1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
18 ///////////////////////////////////////////////////////////////////////////////
20 // The standard TRD tracker //
21 // Based on Kalman filltering approach //
23 ///////////////////////////////////////////////////////////////////////////////
25 #include <Riostream.h>
29 #include <TObjArray.h>
31 #include "AliTRDgeometry.h"
32 #include "AliTRDpadPlane.h"
33 #include "AliTRDgeometry.h"
34 #include "AliTRDcluster.h"
35 #include "AliTRDtrack.h"
36 #include "AliTRDseed.h"
39 #include "AliTRDcalibDB.h"
40 #include "AliTRDCommonParam.h"
42 #include "TTreeStream.h"
44 #include "AliTRDtracker.h"
45 #include "TLinearFitter.h"
46 #include "AliRieman.h"
47 #include "AliTrackPointArray.h"
48 #include "AliAlignObj.h"
49 #include "AliTRDReconstructor.h"
51 ClassImp(AliTRDtracker)
53 const Float_t AliTRDtracker::fgkMinClustersInTrack = 0.5;
54 const Float_t AliTRDtracker::fgkLabelFraction = 0.8;
55 const Double_t AliTRDtracker::fgkMaxChi2 = 12.;
56 const Double_t AliTRDtracker::fgkMaxSnp = 0.95; // correspond to tan = 3
57 const Double_t AliTRDtracker::fgkMaxStep = 2.; // maximal step size in propagation
59 //_____________________________________________________________________________
60 AliTRDtracker::AliTRDtracker():AliTracker(),
73 // Default constructor
76 for(Int_t i=0;i<kTrackingSectors;i++) fTrSec[i]=0;
77 for(Int_t j=0;j<5;j++)
78 for(Int_t k=0;k<18;k++) fHoles[j][k]=kFALSE;
83 //_____________________________________________________________________________
84 AliTRDtracker::AliTRDtracker(const TFile *geomfile):AliTracker()
90 fAddTRDseeds = kFALSE;
94 TDirectory *savedir=gDirectory;
95 TFile *in=(TFile*)geomfile;
97 printf("AliTRDtracker::AliTRDtracker(): geometry file is not open!\n");
98 printf(" FULL TRD geometry and DEFAULT TRD parameter will be used\n");
102 fGeom = (AliTRDgeometry*) in->Get("TRDgeometry");
106 // printf("Found geometry version %d on file \n", fGeom->IsVersion());
109 printf("AliTRDtracker::AliTRDtracker(): can't find TRD geometry!\n");
110 fGeom = new AliTRDgeometry();
112 fGeom->ReadGeoMatrices();
117 fClusters = new TObjArray(2000);
119 fSeeds = new TObjArray(2000);
121 fTracks = new TObjArray(1000);
123 for(Int_t geomS = 0; geomS < kTrackingSectors; geomS++) {
124 Int_t trS = CookSectorIndex(geomS);
125 fTrSec[trS] = new AliTRDtrackingSector(fGeom, geomS);
126 for (Int_t icham=0;icham<AliTRDgeometry::kNcham; icham++){
127 fHoles[icham][trS]=fGeom->IsHole(0,icham,geomS);
130 AliTRDpadPlane *padPlane = AliTRDCommonParam::Instance()->GetPadPlane(0,0);
131 Float_t tiltAngle = TMath::Abs(padPlane->GetTiltingAngle());
132 if(tiltAngle < 0.1) {
136 fTimeBinsPerPlane = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
138 fDebugStreamer = new TTreeSRedirector("TRDdebug.root");
144 //_____________________________________________________________________________
145 AliTRDtracker::~AliTRDtracker()
148 // Destructor of AliTRDtracker
165 for(Int_t geomS = 0; geomS < kTrackingSectors; geomS++) {
166 delete fTrSec[geomS];
168 if (fDebugStreamer) {
169 //fDebugStreamer->Close();
170 delete fDebugStreamer;
175 //_____________________________________________________________________________
176 Int_t AliTRDtracker::LocalToGlobalID(Int_t lid)
179 // Transform internal TRD ID to global detector ID
182 Int_t isector = fGeom->GetSector(lid);
183 Int_t ichamber= fGeom->GetChamber(lid);
184 Int_t iplan = fGeom->GetPlane(lid);
186 AliAlignObj::ELayerID iLayer = AliAlignObj::kTRD1;
189 iLayer = AliAlignObj::kTRD1;
192 iLayer = AliAlignObj::kTRD2;
195 iLayer = AliAlignObj::kTRD3;
198 iLayer = AliAlignObj::kTRD4;
201 iLayer = AliAlignObj::kTRD5;
204 iLayer = AliAlignObj::kTRD6;
207 Int_t modId = isector*fGeom->Ncham()+ichamber;
208 UShort_t volid = AliAlignObj::LayerToVolUID(iLayer,modId);
214 //_____________________________________________________________________________
215 Int_t AliTRDtracker::GlobalToLocalID(Int_t gid)
218 // Transform global detector ID to local detector ID
222 AliAlignObj::ELayerID layerId = AliAlignObj::VolUIDToLayer(gid, modId);
223 Int_t isector = modId/fGeom->Ncham();
224 Int_t ichamber = modId%fGeom->Ncham();
227 case AliAlignObj::kTRD1:
230 case AliAlignObj::kTRD2:
233 case AliAlignObj::kTRD3:
236 case AliAlignObj::kTRD4:
239 case AliAlignObj::kTRD5:
242 case AliAlignObj::kTRD6:
248 if (iLayer<0) return -1;
249 Int_t lid = fGeom->GetDetector(iLayer,ichamber,isector);
255 //_____________________________________________________________________________
256 Bool_t AliTRDtracker::Transform(AliTRDcluster * cluster)
259 // Transform something ... whatever ...
262 const Double_t kX0shift = 2.52; // magic constants for geo manager transformation
263 const Double_t kX0shift5 = 3.05; //
266 // apply alignment and calibration to transform cluster
269 Int_t detector = cluster->GetDetector();
270 Int_t plane = fGeom->GetPlane(cluster->GetDetector());
271 Int_t chamber = fGeom->GetChamber(cluster->GetDetector());
272 Int_t sector = fGeom->GetSector(cluster->GetDetector());
274 Double_t dxAmp = (Double_t) fGeom->CamHght(); // Amplification region
275 Double_t driftX = TMath::Max(cluster->GetX()-dxAmp*0.5,0.); // drift distance
279 Double_t vdrift = AliTRDcalibDB::Instance()->GetVdrift(cluster->GetDetector(),0,0);
280 Double_t exB = AliTRDcalibDB::Instance()->GetOmegaTau(vdrift);
282 AliTRDCommonParam* commonParam = AliTRDCommonParam::Instance();
283 AliTRDpadPlane * padPlane = commonParam->GetPadPlane(plane,chamber);
284 Double_t zshiftIdeal = 0.5*(padPlane->GetRow0()+padPlane->GetRowEnd());
285 Double_t localPos[3], localPosTracker[3];
286 localPos[0] = -cluster->GetX();
287 localPos[1] = cluster->GetY() - driftX*exB;
288 localPos[2] = cluster->GetZ() -zshiftIdeal;
290 cluster->SetY(cluster->GetY() - driftX*exB);
291 Double_t xplane = (Double_t) AliTRDgeometry::GetTime0(plane);
292 cluster->SetX(xplane- cluster->GetX());
294 TGeoHMatrix * matrix = fGeom->GetCorrectionMatrix(cluster->GetDetector());
296 // no matrix found - if somebody used geometry with holes
297 AliError("Invalid Geometry - Default Geometry used\n");
300 matrix->LocalToMaster(localPos, localPosTracker);
304 if (AliTRDReconstructor::StreamLevel()>1){
305 (*fDebugStreamer)<<"Transform"<<
308 "Detector="<<detector<<
311 "Chamber="<<chamber<<
312 "lx0="<<localPosTracker[0]<<
313 "ly0="<<localPosTracker[1]<<
314 "lz0="<<localPosTracker[2]<<
319 cluster->SetX(localPosTracker[0]+kX0shift5);
321 cluster->SetX(localPosTracker[0]+kX0shift);
323 cluster->SetY(localPosTracker[1]);
324 cluster->SetZ(localPosTracker[2]);
330 //_____________________________________________________________________________
331 // Bool_t AliTRDtracker::Transform(AliTRDcluster * cluster)
335 // const Double_t kDriftCorrection = 1.01; // drift coeficient correction
336 // const Double_t kTime0Cor = 0.32; // time0 correction
338 // const Double_t kX0shift = 2.52;
339 // const Double_t kX0shift5 = 3.05;
342 // // apply alignment and calibration to transform cluster
345 // Int_t detector = cluster->GetDetector();
346 // Int_t plane = fGeom->GetPlane(cluster->GetDetector());
347 // Int_t chamber = fGeom->GetChamber(cluster->GetDetector());
348 // Int_t sector = fGeom->GetSector(cluster->GetDetector());
350 // Double_t dxAmp = (Double_t) fGeom->CamHght(); // Amplification region
351 // Double_t driftX = TMath::Max(cluster->GetX()-dxAmp*0.5,0.); // drift distance
355 // Double_t vdrift = AliTRDcalibDB::Instance()->GetVdrift(cluster->GetDetector(),0,0);
356 // Double_t exB = AliTRDcalibDB::Instance()->GetOmegaTau(vdrift);
359 // AliTRDCommonParam* commonParam = AliTRDCommonParam::Instance();
360 // AliTRDpadPlane * padPlane = commonParam->GetPadPlane(plane,chamber);
361 // Double_t zshiftIdeal = 0.5*(padPlane->GetRow0()+padPlane->GetRowEnd());
362 // Double_t localPos[3], globalPos[3], localPosTracker[3], localPosTracker2[3];
363 // localPos[2] = -cluster->GetX();
364 // localPos[0] = cluster->GetY() - driftX*exB;
365 // localPos[1] = cluster->GetZ() -zshiftIdeal;
366 // TGeoHMatrix * matrix = fGeom->GetGeoMatrix(cluster->GetDetector());
367 // matrix->LocalToMaster(localPos, globalPos);
369 // Double_t sectorAngle = 20.*(sector%18)+10;
370 // TGeoHMatrix rotSector;
371 // rotSector.RotateZ(sectorAngle);
372 // rotSector.LocalToMaster(globalPos, localPosTracker);
375 // TGeoHMatrix matrix2(*matrix);
376 // matrix2.MultiplyLeft(&rotSector);
377 // matrix2.LocalToMaster(localPos,localPosTracker2);
381 // cluster->SetY(cluster->GetY() - driftX*exB);
382 // Double_t xplane = (Double_t) AliTRDgeometry::GetTime0(plane);
383 // cluster->SetX(xplane- kDriftCorrection*(cluster->GetX()-kTime0Cor));
384 // (*fDebugStreamer)<<"Transform"<<
386 // "matrix.="<<matrix<<
387 // "matrix2.="<<&matrix2<<
388 // "Detector="<<detector<<
389 // "Sector="<<sector<<
391 // "Chamber="<<chamber<<
392 // "lx0="<<localPosTracker[0]<<
393 // "ly0="<<localPosTracker[1]<<
394 // "lz0="<<localPosTracker[2]<<
395 // "lx2="<<localPosTracker2[0]<<
396 // "ly2="<<localPosTracker2[1]<<
397 // "lz2="<<localPosTracker2[2]<<
401 // cluster->SetX(localPosTracker[0]+kX0shift5);
403 // cluster->SetX(localPosTracker[0]+kX0shift);
405 // cluster->SetY(localPosTracker[1]);
406 // cluster->SetZ(localPosTracker[2]);
410 //_____________________________________________________________________________
411 Bool_t AliTRDtracker::AdjustSector(AliTRDtrack *track)
414 // Rotates the track when necessary
417 Double_t alpha = AliTRDgeometry::GetAlpha();
418 Double_t y = track->GetY();
419 Double_t ymax = track->GetX()*TMath::Tan(0.5*alpha);
421 //Int_t ns = AliTRDgeometry::kNsect;
422 //Int_t s=Int_t(track->GetAlpha()/alpha)%ns;
426 if (!track->Rotate(alpha)) return kFALSE;
427 } else if (y <-ymax) {
429 if (!track->Rotate(-alpha)) return kFALSE;
436 //_____________________________________________________________________________
437 AliTRDcluster *AliTRDtracker::GetCluster(AliTRDtrack *track, Int_t plane
438 , Int_t timebin, UInt_t &index)
441 // Try to find cluster in the backup list
444 AliTRDcluster * cl =0;
445 Int_t *indexes = track->GetBackupIndexes();
446 for (UInt_t i=0;i<kMaxTimeBinIndex;i++){
447 if (indexes[i]==0) break;
448 AliTRDcluster * cli = (AliTRDcluster*)fClusters->UncheckedAt(indexes[i]);
450 if (cli->GetLocalTimeBin()!=timebin) continue;
451 Int_t iplane = fGeom->GetPlane(cli->GetDetector());
463 //_____________________________________________________________________________
464 Int_t AliTRDtracker::GetLastPlane(AliTRDtrack * track)
467 // Return last updated plane
471 Int_t *indexes = track->GetBackupIndexes();
472 for (UInt_t i=0;i<kMaxTimeBinIndex;i++){
473 AliTRDcluster * cli = (AliTRDcluster*)fClusters->UncheckedAt(indexes[i]);
475 Int_t iplane = fGeom->GetPlane(cli->GetDetector());
476 if (iplane>lastplane) {
485 //_____________________________________________________________________________
486 Int_t AliTRDtracker::Clusters2Tracks(AliESD* event)
489 // Finds tracks within the TRD. The ESD event is expected to contain seeds
490 // at the outer part of the TRD. The seeds
491 // are found within the TRD if fAddTRDseeds is TRUE.
492 // The tracks are propagated to the innermost time bin
493 // of the TRD and the ESD event is updated
496 Int_t timeBins = fTrSec[0]->GetNumberOfTimeBins();
497 Float_t foundMin = fgkMinClustersInTrack * timeBins;
500 // Int_t innerTB = fTrSec[0]->GetInnerTimeBin();
502 Int_t n = event->GetNumberOfTracks();
503 for (Int_t i=0; i<n; i++) {
504 AliESDtrack* seed=event->GetTrack(i);
505 ULong_t status=seed->GetStatus();
506 if ( (status & AliESDtrack::kTRDout ) == 0 ) continue;
507 if ( (status & AliESDtrack::kTRDin) != 0 ) continue;
510 AliTRDtrack* seed2 = new AliTRDtrack(*seed);
511 //seed2->ResetCovariance();
512 AliTRDtrack *pt = new AliTRDtrack(*seed2,seed2->GetAlpha());
514 FollowProlongation(t);
515 if (t.GetNumberOfClusters() >= foundMin) {
517 CookLabel(pt, 1-fgkLabelFraction);
521 // cout<<found<<'\r';
524 if (PropagateToX(t,xTPC,fgkMaxStep)) {
525 seed->UpdateTrackParams(pt, AliESDtrack::kTRDin);
531 cout<<"Number of loaded seeds: "<<nseed<<endl;
532 cout<<"Number of found tracks from loaded seeds: "<<found<<endl;
534 // after tracks from loaded seeds are found and the corresponding
535 // clusters are used, look for additional seeds from TRD
538 cout<<"Total number of found tracks: "<<found<<endl;
544 //_____________________________________________________________________________
545 Int_t AliTRDtracker::PropagateBack(AliESD* event)
548 // Gets seeds from ESD event. The seeds are AliTPCtrack's found and
549 // backpropagated by the TPC tracker. Each seed is first propagated
550 // to the TRD, and then its prolongation is searched in the TRD.
551 // If sufficiently long continuation of the track is found in the TRD
552 // the track is updated, otherwise it's stored as originaly defined
553 // by the TPC tracker.
