#include <TMath.h>
#include "AliCluster.h"
-#include "AliTracker.h"
-#include "AliESDtrack.h"
+#include "AliESDVertex.h"
+#include "AliITSReconstructor.h"
#include "AliITStrackV2.h"
+#include "AliTracker.h"
const Int_t AliITStrackV2::fgkWARN = 5;
//____________________________________________________________________________
AliITStrackV2::AliITStrackV2() : AliKalmanTrack(),
+ fCheckInvariant(kTRUE),
fdEdx(0),
fESDtrack(0)
{
//____________________________________________________________________________
-AliITStrackV2::AliITStrackV2(AliESDtrack& t,Bool_t c) throw (const Char_t *) :
+AliITStrackV2::AliITStrackV2(AliESDtrack& t,Bool_t c):
AliKalmanTrack(),
+ fCheckInvariant(kTRUE),
fdEdx(t.GetITSsignal()),
fESDtrack(&t)
{
const AliExternalTrackParam *par=&t;
if (c) {
par=t.GetConstrainedParam();
- if (!par) throw "AliITStrackV2: conversion failed !\n";
+ if (!par) AliError("AliITStrackV2: conversion failed !\n");
}
Set(par->GetX(),par->GetAlpha(),par->GetParameter(),par->GetCovariance());
- //if (!Invariant()) throw "AliITStrackV2: conversion failed !\n";
-
SetLabel(t.GetLabel());
SetMass(t.GetMass());
SetNumberOfClusters(t.GetITSclusters(fIndex));
for(Int_t i=0; i<4; i++) fdEdxSample[i]=0;
}
+//____________________________________________________________________________
+void AliITStrackV2::ResetClusters() {
+ //------------------------------------------------------------------
+ // Reset the array of attached clusters.
+ //------------------------------------------------------------------
+ for (Int_t i=0; i<2*AliITSgeomTGeo::kNLayers; i++) fIndex[i]=-1;
+ SetChi2(0.);
+ SetNumberOfClusters(0);
+}
+
+//____________________________________________________________________________
void AliITStrackV2::UpdateESDtrack(ULong_t flags) const {
+ // Update track params
fESDtrack->UpdateTrackParams(this,flags);
// copy the module indices
for(Int_t i=0;i<12;i++) {
// printf(" %d\n",GetModuleIndex(i));
fESDtrack->SetITSModuleIndex(i,GetModuleIndex(i));
}
+ // copy the 4 dedx samples
+ Double_t sdedx[4]={0.,0.,0.,0.};
+ for(Int_t i=0; i<4; i++) sdedx[i]=fdEdxSample[i];
+ fESDtrack->SetITSdEdxSamples(sdedx);
}
//____________________________________________________________________________
AliITStrackV2::AliITStrackV2(const AliITStrackV2& t) :
AliKalmanTrack(t),
+ fCheckInvariant(t.fCheckInvariant),
fdEdx(t.fdEdx),
fESDtrack(t.fESDtrack)
{
//This function returns a track position in the global system
//------------------------------------------------------------------
Double_t r[3];
- Bool_t rc=GetXYZAt(xloc, AliTracker::GetBz(), r);
+ Bool_t rc=GetXYZAt(xloc, GetBz(), r);
x=r[0]; y=r[1]; z=r[2];
return rc;
}
Double_t oldX=GetX(), oldY=GetY(), oldZ=GetZ();
- Double_t bz=GetBz();
- if (!AliExternalTrackParam::PropagateTo(xk,bz)) return kFALSE;
+ //Double_t bz=GetBz();
+ //if (!AliExternalTrackParam::PropagateTo(xk,bz)) return kFALSE;
+ Double_t b[3]; GetBxByBz(b);
+ if (!AliExternalTrackParam::PropagateToBxByBz(xk,b)) return kFALSE;
Double_t xOverX0,xTimesRho;
xOverX0 = d; xTimesRho = d*x0;
if (!CorrectForMeanMaterial(xOverX0,xTimesRho,kTRUE)) return kFALSE;
}
//____________________________________________________________________________
-Bool_t AliITStrackV2::PropagateToTGeo(Double_t xToGo, Int_t nstep, Double_t &xOverX0, Double_t &xTimesRho) {
+Bool_t AliITStrackV2::PropagateToTGeo(Double_t xToGo, Int_t nstep, Double_t &xOverX0, Double_t &xTimesRho, Bool_t addTime) {
//-------------------------------------------------------------------
// Propagates the track to a reference plane x=xToGo in n steps.
