* provided "as is" without express or implied warranty. *
**************************************************************************/
-/*
-$Log$
-Revision 1.20 2002/11/07 15:52:09 cblume
-Update of tracking code for tilted pads
+/* $Id$ */
-Revision 1.19 2002/10/22 15:53:08 alibrary
-Introducing Riostream.h
-
-Revision 1.18 2002/10/14 14:57:44 hristov
-Merging the VirtualMC branch to the main development branch (HEAD)
-
-Revision 1.14.6.2 2002/07/24 10:09:31 alibrary
-Updating VirtualMC
-
-Revision 1.17 2002/06/13 12:09:58 hristov
-Minor corrections
-
-Revision 1.16 2002/06/12 09:54:36 cblume
-Update of tracking code provided by Sergei
-
-Revision 1.14 2001/11/14 10:50:46 cblume
-Changes in digits IO. Add merging of summable digits
-
-Revision 1.13 2001/05/30 12:17:47 hristov
-Loop variables declared once
-
-Revision 1.12 2001/05/28 17:07:58 hristov
-Last minute changes; ExB correction in AliTRDclusterizerV1; taking into account of material in G10 TEC frames and material between TEC planes (C.Blume,S.Sedykh)
-
-Revision 1.8 2000/12/20 13:00:44 cblume
-Modifications for the HP-compiler
-
-Revision 1.7 2000/12/08 16:07:02 cblume
-Update of the tracking by Sergei
-
-Revision 1.6 2000/11/30 17:38:08 cblume
-Changes to get in line with new STEER and EVGEN
-
-Revision 1.5 2000/11/14 14:40:27 cblume
-Correction for the Sun compiler (kTRUE and kFALSE)
-
-Revision 1.4 2000/11/10 14:57:52 cblume
-Changes in the geometry constants for the DEC compiler
-
-Revision 1.3 2000/10/15 23:40:01 cblume
-Remove AliTRDconst
-
-Revision 1.2 2000/10/06 16:49:46 cblume
-Made Getters const
-
-Revision 1.1.2.2 2000/10/04 16:34:58 cblume
-Replace include files by forward declarations
-
-Revision 1.1.2.1 2000/09/22 14:47:52 cblume
-Add the tracking code
-
-*/
+///////////////////////////////////////////////////////////////////////////////
+// //
+// The standard TRD tracker //
+// //
+///////////////////////////////////////////////////////////////////////////////
#include <Riostream.h>
-
#include <TFile.h>
#include <TBranch.h>
#include <TTree.h>
#include "AliTRDgeometry.h"
#include "AliTRDparameter.h"
+#include "AliTRDpadPlane.h"
#include "AliTRDgeometryDetail.h"
#include "AliTRDcluster.h"
#include "AliTRDtrack.h"
-#include "../TPC/AliTPCtrack.h"
+#include "AliESD.h"
+#include "TTreeStream.h"
+#include "TGraph.h"
#include "AliTRDtracker.h"
+//
ClassImp(AliTRDtracker)
- const Float_t AliTRDtracker::fSeedDepth = 0.5;
- const Float_t AliTRDtracker::fSeedStep = 0.10;
- const Float_t AliTRDtracker::fSeedGap = 0.25;
+ const Float_t AliTRDtracker::fgkSeedDepth = 0.5;
+ const Float_t AliTRDtracker::fgkSeedStep = 0.10;
+ const Float_t AliTRDtracker::fgkSeedGap = 0.25;
- const Float_t AliTRDtracker::fMaxSeedDeltaZ12 = 40.;
- const Float_t AliTRDtracker::fMaxSeedDeltaZ = 25.;
- const Float_t AliTRDtracker::fMaxSeedC = 0.0052;
- const Float_t AliTRDtracker::fMaxSeedTan = 1.2;
- const Float_t AliTRDtracker::fMaxSeedVertexZ = 150.;
+ const Float_t AliTRDtracker::fgkMaxSeedDeltaZ12 = 40.;
+ const Float_t AliTRDtracker::fgkMaxSeedDeltaZ = 25.;
+ const Float_t AliTRDtracker::fgkMaxSeedC = 0.0052;
+ const Float_t AliTRDtracker::fgkMaxSeedTan = 1.2;
+ const Float_t AliTRDtracker::fgkMaxSeedVertexZ = 150.;
- const Double_t AliTRDtracker::fSeedErrorSY = 0.2;
- const Double_t AliTRDtracker::fSeedErrorSY3 = 2.5;
- const Double_t AliTRDtracker::fSeedErrorSZ = 0.1;
+ const Double_t AliTRDtracker::fgkSeedErrorSY = 0.2;
+ const Double_t AliTRDtracker::fgkSeedErrorSY3 = 2.5;
+ const Double_t AliTRDtracker::fgkSeedErrorSZ = 0.1;
- const Float_t AliTRDtracker::fMinClustersInSeed = 0.7;
+ const Float_t AliTRDtracker::fgkMinClustersInSeed = 0.7;
- const Float_t AliTRDtracker::fMinClustersInTrack = 0.5;
- const Float_t AliTRDtracker::fMinFractionOfFoundClusters = 0.8;
+ const Float_t AliTRDtracker::fgkMinClustersInTrack = 0.5;
+ const Float_t AliTRDtracker::fgkMinFractionOfFoundClusters = 0.8;
- const Float_t AliTRDtracker::fSkipDepth = 0.05;
- const Float_t AliTRDtracker::fLabelFraction = 0.8;
- const Float_t AliTRDtracker::fWideRoad = 20.;
+ const Float_t AliTRDtracker::fgkSkipDepth = 0.3;
+ const Float_t AliTRDtracker::fgkLabelFraction = 0.8;
+ const Float_t AliTRDtracker::fgkWideRoad = 20.;
- const Double_t AliTRDtracker::fMaxChi2 = 12.;
+ const Double_t AliTRDtracker::fgkMaxChi2 = 12.;
+// const Double_t AliTRDtracker::fgkOffset = -0.012;
+// const Double_t AliTRDtracker::fgkOffsetX = 0.35;
+// const Double_t AliTRDtracker::fgkCoef = 0.00;
+// const Double_t AliTRDtracker::fgkMean = 8.;
+// const Double_t AliTRDtracker::fgkDriftCorrection = 1.07;
+// const Double_t AliTRDtracker::fgkExB = 0.072;
+
+ const Double_t AliTRDtracker::fgkOffset = -0.015;
+const Double_t AliTRDtracker::fgkOffsetX = 0.26; // "time offset"
+ const Double_t AliTRDtracker::fgkCoef = 0.0096; // angular shift
+ const Double_t AliTRDtracker::fgkMean = 0.;
+ const Double_t AliTRDtracker::fgkDriftCorrection = 1.04; // drift coefficient correction
+ const Double_t AliTRDtracker::fgkExB = 0.072; // ExB angle - for error parameterization
+
+
+// poscorrection = fgkCoef*(GetLocalTimeBin() - fgkMean)+fgkOffset;
+
+const Int_t AliTRDtracker::fgkFirstPlane = 5;
+const Int_t AliTRDtracker::fgkLastPlane = 17;
//____________________________________________________________________
-AliTRDtracker::AliTRDtracker(const TFile *geomfile)
+AliTRDtracker::AliTRDtracker():AliTracker(),
+ fGeom(0),
+ fPar(0),
+ fNclusters(0),
+ fClusters(0),
+ fNseeds(0),
+ fSeeds(0),
+ fNtracks(0),
+ fTracks(0),
+ fSY2corr(0),
+ fSZ2corr(0),
+ fTimeBinsPerPlane(0),
+ fMaxGap(0),
+ fVocal(kFALSE),
+ fAddTRDseeds(kFALSE),
+ fNoTilt(kFALSE)
+{
+ // Default constructor
+
+ for(Int_t i=0;i<kTrackingSectors;i++) fTrSec[i]=0;
+ for(Int_t j=0;j<5;j++)
+ for(Int_t k=0;k<18;k++) fHoles[j][k]=kFALSE;
+ fDebugStreamer = 0;
+}
+//____________________________________________________________________
+AliTRDtracker::AliTRDtracker(const TFile *geomfile):AliTracker()
{
//
// Main constructor
//
- Float_t fTzero = 0;
- Int_t version = 2;
-
+ //Float_t fTzero = 0;
+
fAddTRDseeds = kFALSE;
-
fGeom = NULL;
+ fNoTilt = kFALSE;
TDirectory *savedir=gDirectory;
TFile *in=(TFile*)geomfile;
}
else {
in->cd();
- in->ls();
+// in->ls();
fGeom = (AliTRDgeometry*) in->Get("TRDgeometry");
fPar = (AliTRDparameter*) in->Get("TRDparameter");
- fGeom->Dump();
+// fGeom->Dump();
}
if(fGeom) {
// fTzero = geo->GetT0();
- fTzero = 0.;
- version = fGeom->IsVersion();
- printf("Found geometry version %d on file \n", version);
+ // printf("Found geometry version %d on file \n", fGeom->IsVersion());
}
else {
- printf("AliTRDtracker::AliTRDtracker(): cann't find TRD geometry!\n");
- printf(" DETAIL TRD geometry and DEFAULT TRD parameter will be used\n");
- fGeom = new AliTRDgeometryDetail();
- fPar = new AliTRDparameter();
+ printf("AliTRDtracker::AliTRDtracker(): can't find TRD geometry!\n");
+ //printf("The DETAIL TRD geometry will be used\n");
+ //fGeom = new AliTRDgeometryDetail();
+ fGeom = new AliTRDgeometryDetail();
+ fGeom->SetPHOShole();
+ fGeom->SetRICHhole();
+ }
+
+ if (!fPar) {
+ printf("AliTRDtracker::AliTRDtracker(): can't find TRD parameter!\n");
+ printf("The DEFAULT TRD parameter will be used\n");
+ fPar = new AliTRDparameter("Pica","Vyjebana");
}
+ fPar = new AliTRDparameter("Pica","Vyjebana");
+ fPar->Init();
savedir->cd();
// fGeom->SetT0(fTzero);
- fEvent = 0;
-
fNclusters = 0;
fClusters = new TObjArray(2000);
fNseeds = 0;
fNtracks = 0;
fTracks = new TObjArray(1000);
- for(Int_t geom_s = 0; geom_s < kTRACKING_SECTORS; geom_s++) {
- Int_t tr_s = CookSectorIndex(geom_s);
- fTrSec[tr_s] = new AliTRDtrackingSector(fGeom, geom_s, fPar);
+ for(Int_t geomS = 0; geomS < kTrackingSectors; geomS++) {
+ Int_t trS = CookSectorIndex(geomS);
+ fTrSec[trS] = new AliTRDtrackingSector(fGeom, geomS, fPar);
+ for (Int_t icham=0;icham<AliTRDgeometry::kNcham; icham++){
+ fHoles[icham][trS]=fGeom->IsHole(0,icham,geomS);
+ }
}
+ AliTRDpadPlane *padPlane = fPar->GetPadPlane(0,0);
+ Float_t tiltAngle = TMath::Abs(padPlane->GetTiltingAngle());
+ // Float_t tiltAngle = TMath::Abs(fPar->GetTiltingAngle());
+ if(tiltAngle < 0.1) {
+ fNoTilt = kTRUE;
+ }
+
+ fSY2corr = 0.2;
+ fSZ2corr = 120.;
+
+ if(fNoTilt && (tiltAngle > 0.1)) fSY2corr = fSY2corr + tiltAngle * 0.05;
- fSY2corr = 0.025;
- fSZ2corr = 1.;
// calculate max gap on track
Double_t dxAmp = (Double_t) fGeom->CamHght(); // Amplification region
Double_t dxDrift = (Double_t) fGeom->CdrHght(); // Drift region
- Double_t dx = (Double_t) fPar->GetTimeBinSize();
+ Double_t dx = fgkDriftCorrection*(Double_t) fPar->GetDriftVelocity()
+ / fPar->GetSamplingFrequency();
+
Int_t tbAmp = fPar->GetTimeBefore();
Int_t maxAmp = (Int_t) ((dxAmp+0.000001)/dx);
if(kTRUE) maxAmp = 0; // intentional until we change the parameter class
tbAmp = TMath::Min(tbAmp,maxAmp);
fTimeBinsPerPlane = tbAmp + tbDrift;
- fMaxGap = (Int_t) (fTimeBinsPerPlane * fGeom->Nplan() * fSkipDepth);
+ fMaxGap = (Int_t) (fTimeBinsPerPlane * fGeom->Nplan() * fgkSkipDepth);
fVocal = kFALSE;
+
+ fDebugStreamer = new TTreeSRedirector("TRDdebug.root");
+ savedir->cd();
}
//___________________________________________________________________
AliTRDtracker::~AliTRDtracker()
{
- delete fClusters;
- delete fTracks;
- delete fSeeds;
+ //
+ // Destructor of AliTRDtracker
+ //
+
+ if (fClusters) {
+ fClusters->Delete();
+ delete fClusters;
+ }
+ if (fTracks) {
+ fTracks->Delete();
+ delete fTracks;
+ }
+ if (fSeeds) {
+ fSeeds->Delete();
+ delete fSeeds;
+ }
delete fGeom;
delete fPar;
- for(Int_t geom_s = 0; geom_s < kTRACKING_SECTORS; geom_s++) {
- delete fTrSec[geom_s];
+ for(Int_t geomS = 0; geomS < kTrackingSectors; geomS++) {
+ delete fTrSec[geomS];
+ }
+ if (fDebugStreamer) {
+ //fDebugStreamer->Close();
+ delete fDebugStreamer;
}
}
+//_____________________________________________________________________
+
+Bool_t AliTRDtracker::AdjustSector(AliTRDtrack *track) {
+ //
+ // Rotates the track when necessary
+ //
+
+ Double_t alpha = AliTRDgeometry::GetAlpha();
+ Double_t y = track->GetY();
+ Double_t ymax = track->GetX()*TMath::Tan(0.5*alpha);
+
+ //Int_t ns = AliTRDgeometry::kNsect;
+ //Int_t s=Int_t(track->GetAlpha()/alpha)%ns;
+
+ if (y > ymax) {
+ //s = (s+1) % ns;
+ if (!track->Rotate(alpha)) return kFALSE;
+ } else if (y <-ymax) {
+ //s = (s-1+ns) % ns;
+ if (!track->Rotate(-alpha)) return kFALSE;
+ }
+
+ return kTRUE;
+}
+
//_____________________________________________________________________
inline Double_t f1trd(Double_t x1,Double_t y1,
- Double_t x2,Double_t y2,
- Double_t x3,Double_t y3)
+ Double_t x2,Double_t y2,
+ Double_t x3,Double_t y3)
{
//
// Initial approximation of the track curvature
//_____________________________________________________________________
inline Double_t f2trd(Double_t x1,Double_t y1,
- Double_t x2,Double_t y2,
- Double_t x3,Double_t y3)
+ Double_t x2,Double_t y2,
+ Double_t x3,Double_t y3)
{
//
// Initial approximation of the track curvature times X coordinate
//_____________________________________________________________________
inline Double_t f3trd(Double_t x1,Double_t y1,
- Double_t x2,Double_t y2,
- Double_t z1,Double_t z2)
+ Double_t x2,Double_t y2,
+ Double_t z1,Double_t z2)
{
//
// Initial approximation of the tangent of the track dip angle
return (z1 - z2)/sqrt((x1-x2)*(x1-x2)+(y1-y2)*(y1-y2));
}
+
+AliTRDcluster * AliTRDtracker::GetCluster(AliTRDtrack * track, Int_t plane, Int_t timebin, UInt_t &index){
+ //
+ //try to find cluster in the backup list
+ //
+ AliTRDcluster * cl =0;
+ UInt_t *indexes = track->GetBackupIndexes();
+ for (UInt_t i=0;i<kMaxTimeBinIndex;i++){
+ if (indexes[i]==0) break;
+ AliTRDcluster * cli = (AliTRDcluster*)fClusters->UncheckedAt(indexes[i]);
+ if (!cli) break;
+ if (cli->GetLocalTimeBin()!=timebin) continue;
+ Int_t iplane = fGeom->GetPlane(cli->GetDetector());
+ if (iplane==plane) {
+ cl = cli;
+ index = indexes[i];
+ break;
+ }
+ }
+ return cl;
+}
+
+
+Int_t AliTRDtracker::GetLastPlane(AliTRDtrack * track){
+ //
+ //return last updated plane
+ Int_t lastplane=0;
+ UInt_t *indexes = track->GetBackupIndexes();
+ for (UInt_t i=0;i<kMaxTimeBinIndex;i++){
+ AliTRDcluster * cli = (AliTRDcluster*)fClusters->UncheckedAt(indexes[i]);
+ if (!cli) break;
+ Int_t iplane = fGeom->GetPlane(cli->GetDetector());
+ if (iplane>lastplane) {
+ lastplane = iplane;
+ }
+ }
+ return lastplane;
+}
//___________________________________________________________________
-Int_t AliTRDtracker::Clusters2Tracks(const TFile *inp, TFile *out)
+Int_t AliTRDtracker::Clusters2Tracks(AliESD* event)
{
//
- // Finds tracks within the TRD. File <inp> is expected to contain seeds
- // at the outer part of the TRD. If <inp> is NULL, the seeds
+ // Finds tracks within the TRD. The ESD event is expected to contain seeds
+ // at the outer part of the TRD. The seeds
// are found within the TRD if fAddTRDseeds is TRUE.
// The tracks are propagated to the innermost time bin
- // of the TRD and stored in file <out>.