557 Float_t foundMin = 20;
558 Int_t n = event->GetNumberOfTracks();
561 Float_t *quality =new Float_t[n];
562 Int_t *index =new Int_t[n];
563 for (Int_t i=0; i<n; i++) {
564 AliESDtrack* seed=event->GetTrack(i);
565 Double_t covariance[15];
566 seed->GetExternalCovariance(covariance);
567 quality[i] = covariance[0]+covariance[2];
569 TMath::Sort(n,quality,index,kFALSE);
571 for (Int_t i=0; i<n; i++) {
572 // AliESDtrack* seed=event->GetTrack(i);
573 AliESDtrack* seed=event->GetTrack(index[i]);
575 ULong_t status=seed->GetStatus();
576 if ( (status & AliESDtrack::kTPCout ) == 0 ) continue;
577 if ( (status & AliESDtrack::kTRDout) != 0 ) continue;
579 Int_t lbl = seed->GetLabel();
580 AliTRDtrack *track = new AliTRDtrack(*seed);
581 track->SetSeedLabel(lbl);
582 seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup); //make backup
584 Float_t p4 = track->GetC();
586 Int_t expectedClr = FollowBackProlongation(*track);
587 if (TMath::Abs(track->GetC()-p4)/TMath::Abs(p4)<0.2 || TMath::Abs(track->GetPt())>0.8 ) {
589 //make backup for back propagation
591 Int_t foundClr = track->GetNumberOfClusters();
592 if (foundClr >= foundMin) {
594 CookdEdxTimBin(*track);
595 CookLabel(track, 1-fgkLabelFraction);
596 if (track->GetBackupTrack()) UseClusters(track->GetBackupTrack());
597 if(track->GetChi2()/track->GetNumberOfClusters()<4) { // sign only gold tracks
598 if (seed->GetKinkIndex(0)==0&&TMath::Abs(track->GetPt())<1.5 ) UseClusters(track);
600 Bool_t isGold = kFALSE;
602 if (track->GetChi2()/track->GetNumberOfClusters()<5) { //full gold track
603 // seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup);
604 if (track->GetBackupTrack()) seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
607 if (!isGold && track->GetNCross()==0&&track->GetChi2()/track->GetNumberOfClusters()<7){ //almost gold track
608 // seed->UpdateTrackParams(track, AliESDtrack::kTRDbackup);
609 if (track->GetBackupTrack()) seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
612 if (!isGold && track->GetBackupTrack()){
613 if (track->GetBackupTrack()->GetNumberOfClusters()>foundMin&&
614 (track->GetBackupTrack()->GetChi2()/(track->GetBackupTrack()->GetNumberOfClusters()+1))<7){
615 seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
619 if (track->StatusForTOF()>0 &&track->fNCross==0 && Float_t(track->fN)/Float_t(track->fNExpected)>0.4){
620 //seed->UpdateTrackParams(track->GetBackupTrack(), AliESDtrack::kTRDbackup);
624 // Debug part of tracking
625 TTreeSRedirector& cstream = *fDebugStreamer;
626 Int_t eventNr = event->GetEventNumber();
627 if (AliTRDReconstructor::StreamLevel()>0){
628 if (track->GetBackupTrack()){
630 "EventNr="<<eventNr<<
633 "trdback.="<<track->GetBackupTrack()<<
637 "EventNr="<<eventNr<<
645 //Propagation to the TOF (I.Belikov)
646 if (track->GetStop()==kFALSE){
649 Double_t c2=track->GetC()*xtof - track->GetEta();
650 if (TMath::Abs(c2)>=0.99) {
654 Double_t xTOF0 = 370. ;
655 PropagateToX(*track,xTOF0,fgkMaxStep);
657 //energy losses taken to the account - check one more time
658 c2=track->GetC()*xtof - track->GetEta();
659 if (TMath::Abs(c2)>=0.99) {
665 Double_t ymax=xtof*TMath::Tan(0.5*AliTRDgeometry::GetAlpha());
666 Double_t y=track->GetYat(xtof);
668 if (!track->Rotate(AliTRDgeometry::GetAlpha())) {
672 } else if (y <-ymax) {
673 if (!track->Rotate(-AliTRDgeometry::GetAlpha())) {
679 if (track->PropagateTo(xtof)) {
680 seed->UpdateTrackParams(track, AliESDtrack::kTRDout);
681 for (Int_t i=0;i<AliESDtrack::kNPlane;i++) {
682 for (Int_t j=0;j<AliESDtrack::kNSlice;j++) {
683 seed->SetTRDsignals(track->GetPIDsignals(i,j),i,j);
685 seed->SetTRDTimBin(track->GetPIDTimBin(i),i);
687 // seed->SetTRDtrack(new AliTRDtrack(*track));
688 if (track->GetNumberOfClusters()>foundMin) found++;
691 if (track->GetNumberOfClusters()>15&&track->GetNumberOfClusters()>0.5*expectedClr){
692 seed->UpdateTrackParams(track, AliESDtrack::kTRDout);
693 //seed->SetStatus(AliESDtrack::kTRDStop);
694 for (Int_t i=0;i<AliESDtrack::kNPlane;i++) {
695 for (Int_t j=0;j<AliESDtrack::kNSlice;j++) {
696 seed->SetTRDsignals(track->GetPIDsignals(i,j),i,j);
698 seed->SetTRDTimBin(track->GetPIDTimBin(i),i);
700 //seed->SetTRDtrack(new AliTRDtrack(*track));
704 seed->SetTRDQuality(track->StatusForTOF());
705 seed->SetTRDBudget(track->fBudget[0]);
709 //End of propagation to the TOF
710 //if (foundClr>foundMin)
711 // seed->UpdateTrackParams(track, AliESDtrack::kTRDout);
716 cerr<<"Number of seeds: "<<fNseeds<<endl;
717 cerr<<"Number of back propagated TRD tracks: "<<found<<endl;
719 if (AliTRDReconstructor::SeedingOn()) MakeSeedsMI(3,5,event); //new seeding
721 fSeeds->Clear(); fNseeds=0;
729 //_____________________________________________________________________________
730 Int_t AliTRDtracker::RefitInward(AliESD* event)
733 // Refits tracks within the TRD. The ESD event is expected to contain seeds
734 // at the outer part of the TRD.
735 // The tracks are propagated to the innermost time bin
736 // of the TRD and the ESD event is updated
737 // Origin: Thomas KUHR (Thomas.Kuhr@cern.ch)
740 Int_t timeBins = fTrSec[0]->GetNumberOfTimeBins();
741 Float_t foundMin = fgkMinClustersInTrack * timeBins;
744 // Int_t innerTB = fTrSec[0]->GetInnerTimeBin();
747 Int_t n = event->GetNumberOfTracks();
748 for (Int_t i=0; i<n; i++) {
749 AliESDtrack* seed=event->GetTrack(i);
750 new(&seed2) AliTRDtrack(*seed);
751 if (seed2.GetX()<270){
752 seed->UpdateTrackParams(&seed2, AliESDtrack::kTRDbackup); // backup TPC track - only update
756 ULong_t status=seed->GetStatus();
757 if ( (status & AliESDtrack::kTRDout ) == 0 ) {
760 if ( (status & AliESDtrack::kTRDin) != 0 ) {
764 // if (1/seed2.Get1Pt()>1.5&& seed2.GetX()>260.) {
765 // Double_t oldx = seed2.GetX();
766 // seed2.PropagateTo(500.);
767 // seed2.ResetCovariance(1.);
768 // seed2.PropagateTo(oldx);
771 // seed2.ResetCovariance(5.);
774 AliTRDtrack *pt = new AliTRDtrack(seed2,seed2.GetAlpha());
775 Int_t * indexes2 = seed2.GetIndexes();
776 for (Int_t i=0;i<AliESDtrack::kNPlane;i++) {
777 for (Int_t j=0;j<AliESDtrack::kNSlice;j++) {
778 pt->SetPIDsignals(seed2.GetPIDsignals(i,j),i,j);
780 pt->SetPIDTimBin(seed2.GetPIDTimBin(i),i);
783 Int_t * indexes3 = pt->GetBackupIndexes();
784 for (Int_t i=0;i<200;i++) {
785 if (indexes2[i]==0) break;
786 indexes3[i] = indexes2[i];
788 //AliTRDtrack *pt = seed2;
790 FollowProlongation(t);
791 if (t.GetNumberOfClusters() >= foundMin) {
793 //CookLabel(pt, 1-fgkLabelFraction);
798 // cout<<found<<'\r';
800 if(PropagateToX(t,xTPC,fgkMaxStep)) {
801 seed->UpdateTrackParams(pt, AliESDtrack::kTRDrefit);
802 for (Int_t i=0;i<AliESDtrack::kNPlane;i++) {
803 for (Int_t j=0;j<AliESDtrack::kNSlice;j++) {
804 seed->SetTRDsignals(pt->GetPIDsignals(i,j),i,j);
806 seed->SetTRDTimBin(pt->GetPIDTimBin(i),i);
809 //if not prolongation to TPC - propagate without update
810 AliTRDtrack* seed2 = new AliTRDtrack(*seed);
811 seed2->ResetCovariance(5.);
812 AliTRDtrack *pt2 = new AliTRDtrack(*seed2,seed2->GetAlpha());
814 if (PropagateToX(*pt2,xTPC,fgkMaxStep)) {
815 //pt2->CookdEdx(0.,1.);
816 pt2->CookdEdx( ); // Modification by PS
817 CookdEdxTimBin(*pt2);
818 seed->UpdateTrackParams(pt2, AliESDtrack::kTRDrefit);
819 for (Int_t i=0;i<AliESDtrack::kNPlane;i++) {
820 for (Int_t j=0;j<AliESDtrack::kNSlice;j++) {
821 seed->SetTRDsignals(pt2->GetPIDsignals(i,j),i,j);
823 seed->SetTRDTimBin(pt2->GetPIDTimBin(i),i);
831 cout<<"Number of loaded seeds: "<<nseed<<endl;
832 cout<<"Number of found tracks from loaded seeds: "<<found<<endl;
838 //_____________________________________________________________________________
839 Int_t AliTRDtracker::FollowProlongation(AliTRDtrack& t)
842 // Starting from current position on track=t this function tries
843 // to extrapolate the track up to timeBin=0 and to confirm prolongation
844 // if a close cluster is found. Returns the number of clusters
845 // expected to be found in sensitive layers
846 // GeoManager used to estimate mean density
850 Int_t lastplane = GetLastPlane(&t);
851 Double_t radLength = 0.0;
853 Int_t expectedNumberOfClusters = 0;
857 for (Int_t iplane = lastplane; iplane>=0; iplane--){
859 Int_t row0 = GetGlobalTimeBin(0, iplane,GetTimeBinsPerPlane()-1);
860 Int_t rowlast = GetGlobalTimeBin(0, iplane,0);
862 // propagate track close to the plane if neccessary
864 Double_t currentx = fTrSec[0]->GetLayer(rowlast)->GetX();
865 if (currentx < -fgkMaxStep +t.GetX()){
866 //propagate closer to chamber - safety space fgkMaxStep
867 if (!PropagateToX(t, currentx+fgkMaxStep, fgkMaxStep)) break;
869 if (!AdjustSector(&t)) break;
871 // get material budget
873 Double_t xyz0[3],xyz1[3],param[7],x,y,z;
874 t.GetGlobalXYZ(xyz0[0],xyz0[1],xyz0[2]); //starting global position
875 // end global position
876 x = fTrSec[0]->GetLayer(row0)->GetX();
877 if (!t.GetProlongation(x,y,z)) break;
878 xyz1[0] = x*TMath::Cos(t.GetAlpha())-y*TMath::Sin(t.GetAlpha());
879 xyz1[1] = +x*TMath::Sin(t.GetAlpha())+y*TMath::Cos(t.GetAlpha());
881 AliKalmanTrack::MeanMaterialBudget(xyz0,xyz1,param);
883 radLength = param[1]; // get mean propagation parameters
885 // propagate nad update
887 sector = t.GetSector();
888 // for (Int_t itime=GetTimeBinsPerPlane()-1;itime>=0;itime--) {
889 for (Int_t itime=0 ;itime<GetTimeBinsPerPlane();itime++) {
890 Int_t ilayer = GetGlobalTimeBin(0, iplane,itime);
891 expectedNumberOfClusters++;
893 if (t.fX>345) t.fNExpectedLast++;
894 AliTRDpropagationLayer& timeBin=*(fTrSec[sector]->GetLayer(ilayer));
897 Double_t maxChi2=fgkMaxChi2;
900 AliTRDcluster * cl0 = timeBin[0];
901 if (!cl0) continue; // no clusters in given time bin
902 Int_t plane = fGeom->GetPlane(cl0->GetDetector());
903 if (plane>lastplane) continue;
904 Int_t timebin = cl0->GetLocalTimeBin();
905 AliTRDcluster * cl2= GetCluster(&t,plane, timebin,index);
909 Double_t h01 = GetTiltFactor(cl);
910 maxChi2=t.GetPredictedChi2(cl,h01);
913 // if (cl->GetNPads()<5)
914 Double_t dxsample = timeBin.GetdX();
915 t.SetSampledEdx(TMath::Abs(cl->GetQ()/dxsample));
916 Double_t h01 = GetTiltFactor(cl);
917 Int_t det = cl->GetDetector();
918 Int_t plane = fGeom->GetPlane(det);
921 t.fChi2Last+=maxChi2;
923 Double_t xcluster = cl->GetX();
924 t.PropagateTo(xcluster,radLength,rho);
925 if(!t.UpdateMI(cl,maxChi2,index,h01,plane)) {
932 return expectedNumberOfClusters;
936 //_____________________________________________________________________________
937 Int_t AliTRDtracker::FollowBackProlongation(AliTRDtrack& t)
940 // Starting from current radial position of track <t> this function
941 // extrapolates the track up to outer timebin and in the sensitive
942 // layers confirms prolongation if a close cluster is found.
943 // Returns the number of clusters expected to be found in sensitive layers
944 // Use GEO manager for material Description
948 Int_t clusters[1000];
949 for (Int_t i=0;i<1000;i++) clusters[i]=-1;
950 Double_t radLength = 0.0;
952 Int_t expectedNumberOfClusters = 0;
954 AliTRDtracklet tracklet;
957 for (Int_t iplane = 0; iplane<AliESDtrack::kNPlane; iplane++){
958 Int_t row0 = GetGlobalTimeBin(0, iplane,GetTimeBinsPerPlane()-1);
959 Int_t rowlast = GetGlobalTimeBin(0, iplane,0);
961 Double_t currentx = fTrSec[0]->GetLayer(row0)->GetX();
962 if (currentx<t.GetX()) continue;
964 // propagate closer to chamber if neccessary
966 if (currentx > fgkMaxStep +t.GetX()){
967 if (!PropagateToX(t, currentx-fgkMaxStep, fgkMaxStep)) break;
969 if (!AdjustSector(&t)) break;
970 if (TMath::Abs(t.GetSnp())>fgkMaxSnp) break;
972 // get material budget inside of chamber
974 Double_t xyz0[3],xyz1[3],param[7],x,y,z;
975 t.GetGlobalXYZ(xyz0[0],xyz0[1],xyz0[2]); //starting global position
976 // end global position
977 x = fTrSec[0]->GetLayer(rowlast)->GetX();
978 if (!t.GetProlongation(x,y,z)) break;
979 xyz1[0] = x*TMath::Cos(t.GetAlpha())-y*TMath::Sin(t.GetAlpha());
980 xyz1[1] = +x*TMath::Sin(t.GetAlpha())+y*TMath::Cos(t.GetAlpha());
982 AliKalmanTrack::MeanMaterialBudget(xyz0,xyz1,param);
984 radLength = param[1]; // get mean propagation parameters
988 sector = t.GetSector();
989 Float_t ncl = FindClusters(sector,row0,rowlast,&t,clusters,tracklet);
990 if (tracklet.GetN()<GetTimeBinsPerPlane()/3) continue;
992 // Propagate and update track
994 for (Int_t itime= GetTimeBinsPerPlane()-1;itime>=0;itime--) {
995 Int_t ilayer = GetGlobalTimeBin(0, iplane,itime);
996 expectedNumberOfClusters++;
998 if (t.fX>345) t.fNExpectedLast++;
999 AliTRDpropagationLayer& timeBin=*(fTrSec[sector]->GetLayer(ilayer));
1000 AliTRDcluster *cl=0;
1002 Double_t maxChi2=fgkMaxChi2;
1006 if (clusters[ilayer]>0) {
1007 index = clusters[ilayer];
1008 cl = (AliTRDcluster*)GetCluster(index);
1009 Double_t h01 = GetTiltFactor(cl);
1010 maxChi2=t.GetPredictedChi2(cl,h01);
1014 // if (cl->GetNPads()<5)
1015 Double_t dxsample = timeBin.GetdX();
1016 t.SetSampledEdx(TMath::Abs(cl->GetQ()/dxsample));
1017 Double_t h01 = GetTiltFactor(cl);
1018 Int_t det = cl->GetDetector();
1019 Int_t plane = fGeom->GetPlane(det);
1022 t.fChi2Last+=maxChi2;
1024 Double_t xcluster = cl->GetX();
1025 t.PropagateTo(xcluster,radLength,rho);
1026 if(!t.UpdateMI(cl,maxChi2,index,h01,plane)) {
1027 if(!t.Update(cl,maxChi2,index,h01)) {
1031 // reset material budget if 2 consecutive gold
1033 if (t.fTracklets[plane].GetN()+t.fTracklets[plane-1].GetN()>20){
1039 ratio0 = ncl/Float_t(fTimeBinsPerPlane);
1040 Float_t ratio1 = Float_t(t.fN+1)/Float_t(t.fNExpected+1.);
1041 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){
1042 t.MakeBackupTrack(); // make backup of the track until is gold
1047 return expectedNumberOfClusters;
1051 //_____________________________________________________________________________
1052 Int_t AliTRDtracker::PropagateToX(AliTRDtrack& t, Double_t xToGo, Double_t maxStep)
1055 // Starting from current radial position of track <t> this function
1056 // extrapolates the track up to radial position <xToGo>.
