////////////////////////////////////////////////////////////////////////////
#include "TMath.h"
-#include <TTreeStream.h>
+#include "TTreeStream.h"
+#include "TGraphErrors.h"
#include "AliLog.h"
#include "AliMathBase.h"
+#include "AliRieman.h"
#include "AliCDBManager.h"
-#include "AliTracker.h"
+#include "AliTRDReconstructor.h"
#include "AliTRDpadPlane.h"
+#include "AliTRDtransform.h"
#include "AliTRDcluster.h"
#include "AliTRDseedV1.h"
#include "AliTRDtrackV1.h"
#include "AliTRDtrackerV1.h"
#include "AliTRDrecoParam.h"
#include "AliTRDCommonParam.h"
+#include "AliTRDtrackletOflHelper.h"
+#include "Cal/AliTRDCalTrkAttach.h"
#include "Cal/AliTRDCalPID.h"
#include "Cal/AliTRDCalROC.h"
#include "Cal/AliTRDCalDet.h"
+class AliTracker;
+
ClassImp(AliTRDseedV1)
//____________________________________________________________________
}
+//____________________________________________________________
+void AliTRDseedV1::Init(const AliRieman *rieman)
+{
+// Initialize this tracklet using the riemann fit information
+
+
+ fZref[0] = rieman->GetZat(fX0);
+ fZref[1] = rieman->GetDZat(fX0);
+ fYref[0] = rieman->GetYat(fX0);
+ fYref[1] = rieman->GetDYat(fX0);
+ if(fkReconstructor && fkReconstructor->IsHLT()){
+ fRefCov[0] = 1;
+ fRefCov[2] = 10;
+ }else{
+ fRefCov[0] = rieman->GetErrY(fX0);
+ fRefCov[2] = rieman->GetErrZ(fX0);
+ }
+ fC[0] = rieman->GetC();
+ fChi2 = rieman->GetChi2();
+}
+
+
//____________________________________________________________
Bool_t AliTRDseedV1::Init(AliTRDtrackV1 *track)
{
for(int ic=0; ic<AliTRDtrackerV1::GetNTimeBins(); ic++){
if(!(c = fClusters[ic]) && !(c = fClusters[ic+kNtb])) continue;
Float_t dx = TMath::Abs(fX0 - c->GetX());
-
+
// Filter clusters for dE/dx calculation
-
+
// 1.consider calibration effects for slice determination
Int_t slice;
- if(dx<kDriftLength){ // TODO should be replaced by c->IsInChamber()
+ if(dx<kDriftLength){ // TODO should be replaced by c->IsInChamber()
slice = Int_t(dx * nslices / kDriftLength);
} else slice = c->GetX() < fX0 ? nslices-1 : 0;
// 2. take sharing into account
Float_t w = /*c->IsShared() ? .5 :*/ 1.;
-
+
// 3. take into account large clusters TODO
//w *= c->GetNPads() > 3 ? .8 : 1.;
-
+
//CHECK !!!
fdEdx[slice] += w * GetdQdl(ic); //fdQdl[ic];
} // End of loop over clusters
//____________________________________________________________
Float_t AliTRDseedV1::GetAnodeWireOffset(Float_t zt)
{
+// Find position inside the amplification cell for reading drift velocity map
+
Float_t d = fPad[3] - zt;
if(d<0.){
AliError(Form("Fail AnodeWireOffset calculation z0[%+7.2f] zt[%+7.2f] d[%+7.2f].", fPad[3], zt, d));
}
+//____________________________________________________________________
+Float_t AliTRDseedV1::GetCharge(Bool_t useOutliers) const
+{
+// Computes total charge attached to tracklet. If "useOutliers" is set clusters
+// which are not in chamber are also used (default false)
+
+ AliTRDcluster *c(NULL); Float_t qt(0.);
+ for(int ic=0; ic<kNclusters; ic++){
+ if(!(c=fClusters[ic])) continue;
+ if(c->IsInChamber() && !useOutliers) continue;
+ qt += TMath::Abs(c->GetQ());
+ }
+ return qt;
+}
+
+//____________________________________________________________________
+Bool_t AliTRDseedV1::GetEstimatedCrossPoint(Float_t &x, Float_t &z) const
+{
+// Algorithm to estimate cross point in the x-z plane for pad row cross tracklets.
+// Returns true in case of success.
+ if(!IsRowCross()) return kFALSE;
+
+ x=0.; z=0.;
+ AliTRDcluster *c(NULL);
+ // Find radial range for first row
+ Float_t x1[] = {0., 1.e3};
+ for(int ic=0; ic<kNtb; ic++){
+ if(!(c=fClusters[ic])) continue;
+ if(!c->IsInChamber()) continue;
+ if(c->GetX() <= x1[1]) x1[1] = c->GetX();
+ if(c->GetX() >= x1[0]) x1[0] = c->GetX();
+ z=c->GetZ();
+ }
+ if((x1[0] - x1[1])<1.e-5) return kFALSE;
+
+ // Find radial range for second row
+ Bool_t kZ(kFALSE);
+ Float_t x2[] = {0., 1.e3};
+ for(int ic=kNtb; ic<kNclusters; ic++){
+ if(!(c=fClusters[ic])) continue;
+ if(!c->IsInChamber()) continue;
+ if(c->GetX() <= x2[1]) x2[1] = c->GetX();
+ if(c->GetX() >= x2[0]) x2[0] = c->GetX();
+ if(!kZ){
+ z+=c->GetZ();
+ z*=0.5;
+ kZ=kTRUE;
+ }
+ }
+ if((x2[0] - x2[1])<1.e-5) return kFALSE;
+
+ // Find intersection of the 2 radial regions
+ x = 0.5*((x1[0]+x1[1] > x2[0]+x2[1]) ? (x1[1]+x2[0]) : (x1[0]+x2[1]));
+ return kTRUE;
+}
+
+//____________________________________________________________________
+Float_t AliTRDseedV1::GetdQdl() const
+{
+// Calculate total charge / tracklet length for 1D PID
+//
+ Float_t Q = GetCharge(kTRUE);
+ return Q/TMath::Sqrt(1. + fYref[1]*fYref[1] + fZref[1]*fZref[1]);
+}
+
//____________________________________________________________________
Float_t AliTRDseedV1::GetdQdl(Int_t ic, Float_t *dl) const
{
if(fClusters[ic] && fClusters[ic]->IsInChamber()){
hasClusterInChamber = kTRUE;
dq += TMath::Abs(fClusters[ic]->GetQ());
- }else if(fClusters[ic+kNtb] && fClusters[ic+kNtb]->IsInChamber()){
+ }
+ if(fClusters[ic+kNtb] && fClusters[ic+kNtb]->IsInChamber()){
hasClusterInChamber = kTRUE;
dq += TMath::Abs(fClusters[ic+kNtb]->GetQ());
}
return p;
}
+
//____________________________________________________________________
Float_t AliTRDseedV1::GetOccupancyTB() const
{
//____________________________________________________________________
UShort_t AliTRDseedV1::GetVolumeId() const
{
+// Returns geometry volume id by delegation
+
for(Int_t ic(0);ic<kNclusters; ic++){
if(fClusters[ic]) return fClusters[ic]->GetVolumeId();
}
}
//____________________________________________________________
-void AliTRDseedV1::SetPadPlane(AliTRDpadPlane *p)
+void AliTRDseedV1::SetPadPlane(AliTRDpadPlane * const p)
{
// Shortcut method to initialize pad geometry.
