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 **************************************************************************/
17 Comments to be written here:
19 1. What do we calibrate.
21 Time dependence of gain and drift velocity in order to account for changes in: temperature, pressure, gas composition.
23 AliTPCcalibTime *calibTime = new AliTPCcalibTime("cosmicTime","cosmicTime",0, 1213.9e+06, 1213.96e+06, 0.04e+04, 0.04e+04);
27 #include "Riostream.h"
28 #include "TDatabasePDG.h"
29 #include "TGraphErrors.h"
31 #include "THnSparse.h"
34 #include "TTimeStamp.h"
40 #include "AliDCSSensor.h"
41 #include "AliDCSSensorArray.h"
42 #include "AliESDEvent.h"
43 #include "AliESDInputHandler.h"
44 #include "AliESDVertex.h"
45 #include "AliESDfriend.h"
47 #include "AliRelAlignerKalman.h"
48 #include "AliTPCCalROC.h"
49 #include "AliTPCParam.h"
50 #include "AliTPCTracklet.h"
51 #include "AliTPCcalibDB.h"
52 #include "AliTPCcalibLaser.h"
53 #include "AliTPCcalibTime.h"
54 #include "AliTPCclusterMI.h"
55 #include "AliTPCseed.h"
56 #include "AliTrackPointArray.h"
57 #include "AliTracker.h"
58 #include "AliKFVertex.h"
61 ClassImp(AliTPCcalibTime)
64 AliTPCcalibTime::AliTPCcalibTime()
66 fMemoryMode(1), // 0 -do not fill THnSparse with residuals 1- fill only important QA THn 2 - Fill all THnsparse for calibration
67 fLaser(0), // pointer to laser calibration
68 fDz(0), // current delta z
69 fCutMaxD(3), // maximal distance in rfi ditection
70 fCutMaxDz(25), // maximal distance in rfi ditection
71 fCutTheta(0.03), // maximal distan theta
72 fCutMinDir(-0.99), // direction vector products
74 fArrayLaserA(0), //laser fit parameters C
75 fArrayLaserC(0), //laser fit parameters A
76 fArrayDz(0), //NEW! Tmap of V drifts for different triggers
77 fAlignITSTPC(0), //alignemnt array ITS TPC match
78 fAlignTRDTPC(0), //alignemnt array TRD TPC match
79 fAlignTOFTPC(0), //alignemnt array TOF TPC match
80 fTimeKalmanBin(60*15), //time bin width for kalman - 15 minutes default
95 // default constructor
97 AliInfo("Default Constructor");
98 for (Int_t i=0;i<3;i++) {
99 fHistVdriftLaserA[i]=0;
100 fHistVdriftLaserC[i]=0;
102 for (Int_t i=0;i<10;i++) {
103 fCosmiMatchingHisto[i]=0;
106 for (Int_t i=0;i<5;i++) {
108 fResHistoTPCITS[i]=0;
109 fResHistoTPCTRD[i]=0;
110 fResHistoTPCTOF[i]=0;
111 fResHistoTPCvertex[i]=0;
114 for (Int_t i=0;i<12;i++) {
117 for (Int_t i=0;i<5;i++) {
118 fTPCVertexCorrelation[i]=0;
120 static Int_t counter=0;
124 AliInfo(Form("Counter Constructor\t%d\t%d",counter,time));
130 AliTPCcalibTime::AliTPCcalibTime(const Text_t *name, const Text_t *title, UInt_t StartTime, UInt_t EndTime, Int_t deltaIntegrationTimeVdrift, Int_t memoryMode)
132 fMemoryMode(memoryMode), // 0 -do not fill THnSparse with residuals 1- fill only important QA THn 2 - Fill all THnsparse for calibration
133 fLaser(0), // pointer to laser calibration
134 fDz(0), // current delta z
135 fCutMaxD(5*0.5356), // maximal distance in rfi ditection
136 fCutMaxDz(40), // maximal distance in rfi ditection
137 fCutTheta(5*0.004644),// maximal distan theta