// These n steps are only used to take into account the curvature.
Double_t sign = (startx<xToGo) ? -1.:1.;
Double_t step = (xToGo-startx)/TMath::Abs(nstep);
- Double_t start[3], end[3], mparam[7], bz = GetBz();
+ Double_t start[3], end[3], mparam[7];
+ //Double_t bz = GetBz();
+ Double_t b[3]; GetBxByBz(b);
+ Double_t bz = b[2];
+
Double_t x = startx;
for (Int_t i=0; i<nstep; i++) {
GetXYZ(start); //starting global position
x += step;
if (!GetXYZAt(x, bz, end)) return kFALSE;
- if (!AliExternalTrackParam::PropagateTo(x, bz)) return kFALSE;
+ //if (!AliExternalTrackParam::PropagateTo(x, bz)) return kFALSE;
+ if (!AliExternalTrackParam::PropagateToBxByBz(x, b)) return kFALSE;
AliTracker::MeanMaterialBudget(start, end, mparam);
+ xTimesRho = sign*mparam[4]*mparam[0];
+ xOverX0 = mparam[1];
if (mparam[1]<900000) {
- xTimesRho = sign*mparam[4]*mparam[0];
- xOverX0 = mparam[1];
if (!AliExternalTrackParam::CorrectForMeanMaterial(xOverX0,
- xTimesRho,GetMass())) return kFALSE;
+ xTimesRho,GetMass())) return kFALSE;
+ } else { // this happens when MeanMaterialBudget cannot cross a boundary
+ return kFALSE;
}
}
- if (IsStartedTimeIntegral() && GetX()>startx) {
+ if (addTime && IsStartedTimeIntegral() && GetX()>startx) {
Double_t l2 = ( (GetX()-startx)*(GetX()-startx) +
(GetY()-starty)*(GetY()-starty) +
(GetZ()-startz)*(GetZ()-startz) );
//This function updates track parameters
//------------------------------------------------------------------
Double_t p[2]={c->GetY(), c->GetZ()};
- Double_t cov[3]={c->GetSigmaY2(), 0., c->GetSigmaZ2()};
+ Double_t cov[3]={c->GetSigmaY2(), c->GetSigmaYZ(), c->GetSigmaZ2()};
if (!AliExternalTrackParam::Update(p,cov)) return kFALSE;
+ Int_t n=GetNumberOfClusters();
if (!Invariant()) {
- AliWarning("Wrong invariant !");
+ if (n>fgkWARN) AliWarning("Wrong invariant !");
return kFALSE;
}
if (chi2<0) return kTRUE;
- Int_t n=GetNumberOfClusters();
+ // fill residuals for ITS+TPC tracks
+ if (fESDtrack) {
+ if (fESDtrack->GetStatus()&AliESDtrack::kTPCin) {
+ AliTracker::FillResiduals(this,p,cov,c->GetVolumeId());
+ }
+ }
+
fIndex[n]=index;
SetNumberOfClusters(n+1);
SetChi2(GetChi2()+chi2);
//------------------------------------------------------------------
// This function is for debugging purpose only
//------------------------------------------------------------------
+ if(!fCheckInvariant) return kTRUE;
+
Int_t n=GetNumberOfClusters();
+ // take into account the misalignment error
+ Float_t maxMisalErrY2=0,maxMisalErrZ2=0;
+ for (Int_t lay=0; lay<AliITSgeomTGeo::kNLayers; lay++) {
+ maxMisalErrY2 = TMath::Max(maxMisalErrY2,AliITSReconstructor::GetRecoParam()->GetClusterMisalErrorY(lay,GetBz()));