fPad[0] = p->GetLengthIPad();
}
+
//____________________________________________________________________
-Bool_t AliTRDseedV1::AttachClusters(AliTRDtrackingChamber *const chamber, Bool_t tilt)
+Bool_t AliTRDseedV1::AttachClusters(AliTRDtrackingChamber *const chamber, Bool_t tilt, Bool_t chgPos, Int_t ev)
{
//
// Projective algorithm to attach clusters to seeding tracklets. The following steps are performed :
// - true : if tracklet found successfully. Failure can happend because of the following:
// -
// Detailed description
-//
+//
// We start up by defining the track direction in the xy plane and roads. The roads are calculated based
// on tracking information (variance in the r-phi direction) and estimated variance of the standard
// clusters (see AliTRDcluster::SetSigmaY2()) corrected for tilt (see GetCovAt()). From this the road is
// END_LATEX
//
// Author : Alexandru Bercuci <A.Bercuci@gsi.de>
-// Debug : level >3
+// Debug : level = 2 for calibration
+// level = 3 for visualization in the track SR
+// level = 4 for full visualization including digit level
const AliTRDrecoParam* const recoParam = fkReconstructor->GetRecoParam(); //the dynamic cast in GetRecoParam is slow, so caching the pointer to it
AliError("Tracklets can not be used without a valid RecoParam.");
return kFALSE;
}
+ AliTRDcalibDB *calibration = AliTRDcalibDB::Instance();
+ if (!calibration) {
+ AliError("No access to calibration data");
+ return kFALSE;
+ }
+ // Retrieve the CDB container class with the parametric likelihood
+ const AliTRDCalTrkAttach *attach = calibration->GetAttachObject();
+ if (!attach) {
+ AliError("No usable AttachClusters calib object.");
+ return kFALSE;
+ }
+
// Initialize reco params for this tracklet
// 1. first time bin in the drift region
Int_t t0 = 14;
Int_t kClmin = Int_t(recoParam->GetFindableClusters()*AliTRDtrackerV1::GetNTimeBins());
+ Int_t kTBmin = 4;
- Double_t sysCov[5]; recoParam->GetSysCovMatrix(sysCov);
+ Double_t sysCov[5]; recoParam->GetSysCovMatrix(sysCov);
Double_t s2yTrk= fRefCov[0],
s2yCl = 0.,
s2zCl = GetPadLength()*GetPadLength()/12.,
syRef = TMath::Sqrt(s2yTrk),
t2 = GetTilt()*GetTilt();
//define roads
- Double_t kroady = 1., //recoParam->GetRoad1y();
- kroadz = GetPadLength() * recoParam->GetRoadzMultiplicator() + 1.;
+ const Double_t kroady = 3.; //recoParam->GetRoad1y();
+ const Double_t kroadz = GetPadLength() * recoParam->GetRoadzMultiplicator() + 1.;
// define probing cluster (the perfect cluster) and default calibration
Short_t sig[] = {0, 0, 10, 30, 10, 0,0};
AliTRDcluster cp(fDet, 6, 75, 0, sig, 0);
if(fkReconstructor->IsHLT()) cp.SetRPhiMethod(AliTRDcluster::kCOG);
if(!IsCalibrated()) Calibrate();
- AliDebug(4, "");
- AliDebug(4, Form("syKalman[%f] rY[%f] rZ[%f]", syRef, kroady, kroadz));
+ Int_t kroadyShift(0);
+ Float_t bz(AliTrackerBase::GetBz());
+ if(TMath::Abs(bz)>2.){
+ if(bz<0.) kroadyShift = chgPos ? +1 : -1;
+ else kroadyShift = chgPos ? -1 : +1;
+ }
+ AliDebug(4, Form("\n syTrk[cm]=%4.2f dydxTrk[deg]=%+6.2f rs[%d] Chg[%c] rY[cm]=%4.2f rZ[cm]=%5.2f TC[%c]", syRef, TMath::ATan(fYref[1])*TMath::RadToDeg(), kroadyShift, chgPos?'+':'-', kroady, kroadz, tilt?'y':'n'));
+ Double_t phiTrk(TMath::ATan(fYref[1])),
+ thtTrk(TMath::ATan(fZref[1]));
// working variables
const Int_t kNrows = 16;
const Int_t kNcls = 3*kNclusters; // buffer size
- AliTRDcluster *clst[kNrows][kNcls];
+ TObjArray clst[kNrows];
Bool_t blst[kNrows][kNcls];
- Double_t cond[4], dx, dy, yt, zt, yres[kNrows][kNcls];
+ Double_t cond[4],
+ dx, dy, dz,
+ yt, zt,
+ zc[kNrows],
+ xres[kNrows][kNcls], yres[kNrows][kNcls], zres[kNrows][kNcls], s2y[kNrows][kNcls];
Int_t idxs[kNrows][kNcls], ncl[kNrows], ncls = 0;
memset(ncl, 0, kNrows*sizeof(Int_t));
+ memset(zc, 0, kNrows*sizeof(Double_t));
+ memset(idxs, 0, kNrows*kNcls*sizeof(Int_t));
+ memset(xres, 0, kNrows*kNcls*sizeof(Double_t));
memset(yres, 0, kNrows*kNcls*sizeof(Double_t));
+ memset(zres, 0, kNrows*kNcls*sizeof(Double_t));
+ memset(s2y, 0, kNrows*kNcls*sizeof(Double_t));
memset(blst, 0, kNrows*kNcls*sizeof(Bool_t)); //this is 8 times faster to memset than "memset(clst, 0, kNrows*kNcls*sizeof(AliTRDcluster*))"
- // Do cluster projection
- AliTRDcluster *c = NULL;
- AliTRDchamberTimeBin *layer = NULL;
+ Double_t roady(0.), s2Mean(0.), sMean(0.); Int_t ns2Mean(0);
+
+ // Do cluster projection and pick up cluster candidates
+ AliTRDcluster *c(NULL);
+ AliTRDchamberTimeBin *layer(NULL);
Bool_t kBUFFER = kFALSE;
for (Int_t it = 0; it < kNtb; it++) {
if(!(layer = chamber->GetTB(it))) continue;
dx = fX0 - layer->GetX();
yt = fYref[0] - fYref[1] * dx;
zt = fZref[0] - fZref[1] * dx;
- // get standard cluster error corrected for tilt
+ // get standard cluster error corrected for tilt if selected
cp.SetLocalTimeBin(it);
cp.SetSigmaY2(0.02, fDiffT, fExB, dx, -1./*zt*/, fYref[1]);
- s2yCl = (cp.GetSigmaY2() + sysCov[0] + t2*s2zCl)/(1.+t2);
- // get estimated road
- kroady = 3.*TMath::Sqrt(12.*(s2yTrk + s2yCl));
-
- AliDebug(5, Form(" %2d x[%f] yt[%f] zt[%f]", it, dx, yt, zt));
-
- AliDebug(5, Form(" syTrk[um]=%6.2f syCl[um]=%6.2f syClTlt[um]=%6.2f Ry[mm]=%f", 1.e4*TMath::Sqrt(s2yTrk), 1.e4*TMath::Sqrt(cp.GetSigmaY2()), 1.e4*TMath::Sqrt(s2yCl), 1.e1*kroady));
-
- // select clusters
- cond[0] = yt; cond[2] = kroady;
+ s2yCl = cp.GetSigmaY2() + sysCov[0]; if(!tilt) s2yCl = (s2yCl + t2*s2zCl)/(1.+t2);
+ if(TMath::Abs(it-12)<7){ s2Mean += cp.GetSigmaY2(); ns2Mean++;}
+ // get estimated road in r-phi direction
+ roady = TMath::Min(3.*TMath::Sqrt(12.*(s2yTrk + s2yCl)), kroady);
+
+ AliDebug(5, Form("\n"
+ " %2d xd[cm]=%6.3f yt[cm]=%7.2f zt[cm]=%8.2f\n"
+ " syTrk[um]=%6.2f syCl[um]=%6.2f syClTlt[um]=%6.2f\n"
+ " Ry[mm]=%f"
+ , it, dx, yt, zt
+ , 1.e4*TMath::Sqrt(s2yTrk), 1.e4*TMath::Sqrt(cp.GetSigmaY2()+sysCov[0]), 1.e4*TMath::Sqrt(s2yCl)
+ , 1.e1*roady));
+
+ // get clusters from layer
+ cond[0] = yt/*+0.5*kroadyShift*kroady*/; cond[2] = roady;
cond[1] = zt; cond[3] = kroadz;
- Int_t n=0, idx[6];
- layer->GetClusters(cond, idx, n, 6);
+ Int_t n=0, idx[6]; layer->GetClusters(cond, idx, n, 6);
for(Int_t ic = n; ic--;){
c = (*layer)[idx[ic]];
- dy = yt - c->GetY();
- dy += tilt ? GetTilt() * (c->GetZ() - zt) : 0.;
- // select clusters on a 3 sigmaKalman level
-/* if(tilt && TMath::Abs(dy) > 3.*syRef){
- printf("too large !!!\n");
- continue;
- }*/
+ dx = fX0 - c->GetX();
+ yt = fYref[0] - fYref[1] * dx;
+ zt = fZref[0] - fZref[1] * dx;
+ dz = zt - c->GetZ();
+ dy = yt - (c->GetY() + (tilt ? (GetTilt() * dz) : 0.));
Int_t r = c->GetPadRow();
- AliDebug(5, Form(" -> dy[%f] yc[%f] r[%d]", TMath::Abs(dy), c->GetY(), r));