1057 // Returns 1 if track reaches the plane, and 0 otherwise
1060 const Double_t kEpsilon = 0.00001;
1061 // Double_t tanmax = TMath::Tan(0.5*AliTRDgeometry::GetAlpha());
1062 Double_t xpos = t.GetX();
1063 Double_t dir = (xpos<xToGo) ? 1.:-1.;
1065 while ( (xToGo-xpos)*dir > kEpsilon){
1066 Double_t step = dir*TMath::Min(TMath::Abs(xToGo-xpos), maxStep);
1068 Double_t xyz0[3],xyz1[3],param[7],x,y,z;
1069 t.GetGlobalXYZ(xyz0[0],xyz0[1],xyz0[2]); //starting global position
1072 if (!t.GetProlongation(x,y,z)) return 0; // no prolongation
1074 xyz1[0] = x*TMath::Cos(t.GetAlpha())-y*TMath::Sin(t.GetAlpha());
1075 xyz1[1] = +x*TMath::Sin(t.GetAlpha())+y*TMath::Cos(t.GetAlpha());
1078 AliKalmanTrack::MeanMaterialBudget(xyz0,xyz1,param);
1079 if (!t.PropagateTo(x,param[1],param[0])) return 0;
1088 //_____________________________________________________________________________
1089 Int_t AliTRDtracker::LoadClusters(TTree *cTree)
1092 // Fills clusters into TRD tracking_sectors
1093 // Note that the numbering scheme for the TRD tracking_sectors
1094 // differs from that of TRD sectors
1097 cout<<"\n Read Sectors clusters"<<endl;
1098 if (ReadClusters(fClusters,cTree)) {
1099 Error("LoadClusters","Problem with reading the clusters !");
1102 Int_t ncl=fClusters->GetEntriesFast();
1104 cout<<"\n LoadSectors: sorting "<<ncl<<" clusters"<<endl;
1107 for (Int_t ichamber=0;ichamber<5;ichamber++)
1108 for (Int_t isector=0;isector<18;isector++){
1109 fHoles[ichamber][isector]=kTRUE;
1114 // printf("\r %d left ",ncl);
1115 AliTRDcluster *c=(AliTRDcluster*)fClusters->UncheckedAt(ncl);
1116 Int_t detector=c->GetDetector();
1117 Int_t localTimeBin=c->GetLocalTimeBin();
1118 Int_t sector=fGeom->GetSector(detector);
1119 Int_t plane=fGeom->GetPlane(detector);
1121 Int_t trackingSector = CookSectorIndex(sector);
1122 if (c->GetLabel(0)>0){
1123 Int_t chamber = fGeom->GetChamber(detector);
1124 fHoles[chamber][trackingSector]=kFALSE;
1127 Int_t gtb = fTrSec[trackingSector]->CookTimeBinIndex(plane,localTimeBin);
1128 if(gtb < 0) continue;
1129 Int_t layer = fTrSec[trackingSector]->GetLayerNumber(gtb);
1133 // apply pos correction
1135 fTrSec[trackingSector]->GetLayer(layer)->InsertCluster(c,index);
1142 //_____________________________________________________________________________
1143 void AliTRDtracker::UnloadClusters()
1146 // Clears the arrays of clusters and tracks. Resets sectors and timebins
1151 nentr = fClusters->GetEntriesFast();
1152 for (i = 0; i < nentr; i++) delete fClusters->RemoveAt(i);
1155 nentr = fSeeds->GetEntriesFast();
1156 for (i = 0; i < nentr; i++) delete fSeeds->RemoveAt(i);
1158 nentr = fTracks->GetEntriesFast();
1159 for (i = 0; i < nentr; i++) delete fTracks->RemoveAt(i);
1161 Int_t nsec = AliTRDgeometry::kNsect;
1163 for (i = 0; i < nsec; i++) {
1164 for(Int_t pl = 0; pl < fTrSec[i]->GetNumberOfLayers(); pl++) {
1165 fTrSec[i]->GetLayer(pl)->Clear();
1171 //_____________________________________________________________________________
1172 void AliTRDtracker::MakeSeedsMI(Int_t /*inner*/, Int_t /*outer*/, AliESD * esd)
1175 // Creates seeds using clusters between position inner plane and outer plane
1178 const Double_t kMaxTheta = 1;
1179 const Double_t kMaxPhi = 2.0;
1181 const Double_t kRoad0y = 6; // road for middle cluster
1182 const Double_t kRoad0z = 8.5; // road for middle cluster
1184 const Double_t kRoad1y = 2; // road in y for seeded cluster
1185 const Double_t kRoad1z = 20; // road in z for seeded cluster
1187 const Double_t kRoad2y = 3; // road in y for extrapolated cluster
1188 const Double_t kRoad2z = 20; // road in z for extrapolated cluster
1189 const Int_t kMaxSeed = 3000;
1190 Int_t maxSec=AliTRDgeometry::kNsect;
1193 // linear fitters in planes
1194 TLinearFitter fitterTC(2,"hyp2"); // fitting with tilting pads - kz fixed - kz= Z/x, + vertex const
1195 TLinearFitter fitterT2(4,"hyp4"); // fitting with tilting pads - kz not fixed
1196 fitterTC.StoreData(kTRUE);
1197 fitterT2.StoreData(kTRUE);
1198 AliRieman rieman(1000); // rieman fitter
1199 AliRieman rieman2(1000); // rieman fitter
1201 // find the maximal and minimal layer for the planes
1204 AliTRDpropagationLayer* reflayers[6];
1205 for (Int_t i=0;i<6;i++){layers[i][0]=10000; layers[i][1]=0;}
1206 for (Int_t ns=0;ns<maxSec;ns++){
1207 for (Int_t ilayer=0;ilayer<fTrSec[ns]->GetNumberOfLayers();ilayer++){
1208 AliTRDpropagationLayer& layer=*(fTrSec[ns]->GetLayer(ilayer));
1209 if (layer==0) continue;
1210 Int_t det = layer[0]->GetDetector();
1211 Int_t plane = fGeom->GetPlane(det);
1212 if (ilayer<layers[plane][0]) layers[plane][0] = ilayer;
1213 if (ilayer>layers[plane][1]) layers[plane][1] = ilayer;
1217 AliTRDpadPlane *padPlane = AliTRDCommonParam::Instance()->GetPadPlane(0,0);
1218 Double_t h01 = TMath::Tan(-TMath::Pi() / 180.0 * padPlane->GetTiltingAngle());
1219 Double_t hL[6]; // tilting angle
1220 Double_t xcl[6]; // x - position of reference cluster
1221 Double_t ycl[6]; // y - position of reference cluster
1222 Double_t zcl[6]; // z - position of reference cluster
1223 AliTRDcluster *cl[6]={0,0,0,0,0,0}; // seeding clusters
1224 Float_t padlength[6]={10,10,10,10,10,10}; //current pad-length
1225 Double_t chi2R =0, chi2Z=0;
1226 Double_t chi2RF =0, chi2ZF=0;
1228 Int_t nclusters; // total number of clusters
1229 for (Int_t i=0;i<6;i++) {hL[i]=h01; if (i%2==1) hL[i]*=-1.;}
1233 AliTRDseed *pseed = new AliTRDseed[kMaxSeed*6];
1234 AliTRDseed *seed[kMaxSeed];
1235 for (Int_t iseed=0;iseed<kMaxSeed;iseed++) seed[iseed]= &pseed[iseed*6];
1236 AliTRDseed *cseed = seed[0];
1238 Double_t seedquality[kMaxSeed];
1239 Double_t seedquality2[kMaxSeed];
1240 Double_t seedparams[kMaxSeed][7];
1241 Int_t seedlayer[kMaxSeed];
1242 Int_t registered =0;
1243 Int_t sort[kMaxSeed];
1247 for (Int_t ns = 0; ns<maxSec; ns++){ //loop over sectors
1248 //for (Int_t ns = 0; ns<5; ns++){ //loop over sectors
1249 registered = 0; // reset registerd seed counter
1250 cseed = seed[registered];
1252 for (Int_t sLayer=2; sLayer>=0;sLayer--){
1253 //for (Int_t dseed=5;dseed<15; dseed+=3){ //loop over central seeding time bins
1255 Int_t dseed = 5+Int_t(iter)*3;
1256 // Initialize seeding layers
1257 for (Int_t ilayer=0;ilayer<6;ilayer++){
1258 reflayers[ilayer] = fTrSec[ns]->GetLayer(layers[ilayer][1]-dseed);
1259 xcl[ilayer] = reflayers[ilayer]->GetX();
1262 Double_t xref = (xcl[sLayer+1] + xcl[sLayer+2])*0.5;
1263 AliTRDpropagationLayer& layer0=*reflayers[sLayer+0];
1264 AliTRDpropagationLayer& layer1=*reflayers[sLayer+1];
1265 AliTRDpropagationLayer& layer2=*reflayers[sLayer+2];
1266 AliTRDpropagationLayer& layer3=*reflayers[sLayer+3];
1268 Int_t maxn3 = layer3;
1269 for (Int_t icl3=0;icl3<maxn3;icl3++){
1270 AliTRDcluster *cl3 = layer3[icl3];
1272 padlength[sLayer+3] = TMath::Sqrt(cl3->GetSigmaZ2()*12.);
1273 ycl[sLayer+3] = cl3->GetY();
1274 zcl[sLayer+3] = cl3->GetZ();
1275 Float_t yymin0 = ycl[sLayer+3] - 1- kMaxPhi *(xcl[sLayer+3]-xcl[sLayer+0]);
1276 Float_t yymax0 = ycl[sLayer+3] + 1+ kMaxPhi *(xcl[sLayer+3]-xcl[sLayer+0]);
1277 Int_t maxn0 = layer0; //
1278 for (Int_t icl0=layer0.Find(yymin0);icl0<maxn0;icl0++){
1279 AliTRDcluster *cl0 = layer0[icl0];
1281 if (cl3->IsUsed()&&cl0->IsUsed()) continue;
1282 ycl[sLayer+0] = cl0->GetY();
1283 zcl[sLayer+0] = cl0->GetZ();
1284 if ( ycl[sLayer+0]>yymax0) break;
1285 Double_t tanphi = (ycl[sLayer+3]-ycl[sLayer+0])/(xcl[sLayer+3]-xcl[sLayer+0]);
1286 if (TMath::Abs(tanphi)>kMaxPhi) continue;
1287 Double_t tantheta = (zcl[sLayer+3]-zcl[sLayer+0])/(xcl[sLayer+3]-xcl[sLayer+0]);
1288 if (TMath::Abs(tantheta)>kMaxTheta) continue;
1289 padlength[sLayer+0] = TMath::Sqrt(cl0->GetSigmaZ2()*12.);
1291 // expected position in 1 layer
1292 Double_t y1exp = ycl[sLayer+0]+(tanphi) *(xcl[sLayer+1]-xcl[sLayer+0]);
1293 Double_t z1exp = zcl[sLayer+0]+(tantheta)*(xcl[sLayer+1]-xcl[sLayer+0]);
1294 Float_t yymin1 = y1exp - kRoad0y-tanphi;
1295 Float_t yymax1 = y1exp + kRoad0y+tanphi;
1296 Int_t maxn1 = layer1; //
1298 for (Int_t icl1=layer1.Find(yymin1);icl1<maxn1;icl1++){
1299 AliTRDcluster *cl1 = layer1[icl1];
1302 if (cl3->IsUsed()) nusedCl++;
1303 if (cl0->IsUsed()) nusedCl++;
1304 if (cl1->IsUsed()) nusedCl++;
1305 if (nusedCl>1) continue;
1306 ycl[sLayer+1] = cl1->GetY();
1307 zcl[sLayer+1] = cl1->GetZ();
1308 if ( ycl[sLayer+1]>yymax1) break;
1309 if (TMath::Abs(ycl[sLayer+1]-y1exp)>kRoad0y+tanphi) continue;
1310 if (TMath::Abs(zcl[sLayer+1]-z1exp)>kRoad0z) continue;
1311 padlength[sLayer+1] = TMath::Sqrt(cl1->GetSigmaZ2()*12.);
1313 Double_t y2exp = ycl[sLayer+0]+(tanphi) *(xcl[sLayer+2]-xcl[sLayer+0])+(ycl[sLayer+1]-y1exp);
1314 Double_t z2exp = zcl[sLayer+0]+(tantheta)*(xcl[sLayer+2]-xcl[sLayer+0]);
1315 Int_t index2 = layer2.FindNearestCluster(y2exp,z2exp,kRoad1y, kRoad1z);
1316 if (index2<=0) continue;
1317 AliTRDcluster *cl2 = (AliTRDcluster*)GetCluster(index2);
1318 padlength[sLayer+2] = TMath::Sqrt(cl2->GetSigmaZ2()*12.);
1319 ycl[sLayer+2] = cl2->GetY();
1320 zcl[sLayer+2] = cl2->GetZ();
1321 if (TMath::Abs(cl2->GetZ()-z2exp)>kRoad0z) continue;
1324 rieman.AddPoint(xcl[sLayer+0],ycl[sLayer+0],zcl[sLayer+0],1,10);
1325 rieman.AddPoint(xcl[sLayer+1],ycl[sLayer+1],zcl[sLayer+1],1,10);
1326 rieman.AddPoint(xcl[sLayer+3],ycl[sLayer+3],zcl[sLayer+3],1,10);
1327 rieman.AddPoint(xcl[sLayer+2],ycl[sLayer+2],zcl[sLayer+2],1,10);
1331 for (Int_t iLayer=0;iLayer<6;iLayer++){
1332 cseed[iLayer].Reset();
1334 chi2Z =0.; chi2R=0.;
1335 for (Int_t iLayer=0;iLayer<4;iLayer++){
1336 cseed[sLayer+iLayer].fZref[0] = rieman.GetZat(xcl[sLayer+iLayer]);
1337 chi2Z += (cseed[sLayer+iLayer].fZref[0]- zcl[sLayer+iLayer])*
1338 (cseed[sLayer+iLayer].fZref[0]- zcl[sLayer+iLayer]);
1339 cseed[sLayer+iLayer].fZref[1] = rieman.GetDZat(xcl[sLayer+iLayer]);
1340 cseed[sLayer+iLayer].fYref[0] = rieman.GetYat(xcl[sLayer+iLayer]);
1341 chi2R += (cseed[sLayer+iLayer].fYref[0]- ycl[sLayer+iLayer])*
1342 (cseed[sLayer+iLayer].fYref[0]- ycl[sLayer+iLayer]);
1343 cseed[sLayer+iLayer].fYref[1] = rieman.GetDYat(xcl[sLayer+iLayer]);
1345 if (TMath::Sqrt(chi2R)>1./iter) continue;
1346 if (TMath::Sqrt(chi2Z)>7./iter) continue;
1350 Float_t minmax[2]={-100,100};
1351 for (Int_t iLayer=0;iLayer<4;iLayer++){
1352 Float_t max = zcl[sLayer+iLayer]+padlength[sLayer+iLayer]*0.5+1 -cseed[sLayer+iLayer].fZref[0];
1353 if (max<minmax[1]) minmax[1]=max;
1354 Float_t min = zcl[sLayer+iLayer]-padlength[sLayer+iLayer]*0.5-1 -cseed[sLayer+iLayer].fZref[0];
1355 if (min>minmax[0]) minmax[0]=min;
1357 Bool_t isFake = kFALSE;
1358 if (cl0->GetLabel(0)!=cl3->GetLabel(0)) isFake = kTRUE;
1359 if (cl1->GetLabel(0)!=cl3->GetLabel(0)) isFake = kTRUE;
1360 if (cl2->GetLabel(0)!=cl3->GetLabel(0)) isFake = kTRUE;
1361 if (AliTRDReconstructor::StreamLevel()>0){
1362 if ((!isFake) || (icl3%10)==0 ){ //debugging print
1363 TTreeSRedirector& cstream = *fDebugStreamer;
1371 "X0="<<xcl[sLayer+0]<<
1372 "X1="<<xcl[sLayer+1]<<
1373 "X2="<<xcl[sLayer+2]<<
1374 "X3="<<xcl[sLayer+3]<<
1379 "Seed0.="<<&cseed[sLayer+0]<<
1380 "Seed1.="<<&cseed[sLayer+1]<<
1381 "Seed2.="<<&cseed[sLayer+2]<<
1382 "Seed3.="<<&cseed[sLayer+3]<<
1383 "Zmin="<<minmax[0]<<
1384 "Zmax="<<minmax[1]<<
1389 //<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1390 //<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1391 //<<<<<<<<<<<<<<<<<< FIT SEEDING PART <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1392 //<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1398 for (Int_t jLayer=0;jLayer<4;jLayer++){
1399 cseed[sLayer+jLayer].fTilt = hL[sLayer+jLayer];
1400 cseed[sLayer+jLayer].fPadLength = padlength[sLayer+jLayer];
1401 cseed[sLayer+jLayer].fX0 = xcl[sLayer+jLayer];
1402 for (Int_t iter=0; iter<2; iter++){
1404 // in iteration 0 we try only one pad-row