+ // of the TRD and the ESD event is updated
//
- LoadEvent();
-
- TDirectory *savedir=gDirectory;
-
- char tname[100];
-
- if (!out->IsOpen()) {
- cerr<<"AliTRDtracker::Clusters2Tracks(): output file is not open !\n";
- return 1;
- }
-
- sprintf(tname,"seedTRDtoTPC_%d",fEvent);
- TTree tpc_tree(tname,"Tree with seeds from TRD at outer TPC pad row");
- AliTPCtrack *iotrack=0;
- tpc_tree.Branch("tracks","AliTPCtrack",&iotrack,32000,0);
-
- sprintf(tname,"TreeT%d_TRD",fEvent);
- TTree trd_tree(tname,"TRD tracks at inner TRD time bin");
- AliTRDtrack *iotrack_trd=0;
- trd_tree.Branch("tracks","AliTRDtrack",&iotrack_trd,32000,0);
-
Int_t timeBins = fTrSec[0]->GetNumberOfTimeBins();
- Float_t foundMin = fMinClustersInTrack * timeBins;
-
- if (inp) {
- TFile *in=(TFile*)inp;
- if (!in->IsOpen()) {
- cerr<<"AliTRDtracker::Clusters2Tracks(): file with seeds is not open !\n";
- cerr<<" ... going for seeds finding inside the TRD\n";
- }
- else {
- in->cd();
- sprintf(tname,"TRDb_%d",fEvent);
- TTree *seedTree=(TTree*)in->Get(tname);
- if (!seedTree) {
- cerr<<"AliTRDtracker::Clusters2Tracks(): ";
- cerr<<"can't get a tree with track seeds !\n";
- return 3;
- }
- AliTRDtrack *seed=new AliTRDtrack;
- seedTree->SetBranchAddress("tracks",&seed);
-
- Int_t n=(Int_t)seedTree->GetEntries();
- for (Int_t i=0; i<n; i++) {
- seedTree->GetEvent(i);
- seed->ResetCovariance();
- AliTRDtrack *tr = new AliTRDtrack(*seed,seed->GetAlpha());
- fSeeds->AddLast(tr);
- fNseeds++;
- }
- delete seed;
- delete seedTree;
- }
- }
-
- out->cd();
-
-
-
- // find tracks from loaded seeds
-
- Int_t nseed=fSeeds->GetEntriesFast();
- Int_t i, found = 0;
+ Float_t foundMin = fgkMinClustersInTrack * timeBins;
+ Int_t nseed = 0;
+ Int_t found = 0;
Int_t innerTB = fTrSec[0]->GetInnerTimeBin();
- for (i=0; i<nseed; i++) {
- AliTRDtrack *pt=(AliTRDtrack*)fSeeds->UncheckedAt(i), &t=*pt;
+ Int_t n = event->GetNumberOfTracks();
+ for (Int_t i=0; i<n; i++) {
+ AliESDtrack* seed=event->GetTrack(i);
+ ULong_t status=seed->GetStatus();
+ if ( (status & AliESDtrack::kTRDout ) == 0 ) continue;
+ if ( (status & AliESDtrack::kTRDin) != 0 ) continue;
+ nseed++;
+
+ AliTRDtrack* seed2 = new AliTRDtrack(*seed);
+ //seed2->ResetCovariance();
+ AliTRDtrack *pt = new AliTRDtrack(*seed2,seed2->GetAlpha());
+ AliTRDtrack &t=*pt;
FollowProlongation(t, innerTB);
if (t.GetNumberOfClusters() >= foundMin) {
UseClusters(&t);
- CookLabel(pt, 1-fLabelFraction);
+ CookLabel(pt, 1-fgkLabelFraction);
// t.CookdEdx();
}
- iotrack_trd = pt;
- trd_tree.Fill();
- cout<<found++<<'\r';
+ found++;
+// cout<<found<<'\r';
if(PropagateToTPC(t)) {
- AliTPCtrack *tpc = new AliTPCtrack(*pt,pt->GetAlpha());
- iotrack = tpc;
- tpc_tree.Fill();
- delete tpc;
+ seed->UpdateTrackParams(pt, AliESDtrack::kTRDin);
}
- delete fSeeds->RemoveAt(i);
- fNseeds--;
+ delete seed2;
+ delete pt;
}
cout<<"Number of loaded seeds: "<<nseed<<endl;
// Find tracks for the seeds in the TRD
Int_t timeBins = fTrSec[0]->GetNumberOfTimeBins();
- Int_t nSteps = (Int_t) (fSeedDepth / fSeedStep);
- Int_t gap = (Int_t) (timeBins * fSeedGap);
- Int_t step = (Int_t) (timeBins * fSeedStep);
+ Int_t nSteps = (Int_t) (fgkSeedDepth / fgkSeedStep);
+ Int_t gap = (Int_t) (timeBins * fgkSeedGap);
+ Int_t step = (Int_t) (timeBins * fgkSeedStep);
// make a first turn with tight cut on initial curvature
for(Int_t turn = 1; turn <= 2; turn++) {
if(turn == 2) {
- nSteps = (Int_t) (fSeedDepth / (3*fSeedStep));
- step = (Int_t) (timeBins * (3*fSeedStep));
+ nSteps = (Int_t) (fgkSeedDepth / (3*fgkSeedStep));
+ step = (Int_t) (timeBins * (3*fgkSeedStep));
}
for(Int_t i=0; i<nSteps; i++) {
- Int_t outer=timeBins-1-i*step;
- Int_t inner=outer-gap;
+ Int_t outer=timeBins-1-i*step;
+ Int_t inner=outer-gap;
- nseed=fSeeds->GetEntriesFast();
+ nseed=fSeeds->GetEntriesFast();
- MakeSeeds(inner, outer, turn);
+ MakeSeeds(inner, outer, turn);
- nseed=fSeeds->GetEntriesFast();
- printf("\n turn %d, step %d: number of seeds for TRD inward %d\n",
- turn, i, nseed);
-
- for (Int_t i=0; i<nseed; i++) {
- AliTRDtrack *pt=(AliTRDtrack*)fSeeds->UncheckedAt(i), &t=*pt;
- FollowProlongation(t,innerTB);
- if (t.GetNumberOfClusters() >= foundMin) {
- UseClusters(&t);
- CookLabel(pt, 1-fLabelFraction);
- t.CookdEdx();
- cout<<found++<<'\r';
- iotrack_trd = pt;
- trd_tree.Fill();
- if(PropagateToTPC(t)) {
- AliTPCtrack *tpc = new AliTPCtrack(*pt,pt->GetAlpha());
- iotrack = tpc;
- tpc_tree.Fill();
- delete tpc;
- }
- }
- delete fSeeds->RemoveAt(i);
- fNseeds--;
- }
+ nseed=fSeeds->GetEntriesFast();
+ // printf("\n turn %d, step %d: number of seeds for TRD inward %d\n",
+ // turn, i, nseed);
+
+ for (Int_t i=0; i<nseed; i++) {
+ AliTRDtrack *pt=(AliTRDtrack*)fSeeds->UncheckedAt(i), &t=*pt;
+ FollowProlongation(t,innerTB);
+ if (t.GetNumberOfClusters() >= foundMin) {
+ UseClusters(&t);
+ CookLabel(pt, 1-fgkLabelFraction);
+ t.CookdEdx();
+ found++;
+// cout<<found<<'\r';
+ if(PropagateToTPC(t)) {
+ AliESDtrack track;
+ track.UpdateTrackParams(pt,AliESDtrack::kTRDin);
+ event->AddTrack(&track);
+ // track.SetTRDtrack(new AliTRDtrack(*pt));
+ }
+ }
+ delete fSeeds->RemoveAt(i);
+ fNseeds--;
+ }
}
}
}
- tpc_tree.Write();
- trd_tree.Write();
cout<<"Total number of found tracks: "<<found<<endl;
- UnloadEvent();
-
- savedir->cd();
-
return 0;
}
//_____________________________________________________________________________
-Int_t AliTRDtracker::PropagateBack(const TFile *inp, TFile *out) {
+Int_t AliTRDtracker::PropagateBack(AliESD* event) {
//
- // Reads seeds from file <inp>. The seeds are AliTPCtrack's found and
+ // Gets seeds from ESD event. The seeds are AliTPCtrack's found and
// backpropagated by the TPC tracker. Each seed is first propagated
// to the TRD, and then its prolongation is searched in the TRD.
// If sufficiently long continuation of the track is found in the TRD
// by the TPC tracker.
//
-
- LoadEvent();
-
- TDirectory *savedir=gDirectory;
-
- TFile *in=(TFile*)inp;
-
- if (!in->IsOpen()) {
- cerr<<"AliTRDtracker::PropagateBack(): ";
- cerr<<"file with back propagated TPC tracks is not open !\n";
- return 1;
- }
-
- if (!out->IsOpen()) {
- cerr<<"AliTRDtracker::PropagateBack(): ";
- cerr<<"file for back propagated TRD tracks is not open !\n";
- return 2;
- }
-
- in->cd();
- char tname[100];
- sprintf(tname,"seedsTPCtoTRD_%d",fEvent);
- TTree *seedTree=(TTree*)in->Get(tname);
- if (!seedTree) {
- cerr<<"AliTRDtracker::PropagateBack(): ";
- cerr<<"can't get a tree with seeds from TPC !\n";
- cerr<<"check if your version of TPC tracker creates tree "<<tname<<"\n";
- return 3;
- }
-
- AliTPCtrack *seed=new AliTPCtrack;
- seedTree->SetBranchAddress("tracks",&seed);
-
- Int_t n=(Int_t)seedTree->GetEntries();
+ Int_t found=0;
+ Float_t foundMin = 20;
+ Int_t n = event->GetNumberOfTracks();
+ //
+ //Sort tracks
+ Float_t *quality =new Float_t[n];
+ Int_t *index =new Int_t[n];
for (Int_t i=0; i<n; i++) {
- seedTree->GetEvent(i);
- Int_t lbl = seed->GetLabel();
- AliTRDtrack *tr = new AliTRDtrack(*seed,seed->GetAlpha());
- tr->SetSeedLabel(lbl);
- fSeeds->AddLast(tr);
- fNseeds++;
+ AliESDtrack* seed=event->GetTrack(i);
+ Double_t covariance[15];
+ seed->GetExternalCovariance(covariance);
+ quality[i] = covariance[0]+covariance[2];
}
+ TMath::Sort(n,quality,index,kFALSE);
+ //
+ for (Int_t i=0; i<n; i++) {
+ // AliESDtrack* seed=event->GetTrack(i);
+ AliESDtrack* seed=event->GetTrack(index[i]);
+
+ ULong_t status=seed->GetStatus();
+ if ( (status & AliESDtrack::kTPCout ) == 0 ) continue;
+ if ( (status & AliESDtrack::kTRDout) != 0 ) continue;
+
+ Int_t lbl = seed->GetLabel();
+ AliTRDtrack *track = new AliTRDtrack(*seed);
+ track->SetSeedLabel(lbl);
+ seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup); //make backup
+ fNseeds++;
+ Float_t p4 = track->GetC();
+ //
+ Int_t expectedClr = FollowBackProlongation(*track);
+ /*
+ // only debug purpose
+ if (track->GetNumberOfClusters()<expectedClr/3){
+ AliTRDtrack *track1 = new AliTRDtrack(*seed);
+ track1->SetSeedLabel(lbl);
+ FollowBackProlongation(*track1);
+ AliTRDtrack *track2= new AliTRDtrack(*seed);
+ track->SetSeedLabel(lbl);
+ FollowBackProlongation(*track2);
+ delete track1;
+ delete track2;
+ }
+ */
+ if (TMath::Abs(track->GetC()-p4)/TMath::Abs(p4)<0.2 || TMath::Abs(track->GetPt())>0.8 ) {
+ //
+ //make backup for back propagation
+ //
+ Int_t foundClr = track->GetNumberOfClusters();
+ if (foundClr >= foundMin) {
+ track->CookdEdx();
+ CookLabel(track, 1-fgkLabelFraction);
+ if(track->GetChi2()/track->GetNumberOfClusters()<4) { // sign only gold tracks
+ if (seed->GetKinkIndex(0)==0&&TMath::Abs(track->GetPt())<1.5 ) UseClusters(track);
+ }
+ Bool_t isGold = kFALSE;
+
+ if (track->GetChi2()/track->GetNumberOfClusters()<5) { //full gold track
+ // seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup);
+ if (track->GetBackupTrack()) seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
+ isGold = kTRUE;
+ }
+ if (!isGold && track->GetNCross()==0&&track->GetChi2()/track->GetNumberOfClusters()<7){ //almost gold track
+ // seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup);
+ if (track->GetBackupTrack()) seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
+ isGold = kTRUE;
+ }
+ if (!isGold && track->GetBackupTrack()){
+ if (track->GetBackupTrack()->GetNumberOfClusters()>foundMin&&
+ (track->GetBackupTrack()->GetChi2()/(track->GetBackupTrack()->GetNumberOfClusters()+1))<7){
+ seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
+ isGold = kTRUE;
+ }
+ }
+ if (track->StatusForTOF()>0 &&track->fNCross==0 && Float_t(track->fN)/Float_t(track->fNExpected)>0.4){
+ seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup);
+ }
+ }
+ }
+ //
+ //Propagation to the TOF (I.Belikov)
+
+ if (track->GetStop()==kFALSE){
+
+ Double_t xtof=371.;
+ Double_t c2=track->GetC()*xtof - track->GetEta();
+ if (TMath::Abs(c2)>=0.99) {
+ delete track;
+ continue;
+ }
+ Double_t xTOF0 = 365. ;
+ PropagateToOuterPlane(*track,xTOF0);
+ //
+ //energy losses taken to the account - check one more time
+ c2=track->GetC()*xtof - track->GetEta();
+ if (TMath::Abs(c2)>=0.99) {
+ delete track;
+ continue;
+ }
- delete seed;
- delete seedTree;
-
- out->cd();
-
- AliTPCtrack *otrack=0;
-
- sprintf(tname,"seedsTRDtoTOF1_%d",fEvent);
- TTree tofTree1(tname,"Tracks back propagated through TPC and TRD");
- tofTree1.Branch("tracks","AliTPCtrack",&otrack,32000,0);
-
- sprintf(tname,"seedsTRDtoTOF2_%d",fEvent);
- TTree tofTree2(tname,"Tracks back propagated through TPC and TRD");
- tofTree2.Branch("tracks","AliTPCtrack",&otrack,32000,0);
-
- sprintf(tname,"seedsTRDtoPHOS_%d",fEvent);
- TTree phosTree(tname,"Tracks back propagated through TPC and TRD");
- phosTree.Branch("tracks","AliTPCtrack",&otrack,32000,0);
-
- sprintf(tname,"seedsTRDtoRICH_%d",fEvent);
- TTree richTree(tname,"Tracks back propagated through TPC and TRD");
- richTree.Branch("tracks","AliTPCtrack",&otrack,32000,0);
+ //
+ Double_t ymax=xtof*TMath::Tan(0.5*AliTRDgeometry::GetAlpha());
+ Double_t y=track->GetYat(xtof);
+ if (y > ymax) {
+ if (!track->Rotate(AliTRDgeometry::GetAlpha())) {
+ delete track;
+ continue;
+ }
+ } else if (y <-ymax) {
+ if (!track->Rotate(-AliTRDgeometry::GetAlpha())) {
+ delete track;
+ continue;
+ }
+ }
+
+ if (track->PropagateTo(xtof)) {
+ seed->UpdateTrackParams(track, AliESDtrack::kTRDout);
+ for (Int_t i=0;i<kNPlane;i++) {
+ seed->SetTRDsignals(track->GetPIDsignals(i),i);
+ seed->SetTRDTimBin(track->GetPIDTimBin(i),i);
+ }
+ // seed->SetTRDtrack(new AliTRDtrack(*track));
+ if (track->GetNumberOfClusters()>foundMin) found++;
+ }
+ }else{
+ if (track->GetNumberOfClusters()>15&&track->GetNumberOfClusters()>0.5*expectedClr){
+ seed->UpdateTrackParams(track, AliESDtrack::kTRDout);
+ //seed->SetStatus(AliESDtrack::kTRDStop);
+ for (Int_t i=0;i<kNPlane;i++) {
+ seed->SetTRDsignals(track->GetPIDsignals(i),i);
+ seed->SetTRDTimBin(track->GetPIDTimBin(i),i);
+ }
+ //seed->SetTRDtrack(new AliTRDtrack(*track));
+ found++;
+ }
+ }
+ seed->SetTRDQuality(track->StatusForTOF());
+ //
+ // Debug part of tracking
+ TTreeSRedirector& cstream = *fDebugStreamer;
+ Int_t eventNr = event->GetEventNumber();
+ if (track->GetBackupTrack()){
+ cstream<<"Tracks"<<
+ "EventNr="<<eventNr<<
+ "ESD.="<<seed<<
+ "trd.="<<track<<
+ "trdback.="<<track->GetBackupTrack()<<
+ "\n";
+ }else{
+ cstream<<"Tracks"<<
+ "EventNr="<<eventNr<<
+ "ESD.="<<seed<<
+ "trd.="<<track<<
+ "trdback.="<<track<<
+ "\n";
+ }
+ delete track;
+ //
+ //End of propagation to the TOF
+ //if (foundClr>foundMin)
+ // seed->UpdateTrackParams(track, AliESDtrack::kTRDout);
+
- sprintf(tname,"TRDb_%d",fEvent);
- TTree trdTree(tname,"Back propagated TRD tracks at outer TRD time bin");
- AliTRDtrack *otrack_trd=0;
- trdTree.Branch("tracks","AliTRDtrack",&otrack_trd,32000,0);
-
- Int_t found=0;
+ }
+
+ cerr<<"Number of seeds: "<<fNseeds<<endl;
+ cerr<<"Number of back propagated TRD tracks: "<<found<<endl;
- Int_t nseed=fSeeds->GetEntriesFast();
+ // MakeSeedsMI(3,5); //new seeding
- Float_t foundMin = fMinClustersInTrack * fTimeBinsPerPlane * fGeom->Nplan();
- Int_t outermost_tb = fTrSec[0]->GetOuterTimeBin();
+ fSeeds->Clear(); fNseeds=0;
+ delete [] index;
+ delete [] quality;
+
+ return 0;
- for (Int_t i=0; i<nseed; i++) {
+}
- AliTRDtrack *ps=(AliTRDtrack*)fSeeds->UncheckedAt(i), &s=*ps;
- Int_t expectedClr = FollowBackProlongation(s);
- Int_t foundClr = s.GetNumberOfClusters();
- Int_t last_tb = fTrSec[0]->GetLayerNumber(s.GetX());
+//_____________________________________________________________________________
+Int_t AliTRDtracker::RefitInward(AliESD* event)
+{
+ //
+ // Refits tracks within the TRD. The ESD event is expected to contain seeds
+ // at the outer part of the TRD.