+ maxMisalErrZ2 = TMath::Max(maxMisalErrZ2,AliITSReconstructor::GetRecoParam()->GetClusterMisalErrorZ(lay,GetBz()));
+ }
+ maxMisalErrY2 *= maxMisalErrY2;
+ maxMisalErrZ2 *= maxMisalErrZ2;
+ // this is because when we reset before refitting, we multiply the
+ // matrix by 10
+ maxMisalErrY2 *= 10.;
+ maxMisalErrZ2 *= 10.;
+
Double_t sP2=GetParameter()[2];
if (TMath::Abs(sP2) >= kAlmost1){
if (n>fgkWARN) Warning("Invariant","fP2=%f\n",sP2);
return kFALSE;
}
Double_t sC00=GetCovariance()[0];
- if (sC00<=0 || sC00>9.) {
+ if (sC00<=0 || sC00>(9.+maxMisalErrY2)) {
if (n>fgkWARN) Warning("Invariant","fC00=%f\n",sC00);
return kFALSE;
}
Double_t sC11=GetCovariance()[2];
- if (sC11<=0 || sC11>9.) {
+ if (sC11<=0 || sC11>(9.+maxMisalErrZ2)) {
if (n>fgkWARN) Warning("Invariant","fC11=%f\n",sC11);
return kFALSE;
}
//------------------------------------------------------------------
//This function propagates a track
//------------------------------------------------------------------
- Double_t bz=GetBz();
- if (!AliExternalTrackParam::Propagate(alp,xk,bz)) return kFALSE;
+ //Double_t bz=GetBz();
+ //if (!AliExternalTrackParam::Propagate(alp,xk,bz)) return kFALSE;
+ Double_t b[3]; GetBxByBz(b);
+ if (!AliExternalTrackParam::PropagateBxByBz(alp,xk,b)) return kFALSE;
if (!Invariant()) {
- AliWarning("Wrong invariant !");
- return kFALSE;
+ Int_t n=GetNumberOfClusters();
+ if (n>fgkWARN) AliWarning("Wrong invariant !");
+ return kFALSE;
}
return kTRUE;
//------------------------------------------------------------------
//This function improves angular track parameters
//------------------------------------------------------------------
+ //Store the initail track parameters
+
+ Double_t x = GetX();
+ Double_t alpha = GetAlpha();
+ Double_t par[] = {GetY(),GetZ(),GetSnp(),GetTgl(),GetSigned1Pt()};
+ Double_t cov[] = {
+ GetSigmaY2(),
+ GetSigmaZY(),
+ GetSigmaZ2(),
+ GetSigmaSnpY(),
+ GetSigmaSnpZ(),
+ GetSigmaSnp2(),
+ GetSigmaTglY(),
+ GetSigmaTglZ(),
+ GetSigmaTglSnp(),
+ GetSigmaTgl2(),
+ GetSigma1PtY(),
+ GetSigma1PtZ(),
+ GetSigma1PtSnp(),
+ GetSigma1PtTgl(),
+ GetSigma1Pt2()
+ };
+
+
Double_t cs=TMath::Cos(GetAlpha()), sn=TMath::Sin(GetAlpha());
//Double_t xv = xyz[0]*cs + xyz[1]*sn; // vertex
Double_t yv =-xyz[0]*sn + xyz[1]*cs; // in the
Double_t zv = xyz[2]; // local frame
- Double_t dy = Par(0) - yv, dz = Par(1) - zv;
+ Double_t dy = par[0] - yv, dz = par[1] - zv;
Double_t r2=GetX()*GetX() + dy*dy;
Double_t p2=(1.+ GetTgl()*GetTgl())/(GetSigned1Pt()*GetSigned1Pt());
Double_t beta2=p2/(p2 + GetMass()*GetMass());
Double_t dummy = 4/r2 - GetC()*GetC();
if (dummy < 0) return kFALSE;
Double_t parp = 0.5*(GetC()*GetX() + dy*TMath::Sqrt(dummy));
- Double_t sigma2p = theta2*(1.- GetSnp()*GetSnp())*(1. + GetTgl()*GetTgl());