- clst[r][ncl[r]] = c;
+ clst[r].AddAtAndExpand(c, ncl[r]);
blst[r][ncl[r]] = kTRUE;
idxs[r][ncl[r]] = idx[ic];
+ zres[r][ncl[r]] = dz/GetPadLength();
yres[r][ncl[r]] = dy;
+ xres[r][ncl[r]] = dx;
+ zc[r] = c->GetZ();
+ // TODO temporary solution to avoid divercences in error parametrization
+ s2y[r][ncl[r]] = TMath::Min(c->GetSigmaY2()+sysCov[0], 0.025);
+ AliDebug(5, Form(" -> dy[cm]=%+7.4f yc[cm]=%7.2f row[%d] idx[%2d]", dy, c->GetY(), r, ncl[r]));
ncl[r]++; ncls++;
if(ncl[r] >= kNcls) {
}
if(kBUFFER) break;
}
- AliDebug(4, Form("Found %d clusters. Processing ...", ncls));
if(ncls<kClmin){
AliDebug(1, Form("CLUSTERS FOUND %d LESS THAN THRESHOLD %d.", ncls, kClmin));
SetErrorMsg(kAttachClFound);
+ for(Int_t ir(kNrows);ir--;) clst[ir].Clear();
+ return kFALSE;
+ }
+ if(ns2Mean<kTBmin){
+ AliDebug(1, Form("CLUSTERS IN TimeBins %d LESS THAN THRESHOLD %d.", ns2Mean, kTBmin));
+ SetErrorMsg(kAttachClFound);
+ for(Int_t ir(kNrows);ir--;) clst[ir].Clear();
return kFALSE;
}
+ s2Mean /= ns2Mean; sMean = TMath::Sqrt(s2Mean);
+ //Double_t sRef(TMath::Sqrt(s2Mean+s2yTrk)); // reference error parameterization
+
+ // organize row candidates
+ Int_t idxRow[kNrows], nrc(0); Double_t zresRow[kNrows];
+ for(Int_t ir(0); ir<kNrows; ir++){
+ idxRow[ir]=-1; zresRow[ir] = 999.;
+ if(!ncl[ir]) continue;
+ // get mean z resolution
+ dz = 0.; for(Int_t ic = ncl[ir]; ic--;) dz += zres[ir][ic]; dz/=ncl[ir];
+ // insert row
+ idxRow[nrc] = ir; zresRow[nrc] = TMath::Abs(dz); nrc++;
+ }
+ AliDebug(4, Form("Found %d clusters in %d rows. Sorting ...", ncls, nrc));
+
+ // sort row candidates
+ if(nrc>=2){
+ if(nrc==2){
+ if(zresRow[0]>zresRow[1]){ // swap
+ Int_t itmp=idxRow[1]; idxRow[1] = idxRow[0]; idxRow[0] = itmp;
+ Double_t dtmp=zresRow[1]; zresRow[1] = zresRow[0]; zresRow[0] = dtmp;
+ }
+ if(TMath::Abs(idxRow[1] - idxRow[0]) != 1){
+ SetErrorMsg(kAttachRowGap);
+ AliDebug(2, Form("Rows attached not continuous. Select first candidate.\n"
+ " row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f",
+ idxRow[0], ncl[idxRow[0]], zresRow[0], idxRow[1], idxRow[1]<0?0:ncl[idxRow[1]], zresRow[1]));
+ nrc=1; idxRow[1] = -1; zresRow[1] = 999.;
+ }
+ } else {
+ Int_t idx0[kNrows];
+ TMath::Sort(nrc, zresRow, idx0, kFALSE);
+ nrc = 3; // select only maximum first 3 candidates
+ Int_t iatmp[] = {-1, -1, -1}; Double_t datmp[] = {999., 999., 999.};
+ for(Int_t irc(0); irc<nrc; irc++){
+ iatmp[irc] = idxRow[idx0[irc]];
+ datmp[irc] = zresRow[idx0[irc]];
+ }
+ idxRow[0] = iatmp[0]; zresRow[0] = datmp[0];
+ idxRow[1] = iatmp[1]; zresRow[1] = datmp[1];
+ idxRow[2] = iatmp[2]; zresRow[2] = datmp[2]; // temporary
+ if(TMath::Abs(idxRow[1] - idxRow[0]) != 1){
+ SetErrorMsg(kAttachRowGap);
+ AliDebug(2, Form("Rows attached not continuous. Turn on selection.\n"
+ "row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f\n"
+ "row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f\n"
+ "row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f",
+ idxRow[0], ncl[idxRow[0]], zresRow[0],
+ idxRow[1], ncl[idxRow[1]], zresRow[1],
+ idxRow[2], ncl[idxRow[2]], zresRow[2]));
+ if(TMath::Abs(idxRow[0] - idxRow[2]) == 1){ // select second candidate
+ AliDebug(2, "Solved ! Remove second candidate.");
+ nrc = 2;
+ idxRow[1] = idxRow[2]; zresRow[1] = zresRow[2]; // swap
+ idxRow[2] = -1; zresRow[2] = 999.; // remove
+ } else if(TMath::Abs(idxRow[1] - idxRow[2]) == 1){
+ if(ncl[idxRow[1]]+ncl[idxRow[2]] > ncl[idxRow[0]]){
+ AliDebug(2, "Solved ! Remove first candidate.");
+ nrc = 2;
+ idxRow[0] = idxRow[1]; zresRow[0] = zresRow[1]; // swap
+ idxRow[1] = idxRow[2]; zresRow[1] = zresRow[2]; // swap
+ } else {
+ AliDebug(2, "Solved ! Remove second and third candidate.");
+ nrc = 1;
+ idxRow[1] = -1; zresRow[1] = 999.; // remove
+ idxRow[2] = -1; zresRow[2] = 999.; // remove
+ }
+ } else {
+ AliDebug(2, "Unsolved !!! Remove second and third candidate.");
+ nrc = 1;
+ idxRow[1] = -1; zresRow[1] = 999.; // remove
+ idxRow[2] = -1; zresRow[2] = 999.; // remove
+ }
+ } else { // remove temporary candidate
+ nrc = 2;
+ idxRow[2] = -1; zresRow[2] = 999.;
+ }
+ }
+ }
+ AliDebug(4, Form("Sorted row candidates:\n"
+ " row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f row[%2d] Ncl[%2d] <dz>[cm]=%+8.2f"
+ , idxRow[0], ncl[idxRow[0]], zresRow[0], idxRow[1], idxRow[1]>=0?ncl[idxRow[1]]:0, zresRow[1]));
+
+ // initialize debug streamer
+ TTreeSRedirector *pstreamer(NULL);
+ if(recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 3 && fkReconstructor->IsDebugStreaming()) pstreamer = fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
+ if(pstreamer){
+ // save config. for calibration
+ TVectorD vdy[2], vdx[2], vs2[2];
+ for(Int_t jr(0); jr<nrc; jr++){
+ Int_t ir(idxRow[jr]);
+ vdx[jr].ResizeTo(ncl[ir]); vdy[jr].ResizeTo(ncl[ir]); vs2[jr].ResizeTo(ncl[ir]);
+ for(Int_t ic(ncl[ir]); ic--;){
+ vdx[jr](ic) = xres[ir][ic];
+ vdy[jr](ic) = yres[ir][ic];
+ vs2[jr](ic) = s2y[ir][ic];
+ }
+ }
+ (*pstreamer) << "AttachClusters4"
+ << "r0=" << idxRow[0]
+ << "dz0=" << zresRow[0]
+ << "dx0=" << &vdx[0]
+ << "dy0=" << &vdy[0]
+ << "s20=" << &vs2[0]
+ << "r1=" << idxRow[1]
+ << "dz1=" << zresRow[1]
+ << "dx1=" << &vdx[1]
+ << "dy1=" << &vdy[1]
+ << "s21=" << &vs2[1]
+ << "\n";
+ vdx[0].Clear(); vdy[0].Clear(); vs2[0].Clear();
+ vdx[1].Clear(); vdy[1].Clear(); vs2[1].Clear();
+ if(recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 4){
+ Int_t idx(0);
+ if(idxRow[1]<0){
+ for(Int_t ir(0); ir<kNrows; ir++){
+ if(clst[ir].GetEntries()>0) continue;
+ idx = ir;
+ break;
+ }
+ } else idx = idxRow[1];
+ (*pstreamer) << "AttachClusters5"
+ << "c0.=" << &clst[idxRow[0]]
+ << "c1.=" << &clst[idx]
+ << "\n";
+ }
+ }
- // analyze each row individualy
- Bool_t kRowSelection(kFALSE);
- Double_t mean[]={1.e3, 1.e3, 1.3}, syDis[]={1.e3, 1.e3, 1.3};
- Int_t nrow[] = {0, 0, 0}, rowId[] = {-1, -1, -1}, nr = 0, lr=-1;
- TVectorD vdy[3];
- for(Int_t ir=0; ir<kNrows; ir++){
- if(!(ncl[ir])) continue;
- if(lr>0 && ir-lr != 1){
- AliDebug(2, "Rows attached not continuous. Turn on selection.");
- kRowSelection=kTRUE;
+//=======================================================================================
+ // Analyse cluster topology
+ Double_t f[kNcls], // likelihood factors for segments
+ r[2][kNcls], // d(dydx) of tracklet candidate with respect to track
+ xm[2][kNcls], // mean <x>
+ ym[2][kNcls], // mean <y>
+ sm[2][kNcls], // mean <s_y>
+ s[2][kNcls], // sigma_y
+ p[2][kNcls]; // prob of Gauss
+ memset(f, 0, kNcls*sizeof(Double_t));
+ Int_t index[2][kNcls], n[2][kNcls];
+ memset(n, 0, 2*kNcls*sizeof(Int_t));