+ // The tracks are propagated to the innermost time bin
+ // of the TRD and the ESD event is updated
+ // Origin: Thomas KUHR (Thomas.Kuhr@cern.ch)
+ //
- // printf("seed %d: found %d out of %d expected clusters, Min is %f\n",
- // i, foundClr, expectedClr, foundMin);
+ Int_t timeBins = fTrSec[0]->GetNumberOfTimeBins();
+ Float_t foundMin = fgkMinClustersInTrack * timeBins;
+ Int_t nseed = 0;
+ Int_t found = 0;
+ Int_t innerTB = fTrSec[0]->GetInnerTimeBin();
+ AliTRDtrack seed2;
- if (foundClr >= foundMin) {
- s.CookdEdx();
- CookLabel(ps, 1-fLabelFraction);
- UseClusters(ps);
- otrack_trd=ps;
- trdTree.Fill();
- cout<<found++<<'\r';
+ Int_t n = event->GetNumberOfTracks();
+ for (Int_t i=0; i<n; i++) {
+ AliESDtrack* seed=event->GetTrack(i);
+ new(&seed2) AliTRDtrack(*seed);
+ if (seed2.GetX()<270){
+ seed->UpdateTrackParams(&seed2, AliESDtrack::kTRDbackup); // backup TPC track - only update
+ continue;
}
- if(((expectedClr < 10) && (last_tb == outermost_tb)) ||
- ((expectedClr >= 10) &&
- (((Float_t) foundClr) / ((Float_t) expectedClr) >=
- fMinFractionOfFoundClusters) && (last_tb == outermost_tb))) {
-
- Double_t x_tof = 375.5;
-
- if(PropagateToOuterPlane(s,x_tof)) {
- AliTPCtrack *pt = new AliTPCtrack(*ps,ps->GetAlpha());
- otrack = pt;
- tofTree1.Fill();
- delete pt;
-
- x_tof = 381.5;
-
- if(PropagateToOuterPlane(s,x_tof)) {
- AliTPCtrack *pt = new AliTPCtrack(*ps,ps->GetAlpha());
- otrack = pt;
- tofTree2.Fill();
- delete pt;
+ ULong_t status=seed->GetStatus();
+ if ( (status & AliESDtrack::kTRDout ) == 0 ) {
+ continue;
+ }
+ if ( (status & AliESDtrack::kTRDin) != 0 ) {
+ continue;
+ }
+ nseed++;
+// if (1/seed2.Get1Pt()>1.5&& seed2.GetX()>260.) {
+// Double_t oldx = seed2.GetX();
+// seed2.PropagateTo(500.);
+// seed2.ResetCovariance(1.);
+// seed2.PropagateTo(oldx);
+// }
+// else{
+// seed2.ResetCovariance(5.);
+// }
+
+ AliTRDtrack *pt = new AliTRDtrack(seed2,seed2.GetAlpha());
+ UInt_t * indexes2 = seed2.GetIndexes();
+ for (Int_t i=0;i<kNPlane;i++) {
+ pt->SetPIDsignals(seed2.GetPIDsignals(i),i);
+ pt->SetPIDTimBin(seed2.GetPIDTimBin(i),i);
+ }
- Double_t x_phos = 460.;
-
- if(PropagateToOuterPlane(s,x_phos)) {
- AliTPCtrack *pt = new AliTPCtrack(*ps,ps->GetAlpha());
- otrack = pt;
- phosTree.Fill();
- delete pt;
-
- Double_t x_rich = 490+1.267;
-
- if(PropagateToOuterPlane(s,x_rich)) {
- AliTPCtrack *pt = new AliTPCtrack(*ps,ps->GetAlpha());
- otrack = pt;
- richTree.Fill();
- delete pt;
- }
- }
- }
- }
+ UInt_t * indexes3 = pt->GetBackupIndexes();
+ for (Int_t i=0;i<200;i++) {
+ if (indexes2[i]==0) break;
+ indexes3[i] = indexes2[i];
+ }
+ //AliTRDtrack *pt = seed2;
+ AliTRDtrack &t=*pt;
+ FollowProlongation(t, innerTB);
+ if (t.GetNumberOfClusters() >= foundMin) {
+ // UseClusters(&t);
+ //CookLabel(pt, 1-fgkLabelFraction);
+ t.CookdEdx();
+ CookdEdxTimBin(t);
}
- }
-
- tofTree1.Write();
- tofTree2.Write();
- phosTree.Write();
- richTree.Write();
- trdTree.Write();
+ found++;
+// cout<<found<<'\r';
- savedir->cd();
- cerr<<"Number of seeds: "<<nseed<<endl;
- cerr<<"Number of back propagated TRD tracks: "<<found<<endl;
+ if(PropagateToTPC(t)) {
+ seed->UpdateTrackParams(pt, AliESDtrack::kTRDrefit);
+ for (Int_t i=0;i<kNPlane;i++) {
+ seed->SetTRDsignals(pt->GetPIDsignals(i),i);
+ seed->SetTRDTimBin(pt->GetPIDTimBin(i),i);
+ }
+ }else{
+ //if not prolongation to TPC - propagate without update
+ AliTRDtrack* seed2 = new AliTRDtrack(*seed);
+ seed2->ResetCovariance(5.);
+ AliTRDtrack *pt2 = new AliTRDtrack(*seed2,seed2->GetAlpha());
+ delete seed2;
+ if (PropagateToTPC(*pt2)) {
+ pt2->CookdEdx(0.,1.);
+ CookdEdxTimBin(*pt2);
+ seed->UpdateTrackParams(pt2, AliESDtrack::kTRDrefit);
+ for (Int_t i=0;i<kNPlane;i++) {
+ seed->SetTRDsignals(pt2->GetPIDsignals(i),i);
+ seed->SetTRDTimBin(pt2->GetPIDTimBin(i),i);
+ }
+ }
+ delete pt2;
+ }
+ delete pt;
+ }
- UnloadEvent();
+ cout<<"Number of loaded seeds: "<<nseed<<endl;
+ cout<<"Number of found tracks from loaded seeds: "<<found<<endl;
return 0;
Float_t wYrt, wYclosest, wYcorrect, wYwindow;
Float_t wZrt, wZclosest, wZcorrect, wZwindow;
Float_t wPx, wPy, wPz, wC;
- Double_t Px, Py, Pz;
+ Double_t px, py, pz;
Float_t wSigmaC2, wSigmaTgl2, wSigmaY2, wSigmaZ2;
+ Int_t lastplane = GetLastPlane(&t);
Int_t trackIndex = t.GetLabel();
Int_t ns=Int_t(2*TMath::Pi()/AliTRDgeometry::GetAlpha()+0.5);
- Int_t try_again=fMaxGap;
+ Int_t tryAgain=fMaxGap;
Double_t alpha=t.GetAlpha();
-
- if (alpha > 2.*TMath::Pi()) alpha -= 2.*TMath::Pi();
- if (alpha < 0. ) alpha += 2.*TMath::Pi();
+ alpha = TVector2::Phi_0_2pi(alpha);
Int_t s=Int_t(alpha/AliTRDgeometry::GetAlpha())%AliTRDgeometry::kNsect;
-
- Double_t rad_length, rho, x, dx, y, ymax, z;
+ Double_t radLength, rho, x, dx, y, ymax, z;
Int_t expectedNumberOfClusters = 0;
Bool_t lookForCluster;
y = t.GetY(); z = t.GetZ();
// first propagate to the inner surface of the current time bin
- fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
+ fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
x = fTrSec[s]->GetLayer(nr)->GetX()-dx/2; y = t.GetY(); z = t.GetZ();
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
y = t.GetY();
ymax = x*TMath::Tan(0.5*alpha);
if (y > ymax) {
s = (s+1) % ns;
if (!t.Rotate(alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
} else if (y <-ymax) {
s = (s-1+ns) % ns;
if (!t.Rotate(-alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
}
y = t.GetY(); z = t.GetZ();
// now propagate to the middle plane of the next time bin
- fTrSec[s]->GetLayer(nr-1)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
+ fTrSec[s]->GetLayer(nr-1)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
x = fTrSec[s]->GetLayer(nr-1)->GetX(); y = t.GetY(); z = t.GetZ();
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
y = t.GetY();
ymax = x*TMath::Tan(0.5*alpha);
if (y > ymax) {
s = (s+1) % ns;
if (!t.Rotate(alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
} else if (y <-ymax) {
s = (s-1+ns) % ns;
if (!t.Rotate(-alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
}
if(lookForCluster) {
-
expectedNumberOfClusters++;
-
wIndex = (Float_t) t.GetLabel();
wTB = nr;
-
- AliTRDpropagationLayer& time_bin=*(fTrSec[s]->GetLayer(nr-1));
-
+ AliTRDpropagationLayer& timeBin=*(fTrSec[s]->GetLayer(nr-1));
Double_t sy2=ExpectedSigmaY2(x,t.GetTgl(),t.GetPt());
-
-
Double_t sz2=ExpectedSigmaZ2(x,t.GetTgl());
Double_t road;
wYrt = (Float_t) y;
wZrt = (Float_t) z;
wYwindow = (Float_t) road;
- t.GetPxPyPz(Px,Py,Pz);
- wPx = (Float_t) Px;
- wPy = (Float_t) Py;
- wPz = (Float_t) Pz;
+ t.GetPxPyPz(px,py,pz);
+ wPx = (Float_t) px;
+ wPy = (Float_t) py;
+ wPz = (Float_t) pz;
wC = (Float_t) t.GetC();
wSigmaC2 = (Float_t) t.GetSigmaC2();
wSigmaTgl2 = (Float_t) t.GetSigmaTgl2();
wSigmaZ2 = (Float_t) t.GetSigmaZ2();
wChi2 = -1;
- if (road>fWideRoad) {
- if (t.GetNumberOfClusters()>4)
- cerr<<t.GetNumberOfClusters()
- <<"FindProlongation warning: Too broad road !\n";
- return 0;
- }
AliTRDcluster *cl=0;
UInt_t index=0;
- Double_t max_chi2=fMaxChi2;
+ Double_t maxChi2=fgkMaxChi2;
wYclosest = 12345678;
wYcorrect = 12345678;
wZwindow = TMath::Sqrt(2.25 * 12 * sz2);
// Find the closest correct cluster for debugging purposes
- if (time_bin) {
- Float_t minDY = 1000000;
- for (Int_t i=0; i<time_bin; i++) {
- AliTRDcluster* c=(AliTRDcluster*)(time_bin[i]);
- if((c->GetLabel(0) != trackIndex) &&
- (c->GetLabel(1) != trackIndex) &&
- (c->GetLabel(2) != trackIndex)) continue;
- if(TMath::Abs(c->GetY() - y) > minDY) continue;
- minDY = TMath::Abs(c->GetY() - y);
- wYcorrect = c->GetY();
- wZcorrect = c->GetZ();
-
- Double_t h01 = GetTiltFactor(c);
- wChi2 = t.GetPredictedChi2(c, h01);
- }
+ if (timeBin&&fVocal) {
+ Float_t minDY = 1000000;
+ for (Int_t i=0; i<timeBin; i++) {
+ AliTRDcluster* c=(AliTRDcluster*)(timeBin[i]);
+ if((c->GetLabel(0) != trackIndex) &&
+ (c->GetLabel(1) != trackIndex) &&
+ (c->GetLabel(2) != trackIndex)) continue;
+ if(TMath::Abs(c->GetY() - y) > minDY) continue;
+ minDY = TMath::Abs(c->GetY() - y);
+ wYcorrect = c->GetY();
+ wZcorrect = c->GetZ();
+
+ Double_t h01 = GetTiltFactor(c);
+ wChi2 = t.GetPredictedChi2(c, h01);
+ }
}
// Now go for the real cluster search
- if (time_bin) {
-
- for (Int_t i=time_bin.Find(y-road); i<time_bin; i++) {
- AliTRDcluster* c=(AliTRDcluster*)(time_bin[i]);
- if (c->GetY() > y+road) break;
- if (c->IsUsed() > 0) continue;
- if((c->GetZ()-z)*(c->GetZ()-z) > 3 * sz2) continue;
-
- Double_t h01 = GetTiltFactor(c);
- Double_t chi2=t.GetPredictedChi2(c,h01);
-
- if (chi2 > max_chi2) continue;
- max_chi2=chi2;
- cl=c;
- index=time_bin.GetIndex(i);
- }
-
- if(!cl) {
-
- for (Int_t i=time_bin.Find(y-road); i<time_bin; i++) {
- AliTRDcluster* c=(AliTRDcluster*)(time_bin[i]);
-
- if (c->GetY() > y+road) break;
- if (c->IsUsed() > 0) continue;
- if((c->GetZ()-z)*(c->GetZ()-z) > 12 * sz2) continue;
-
- Double_t h01 = GetTiltFactor(c);
- Double_t chi2=t.GetPredictedChi2(c, h01);
-
- if (chi2 > max_chi2) continue;
- max_chi2=chi2;
- cl=c;
- index=time_bin.GetIndex(i);
- }
- }
+ if (timeBin) {
+ //
+ //find cluster in history
+ cl =0;
-
- if (cl) {
- wYclosest = cl->GetY();
- wZclosest = cl->GetZ();
- Double_t h01 = GetTiltFactor(cl);
-
- t.SetSampledEdx(cl->GetQ()/dx,t.GetNumberOfClusters());
- if(!t.Update(cl,max_chi2,index,h01)) {
- if(!try_again--) return 0;
- }
- else try_again=fMaxGap;
+ AliTRDcluster * cl0 = timeBin[0];
+ if (!cl0) {
+ continue;
}
- else {
- if (try_again==0) break;
- try_again--;
+ Int_t plane = fGeom->GetPlane(cl0->GetDetector());
+ if (plane>lastplane) continue;
+ Int_t timebin = cl0->GetLocalTimeBin();
+ AliTRDcluster * cl2= GetCluster(&t,plane, timebin,index);
+ if (cl2) {
+ cl =cl2;
+ Double_t h01 = GetTiltFactor(cl);
+ maxChi2=t.GetPredictedChi2(cl,h01);
}
-
- /*
- if((((Int_t) wTB)%15 == 0) || (((Int_t) wTB)%15 == 14)) {
+ if ((!cl) && road>fgkWideRoad) {
+ //if (t.GetNumberOfClusters()>4)
+ // cerr<<t.GetNumberOfClusters()
+ // <<"FindProlongation warning: Too broad road !\n";
+ continue;
+ }
+
+ if (cl) {
- printf(" %f", wIndex); //1
- printf(" %f", wTB); //2
- printf(" %f", wYrt); //3
- printf(" %f", wYclosest); //4
- printf(" %f", wYcorrect); //5
- printf(" %f", wYwindow); //6
- printf(" %f", wZrt); //7
- printf(" %f", wZclosest); //8
- printf(" %f", wZcorrect); //9
- printf(" %f", wZwindow); //10
- printf(" %f", wPx); //11
- printf(" %f", wPy); //12
- printf(" %f", wPz); //13
- printf(" %f", wSigmaC2*1000000); //14
- printf(" %f", wSigmaTgl2*1000); //15
- printf(" %f", wSigmaY2); //16
- // printf(" %f", wSigmaZ2); //17
- printf(" %f", wChi2); //17
- printf(" %f", wC); //18
- printf("\n");
- }
- */
+ wYclosest = cl->GetY();
+ wZclosest = cl->GetZ();
+ Double_t h01 = GetTiltFactor(cl);
+
+ if (cl->GetNPads()<5)
+ t.SetSampledEdx(TMath::Abs(cl->GetQ()/dx));
+ Int_t det = cl->GetDetector();
+ Int_t plane = fGeom->GetPlane(det);
+
+ if(!t.UpdateMI(cl,maxChi2,index,h01,plane)) {
+ //if(!t.Update(cl,maxChi2,index,h01)) {
+ //if(!tryAgain--) return 0;
+ }
+ else tryAgain=fMaxGap;
+ }
+ else {
+ //if (tryAgain==0) break;
+ tryAgain--;
+ }
}
}
}
// layers confirms prolongation if a close cluster is found.
// Returns the number of clusters expected to be found in sensitive layers
- Float_t wIndex, wTB, wChi2;
- Float_t wYrt, wYclosest, wYcorrect, wYwindow;
- Float_t wZrt, wZclosest, wZcorrect, wZwindow;
- Float_t wPx, wPy, wPz, wC;
- Double_t Px, Py, Pz;
- Float_t wSigmaC2, wSigmaTgl2, wSigmaY2, wSigmaZ2;
-
- Int_t trackIndex = t.GetLabel();
-
- Int_t ns=Int_t(2*TMath::Pi()/AliTRDgeometry::GetAlpha()+0.5);
-
- Int_t try_again=fMaxGap;
+ Int_t tryAgain=fMaxGap;
Double_t alpha=t.GetAlpha();
+ TVector2::Phi_0_2pi(alpha);
- if (alpha > 2.*TMath::Pi()) alpha -= 2.*TMath::Pi();
- if (alpha < 0. ) alpha += 2.*TMath::Pi();
-
- Int_t s=Int_t(alpha/AliTRDgeometry::GetAlpha())%AliTRDgeometry::kNsect;
+ Int_t s;
+
+ Int_t clusters[1000];
+ for (Int_t i=0;i<1000;i++) clusters[i]=-1;
Int_t outerTB = fTrSec[0]->GetOuterTimeBin();
-
- Double_t rad_length, rho, x, dx, y, ymax, z;
-
+ //Double_t radLength, rho, x, dx, y, ymax = 0, z;
+ Double_t radLength, rho, x, dx, y, z;
Bool_t lookForCluster;
Int_t expectedNumberOfClusters = 0;
alpha=AliTRDgeometry::GetAlpha(); // note: change in meaning
+ // Int_t zone =0;
+ Int_t nr;
+ Float_t ratio0=0;
+ AliTRDtracklet tracklet;
+ //
+ for (nr=fTrSec[0]->GetLayerNumber(t.GetX()); nr<outerTB+1; nr++) {
+
+ y = t.GetY();
+ z = t.GetZ();
+ // first propagate to the outer surface of the current time bin
- for (Int_t nr=fTrSec[0]->GetLayerNumber(t.GetX()); nr<outerTB; nr++) {
+ s = t.GetSector();
+ fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
+ x = fTrSec[s]->GetLayer(nr)->GetX()+dx/2;
+ y = t.GetY();
+ z = t.GetZ();
+
+ if(!t.PropagateTo(x,radLength,rho)) break;
+ //
+ // MI -fix untill correct material desription will be implemented
+ //
+ //Int_t nrotate = t.GetNRotate();
+ if (!AdjustSector(&t)) break;
+ //
+ //
+ y = t.GetY();
+ z = t.GetZ();
+ s = t.GetSector();
- y = t.GetY(); z = t.GetZ();
+ // now propagate to the middle plane of the next time bin
+ fTrSec[s]->GetLayer(nr+1)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
+// if (nrotate!=t.GetNRotate()){
+// rho = 1000*2.7; radLength = 24.01; //TEMPORARY - aluminium in between z - will be detected using GeoModeler in future versions
+// }
+ x = fTrSec[s]->GetLayer(nr+1)->GetX();
+ if(!t.PropagateTo(x,radLength,rho)) break;
+ if (!AdjustSector(&t)) break;
+ s = t.GetSector();
+ // if(!t.PropagateTo(x,radLength,rho)) break;
+
+ if (TMath::Abs(t.GetSnp())>0.95) break;
- // first propagate to the outer surface of the current time bin
+ y = t.GetY();
+ z = t.GetZ();
- fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
- x = fTrSec[s]->GetLayer(nr)->GetX()+dx/2; y = t.GetY(); z = t.GetZ();
+ if(lookForCluster) {
+ if (clusters[nr]==-1) {
+ Float_t ncl = FindClusters(s,nr,nr+30,&t,clusters,tracklet);
+ ratio0 = ncl/Float_t(fTimeBinsPerPlane);
+ Float_t ratio1 = Float_t(t.fN+1)/Float_t(t.fNExpected+1.);
+ if (tracklet.GetChi2()<18.&&ratio0>0.8 && ratio1>0.6 && ratio0+ratio1>1.5 && t.GetNCross()==0 && TMath::Abs(t.GetSnp())<0.85&&t.fN>20){
+ t.MakeBackupTrack(); // make backup of the track until is gold
+ }
+// if (ncl>4){
+// t.PropagateTo(tracklet.GetX());
+// t.UpdateMI(tracklet);
+// nr = fTrSec[0]->GetLayerNumber(t.GetX())+1;
+// continue;
+// }
+ }
+
+ expectedNumberOfClusters++;
+ t.fNExpected++;
+ if (t.fX>345) t.fNExpectedLast++;
+
+ AliTRDpropagationLayer& timeBin=*(fTrSec[s]->GetLayer(nr+1));
+ Double_t sy2=ExpectedSigmaY2(t.GetX(),t.GetTgl(),t.GetPt());
+ if((t.GetSigmaY2() + sy2) < 0) {
+ printf("problem\n");
+ break;
+ }
+ Double_t road = 10.*sqrt(t.GetSigmaY2() + sy2);
+
+ if (road>fgkWideRoad) {
+ return 0;
+ }
+
+ AliTRDcluster *cl=0;
+ UInt_t index=0;
+ Double_t maxChi2=fgkMaxChi2;
+
+ // Now go for the real cluster search
+
+ if (timeBin) {
+
+ if (clusters[nr+1]>0) {
+ index = clusters[nr+1];
+ cl = (AliTRDcluster*)GetCluster(index);
+ Double_t h01 = GetTiltFactor(cl);