138 fCutMinDir(-0.99), // direction vector products
140 fArrayLaserA(new TObjArray(1000)), //laser fit parameters C
141 fArrayLaserC(new TObjArray(1000)), //laser fit parameters A
142 fArrayDz(0), //Tmap of V drifts for different triggers
143 fAlignITSTPC(0), //alignemnt array ITS TPC match
144 fAlignTRDTPC(0), //alignemnt array TRD TPC match
145 fAlignTOFTPC(0), //alignemnt array TOF TPC match
146 fTimeKalmanBin(60*15), //time bin width for kalman - 15 minutes default
161 // Non deafaul constructor - to be used in the Calibration setups
166 for (Int_t i=0;i<3;i++) {
167 fHistVdriftLaserA[i]=0;
168 fHistVdriftLaserC[i]=0;
171 for (Int_t i=0;i<5;i++) {
173 fResHistoTPCITS[i]=0;
174 fResHistoTPCTRD[i]=0;
175 fResHistoTPCTOF[i]=0;
176 fResHistoTPCvertex[i]=0;
180 AliInfo("Non Default Constructor");
181 fTimeBins =(EndTime-StartTime)/deltaIntegrationTimeVdrift;
182 fTimeStart =StartTime; //(((TObjString*)(mapGRP->GetValue("fAliceStartTime")))->GetString()).Atoi();
183 fTimeEnd =EndTime; //(((TObjString*)(mapGRP->GetValue("fAliceStopTime")))->GetString()).Atoi();
194 Int_t binsVdriftLaser[4] = {fTimeBins , fPtBins , fVdriftBins*20, fRunBins };
195 Double_t xminVdriftLaser[4] = {fTimeStart, fPtStart, fVdriftStart , fRunStart};
196 Double_t xmaxVdriftLaser[4] = {fTimeEnd , fPtEnd , fVdriftEnd , fRunEnd };
197 TString axisTitle[4]={
203 TString histoName[3]={
210 for (Int_t i=0;i<3;i++) {
211 fHistVdriftLaserA[i] = new THnSparseF("HistVdriftLaser","HistVdriftLaser;time;p/T ratio;Vdrift;run",4,binsVdriftLaser,xminVdriftLaser,xmaxVdriftLaser);
212 fHistVdriftLaserC[i] = new THnSparseF("HistVdriftLaser","HistVdriftLaser;time;p/T ratio;Vdrift;run",4,binsVdriftLaser,xminVdriftLaser,xmaxVdriftLaser);
213 fHistVdriftLaserA[i]->SetName(histoName[i]);
214 fHistVdriftLaserC[i]->SetName(histoName[i]);
215 for (Int_t iaxis=0; iaxis<4;iaxis++){
216 fHistVdriftLaserA[i]->GetAxis(iaxis)->SetName(axisTitle[iaxis]);
217 fHistVdriftLaserC[i]->GetAxis(iaxis)->SetName(axisTitle[iaxis]);
220 fBinsVdrift[0] = fTimeBins;
221 fBinsVdrift[1] = fPtBins;
222 fBinsVdrift[2] = fVdriftBins;
223 fBinsVdrift[3] = fRunBins;
224 fXminVdrift[0] = fTimeStart;
225 fXminVdrift[1] = fPtStart;
226 fXminVdrift[2] = fVdriftStart;
227 fXminVdrift[3] = fRunStart;
228 fXmaxVdrift[0] = fTimeEnd;
229 fXmaxVdrift[1] = fPtEnd;
230 fXmaxVdrift[2] = fVdriftEnd;
231 fXmaxVdrift[3] = fRunEnd;
233 fArrayDz=new TObjArray();
234 fAlignITSTPC = new TObjArray; //alignemnt array ITS TPC match
235 fAlignTRDTPC = new TObjArray; //alignemnt array ITS TPC match
236 fAlignTOFTPC = new TObjArray; //alignemnt array ITS TPC match
237 fAlignITSTPC->SetOwner(kTRUE);
238 fAlignTRDTPC->SetOwner(kTRUE);
239 fAlignTOFTPC->SetOwner(kTRUE);
242 fCosmiMatchingHisto[0]=new TH1F("Cosmics matching","p0-all" ,100,-10*0.5356 ,10*0.5356 );
243 fCosmiMatchingHisto[1]=new TH1F("Cosmics matching","p1-all" ,100,-10*4.541 ,10*4.541 );
244 fCosmiMatchingHisto[2]=new TH1F("Cosmics matching","p2-all" ,100,-10*0.01134 ,10*0.01134 );
245 fCosmiMatchingHisto[3]=new TH1F("Cosmics matching","p3-all" ,100,-10*0.004644,10*0.004644);