- sigma2p += Cov(0)/r2*(1.- dy*dy/r2)*(1.- dy*dy/r2);
+ Double_t sigma2p = theta2*(1.-GetSnp())*(1.+GetSnp())*(1. + GetTgl()*GetTgl());
+ Double_t ovSqr2 = 1./TMath::Sqrt(r2);
+ Double_t tfact = ovSqr2*(1.-dy*ovSqr2)*(1.+dy*ovSqr2);
+ sigma2p += cov[0]*tfact*tfact;
sigma2p += ers[1]*ers[1]/r2;
- sigma2p += 0.25*Cov(14)*cnv*cnv*GetX()*GetX();
- Double_t eps2p=sigma2p/(Cov(5) + sigma2p);
- Par(0) += Cov(3)/(Cov(5) + sigma2p)*(parp - GetSnp());
- Par(2) = eps2p*GetSnp() + (1 - eps2p)*parp;
- Cov(5) *= eps2p;
- Cov(3) *= eps2p;
+ sigma2p += 0.25*cov[14]*cnv*cnv*GetX()*GetX();
+ Double_t eps2p=sigma2p/(cov[5] + sigma2p);
+ par[0] += cov[3]/(cov[5] + sigma2p)*(parp - GetSnp());
+ par[2] = eps2p*GetSnp() + (1 - eps2p)*parp;
+ cov[5] *= eps2p;
+ cov[3] *= eps2p;
}
{
Double_t parl=0.5*GetC()*dz/TMath::ASin(0.5*GetC()*TMath::Sqrt(r2));
Double_t sigma2l=theta2;
- sigma2l += Cov(2)/r2 + Cov(0)*dy*dy*dz*dz/(r2*r2*r2);
+ sigma2l += cov[2]/r2 + cov[0]*dy*dy*dz*dz/(r2*r2*r2);
sigma2l += ers[2]*ers[2]/r2;
- Double_t eps2l = sigma2l/(Cov(9) + sigma2l);
- Par(1) += Cov(7 )/(Cov(9) + sigma2l)*(parl - Par(3));
- Par(4) += Cov(13)/(Cov(9) + sigma2l)*(parl - Par(3));
- Par(3) = eps2l*Par(3) + (1-eps2l)*parl;
- Cov(9) *= eps2l;
- Cov(13)*= eps2l;
- Cov(7) *= eps2l;
+ Double_t eps2l = sigma2l/(cov[9] + sigma2l);
+ par[1] += cov[7 ]/(cov[9] + sigma2l)*(parl - par[3]);
+ par[4] += cov[13]/(cov[9] + sigma2l)*(parl - par[3]);
+ par[3] = eps2l*par[3] + (1-eps2l)*parl;
+ cov[9] *= eps2l;
+ cov[13]*= eps2l;
+ cov[7] *= eps2l;
}
+
+ Set(x,alpha,par,cov);
+
if (!Invariant()) return kFALSE;
return kTRUE;
//-----------------------------------------------------------------
// This function calculates dE/dX within the "low" and "up" cuts.
// Origin: Boris Batyunya, JINR, Boris.Batiounia@cern.ch
+ // Updated: F. Prino 8-June-2009
//-----------------------------------------------------------------
- // The clusters order is: SSD-2, SSD-1, SDD-2, SDD-1, SPD-2, SPD-1
+ // The cluster order is: SDD-1, SDD-2, SSD-1, SSD-2
- Int_t i;
Int_t nc=0;
- for (i=0; i<GetNumberOfClusters(); i++) {
- Int_t idx=GetClusterIndex(i);
- idx=(idx&0xf0000000)>>28;
- if (idx>1) nc++; // Take only SSD and SDD
+ Float_t dedx[4];
+ for (Int_t il=0; il<4; il++) { // count good (>0) dE/dx values
+ if(fdEdxSample[il]>0.){
+ dedx[nc]= fdEdxSample[il];
+ nc++;
+ }
+ }
+ if(nc<1){
+ SetdEdx(0.);
+ return;
}
- Int_t swap;//stupid sorting
+ Int_t swap; // sort in ascending order
do {
swap=0;
- for (i=0; i<nc-1; i++) {
- if (fdEdxSample[i]<=fdEdxSample[i+1]) continue;
- Float_t tmp=fdEdxSample[i];
- fdEdxSample[i]=fdEdxSample[i+1]; fdEdxSample[i+1]=tmp;
+ for (Int_t i=0; i<nc-1; i++) {
+ if (dedx[i]<=dedx[i+1]) continue;
+ Float_t tmp=dedx[i];