+ maxChi2=t.GetPredictedChi2(cl,h01);
+ }
+
+ if (cl) {
+ if (cl->GetNPads()<5)
+ t.SetSampledEdx(TMath::Abs(cl->GetQ()/dx));
+ Double_t h01 = GetTiltFactor(cl);
+ Int_t det = cl->GetDetector();
+ Int_t plane = fGeom->GetPlane(det);
+ if (t.fX>345){
+ t.fNLast++;
+ t.fChi2Last+=maxChi2;
+ }
+ if(!t.UpdateMI(cl,maxChi2,index,h01,plane)) {
+ if(!t.Update(cl,maxChi2,index,h01)) {
+ //if(!tryAgain--) return 0;
+ }
+ }
+ else tryAgain=fMaxGap;
+ //
+
+ if (cl->GetLocalTimeBin()==1&&t.fN>20 && float(t.fChi2)/float(t.fN)<5){
+ Float_t ratio1 = Float_t(t.fN)/Float_t(t.fNExpected);
+ if (tracklet.GetChi2()<18&&ratio0>0.8&&ratio1>0.6 &&ratio0+ratio1>1.5 && t.GetNCross()==0 && TMath::Abs(t.GetSnp())<0.85){
+ t.MakeBackupTrack(); // make backup of the track until is gold
+ }
+ }
+
+ }
+ else {
+ // if (tryAgain==0) break;
+ //tryAgain--;
+ }
+
+
+ }
+ }
+ }
+ if (nr<outerTB)
+ t.SetStop(kTRUE);
+ else
+ t.SetStop(kFALSE);
+ return expectedNumberOfClusters;
+
+
+}
- if(!t.PropagateTo(x,rad_length,rho)) break;
+//---------------------------------------------------------------------------
+Int_t AliTRDtracker::Refit(AliTRDtrack& t, Int_t rf)
+{
+ // Starting from current position on track=t this function tries
+ // to extrapolate the track up to timeBin=0 and to reuse already
+ // assigned clusters. Returns the number of clusters
+ // expected to be found in sensitive layers
+ // get indices of assigned clusters for each layer
+ // Origin: Thomas KUHR (Thomas.Kuhr@cern.ch)
+
+ Int_t iCluster[90];
+ for (Int_t i = 0; i < 90; i++) iCluster[i] = 0;
+ for (Int_t i = 0; i < t.GetNumberOfClusters(); i++) {
+ Int_t index = t.GetClusterIndex(i);
+ AliTRDcluster *cl=(AliTRDcluster*) GetCluster(index);
+ if (!cl) continue;
+ Int_t detector=cl->GetDetector();
+ Int_t localTimeBin=cl->GetLocalTimeBin();
+ Int_t sector=fGeom->GetSector(detector);
+ Int_t plane=fGeom->GetPlane(detector);
+
+ Int_t trackingSector = CookSectorIndex(sector);
+
+ Int_t gtb = fTrSec[trackingSector]->CookTimeBinIndex(plane,localTimeBin);
+ if(gtb < 0) continue;
+ Int_t layer = fTrSec[trackingSector]->GetLayerNumber(gtb);
+ iCluster[layer] = index;
+ }
+ t.ResetClusters();
+ Int_t ns=Int_t(2*TMath::Pi()/AliTRDgeometry::GetAlpha()+0.5);
+
+ Double_t alpha=t.GetAlpha();
+ alpha = TVector2::Phi_0_2pi(alpha);
+
+ Int_t s=Int_t(alpha/AliTRDgeometry::GetAlpha())%AliTRDgeometry::kNsect;
+ Double_t radLength, rho, x, dx, y, ymax, z;
+
+ Int_t expectedNumberOfClusters = 0;
+ Bool_t lookForCluster;
+
+ alpha=AliTRDgeometry::GetAlpha(); // note: change in meaning
+
+
+ for (Int_t nr=fTrSec[0]->GetLayerNumber(t.GetX()); nr>rf; nr--) {
+
+ y = t.GetY(); z = t.GetZ();
+
+ // first propagate to the inner surface of the current time bin
+ fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
+ x = fTrSec[s]->GetLayer(nr)->GetX()-dx/2; y = t.GetY(); z = t.GetZ();
+ if(!t.PropagateTo(x,radLength,rho)) break;
y = t.GetY();
ymax = x*TMath::Tan(0.5*alpha);
-
if (y > ymax) {
s = (s+1) % ns;
if (!t.Rotate(alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
} else if (y <-ymax) {
s = (s-1+ns) % ns;
if (!t.Rotate(-alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
}
+
y = t.GetY(); z = t.GetZ();
// now propagate to the middle plane of the next time bin
- fTrSec[s]->GetLayer(nr+1)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
-
- x = fTrSec[s]->GetLayer(nr+1)->GetX(); y = t.GetY(); z = t.GetZ();
-
- if(!t.PropagateTo(x,rad_length,rho)) break;
-
+ fTrSec[s]->GetLayer(nr-1)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
+ x = fTrSec[s]->GetLayer(nr-1)->GetX(); y = t.GetY(); z = t.GetZ();
+ if(!t.PropagateTo(x,radLength,rho)) break;
y = t.GetY();
-
ymax = x*TMath::Tan(0.5*alpha);
-
- if(fVocal) printf("nr+1=%d, x %f, z %f, y %f, ymax %f\n",nr+1,x,z,y,ymax);
-
if (y > ymax) {
s = (s+1) % ns;
if (!t.Rotate(alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
} else if (y <-ymax) {
- s = (s-1+ns) % ns;
+ s = (s-1+ns) % ns;
if (!t.Rotate(-alpha)) break;
- if(!t.PropagateTo(x,rad_length,rho)) break;
+ if(!t.PropagateTo(x,radLength,rho)) break;
}
- // printf("label %d, pl %d, lookForCluster %d \n",
- // trackIndex, nr+1, lookForCluster);
-
- if(lookForCluster) {
- expectedNumberOfClusters++;
-
- wIndex = (Float_t) t.GetLabel();
- wTB = fTrSec[s]->GetLayer(nr+1)->GetTimeBinIndex();
-
- AliTRDpropagationLayer& time_bin=*(fTrSec[s]->GetLayer(nr+1));
- Double_t sy2=ExpectedSigmaY2(t.GetX(),t.GetTgl(),t.GetPt());
- Double_t sz2=ExpectedSigmaZ2(t.GetX(),t.GetTgl());
- if((t.GetSigmaY2() + sy2) < 0) break;
- Double_t road = 10.*sqrt(t.GetSigmaY2() + sy2);
- Double_t y=t.GetY(), z=t.GetZ();
-
- wYrt = (Float_t) y;
- wZrt = (Float_t) z;
- wYwindow = (Float_t) road;
- t.GetPxPyPz(Px,Py,Pz);
- wPx = (Float_t) Px;
- wPy = (Float_t) Py;
- wPz = (Float_t) Pz;
- wC = (Float_t) t.GetC();
- wSigmaC2 = (Float_t) t.GetSigmaC2();
- wSigmaTgl2 = (Float_t) t.GetSigmaTgl2();
- wSigmaY2 = (Float_t) t.GetSigmaY2();
- wSigmaZ2 = (Float_t) t.GetSigmaZ2();
- wChi2 = -1;
-
- if (road>fWideRoad) {
- if (t.GetNumberOfClusters()>4)
- cerr<<t.GetNumberOfClusters()
- <<"FindProlongation warning: Too broad road !\n";
- return 0;
- }
+ if(lookForCluster) expectedNumberOfClusters++;
- AliTRDcluster *cl=0;
- UInt_t index=0;
-
- Double_t max_chi2=fMaxChi2;
-
- wYclosest = 12345678;
- wYcorrect = 12345678;
- wZclosest = 12345678;
- wZcorrect = 12345678;
- wZwindow = TMath::Sqrt(2.25 * 12 * sz2);
+ // use assigned cluster
+ if (!iCluster[nr-1]) continue;
+ AliTRDcluster *cl=(AliTRDcluster*)GetCluster(iCluster[nr-1]);
+ Double_t h01 = GetTiltFactor(cl);
+ Double_t chi2=t.GetPredictedChi2(cl, h01);
+ if (cl->GetNPads()<5) t.SetSampledEdx(TMath::Abs(cl->GetQ()/dx));
- // Find the closest correct cluster for debugging purposes
- if (time_bin) {
- Float_t minDY = 1000000;
- for (Int_t i=0; i<time_bin; i++) {
- AliTRDcluster* c=(AliTRDcluster*)(time_bin[i]);
- if((c->GetLabel(0) != trackIndex) &&
- (c->GetLabel(1) != trackIndex) &&
- (c->GetLabel(2) != trackIndex)) continue;
- if(TMath::Abs(c->GetY() - y) > minDY) continue;
- minDY = TMath::Abs(c->GetY() - y);
- wYcorrect = c->GetY();
- wZcorrect = c->GetZ();
-
- Double_t h01 = GetTiltFactor(c);
- wChi2 = t.GetPredictedChi2(c, h01);
- }
- }
-
- // Now go for the real cluster search
-
- if (time_bin) {
-
- for (Int_t i=time_bin.Find(y-road); i<time_bin; i++) {
- AliTRDcluster* c=(AliTRDcluster*)(time_bin[i]);
- if (c->GetY() > y+road) break;
- if (c->IsUsed() > 0) continue;
- if((c->GetZ()-z)*(c->GetZ()-z) > 3 * sz2) continue;
-
- Double_t h01 = GetTiltFactor(c);
- Double_t chi2=t.GetPredictedChi2(c,h01);
-
- if (chi2 > max_chi2) continue;
- max_chi2=chi2;
- cl=c;
- index=time_bin.GetIndex(i);
- }
-
- if(!cl) {
-
- for (Int_t i=time_bin.Find(y-road); i<time_bin; i++) {
- AliTRDcluster* c=(AliTRDcluster*)(time_bin[i]);
-
- if (c->GetY() > y+road) break;
- if (c->IsUsed() > 0) continue;
- if((c->GetZ()-z)*(c->GetZ()-z) > 2.25 * 12 * sz2) continue;
-
- Double_t h01 = GetTiltFactor(c);
- Double_t chi2=t.GetPredictedChi2(c,h01);
-
- if (chi2 > max_chi2) continue;
- max_chi2=chi2;
- cl=c;
- index=time_bin.GetIndex(i);
- }
- }
-
- if (cl) {
- wYclosest = cl->GetY();
- wZclosest = cl->GetZ();
-
- t.SetSampledEdx(cl->GetQ()/dx,t.GetNumberOfClusters());
- Double_t h01 = GetTiltFactor(cl);
- if(!t.Update(cl,max_chi2,index,h01)) {
- if(!try_again--) return 0;
- }
- else try_again=fMaxGap;
- }
- else {
- if (try_again==0) break;
- try_again--;
- }
-
- /*
- if((((Int_t) wTB)%15 == 0) || (((Int_t) wTB)%15 == 14)) {
-
- printf(" %f", wIndex); //1
- printf(" %f", wTB); //2
- printf(" %f", wYrt); //3
- printf(" %f", wYclosest); //4
- printf(" %f", wYcorrect); //5
- printf(" %f", wYwindow); //6
- printf(" %f", wZrt); //7
- printf(" %f", wZclosest); //8
- printf(" %f", wZcorrect); //9
- printf(" %f", wZwindow); //10
- printf(" %f", wPx); //11
- printf(" %f", wPy); //12
- printf(" %f", wPz); //13
- printf(" %f", wSigmaC2*1000000); //14
- printf(" %f", wSigmaTgl2*1000); //15
- printf(" %f", wSigmaY2); //16
- // printf(" %f", wSigmaZ2); //17
- printf(" %f", wChi2); //17
- printf(" %f", wC); //18
- printf("\n");
- }
- */
- }
- }
+ //t.SetSampledEdx(cl->GetQ()/dx,t.GetNumberOfClusters());
+ t.Update(cl,chi2,iCluster[nr-1],h01);
}
+
return expectedNumberOfClusters;
-}
+}
//___________________________________________________________________
Int_t s=Int_t(alpha/AliTRDgeometry::GetAlpha())%AliTRDgeometry::kNsect;
Bool_t lookForCluster;
- Double_t rad_length, rho, x, dx, y, ymax, z;
+ Double_t radLength, rho, x, dx, y, ymax, z;
x = t.GetX();
y = t.GetY(); z = t.GetZ();
// first propagate to the outer surface of the current time bin
- fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
+ fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
x = fTrSec[s]->GetLayer(nr)->GetX()+dx/2; y = t.GetY(); z = t.GetZ();
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
y = t.GetY();
ymax = x*TMath::Tan(0.5*alpha);
if (y > ymax) {
s = (s-1+ns) % ns;
if (!t.Rotate(-alpha)) return 0;
}
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
y = t.GetY(); z = t.GetZ();
// now propagate to the middle plane of the next time bin
- fTrSec[s]->GetLayer(nr+1)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
+ fTrSec[s]->GetLayer(nr+1)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
x = fTrSec[s]->GetLayer(nr+1)->GetX(); y = t.GetY(); z = t.GetZ();
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
y = t.GetY();
ymax = x*TMath::Tan(0.5*alpha);
if (y > ymax) {
s = (s-1+ns) % ns;
if (!t.Rotate(-alpha)) return 0;
}
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
}
return 1;
}
// padrow of the TPC.
// Returns 1 if track reaches the TPC, and 0 otherwise
- Int_t ns=Int_t(2*TMath::Pi()/AliTRDgeometry::GetAlpha()+0.5);
+ //Int_t ns=Int_t(2*TMath::Pi()/AliTRDgeometry::GetAlpha()+0.5);
Double_t alpha=t.GetAlpha();
-
- if (alpha > 2.*TMath::Pi()) alpha -= 2.*TMath::Pi();
- if (alpha < 0. ) alpha += 2.*TMath::Pi();
+ alpha = TVector2::Phi_0_2pi(alpha);
Int_t s=Int_t(alpha/AliTRDgeometry::GetAlpha())%AliTRDgeometry::kNsect;
Bool_t lookForCluster;
- Double_t rad_length, rho, x, dx, y, ymax, z;
+ Double_t radLength, rho, x, dx, y, /*ymax,*/ z;
x = t.GetX();
alpha=AliTRDgeometry::GetAlpha(); // note: change in meaning
-
Int_t plTPC = fTrSec[0]->GetLayerNumber(246.055);
for (Int_t nr=fTrSec[0]->GetLayerNumber(x); nr>plTPC; nr--) {
- y = t.GetY(); z = t.GetZ();
+ y = t.GetY();
+ z = t.GetZ();
// first propagate to the outer surface of the current time bin
- fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
- x = fTrSec[s]->GetLayer(nr)->GetX()-dx/2; y = t.GetY(); z = t.GetZ();
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
- y = t.GetY();
- ymax = x*TMath::Tan(0.5*alpha);
- if (y > ymax) {
- s = (s+1) % ns;
- if (!t.Rotate(alpha)) return 0;
- } else if (y <-ymax) {
- s = (s-1+ns) % ns;
- if (!t.Rotate(-alpha)) return 0;
- }
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
+ fTrSec[s]->GetLayer(nr)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
+ x = fTrSec[s]->GetLayer(nr)->GetX()-dx/2;
+
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
+ AdjustSector(&t);
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
- y = t.GetY(); z = t.GetZ();
+ y = t.GetY();
+ z = t.GetZ();
// now propagate to the middle plane of the next time bin
- fTrSec[s]->GetLayer(nr-1)->GetPropagationParameters(y,z,dx,rho,rad_length,lookForCluster);
- x = fTrSec[s]->GetLayer(nr-1)->GetX(); y = t.GetY(); z = t.GetZ();
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
- y = t.GetY();
- ymax = x*TMath::Tan(0.5*alpha);
- if (y > ymax) {
- s = (s+1) % ns;
- if (!t.Rotate(alpha)) return 0;
- } else if (y <-ymax) {
- s = (s-1+ns) % ns;
- if (!t.Rotate(-alpha)) return 0;
- }
- if(!t.PropagateTo(x,rad_length,rho)) return 0;
- }
+ fTrSec[s]->GetLayer(nr-1)->GetPropagationParameters(y,z,dx,rho,radLength,lookForCluster);
+ x = fTrSec[s]->GetLayer(nr-1)->GetX();
+
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
+ AdjustSector(&t);
+ if(!t.PropagateTo(x,radLength,rho)) return 0;
+ }
return 1;
}
-
//_____________________________________________________________________________
-void AliTRDtracker::LoadEvent()
+Int_t AliTRDtracker::LoadClusters(TTree *cTree)
{
// Fills clusters into TRD tracking_sectors
// Note that the numbering scheme for the TRD tracking_sectors
// differs from that of TRD sectors
-
- ReadClusters(fClusters);
+ cout<<"\n Read Sectors clusters"<<endl;
+ if (ReadClusters(fClusters,cTree)) {
+ Error("LoadClusters","Problem with reading the clusters !");
+ return 1;
+ }
Int_t ncl=fClusters->GetEntriesFast();
+ fNclusters=ncl;
cout<<"\n LoadSectors: sorting "<<ncl<<" clusters"<<endl;
UInt_t index;
+ for (Int_t ichamber=0;ichamber<5;ichamber++)
+ for (Int_t isector=0;isector<18;isector++){
+ fHoles[ichamber][isector]=kTRUE;
+ }
+
+
while (ncl--) {
- printf("\r %d left ",ncl);
+// printf("\r %d left ",ncl);
AliTRDcluster *c=(AliTRDcluster*)fClusters->UncheckedAt(ncl);
- Int_t detector=c->GetDetector(), local_time_bin=c->GetLocalTimeBin();
+ Int_t detector=c->GetDetector();
+ Int_t localTimeBin=c->GetLocalTimeBin();
Int_t sector=fGeom->GetSector(detector);
Int_t plane=fGeom->GetPlane(detector);
+
+ Int_t trackingSector = CookSectorIndex(sector);
+ if (c->GetLabel(0)>0){
+ Int_t chamber = fGeom->GetChamber(detector);
+ fHoles[chamber][trackingSector]=kFALSE;
+ }
- Int_t tracking_sector = CookSectorIndex(sector);
-
- Int_t gtb = fTrSec[tracking_sector]->CookTimeBinIndex(plane,local_time_bin);
+ Int_t gtb = fTrSec[trackingSector]->CookTimeBinIndex(plane,localTimeBin);
if(gtb < 0) continue;
- Int_t layer = fTrSec[tracking_sector]->GetLayerNumber(gtb);
+ Int_t layer = fTrSec[trackingSector]->GetLayerNumber(gtb);
index=ncl;
- fTrSec[tracking_sector]->GetLayer(layer)->InsertCluster(c,index);
+ fTrSec[trackingSector]->GetLayer(layer)->InsertCluster(c,index);
}
- printf("\r\n");
-
+ // printf("\r\n");
+ //
+ //
+ /*
+ for (Int_t isector=0;isector<18;isector++){
+ for (Int_t ichamber=0;ichamber<5;ichamber++)
+ if (fHoles[ichamber][isector]!=fGeom->IsHole(0,ichamber,17-isector))
+ printf("Problem \t%d\t%d\t%d\t%d\n",isector,ichamber,fHoles[ichamber][isector],
+ fGeom->IsHole(0,ichamber,17-isector));
+ }
+ */
+ return 0;
}
//_____________________________________________________________________________
-void AliTRDtracker::UnloadEvent()
+void AliTRDtracker::UnloadClusters()
{
//
// Clears the arrays of clusters and tracks. Resets sectors and timebins
nentr = fClusters->GetEntriesFast();
for (i = 0; i < nentr; i++) delete fClusters->RemoveAt(i);
+ fNclusters = 0;
nentr = fSeeds->GetEntriesFast();
for (i = 0; i < nentr; i++) delete fSeeds->RemoveAt(i);
}
Double_t x[5], c[15];
- Int_t max_sec=AliTRDgeometry::kNsect;
+ Int_t maxSec=AliTRDgeometry::kNsect;
Double_t alpha=AliTRDgeometry::GetAlpha();
Double_t shift=AliTRDgeometry::GetAlpha()/2.;
Double_t x1 =fTrSec[0]->GetX(i1);
Double_t xx2=fTrSec[0]->GetX(i2);