246 fCosmiMatchingHisto[4]=new TH1F("Cosmics matching","p4-all" ,100,-10*0.03773 ,10*0.03773 );
247 fCosmiMatchingHisto[5]=new TH1F("Cosmics matching","p0-isPair",100,-10*0.5356 ,10*0.5356 );
248 fCosmiMatchingHisto[6]=new TH1F("Cosmics matching","p1-isPair",100,-10*4.541 ,10*4.541 );
249 fCosmiMatchingHisto[7]=new TH1F("Cosmics matching","p2-isPair",100,-10*0.01134 ,10*0.01134 );
250 fCosmiMatchingHisto[8]=new TH1F("Cosmics matching","p3-isPair",100,-10*0.004644,10*0.004644);
251 fCosmiMatchingHisto[9]=new TH1F("Cosmics matching","p4-isPair",100,-10*0.03773 ,10*0.03773 );
252 for (Int_t i=0;i<12;i++) {
255 for (Int_t i=0;i<5;i++) {
256 fTPCVertexCorrelation[i]=0;
258 BookDistortionMaps();
262 AliTPCcalibTime::~AliTPCcalibTime(){
264 // Virtual Destructor
266 static Int_t counter=0;
270 AliInfo(Form("Counter Destructor\t%s\t%d\t%d",GetName(),counter,time));
273 for(Int_t i=0;i<3;i++){
274 if(fHistVdriftLaserA[i]){
275 delete fHistVdriftLaserA[i];
276 fHistVdriftLaserA[i]=NULL;
278 if(fHistVdriftLaserC[i]){
279 delete fHistVdriftLaserC[i];
280 fHistVdriftLaserC[i]=NULL;
284 fArrayDz->SetOwner();
289 for(Int_t i=0;i<5;i++){
290 if(fCosmiMatchingHisto[i]){
291 delete fCosmiMatchingHisto[i];
292 fCosmiMatchingHisto[i]=NULL;
296 for (Int_t i=0;i<5;i++) {
297 delete fResHistoTPCCE[i];
298 delete fResHistoTPCITS[i];
299 delete fResHistoTPCTRD[i];
300 delete fResHistoTPCTOF[i];
301 delete fResHistoTPCvertex[i];
303 fResHistoTPCITS[i]=0;
304 fResHistoTPCTRD[i]=0;
305 fResHistoTPCTOF[i]=0;
306 fResHistoTPCvertex[i]=0;
310 for (Int_t i=0;i<12;i++) delete fTPCVertex[i];
312 if (fTPCVertexCorrelation[0]) {
313 for (Int_t i=0;i<5;i++) delete fTPCVertexCorrelation[i];
316 fAlignITSTPC->SetOwner(kTRUE);
317 fAlignTRDTPC->SetOwner(kTRUE);
318 fAlignTOFTPC->SetOwner(kTRUE);
320 fAlignITSTPC->Delete();
321 fAlignTRDTPC->Delete();
322 fAlignTOFTPC->Delete();
328 // Bool_t AliTPCcalibTime::IsLaser(const AliESDEvent *const /*event*/) const{
330 // // Indicator is laser event not yet implemented - to be done using trigger info or event specie
332 // return kTRUE; //More accurate creteria to be added
334 // Bool_t AliTPCcalibTime::IsCosmics(const AliESDEvent *const /*event*/){
336 // // Indicator is cosmic event not yet implemented - to be done using trigger info or event specie
339 // return kTRUE; //More accurate creteria to be added
341 // Bool_t AliTPCcalibTime::IsBeam(const AliESDEvent *const /*event*/) const{
343 // // Indicator is physic event not yet implemented - to be done using trigger info or event specie
346 // return kTRUE; //More accurate creteria to be added
348 void AliTPCcalibTime::ResetCurrent(){
352 fDz=0; //Reset current dz
357 void AliTPCcalibTime::Process(AliESDEvent *event){
359 // main function to make calibration
362 if (event->GetNumberOfTracks()<2) return;
363 AliESDfriend *ESDfriend=static_cast<AliESDfriend*>(event->FindListObject("AliESDfriend"));
367 if (ESDfriend->TestSkipBit()) return;
370 //if(IsLaser (event))
371 ProcessLaser (event);
372 //if(IsCosmics(event))
373 ProcessCosmic(event);
378 void AliTPCcalibTime::ProcessLaser(AliESDEvent *event){