+ Int_t mts(0), nts[2] = {0, 0}; // no of tracklet segments in row
+ AliTRDpadPlane *pp(AliTRDtransform::Geometry().GetPadPlane(fDet));
+ AliTRDtrackletOflHelper helper;
+ Int_t lyDet(AliTRDgeometry::GetLayer(fDet));
+ for(Int_t jr(0), n0(0); jr<nrc; jr++){
+ Int_t ir(idxRow[jr]);
+ // cluster segmentation
+ Bool_t kInit(kFALSE);
+ if(jr==0){
+ n0 = helper.Init(pp, &clst[ir]); kInit = kTRUE;
+ if(!n0 || (helper.ClassifyTopology() == AliTRDtrackletOflHelper::kNormal)){
+ nts[jr] = 1; memset(index[jr], 0, ncl[ir]*sizeof(Int_t));
+ n[jr][0] = ncl[ir];
+ }
+ }
+ if(!n[jr][0]){
+ nts[jr] = AliTRDtrackletOflHelper::Segmentation(ncl[ir], xres[ir], yres[ir], index[jr]);
+ for(Int_t ic(ncl[ir]);ic--;) n[jr][index[jr][ic]]++;
}
+ mts += nts[jr];
+
+ // tracklet segment processing
+ for(Int_t its(0); its<nts[jr]; its++){
+ if(n[jr][its]<=2) { // don't touch small segments
+ xm[jr][its] = 0.;ym[jr][its] = 0.;sm[jr][its] = 0.;
+ for(Int_t ic(ncl[ir]); ic--;){
+ if(its != index[jr][ic]) continue;
+ ym[jr][its] += yres[ir][ic];
+ xm[jr][its] += xres[ir][ic];
+ sm[jr][its] += TMath::Sqrt(s2y[ir][ic]);
+ }
+ if(n[jr][its]==2){ xm[jr][its] *= 0.5; ym[jr][its] *= 0.5; sm[jr][its] *= 0.5;}
+ xm[jr][its]= fX0 - xm[jr][its];
+ r[jr][its] = 0.;
+ s[jr][its] = 1.e-5;
+ p[jr][its] = 1.;
+ continue;
+ }
+
+ // for longer tracklet segments
+ if(!kInit) n0 = helper.Init(pp, &clst[ir], index[jr], its);
+ Int_t n1 = helper.GetRMS(r[jr][its], ym[jr][its], s[jr][its], xm[jr][its]);
+ p[jr][its] = Double_t(n1)/n0;
+ sm[jr][its] = helper.GetSyMean();
+
+ Double_t dxm= fX0 - xm[jr][its];
+ yt = fYref[0] - fYref[1]*dxm;
+ zt = fZref[0] - fZref[1]*dxm;
+ // correct tracklet fit for tilt
+ ym[jr][its]+= GetTilt()*(zt - zc[ir]);
+ r[jr][its] += GetTilt() * fZref[1];
+ // correct tracklet fit for track position/inclination
+ ym[jr][its]= yt - ym[jr][its];
+ r[jr][its] = (r[jr][its] - fYref[1])/(1+r[jr][its]*fYref[1]);
+ // report inclination in radians
+ r[jr][its] = TMath::ATan(r[jr][its]);
+ if(jr) continue; // calculate only for first row likelihoods
+
+ f[its] = attach->CookLikelihood(chgPos, lyDet, fPt, phiTrk, n[jr][its], ym[jr][its]/*sRef*/, r[jr][its]*TMath::RadToDeg(), s[jr][its]/sm[jr][its]);
+ }
+ }
+ AliDebug(4, Form(" Tracklet candidates: row[%2d] = %2d row[%2d] = %2d:", idxRow[0], nts[0], idxRow[1], nts[1]));
+ if(AliLog::GetDebugLevel("TRD", "AliTRDseedV1")>3){
+ for(Int_t jr(0); jr<nrc; jr++){
+ Int_t ir(idxRow[jr]);
+ for(Int_t its(0); its<nts[jr]; its++){
+ printf(" segId[%2d] row[%2d] Ncl[%2d] x[cm]=%7.2f dz[pu]=%4.2f dy[mm]=%+7.3f r[deg]=%+6.2f p[%%]=%6.2f s[um]=%7.2f\n",
+ its, ir, n[jr][its], xm[jr][its], zresRow[jr], 1.e1*ym[jr][its], r[jr][its]*TMath::RadToDeg(), 100.*p[jr][its], 1.e4*s[jr][its]);
+ }
+ }
+ }
+ if(!pstreamer && recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 2 && fkReconstructor->IsDebugStreaming()) pstreamer = fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
+ if(pstreamer){
+ // save config. for calibration
+ TVectorD vidx, vn, vx, vy, vr, vs, vsm, vp, vf;
+ vidx.ResizeTo(ncl[idxRow[0]]+(idxRow[1]<0?0:ncl[idxRow[1]]));
+ vn.ResizeTo(mts);
+ vx.ResizeTo(mts);
+ vy.ResizeTo(mts);
+ vr.ResizeTo(mts);
+ vs.ResizeTo(mts);
+ vsm.ResizeTo(mts);
+ vp.ResizeTo(mts);
+ vf.ResizeTo(mts);
+ for(Int_t jr(0), jts(0), jc(0); jr<nrc; jr++){
+ Int_t ir(idxRow[jr]);
+ for(Int_t its(0); its<nts[jr]; its++, jts++){
+ vn[jts] = n[jr][its];
+ vx[jts] = xm[jr][its];
+ vy[jts] = ym[jr][its];
+ vr[jts] = r[jr][its];
+ vs[jts] = s[jr][its];
+ vsm[jts]= sm[jr][its];
+ vp[jts] = p[jr][its];
+ vf[jts] = jr?-1.:f[its];
+ }
+ for(Int_t ic(0); ic<ncl[ir]; ic++, jc++) vidx[jc] = index[jr][ic];
+ }
+ (*pstreamer) << "AttachClusters3"
+ << "idx=" << &vidx
+ << "n=" << &vn
+ << "x=" << &vx
+ << "y=" << &vy
+ << "r=" << &vr
+ << "s=" << &vs
+ << "sm=" << &vsm
+ << "p=" << &vp
+ << "f=" << &vf
+ << "\n";
+ }
- AliDebug(5, Form(" r[%d] n[%d]", ir, ncl[ir]));
- // Evaluate truncated mean on the y direction
- if(ncl[ir] < 4) continue;
- AliMathBase::EvaluateUni(ncl[ir], yres[ir], mean[nr], syDis[nr], Int_t(ncl[ir]*.8));
-
- // TODO check mean and sigma agains cluster resolution !!
- AliDebug(4, Form(" m_%d[%+5.3f (%5.3fs)] s[%f]", nr, mean[nr], TMath::Abs(mean[nr]/syDis[nr]), syDis[nr]));
- // remove outliers based on a 3 sigmaDistr level
- Bool_t kFOUND = kFALSE;
- for(Int_t ic = ncl[ir]; ic--;){
- if(yres[ir][ic] - mean[nr] > 3. * syDis[nr]){
- blst[ir][ic] = kFALSE; continue;
+//=========================================================
+ // Get seed tracklet segment
+ Int_t idx2[kNcls]; memset(idx2, 0, kNcls*sizeof(Int_t)); // seeding indexing
+ if(nts[0]>1) TMath::Sort(nts[0], f, idx2);
+ Int_t is(idx2[0]); // seed index
+ Int_t idxTrklt[kNcls],
+ kts(0),
+ nTrklt(n[0][is]);
+ Double_t fTrklt(f[is]),
+ rTrklt(r[0][is]),
+ yTrklt(ym[0][is]),
+ sTrklt(s[0][is]),
+ smTrklt(sm[0][is]),
+ xTrklt(xm[0][is]),
+ pTrklt(p[0][is]);
+ memset(idxTrklt, 0, kNcls*sizeof(Int_t));
+ // check seed idx2[0] exit if not found
+ if(f[is]<1.e-2){
+ AliDebug(1, Form("Seed seg[%d] row[%2d] n[%2d] f[%f]<0.01.", is, idxRow[0], n[0][is], f[is]));
+ SetErrorMsg(kAttachClAttach);
+ if(!pstreamer && recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 1 && fkReconstructor->IsDebugStreaming()) pstreamer = fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
+ if(pstreamer){
+ UChar_t stat(0);
+ if(IsKink()) SETBIT(stat, 1);
+ if(IsStandAlone()) SETBIT(stat, 2);
+ if(IsRowCross()) SETBIT(stat, 3);
+ SETBIT(stat, 4); // set error bit
+ TVectorD vidx; vidx.ResizeTo(1); vidx[0] = is;
+ (*pstreamer) << "AttachClusters2"
+ << "stat=" << stat
+ << "ev=" << ev
+ << "chg=" << chgPos
+ << "det=" << fDet
+ << "x0=" << fX0
+ << "y0=" << fYref[0]
+ << "z0=" << fZref[0]
+ << "phi=" << phiTrk
+ << "tht=" << thtTrk
+ << "pt=" << fPt
+ << "s2Trk=" << s2yTrk
+ << "s2Cl=" << s2Mean
+ << "idx=" << &vidx
+ << "n=" << nTrklt
+ << "f=" << fTrklt
+ << "x=" << xTrklt
+ << "y=" << yTrklt
+ << "r=" << rTrklt
+ << "s=" << sTrklt
+ << "sm=" << smTrklt
+ << "p=" << pTrklt
+ << "\n";
+ }
+ return kFALSE;
+ }
+ AliDebug(2, Form("Seed seg[%d] row[%2d] n[%2d] dy[%f] r[%+5.2f] s[%+5.2f] f[%5.3f]", is, idxRow[0], n[0][is], ym[0][is], r[0][is]*TMath::RadToDeg(), s[0][is]/sm[0][is], f[is]));
+
+ // save seeding segment in the helper
+ idxTrklt[kts++] = is;
+ helper.Init(pp, &clst[idxRow[0]], index[0], is);
+ AliTRDtrackletOflHelper test; // helper to test segment expantion
+ Float_t rcLikelihood(0.); SetBit(kRowCross, kFALSE);
+ Double_t dyRez[kNcls]; Int_t idx3[kNcls];
+
+ //=========================================================