+ dedx[i]=dedx[i+1];
+ dedx[i+1]=tmp;
swap++;
}
} while (swap);
- Int_t nl=Int_t(low*nc), nu=Int_t(up*nc); //b.b. to take two lowest dEdX
- // values from four ones choose
- // nu=2
- Float_t dedx=0;
- for (i=nl; i<nu; i++) dedx += fdEdxSample[i];
- if (nu-nl>0) dedx /= (nu-nl);
-
- SetdEdx(dedx);
-}
-Double_t AliITStrackV2::GetBz() const {
- //
- // returns Bz component of the magnetic field (kG)
- //
- if (AliTracker::UniformField()) return AliTracker::GetBz();
- Double_t r[3]; GetXYZ(r);
- return AliTracker::GetBz(r);
+ Double_t nl=low*nc, nu =up*nc;
+ Float_t sumamp = 0;
+ Float_t sumweight =0;
+ for (Int_t i=0; i<nc; i++) {
+ Float_t weight =1;
+ if (i<nl+0.1) weight = TMath::Max(1.-(nl-i),0.);
+ if (i>nu-1) weight = TMath::Max(nu-i,0.);
+ sumamp+= dedx[i]*weight;
+ sumweight+=weight;
+ }
+ SetdEdx(sumamp/sumweight);
}
//____________________________________________________________________________
// The track curvature is neglected.
//------------------------------------------------------------------
Double_t d=GetD(0.,0.);
- if (TMath::Abs(d) > r) return kFALSE;
+ if (TMath::Abs(d) > r) {
+ if (r>1e-1) return kFALSE;
+ r = TMath::Abs(d);
+ }
Double_t rcurr=TMath::Sqrt(GetX()*GetX() + GetY()*GetY());
- if (TMath::Abs(d) > rcurr) return kFALSE;
- Double_t phicurr=GetAlpha()+TMath::ASin(GetSnp());
+ if (TMath::Abs(d) > rcurr) return kFALSE;
+ Double_t globXYZcurr[3]; GetXYZ(globXYZcurr);
+ Double_t phicurr=TMath::ATan2(globXYZcurr[1],globXYZcurr[0]);
+
+ if (GetX()>=0.) {
+ phi=phicurr+TMath::ASin(d/r)-TMath::ASin(d/rcurr);
+ } else {
+ phi=phicurr+TMath::ASin(d/r)+TMath::ASin(d/rcurr)-TMath::Pi();
+ }
- phi=phicurr+TMath::ASin(d/r)-TMath::ASin(d/rcurr);
+ // return a phi in [0,2pi[
+ if (phi<0.) phi+=2.*TMath::Pi();
+ else if (phi>=2.*TMath::Pi()) phi-=2.*TMath::Pi();
z=GetZ()+GetTgl()*(TMath::Sqrt((r-d)*(r+d))-TMath::Sqrt((rcurr-d)*(rcurr+d)));
return kTRUE;
}
// The track curvature is neglected.
//------------------------------------------------------------------
Double_t d=GetD(0.,0.);
- if (TMath::Abs(d) > r) return kFALSE;
+ if (TMath::Abs(d) > r) {
+ if (r>1e-1) return kFALSE;
+ r = TMath::Abs(d);
+ }
Double_t rcurr=TMath::Sqrt(GetX()*GetX() + GetY()*GetY());
- Double_t phicurr=GetAlpha()+TMath::ASin(GetSnp());
- Double_t phi=phicurr+TMath::ASin(d/r)-TMath::ASin(d/rcurr);
+ Double_t globXYZcurr[3]; GetXYZ(globXYZcurr);
+ Double_t phicurr=TMath::ATan2(globXYZcurr[1],globXYZcurr[0]);
+ Double_t phi;
+ if (GetX()>=0.) {
+ phi=phicurr+TMath::ASin(d/r)-TMath::ASin(d/rcurr);
+ } else {
+ phi=phicurr+TMath::ASin(d/r)+TMath::ASin(d/rcurr)-TMath::Pi();
+ }
xloc=r*(TMath::Cos(phi)*TMath::Cos(GetAlpha())
+TMath::Sin(phi)*TMath::Sin(GetAlpha()));
return kTRUE;
}
-