380 // Fit drift velocity using laser
383 const Int_t kMinTracks = 40; // minimal number of laser tracks
384 const Int_t kMinTracksSide = 20; // minimal number of tracks per side
385 const Float_t kMaxDeltaZ = 30.; // maximal trigger delay
386 const Float_t kMaxDeltaV = 0.05; // maximal deltaV
387 const Float_t kMaxRMS = 0.1; // maximal RMS of tracks
390 TCut cutRMS("sqrt(laserA.fElements[4])<0.1&&sqrt(laserC.fElements[4])<0.1");
391 TCut cutZ("abs(laserA.fElements[0]-laserC.fElements[0])<3");
392 TCut cutV("abs(laserA.fElements[1]-laserC.fElements[1])<0.01");
393 TCut cutY("abs(laserA.fElements[2]-laserC.fElements[2])<2");
394 TCut cutAll = cutRMS+cutZ+cutV+cutY;
396 if (event->GetNumberOfTracks()<kMinTracks) return;
398 if(!fLaser) fLaser = new AliTPCcalibLaser("laserTPC","laserTPC",kFALSE);
399 fLaser->Process(event);
400 if (fLaser->GetNtracks()<kMinTracks) return; // small amount of tracks cut
401 if (fLaser->fFitAside->GetNrows()==0 && fLaser->fFitCside->GetNrows()==0) return; // no fit neither a or C side
403 // debug streamer - activate stream level
404 // Use it for tuning of the cuts
406 // cuts to be applied
408 Int_t isReject[2]={0,0};
411 if (TMath::Abs((*fLaser->fFitAside)[3]) < kMinTracksSide) isReject[0]|=1;
412 if (TMath::Abs((*fLaser->fFitCside)[3]) < kMinTracksSide) isReject[1]|=1;
413 // unreasonable z offset
414 if (TMath::Abs((*fLaser->fFitAside)[0])>kMaxDeltaZ) isReject[0]|=2;
415 if (TMath::Abs((*fLaser->fFitCside)[0])>kMaxDeltaZ) isReject[1]|=2;
416 // unreasonable drift velocity
417 if (TMath::Abs((*fLaser->fFitAside)[1]-1)>kMaxDeltaV) isReject[0]|=4;
418 if (TMath::Abs((*fLaser->fFitCside)[1]-1)>kMaxDeltaV) isReject[1]|=4;
420 if (TMath::Sqrt(TMath::Abs((*fLaser->fFitAside)[4]))>kMaxRMS ) isReject[0]|=8;
421 if (TMath::Sqrt(TMath::Abs((*fLaser->fFitCside)[4]))>kMaxRMS ) isReject[1]|=8;
427 printf("Trigger: %s\n",event->GetFiredTriggerClasses().Data());
429 TTreeSRedirector *cstream = GetDebugStreamer();
431 TTimeStamp tstamp(fTime);
432 (*cstream)<<"laserInfo"<<
433 "run="<<fRun<< // run number
434 "event="<<fEvent<< // event number
435 "time="<<fTime<< // time stamp of event
436 "trigger="<<fTrigger<< // trigger
437 "mag="<<fMagF<< // magnetic field
439 "rejectA="<<isReject[0]<<
440 "rejectC="<<isReject[1]<<
441 "laserA.="<<fLaser->fFitAside<<
442 "laserC.="<<fLaser->fFitCside<<
443 "laserAC.="<<fLaser->fFitACside<<
444 "trigger="<<event->GetFiredTriggerClasses()<<
451 TVectorD vdriftA(5), vdriftC(5),vdriftAC(6);
452 vdriftA=*(fLaser->fFitAside);
453 vdriftC=*(fLaser->fFitCside);
454 vdriftAC=*(fLaser->fFitACside);
455 Int_t npointsA=0, npointsC=0;
456 Float_t chi2A=0, chi2C=0;
457 npointsA= TMath::Nint(vdriftA[3]);
459 npointsC= TMath::Nint(vdriftC[3]);
462 if (npointsA>kMinTracksSide || npointsC>kMinTracksSide){
463 TVectorD *fitA = new TVectorD(6);
464 TVectorD *fitC = new TVectorD(6);
465 for (Int_t ipar=0; ipar<5; ipar++){
466 (*fitA)[ipar]=vdriftA[ipar];
467 (*fitC)[ipar]=vdriftC[ipar];
471 fArrayLaserA->AddLast(fitA);
472 fArrayLaserC->AddLast(fitC);
476 TTimeStamp tstamp(fTime);