1405 // if quality not sufficient we try 2 pad-rows - about 5% of tracks cross 2 pad-rows
1407 AliTRDseed tseed = cseed[sLayer+jLayer];
1408 Float_t roadz = padlength[sLayer+jLayer]*0.5;
1409 if (iter>0) roadz = padlength[sLayer+jLayer];
1411 Float_t quality =10000;
1412 for (Int_t iTime=2;iTime<20;iTime++){
1413 AliTRDpropagationLayer& layer = *(fTrSec[ns]->GetLayer(layers[sLayer+jLayer][1]-iTime));
1414 Double_t dxlayer= layer.GetX()-xcl[sLayer+jLayer];
1415 Double_t zexp = cl[sLayer+jLayer]->GetZ() ;
1417 // try 2 pad-rows in second iteration
1418 zexp = tseed.fZref[0]+ tseed.fZref[1]*dxlayer;
1419 if (zexp>cl[sLayer+jLayer]->GetZ()) zexp = cl[sLayer+jLayer]->GetZ()+padlength[sLayer+jLayer]*0.5;
1420 if (zexp<cl[sLayer+jLayer]->GetZ()) zexp = cl[sLayer+jLayer]->GetZ()-padlength[sLayer+jLayer]*0.5;
1423 Double_t yexp = tseed.fYref[0]+
1424 tseed.fYref[1]*dxlayer;
1425 Int_t index = layer.FindNearestCluster(yexp,zexp,kRoad1y, roadz);
1426 if (index<=0) continue;
1427 AliTRDcluster *cl = (AliTRDcluster*)GetCluster(index);
1429 tseed.fIndexes[iTime] = index;
1430 tseed.fClusters[iTime] = cl; // register cluster
1431 tseed.fX[iTime] = dxlayer; // register cluster
1432 tseed.fY[iTime] = cl->GetY(); // register cluster
1433 tseed.fZ[iTime] = cl->GetZ(); // register cluster
1436 //count the number of clusters and distortions into quality
1437 Float_t dangle = tseed.fYfit[1]-tseed.fYref[1];
1438 Float_t tquality = (18-tseed.fN2)/2. + TMath::Abs(dangle)/0.1+
1439 TMath::Abs(tseed.fYfit[0]-tseed.fYref[0])/0.2+
1440 2.*TMath::Abs(tseed.fMeanz-tseed.fZref[0])/padlength[jLayer];
1441 if (iter==0 && tseed.IsOK()) {
1442 cseed[sLayer+jLayer] = tseed;
1444 if (tquality<5) break;
1446 if (tseed.IsOK() && tquality<quality)
1447 cseed[sLayer+jLayer] = tseed;
1449 if (!cseed[sLayer+jLayer].IsOK()){
1453 cseed[sLayer+jLayer].CookLabels();
1454 cseed[sLayer+jLayer].UpdateUsed();
1455 nusedCl+= cseed[sLayer+jLayer].fNUsed;
1462 if (!isOK) continue;
1464 for (Int_t iLayer=0;iLayer<4;iLayer++){
1465 if (cseed[sLayer+iLayer].IsOK()){
1466 nclusters+=cseed[sLayer+iLayer].fN2;
1472 for (Int_t iLayer=0;iLayer<4;iLayer++){
1473 rieman.AddPoint(xcl[sLayer+iLayer],cseed[sLayer+iLayer].fYfitR[0],
1474 cseed[sLayer+iLayer].fZProb,1,10);
1480 for (Int_t iLayer=0;iLayer<4;iLayer++){
1481 cseed[sLayer+iLayer].fYref[0] = rieman.GetYat(xcl[sLayer+iLayer]);
1482 chi2R += (cseed[sLayer+iLayer].fYref[0]-cseed[sLayer+iLayer].fYfitR[0])*
1483 (cseed[sLayer+iLayer].fYref[0]-cseed[sLayer+iLayer].fYfitR[0]);
1484 cseed[sLayer+iLayer].fYref[1] = rieman.GetDYat(xcl[sLayer+iLayer]);
1485 cseed[sLayer+iLayer].fZref[0] = rieman.GetZat(xcl[sLayer+iLayer]);
1486 chi2Z += (cseed[sLayer+iLayer].fZref[0]- cseed[sLayer+iLayer].fMeanz)*
1487 (cseed[sLayer+iLayer].fZref[0]- cseed[sLayer+iLayer].fMeanz);
1488 cseed[sLayer+iLayer].fZref[1] = rieman.GetDZat(xcl[sLayer+iLayer]);
1490 Double_t curv = rieman.GetC();
1495 TMath::Abs(cseed[sLayer+0].fYfitR[1]- cseed[sLayer+0].fYref[1])+
1496 TMath::Abs(cseed[sLayer+1].fYfitR[1]- cseed[sLayer+1].fYref[1])+
1497 TMath::Abs(cseed[sLayer+2].fYfitR[1]- cseed[sLayer+2].fYref[1])+
1498 TMath::Abs(cseed[sLayer+3].fYfitR[1]- cseed[sLayer+3].fYref[1]);
1499 Double_t likea = TMath::Exp(-sumda*10.6);
1500 Double_t likechi2 = 0.0000000001;
1501 if (chi2R<0.5) likechi2+=TMath::Exp(-TMath::Sqrt(chi2R)*7.73);
1502 Double_t likechi2z = TMath::Exp(-chi2Z*0.088)/TMath::Exp(-chi2Z*0.019);
1503 Double_t likeN = TMath::Exp(-(72-nclusters)*0.19);
1504 Double_t like = likea*likechi2*likechi2z*likeN;
1506 Double_t likePrimY = TMath::Exp(-TMath::Abs(cseed[sLayer+0].fYref[1]-130*curv)*1.9);
1507 Double_t likePrimZ = TMath::Exp(-TMath::Abs(cseed[sLayer+0].fZref[1]-
1508 cseed[sLayer+0].fZref[0]/xcl[sLayer+0])*5.9);
1509 Double_t likePrim = TMath::Max(likePrimY*likePrimZ,0.0005);
1511 seedquality[registered] = like;
1512 seedlayer[registered] = sLayer;
1513 if (TMath::Log(0.000000000000001+like)<-15) continue;
1514 AliTRDseed seedb[6];
1515 for (Int_t iLayer=0;iLayer<6;iLayer++){
1516 seedb[iLayer] = cseed[iLayer];
1519 //<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1520 //<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1521 //<<<<<<<<<<<<<<< FULL TRACK FIT PART <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1522 //<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1528 // add new layers - avoid long extrapolation
1530 Int_t tLayer[2]={0,0};
1531 if (sLayer==2) {tLayer[0]=1; tLayer[1]=0;}
1532 if (sLayer==1) {tLayer[0]=5; tLayer[1]=0;}
1533 if (sLayer==0) {tLayer[0]=4; tLayer[1]=5;}
1535 for (Int_t iLayer=0;iLayer<2;iLayer++){
1536 Int_t jLayer = tLayer[iLayer]; // set tracking layer
1537 cseed[jLayer].Reset();
1538 cseed[jLayer].fTilt = hL[jLayer];
1539 cseed[jLayer].fPadLength = padlength[jLayer];
1540 cseed[jLayer].fX0 = xcl[jLayer];
1541 // get pad length and rough cluster
1542 Int_t indexdummy = reflayers[jLayer]->FindNearestCluster(cseed[jLayer].fYref[0],
1543 cseed[jLayer].fZref[0],kRoad2y,kRoad2z);
1544 if (indexdummy<=0) continue;
1545 AliTRDcluster *cldummy = (AliTRDcluster*)GetCluster(indexdummy);
1546 padlength[jLayer] = TMath::Sqrt(cldummy->GetSigmaZ2()*12.);
1548 AliTRDseed::FitRiemanTilt(cseed, kTRUE);
1550 for (Int_t iLayer=0;iLayer<2;iLayer++){
1551 Int_t jLayer = tLayer[iLayer]; // set tracking layer
1552 if ( (jLayer==0) && !(cseed[1].IsOK())) continue; // break not allowed
1553 if ( (jLayer==5) && !(cseed[4].IsOK())) continue; // break not allowed
1554 Float_t zexp = cseed[jLayer].fZref[0];
1555 Double_t zroad = padlength[jLayer]*0.5+1.;
1558 for (Int_t iter=0;iter<2;iter++){
1559 AliTRDseed tseed = cseed[jLayer];
1560 Float_t quality = 10000;
1561 for (Int_t iTime=2;iTime<20;iTime++){
1562 AliTRDpropagationLayer& layer = *(fTrSec[ns]->GetLayer(layers[jLayer][1]-iTime));
1563 Double_t dxlayer = layer.GetX()-xcl[jLayer];
1564 Double_t yexp = tseed.fYref[0]+tseed.fYref[1]*dxlayer;
1565 Float_t yroad = kRoad1y;
1566 Int_t index = layer.FindNearestCluster(yexp,zexp, yroad, zroad);
1567 if (index<=0) continue;
1568 AliTRDcluster *cl = (AliTRDcluster*)GetCluster(index);
1570 tseed.fIndexes[iTime] = index;
1571 tseed.fClusters[iTime] = cl; // register cluster
1572 tseed.fX[iTime] = dxlayer; // register cluster
1573 tseed.fY[iTime] = cl->GetY(); // register cluster
1574 tseed.fZ[iTime] = cl->GetZ(); // register cluster
1578 Float_t dangle = tseed.fYfit[1]-tseed.fYref[1];
1579 Float_t tquality = (18-tseed.fN2)/2. + TMath::Abs(dangle)/0.1+
1580 TMath::Abs(tseed.fYfit[0]-tseed.fYref[0])/0.2+
1581 2.*TMath::Abs(tseed.fMeanz-tseed.fZref[0])/padlength[jLayer];
1583 if (tquality<quality){
1584 cseed[jLayer]=tseed;
1590 if ( cseed[jLayer].IsOK()){
1591 cseed[jLayer].CookLabels();
1592 cseed[jLayer].UpdateUsed();
1593 nusedf+= cseed[jLayer].fNUsed;
1594 AliTRDseed::FitRiemanTilt(cseed, kTRUE);
1600 AliTRDseed bseed[6];
1601 for (Int_t jLayer=0;jLayer<6;jLayer++){
1602 bseed[jLayer] = cseed[jLayer];
1604 Float_t lastquality = 10000;
1605 Float_t lastchi2 = 10000;
1606 Float_t chi2 = 1000;
1609 for (Int_t iter =0; iter<4;iter++){
1611 // sort tracklets according "quality", try to "improve" 4 worst
1613 Float_t sumquality = 0;
1614 Float_t squality[6];
1615 Int_t sortindexes[6];
1616 for (Int_t jLayer=0;jLayer<6;jLayer++){
1617 if (bseed[jLayer].IsOK()){
1618 AliTRDseed &tseed = bseed[jLayer];
1619 Double_t zcor = tseed.fTilt*(tseed.fZProb-tseed.fZref[0]);
1620 Float_t dangle = tseed.fYfit[1]-tseed.fYref[1];
1621 Float_t tquality = (18-tseed.fN2)/2. + TMath::Abs(dangle)/0.1+
1622 TMath::Abs(tseed.fYfit[0]-(tseed.fYref[0]-zcor))/0.2+
1623 2.*TMath::Abs(tseed.fMeanz-tseed.fZref[0])/padlength[jLayer];
1624 squality[jLayer] = tquality;
1626 else squality[jLayer]=-1;
1627 sumquality +=squality[jLayer];
1630 if (sumquality>=lastquality || chi2>lastchi2) break;
1631 lastquality = sumquality;
1634 for (Int_t jLayer=0;jLayer<6;jLayer++){
1635 cseed[jLayer] = bseed[jLayer];
1638 TMath::Sort(6,squality,sortindexes,kFALSE);
1641 for (Int_t jLayer=5;jLayer>1;jLayer--){
1642 Int_t bLayer = sortindexes[jLayer];
1643 AliTRDseed tseed = bseed[bLayer];
1644 for (Int_t iTime=2;iTime<20;iTime++){
1645 AliTRDpropagationLayer& layer = *(fTrSec[ns]->GetLayer(layers[bLayer][1]-iTime));
1646 Double_t dxlayer= layer.GetX()-xcl[bLayer];
1648 Double_t zexp = tseed.fZref[0];
1649 Double_t zcor = tseed.fTilt*(tseed.fZProb-tseed.fZref[0]);
1651 Float_t roadz = padlength[bLayer]+1;
1652 if (TMath::Abs(tseed.fZProb-zexp)> padlength[bLayer]*0.5) {roadz = padlength[bLayer]*0.5;}
1653 if (tseed.fZfit[1]*tseed.fZref[1]<0) {roadz = padlength[bLayer]*0.5;}
1654 if (TMath::Abs(tseed.fZProb-zexp)<0.1*padlength[bLayer]) {
1655 zexp = tseed.fZProb;
1656 roadz = padlength[bLayer]*0.5;
1659 Double_t yexp = tseed.fYref[0]+
1660 tseed.fYref[1]*dxlayer-zcor;
1661 Int_t index = layer.FindNearestCluster(yexp,zexp,kRoad1y, roadz);
1662 if (index<=0) continue;
1663 AliTRDcluster *cl = (AliTRDcluster*)GetCluster(index);
1665 tseed.fIndexes[iTime] = index;
1666 tseed.fClusters[iTime] = cl; // register cluster
1667 tseed.fX[iTime] = dxlayer; // register cluster
1668 tseed.fY[iTime] = cl->GetY(); // register cluster
1669 tseed.fZ[iTime] = cl->GetZ(); // register cluster
1673 Float_t dangle = tseed.fYfit[1]-tseed.fYref[1];
1674 Double_t zcor = tseed.fTilt*(tseed.fZProb-tseed.fZref[0]);
1676 Float_t tquality = (18-tseed.fN2)/2. + TMath::Abs(dangle)/0.1+
1677 TMath::Abs(tseed.fYfit[0]-(tseed.fYref[0]-zcor))/0.2+
1678 2.*TMath::Abs(tseed.fMeanz-tseed.fZref[0])/padlength[jLayer];
1680 if (tquality<squality[bLayer])
1681 bseed[bLayer] = tseed;
1684 chi2 = AliTRDseed::FitRiemanTilt(bseed, kTRUE);
1692 for (Int_t iLayer=0;iLayer<6;iLayer++) {
1693 if (TMath::Abs(cseed[iLayer].fYref[0]/cseed[iLayer].fX0)<0.15)
1695 if (cseed[iLayer].IsOK()){
1696 nclusters+=cseed[iLayer].fN2;
1700 if (nlayers<3) continue;
1702 for (Int_t iLayer=0;iLayer<6;iLayer++){
1703 if (cseed[iLayer].IsOK()) rieman.AddPoint(xcl[iLayer],cseed[iLayer].fYfitR[0],
1704 cseed[iLayer].fZProb,1,10);
1710 for (Int_t iLayer=0;iLayer<6;iLayer++){
1711 if (cseed[iLayer].IsOK()){
1712 cseed[iLayer].fYref[0] = rieman.GetYat(xcl[iLayer]);
1713 chi2RF += (cseed[iLayer].fYref[0]-cseed[iLayer].fYfitR[0])*
1714 (cseed[iLayer].fYref[0]-cseed[iLayer].fYfitR[0]);
1715 cseed[iLayer].fYref[1] = rieman.GetDYat(xcl[iLayer]);
1716 cseed[iLayer].fZref[0] = rieman.GetZat(xcl[iLayer]);
1717 chi2ZF += (cseed[iLayer].fZref[0]- cseed[iLayer].fMeanz)*
1718 (cseed[iLayer].fZref[0]- cseed[iLayer].fMeanz);
1719 cseed[iLayer].fZref[1] = rieman.GetDZat(xcl[iLayer]);
1722 chi2RF/=TMath::Max((nlayers-3.),1.);
1723 chi2ZF/=TMath::Max((nlayers-3.),1.);
1724 curv = rieman.GetC();
1728 Double_t xref2 = (xcl[2]+xcl[3])*0.5; // middle of the chamber
1729 Double_t dzmf = rieman.GetDZat(xref2);
1730 Double_t zmf = rieman.GetZat(xref2);
1735 fitterTC.ClearPoints();
1736 fitterT2.ClearPoints();
1738 for (Int_t iLayer=0; iLayer<6;iLayer++){
1739 if (!cseed[iLayer].IsOK()) continue;
1740 for (Int_t itime=0;itime<25;itime++){
1741 if (!cseed[iLayer].fUsable[itime]) continue;
1742 Double_t x = cseed[iLayer].fX[itime]+cseed[iLayer].fX0-xref2; // x relative to the midle chamber
1743 Double_t y = cseed[iLayer].fY[itime];
1744 Double_t z = cseed[iLayer].fZ[itime];
1745 // ExB correction to the correction
1749 Double_t x2 = cseed[iLayer].fX[itime]+cseed[iLayer].fX0; // global x
1751 Double_t t = 1./(x2*x2+y*y);
1753 uvt[0] = 2.*x2*uvt[1]; // u
1755 uvt[2] = 2.0*hL[iLayer]*uvt[1];
1756 uvt[3] = 2.0*hL[iLayer]*x*uvt[1];
1757 uvt[4] = 2.0*(y+hL[iLayer]*z)*uvt[1];
1759 Double_t error = 2*0.2*uvt[1];
1760 fitterT2.AddPoint(uvt,uvt[4],error);
1762 // constrained rieman
1764 z =cseed[iLayer].fZ[itime];
1765 uvt[0] = 2.*x2*t; // u
1766 uvt[1] = 2*hL[iLayer]*x2*uvt[1];