+ // Define filter parameters from OCDB
+ Int_t kNSgmDy[2]; attach->GetNsgmDy(kNSgmDy[0], kNSgmDy[1]);
+ Float_t kLikeMinRelDecrease[2]; attach->GetLikeMinRelDecrease(kLikeMinRelDecrease[0], kLikeMinRelDecrease[1]);
+ Float_t kRClikeLimit(attach->GetRClikeLimit());
+
+ //=========================================================
+ // Try attaching next segments from first row (if any)
+ if(nts[0]>1){
+ Int_t jr(0), ir(idxRow[jr]);
+ // organize secondary sgms. in decreasing order of their distance from seed
+ memset(dyRez, 0, nts[jr]*sizeof(Double_t));
+ for(Int_t jts(1); jts<nts[jr]; jts++) {
+ Int_t its(idx2[jts]);
+ Double_t rot(TMath::Tan(r[0][is]));
+ dyRez[its] = TMath::Abs(ym[0][is] - ym[jr][its] + rot*(xm[0][is]-xm[jr][its]));
+ }
+ TMath::Sort(nts[jr], dyRez, idx3, kFALSE);
+ for (Int_t jts(1); jts<nts[jr]; jts++) {
+ Int_t its(idx3[jts]);
+ if(dyRez[its] > kNSgmDy[jr]*smTrklt){
+ AliDebug(2, Form("Reject seg[%d] row[%2d] n[%2d] dy[%f] > %d*s[%f].", its, idxRow[jr], n[jr][its], dyRez[its], kNSgmDy[jr], kNSgmDy[jr]*smTrklt));
+ continue;
+ }
+
+ test = helper;
+ Int_t n0 = test.Expand(&clst[ir], index[jr], its);
+ Double_t rt, dyt, st, xt, smt, pt, ft;
+ Int_t n1 = test.GetRMS(rt, dyt, st, xt);
+ pt = Double_t(n1)/n0;
+ smt = test.GetSyMean();
+ // correct position
+ Double_t dxm= fX0 - xt;
+ yt = fYref[0] - fYref[1]*dxm;
+ zt = fZref[0] - fZref[1]*dxm;
+ // correct tracklet fit for tilt
+ dyt+= GetTilt()*(zt - zc[idxRow[0]]);
+ rt += GetTilt() * fZref[1];
+ // correct tracklet fit for track position/inclination
+ dyt= yt - dyt;
+ rt = (rt - fYref[1])/(1+rt*fYref[1]);
+ // report inclination in radians
+ rt = TMath::ATan(rt);
+
+ ft = (n0>=2) ? attach->CookLikelihood(chgPos, lyDet, fPt, phiTrk, n0, dyt/*sRef*/, rt*TMath::RadToDeg(), st/smt) : 0.;
+ Bool_t kAccept(ft>=fTrklt*(1.-kLikeMinRelDecrease[jr]));
+
+ AliDebug(2, Form("%s seg[%d] row[%2d] n[%2d] dy[%f] r[%+5.2f] s[%+5.2f] f[%f] < %4.2f*F[%f].",
+ (kAccept?"Adding":"Reject"), its, idxRow[jr], n0, dyt, rt*TMath::RadToDeg(), st/smt, ft, 1.-kLikeMinRelDecrease[jr], fTrklt*(1.-kLikeMinRelDecrease[jr])));
+ if(kAccept){
+ idxTrklt[kts++] = its;
+ nTrklt = n0;
+ fTrklt = ft;
+ rTrklt = rt;
+ yTrklt = dyt;
+ sTrklt = st;
+ smTrklt= smt;
+ xTrklt = xt;
+ pTrklt = pt;
+ helper.Expand(&clst[ir], index[jr], its);
}
- nrow[nr]++; rowId[nr]=ir; kFOUND = kTRUE;
}
- if(kFOUND){
- vdy[nr].Use(nrow[nr], yres[ir]);
- nr++;
+ }
+
+ //=========================================================
+ // Try attaching next segments from second row (if any)
+ if(nts[1] && (rcLikelihood = zresRow[0]/zresRow[1]) > kRClikeLimit){
+ // organize secondaries in decreasing order of their distance from seed
+ Int_t jr(1), ir(idxRow[jr]);
+ memset(dyRez, 0, nts[jr]*sizeof(Double_t));
+ Double_t rot(TMath::Tan(r[0][is]));
+ for(Int_t jts(0); jts<nts[jr]; jts++) {
+ dyRez[jts] = TMath::Abs(ym[0][is] - ym[jr][jts] + rot*(xm[0][is]-xm[jr][jts]));
+ }
+ TMath::Sort(nts[jr], dyRez, idx3, kFALSE);
+ for (Int_t jts(0); jts<nts[jr]; jts++) {
+ Int_t its(idx3[jts]);
+ if(dyRez[its] > kNSgmDy[jr]*smTrklt){
+ AliDebug(2, Form("Reject seg[%d] row[%2d] n[%2d] dy[%f] > %d*s[%f].", its, idxRow[jr], n[jr][its], dyRez[its], kNSgmDy[jr], kNSgmDy[jr]*smTrklt));
+ continue;
+ }
+
+ test = helper;
+ Int_t n0 = test.Expand(&clst[ir], index[jr], its);
+ Double_t rt, dyt, st, xt, smt, pt, ft;
+ Int_t n1 = test.GetRMS(rt, dyt, st, xt);
+ pt = Double_t(n1)/n0;
+ smt = test.GetSyMean();
+ // correct position
+ Double_t dxm= fX0 - xt;
+ yt = fYref[0] - fYref[1]*dxm;
+ zt = fZref[0] - fZref[1]*dxm;
+ // correct tracklet fit for tilt
+ dyt+= GetTilt()*(zt - zc[idxRow[0]]);
+ rt += GetTilt() * fZref[1];
+ // correct tracklet fit for track position/inclination
+ dyt= yt - dyt;
+ rt = (rt - fYref[1])/(1+rt*fYref[1]);
+ // report inclination in radians
+ rt = TMath::ATan(rt);
+
+ ft = (n0>=2) ? attach->CookLikelihood(chgPos, lyDet, fPt, phiTrk, n0, dyt/*sRef*/, rt*TMath::RadToDeg(), st/smt) : 0.;
+ Bool_t kAccept(ft>=fTrklt*(1.-kLikeMinRelDecrease[jr]));
+
+ AliDebug(2, Form("%s seg[%d] row[%2d] n[%2d] dy[%f] r[%+5.2f] s[%+5.2f] f[%f] < %4.2f*F[%f].",
+ (kAccept?"Adding":"Reject"), its, idxRow[jr], n0, dyt, rt*TMath::RadToDeg(), st/smt, ft, 1.-kLikeMinRelDecrease[jr], fTrklt*(1.-kLikeMinRelDecrease[jr])));
+ if(kAccept){
+ idxTrklt[kts++] = its;
+ nTrklt = n0;
+ fTrklt = ft;
+ rTrklt = rt;
+ yTrklt = dyt;
+ sTrklt = st;
+ smTrklt= smt;
+ xTrklt = xt;
+ pTrklt = pt;
+ helper.Expand(&clst[ir], index[jr], its);
+ SetBit(kRowCross, kTRUE); // mark pad row crossing
+ }
}
- lr = ir; if(nr>=3) break;
}
- if(recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 3 && fkReconstructor->IsDebugStreaming()){
- TTreeSRedirector &cstreamer = *fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
+ // clear local copy of clusters
+ for(Int_t ir(0); ir<kNrows; ir++) clst[ir].Clear();
+
+ if(!pstreamer && recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 1 && fkReconstructor->IsDebugStreaming()) pstreamer = fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
+ if(pstreamer){
UChar_t stat(0);
if(IsKink()) SETBIT(stat, 1);
if(IsStandAlone()) SETBIT(stat, 2);
- cstreamer << "AttachClusters"
+ if(IsRowCross()) SETBIT(stat, 3);
+ TVectorD vidx; vidx.ResizeTo(kts);
+ for(Int_t its(0); its<kts; its++) vidx[its] = idxTrklt[its];
+ (*pstreamer) << "AttachClusters2"
<< "stat=" << stat
+ << "ev=" << ev
+ << "chg=" << chgPos
<< "det=" << fDet
+ << "x0=" << fX0
+ << "y0=" << fYref[0]
+ << "z0=" << fZref[0]
+ << "phi=" << phiTrk
+ << "tht=" << thtTrk
<< "pt=" << fPt
- << "s2y=" << s2yTrk
- << "r0=" << rowId[0]
- << "dy0=" << &vdy[0]
- << "m0=" << mean[0]
- << "s0=" << syDis[0]
- << "r1=" << rowId[1]
- << "dy1=" << &vdy[1]
- << "m1=" << mean[1]
- << "s1=" << syDis[1]
- << "r2=" << rowId[2]
- << "dy2=" << &vdy[2]
- << "m2=" << mean[2]
- << "s2=" << syDis[2]
+ << "s2Trk=" << s2yTrk
+ << "s2Cl=" << s2Mean
+ << "idx=" << &vidx
+ << "n=" << nTrklt
+ << "f=" << fTrklt
+ << "x=" << xTrklt
+ << "y=" << yTrklt
+ << "r=" << rTrklt
+ << "s=" << sTrklt
+ << "sm=" << smTrklt
+ << "p=" << pTrklt
<< "\n";
}
-
-
- // analyze gap in rows attached
- if(kRowSelection){
- SetErrorMsg(kAttachRowGap);
- Int_t rowRemove(-1);
- if(nr==2){ // select based on minimum distance to track projection
- if(TMath::Abs(mean[0])<TMath::Abs(mean[1])){
- if(nrow[1]>nrow[0]) AliDebug(2, Form("Conflicting mean[%f < %f] but ncl[%d < %d].", TMath::Abs(mean[0]), TMath::Abs(mean[1]), nrow[0], nrow[1]));
- }else{
- if(nrow[1]<nrow[0]) AliDebug(2, Form("Conflicting mean[%f > %f] but ncl[%d > %d].", TMath::Abs(mean[0]), TMath::Abs(mean[1]), nrow[0], nrow[1]));