477 Double_t ptrelative0 = AliTPCcalibDB::GetPTRelative(tstamp,fRun,0);
478 Double_t ptrelative1 = AliTPCcalibDB::GetPTRelative(tstamp,fRun,1);
479 Double_t driftA=0, driftC=0;
480 if (vdriftA[1]>1.-kMaxDeltaV) driftA = 1./vdriftA[1]-1.;
481 if (vdriftC[1]>1.-kMaxDeltaV) driftC = 1./vdriftC[1]-1.;
483 Double_t vecDriftLaserA[4]={fTime,(ptrelative0+ptrelative1)/2.0,driftA,event->GetRunNumber()};
484 Double_t vecDriftLaserC[4]={fTime,(ptrelative0+ptrelative1)/2.0,driftC,event->GetRunNumber()};
485 // Double_t vecDrift[4] ={fTime,(ptrelative0+ptrelative1)/2.0,1./((*(fLaser->fFitACside))[1])-1,event->GetRunNumber()};
487 for (Int_t icalib=0;icalib<3;icalib++){
488 if (icalib==0){ //z0 shift
489 vecDriftLaserA[2]=vdriftA[0]/250.;
490 vecDriftLaserC[2]=vdriftC[0]/250.;
492 if (icalib==1){ //vdrel shift
493 vecDriftLaserA[2]=driftA;
494 vecDriftLaserC[2]=driftC;
496 if (icalib==2){ //gy shift - full gy - full drift
497 vecDriftLaserA[2]=vdriftA[2]/250.;
498 vecDriftLaserC[2]=vdriftC[2]/250.;
500 //if (isReject[0]==0) fHistVdriftLaserA[icalib]->Fill(vecDriftLaserA);
501 //if (isReject[1]==0) fHistVdriftLaserC[icalib]->Fill(vecDriftLaserC);
502 fHistVdriftLaserA[icalib]->Fill(vecDriftLaserA);
503 fHistVdriftLaserC[icalib]->Fill(vecDriftLaserC);
507 void AliTPCcalibTime::ProcessCosmic(const AliESDEvent *const event){
509 // process Cosmic event - track matching A side C side
512 Printf("ERROR: ESD not available");
515 if (event->GetTimeStamp() == 0 ) {
516 Printf("no time stamp!");
523 // Track0 is choosen in upper TPC part
524 // Track1 is choosen in lower TPC part
526 const Int_t kMinClustersCross =30;
527 const Int_t kMinClusters =80;
528 Int_t ntracks=event->GetNumberOfTracks();
529 if (ntracks==0) return;
530 if (ntracks > fCutTracks) return;
532 if (GetDebugLevel()>20) printf("Hallo world: Im here\n");
533 AliESDfriend *esdFriend=(AliESDfriend*)(((AliESDEvent*)event)->FindListObject("AliESDfriend"));
535 TObjArray tpcSeeds(ntracks);
536 Double_t vtxx[3]={0,0,0};
537 Double_t svtxx[3]={0.000001,0.000001,100.};
538 AliESDVertex vtx(vtxx,svtxx);
542 TArrayI clusterSideA(ntracks);
543 TArrayI clusterSideC(ntracks);
544 for (Int_t i=0;i<ntracks;++i) {
547 AliESDtrack *track = event->GetTrack(i);
549 const AliExternalTrackParam * trackIn = track->GetInnerParam();
550 const AliExternalTrackParam * trackOut = track->GetOuterParam();
551 if (!trackIn) continue;
552 if (!trackOut) continue;
554 AliESDfriendTrack *friendTrack = esdFriend->GetTrack(i);
555 if (!friendTrack) continue;
556 if (friendTrack) ProcessSame(track,friendTrack,event);
557 if (friendTrack) ProcessAlignITS(track,friendTrack,event,esdFriend);
558 if (friendTrack) ProcessAlignTRD(track,friendTrack);
559 if (friendTrack) ProcessAlignTOF(track,friendTrack);
560 TObject *calibObject;
561 AliTPCseed *seed = 0;
562 for (Int_t l=0;(calibObject=friendTrack->GetCalibObject(l));++l) if ((seed=dynamic_cast<AliTPCseed*>(calibObject))) break;
564 tpcSeeds.AddAt(seed,i);
566 for (Int_t irow=159;irow>0;irow--) {
567 AliTPCclusterMI *cl=seed->GetClusterPointer(irow);