- for (Int_t ns=0; ns<max_sec; ns++) {
+ for (Int_t ns=0; ns<maxSec; ns++) {
- Int_t nl2 = *(fTrSec[(ns-2+max_sec)%max_sec]->GetLayer(i2));
- Int_t nl=(*fTrSec[(ns-1+max_sec)%max_sec]->GetLayer(i2));
+ Int_t nl2 = *(fTrSec[(ns-2+maxSec)%maxSec]->GetLayer(i2));
+ Int_t nl=(*fTrSec[(ns-1+maxSec)%maxSec]->GetLayer(i2));
Int_t nm=(*fTrSec[ns]->GetLayer(i2));
- Int_t nu=(*fTrSec[(ns+1)%max_sec]->GetLayer(i2));
- Int_t nu2=(*fTrSec[(ns+2)%max_sec]->GetLayer(i2));
+ Int_t nu=(*fTrSec[(ns+1)%maxSec]->GetLayer(i2));
+ Int_t nu2=(*fTrSec[(ns+2)%maxSec]->GetLayer(i2));
AliTRDpropagationLayer& r1=*(fTrSec[ns]->GetLayer(i1));
Double_t y1=r1[is]->GetY(), z1=r1[is]->GetZ();
for (Int_t js=0; js < nl2+nl+nm+nu+nu2; js++) {
-
- const AliTRDcluster *cl;
- Double_t x2, y2, z2;
- Double_t x3=0., y3=0.;
-
- if (js<nl2) {
- if(turn != 2) continue;
- AliTRDpropagationLayer& r2=*(fTrSec[(ns-2+max_sec)%max_sec]->GetLayer(i2));
- cl=r2[js];
- y2=cl->GetY(); z2=cl->GetZ();
-
- x2= xx2*cs2+y2*sn2;
- y2=-xx2*sn2+y2*cs2;
- }
- else if (js<nl2+nl) {
- if(turn != 1) continue;
- AliTRDpropagationLayer& r2=*(fTrSec[(ns-1+max_sec)%max_sec]->GetLayer(i2));
- cl=r2[js-nl2];
- y2=cl->GetY(); z2=cl->GetZ();
-
- x2= xx2*cs+y2*sn;
- y2=-xx2*sn+y2*cs;
- }
- else if (js<nl2+nl+nm) {
- if(turn != 1) continue;
- AliTRDpropagationLayer& r2=*(fTrSec[ns]->GetLayer(i2));
- cl=r2[js-nl2-nl];
- x2=xx2; y2=cl->GetY(); z2=cl->GetZ();
- }
- else if (js<nl2+nl+nm+nu) {
- if(turn != 1) continue;
- AliTRDpropagationLayer& r2=*(fTrSec[(ns+1)%max_sec]->GetLayer(i2));
- cl=r2[js-nl2-nl-nm];
- y2=cl->GetY(); z2=cl->GetZ();
-
- x2=xx2*cs-y2*sn;
- y2=xx2*sn+y2*cs;
- }
- else {
- if(turn != 2) continue;
- AliTRDpropagationLayer& r2=*(fTrSec[(ns+2)%max_sec]->GetLayer(i2));
- cl=r2[js-nl2-nl-nm-nu];
- y2=cl->GetY(); z2=cl->GetZ();
-
- x2=xx2*cs2-y2*sn2;
- y2=xx2*sn2+y2*cs2;
+
+ const AliTRDcluster *cl;
+ Double_t x2, y2, z2;
+ Double_t x3=0., y3=0.;
+
+ if (js<nl2) {
+ if(turn != 2) continue;
+ AliTRDpropagationLayer& r2=*(fTrSec[(ns-2+maxSec)%maxSec]->GetLayer(i2));
+ cl=r2[js];
+ y2=cl->GetY(); z2=cl->GetZ();
+
+ x2= xx2*cs2+y2*sn2;
+ y2=-xx2*sn2+y2*cs2;
+ }
+ else if (js<nl2+nl) {
+ if(turn != 1) continue;
+ AliTRDpropagationLayer& r2=*(fTrSec[(ns-1+maxSec)%maxSec]->GetLayer(i2));
+ cl=r2[js-nl2];
+ y2=cl->GetY(); z2=cl->GetZ();
+
+ x2= xx2*cs+y2*sn;
+ y2=-xx2*sn+y2*cs;
+ }
+ else if (js<nl2+nl+nm) {
+ if(turn != 1) continue;
+ AliTRDpropagationLayer& r2=*(fTrSec[ns]->GetLayer(i2));
+ cl=r2[js-nl2-nl];
+ x2=xx2; y2=cl->GetY(); z2=cl->GetZ();
+ }
+ else if (js<nl2+nl+nm+nu) {
+ if(turn != 1) continue;
+ AliTRDpropagationLayer& r2=*(fTrSec[(ns+1)%maxSec]->GetLayer(i2));
+ cl=r2[js-nl2-nl-nm];
+ y2=cl->GetY(); z2=cl->GetZ();
+
+ x2=xx2*cs-y2*sn;
+ y2=xx2*sn+y2*cs;
+ }
+ else {
+ if(turn != 2) continue;
+ AliTRDpropagationLayer& r2=*(fTrSec[(ns+2)%maxSec]->GetLayer(i2));
+ cl=r2[js-nl2-nl-nm-nu];
+ y2=cl->GetY(); z2=cl->GetZ();
+
+ x2=xx2*cs2-y2*sn2;
+ y2=xx2*sn2+y2*cs2;
+ }
+
+ if(TMath::Abs(z1-z2) > fgkMaxSeedDeltaZ12) continue;
+
+ Double_t zz=z1 - z1/x1*(x1-x2);
+
+ if (TMath::Abs(zz-z2)>fgkMaxSeedDeltaZ) continue;
+
+ Double_t d=(x2-x1)*(0.-y2)-(0.-x2)*(y2-y1);
+ if (d==0.) {cerr<<"TRD MakeSeeds: Straight seed !\n"; continue;}
+
+ x[0]=y1;
+ x[1]=z1;
+ x[4]=f1trd(x1,y1,x2,y2,x3,y3);
+
+ if (TMath::Abs(x[4]) > fgkMaxSeedC) continue;
+
+ x[2]=f2trd(x1,y1,x2,y2,x3,y3);
+
+ if (TMath::Abs(x[4]*x1-x[2]) >= 0.99999) continue;
+
+ x[3]=f3trd(x1,y1,x2,y2,z1,z2);
+
+ if (TMath::Abs(x[3]) > fgkMaxSeedTan) continue;
+
+ Double_t a=asin(x[2]);
+ Double_t zv=z1 - x[3]/x[4]*(a+asin(x[4]*x1-x[2]));
+
+ if (TMath::Abs(zv)>fgkMaxSeedVertexZ) continue;
+
+ Double_t sy1=r1[is]->GetSigmaY2(), sz1=r1[is]->GetSigmaZ2();
+ Double_t sy2=cl->GetSigmaY2(), sz2=cl->GetSigmaZ2();
+ Double_t sy3=fgkSeedErrorSY3, sy=fgkSeedErrorSY, sz=fgkSeedErrorSZ;
+
+ // Tilt changes
+ Double_t h01 = GetTiltFactor(r1[is]);
+ Double_t xuFactor = 100.;
+ if(fNoTilt) {
+ h01 = 0;
+ xuFactor = 1;
}
-
- if(TMath::Abs(z1-z2) > fMaxSeedDeltaZ12) continue;
-
- Double_t zz=z1 - z1/x1*(x1-x2);
-
- if (TMath::Abs(zz-z2)>fMaxSeedDeltaZ) continue;
-
- Double_t d=(x2-x1)*(0.-y2)-(0.-x2)*(y2-y1);
- if (d==0.) {cerr<<"TRD MakeSeeds: Straight seed !\n"; continue;}
-
- x[0]=y1;
- x[1]=z1;
- x[4]=f1trd(x1,y1,x2,y2,x3,y3);
-
- if (TMath::Abs(x[4]) > fMaxSeedC) continue;
-
- x[2]=f2trd(x1,y1,x2,y2,x3,y3);
-
- if (TMath::Abs(x[4]*x1-x[2]) >= 0.99999) continue;
-
- x[3]=f3trd(x1,y1,x2,y2,z1,z2);
-
- if (TMath::Abs(x[3]) > fMaxSeedTan) continue;
-
- Double_t a=asin(x[2]);
- Double_t zv=z1 - x[3]/x[4]*(a+asin(x[4]*x1-x[2]));
-
- if (TMath::Abs(zv)>fMaxSeedVertexZ) continue;
-
- Double_t sy1=r1[is]->GetSigmaY2(), sz1=r1[is]->GetSigmaZ2();
- Double_t sy2=cl->GetSigmaY2(), sz2=cl->GetSigmaZ2();
- Double_t sy3=fSeedErrorSY3, sy=fSeedErrorSY, sz=fSeedErrorSZ;
- // Tilt changes
- Double_t h01 = GetTiltFactor(r1[is]);
sy1=sy1+sz1*h01*h01;
Double_t syz=sz1*(-h01);
- // end of tilt changes
-
+ // end of tilt changes
+
Double_t f40=(f1trd(x1,y1+sy,x2,y2,x3,y3)-x[4])/sy;
Double_t f42=(f1trd(x1,y1,x2,y2+sy,x3,y3)-x[4])/sy;
Double_t f43=(f1trd(x1,y1,x2,y2,x3,y3+sy)-x[4])/sy;
Double_t f32=(f3trd(x1,y1,x2,y2+sy,z1,z2)-x[3])/sy;
Double_t f34=(f3trd(x1,y1,x2,y2,z1,z2+sz)-x[3])/sz;
-
+
c[0]=sy1;
- // c[1]=0.; c[2]=sz1;
- c[1]=syz; c[2]=sz1*100;
+ // c[1]=0.; c[2]=sz1;
+ c[1]=syz; c[2]=sz1*xuFactor;
c[3]=f20*sy1; c[4]=0.; c[5]=f20*sy1*f20+f22*sy2*f22+f23*sy3*f23;
c[6]=f30*sy1; c[7]=f31*sz1; c[8]=f30*sy1*f20+f32*sy2*f22;
c[9]=f30*sy1*f30+f31*sz1*f31+f32*sy2*f32+f34*sz2*f34;
c[10]=f40*sy1; c[11]=0.; c[12]=f40*sy1*f20+f42*sy2*f22+f43*sy3*f23;
c[13]=f30*sy1*f40+f32*sy2*f42;
c[14]=f40*sy1*f40+f42*sy2*f42+f43*sy3*f43;
+
+ UInt_t index=r1.GetIndex(is);
+
+ AliTRDtrack *track=new AliTRDtrack(r1[is],index,x,c,x1,ns*alpha+shift);
+
+ Int_t rc=FollowProlongation(*track, i2);
+
+ if ((rc < 1) ||
+ (track->GetNumberOfClusters() <
+ (outer-inner)*fgkMinClustersInSeed)) delete track;
+ else {
+ fSeeds->AddLast(track); fNseeds++;
+// cerr<<"\r found seed "<<fNseeds;
+ }
+ }
+ }
+ }
+}
+//__________________________________________________________________________
+void AliTRDtracker::MakeSeedsMI(Int_t /*inner*/, Int_t /*outer*/)
+{
+ //
+ // Creates seeds using clusters between position inner plane and outer plane
+ //
-
- UInt_t index=r1.GetIndex(is);
-
- AliTRDtrack *track=new AliTRDtrack(r1[is],index,x,c,x1,ns*alpha+shift);
+ const Double_t maxtheta = 2;
+ const Double_t maxphi = 1.5;
+ Int_t maxSec=AliTRDgeometry::kNsect;
- Int_t rc=FollowProlongation(*track, i2);
-
- if ((rc < 1) ||
- (track->GetNumberOfClusters() <
- (outer-inner)*fMinClustersInSeed)) delete track;
- else {
- fSeeds->AddLast(track); fNseeds++;
- cerr<<"\r found seed "<<fNseeds;
+ //
+ // find the maximal and minimal layer for the planes
+ // fucking "object oriented" geometry - find the time bin range for different planes
+ //
+ Int_t layers[6][2];
+ for (Int_t i=0;i<6;i++){layers[i][0]=10000; layers[i][1]=0;}
+
+ for (Int_t ns=0;ns<maxSec;ns++){
+ for (Int_t ilayer=0;ilayer<fTrSec[ns]->GetNumberOfLayers();ilayer++){
+ AliTRDpropagationLayer& layer=*(fTrSec[ns]->GetLayer(ilayer));
+ if (layer==0) continue;
+ Int_t det = layer[0]->GetDetector();
+ Int_t plane = fGeom->GetPlane(det);
+ if (ilayer<layers[plane][0]) layers[plane][0] = ilayer;
+ if (ilayer>layers[plane][1]) layers[plane][1] = ilayer;
+ }
+ }
+ //
+
+ Int_t ilayer1 = layers[5][1]; // time bin in mplification region
+ Int_t ilayer2 = layers[3][1]; //
+ Int_t ilayerM = layers[4][1]; //
+ //
+ Double_t x1 = fTrSec[0]->GetX(ilayer1);
+ Double_t x2 = fTrSec[0]->GetX(ilayer2);
+ Double_t xm = fTrSec[0]->GetX(ilayerM);
+ Double_t dist = x2-x1;
+ // Int_t indexes1[20];
+ //Int_t indexes2[20];
+ AliTRDcluster *clusters1[15],*clusters2[15],*clustersM[15];
+ //
+ //
+ for (Int_t ns=0; ns<maxSec; ns++) {
+ AliTRDpropagationLayer& layer1=*(fTrSec[ns]->GetLayer(ilayer1)); //select propagation layers
+ AliTRDpropagationLayer& layer2=*(fTrSec[ns]->GetLayer(ilayer2));
+ //
+ for (Int_t icl1=0;icl1<layer1;icl1++){
+ AliTRDcluster *cl1 = layer1[icl1];
+ if (!cl1) continue;
+ Double_t y1 = cl1->GetY();
+ Double_t z1 = cl1->GetZ();
+ //
+ for (Int_t icl2=0;icl2<layer2;icl2++){
+ AliTRDcluster *cl2 = layer2[icl2];
+ if (!cl2) continue;
+ Double_t y2 = cl2->GetY();
+ Double_t z2 = cl2->GetZ();
+ Double_t tanphi = (y2-y1)/dist;
+ Double_t tantheta = (z2-z1)/dist;
+ if (TMath::Abs(tanphi)>maxphi) continue;
+ if (TMath::Abs(tantheta)>maxtheta) continue;
+ //
+ clusters1[0] = cl1;
+ clusters2[0] = cl2;
+ Double_t road = 0.5+TMath::Abs(tanphi)*1;
+ Int_t ncl=0;
+ Double_t sum1=0, sumx1=0,sum2x1=0,sumxy1=0, sumy1=0;
+ Double_t sum2=0, sumx2=0,sum2x2=0,sumxy2=0, sumy2=0;
+ //
+ for (Int_t dlayer=1;dlayer<15;dlayer++){
+ clusters1[dlayer]=0;
+ clusters2[dlayer]=0;
+ AliTRDpropagationLayer& layer1C=*(fTrSec[ns]->GetLayer(ilayer1-dlayer)); //select propagation layers
+ AliTRDpropagationLayer& layer2C=*(fTrSec[ns]->GetLayer(ilayer2-dlayer)); //
+ Double_t yy1 = y1+(tanphi) *(layer1C.GetX()-x1);
+ Double_t zz1 = z1+(tantheta)*(layer1C.GetX()-x1);
+ Double_t yy2 = y1+(tanphi) *(layer2C.GetX()-x1);
+ Double_t zz2 = z1+(tantheta)*(layer2C.GetX()-x1);
+ Int_t index1 = layer1C.FindNearestCluster(yy1,zz1,road);
+ Int_t index2 = layer2C.FindNearestCluster(yy2,zz2,road);
+ if (index1>=0) {
+ clusters1[dlayer]= (AliTRDcluster*)GetCluster(index1);
+ ncl++;
+ sum1++;
+ Double_t dx = layer1C.GetX()-x1;
+ sumx1 +=dx;
+ sum2x1+=dx*dx;
+ sumxy1+=dx*clusters1[dlayer]->GetY();
+ sumy1 +=clusters1[dlayer]->GetY();
+ }
+ if (index2>=0) {
+ clusters2[dlayer]= (AliTRDcluster*)GetCluster(index2);
+ ncl++;
+ sum2++;
+ Double_t dx = layer2C.GetX()-x2;
+ sumx2 +=dx;
+ sum2x2+=dx*dx;
+ sumxy2+=dx*clusters2[dlayer]->GetY();
+ sumy2 +=clusters2[dlayer]->GetY();
+ }
+ }
+ if (sum1<10) continue;
+ if (sum2<10) continue;
+ //
+ Double_t det1 = sum1*sum2x1-sumx1*sumx1;
+ Double_t angle1 = (sum1*sumxy1-sumx1*sumy1)/det1;
+ Double_t pos1 = (sum2x1*sumy1-sumx1*sumxy1)/det1; // at x1
+ //
+ Double_t det2 = sum2*sum2x2-sumx2*sumx2;
+ Double_t angle2 = (sum2*sumxy2-sumx2*sumy2)/det2;
+ Double_t pos2 = (sum2x2*sumy2-sumx2*sumxy2)/det2; // at x2
+ //
+ //
+
+ Double_t sumM=0, sumxM=0,sum2xM=0,sumxyM=0, sumyM=0;
+ //
+ for (Int_t dlayer=1;dlayer<15;dlayer++){
+ clustersM[dlayer]=0;
+ AliTRDpropagationLayer& layerM=*(fTrSec[ns]->GetLayer(ilayerM-dlayer)); //select propagation layers
+ Double_t yyM = y1+(tanphi) *(layerM.GetX()-x1);
+ Double_t zzM = z1+(tantheta)*(layerM.GetX()-x1);
+ Int_t indexM = layerM.FindNearestCluster(yyM,zzM,road);
+ if (indexM>=0) {
+ clustersM[dlayer]= (AliTRDcluster*)GetCluster(indexM);
+ ncl++;
+ sumM++;
+ Double_t dx = layerM.GetX()-xm;
+ sumxM +=dx;
+ sum2xM+=dx*dx;
+ sumxyM+=dx*clustersM[dlayer]->GetY();
+ sumyM +=clustersM[dlayer]->GetY();
+ }
+ }
+ Double_t detM = sumM*sum2xM-sumxM*sumxM;
+ Double_t posM=0, angleM=0;
+ if (TMath::Abs(detM)>0.0000001){
+ angleM = (sumM*sumxyM-sumxM*sumyM)/detM;
+ posM = (sum2xM*sumyM-sumxM*sumxyM)/detM; // at xm
+ }
+ //
+
+ if (ncl>15){
+ TTreeSRedirector& cstream = *fDebugStreamer;
+ cstream<<"Seeds"<<
+ "Ncl="<<ncl<<
+ "SumM="<<sumM<<
+ "x1="<<x1<<
+ "x2="<<x2<<
+ "Cl1.="<<cl1<<
+ "Cl2.="<<cl2<<
+ "Phi="<<tanphi<<
+ "Theta="<<tantheta<<
+ "Pos1="<<pos1<<
+ "Pos2="<<pos2<<
+ "PosM="<<posM<<
+ "Angle1="<<angle1<<
+ "Angle2="<<angle2<<
+ "AngleM="<<angleM<<
+ "\n";
}
}
}
}
//_____________________________________________________________________________
-void AliTRDtracker::ReadClusters(TObjArray *array, const TFile *inp)
+Int_t AliTRDtracker::ReadClusters(TObjArray *array, TTree *ClusterTree) const
{
//
// Reads AliTRDclusters (option >= 0) or AliTRDrecPoints (option < 0)
// from the file. The names of the cluster tree and branches
// should match the ones used in AliTRDclusterizer::WriteClusters()
//
-
- TDirectory *savedir=gDirectory;
-
- if (inp) {
- TFile *in=(TFile*)inp;
- if (!in->IsOpen()) {
- cerr<<"AliTRDtracker::ReadClusters(): input file is not open !\n";
- return;
- }
- else{
- in->cd();
- }
- }
-
- Char_t treeName[12];
- sprintf(treeName,"TreeR%d_TRD",fEvent);
- TTree *ClusterTree = (TTree*) gDirectory->Get(treeName);
+ Int_t nsize = Int_t(ClusterTree->GetTotBytes()/(sizeof(AliTRDcluster)));
+ TObjArray *clusterArray = new TObjArray(nsize+1000);
- TObjArray *ClusterArray = new TObjArray(400);
-
- ClusterTree->GetBranch("TRDcluster")->SetAddress(&ClusterArray);
+ TBranch *branch=ClusterTree->GetBranch("TRDcluster");
+ if (!branch) {
+ Error("ReadClusters","Can't get the branch !");
+ return 1;
+ }
+ branch->SetAddress(&clusterArray);
Int_t nEntries = (Int_t) ClusterTree->GetEntries();
- printf("found %d entries in %s.\n",nEntries,ClusterTree->GetName());
+ // printf("found %d entries in %s.\n",nEntries,ClusterTree->GetName());
// Loop through all entries in the tree
- Int_t nbytes;
+ Int_t nbytes = 0;
AliTRDcluster *c = 0;
- printf("\n");
-
+ // printf("\n");
for (Int_t iEntry = 0; iEntry < nEntries; iEntry++) {
// Import the tree
nbytes += ClusterTree->GetEvent(iEntry);
// Get the number of points in the detector
- Int_t nCluster = ClusterArray->GetEntriesFast();
- printf("\r Read %d clusters from entry %d", nCluster, iEntry);
+ Int_t nCluster = clusterArray->GetEntriesFast();
+// printf("\r Read %d clusters from entry %d", nCluster, iEntry);
// Loop through all TRD digits
for (Int_t iCluster = 0; iCluster < nCluster; iCluster++) {
- c = (AliTRDcluster*)ClusterArray->UncheckedAt(iCluster);
- AliTRDcluster *co = new AliTRDcluster(*c);
+ c = (AliTRDcluster*)clusterArray->UncheckedAt(iCluster);
+// if (c->GetNPads()>3&&(iCluster%3>0)) {
+// delete clusterArray->RemoveAt(iCluster);
+// continue;
+// }
+ // AliTRDcluster *co = new AliTRDcluster(*c); //remove unnecesary coping - + clusters are together in memory
+ AliTRDcluster *co = c;
co->SetSigmaY2(c->GetSigmaY2() * fSY2corr);
Int_t ltb = co->GetLocalTimeBin();
- if(ltb != 0) co->SetSigmaZ2(c->GetSigmaZ2() * fSZ2corr);
-
+ if(ltb == 19) co->SetSigmaZ2(c->GetSigmaZ2());
+ else if(fNoTilt) co->SetSigmaZ2(c->GetSigmaZ2() * fSZ2corr);
array->AddLast(co);
- delete ClusterArray->RemoveAt(iCluster);
+ // delete clusterArray->RemoveAt(iCluster);
+ clusterArray->RemoveAt(iCluster);
}
}
+// cout<<"Allocated"<<nsize<<"\tLoaded"<<array->GetEntriesFast()<<"\n";
- delete ClusterArray;
- savedir->cd();
+ delete clusterArray;
+ return 0;
}
-//______________________________________________________________________
-void AliTRDtracker::ReadClusters(TObjArray *array, const Char_t *filename)
+//__________________________________________________________________
+void AliTRDtracker::CookLabel(AliKalmanTrack* pt, Float_t wrong) const
{
//
- // Reads AliTRDclusters from file <filename>. The names of the cluster
- // tree and branches should match the ones used in
- // AliTRDclusterizer::WriteClusters()
- // if <array> == 0, clusters are added into AliTRDtracker fCluster array
+ // This cooks a label. Mmmmh, smells good...
