  Sm = SmNinv.Similarity(DSmInv); // Error matrix inverted
  TMatrixDSym H = Sm.SimilarityT(Rm); // Calculate half Hessian
  // Normalize before inversion
  const Int_t Npar = 5;
  TMatrixDSym DHinv(Npar); DHinv.Zero();
  for (Int_t i = 0; i < Npar; i++)DHinv(i, i) = 1.0 / TMath::Sqrt(H(i, i));
  TMatrixDSym Hnrm = H.Similarity(DHinv);
  // Invert and restore
  Hnrm.Invert();
  fCov = Hnrm.Similarity(DHinv);
}

// Force positive definitness in normalized matrix
TMatrixDSym SolTrack::MakePosDef(TMatrixDSym NormMat)
{
  // Input: symmetric matrix with 1's on diagonal
  // Output: positive definite matrix with 1's on diagonal

  // Default return value
  TMatrixDSym rMatN = NormMat;
  // Check the diagonal
  Bool_t Check = kFALSE;
  Int_t Size = NormMat.GetNcols();
  for (Int_t i = 0; i < Size; i++)if (TMath::Abs(NormMat(i, i) - 1.0)>1.0E-15)Check = kTRUE;
  if (Check)
  {
    cout << "SolTrack::MakePosDef: input matrix doesn't have 1 on diagonal. Abort." << endl;
    return rMatN;
  }
  // Diagonalize matrix
  TMatrixDSymEigen Eign(NormMat);
  TMatrixD U = Eign.GetEigenVectors();
  TVectorD lambda = Eign.GetEigenValues();
  // Reset negative eigenvalues to small positive value
  TMatrixDSym D(Size); D.Zero(); Double_t eps = 1.0e-13;
  for (Int_t i = 0; i < Size; i++)
  {
    D(i, i) = lambda(i);
    if (lambda(i) <= 0) D(i, i) = eps;
  }
  // Rebuild matrix
  TMatrixD Ut(TMatrixD::kTransposed, U);
  TMatrixD rMat = (U*D)*Ut;       // Now it is positive defite
  // Restore all ones on diagonal
  for (Int_t i1 = 0; i1 < Size; i1++)
  {
    Double_t rn1 = TMath::Sqrt(rMat(i1, i1));
    for (Int_t i2 = 0; i2 <= i1; i2++)
    {
      Double_t rn2 = TMath::Sqrt(rMat(i2, i2));
      rMatN(i1, i2) = 0.5*(rMat(i1, i2) + rMat(i2, i1)) / (rn1*rn2);
      rMatN(i2, i1) = rMatN(i1, i2);
    }
  }
  return rMatN;
}