1767 uvt[2] = 2*(y+hL[iLayer]*(z-GetZ()))*t;
1768 fitterTC.AddPoint(uvt,uvt[2],error);
1770 rieman2.AddPoint(x2,y,z,1,10);
1777 Double_t rpolz0 = fitterT2.GetParameter(3);
1778 Double_t rpolz1 = fitterT2.GetParameter(4);
1780 // linear fitter - not possible to make boundaries
1781 // non accept non possible z and dzdx combination
1783 Bool_t acceptablez =kTRUE;
1784 for (Int_t iLayer=0; iLayer<6;iLayer++){
1785 if (cseed[iLayer].IsOK()){
1786 Double_t zT2 = rpolz0+rpolz1*(xcl[iLayer] - xref2);
1787 if (TMath::Abs(cseed[iLayer].fZProb-zT2)>padlength[iLayer]*0.5+1)
1788 acceptablez = kFALSE;
1792 fitterT2.FixParameter(3,zmf);
1793 fitterT2.FixParameter(4,dzmf);
1795 fitterT2.ReleaseParameter(3);
1796 fitterT2.ReleaseParameter(4);
1797 rpolz0 = fitterT2.GetParameter(3);
1798 rpolz1 = fitterT2.GetParameter(4);
1801 Double_t chi2TR = fitterT2.GetChisquare()/Float_t(npointsT);
1802 Double_t chi2TC = fitterTC.GetChisquare()/Float_t(npointsT);
1804 Double_t polz1c = fitterTC.GetParameter(2);
1805 Double_t polz0c = polz1c*xref2;
1807 Double_t aC = fitterTC.GetParameter(0);
1808 Double_t bC = fitterTC.GetParameter(1);
1809 Double_t cC = aC/TMath::Sqrt(bC*bC+1.); // curvature
1811 Double_t aR = fitterT2.GetParameter(0);
1812 Double_t bR = fitterT2.GetParameter(1);
1813 Double_t dR = fitterT2.GetParameter(2);
1814 Double_t cR = 1+bR*bR-dR*aR;
1817 dca = -dR/(TMath::Sqrt(1+bR*bR-dR*aR)+TMath::Sqrt(1+bR*bR));
1818 cR = aR/TMath::Sqrt(cR);
1821 Double_t chi2ZT2=0, chi2ZTC=0;
1822 for (Int_t iLayer=0; iLayer<6;iLayer++){
1823 if (cseed[iLayer].IsOK()){
1824 Double_t zT2 = rpolz0+rpolz1*(xcl[iLayer] - xref2);
1825 Double_t zTC = polz0c+polz1c*(xcl[iLayer] - xref2);
1826 chi2ZT2 += TMath::Abs(cseed[iLayer].fMeanz-zT2);
1827 chi2ZTC += TMath::Abs(cseed[iLayer].fMeanz-zTC);
1830 chi2ZT2/=TMath::Max((nlayers-3.),1.);
1831 chi2ZTC/=TMath::Max((nlayers-3.),1.);
1835 AliTRDseed::FitRiemanTilt(cseed, kTRUE);
1837 for (Int_t iLayer=0;iLayer<6;iLayer++){
1838 if (cseed[iLayer].IsOK())
1839 sumdaf += TMath::Abs((cseed[iLayer].fYfit[1]-cseed[iLayer].fYref[1])/cseed[iLayer].fSigmaY2);
1841 sumdaf /= Float_t (nlayers-2.);
1843 // likelihoods for full track
1845 Double_t likezf = TMath::Exp(-chi2ZF*0.14);
1846 Double_t likechi2C = TMath::Exp(-chi2TC*0.677);
1847 Double_t likechi2TR = TMath::Exp(-chi2TR*0.78);
1848 Double_t likeaf = TMath::Exp(-sumdaf*3.23);
1849 seedquality2[registered] = likezf*likechi2TR*likeaf;
1850 // Bool_t isGold = kFALSE;
1852 // if (nlayers == 6 && TMath::Log(0.000000001+seedquality2[index])<-5.) isGold =kTRUE; // gold
1853 // if (nlayers == findable && TMath::Log(0.000000001+seedquality2[index])<-4.) isGold =kTRUE; // gold
1854 // if (isGold &&nusedf<10){
1855 // for (Int_t jLayer=0;jLayer<6;jLayer++){
1856 // if ( seed[index][jLayer].IsOK()&&TMath::Abs(seed[index][jLayer].fYfit[1]-seed[index][jLayer].fYfit[1])<0.1)
1857 // seed[index][jLayer].UseClusters(); //sign gold
1864 if (!cseed[0].IsOK()){
1866 if (!cseed[1].IsOK()) index0 = 2;
1868 seedparams[registered][0] = cseed[index0].fX0;
1869 seedparams[registered][1] = cseed[index0].fYref[0];
1870 seedparams[registered][2] = cseed[index0].fZref[0];
1871 seedparams[registered][5] = cR;
1872 seedparams[registered][3] = cseed[index0].fX0*cR - TMath::Sin(TMath::ATan(cseed[0].fYref[1]));
1873 seedparams[registered][4] = cseed[index0].fZref[1]/
1874 TMath::Sqrt(1+cseed[index0].fYref[1]*cseed[index0].fYref[1]);
1875 seedparams[registered][6] = ns;
1878 Int_t labels[12], outlab[24];
1880 for (Int_t iLayer=0;iLayer<6;iLayer++){
1881 if (!cseed[iLayer].IsOK()) continue;
1882 if (cseed[iLayer].fLabels[0]>=0) {
1883 labels[nlab] = cseed[iLayer].fLabels[0];
1886 if (cseed[iLayer].fLabels[1]>=0) {
1887 labels[nlab] = cseed[iLayer].fLabels[1];
1891 Freq(nlab,labels,outlab,kFALSE);
1892 Int_t label = outlab[0];
1893 Int_t frequency = outlab[1];
1894 for (Int_t iLayer=0;iLayer<6;iLayer++){
1895 cseed[iLayer].fFreq = frequency;
1896 cseed[iLayer].fC = cR;
1897 cseed[iLayer].fCC = cC;
1898 cseed[iLayer].fChi2 = chi2TR;
1899 cseed[iLayer].fChi2Z = chi2ZF;
1902 if (1||(!isFake)){ //debugging print
1903 Float_t zvertex = GetZ();
1904 TTreeSRedirector& cstream = *fDebugStreamer;
1905 if (AliTRDReconstructor::StreamLevel()>0)
1908 "Vertex="<<zvertex<<
1909 "Rieman2.="<<&rieman2<<
1910 "Rieman.="<<&rieman<<
1920 "Chi2RF="<<chi2RF<< //chi2 of trackletes on full track
1921 "Chi2ZF="<<chi2ZF<< //chi2 z on tracklets on full track
1922 "Chi2ZT2="<<chi2ZT2<< //chi2 z on tracklets on full track - rieman tilt
1923 "Chi2ZTC="<<chi2ZTC<< //chi2 z on tracklets on full track - rieman tilt const
1925 "Chi2TR="<<chi2TR<< //chi2 without vertex constrain
1926 "Chi2TC="<<chi2TC<< //chi2 with vertex constrain
1927 "C="<<curv<< // non constrained - no tilt correction
1928 "DR="<<dR<< // DR parameter - tilt correction
1929 "DCA="<<dca<< // DCA - tilt correction
1930 "CR="<<cR<< // non constrained curvature - tilt correction
1931 "CC="<<cC<< // constrained curvature
1937 "Nlayers="<<nlayers<<
1938 "NUsedS="<<nusedCl<<
1940 "Findable="<<findable<<
1942 "LikePrim="<<likePrim<<
1943 "Likechi2C="<<likechi2C<<
1944 "Likechi2TR="<<likechi2TR<<
1946 "LikeF="<<seedquality2[registered]<<
1953 "SB0.="<<&seedb[0]<<
1954 "SB1.="<<&seedb[1]<<
1955 "SB2.="<<&seedb[2]<<
1956 "SB3.="<<&seedb[3]<<
1957 "SB4.="<<&seedb[4]<<
1958 "SB5.="<<&seedb[5]<<
1960 "Freq="<<frequency<<
1964 if (registered<kMaxSeed-1) {
1966 cseed = seed[registered];
1968 }// end of loop over layer 1
1969 } // end of loop over layer 0
1970 } // end of loop over layer 3
1971 } // end of loop over seeding time bins
1975 TMath::Sort(registered,seedquality2,sort,kTRUE);
1976 Bool_t signedseed[kMaxSeed];
1977 for (Int_t i=0;i<registered;i++){
1978 signedseed[i]= kFALSE;
1980 for (Int_t iter=0; iter<5; iter++){
1981 for (Int_t iseed=0;iseed<registered;iseed++){
1982 Int_t index = sort[iseed];
1983 if (signedseed[index]) continue;
1984 Int_t labelsall[1000];
1987 Int_t sLayer = seedlayer[index];
1992 for (Int_t jLayer=0;jLayer<6;jLayer++){
1993 if (TMath::Abs(seed[index][jLayer].fYref[0]/xcl[jLayer])<0.15)
1995 if (seed[index][jLayer].IsOK()){
1996 seed[index][jLayer].UpdateUsed();
1997 ncl +=seed[index][jLayer].fN2;
1998 nused +=seed[index][jLayer].fNUsed;
2001 for (Int_t itime=0;itime<25;itime++){
2002 if (seed[index][jLayer].fUsable[itime]){
2004 for (Int_t ilab=0;ilab<3;ilab++){
2005 Int_t tindex = seed[index][jLayer].fClusters[itime]->GetLabel(ilab);
2007 labelsall[nlabelsall] = tindex;
2016 if (nused>30) continue;
2019 if (nlayers<6) continue;
2020 if (TMath::Log(0.000000001+seedquality2[index])<-5.) continue; // gold
2024 if (nlayers<findable) continue;
2025 if (TMath::Log(0.000000001+seedquality2[index])<-4.) continue; //
2030 if (nlayers==findable || nlayers==6) continue;
2031 if (TMath::Log(0.000000001+seedquality2[index])<-6.) continue;
2035 if (TMath::Log(0.000000001+seedquality2[index])<-5.) continue;
2039 if (TMath::Log(0.000000001+seedquality2[index])-nused/(nlayers-3.)<-15.) continue;
2042 signedseed[index] = kTRUE;
2044 Int_t labels[1000], outlab[1000];
2046 for (Int_t iLayer=0;iLayer<6;iLayer++){
2047 if (seed[index][iLayer].IsOK()){
2048 if (seed[index][iLayer].fLabels[0]>=0) {
2049 labels[nlab] = seed[index][iLayer].fLabels[0];
2052 if (seed[index][iLayer].fLabels[1]>=0) {
2053 labels[nlab] = seed[index][iLayer].fLabels[1];
2058 Freq(nlab,labels,outlab,kFALSE);
2059 Int_t label = outlab[0];
2060 Int_t frequency = outlab[1];
2061 Freq(nlabelsall,labelsall,outlab,kFALSE);
2062 Int_t label1 = outlab[0];
2063 Int_t label2 = outlab[2];
2064 Float_t fakeratio = (naccepted-outlab[1])/Float_t(naccepted);
2065 Float_t ratio = Float_t(nused)/Float_t(ncl);
2067 for (Int_t jLayer=0;jLayer<6;jLayer++){
2068 if ( seed[index][jLayer].IsOK()&&TMath::Abs(seed[index][jLayer].fYfit[1]-seed[index][jLayer].fYfit[1])<0.2 )
2069 seed[index][jLayer].UseClusters(); //sign gold
2073 Int_t eventNr = esd->GetEventNumber();
2074 TTreeSRedirector& cstream = *fDebugStreamer;
2078 AliTRDtrack * track = RegisterSeed(seed[index],seedparams[index]);
2080 if (!track) track=&dummy;
2082 AliESDtrack esdtrack;
2083 esdtrack.UpdateTrackParams(track, AliESDtrack::kTRDout);
2084 esdtrack.SetLabel(label);
2085 esd->AddTrack(&esdtrack);
2086 TTreeSRedirector& cstream = *fDebugStreamer;
2087 if (AliTRDReconstructor::StreamLevel()>0)
2089 "EventNr="<<eventNr<<
2090 "ESD.="<<&esdtrack<<
2092 "trdback.="<<track<<
2095 if (AliTRDReconstructor::StreamLevel()>0)
2099 "Like="<<seedquality[index]<<
2100 "LikeF="<<seedquality2[index]<<
2101 "S0.="<<&seed[index][0]<<
2102 "S1.="<<&seed[index][1]<<
2103 "S2.="<<&seed[index][2]<<
2104 "S3.="<<&seed[index][3]<<
2105 "S4.="<<&seed[index][4]<<
2106 "S5.="<<&seed[index][5]<<
2110 "FakeRatio="<<fakeratio<<
2111 "Freq="<<frequency<<
2113 "Nlayers="<<nlayers<<
2114 "Findable="<<findable<<
2117 "EventNr="<<eventNr<<
2121 } // end of loop over sectors
2127 //_____________________________________________________________________________
2128 Int_t AliTRDtracker::ReadClusters(TObjArray *array, TTree *ClusterTree) const
2131 // Reads AliTRDclusters (option >= 0) or AliTRDrecPoints (option < 0)
2132 // from the file. The names of the cluster tree and branches
2133 // should match the ones used in AliTRDclusterizer::WriteClusters()
2136 Int_t nsize = Int_t(ClusterTree->GetTotBytes()/(sizeof(AliTRDcluster)));
2137 TObjArray *clusterArray = new TObjArray(nsize+1000);
2139 TBranch *branch=ClusterTree->GetBranch("TRDcluster");
2141 Error("ReadClusters","Can't get the branch !");
2144 branch->SetAddress(&clusterArray);
2146 Int_t nEntries = (Int_t) ClusterTree->GetEntries();
2147 // printf("found %d entries in %s.\n",nEntries,ClusterTree->GetName());
2149 // Loop through all entries in the tree
2151 AliTRDcluster *c = 0;
2153 for (Int_t iEntry = 0; iEntry < nEntries; iEntry++) {
2156 nbytes += ClusterTree->GetEvent(iEntry);
2158 // Get the number of points in the detector
2159 Int_t nCluster = clusterArray->GetEntriesFast();
2160 // printf("\r Read %d clusters from entry %d", nCluster, iEntry);
2162 // Loop through all TRD digits
2163 for (Int_t iCluster = 0; iCluster < nCluster; iCluster++) {
2164 c = (AliTRDcluster*)clusterArray->UncheckedAt(iCluster);
2165 AliTRDcluster *co = c;
2167 // delete clusterArray->RemoveAt(iCluster);
2168 clusterArray->RemoveAt(iCluster);
2171 // cout<<"Allocated"<<nsize<<"\tLoaded"<<array->GetEntriesFast()<<"\n";
2173 delete clusterArray;
2179 //_____________________________________________________________________________
2180 Bool_t AliTRDtracker::GetTrackPoint(Int_t index, AliTrackPoint& p) const
2183 // Get track space point with index i
2184 // Origin: C.Cheshkov
2187 AliTRDcluster *cl = (AliTRDcluster*)fClusters->UncheckedAt(index);
2188 Int_t idet = cl->GetDetector();
2189 Int_t isector = fGeom->GetSector(idet);
2190 Int_t ichamber= fGeom->GetChamber(idet);
2191 Int_t iplan = fGeom->GetPlane(idet);
2193 local[0]=GetX(isector,iplan,cl->GetLocalTimeBin());
2194 local[1]=cl->GetY();
2195 local[2]=cl->GetZ();
2197 fGeom->RotateBack(idet,local,global);
2198 p.SetXYZ(global[0],global[1],global[2]);
2199 AliAlignObj::ELayerID iLayer = AliAlignObj::kTRD1;
2202 iLayer = AliAlignObj::kTRD1;
2205 iLayer = AliAlignObj::kTRD2;
2208 iLayer = AliAlignObj::kTRD3;
2211 iLayer = AliAlignObj::kTRD4;
2214 iLayer = AliAlignObj::kTRD5;
2217 iLayer = AliAlignObj::kTRD6;
2220 Int_t modId = isector*fGeom->Ncham()+ichamber;
2221 UShort_t volid = AliAlignObj::LayerToVolUID(iLayer,modId);
2222 p.SetVolumeID(volid);
2228 //_____________________________________________________________________________
2229 void AliTRDtracker::CookLabel(AliKalmanTrack* pt, Float_t wrong) const
2232 // This cooks a label. Mmmmh, smells good...