//
- TDirectory *savedir=gDirectory;
-
- TFile *file = TFile::Open(filename);
- if (!file->IsOpen()) {
- cerr<<"Can't open file with TRD clusters"<<endl;
- return;
- }
-
- Char_t treeName[12];
- sprintf(treeName,"TreeR%d_TRD",fEvent);
- TTree *ClusterTree = (TTree*) gDirectory->Get(treeName);
-
- if (!ClusterTree) {
- cerr<<"AliTRDtracker::ReadClusters(): ";
- cerr<<"can't get a tree with clusters !\n";
- return;
- }
-
- TObjArray *ClusterArray = new TObjArray(400);
-
- ClusterTree->GetBranch("TRDcluster")->SetAddress(&ClusterArray);
-
- Int_t nEntries = (Int_t) ClusterTree->GetEntries();
- cout<<"found "<<nEntries<<" in ClusterTree"<<endl;
-
- // Loop through all entries in the tree
- Int_t nbytes;
- AliTRDcluster *c = 0;
-
- printf("\n");
-
- for (Int_t iEntry = 0; iEntry < nEntries; iEntry++) {
-
- // Import the tree
- nbytes += ClusterTree->GetEvent(iEntry);
-
- // Get the number of points in the detector
- Int_t nCluster = ClusterArray->GetEntriesFast();
- printf("\n Read %d clusters from entry %d", nCluster, iEntry);
-
- // Loop through all TRD digits
- for (Int_t iCluster = 0; iCluster < nCluster; iCluster++) {
- c = (AliTRDcluster*)ClusterArray->UncheckedAt(iCluster);
- AliTRDcluster *co = new AliTRDcluster(*c);
- co->SetSigmaY2(c->GetSigmaY2() * fSY2corr);
- Int_t ltb = co->GetLocalTimeBin();
- if(ltb != 0) co->SetSigmaZ2(c->GetSigmaZ2() * fSZ2corr);
- array->AddLast(co);
- delete ClusterArray->RemoveAt(iCluster);
- }
- }
-
- file->Close();
- delete ClusterArray;
- savedir->cd();
-
-}
-
-
-//__________________________________________________________________
-void AliTRDtracker::CookLabel(AliKalmanTrack* pt, Float_t wrong) const {
-
Int_t label=123456789, index, i, j;
Int_t ncl=pt->GetNumberOfClusters();
- const Int_t range = fTrSec[0]->GetOuterTimeBin()+1;
+ const Int_t kRange = fTrSec[0]->GetOuterTimeBin()+1;
- Bool_t label_added;
+ Bool_t labelAdded;
- // Int_t s[range][2];
- Int_t **s = new Int_t* [range];
- for (i=0; i<range; i++) {
+ // Int_t s[kRange][2];
+ Int_t **s = new Int_t* [kRange];
+ for (i=0; i<kRange; i++) {
s[i] = new Int_t[2];
}
- for (i=0; i<range; i++) {
+ for (i=0; i<kRange; i++) {
s[i][0]=-1;
s[i][1]=0;
}
AliTRDcluster *c=(AliTRDcluster*)fClusters->UncheckedAt(index);
for (Int_t k=0; k<3; k++) {
label=c->GetLabel(k);
- label_added=kFALSE; j=0;
+ labelAdded=kFALSE; j=0;
if (label >= 0) {
- while ( (!label_added) && ( j < range ) ) {
- if (s[j][0]==label || s[j][1]==0) {
- s[j][0]=label;
- s[j][1]=s[j][1]+1;
- label_added=kTRUE;
- }
- j++;
- }
+ while ( (!labelAdded) && ( j < kRange ) ) {
+ if (s[j][0]==label || s[j][1]==0) {
+ s[j][0]=label;
+ s[j][1]=s[j][1]+1;
+ labelAdded=kTRUE;
+ }
+ j++;
+ }
}
}
}
Int_t max=0;
label = -123456789;
- for (i=0; i<range; i++) {
+ for (i=0; i<kRange; i++) {
if (s[i][1]>max) {
max=s[i][1]; label=s[i][0];
}
}
- for (i=0; i<range; i++) {
+ for (i=0; i<kRange; i++) {
delete []s[i];
}
//__________________________________________________________________
-void AliTRDtracker::UseClusters(const AliKalmanTrack* t, Int_t from) const {
+void AliTRDtracker::UseClusters(const AliKalmanTrack* t, Int_t from) const
+{
+ //
+ // Use clusters, but don't abuse them!
+ //
+
Int_t ncl=t->GetNumberOfClusters();
for (Int_t i=from; i<ncl; i++) {
Int_t index = t->GetClusterIndex(i);
//_____________________________________________________________________
-Double_t AliTRDtracker::ExpectedSigmaY2(Double_t r, Double_t tgl, Double_t pt)
+Double_t AliTRDtracker::ExpectedSigmaY2(Double_t , Double_t , Double_t ) const
{
// Parametrised "expected" error of the cluster reconstruction in Y
}
//_____________________________________________________________________
-Double_t AliTRDtracker::ExpectedSigmaZ2(Double_t r, Double_t tgl)
+Double_t AliTRDtracker::ExpectedSigmaZ2(Double_t , Double_t ) const
{
// Parametrised "expected" error of the cluster reconstruction in Z
- Double_t s = 6 * 6 /12.;
+ Double_t s = 9 * 9 /12.;
return s;
}
-
//_____________________________________________________________________
-Double_t AliTRDtracker::GetX(Int_t sector, Int_t plane, Int_t local_tb) const
+Double_t AliTRDtracker::GetX(Int_t sector, Int_t plane, Int_t localTB) const
{
//
- // Returns radial position which corresponds to time bin <local_tb>
+ // Returns radial position which corresponds to time bin <localTB>
// in tracking sector <sector> and plane <plane>
//
- Int_t index = fTrSec[sector]->CookTimeBinIndex(plane, local_tb);
+ Int_t index = fTrSec[sector]->CookTimeBinIndex(plane, localTB);
Int_t pl = fTrSec[sector]->GetLayerNumber(index);
return fTrSec[sector]->GetLayer(pl)->GetX();
//_______________________________________________________
AliTRDtracker::AliTRDpropagationLayer::AliTRDpropagationLayer(Double_t x,
- Double_t dx, Double_t rho, Double_t rad_length, Int_t tb_index)
+ Double_t dx, Double_t rho, Double_t radLength, Int_t tbIndex)
{
//
// AliTRDpropagationLayer constructor
//
- fN = 0; fX = x; fdX = dx; fRho = rho; fX0 = rad_length;
- fClusters = NULL; fIndex = NULL; fTimeBinIndex = tb_index;
+ fN = 0; fX = x; fdX = dx; fRho = rho; fX0 = radLength;
+ fClusters = NULL; fIndex = NULL; fTimeBinIndex = tbIndex;
- for(Int_t i=0; i < (Int_t) kZONES; i++) {
+ for(Int_t i=0; i < (Int_t) kZones; i++) {
fZc[i]=0; fZmax[i] = 0;
}
fYmax = 0;
if(fTimeBinIndex >= 0) {
- fClusters = new AliTRDcluster*[kMAX_CLUSTER_PER_TIME_BIN];
- fIndex = new UInt_t[kMAX_CLUSTER_PER_TIME_BIN];
+ fClusters = new AliTRDcluster*[kMaxClusterPerTimeBin];
+ fIndex = new UInt_t[kMaxClusterPerTimeBin];
}
+ for (Int_t i=0;i<5;i++) fIsHole[i] = kFALSE;
fHole = kFALSE;
fHoleZc = 0;
fHoleZmax = 0;
//_______________________________________________________
void AliTRDtracker::AliTRDpropagationLayer::SetHole(
- Double_t Zmax, Double_t Ymax, Double_t rho,
- Double_t rad_length, Double_t Yc, Double_t Zc)
+ Double_t Zmax, Double_t Ymax, Double_t rho,
+ Double_t radLength, Double_t Yc, Double_t Zc)
{
//
// Sets hole in the layer
//
-
fHole = kTRUE;
fHoleZc = Zc;
fHoleZmax = Zmax;
fHoleYc = Yc;
fHoleYmax = Ymax;
fHoleRho = rho;
- fHoleX0 = rad_length;
+ fHoleX0 = radLength;
}
//
// AliTRDtrackingSector Constructor
//
+ AliTRDpadPlane *padPlane = 0;
fGeom = geo;
fPar = par;
fGeomSector = gs;
fTzeroShift = 0.13;
fN = 0;
-
- for(UInt_t i=0; i < kMAX_TIME_BIN_INDEX; i++) fTimeBinIndex[i] = -1;
+ //
+ // get holes description from geometry
+ Bool_t holes[AliTRDgeometry::kNcham];
+ //printf("sector\t%d\t",gs);
+ for (Int_t icham=0; icham<AliTRDgeometry::kNcham;icham++){
+ holes[icham] = fGeom->IsHole(0,icham,gs);
+ //printf("%d",holes[icham]);
+ }
+ //printf("\n");
+
+ for(UInt_t i=0; i < kMaxTimeBinIndex; i++) fTimeBinIndex[i] = -1;
AliTRDpropagationLayer* ppl;
- Double_t x, xin, xout, dx, rho, rad_length;
+ Double_t x, xin, xout, dx, rho, radLength;
Int_t steps;
// set time bins in the gas of the TPC
xin = 246.055; xout = 254.055; steps = 20; dx = (xout-xin)/steps;
- rho = 0.9e-3; rad_length = 28.94;
+ rho = 0.9e-3; radLength = 28.94;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
// set time bins in the outer field cage vessel
- dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; rad_length = 44.77; // Tedlar
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; radLength = 44.77; // Tedlar
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 0.02; xin = xout; xout = xin + dx; rho = 1.45; rad_length = 44.86; // prepreg
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 0.02; xin = xout; xout = xin + dx; rho = 1.45; radLength = 44.86; // prepreg
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 2.; xin = xout; xout = xin + dx; rho = 1.45*0.02; rad_length = 41.28; // Nomex
+ dx = 2.; xin = xout; xout = xin + dx; rho = 1.45*0.02; radLength = 41.28; // Nomex
steps = 5; dx = (xout - xin)/steps;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
- dx = 0.02; xin = xout; xout = xin + dx; rho = 1.45; rad_length = 44.86; // prepreg
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 0.02; xin = xout; xout = xin + dx; rho = 1.45; radLength = 44.86; // prepreg
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; rad_length = 44.77; // Tedlar
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; radLength = 44.77; // Tedlar
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
xin = xout; xout = 275.0;
steps = 50; dx = (xout - xin)/steps;
- rho = 1.977e-3; rad_length = 36.2;
+ rho = 1.977e-3; radLength = 36.2;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
// set time bins in the outer containment vessel
- dx = 50e-4; xin = xout; xout = xin + dx; rho = 2.7; rad_length = 24.01; // Al
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 50e-4; xin = xout; xout = xin + dx; rho = 2.7; radLength = 24.01; // Al
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; rad_length = 44.77; // Tedlar
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; radLength = 44.77; // Tedlar
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 0.06; xin = xout; xout = xin + dx; rho = 1.45; rad_length = 44.86; // prepreg
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 0.06; xin = xout; xout = xin + dx; rho = 1.45; radLength = 44.86; // prepreg
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 3.; xin = xout; xout = xin + dx; rho = 1.45*0.02; rad_length = 41.28; // Nomex
+ dx = 3.; xin = xout; xout = xin + dx; rho = 1.45*0.02; radLength = 41.28; // Nomex
steps = 10; dx = (xout - xin)/steps;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
- dx = 0.06; xin = xout; xout = xin + dx; rho = 1.45; rad_length = 44.86; // prepreg
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 0.06; xin = xout; xout = xin + dx; rho = 1.45; radLength = 44.86; // prepreg
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; rad_length = 44.77; // Tedlar
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 50e-4; xin = xout; xout = xin + dx; rho = 1.71; radLength = 44.77; // Tedlar
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
- dx = 50e-4; xin = xout; xout = xin + dx; rho = 2.7; rad_length = 24.01; // Al
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
+ dx = 50e-4; xin = xout; xout = xin + dx; rho = 2.7; radLength = 24.01; // Al
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
InsertLayer(ppl);
Double_t xtrd = (Double_t) fGeom->Rmin();
// add layers between TPC and TRD (Air temporarily)
xin = xout; xout = xtrd;
steps = 50; dx = (xout - xin)/steps;
- rho = 1.2e-3; rad_length = 36.66;
+ rho = 1.2e-3; radLength = 36.66;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
- Double_t alpha=AliTRDgeometry::GetAlpha();
+ // Double_t alpha=AliTRDgeometry::GetAlpha();
// add layers for each of the planes
Double_t dxTEC = dxRad + dxDrift + dxAmp + dxRo;
Double_t dxPlane = dxTEC + dxSpace;
- Int_t tb, tb_index;
- const Int_t nChambers = AliTRDgeometry::Ncham();
- Double_t Ymax = 0, holeYmax = 0;
- Double_t * Zc = new Double_t[nChambers];
- Double_t * Zmax = new Double_t[nChambers];
- Double_t holeZmax = 1000.; // the whole sector is missing
+ Int_t tb, tbIndex;
+ const Int_t kNchambers = AliTRDgeometry::Ncham();
+ Double_t ymax = 0;
+ //, holeYmax = 0;
+ Double_t ymaxsensitive=0;
+ Double_t *zc = new Double_t[kNchambers];
+ Double_t *zmax = new Double_t[kNchambers];
+ Double_t *zmaxsensitive = new Double_t[kNchambers];
+ // Double_t holeZmax = 1000.; // the whole sector is missing
for(Int_t plane = 0; plane < AliTRDgeometry::Nplan(); plane++) {
-
+ //
// Radiator
xin = xtrd + plane * dxPlane; xout = xin + dxRad;
- steps = 12; dx = (xout - xin)/steps; rho = 0.074; rad_length = 40.6;
+ steps = 12; dx = (xout - xin)/steps; rho = 0.074; radLength = 40.6;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
- Ymax = fGeom->GetChamberWidth(plane)/2;
- for(Int_t ch = 0; ch < nChambers; ch++) {
- Zmax[ch] = fGeom->GetChamberLength(plane,ch)/2;
- Float_t pad = fPar->GetRowPadSize(plane,ch,0);
+ ymax = fGeom->GetChamberWidth(plane)/2.;
+ // Modidified for new pad plane class, 22.04.05 (C.B.)
+ // ymaxsensitive = (fPar->GetColPadSize(plane)*fPar->GetColMax(plane)-4)/2.;
+ padPlane = fPar->GetPadPlane(plane,0);
+ ymaxsensitive = (padPlane->GetColSize(1)*padPlane->GetNcols()-4)/2.;
+
+ // ymaxsensitive = (fPar->GetColPadSize(plane)*fPar->GetColMax(plane)-4)/2.;
+
+ for(Int_t ch = 0; ch < kNchambers; ch++) {
+ zmax[ch] = fGeom->GetChamberLength(plane,ch)/2;
+ //
+ // Modidified for new pad plane class, 22.04.05 (C.B.)