- Swap(nrow[0],nrow[1]); Swap(rowId[0],rowId[1]);
- Swap(mean[0],mean[1]); Swap(syDis[0],syDis[1]);
- }
- rowRemove=1; nr=1;
- } else if(nr==3){ // select based on 2 consecutive rows
- if(rowId[1]==rowId[0]+1 && rowId[1]!=rowId[2]-1){
- nr=2;rowRemove=2;
- } else if(rowId[1]!=rowId[0]+1 && rowId[1]==rowId[2]-1){
- Swap(nrow[0],nrow[2]); Swap(rowId[0],rowId[2]);
- Swap(mean[0],mean[2]); Swap(syDis[0],syDis[2]);
- nr=2; rowRemove=2;
- }
- }
- if(rowRemove>0){nrow[rowRemove]=0; rowId[rowRemove]=-1;}
- }
- AliDebug(4, Form(" Ncl[%d[%d] + %d[%d] + %d[%d]]", nrow[0], rowId[0], nrow[1], rowId[1], nrow[2], rowId[2]));
-
- if(nr==3){
- SetBit(kRowCross, kTRUE); // mark pad row crossing
- SetErrorMsg(kAttachRow);
- const Float_t am[]={TMath::Abs(mean[0]), TMath::Abs(mean[1]), TMath::Abs(mean[2])};
- AliDebug(4, Form("complex row configuration\n"
- " r[%d] n[%d] m[%6.3f] s[%6.3f]\n"
- " r[%d] n[%d] m[%6.3f] s[%6.3f]\n"
- " r[%d] n[%d] m[%6.3f] s[%6.3f]\n"
- , rowId[0], nrow[0], am[0], syDis[0]
- , rowId[1], nrow[1], am[1], syDis[1]
- , rowId[2], nrow[2], am[2], syDis[2]));
- Int_t id[]={0,1,2}; TMath::Sort(3, am, id, kFALSE);
- // backup
- Int_t rnn[3]; memcpy(rnn, nrow, 3*sizeof(Int_t));
- Int_t rid[3]; memcpy(rid, rowId, 3*sizeof(Int_t));
- Double_t rm[3]; memcpy(rm, mean, 3*sizeof(Double_t));
- Double_t rs[3]; memcpy(rs, syDis, 3*sizeof(Double_t));
- nrow[0]=rnn[id[0]]; rowId[0]=rid[id[0]]; mean[0]=rm[id[0]]; syDis[0]=rs[id[0]];
- nrow[1]=rnn[id[1]]; rowId[1]=rid[id[1]]; mean[1]=rm[id[1]]; syDis[1]=rs[id[1]];
- nrow[2]=0; rowId[2]=-1; mean[2] = 1.e3; syDis[2] = 1.e3;
- AliDebug(4, Form("solved configuration\n"
- " r[%d] n[%d] m[%+6.3f] s[%6.3f]\n"
- " r[%d] n[%d] m[%+6.3f] s[%6.3f]\n"
- " r[%d] n[%d] m[%+6.3f] s[%6.3f]\n"
- , rowId[0], nrow[0], mean[0], syDis[0]
- , rowId[1], nrow[1], mean[1], syDis[1]
- , rowId[2], nrow[2], mean[2], syDis[2]));
- nr=2;
- } else if(nr==2) {
- SetBit(kRowCross, kTRUE); // mark pad row crossing
- if(nrow[1] > nrow[0]){ // swap row order
- Swap(nrow[0],nrow[1]); Swap(rowId[0],rowId[1]);
- Swap(mean[0],mean[1]); Swap(syDis[0],syDis[1]);
- }
+
+
+ //=========================================================
+ // Store clusters
+ Int_t nselected(0), nc(0);
+ TObjArray *selected(helper.GetClusters());
+ if(!selected || !(nselected = selected->GetEntriesFast())){
+ AliError("Cluster candidates missing !!!");
+ SetErrorMsg(kAttachClAttach);
+ return kFALSE;
}
-
- // Select and store clusters
- // We should consider here :
- // 1. How far is the chamber boundary
- // 2. How big is the mean
- Int_t n(0); Float_t dyc[kNclusters]; memset(dyc,0,kNclusters*sizeof(Float_t));
- for (Int_t ir = 0; ir < nr; ir++) {
- Int_t jr(rowId[ir]);
- AliDebug(4, Form(" Attaching Ncl[%d]=%d ...", jr, ncl[jr]));
- for (Int_t ic = 0; ic < ncl[jr]; ic++) {
- if(!blst[jr][ic])continue;
- c = clst[jr][ic];
- Int_t it(c->GetPadTime());
- Int_t idx(it+kNtb*ir);
- if(fClusters[idx]){
- AliDebug(4, Form("Many cluster candidates on row[%2d] tb[%2d].", jr, it));
- // TODO should save also the information on where the multiplicity happened and its size
- SetErrorMsg(kAttachMultipleCl);
- // TODO should also compare with mean and sigma for this row
- if(yres[jr][ic] > dyc[idx]) continue;
- }
-
- // TODO proper indexing of clusters !!
- fIndexes[idx] = chamber->GetTB(it)->GetGlobalIndex(idxs[jr][ic]);
- fClusters[idx] = c;
- dyc[idx] = yres[jr][ic];
- n++;
+ for(Int_t ic(0); ic<nselected; ic++){
+ if(!(c = (AliTRDcluster*)selected->At(ic))) continue;
+ Int_t it(c->GetPadTime()),
+ jr(Int_t(helper.GetRow() != c->GetPadRow())),
+ idx(it+kNtb*jr);
+ if(fClusters[idx]){
+ AliDebug(1, Form("Multiple clusters/tb for D[%03d] Tb[%02d] Row[%2d]", fDet, it, c->GetPadRow()));
+ continue; // already booked
}
+ // TODO proper indexing of clusters !!
+ fIndexes[idx] = chamber->GetTB(it)->GetGlobalIndex(idxs[idxRow[jr]][ic]);
+ fClusters[idx] = c;
+ nc++;
}
- SetN(n);
+ AliDebug(2, Form("Clusters Found[%2d] Attached[%2d] RC[%c]", nselected, nc, IsRowCross()?'y':'n'));
// number of minimum numbers of clusters expected for the tracklet
- if (GetN() < kClmin){
- AliDebug(1, Form("NOT ENOUGH CLUSTERS %d ATTACHED TO THE TRACKLET [min %d] FROM FOUND %d.", GetN(), kClmin, n));
+ if (nc < kClmin){
+ AliDebug(1, Form("NOT ENOUGH CLUSTERS %d ATTACHED TO THE TRACKLET [min %d] FROM FOUND %d.", nc, kClmin, ncls));
SetErrorMsg(kAttachClAttach);
return kFALSE;
}
+ SetN(nc);
// Load calibration parameters for this tracklet
- Calibrate();
+ //Calibrate();
// calculate dx for time bins in the drift region (calibration aware)
Float_t x[2] = {0.,0.}; Int_t tb[2]={0,0};
const Char_t *tcName[]={"NONE", "FULL", "HALF"};
AliDebug(2, Form("Options : TC[%s] dzdx[%c]", tcName[opt], kDZDX?'Y':'N'));
+
for (Int_t ic=0; ic<kNclusters; ic++, ++jc) {
xc[ic] = -1.; yc[ic] = 999.; zc[ic] = 999.; sy[ic] = 0.;
if(!(c = (*jc))) continue;
// to few clusters
if (n < kClmin){
+ AliDebug(1, Form("Not enough clusters to fit. Clusters: Attached[%d] Fit[%d].", GetN(), n));
SetErrorMsg(kFitCl);
return kFALSE;
}
-
// fit XY
if(!fitterY.Eval()){
+ AliDebug(1, "Fit Y failed.");
SetErrorMsg(kFitFailedY);
return kFALSE;
}
// fit QZ
if(opt!=1 && IsRowCross()){
if(!fitterZ.Eval()) SetErrorMsg(kFitFailedZ);
- if(!HasError(kFitFailedZ) && fitterZ.GetFunctionParameter(1)!=0.){
+ if(!HasError(kFitFailedZ) && TMath::Abs(fitterZ.GetFunctionParameter(1))>1.e-10){
// TODO - one has to recalculate xy fit based on
// better knowledge of z position
// Double_t x = -fitterZ.GetFunctionParameter(0)/fitterZ.GetFunctionParameter(1);
}
-/*
-//_____________________________________________________________________________
-void AliTRDseedV1::FitMI()
+//____________________________________________________________________
+Bool_t AliTRDseedV1::FitRobust(Bool_t chg)
{
//
-// Fit the seed.
-// Marian Ivanov's version
+// Linear fit of the clusters attached to the tracklet
//
-// linear fit on the y direction with respect to the reference direction.
-// The residuals for each x (x = xc - x0) are deduced from:
-// dy = y - yt (1)
-// the tilting correction is written :
-// y = yc + h*(zc-zt) (2)
-// yt = y0+dy/dx*x (3)
-// zt = z0+dz/dx*x (4)
-// from (1),(2),(3) and (4)
-// dy = yc - y0 - (dy/dx + h*dz/dx)*x + h*(zc-z0)
-// the last term introduces the correction on y direction due to tilting pads. There are 2 ways to account for this:
-// 1. use tilting correction for calculating the y
-// 2. neglect tilting correction here and account for it in the error parametrization of the tracklet.