2235 Int_t label=123456789, index, i, j;
2236 Int_t ncl=pt->GetNumberOfClusters();
2237 const Int_t kRange = fTrSec[0]->GetOuterTimeBin()+1;
2241 // Int_t s[kRange][2];
2242 Int_t **s = new Int_t* [kRange];
2243 for (i=0; i<kRange; i++) {
2244 s[i] = new Int_t[2];
2246 for (i=0; i<kRange; i++) {
2252 for (i=0; i<ncl; i++) {
2253 index=pt->GetClusterIndex(i);
2254 AliTRDcluster *c=(AliTRDcluster*)fClusters->UncheckedAt(index);
2260 for (i=0; i<ncl; i++) {
2261 index=pt->GetClusterIndex(i);
2262 AliTRDcluster *c=(AliTRDcluster*)fClusters->UncheckedAt(index);
2263 for (Int_t k=0; k<3; k++) {
2264 label=c->GetLabel(k);
2265 labelAdded=kFALSE; j=0;
2267 while ( (!labelAdded) && ( j < kRange ) ) {
2268 if (s[j][0]==label || s[j][1]==0) {
2282 for (i=0; i<kRange; i++) {
2284 max=s[i][1]; label=s[i][0];
2288 for (i=0; i<kRange; i++) {
2294 if ((1.- Float_t(max)/ncl) > wrong) label=-label;
2296 pt->SetLabel(label);
2300 //_____________________________________________________________________________
2301 void AliTRDtracker::UseClusters(const AliKalmanTrack* t, Int_t from) const
2304 // Use clusters, but don't abuse them!
2307 const Float_t kmaxchi2 =18;
2308 const Float_t kmincl =10;
2309 AliTRDtrack * track = (AliTRDtrack*)t;
2311 Int_t ncl=t->GetNumberOfClusters();
2312 for (Int_t i=from; i<ncl; i++) {
2313 Int_t index = t->GetClusterIndex(i);
2314 AliTRDcluster *c=(AliTRDcluster*)fClusters->UncheckedAt(index);
2316 Int_t iplane = fGeom->GetPlane(c->GetDetector());
2317 if (track->fTracklets[iplane].GetChi2()>kmaxchi2) continue;
2318 if (track->fTracklets[iplane].GetN()<kmincl) continue;
2319 if (!(c->IsUsed())) c->Use();
2324 //_____________________________________________________________________________
2325 Double_t AliTRDtracker::ExpectedSigmaY2(Double_t , Double_t , Double_t ) const
2328 // Parametrised "expected" error of the cluster reconstruction in Y
2331 Double_t s = 0.08 * 0.08;
2336 //_____________________________________________________________________________
2337 Double_t AliTRDtracker::ExpectedSigmaZ2(Double_t , Double_t ) const
2340 // Parametrised "expected" error of the cluster reconstruction in Z
2343 Double_t s = 9 * 9 /12.;
2348 //_____________________________________________________________________________
2349 Double_t AliTRDtracker::GetX(Int_t sector, Int_t plane, Int_t localTB) const
2352 // Returns radial position which corresponds to time bin <localTB>
2353 // in tracking sector <sector> and plane <plane>
2356 Int_t index = fTrSec[sector]->CookTimeBinIndex(plane, localTB);
2357 Int_t pl = fTrSec[sector]->GetLayerNumber(index);
2358 return fTrSec[sector]->GetLayer(pl)->GetX();
2362 //_____________________________________________________________________________
2363 AliTRDtracker::AliTRDpropagationLayer
2364 ::AliTRDpropagationLayer(Double_t x, Double_t dx, Double_t rho
2365 , Double_t radLength, Int_t tbIndex, Int_t plane)
2368 // AliTRDpropagationLayer constructor
2371 fN = 0; fX = x; fdX = dx; fRho = rho; fX0 = radLength;
2372 fClusters = NULL; fIndex = NULL; fTimeBinIndex = tbIndex;
2375 for(Int_t i=0; i < (Int_t) kZones; i++) {
2376 fZc[i]=0; fZmax[i] = 0;
2381 if(fTimeBinIndex >= 0) {
2382 fClusters = new AliTRDcluster*[kMaxClusterPerTimeBin];
2383 fIndex = new UInt_t[kMaxClusterPerTimeBin];
2386 for (Int_t i=0;i<5;i++) fIsHole[i] = kFALSE;
2397 //_____________________________________________________________________________
2398 void AliTRDtracker::AliTRDpropagationLayer
2399 ::SetHole(Double_t Zmax, Double_t Ymax, Double_t rho
2400 , Double_t radLength, Double_t Yc, Double_t Zc)
2403 // Sets hole in the layer
2412 fHoleX0 = radLength;
2416 //_____________________________________________________________________________
2417 AliTRDtracker::AliTRDtrackingSector
2418 ::AliTRDtrackingSector(AliTRDgeometry* geo, Int_t gs)
2421 // AliTRDtrackingSector Constructor
2424 AliTRDpadPlane *padPlane = 0;
2430 // get holes description from geometry
2431 Bool_t holes[AliTRDgeometry::kNcham];
2432 //printf("sector\t%d\t",gs);
2433 for (Int_t icham=0; icham<AliTRDgeometry::kNcham;icham++){
2434 holes[icham] = fGeom->IsHole(0,icham,gs);
2435 //printf("%d",holes[icham]);
2439 for(UInt_t i=0; i < kMaxTimeBinIndex; i++) fTimeBinIndex[i] = -1;
2442 AliTRDpropagationLayer* ppl;
2444 Double_t x, dx, rho, radLength;
2447 // add layers for each of the planes
2448 Double_t dxAmp = (Double_t) fGeom->CamHght(); // Amplification region
2449 //Double_t dxDrift = (Double_t) fGeom->CdrHght(); // Drift region
2452 const Int_t kNchambers = AliTRDgeometry::Ncham();
2454 Double_t ymaxsensitive=0;
2455 Double_t *zc = new Double_t[kNchambers];
2456 Double_t *zmax = new Double_t[kNchambers];
2457 Double_t *zmaxsensitive = new Double_t[kNchambers];
2459 AliTRDCommonParam* commonParam = AliTRDCommonParam::Instance();
2462 printf("<AliTRDtracker::AliTRDtrackingSector::AliTRDtrackingSector> ");
2463 printf("Could not get common params\n");
2467 for(Int_t plane = 0; plane < AliTRDgeometry::Nplan(); plane++) {
2469 ymax = fGeom->GetChamberWidth(plane)/2.;
2470 // Modidified for new pad plane class, 22.04.05 (C.B.)
2471 padPlane = commonParam->GetPadPlane(plane,0);
2472 ymaxsensitive = (padPlane->GetColSize(1)*padPlane->GetNcols()-4)/2.;
2473 for(Int_t ch = 0; ch < kNchambers; ch++) {
2474 zmax[ch] = fGeom->GetChamberLength(plane,ch)/2;
2476 // Modidified for new pad plane class, 22.04.05 (C.B.)
2477 Float_t pad = padPlane->GetRowSize(1);
2478 Float_t row0 = commonParam->GetRow0(plane,ch,0);
2479 Int_t nPads = commonParam->GetRowMax(plane,ch,0);
2480 zmaxsensitive[ch] = Float_t(nPads)*pad/2.;
2481 zc[ch] = -(pad * nPads)/2 + row0;
2484 dx = AliTRDcalibDB::Instance()->GetVdrift(0,0,0)
2485 / AliTRDcalibDB::Instance()->GetSamplingFrequency();
2486 rho = 0.00295 * 0.85; radLength = 11.0;
2488 Double_t x0 = (Double_t) AliTRDgeometry::GetTime0(plane);
2489 //Double_t xbottom = x0 - dxDrift;
2490 //Double_t xtop = x0 + dxAmp;
2492 Int_t nTimeBins = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
2493 for (Int_t iTime = 0; iTime<nTimeBins; iTime++){
2494 Double_t xlayer = iTime*dx - dxAmp;
2495 //if (xlayer<0) xlayer=dxAmp/2.;
2498 tbIndex = CookTimeBinIndex(plane, iTime);
2499 ppl = new AliTRDpropagationLayer(x,dx,rho,radLength,tbIndex, plane);
2500 ppl->SetYmax(ymax,ymaxsensitive);
2501 ppl->SetZ(zc, zmax, zmaxsensitive);
2502 ppl->SetHoles(holes);
2510 delete [] zmaxsensitive;
2514 //_____________________________________________________________________________
2515 Int_t AliTRDtracker::AliTRDtrackingSector
2516 ::CookTimeBinIndex(Int_t plane, Int_t localTB) const
2519 // depending on the digitization parameters calculates "global"
2520 // time bin index for timebin <localTB> in plane <plane>
2524 Int_t tbPerPlane = AliTRDcalibDB::Instance()->GetNumberOfTimeBins();
2525 Int_t gtb = (plane+1) * tbPerPlane - localTB -1;
2526 if (localTB<0) return -1;
2527 if (gtb<0) return -1;
2533 //_____________________________________________________________________________
2534 void AliTRDtracker::AliTRDtrackingSector
2535 ::MapTimeBinLayers()
2538 // For all sensitive time bins sets corresponding layer index
2539 // in the array fTimeBins
2544 for(Int_t i = 0; i < fN; i++) {
2545 index = fLayers[i]->GetTimeBinIndex();
2547 // printf("gtb %d -> pl %d -> x %f \n", index, i, fLayers[i]->GetX());
2549 if(index < 0) continue;
2550 if(index >= (Int_t) kMaxTimeBinIndex) {
2551 printf("*** AliTRDtracker::MapTimeBinLayers: \n");
2552 printf(" index %d exceeds allowed maximum of %d!\n",
2553 index, kMaxTimeBinIndex-1);
2556 fTimeBinIndex[index] = i;
2561 //_____________________________________________________________________________
2562 Int_t AliTRDtracker::AliTRDtrackingSector
2563 ::GetLayerNumber(Double_t x) const
2566 // Returns the number of time bin which in radial position is closest to <x>
2569 if(x >= fLayers[fN-1]->GetX()) return fN-1;
2570 if(x <= fLayers[0]->GetX()) return 0;
2572 Int_t b=0, e=fN-1, m=(b+e)/2;
2573 for (; b<e; m=(b+e)/2) {
2574 if (x > fLayers[m]->GetX()) b=m+1;
2577 if(TMath::Abs(x - fLayers[m]->GetX()) >
2578 TMath::Abs(x - fLayers[m+1]->GetX())) return m+1;
2584 //_____________________________________________________________________________
2585 Int_t AliTRDtracker::AliTRDtrackingSector
2586 ::GetInnerTimeBin() const
2589 // Returns number of the innermost SENSITIVE propagation layer
2592 return GetLayerNumber(0);
2596 //_____________________________________________________________________________
2597 Int_t AliTRDtracker::AliTRDtrackingSector
2598 ::GetOuterTimeBin() const
2601 // Returns number of the outermost SENSITIVE time bin
2604 return GetLayerNumber(GetNumberOfTimeBins() - 1);
2608 //_____________________________________________________________________________
2609 Int_t AliTRDtracker::AliTRDtrackingSector
2610 ::GetNumberOfTimeBins() const
2613 // Returns number of SENSITIVE time bins
2617 for(tb = kMaxTimeBinIndex-1; tb >=0; tb--) {
2618 layer = GetLayerNumber(tb);
2626 //_____________________________________________________________________________
2627 void AliTRDtracker::AliTRDtrackingSector
2628 ::InsertLayer(AliTRDpropagationLayer* pl)
2631 // Insert layer <pl> in fLayers array.
2632 // Layers are sorted according to X coordinate.