+ //Float_t pad = fPar->GetRowPadSize(plane,ch,0);
+ Float_t pad = padPlane->GetRowSize(1);
+ //Float_t pad = fPar->GetRowPadSize(plane,ch,0);
Float_t row0 = fPar->GetRow0(plane,ch,0);
Int_t nPads = fPar->GetRowMax(plane,ch,0);
- Zc[ch] = (pad * nPads)/2 + row0 - pad/2;
+ zmaxsensitive[ch] = Float_t(nPads)*pad/2.;
+ // zc[ch] = (pad * nPads)/2 + row0 - pad/2;
+ // zc[ch] = (pad * nPads)/2 + row0;
+ zc[ch] = -(pad * nPads)/2 + row0;
+ //zc[ch] = row0+zmax[ch]-AliTRDgeometry::RpadW();
+
}
- dx = fPar->GetTimeBinSize();
- rho = 0.00295 * 0.85; rad_length = 11.0;
+ dx = fgkDriftCorrection*fPar->GetDriftVelocity()
+ / fPar->GetSamplingFrequency();
+ rho = 0.00295 * 0.85; radLength = 11.0;
Double_t x0 = (Double_t) fPar->GetTime0(plane);
Double_t xbottom = x0 - dxDrift;
Double_t xtop = x0 + dxAmp;
-
+ //
// Amplification region
-
steps = (Int_t) (dxAmp/dx);
for(tb = 0; tb < steps; tb++) {
- x = x0 + tb * dx + dx/2;
- tb_index = CookTimeBinIndex(plane, -tb-1);
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,tb_index);
- ppl->SetYmax(Ymax);
- for(Int_t ch = 0; ch < nChambers; ch++) {
- ppl->SetZmax(ch, Zc[ch], Zmax[ch]);
- }
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ x = x0 + tb * dx + dx/2+ fgkOffsetX;
+ tbIndex = CookTimeBinIndex(plane, -tb-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,tbIndex);
+ ppl->SetYmax(ymax,ymaxsensitive);
+ ppl->SetZ(zc, zmax, zmaxsensitive);
+ ppl->SetHoles(holes);
InsertLayer(ppl);
}
- tb_index = CookTimeBinIndex(plane, -steps);
+ tbIndex = CookTimeBinIndex(plane, -steps);
x = (x + dx/2 + xtop)/2;
dx = 2*(xtop-x);
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,tb_index);
- ppl->SetYmax(Ymax);
- for(Int_t ch = 0; ch < nChambers; ch++) {
- ppl->SetZmax(ch, Zc[ch], Zmax[ch]);
- }
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,tbIndex);
+ ppl->SetYmax(ymax,ymaxsensitive);
+ ppl->SetZ(zc, zmax,zmaxsensitive);
+ ppl->SetHoles(holes);
InsertLayer(ppl);
// Drift region
- dx = fPar->GetTimeBinSize();
+
+ dx = fgkDriftCorrection*fPar->GetDriftVelocity()
+ / fPar->GetSamplingFrequency();
steps = (Int_t) (dxDrift/dx);
for(tb = 0; tb < steps; tb++) {
- x = x0 - tb * dx - dx/2;
- tb_index = CookTimeBinIndex(plane, tb);
+ x = x0 - tb * dx - dx/2 + fgkOffsetX; //temporary fix - fix it the parameters
+ tbIndex = CookTimeBinIndex(plane, tb);
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,tb_index);
- ppl->SetYmax(Ymax);
- for(Int_t ch = 0; ch < nChambers; ch++) {
- ppl->SetZmax(ch, Zc[ch], Zmax[ch]);
- }
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,tbIndex);
+ ppl->SetYmax(ymax,ymaxsensitive);
+ ppl->SetZ(zc, zmax, zmaxsensitive);
+ ppl->SetHoles(holes);
InsertLayer(ppl);
}
- tb_index = CookTimeBinIndex(plane, steps);
+ tbIndex = CookTimeBinIndex(plane, steps);
x = (x - dx/2 + xbottom)/2;
dx = 2*(x-xbottom);
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,tb_index);
- ppl->SetYmax(Ymax);
- for(Int_t ch = 0; ch < nChambers; ch++) {
- ppl->SetZmax(ch, Zc[ch], Zmax[ch]);
- }
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,tbIndex);
+ ppl->SetYmax(ymax,ymaxsensitive);
+ ppl->SetZ(zc, zmax, zmaxsensitive);
+ ppl->SetHoles(holes);
InsertLayer(ppl);
// Pad Plane
- xin = xtop; dx = 0.025; xout = xin + dx; rho = 1.7; rad_length = 33.0;
- ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,rad_length,-1);
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = (xin+dx/2)*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = (xin+dx/2)*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ xin = xtop; dx = 0.025; xout = xin + dx; rho = 1.7; radLength = 33.0;
+ ppl = new AliTRDpropagationLayer(xin+dx/2,dx,rho,radLength,-1);
+ ppl->SetYmax(ymax,ymaxsensitive);
+ ppl->SetZ(zc, zmax,zmax);
+ ppl->SetHoles(holes);
InsertLayer(ppl);
// Rohacell
xin = xout; xout = xtrd + (plane + 1) * dxPlane - dxSpace;
- steps = 5; dx = (xout - xin)/steps; rho = 0.074; rad_length = 40.6;
+ steps = 5; dx = (xout - xin)/steps; rho = 0.074; radLength = 40.6;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
+ ppl->SetYmax(ymax,ymaxsensitive);
+ ppl->SetZ(zc, zmax,zmax);
+ ppl->SetHoles(holes);
InsertLayer(ppl);
}
// Space between the chambers, air
xin = xout; xout = xtrd + (plane + 1) * dxPlane;
- steps = 5; dx = (xout - xin)/steps; rho = 1.29e-3; rad_length = 36.66;
+ steps = 5; dx = (xout - xin)/steps; rho = 1.29e-3; radLength = 36.66;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
- if((fGeom->GetPHOShole()) && (fGeomSector >= 2) && (fGeomSector <= 6)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
- if((fGeom->GetRICHhole()) && (fGeomSector >= 12) && (fGeomSector <= 14)) {
- holeYmax = x*TMath::Tan(0.5*alpha);
- ppl->SetHole(holeYmax, holeZmax);
- }
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
}
// Space between the TRD and RICH
Double_t xRICH = 500.;
xin = xout; xout = xRICH;
- steps = 200; dx = (xout - xin)/steps; rho = 1.29e-3; rad_length = 36.66;
+ steps = 200; dx = (xout - xin)/steps; rho = 1.29e-3; radLength = 36.66;
for(Int_t i=0; i<steps; i++) {
x = xin + i*dx + dx/2;
- ppl = new AliTRDpropagationLayer(x,dx,rho,rad_length,-1);
+ ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,-1);
InsertLayer(ppl);
}
MapTimeBinLayers();
- delete [] Zc;
- delete [] Zmax;
+ delete [] zc;
+ delete [] zmax;
+ delete [] zmaxsensitive;
}
//______________________________________________________
-Int_t AliTRDtracker::AliTRDtrackingSector::CookTimeBinIndex(Int_t plane, Int_t local_tb) const
+Int_t AliTRDtracker::AliTRDtrackingSector::CookTimeBinIndex(Int_t plane, Int_t localTB) const
{
//
// depending on the digitization parameters calculates "global"
- // time bin index for timebin <local_tb> in plane <plane>
+ // time bin index for timebin <localTB> in plane <plane>
//
Double_t dxAmp = (Double_t) fGeom->CamHght(); // Amplification region
Double_t dxDrift = (Double_t) fGeom->CdrHght(); // Drift region
- Double_t dx = (Double_t) fPar->GetTimeBinSize();
+
+ Double_t dx = fgkDriftCorrection*(Double_t) fPar->GetDriftVelocity()
+ / fPar->GetSamplingFrequency();
Int_t tbAmp = fPar->GetTimeBefore();
Int_t maxAmp = (Int_t) ((dxAmp+0.000001)/dx);
Int_t tbDrift = fPar->GetTimeMax();
Int_t maxDrift = (Int_t) ((dxDrift+0.000001)/dx);
- Int_t tb_per_plane = TMath::Min(tbAmp,maxAmp) + TMath::Min(tbDrift,maxDrift);
+ Int_t tbPerPlane = TMath::Min(tbAmp,maxAmp) + TMath::Min(tbDrift,maxDrift);
- Int_t gtb = (plane+1) * tb_per_plane - local_tb - 1 - TMath::Min(tbAmp,maxAmp);
+ Int_t gtb = (plane+1) * tbPerPlane - localTB - 1 - TMath::Min(tbAmp,maxAmp);
- if((local_tb < 0) &&
- (TMath::Abs(local_tb) > TMath::Min(tbAmp,maxAmp))) return -1;
- if(local_tb >= TMath::Min(tbDrift,maxDrift)) return -1;
+ if((localTB < 0) &&
+ (TMath::Abs(localTB) > TMath::Min(tbAmp,maxAmp))) return -1;
+ if(localTB >= TMath::Min(tbDrift,maxDrift)) return -1;
return gtb;
// printf("gtb %d -> pl %d -> x %f \n", index, i, fLayers[i]->GetX());
if(index < 0) continue;
- if(index >= (Int_t) kMAX_TIME_BIN_INDEX) {
+ if(index >= (Int_t) kMaxTimeBinIndex) {
printf("*** AliTRDtracker::MapTimeBinLayers: \n");
printf(" index %d exceeds allowed maximum of %d!\n",
- index, kMAX_TIME_BIN_INDEX-1);
+ index, kMaxTimeBinIndex-1);
continue;
}
fTimeBinIndex[index] = i;
x2 = fLayers[i+1]->GetX();
dx2 = fLayers[i+1]->GetdX();
gap = (x2 - dx2/2) - (x1 + dx1/2);
- if(gap < -0.01) {
- printf("*** warning: layers %d and %d are overlayed:\n",i,i+1);
- printf(" %f + %f + %f > %f\n", x1, dx1/2, dx2/2, x2);
- }
- if(gap > 0.01) {
- printf("*** warning: layers %d and %d have a large gap:\n",i,i+1);
- printf(" (%f - %f) - (%f + %f) = %f\n",
- x2, dx2/2, x1, dx1, gap);
- }
+// if(gap < -0.01) {
+// printf("*** warning: layers %d and %d are overlayed:\n",i,i+1);
+// printf(" %f + %f + %f > %f\n", x1, dx1/2, dx2/2, x2);
+// }
+// if(gap > 0.01) {
+// printf("*** warning: layers %d and %d have a large gap:\n",i,i+1);
+// printf(" (%f - %f) - (%f + %f) = %f\n",
+// x2, dx2/2, x1, dx1, gap);
+// }
}
}
//
Int_t tb, layer;
- for(tb = kMAX_TIME_BIN_INDEX-1; tb >=0; tb--) {
+ for(tb = kMaxTimeBinIndex-1; tb >=0; tb--) {
layer = GetLayerNumber(tb);
if(layer>=0) break;
}
// Insert layer <pl> in fLayers array.
// Layers are sorted according to X coordinate.
- if ( fN == ((Int_t) kMAX_LAYERS_PER_SECTOR)) {
+ if ( fN == ((Int_t) kMaxLayersPerSector)) {
printf("AliTRDtrackingSector::InsertLayer(): Too many layers !\n");
return;
}
return m;
}
+
+
+
+
+//______________________________________________________
+void AliTRDtracker::AliTRDpropagationLayer::SetZ(Double_t* center, Double_t *w, Double_t *wsensitive )
+{
+ //
+ // set centers and the width of sectors
+ for (Int_t icham=0;icham< AliTRDgeometry::kNcham;icham++){
+ fZc[icham] = center[icham];
+ fZmax[icham] = w[icham];
+ fZmaxSensitive[icham] = wsensitive[icham];
+ // printf("chamber\t%d\tzc\t%f\tzmax\t%f\tzsens\t%f\n",icham,fZc[icham],fZmax[icham],fZmaxSensitive[icham]);
+ }
+}
//______________________________________________________
-void AliTRDtracker::AliTRDpropagationLayer::GetPropagationParameters(
- Double_t y, Double_t z, Double_t &dx, Double_t &rho, Double_t &rad_length,
- Bool_t &lookForCluster) const
+void AliTRDtracker::AliTRDpropagationLayer::SetHoles(Bool_t *holes)
+{
+ //
+ // set centers and the width of sectors
+ fHole = kFALSE;
+ for (Int_t icham=0;icham< AliTRDgeometry::kNcham;icham++){
+ fIsHole[icham] = holes[icham];
+ if (holes[icham]) fHole = kTRUE;
+ }
+}
+
+
+
+Bool_t AliTRDtracker::AliTRDpropagationLayer::GetPropagationParameters(
+ Double_t y, Double_t z, Double_t &dx, Double_t &rho, Double_t &radLength,
+ Bool_t &lookForCluster) const
{
//
- // Returns radial step <dx>, density <rho>, rad. length <rad_length>,
+ // Returns radial step <dx>, density <rho>, rad. length <radLength>,
// and sensitivity <lookForCluster> in point <y,z>
//
+ Double_t alpha = AliTRDgeometry::GetAlpha();
+ Double_t ymax = fX*TMath::Tan(0.5*alpha);
+
+
dx = fdX;
rho = fRho;
- rad_length = fX0;
+ radLength = fX0;
lookForCluster = kFALSE;
-
- // check dead regions
- if(fTimeBinIndex >= 0) {
- for(Int_t ch = 0; ch < (Int_t) kZONES; ch++) {
- if(TMath::Abs(z - fZc[ch]) < fZmax[ch])
- lookForCluster = kTRUE;
- }
- if(TMath::Abs(y) > fYmax) lookForCluster = kFALSE;
- if(!lookForCluster) {
- // rho = 1.7; rad_length = 33.0; // G10
+ Bool_t cross =kFALSE;
+ //
+ //
+ if ( (ymax-TMath::Abs(y))<3.){ //cross material
+ rho*=40.;
+ radLength*=40.;
+ cross=kTRUE;
+ }
+ //
+ // check dead regions in sensitive volume
+ //
+ Int_t zone=-1;
+ for(Int_t ch = 0; ch < (Int_t) kZones; ch++) {
+ if (TMath::Abs(z - fZc[ch]) > fZmax[ch]) continue; //not in given zone
+ //
+ if (TMath::Abs(z - fZc[ch]) < fZmaxSensitive[ch]){
+ if (fTimeBinIndex>=0) lookForCluster = !(fIsHole[zone]);
+ if(TMath::Abs(y) > fYmaxSensitive){
+ lookForCluster = kFALSE;
+ }
+ if (fIsHole[zone]) {
+ //if hole
+ rho = 1.29e-3;
+ radLength = 36.66;
+ }
+ }else{
+ cross = kTRUE; rho = 2.7; radLength = 24.01; //aluminium in between
+ }
+ }
+ //
+ if (fTimeBinIndex>=0) return cross;
+ //
+ //
+ // check hole
+ if (fHole==kFALSE) return cross;
+ //
+ for(Int_t ch = 0; ch < (Int_t) kZones; ch++) {
+ if (TMath::Abs(z - fZc[ch]) < fZmax[ch]){
+ if (fIsHole[ch]) {
+ //if hole
+ rho = 1.29e-3;
+ radLength = 36.66;
+ }
}
}
+ return cross;
+}
- // check hole
- if(fHole && (TMath::Abs(y - fHoleYc) < fHoleYmax) &&
- (TMath::Abs(z - fHoleZc) < fHoleZmax)) {
- lookForCluster = kFALSE;
- rho = fHoleRho;
- rad_length = fHoleX0;
- }
-
- return;
+Int_t AliTRDtracker::AliTRDpropagationLayer::GetZone( Double_t z) const
+{
+ //
+ //
+ if (fTimeBinIndex < 0) return -20; //unknown
+ Int_t zone=-10; // dead zone
+ for(Int_t ch = 0; ch < (Int_t) kZones; ch++) {
+ if(TMath::Abs(z - fZc[ch]) < fZmax[ch])
+ zone = ch;
+ }
+ return zone;
}
+
//______________________________________________________
void AliTRDtracker::AliTRDpropagationLayer::InsertCluster(AliTRDcluster* c,
- UInt_t index) {
+ UInt_t index) {
// Insert cluster in cluster array.
// Clusters are sorted according to Y coordinate.
return;
}
- if (fN== (Int_t) kMAX_CLUSTER_PER_TIME_BIN) {
+ if (fN== (Int_t) kMaxClusterPerTimeBin) {
printf("AliTRDpropagationLayer::InsertCluster(): Too many clusters !\n");
return;
}
return m;
}
+Int_t AliTRDtracker::AliTRDpropagationLayer::FindNearestCluster(Double_t y, Double_t z, Double_t maxroad) const
+{
+ //
+ // Returns index of the cluster nearest to the given y,z
+ //
+ Int_t index = -1;
+ Int_t maxn = fN;
+ Double_t mindist = maxroad;
+ Float_t padlength =-1;
+ //
+ for (Int_t i=Find(y-maxroad); i<maxn; i++) {
+ AliTRDcluster* c=(AliTRDcluster*)(fClusters[i]);
+ if (padlength<0){
+ padlength = TMath::Sqrt(c->GetSigmaZ2()*12);
+ }
+ //
+ if (c->GetY() > y+maxroad) break;
+ if((c->GetZ()-z)*(c->GetZ()-z) > padlength*0.75) continue;
+ if (TMath::Abs(c->GetY()-y)<mindist){
+ mindist = TMath::Abs(c->GetY()-y);
+ index = GetIndex(i);
+ }
+ }
+ return index;
+}
+
+
//---------------------------------------------------------
Double_t AliTRDtracker::GetTiltFactor(const AliTRDcluster* c) {
//
// Returns correction factor for tilted pads geometry
//
-
- Double_t h01 = sin(TMath::Pi() / 180.0 * fPar->GetTiltingAngle());
Int_t det = c->GetDetector();
Int_t plane = fGeom->GetPlane(det);
+ AliTRDpadPlane *padPlane = fPar->GetPadPlane(plane,0);
+ Double_t h01 = TMath::Tan(-TMath::Pi() / 180.0 * padPlane->GetTiltingAngle());
- if((plane == 1) || (plane == 3) || (plane == 5)) h01=-h01;
-
+ if(fNoTilt) h01 = 0;
return h01;
}
+void AliTRDtracker::CookdEdxTimBin(AliTRDtrack& TRDtrack)
+{
+ // *** ADDED TO GET MORE INFORMATION FOR TRD PID ---- PS
+ // This is setting fdEdxPlane and fTimBinPlane
+ // Sums up the charge in each plane for track TRDtrack and also get the
+ // Time bin for Max. Cluster
+ // Prashant Shukla (shukla@physi.uni-heidelberg.de)
+
+ // const Int_t kNPlane = AliTRDgeometry::Nplan();
+ // const Int_t kNPlane = 6;
+ Double_t clscharge[kNPlane], maxclscharge[kNPlane];
+ Int_t nCluster[kNPlane], timebin[kNPlane];
+
+ //Initialization of cluster charge per plane.
+ for (Int_t iPlane = 0; iPlane < kNPlane; iPlane++) {
+ clscharge[iPlane] = 0.0;
+ nCluster[iPlane] = 0;
+ timebin[iPlane] = -1;
+ maxclscharge[iPlane] = 0.0;
+ }
+
+ // Loop through all clusters associated to track TRDtrack
+ Int_t nClus = TRDtrack.GetNumberOfClusters(); // from Kalmantrack
+ for (Int_t iClus = 0; iClus < nClus; iClus++) {
+ Double_t charge = TRDtrack.GetClusterdQdl(iClus);
+ Int_t index = TRDtrack.GetClusterIndex(iClus);
+ AliTRDcluster *TRDcluster = (AliTRDcluster *) GetCluster(index);
+ if (!TRDcluster) continue;
+ Int_t tb = TRDcluster->GetLocalTimeBin();
+ if (!tb) continue;
+ Int_t detector = TRDcluster->GetDetector();
+ Int_t iPlane = fGeom->GetPlane(detector);
+ clscharge[iPlane] = clscharge[iPlane]+charge;
+ if(charge > maxclscharge[iPlane]) {
+ maxclscharge[iPlane] = charge;
+ timebin[iPlane] = tb;
+ }
+ nCluster[iPlane]++;
+ } // end of loop over cluster
+
+ // Setting the fdEdxPlane and fTimBinPlane variabales
+ Double_t Total_ch = 0;
+ for (Int_t iPlane = 0; iPlane < kNPlane; iPlane++) {
+ // Quality control of TRD track.