569 if ((cl->GetDetector()%36)<18) nA++;
570 if ((cl->GetDetector()%36)>=18) nC++;
576 if (ntracks<2) return;
581 for (Int_t i=0;i<ntracks;++i) {
582 AliESDtrack *track0 = event->GetTrack(i);
583 // track0 - choosen upper part
584 if (!track0) continue;
585 if (!track0->GetOuterParam()) continue;
586 if (track0->GetOuterParam()->GetAlpha()<0) continue;
588 track0->GetDirection(d1);
589 for (Int_t j=0;j<ntracks;++j) {
591 AliESDtrack *track1 = event->GetTrack(j);
593 if (!track1) continue;
594 if (!track1->GetOuterParam()) continue;
595 if (track0->GetTPCNcls()+ track1->GetTPCNcls()< kMinClusters) continue;
596 Int_t nAC = TMath::Max( TMath::Min(clusterSideA[i], clusterSideC[j]),
597 TMath::Min(clusterSideC[i], clusterSideA[j]));
598 if (nAC<kMinClustersCross) continue;
599 Int_t nA0=clusterSideA[i];
600 Int_t nC0=clusterSideC[i];
601 Int_t nA1=clusterSideA[j];
602 Int_t nC1=clusterSideC[j];
603 // if (track1->GetOuterParam()->GetAlpha()>0) continue;
606 track1->GetDirection(d2);
608 AliTPCseed * seed0 = (AliTPCseed*) tpcSeeds.At(i);
609 AliTPCseed * seed1 = (AliTPCseed*) tpcSeeds.At(j);
610 if (! seed0) continue;
611 if (! seed1) continue;
612 Float_t dir = (d1[0]*d2[0] + d1[1]*d2[1] + d1[2]*d2[2]);
613 Float_t dist0 = track0->GetLinearD(0,0);
614 Float_t dist1 = track1->GetLinearD(0,0);
616 // conservative cuts - convergence to be guarantied
617 // applying before track propagation
618 if (TMath::Abs(TMath::Abs(dist0)-TMath::Abs(dist1))>fCutMaxD) continue; // distance to the 0,0
619 if (TMath::Abs(dir)<TMath::Abs(fCutMinDir)) continue; // direction vector product
620 Float_t bz = AliTracker::GetBz();
621 Float_t dvertex0[2]; //distance to 0,0
622 Float_t dvertex1[2]; //distance to 0,0
623 track0->GetDZ(0,0,0,bz,dvertex0);
624 track1->GetDZ(0,0,0,bz,dvertex1);
625 if (TMath::Abs(dvertex0[1])>250) continue;
626 if (TMath::Abs(dvertex1[1])>250) continue;
630 Float_t dmax = TMath::Max(TMath::Abs(dist0),TMath::Abs(dist1));
631 AliExternalTrackParam param0(*track0);
632 AliExternalTrackParam param1(*track1);
634 // Propagate using Magnetic field and correct fo material budget
636 AliTracker::PropagateTrackTo(¶m0,dmax+1,TDatabasePDG::Instance()->GetParticle("e-")->Mass(),3,kTRUE);
637 AliTracker::PropagateTrackTo(¶m1,dmax+1,TDatabasePDG::Instance()->GetParticle("e-")->Mass(),3,kTRUE);
639 // Propagate rest to the 0,0 DCA - z should be ignored
642 param0.PropagateToDCA(&vtx,bz,1000);
644 param1.PropagateToDCA(&vtx,bz,1000);
645 param0.GetDZ(0,0,0,bz,dvertex0);
646 param1.GetDZ(0,0,0,bz,dvertex1);
651 Bool_t isPair = IsPair(¶m0,¶m1);
652 Bool_t isCross = IsCross(track0, track1);
653 Bool_t isSame = IsSame(track0, track1);
655 THnSparse* hist=new THnSparseF("","HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
656 TString shortName=hist->ClassName();
657 shortName+="_MEAN_VDRIFT_COSMICS_";
661 if((isSame) || (isCross && isPair)){
662 if (track0->GetTPCNcls()+ track1->GetTPCNcls()> 80) {
663 fDz = param0.GetZ() - param1.GetZ();
664 Double_t sign=(nA0>nA1)? 1:-1;
666 TTimeStamp tstamp(fTime);
667 Double_t ptrelative0 = AliTPCcalibDB::GetPTRelative(tstamp,fRun,0);