2635 if ( fN == ((Int_t) kMaxLayersPerSector)) {
2636 printf("AliTRDtrackingSector::InsertLayer(): Too many layers !\n");
2639 if (fN==0) {fLayers[fN++] = pl; return;}
2640 Int_t i=Find(pl->GetX());
2642 memmove(fLayers+i+1 ,fLayers+i,(fN-i)*sizeof(AliTRDpropagationLayer*));
2643 fLayers[i]=pl; fN++;
2647 //_____________________________________________________________________________
2648 Int_t AliTRDtracker::AliTRDtrackingSector
2649 ::Find(Double_t x) const
2652 // Returns index of the propagation layer nearest to X
2655 if (x <= fLayers[0]->GetX()) return 0;
2656 if (x > fLayers[fN-1]->GetX()) return fN;
2657 Int_t b=0, e=fN-1, m=(b+e)/2;
2658 for (; b<e; m=(b+e)/2) {
2659 if (x > fLayers[m]->GetX()) b=m+1;
2667 //_____________________________________________________________________________
2668 void AliTRDtracker::AliTRDpropagationLayer
2669 ::SetZ(Double_t* center, Double_t *w, Double_t *wsensitive )
2672 // set centers and the width of sectors
2675 for (Int_t icham=0;icham< AliTRDgeometry::kNcham;icham++){
2676 fZc[icham] = center[icham];
2677 fZmax[icham] = w[icham];
2678 fZmaxSensitive[icham] = wsensitive[icham];
2679 // printf("chamber\t%d\tzc\t%f\tzmax\t%f\tzsens\t%f\n",icham,fZc[icham],fZmax[icham],fZmaxSensitive[icham]);
2684 //_____________________________________________________________________________
2685 void AliTRDtracker::AliTRDpropagationLayer::SetHoles(Bool_t *holes)
2688 // set centers and the width of sectors
2692 for (Int_t icham=0;icham< AliTRDgeometry::kNcham;icham++){
2693 fIsHole[icham] = holes[icham];
2694 if (holes[icham]) fHole = kTRUE;
2699 //_____________________________________________________________________________
2700 void AliTRDtracker::AliTRDpropagationLayer
2701 ::InsertCluster(AliTRDcluster* c, UInt_t index)
2704 // Insert cluster in cluster array.
2705 // Clusters are sorted according to Y coordinate.
2708 if(fTimeBinIndex < 0) {
2709 printf("*** attempt to insert cluster into non-sensitive time bin!\n");
2713 if (fN== (Int_t) kMaxClusterPerTimeBin) {
2714 printf("AliTRDpropagationLayer::InsertCluster(): Too many clusters !\n");
2717 if (fN==0) {fIndex[0]=index; fClusters[fN++]=c; return;}
2718 Int_t i=Find(c->GetY());
2719 memmove(fClusters+i+1 ,fClusters+i,(fN-i)*sizeof(AliTRDcluster*));
2720 memmove(fIndex +i+1 ,fIndex +i,(fN-i)*sizeof(UInt_t));
2721 fIndex[i]=index; fClusters[i]=c; fN++;
2725 //_____________________________________________________________________________
2726 Int_t AliTRDtracker::AliTRDpropagationLayer::Find(Float_t y) const
2729 // Returns index of the cluster nearest in Y
2732 if (fN<=0) return 0;
2733 if (y <= fClusters[0]->GetY()) return 0;
2734 if (y > fClusters[fN-1]->GetY()) return fN;
2735 Int_t b=0, e=fN-1, m=(b+e)/2;
2736 for (; b<e; m=(b+e)/2) {
2737 if (y > fClusters[m]->GetY()) b=m+1;
2745 //_____________________________________________________________________________
2746 Int_t AliTRDtracker::AliTRDpropagationLayer
2747 ::FindNearestCluster(Float_t y, Float_t z, Float_t maxroad
2748 , Float_t maxroadz) const
2751 // Returns index of the cluster nearest to the given y,z
2756 Float_t mindist = maxroad;
2758 for (Int_t i=Find(y-maxroad); i<maxn; i++) {
2759 AliTRDcluster* c=(AliTRDcluster*)(fClusters[i]);
2760 Float_t ycl = c->GetY();
2762 if (ycl > y+maxroad) break;
2763 if (TMath::Abs(c->GetZ()-z) > maxroadz) continue;
2764 if (TMath::Abs(ycl-y)<mindist){
2765 mindist = TMath::Abs(ycl-y);
2774 //_____________________________________________________________________________
2775 Double_t AliTRDtracker::GetTiltFactor(const AliTRDcluster* c)
2778 // Returns correction factor for tilted pads geometry
2781 Int_t det = c->GetDetector();
2782 Int_t plane = fGeom->GetPlane(det);
2783 AliTRDpadPlane *padPlane = AliTRDCommonParam::Instance()->GetPadPlane(plane,0);
2784 Double_t h01 = TMath::Tan(-TMath::Pi() / 180.0 * padPlane->GetTiltingAngle());
2786 if(fNoTilt) h01 = 0;
2792 //_____________________________________________________________________________
2793 void AliTRDtracker::CookdEdxTimBin(AliTRDtrack& TRDtrack)
2796 // *** ADDED TO GET MORE INFORMATION FOR TRD PID ---- PS
2797 // This is setting fdEdxPlane and fTimBinPlane
2798 // Sums up the charge in each plane for track TRDtrack and also get the
2799 // Time bin for Max. Cluster
2800 // Prashant Shukla (shukla@physi.uni-heidelberg.de)
2803 Double_t clscharge[AliESDtrack::kNPlane][AliESDtrack::kNSlice];
2804 Double_t maxclscharge[AliESDtrack::kNPlane];
2805 Int_t nCluster[AliESDtrack::kNPlane][AliESDtrack::kNSlice];
2806 Int_t timebin[AliESDtrack::kNPlane];
2808 //Initialization of cluster charge per plane.
2809 for (Int_t iPlane = 0; iPlane < AliESDtrack::kNPlane; iPlane++) {
2810 for (Int_t iSlice = 0; iSlice < AliESDtrack::kNSlice; iSlice++) {
2811 clscharge[iPlane][iSlice] = 0.0;
2812 nCluster[iPlane][iSlice] = 0;
2816 //Initialization of cluster charge per plane.
2817 for (Int_t iPlane = 0; iPlane < AliESDtrack::kNPlane; iPlane++) {
2818 timebin[iPlane] = -1;
2819 maxclscharge[iPlane] = 0.0;
2822 // Loop through all clusters associated to track TRDtrack
2823 Int_t nClus = TRDtrack.GetNumberOfClusters(); // from Kalmantrack
2824 for (Int_t iClus = 0; iClus < nClus; iClus++) {
2825 Double_t charge = TRDtrack.GetClusterdQdl(iClus);
2826 Int_t index = TRDtrack.GetClusterIndex(iClus);
2827 AliTRDcluster *pTRDcluster = (AliTRDcluster *) GetCluster(index);
2828 if (!pTRDcluster) continue;
2829 Int_t tb = pTRDcluster->GetLocalTimeBin();
2831 Int_t detector = pTRDcluster->GetDetector();
2832 Int_t iPlane = fGeom->GetPlane(detector);
2833 Int_t iSlice = tb*AliESDtrack::kNSlice/AliTRDtrack::kNtimeBins;
2834 clscharge[iPlane][iSlice] = clscharge[iPlane][iSlice]+charge;
2835 if(charge > maxclscharge[iPlane]) {
2836 maxclscharge[iPlane] = charge;
2837 timebin[iPlane] = tb;
2839 nCluster[iPlane][iSlice]++;
2840 } // end of loop over cluster
2842 // Setting the fdEdxPlane and fTimBinPlane variabales
2843 Double_t totalCharge = 0;
2845 for (Int_t iPlane = 0; iPlane < AliESDtrack::kNPlane; iPlane++) {
2846 for (Int_t iSlice = 0; iSlice < AliESDtrack::kNSlice; iSlice++) {
2847 if (nCluster[iPlane][iSlice]) clscharge[iPlane][iSlice] /= nCluster[iPlane][iSlice];
2848 TRDtrack.SetPIDsignals(clscharge[iPlane][iSlice], iPlane, iSlice);
2849 totalCharge= totalCharge+clscharge[iPlane][iSlice];
2851 TRDtrack.SetPIDTimBin(timebin[iPlane], iPlane);
2855 // Int_t nc=TRDtrack.GetNumberOfClusters();
2857 // for (i=0; i<nc; i++) dedx += TRDtrack.GetClusterdQdl(i);
2859 // for (Int_t iPlane = 0; iPlane < kNPlane; iPlane++) {
2860 // TRDtrack.SetPIDsignals(dedx, iPlane);
2861 // TRDtrack.SetPIDTimBin(timbin[iPlane], iPlane);
2866 //_____________________________________________________________________________
2867 Int_t AliTRDtracker::FindClusters(Int_t sector, Int_t t0, Int_t t1
2868 , AliTRDtrack * track
2869 , Int_t *clusters,AliTRDtracklet&tracklet)
2873 // Try to find nearest clusters to the track in timebins from t0 to t1
2877 // correction coeficients - depends on TRD parameters - to be changed according it
2880 Double_t x[100],yt[100],zt[100];
2881 Double_t xmean=0; //reference x
2882 Double_t dz[10][100],dy[10][100];
2883 Float_t zmean[100], nmean[100];
2885 Int_t indexes[10][100]; // indexes of the clusters in the road
2886 AliTRDcluster *cl[10][100]; // pointers to the clusters in the road
2887 Int_t best[10][100]; // index of best matching cluster
2891 for (Int_t it=0;it<100; it++){
2899 for (Int_t ih=0;ih<10;ih++){
2900 indexes[ih][it]=-2; //reset indexes1
2908 Double_t x0 = track->GetX();
2909 Double_t sigmaz = TMath::Sqrt(TMath::Abs(track->GetSigmaZ2()));
2915 Float_t padlength=0;
2916 AliTRDtrack track2(*track);
2917 Float_t snpy = track->GetSnp();
2918 Float_t tany = TMath::Sqrt(snpy*snpy/(1.-snpy*snpy));
2919 if (snpy<0) tany*=-1;
2921 Double_t sy2=ExpectedSigmaY2(x0,track->GetTgl(),track->GetPt());
2922 Double_t sz2=ExpectedSigmaZ2(x0,track->GetTgl());
2923 Double_t road = 15.*sqrt(track->GetSigmaY2() + sy2);
2924 if (road>6.) road=6.;
2927 for (Int_t it=0;it<t1-t0;it++){
2928 Double_t maxChi2[2]={fgkMaxChi2,fgkMaxChi2};
2929 AliTRDpropagationLayer& timeBin=*(fTrSec[sector]->GetLayer(it+t0));
2930 if (timeBin==0) continue; // no indexes1
2931 Int_t maxn = timeBin;
2932 x[it] = timeBin.GetX();
2933 track2.PropagateTo(x[it]);
2934 yt[it] = track2.GetY();
2935 zt[it] = track2.GetZ();
2937 Double_t y=yt[it],z=zt[it];
2938 Double_t chi2 =1000000;
2941 // find 2 nearest cluster at given time bin
2944 for (Int_t i=timeBin.Find(y-road); i<maxn; i++) {
2945 AliTRDcluster* c=(AliTRDcluster*)(timeBin[i]);
2946 h01 = GetTiltFactor(c);
2948 Int_t det = c->GetDetector();
2949 plane = fGeom->GetPlane(det);
2950 padlength = TMath::Sqrt(c->GetSigmaZ2()*12.);
2952 // if (c->GetLocalTimeBin()==0) continue;
2953 if (c->GetY() > y+road) break;
2954 if((c->GetZ()-z)*(c->GetZ()-z) > 12. * sz2) continue;
2956 Double_t dist = TMath::Abs(c->GetZ()-z);
2957 if (dist> (0.5*padlength+6.*sigmaz)) continue; // 6 sigma boundary cut
2960 if (dist> (0.5*padlength-sigmaz)){ // sigma boundary cost function
2961 cost = (dist-0.5*padlength)/(2.*sigmaz);
2962 if (cost>-1) cost= (cost+1.)*(cost+1.);
2965 // Int_t label = TMath::Abs(track->GetLabel());
2966 // if (c->GetLabel(0)!=label && c->GetLabel(1)!=label&&c->GetLabel(2)!=label) continue;
2967 chi2=track2.GetPredictedChi2(c,h01)+cost;
2970 if (chi2 > maxChi2[1]) continue;
2971 detector = c->GetDetector();
2973 for (Int_t ih=2;ih<9; ih++){ //store the clusters in the road
2976 indexes[ih][it] =timeBin.GetIndex(i); // index - 9 - reserved for outliers
2981 if (chi2 <maxChi2[0]){
2982 maxChi2[1] = maxChi2[0];
2984 indexes[1][it] = indexes[0][it];
2985 cl[1][it] = cl[0][it];
2986 indexes[0][it] = timeBin.GetIndex(i);
2992 indexes[1][it] =timeBin.GetIndex(i);
3000 if (nfound<4) return 0;
3001 xmean /=Float_t(nfound); // middle x
3002 track2.PropagateTo(xmean); // propagate track to the center
3004 // choose one of the variants
3010 Double_t sumdy2 = 0;
3020 Double_t moffset[10]; // mean offset
3021 Double_t mean[10]; // mean value
3022 Double_t angle[10]; // angle
3024 Double_t smoffset[10]; // sigma of mean offset
3025 Double_t smean[10]; // sigma of mean value
3026 Double_t sangle[10]; // sigma of angle
3027 Double_t smeanangle[10]; // correlation
3029 Double_t sigmas[10];
3030 Double_t tchi2s[10]; // chi2s for tracklet
3032 for (Int_t it=0;it<10;it++) {
3038 moffset[it] = 0; // mean offset
3039 mean[it] = 0; // mean value
3040 angle[it] = 0; // angle
3042 smoffset[it] = 1e10; // sigma of mean offset
3043 smean[it] = 1e10; // sigma of mean value
3044 sangle[it] = 1e10; // sigma of angle
3045 smeanangle[it] = 0; // correlation
3048 tchi2s[it] = 1e10; // chi2s for tracklet
3055 for (Int_t it=0;it<t1-t0;it++){
3056 if (!cl[0][it]) continue;
3057 for (Int_t dt=-3;dt<=3;dt++){
3058 if (it+dt<0) continue;
3059 if (it+dt>t1-t0) continue;
3060 if (!cl[0][it+dt]) continue;
3061 zmean[it]+=cl[0][it+dt]->GetZ();
3064 zmean[it]/=nmean[it];
3067 for (Int_t it=0; it<t1-t0;it++){
3069 for (Int_t ih=0;ih<10;ih++){
3072 if (!cl[ih][it]) continue;
3073 Double_t xcluster = cl[ih][it]->GetX();
3074 Double_t ytrack,ztrack;
3075 track2.GetProlongation(xcluster, ytrack, ztrack );
3076 dz[ih][it] = cl[ih][it]->GetZ()- ztrack; // calculate distance from track in z
3077 dy[ih][it] = cl[ih][it]->GetY()+ dz[ih][it]*h01 -ytrack; // in y
3080 if (!cl[0][it]) continue;
3081 if (TMath::Abs(cl[0][it]->GetZ()-zmean[it])> padlength*0.8 &&cl[1][it])
3082 if (TMath::Abs(cl[1][it]->GetZ()-zmean[it])< padlength*0.5){
3087 // iterative choosing of "best path"
3090 Int_t label = TMath::Abs(track->GetLabel());
3093 for (Int_t iter=0;iter<9;iter++){
3096 sumz = 0; sum=0; sumdy=0;sumdy2=0;sumx=0;sumx2=0;sumxy=0;mpads=0; ngood[iter]=0; nbad[iter]=0;
3098 for (Int_t it=0;it<t1-t0;it++){
3099 if (!cl[best[iter][it]][it]) continue;
3100 //calculates pad-row changes
3101 Double_t zbefore= cl[best[iter][it]][it]->GetZ();
3102 Double_t zafter = cl[best[iter][it]][it]->GetZ();
3103 for (Int_t itd = it-1; itd>=0;itd--) {
3104 if (cl[best[iter][itd]][itd]) {
3105 zbefore= cl[best[iter][itd]][itd]->GetZ();
3109 for (Int_t itd = it+1; itd<t1-t0;itd++) {
3110 if (cl[best[iter][itd]][itd]) {
3111 zafter= cl[best[iter][itd]][itd]->GetZ();
3115 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]++;
3117 Double_t dx = x[it]-xmean; // distance to reference x