- const Float_t kRatio = 0.8;
- const Int_t kClmin = 5;
- const Float_t kmaxtan = 2;
-
- if (TMath::Abs(fYref[1]) > kmaxtan){
- //printf("Exit: Abs(fYref[1]) = %3.3f, kmaxtan = %3.3f\n", TMath::Abs(fYref[1]), kmaxtan);
- return; // Track inclined too much
- }
-
- Float_t sigmaexp = 0.05 + TMath::Abs(fYref[1] * 0.25); // Expected r.m.s in y direction
- Float_t ycrosscor = GetPadLength() * GetTilt() * 0.5; // Y correction for crossing
- Int_t fNChange = 0;
-
- Double_t sumw;
- Double_t sumwx;
- Double_t sumwx2;
- Double_t sumwy;
- Double_t sumwxy;
- Double_t sumwz;
- Double_t sumwxz;
-
- // Buffering: Leave it constant fot Performance issues
- Int_t zints[kNtb]; // Histograming of the z coordinate
- // Get 1 and second max probable coodinates in z
- Int_t zouts[2*kNtb];
- Float_t allowedz[kNtb]; // Allowed z for given time bin
- Float_t yres[kNtb]; // Residuals from reference
- //Float_t anglecor = GetTilt() * fZref[1]; // Correction to the angle
-
- Float_t pos[3*kNtb]; memset(pos, 0, 3*kNtb*sizeof(Float_t));
- Float_t *fX = &pos[0], *fY = &pos[kNtb], *fZ = &pos[2*kNtb];
-
- Int_t fN = 0; AliTRDcluster *c = 0x0;
- fN2 = 0;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
- yres[i] = 10000.0;
- if (!(c = fClusters[i])) continue;
- if(!c->IsInChamber()) continue;
- // Residual y
- //yres[i] = fY[i] - fYref[0] - (fYref[1] + anglecor) * fX[i] + GetTilt()*(fZ[i] - fZref[0]);
- fX[i] = fX0 - c->GetX();
- fY[i] = c->GetY();
- fZ[i] = c->GetZ();
- yres[i] = fY[i] - GetTilt()*(fZ[i] - (fZref[0] - fX[i]*fZref[1]));
- zints[fN] = Int_t(fZ[i]);
- fN++;
- }
-
- if (fN < kClmin){
- //printf("Exit fN < kClmin: fN = %d\n", fN);
- return;
- }
- Int_t nz = AliTRDtrackerV1::Freq(fN, zints, zouts, kFALSE);
- Float_t fZProb = zouts[0];
- if (nz <= 1) zouts[3] = 0;
- if (zouts[1] + zouts[3] < kClmin) {
- //printf("Exit zouts[1] = %d, zouts[3] = %d\n",zouts[1],zouts[3]);
- return;
- }
-
- // Z distance bigger than pad - length
- if (TMath::Abs(zouts[0]-zouts[2]) > 12.0) zouts[3] = 0;
-
- Int_t breaktime = -1;
- Bool_t mbefore = kFALSE;
- Int_t cumul[kNtb][2];
- Int_t counts[2] = { 0, 0 };
-
- if (zouts[3] >= 3) {
-
- //
- // Find the break time allowing one chage on pad-rows
- // with maximal number of accepted clusters
- //
- fNChange = 1;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
- cumul[i][0] = counts[0];
- cumul[i][1] = counts[1];
- if (TMath::Abs(fZ[i]-zouts[0]) < 2) counts[0]++;
- if (TMath::Abs(fZ[i]-zouts[2]) < 2) counts[1]++;
- }
- Int_t maxcount = 0;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
- Int_t after = cumul[AliTRDtrackerV1::GetNTimeBins()][0] - cumul[i][0];
- Int_t before = cumul[i][1];
- if (after + before > maxcount) {
- maxcount = after + before;
- breaktime = i;
- mbefore = kFALSE;
- }
- after = cumul[AliTRDtrackerV1::GetNTimeBins()-1][1] - cumul[i][1];
- before = cumul[i][0];
- if (after + before > maxcount) {
- maxcount = after + before;
- breaktime = i;
- mbefore = kTRUE;
- }
- }
- breaktime -= 1;
- }
+// Author
+// A.Bercuci <A.Bercuci@gsi.de>
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
- if (i > breaktime) allowedz[i] = mbefore ? zouts[2] : zouts[0];
- if (i <= breaktime) allowedz[i] = (!mbefore) ? zouts[2] : zouts[0];
- }
+ TTreeSRedirector *pstreamer(NULL);
+ const AliTRDrecoParam* const recoParam = fkReconstructor->GetRecoParam(); if(recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) > 3 && fkReconstructor->IsDebugStreaming()) pstreamer = fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
- if (((allowedz[0] > allowedz[AliTRDtrackerV1::GetNTimeBins()]) && (fZref[1] < 0)) ||
- ((allowedz[0] < allowedz[AliTRDtrackerV1::GetNTimeBins()]) && (fZref[1] > 0))) {
- //
- // Tracklet z-direction not in correspondance with track z direction
- //
- fNChange = 0;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
- allowedz[i] = zouts[0]; // Only longest taken
- }
- }
-
- if (fNChange > 0) {
- //
- // Cross pad -row tracklet - take the step change into account
- //
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
- if (!fClusters[i]) continue;
- if(!fClusters[i]->IsInChamber()) continue;
- if (TMath::Abs(fZ[i] - allowedz[i]) > 2) continue;
- // Residual y
- //yres[i] = fY[i] - fYref[0] - (fYref[1] + anglecor) * fX[i] + GetTilt()*(fZ[i] - fZref[0]);
- yres[i] = fY[i] - GetTilt()*(fZ[i] - (fZref[0] - fX[i]*fZref[1]));
-// if (TMath::Abs(fZ[i] - fZProb) > 2) {
-// if (fZ[i] > fZProb) yres[i] += GetTilt() * GetPadLength();
-// if (fZ[i] < fZProb) yres[i] -= GetTilt() * GetPadLength();
- }
+ // factor to scale y pulls.
+ // ideally if error parametrization correct this is 1.
+ //Float_t lyScaler = 1./(AliTRDgeometry::GetLayer(fDet)+1.);
+ Float_t kScalePulls = 1.;
+ AliTRDcalibDB *calibration = AliTRDcalibDB::Instance();
+ if(!calibration){
+ AliWarning("No access to calibration data");
+ } else {
+ // Retrieve the CDB container class with the parametric likelihood
+ const AliTRDCalTrkAttach *attach = calibration->GetAttachObject();
+ if(!attach){
+ AliWarning("No usable AttachClusters calib object.");
+ } else {
+ kScalePulls = attach->GetScaleCov();//*lyScaler;
}
+ }
+ Double_t xc[kNclusters], yc[kNclusters], sy[kNclusters];
+ Int_t n(0), // clusters used in fit
+ row[]={-1, 0}; // pad row spanned by the tracklet
+ AliTRDcluster *c(NULL), **jc = &fClusters[0];
+ for(Int_t ic=0; ic<kNtb; ic++, ++jc) {
+ if(!(c = (*jc))) continue;
+ if(!c->IsInChamber()) continue;
+ if(row[0]<0){
+ fZfit[0] = c->GetZ();
+ fZfit[1] = 0.;
+ row[0] = c->GetPadRow();
+ }
+ xc[n] = fX0 - c->GetX();
+ yc[n] = c->GetY();
+ sy[n] = c->GetSigmaY2()>0?(TMath::Min(TMath::Sqrt(c->GetSigmaY2()), 0.08)):0.08;
+ n++;
}
-
- Double_t yres2[kNtb];
- Double_t mean;
- Double_t sigma;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
- if (!fClusters[i]) continue;
- if(!fClusters[i]->IsInChamber()) continue;
- if (TMath::Abs(fZ[i] - allowedz[i]) > 2) continue;
- yres2[fN2] = yres[i];
- fN2++;
- }
- if (fN2 < kClmin) {
- //printf("Exit fN2 < kClmin: fN2 = %d\n", fN2);
- fN2 = 0;
- return;
- }
- AliMathBase::EvaluateUni(fN2,yres2,mean,sigma, Int_t(fN2*kRatio-2.));
- if (sigma < sigmaexp * 0.8) {
- sigma = sigmaexp;
- }
- //Float_t fSigmaY = sigma;
-
- // Reset sums
- sumw = 0;
- sumwx = 0;
- sumwx2 = 0;
- sumwy = 0;
- sumwxy = 0;
- sumwz = 0;
- sumwxz = 0;
-
- fN2 = 0;