+ if (nCluster[iPlane]<= 5) {
+ clscharge[iPlane]=0.0;
+ timebin[iPlane]=-1;
+ }
+ if (nCluster[iPlane]) clscharge[iPlane] /= nCluster[iPlane];
+ TRDtrack.SetPIDsignals(clscharge[iPlane], iPlane);
+ TRDtrack.SetPIDTimBin(timebin[iPlane], iPlane);
+ Total_ch= Total_ch+clscharge[iPlane];
+ }
+ // Int_t i;
+ // Int_t nc=TRDtrack.GetNumberOfClusters();
+ // Float_t dedx=0;
+ // for (i=0; i<nc; i++) dedx += TRDtrack.GetClusterdQdl(i);
+ // dedx /= nc;
+ // for (Int_t iPlane = 0; iPlane < kNPlane; iPlane++) {
+ // TRDtrack.SetPIDsignals(dedx, iPlane);
+ // TRDtrack.SetPIDTimBin(timbin[iPlane], iPlane);
+ // }
+
+} // end of function
+
+
+Int_t AliTRDtracker::FindClusters(Int_t sector, Int_t t0, Int_t t1, AliTRDtrack * track, Int_t *clusters,AliTRDtracklet&tracklet)
+{
+ //
+ //
+ // try to find nearest clusters to the track in timebins from t0 to t1
+ //
+ //
+ //
+ // correction coeficients - depends on TRD parameters - to be changed according it
+ //
+ Double_t x[100],yt[100],zt[100];
+ Double_t xmean=0; //reference x
+ Double_t dz[10][100],dy[10][100];
+ Float_t zmean[100], nmean[100];
+ Int_t clfound=0;
+ Int_t indexes[10][100]; // indexes of the clusters in the road
+ AliTRDcluster *cl[10][100]; // pointers to the clusters in the road
+ Int_t best[10][100]; // index of best matching cluster
+ //
+ //
+ TClonesArray array0("AliTRDcluster",1);
+ TClonesArray array1("AliTRDcluster",1);
+ for (Int_t it=0;it<t1-t0; it++){
+ x[it]=0;
+ yt[it]=0;
+ zt[it]=0;
+ clusters[it+t0]=-2;
+ zmean[it]=0;
+ nmean[it]=0;
+ //
+ for (Int_t ih=0;ih<10;ih++){
+ indexes[ih][it]=-2; //reset indexes1
+ cl[ih][it]=0;
+ dz[ih][it]=-100;
+ dy[ih][it]=-100;
+ best[ih][it]=0;
+ }
+ }
+ //
+ Double_t x0 = track->GetX();
+ Double_t sigmaz = TMath::Sqrt(track->GetSigmaZ2());
+ Int_t nall=0;
+ Int_t nfound=0;
+ Double_t h01 =0;
+ Int_t plane =-1;
+ Float_t padlength=0;
+ AliTRDtrack track2(*track);
+ Float_t snpy = track->GetSnp();
+ Float_t tany = TMath::Sqrt(snpy*snpy/(1.-snpy*snpy));
+ if (snpy<0) tany*=-1;
+ //
+ Double_t sy2=ExpectedSigmaY2(x0,track->GetTgl(),track->GetPt());
+ Double_t sz2=ExpectedSigmaZ2(x0,track->GetTgl());
+ Double_t road = 15.*sqrt(track->GetSigmaY2() + sy2);
+ if (road>6.) road=6.;
+ //
+ for (Int_t it=0;it<t1-t0;it++){
+ Double_t maxChi2[2]={fgkMaxChi2,fgkMaxChi2};
+ AliTRDpropagationLayer& timeBin=*(fTrSec[sector]->GetLayer(it+t0));
+ if (timeBin==0) continue; // no indexes1
+ Int_t maxn = timeBin;
+ x[it] = timeBin.GetX();
+ track2.PropagateTo(x[it]);
+ yt[it] = track2.GetY();
+ zt[it] = track2.GetZ();
+
+ Double_t y=yt[it],z=zt[it];
+ Double_t chi2 =1000000;
+ nall++;
+ //
+ // find 2 nearest cluster at given time bin
+ //
+ //
+ for (Int_t i=timeBin.Find(y-road); i<maxn; i++) {
+ AliTRDcluster* c=(AliTRDcluster*)(timeBin[i]);
+ h01 = GetTiltFactor(c);
+ if (plane<0){
+ Int_t det = c->GetDetector();
+ plane = fGeom->GetPlane(det);
+ padlength = TMath::Sqrt(c->GetSigmaZ2()*12.);
+ }
+ // if (c->GetLocalTimeBin()==0) continue;
+ if (c->GetY() > y+road) break;
+ if((c->GetZ()-z)*(c->GetZ()-z) > 12. * sz2) continue;
+
+ Double_t dist = TMath::Abs(c->GetZ()-z);
+ if (dist> (0.5*padlength+6.*sigmaz)) continue; // 6 sigma boundary cut
+ Double_t cost = 0;
+ //
+ if (dist> (0.5*padlength-sigmaz)){ // sigma boundary cost function
+ cost = (dist-0.5*padlength)/(2.*sigmaz);
+ if (cost>-1) cost= (cost+1.)*(cost+1.);
+ else cost=0;
+ }
+ // Int_t label = TMath::Abs(track->GetLabel());
+ // if (c->GetLabel(0)!=label && c->GetLabel(1)!=label&&c->GetLabel(2)!=label) continue;
+ chi2=track2.GetPredictedChi2(c,h01)+cost;
+ //
+ clfound++;
+ if (chi2 > maxChi2[1]) continue;
+
+ for (Int_t ih=2;ih<9; ih++){ //store the clusters in the road
+ if (cl[ih][it]==0){
+ cl[ih][it] = c;
+ indexes[ih][it] =timeBin.GetIndex(i); // index - 9 - reserved for outliers
+ break;
+ }
+ }
+ //
+ if (chi2 <maxChi2[0]){
+ maxChi2[1] = maxChi2[0];
+ maxChi2[0] = chi2;
+ indexes[1][it] = indexes[0][it];
+ cl[1][it] = cl[0][it];
+ indexes[0][it] = timeBin.GetIndex(i);
+ cl[0][it] = c;
+ continue;
+ }
+ maxChi2[1]=chi2;
+ cl[1][it] = c;
+ indexes[1][it] =timeBin.GetIndex(i);
+ }
+ if (cl[0][it]){
+ nfound++;
+ xmean += x[it];
+ }
+ }
+ //
+ if (nfound<4) return 0;
+ xmean /=Float_t(nfound); // middle x
+ track2.PropagateTo(xmean); // propagate track to the center
+ //
+ // choose one of the variants
+ //
+ Int_t changes[10];
+ Float_t sumz = 0;
+ Float_t sum = 0;
+ Double_t sumdy = 0;
+ Double_t sumdy2 = 0;
+ Double_t sumx = 0;
+ Double_t sumxy = 0;
+ Double_t sumx2 = 0;
+ Double_t mpads = 0;
+ //
+ Int_t ngood[10];
+ Int_t nbad[10];
+ //
+ Double_t meanz[10];
+ Double_t moffset[10]; // mean offset
+ Double_t mean[10]; // mean value
+ Double_t angle[10]; // angle
+ //
+ Double_t smoffset[10]; // sigma of mean offset
+ Double_t smean[10]; // sigma of mean value
+ Double_t sangle[10]; // sigma of angle
+ Double_t smeanangle[10]; // correlation
+ //
+ Double_t sigmas[10];
+ Double_t tchi2s[10]; // chi2s for tracklet
+ //
+ // calculate zmean
+ //
+ for (Int_t it=0;it<t1-t0;it++){
+ if (!cl[0][it]) continue;
+ for (Int_t dt=-3;dt<=3;dt++){
+ if (it+dt<0) continue;
+ if (it+dt>t1) continue;
+ if (!cl[0][it+dt]) continue;
+ zmean[it]+=cl[0][it+dt]->GetZ();
+ nmean[it]+=1.;
+ }
+ zmean[it]/=nmean[it];
+ }
+ //
+ for (Int_t it=0; it<t1-t0;it++){
+ best[0][it]=0;
+ for (Int_t ih=0;ih<10;ih++){
+ dz[ih][it]=-100;
+ dy[ih][it]=-100;
+ if (!cl[ih][it]) continue;
+ Float_t poscor = fgkCoef*(cl[ih][it]->GetLocalTimeBin() - fgkMean)+fgkOffset;
+ dz[ih][it] = cl[ih][it]->GetZ()- zt[it]; // calculate distance from track in z
+ dy[ih][it] = cl[ih][it]->GetY()+ dz[ih][it]*h01 - poscor -yt[it]; // in y
+ }
+ // minimize changes
+ if (!cl[0][it]) continue;
+ if (TMath::Abs(cl[0][it]->GetZ()-zmean[it])> padlength*0.8 &&cl[1][it])
+ if (TMath::Abs(cl[1][it]->GetZ()-zmean[it])< padlength*0.5){
+ best[0][it]=1;
+ }
+ }
+ //
+ // iterative choosing of "best path"
+ //
+ //
+ Int_t label = TMath::Abs(track->GetLabel());
+ Int_t bestiter=0;
+ //
+ for (Int_t iter=0;iter<9;iter++){
+ //
+ changes[iter]= 0;
+ sumz = 0; sum=0; sumdy=0;sumdy2=0;sumx=0;sumx2=0;sumxy=0;mpads=0; ngood[iter]=0; nbad[iter]=0;
+ // linear fit
+ for (Int_t it=0;it<t1-t0;it++){
+ if (!cl[best[iter][it]][it]) continue;
+ //calculates pad-row changes
+ Double_t zbefore= cl[best[iter][it]][it]->GetZ();
+ Double_t zafter = cl[best[iter][it]][it]->GetZ();
+ for (Int_t itd = it-1; itd>=0;itd--) {
+ if (cl[best[iter][itd]][itd]) {
+ zbefore= cl[best[iter][itd]][itd]->GetZ();
+ break;
+ }
+ }
+ for (Int_t itd = it+1; itd<t1-t0;itd++) {
+ if (cl[best[iter][itd]][itd]) {
+ zafter= cl[best[iter][itd]][itd]->GetZ();
+ break;
+ }
+ }
+ if (TMath::Abs(cl[best[iter][it]][it]->GetZ()-zbefore)>0.1&&TMath::Abs(cl[best[iter][it]][it]->GetZ()-zafter)>0.1) changes[iter]++;
+ //
+ Double_t dx = x[it]-xmean; // distance to reference x
+ sumz += cl[best[iter][it]][it]->GetZ();
+ sum++;
+ sumdy += dy[best[iter][it]][it];
+ sumdy2+= dy[best[iter][it]][it]*dy[best[iter][it]][it];
+ sumx += dx;
+ sumx2 += dx*dx;
+ sumxy += dx*dy[best[iter][it]][it];
+ mpads += cl[best[iter][it]][it]->GetNPads();
+ if (cl[best[iter][it]][it]->GetLabel(0)==label || cl[best[iter][it]][it]->GetLabel(1)==label||cl[best[iter][it]][it]->GetLabel(2)==label){
+ ngood[iter]++;
+ }
+ else{
+ nbad[iter]++;
+ }
+ }
+ //
+ // calculates line parameters
+ //
+ Double_t det = sum*sumx2-sumx*sumx;
+ angle[iter] = (sum*sumxy-sumx*sumdy)/det;
+ mean[iter] = (sumx2*sumdy-sumx*sumxy)/det;
+ meanz[iter] = sumz/sum;
+ moffset[iter] = sumdy/sum;
+ mpads /= sum; // mean number of pads
+ //
+ //
+ Double_t sigma2 = 0; // normalized residuals - for line fit
+ Double_t sigma1 = 0; // normalized residuals - constant fit
+ //
+ for (Int_t it=0;it<t1-t0;it++){
+ if (!cl[best[iter][it]][it]) continue;
+ Double_t dx = x[it]-xmean;
+ Double_t ytr = mean[iter]+angle[iter]*dx;
+ sigma2 += (dy[best[iter][it]][it]-ytr)*(dy[best[iter][it]][it]-ytr);
+ sigma1 += (dy[best[iter][it]][it]-moffset[iter])*(dy[best[iter][it]][it]-moffset[iter]);
+ sum++;
+ }
+ sigma2 /=(sum-2); // normalized residuals
+ sigma1 /=(sum-1); // normalized residuals
+ //
+ smean[iter] = sigma2*(sumx2/det); // estimated error2 of mean
+ sangle[iter] = sigma2*(sum/det); // estimated error2 of angle
+ smeanangle[iter] = sigma2*(-sumx/det); // correlation
+ //
+ //
+ sigmas[iter] = TMath::Sqrt(sigma1); //
+ smoffset[iter]= (sigma1/sum)+0.01*0.01; // sigma of mean offset + unisochronity sigma
+ //
+ // iterative choosing of "better path"
+ //
+ for (Int_t it=0;it<t1-t0;it++){
+ if (!cl[best[iter][it]][it]) continue;
+ //
+ Double_t sigmatr2 = smoffset[iter]+0.5*tany*tany; //add unisochronity + angular effect contribution
+ Double_t sweight = 1./sigmatr2+1./track->fCyy;
+ Double_t weighty = (moffset[iter]/sigmatr2)/sweight; // weighted mean
+ Double_t sigmacl = TMath::Sqrt(sigma1*sigma1+track->fCyy); //
+ Double_t mindist=100000;
+ Int_t ihbest=0;
+ for (Int_t ih=0;ih<10;ih++){
+ if (!cl[ih][it]) break;
+ Double_t dist2 = (dy[ih][it]-weighty)/sigmacl;
+ dist2*=dist2; //chi2 distance
+ if (dist2<mindist){
+ mindist = dist2;
+ ihbest =ih;
+ }
+ }
+ best[iter+1][it]=ihbest;
+ }
+ //
+ // update best hypothesy if better chi2 according tracklet position and angle
+ //
+ Double_t sy2 = smean[iter] + track->fCyy;
+ Double_t sa2 = sangle[iter] + track->fCee;
+ Double_t say = track->fCey;
+ // Double_t chi20 = mean[bestiter]*mean[bestiter]/sy2+angle[bestiter]*angle[bestiter]/sa2;
+ // Double_t chi21 = mean[iter]*mean[iter]/sy2+angle[iter]*angle[iter]/sa2;
+
+ Double_t detchi = sy2*sa2-say*say;
+ Double_t invers[3] = {sa2/detchi, sy2/detchi, -say/detchi}; //inverse value of covariance matrix
+
+ Double_t chi20 = mean[bestiter]*mean[bestiter]*invers[0]+angle[bestiter]*angle[bestiter]*invers[1]+
+ 2.*mean[bestiter]*angle[bestiter]*invers[2];
+ Double_t chi21 = mean[iter]*mean[iter]*invers[0]+angle[iter]*angle[iter]*invers[1]+
+ 2*mean[iter]*angle[iter]*invers[2];
+ tchi2s[iter] =chi21;
+ //
+ if (changes[iter]<=changes[bestiter] && chi21<chi20) {
+ bestiter =iter;
+ }
+ }
+ //
+ //set clusters
+ //
+ Double_t sigma2 = sigmas[0]; // choose as sigma from 0 iteration
+ //if (tchi2s[bestiter]>25.) sigma2*=tchi2s[bestiter]/25.;
+ //if (tchi2s[bestiter]>25.) sigma2=1000.; // dont'accept
+
+ Double_t expectederr = sigma2*sigma2+0.01*0.01;
+ if (mpads>3.5) expectederr += (mpads-3.5)*0.04;
+ if (changes[bestiter]>1) expectederr+= changes[bestiter]*0.01;
+ expectederr+=(0.03*(tany-fgkExB)*(tany-fgkExB))*15;
+ // if (tchi2s[bestiter]>18.) expectederr*= tchi2s[bestiter]/18.;
+ //expectederr+=10000;
+ for (Int_t it=0;it<t1-t0;it++){
+ if (!cl[best[bestiter][it]][it]) continue;
+ Float_t poscor = fgkCoef*(cl[best[bestiter][it]][it]->GetLocalTimeBin() - fgkMean)+fgkOffset;
+ cl[best[bestiter][it]][it]->SetSigmaY2(expectederr); // set cluster error
+ if (!cl[best[bestiter][it]][it]->IsUsed()){
+ cl[best[bestiter][it]][it]->SetY( cl[best[bestiter][it]][it]->GetY()-poscor); // ExB corrction correction
+ cl[best[bestiter][it]][it]->Use();
+ }
+ clusters[it+t0] = indexes[best[bestiter][it]][it];
+ }
+ //
+ // set tracklet parameters
+ //
+ Double_t trackleterr2 = smoffset[bestiter]+0.01*0.01;
+ if (mpads>3.5) trackleterr2 += (mpads-3.5)*0.04;
+ trackleterr2+= changes[bestiter]*0.01;
+ trackleterr2*= TMath::Max(14.-nfound,1.);
+ trackleterr2+= 0.2*(tany-fgkExB)*(tany-fgkExB);
+ //
+ tracklet.Set(xmean, track2.GetY()+moffset[bestiter], meanz[bestiter], track2.GetAlpha(), trackleterr2); //set tracklet parameters
+ tracklet.SetTilt(h01);
+ tracklet.SetP0(mean[bestiter]);
+ tracklet.SetP1(angle[bestiter]);
+ tracklet.SetN(nfound);
+ tracklet.SetNCross(changes[bestiter]);
+ tracklet.SetPlane(plane);
+ tracklet.SetSigma2(expectederr);
+ tracklet.SetChi2(tchi2s[bestiter]);
+ track->fTracklets[plane] = tracklet;
+ track->fNWrong+=nbad[0];
+ //
+ // Debuging part
+ //
+ TTreeSRedirector& cstream = *fDebugStreamer;
+ AliTRDcluster dummy;
+ Double_t dy0[100];
+ Double_t dyb[100];
+ for (Int_t it=0;it<t1-t0;it++){
+ dy0[it] = dy[0][it];
+ dyb[it] = dy[best[bestiter][it]][it];
+ if(cl[0][it]) {
+ new(array0[it]) AliTRDcluster(*cl[0][it]);
+ }
+ else{
+ new(array0[it]) AliTRDcluster(dummy);
+ }
+ if(cl[best[bestiter][it]][it]) {
+ new(array1[it]) AliTRDcluster(*cl[best[bestiter][it]][it]);
+ }
+ else{
+ new(array1[it]) AliTRDcluster(dummy);
+ }
+ }
+ TGraph graph0(t1-t0,x,dy0);
+ TGraph graph1(t1-t0,x,dyb);
+ TGraph graphy(t1-t0,x,yt);
+ TGraph graphz(t1-t0,x,zt);
+ //
+ //
+ cstream<<"tracklet"<<
+ "track.="<<track<< // track parameters
+ "tany="<<tany<< // tangent of the local track angle
+ "xmean="<<xmean<< // xmean - reference x of tracklet
+ "tilt="<<h01<< // tilt angle
+ "nall="<<nall<< // number of foundable clusters
+ "nfound="<<nfound<< // number of found clusters
+ "clfound="<<clfound<< // total number of found clusters in road
+ "mpads="<<mpads<< // mean number of pads per cluster
+ "plane="<<plane<< // plane number
+ "road="<<road<< // the width of the used road
+ "graph0.="<<&graph0<< // x - y = dy for closest cluster
+ "graph1.="<<&graph1<< // x - y = dy for second closest cluster
+ "graphy.="<<&graphy<< // y position of the track
+ "graphz.="<<&graphz<< // z position of the track
+ "fCl.="<<&array0<< // closest cluster
+ "fCl2.="<<&array1<< // second closest cluster
+ //
+ "bestiter="<<bestiter<< // best iteration number
+ "tracklet.="<<&tracklet<< // corrspond to the best iteration
+ "tchi20="<<tchi2s[0]<< // chi2 of cluster in the 0 iteration
+ "tchi2b="<<tchi2s[bestiter]<< // chi2 of cluster in the best iteration
+ "sigmas0="<<sigmas[0]<< // residuals sigma
+ "sigmasb="<<sigmas[bestiter]<< // residulas sigma
+ //
+ "ngood0="<<ngood[0]<< // number of good clusters in 0 iteration
+ "nbad0="<<nbad[0]<< // number of bad clusters in 0 iteration
+ "ngoodb="<<ngood[bestiter]<< // in best iteration
+ "nbadb="<<nbad[bestiter]<< // in best iteration
+ //
+ "changes0="<<changes[0]<< // changes of pardrows in iteration number 0
+ "changesb="<<changes[bestiter]<< // changes of pardrows in best iteration
+ //
+ "moffset0="<<moffset[0]<< // offset fixing angle in iter=0
+ "smoffset0="<<smoffset[0]<< // sigma of offset fixing angle in iter=0
+ "moffsetb="<<moffset[bestiter]<< // offset fixing angle in iter=best
+ "smoffsetb="<<smoffset[bestiter]<< // sigma of offset fixing angle in iter=best
+ //
+ "mean0="<<mean[0]<< // mean dy in iter=0;
+ "smean0="<<smean[0]<< // sigma of mean dy in iter=0
+ "meanb="<<mean[bestiter]<< // mean dy in iter=best
+ "smeanb="<<smean[bestiter]<< // sigma of mean dy in iter=best
+ //
+ "angle0="<<angle[0]<< // angle deviation in the iteration number 0
+ "sangle0="<<sangle[0]<< // sigma of angular deviation in iteration number 0
+ "angleb="<<angle[bestiter]<< // angle deviation in the best iteration
+ "sangleb="<<sangle[bestiter]<< // sigma of angle deviation in the best iteration
+ //
+ "expectederr="<<expectederr<< // expected error of cluster position
+ "\n";
+ //
+ //
+ return nfound;
+}