3118 sumz += cl[best[iter][it]][it]->GetZ();
3120 sumdy += dy[best[iter][it]][it];
3121 sumdy2+= dy[best[iter][it]][it]*dy[best[iter][it]][it];
3124 sumxy += dx*dy[best[iter][it]][it];
3125 mpads += cl[best[iter][it]][it]->GetNPads();
3126 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){
3134 // calculates line parameters
3136 Double_t det = sum*sumx2-sumx*sumx;
3137 angle[iter] = (sum*sumxy-sumx*sumdy)/det;
3138 mean[iter] = (sumx2*sumdy-sumx*sumxy)/det;
3139 meanz[iter] = sumz/sum;
3140 moffset[iter] = sumdy/sum;
3141 mpads /= sum; // mean number of pads
3144 Double_t sigma2 = 0; // normalized residuals - for line fit
3145 Double_t sigma1 = 0; // normalized residuals - constant fit
3147 for (Int_t it=0;it<t1-t0;it++){
3148 if (!cl[best[iter][it]][it]) continue;
3149 Double_t dx = x[it]-xmean;
3150 Double_t ytr = mean[iter]+angle[iter]*dx;
3151 sigma2 += (dy[best[iter][it]][it]-ytr)*(dy[best[iter][it]][it]-ytr);
3152 sigma1 += (dy[best[iter][it]][it]-moffset[iter])*(dy[best[iter][it]][it]-moffset[iter]);
3155 sigma2 /=(sum-2); // normalized residuals
3156 sigma1 /=(sum-1); // normalized residuals
3158 smean[iter] = sigma2*(sumx2/det); // estimated error2 of mean
3159 sangle[iter] = sigma2*(sum/det); // estimated error2 of angle
3160 smeanangle[iter] = sigma2*(-sumx/det); // correlation
3163 sigmas[iter] = TMath::Sqrt(sigma1); //
3164 smoffset[iter]= (sigma1/sum)+0.01*0.01; // sigma of mean offset + unisochronity sigma
3166 // iterative choosing of "better path"
3168 for (Int_t it=0;it<t1-t0;it++){
3169 if (!cl[best[iter][it]][it]) continue;
3171 Double_t sigmatr2 = smoffset[iter]+0.5*tany*tany; //add unisochronity + angular effect contribution
3172 Double_t sweight = 1./sigmatr2+1./track->GetSigmaY2();
3173 Double_t weighty = (moffset[iter]/sigmatr2)/sweight; // weighted mean
3174 Double_t sigmacl = TMath::Sqrt(sigma1*sigma1+track->GetSigmaY2()); //
3175 Double_t mindist=100000;
3177 for (Int_t ih=0;ih<10;ih++){
3178 if (!cl[ih][it]) break;
3179 Double_t dist2 = (dy[ih][it]-weighty)/sigmacl;
3180 dist2*=dist2; //chi2 distance
3186 best[iter+1][it]=ihbest;
3189 // update best hypothesy if better chi2 according tracklet position and angle
3191 Double_t sy2 = smean[iter] + track->GetSigmaY2();
3192 Double_t sa2 = sangle[iter] + track->fCee;
3193 Double_t say = track->fCey;
3194 // Double_t chi20 = mean[bestiter]*mean[bestiter]/sy2+angle[bestiter]*angle[bestiter]/sa2;
3195 // Double_t chi21 = mean[iter]*mean[iter]/sy2+angle[iter]*angle[iter]/sa2;
3197 Double_t detchi = sy2*sa2-say*say;
3198 Double_t invers[3] = {sa2/detchi, sy2/detchi, -say/detchi}; //inverse value of covariance matrix
3200 Double_t chi20 = mean[bestiter]*mean[bestiter]*invers[0]+angle[bestiter]*angle[bestiter]*invers[1]+
3201 2.*mean[bestiter]*angle[bestiter]*invers[2];
3202 Double_t chi21 = mean[iter]*mean[iter]*invers[0]+angle[iter]*angle[iter]*invers[1]+
3203 2*mean[iter]*angle[iter]*invers[2];
3204 tchi2s[iter] =chi21;
3206 if (changes[iter]<=changes[bestiter] && chi21<chi20) {
3213 Double_t sigma2 = sigmas[0]; // choose as sigma from 0 iteration
3214 Short_t maxpos = -1;
3215 Float_t maxcharge = 0;
3216 Short_t maxpos4 = -1;
3217 Float_t maxcharge4 = 0;
3218 Short_t maxpos5 = -1;
3219 Float_t maxcharge5 = 0;
3221 //if (tchi2s[bestiter]>25.) sigma2*=tchi2s[bestiter]/25.;
3222 //if (tchi2s[bestiter]>25.) sigma2=1000.; // dont'accept
3224 Double_t exB = AliTRDcalibDB::Instance()->GetOmegaTau(AliTRDcalibDB::Instance()->GetVdrift(0,0,0));
3225 Double_t expectederr = sigma2*sigma2+0.01*0.01;
3226 if (mpads>3.5) expectederr += (mpads-3.5)*0.04;
3227 if (changes[bestiter]>1) expectederr+= changes[bestiter]*0.01;
3228 expectederr+=(0.03*(tany-exB)*(tany-exB))*15;
3229 // if (tchi2s[bestiter]>18.) expectederr*= tchi2s[bestiter]/18.;
3230 //expectederr+=10000;
3231 for (Int_t it=0;it<t1-t0;it++){
3232 if (!cl[best[bestiter][it]][it]) continue;
3233 cl[best[bestiter][it]][it]->SetSigmaY2(expectederr); // set cluster error
3234 if (!cl[best[bestiter][it]][it]->IsUsed()){
3235 cl[best[bestiter][it]][it]->SetY( cl[best[bestiter][it]][it]->GetY());
3236 // cl[best[bestiter][it]][it]->Use();
3239 // time bins with maximal charge
3240 if (TMath::Abs(cl[best[bestiter][it]][it]->GetQ())> maxcharge){
3241 maxcharge = TMath::Abs(cl[best[bestiter][it]][it]->GetQ());
3242 maxpos = cl[best[bestiter][it]][it]->GetLocalTimeBin();
3245 if (TMath::Abs(cl[best[bestiter][it]][it]->GetQ())> maxcharge4){
3246 if (cl[best[bestiter][it]][it]->GetLocalTimeBin()>=4){
3247 maxcharge4 = TMath::Abs(cl[best[bestiter][it]][it]->GetQ());
3248 maxpos4 = cl[best[bestiter][it]][it]->GetLocalTimeBin();
3251 if (TMath::Abs(cl[best[bestiter][it]][it]->GetQ())> maxcharge5){
3252 if (cl[best[bestiter][it]][it]->GetLocalTimeBin()>=5){
3253 maxcharge5 = TMath::Abs(cl[best[bestiter][it]][it]->GetQ());
3254 maxpos5 = cl[best[bestiter][it]][it]->GetLocalTimeBin();
3258 // time bins with maximal charge
3259 if (TMath::Abs(cl[best[bestiter][it]][it]->GetQ())> maxcharge){
3260 maxcharge = TMath::Abs(cl[best[bestiter][it]][it]->GetQ());
3261 maxpos = cl[best[bestiter][it]][it]->GetLocalTimeBin();
3264 if (TMath::Abs(cl[best[bestiter][it]][it]->GetQ())> maxcharge4){
3265 if (cl[best[bestiter][it]][it]->GetLocalTimeBin()>=4){
3266 maxcharge4 = TMath::Abs(cl[best[bestiter][it]][it]->GetQ());
3267 maxpos4 = cl[best[bestiter][it]][it]->GetLocalTimeBin();
3270 if (TMath::Abs(cl[best[bestiter][it]][it]->GetQ())> maxcharge5){
3271 if (cl[best[bestiter][it]][it]->GetLocalTimeBin()>=5){
3272 maxcharge5 = TMath::Abs(cl[best[bestiter][it]][it]->GetQ());
3273 maxpos5 = cl[best[bestiter][it]][it]->GetLocalTimeBin();
3276 clusters[it+t0] = indexes[best[bestiter][it]][it];
3277 //if (cl[best[bestiter][it]][it]->GetLocalTimeBin()>4 && cl[best[bestiter][it]][it]->GetLocalTimeBin()<18) clusters[it+t0] = indexes[best[bestiter][it]][it]; //Test
3280 // set tracklet parameters
3282 Double_t trackleterr2 = smoffset[bestiter]+0.01*0.01;
3283 if (mpads>3.5) trackleterr2 += (mpads-3.5)*0.04;
3284 trackleterr2+= changes[bestiter]*0.01;
3285 trackleterr2*= TMath::Max(14.-nfound,1.);
3286 trackleterr2+= 0.2*(tany-exB)*(tany-exB);
3288 tracklet.Set(xmean, track2.GetY()+moffset[bestiter], meanz[bestiter], track2.GetAlpha(), trackleterr2); //set tracklet parameters
3289 tracklet.SetTilt(h01);
3290 tracklet.SetP0(mean[bestiter]);
3291 tracklet.SetP1(angle[bestiter]);
3292 tracklet.SetN(nfound);
3293 tracklet.SetNCross(changes[bestiter]);
3294 tracklet.SetPlane(plane);
3295 tracklet.SetSigma2(expectederr);
3296 tracklet.SetChi2(tchi2s[bestiter]);
3297 tracklet.SetMaxPos(maxpos,maxpos4,maxpos5);
3298 track->fTracklets[plane] = tracklet;
3299 track->fNWrong+=nbad[0];
3303 TClonesArray array0("AliTRDcluster");
3304 TClonesArray array1("AliTRDcluster");
3305 array0.ExpandCreateFast(t1-t0+1);
3306 array1.ExpandCreateFast(t1-t0+1);
3307 TTreeSRedirector& cstream = *fDebugStreamer;
3308 AliTRDcluster dummy;
3312 for (Int_t it=0;it<t1-t0;it++){
3313 dy0[it] = dy[0][it];
3314 dyb[it] = dy[best[bestiter][it]][it];
3316 new(array0[it]) AliTRDcluster(*cl[0][it]);
3319 new(array0[it]) AliTRDcluster(dummy);
3321 if(cl[best[bestiter][it]][it]) {
3322 new(array1[it]) AliTRDcluster(*cl[best[bestiter][it]][it]);
3325 new(array1[it]) AliTRDcluster(dummy);
3328 TGraph graph0(t1-t0,x,dy0);
3329 TGraph graph1(t1-t0,x,dyb);
3330 TGraph graphy(t1-t0,x,yt);
3331 TGraph graphz(t1-t0,x,zt);
3334 if (AliTRDReconstructor::StreamLevel()>0)
3335 cstream<<"tracklet"<<
3336 "track.="<<track<< // track parameters
3337 "tany="<<tany<< // tangent of the local track angle
3338 "xmean="<<xmean<< // xmean - reference x of tracklet
3339 "tilt="<<h01<< // tilt angle
3340 "nall="<<nall<< // number of foundable clusters
3341 "nfound="<<nfound<< // number of found clusters
3342 "clfound="<<clfound<< // total number of found clusters in road
3343 "mpads="<<mpads<< // mean number of pads per cluster
3344 "plane="<<plane<< // plane number
3345 "detector="<<detector<< // detector number
3346 "road="<<road<< // the width of the used road
3347 "graph0.="<<&graph0<< // x - y = dy for closest cluster
3348 "graph1.="<<&graph1<< // x - y = dy for second closest cluster
3349 "graphy.="<<&graphy<< // y position of the track
3350 "graphz.="<<&graphz<< // z position of the track
3351 // "fCl.="<<&array0<< // closest cluster
3352 //"fCl2.="<<&array1<< // second closest cluster
3353 "maxpos="<<maxpos<< // maximal charge postion
3354 "maxcharge="<<maxcharge<< // maximal charge
3355 "maxpos4="<<maxpos4<< // maximal charge postion - after bin 4
3356 "maxcharge4="<<maxcharge4<< // maximal charge - after bin 4
3357 "maxpos5="<<maxpos5<< // maximal charge postion - after bin 5
3358 "maxcharge5="<<maxcharge5<< // maximal charge - after bin 5
3360 "bestiter="<<bestiter<< // best iteration number
3361 "tracklet.="<<&tracklet<< // corrspond to the best iteration
3362 "tchi20="<<tchi2s[0]<< // chi2 of cluster in the 0 iteration
3363 "tchi2b="<<tchi2s[bestiter]<< // chi2 of cluster in the best iteration
3364 "sigmas0="<<sigmas[0]<< // residuals sigma
3365 "sigmasb="<<sigmas[bestiter]<< // residulas sigma
3367 "ngood0="<<ngood[0]<< // number of good clusters in 0 iteration
3368 "nbad0="<<nbad[0]<< // number of bad clusters in 0 iteration
3369 "ngoodb="<<ngood[bestiter]<< // in best iteration
3370 "nbadb="<<nbad[bestiter]<< // in best iteration
3372 "changes0="<<changes[0]<< // changes of pardrows in iteration number 0
3373 "changesb="<<changes[bestiter]<< // changes of pardrows in best iteration
3375 "moffset0="<<moffset[0]<< // offset fixing angle in iter=0
3376 "smoffset0="<<smoffset[0]<< // sigma of offset fixing angle in iter=0
3377 "moffsetb="<<moffset[bestiter]<< // offset fixing angle in iter=best
3378 "smoffsetb="<<smoffset[bestiter]<< // sigma of offset fixing angle in iter=best
3380 "mean0="<<mean[0]<< // mean dy in iter=0;
3381 "smean0="<<smean[0]<< // sigma of mean dy in iter=0
3382 "meanb="<<mean[bestiter]<< // mean dy in iter=best
3383 "smeanb="<<smean[bestiter]<< // sigma of mean dy in iter=best
3385 "angle0="<<angle[0]<< // angle deviation in the iteration number 0
3386 "sangle0="<<sangle[0]<< // sigma of angular deviation in iteration number 0
3387 "angleb="<<angle[bestiter]<< // angle deviation in the best iteration
3388 "sangleb="<<sangle[bestiter]<< // sigma of angle deviation in the best iteration
3390 "expectederr="<<expectederr<< // expected error of cluster position
3398 //_____________________________________________________________________________
3399 Int_t AliTRDtracker::Freq(Int_t n, const Int_t *inlist
3400 , Int_t *outlist, Bool_t down)
3403 // Sort eleements according occurancy
3404 // The size of output array has is 2*n
3407 Int_t * sindexS = new Int_t[n]; // temp array for sorting
3408 Int_t * sindexF = new Int_t[2*n];
3409 for (Int_t i=0;i<n;i++) sindexF[i]=0;
3411 TMath::Sort(n,inlist, sindexS, down);
3412 Int_t last = inlist[sindexS[0]];
3415 sindexF[0+n] = last;
3419 for(Int_t i=1;i<n; i++){
3420 val = inlist[sindexS[i]];
3421 if (last == val) sindexF[countPos]++;
3424 sindexF[countPos+n] = val;
3425 sindexF[countPos]++;
3429 if (last==val) countPos++;
3430 // sort according frequency
3431 TMath::Sort(countPos, sindexF, sindexS, kTRUE);
3432 for (Int_t i=0;i<countPos;i++){
3433 outlist[2*i ] = sindexF[sindexS[i]+n];
3434 outlist[2*i+1] = sindexF[sindexS[i]];
3443 //_____________________________________________________________________________
3444 AliTRDtrack *AliTRDtracker::RegisterSeed(AliTRDseed * seeds, Double_t * params)
3449 Double_t alpha=AliTRDgeometry::GetAlpha();
3450 Double_t shift=AliTRDgeometry::GetAlpha()/2.;
3453 c[1] = 0 ; c[2] = 2;
3454 c[3] = 0 ; c[4] = 0; c[5] = 0.02;
3455 c[6] = 0 ; c[7] = 0; c[8] = 0; c[9] = 0.1;
3456 c[10] = 0 ; c[11] = 0; c[12] = 0; c[13] = 0.0; c[14] = params[5]*params[5]*0.01;
3459 AliTRDcluster *cl =0;
3460 for (Int_t ilayer=0;ilayer<6;ilayer++){
3461 if (seeds[ilayer].IsOK()){
3462 for (Int_t itime=22;itime>0;itime--){
3463 if (seeds[ilayer].fIndexes[itime]>0){
3464 index = seeds[ilayer].fIndexes[itime];
3465 cl = seeds[ilayer].fClusters[itime];
3472 if (cl==0) return 0;
3473 AliTRDtrack * track = new AliTRDtrack(cl,index,¶ms[1],c, params[0],params[6]*alpha+shift);
3474 track->PropagateTo(params[0]-5.);
3475 track->ResetCovariance(1);
3477 Int_t rc=FollowBackProlongation(*track);
3483 CookdEdxTimBin(*track);
3484 CookLabel(track, 0.9);