- Float_t fMeanz = 0;
- Float_t fMPads = 0;
- fUsable = 0;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
- if (!fClusters[i]) continue;
- if (!fClusters[i]->IsInChamber()) continue;
- if (TMath::Abs(fZ[i] - allowedz[i]) > 2){fClusters[i] = 0x0; continue;}
- if (TMath::Abs(yres[i] - mean) > 4.0 * sigma){fClusters[i] = 0x0; continue;}
- SETBIT(fUsable,i);
- fN2++;
- fMPads += fClusters[i]->GetNPads();
- Float_t weight = 1.0;
- if (fClusters[i]->GetNPads() > 4) weight = 0.5;
- if (fClusters[i]->GetNPads() > 5) weight = 0.2;
-
-
- Double_t x = fX[i];
- //printf("x = %7.3f dy = %7.3f fit %7.3f\n", x, yres[i], fY[i]-yres[i]);
-
- sumw += weight;
- sumwx += x * weight;
- sumwx2 += x*x * weight;
- sumwy += weight * yres[i];
- sumwxy += weight * (yres[i]) * x;
- sumwz += weight * fZ[i];
- sumwxz += weight * fZ[i] * x;
+ Double_t corr = fPad[2]*fPad[0];
+ for(Int_t ic=kNtb; ic<kNclusters; ic++, ++jc) {
+ if(!(c = (*jc))) continue;
+ if(!c->IsInChamber()) continue;
+ if(row[1]==0) row[1] = c->GetPadRow() - row[0];
+ xc[n] = fX0 - c->GetX();
+ yc[n] = c->GetY() + corr*row[1];
+ sy[n] = c->GetSigmaY2()>0?(TMath::Min(TMath::Sqrt(c->GetSigmaY2()), 0.08)):0.08;
+ n++;
}
-
- if (fN2 < kClmin){
- //printf("Exit fN2 < kClmin(2): fN2 = %d\n",fN2);
- fN2 = 0;
- return;
+ UChar_t status(0);
+ Double_t par[3] = {0.,0.,21122012.}, cov[3];
+ if(!AliTRDtrackletOflHelper::Fit(n, xc, yc, sy, par, 1.5, cov)){
+ AliDebug(1, Form("Tracklet fit failed D[%03d].", fDet));
+ SetErrorMsg(kFitCl);
+ return kFALSE;
}
- fMeanz = sumwz / sumw;
- Float_t correction = 0;
- if (fNChange > 0) {
- // Tracklet on boundary
- if (fMeanz < fZProb) correction = ycrosscor;
- if (fMeanz > fZProb) correction = -ycrosscor;
+ fYfit[0] = par[0];
+ fYfit[1] = -par[1];
+ // store covariance
+ fCov[0] = kScalePulls*cov[0]; // variance of y0
+ fCov[1] = kScalePulls*cov[2]; // covariance of y0, dydx
+ fCov[2] = kScalePulls*cov[1]; // variance of dydx
+ // the ref radial position is set at the minimum of
+ // the y variance of the tracklet
+ fX = -fCov[1]/fCov[2];
+ // check radial position
+ Float_t xs=fX+.5*AliTRDgeometry::CamHght();
+ if(xs < 0. || xs > AliTRDgeometry::CamHght()+AliTRDgeometry::CdrHght()){
+ AliDebug(1, Form("Ref radial position x[%5.2f] ouside D[%3d].", fX, fDet));
+ SetErrorMsg(kFitFailedY);
+ return kFALSE;
+ }
+ fS2Y = fCov[0] + fX*fCov[1];
+ fS2Z = fPad[0]*fPad[0]/12.;
+ AliDebug(2, Form("[I] x[cm]=%6.2f y[cm]=%+5.2f z[cm]=%+6.2f dydx[deg]=%+5.2f sy[um]=%6.2f sz[cm]=%6.2f", GetX(), GetY(), GetZ(), TMath::ATan(fYfit[1])*TMath::RadToDeg(), TMath::Sqrt(fS2Y)*1.e4, TMath::Sqrt(fS2Z)));
+ if(IsRowCross()){
+ Float_t x,z;
+ if(!GetEstimatedCrossPoint(x,z)){
+ AliDebug(2, Form("Failed getting crossing point D[%03d].", fDet));
+ SetErrorMsg(kFitFailedY);
+ return kTRUE;
+ }
+ fX = fX0-x;
+ fS2Y = fCov[0] + fX*fCov[1];
+ fZfit[0] = z;
+ if(IsPrimary()){
+ fZfit[1] = z/x;
+ fS2Z = 0.05+0.4*TMath::Abs(fZfit[1]); fS2Z *= fS2Z;
+ }
+ AliDebug(2, Form("[II] x[cm]=%6.2f y[cm]=%+5.2f z[cm]=%+6.2f dydx[deg]=%+5.2f sy[um]=%6.2f sz[um]=%6.2f dzdx[deg]=%+5.2f", GetX(), GetY(), GetZ(), TMath::ATan(fYfit[1])*TMath::RadToDeg(), TMath::Sqrt(fS2Y)*1.e4, TMath::Sqrt(fS2Z)*1.e4, TMath::ATan(fZfit[1])*TMath::RadToDeg()));
}
-
- Double_t det = sumw * sumwx2 - sumwx * sumwx;
- fYfit[0] = (sumwx2 * sumwy - sumwx * sumwxy) / det;
- fYfit[1] = (sumw * sumwxy - sumwx * sumwy) / det;
-
- fS2Y = 0;
- for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
- if (!TESTBIT(fUsable,i)) continue;
- Float_t delta = yres[i] - fYfit[0] - fYfit[1] * fX[i];
- fS2Y += delta*delta;
- }
- fS2Y = TMath::Sqrt(fS2Y / Float_t(fN2-2));
- // TEMPORARY UNTIL covariance properly calculated
- fS2Y = TMath::Max(fS2Y, Float_t(.1));
- fZfit[0] = (sumwx2 * sumwz - sumwx * sumwxz) / det;
- fZfit[1] = (sumw * sumwxz - sumwx * sumwz) / det;
-// fYfitR[0] += fYref[0] + correction;
-// fYfitR[1] += fYref[1];
-// fYfit[0] = fYfitR[0];
- fYfit[1] = -fYfit[1];
-
- UpdateUsed();
-}*/
+ if(pstreamer){
+ Float_t x= fX0 -fX,
+ y = GetY(),
+ yt = fYref[0]-fX*fYref[1];
+ SETBIT(status, 2);
+ TVectorD vcov(3); vcov[0]=cov[0];vcov[1]=cov[1];vcov[2]=cov[2];
+ Double_t sm(0.), chi2(0.), tmp, dy[kNclusters];
+ for(Int_t ic(0); ic<n; ic++){
+ sm += sy[ic];
+ dy[ic] = yc[ic]-(fYfit[0]-xc[ic]*fYfit[1]); tmp = dy[ic]/sy[ic];
+ chi2 += tmp*tmp;
+ }
+ sm /= n; chi2 = TMath::Sqrt(chi2);
+ Double_t m(0.), s(0.);
+ AliMathBase::EvaluateUni(n, dy, m, s, 0);
+ (*pstreamer) << "FitRobust4"
+ << "stat=" << status
+ << "chg=" << chg
+ << "ncl=" << n
+ << "det=" << fDet
+ << "x0=" << fX0
+ << "y0=" << fYfit[0]
+ << "x=" << x
+ << "y=" << y
+ << "dydx=" << fYfit[1]
+ << "pt=" << fPt
+ << "yt=" << yt
+ << "dydxt="<< fYref[1]
+ << "cov=" << &vcov
+ << "chi2=" << chi2
+ << "sm=" << sm
+ << "ss=" << s
+ << "\n";
+ }
+ return kTRUE;
+}
//___________________________________________________________________
void AliTRDseedV1::Print(Option_t *o) const
if ( fZref[i] != inTracklet->fZref[i] ) return kFALSE;
}
- if ( fS2Y != inTracklet->fS2Y ) return kFALSE;
- if ( GetTilt() != inTracklet->GetTilt() ) return kFALSE;
- if ( GetPadLength() != inTracklet->GetPadLength() ) return kFALSE;
+ if ( TMath::Abs(fS2Y - inTracklet->fS2Y)>1.e-10 ) return kFALSE;
+ if ( TMath::Abs(GetTilt() - inTracklet->GetTilt())>1.e-10 ) return kFALSE;
+ if ( TMath::Abs(GetPadLength() - inTracklet->GetPadLength())>1.e-10 ) return kFALSE;
for (Int_t i = 0; i < kNclusters; i++){
// if ( fX[i] != inTracklet->GetX(i) ) return kFALSE;
//if ( fFreq != inTracklet->GetFreq() ) return kFALSE;
//if ( fNChange != inTracklet->GetNChange() ) return kFALSE;
- if ( fC != inTracklet->fC ) return kFALSE;
+ if ( TMath::Abs(fC[0] - inTracklet->fC[0])>1.e-10 ) return kFALSE;
//if ( fCC != inTracklet->GetCC() ) return kFALSE;
- if ( fChi2 != inTracklet->fChi2 ) return kFALSE;
+ if ( TMath::Abs(fChi2 - inTracklet->fChi2)>1.e-10 ) return kFALSE;
// if ( fChi2Z != inTracklet->GetChi2Z() ) return kFALSE;
if ( fDet != inTracklet->fDet ) return kFALSE;
- if ( fPt != inTracklet->fPt ) return kFALSE;
- if ( fdX != inTracklet->fdX ) return kFALSE;
+ if ( TMath::Abs(fPt - inTracklet->fPt)>1.e-10 ) return kFALSE;
+ if ( TMath::Abs(fdX - inTracklet->fdX)>1.e-10 ) return kFALSE;
for (Int_t iCluster = 0; iCluster < kNclusters; iCluster++){
AliTRDcluster *curCluster = fClusters[iCluster];