668 Double_t ptrelative1 = AliTPCcalibDB::GetPTRelative(tstamp,fRun,1);
669 Double_t vecDrift[4]={fTime,(ptrelative0+ptrelative1)/2.0,fDz/500.0,event->GetRunNumber()};
670 THnSparse* curHist=NULL;
674 name+=event->GetFiredTriggerClasses();
676 curHist=(THnSparseF*)fArrayDz->FindObject(name);
678 curHist=new THnSparseF(name,"HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
679 fArrayDz->AddLast(curHist);
681 // curHist=(THnSparseF*)(fMapDz->GetValue(event->GetFiredTriggerClasses()));
683 // curHist=new THnSparseF(event->GetFiredTriggerClasses(),"HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
684 // fMapDz->Add(new TObjString(event->GetFiredTriggerClasses()),curHist);
686 curHist->Fill(vecDrift);
691 curHist=(THnSparseF*)fArrayDz->FindObject(name);
693 curHist=new THnSparseF(name,"HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
694 fArrayDz->AddLast(curHist);
696 // curHist=(THnSparseF*)(fMapDz->GetValue("all"));
698 // curHist=new THnSparseF("all","HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
699 // fMapDz->Add(new TObjString("all"),curHist);
701 curHist->Fill(vecDrift);
704 TTreeSRedirector *cstream = GetDebugStreamer();
707 (*cstream)<<"trackInfo"<<
718 "isCross="<<isCross<<
726 } // end 2nd order loop
727 } // end 1st order loop
730 TTreeSRedirector *cstream = GetDebugStreamer();
732 (*cstream)<<"timeInfo"<<
733 "run="<<fRun<< // run number
734 "event="<<fEvent<< // event number
735 "time="<<fTime<< // time stamp of event
736 "trigger="<<fTrigger<< // trigger
737 "mag="<<fMagF<< // magnetic field
738 // Environment values
740 // accumulated values
742 "fDz="<<fDz<< //! current delta z
743 "trigger="<<event->GetFiredTriggerClasses()<<
747 if (GetDebugLevel()>20) printf("Trigger: %s\n",event->GetFiredTriggerClasses().Data());
750 void AliTPCcalibTime::ProcessBeam(const AliESDEvent *const event){
752 // Process beam data - calculates vartex
753 // from A side and C side
754 // Histogram the differences
756 const Int_t kMinClusters =80;
757 const Int_t kMinTracks =2; // minimal number of tracks to define the vertex
758 const Int_t kMinTracksVertex=30; // minimal number of tracks to define the cumulative vertex
759 const Double_t kMaxTgl =1.2; // maximal Tgl (z angle)
760 const Double_t kMinPt =0.2; // minimal pt
761 const Double_t kMaxD0 =5.; // cut on distance to the primary vertex first guess
762 const Double_t kMaxZ0 =20;
763 const Double_t kMaxD =2.5; // cut on distance to the primary vertex
764 const Double_t kMaxZ =4; // maximal z distance between tracks form the same side
765 const Double_t kMaxChi2 =15; // maximal chi2 of the TPCvertex
766 const Double_t kCumulCovarXY=0.003; //increase the error of cumul vertex 30 microns profile
767 const Double_t kCumulCovarZ=250.; //increase the error of cumul vertex
768 const Double_t kMaxDvertex = 1.0; // cut to accept the vertex;
771 const Int_t kBuffSize=100;
772 static Double_t deltaZ[kBuffSize]={0};
773 static Int_t counterZ=0;
774 static AliKFVertex cumulVertexA, cumulVertexC, cumulVertexAC; // cumulative vertex
775 AliKFVertex vertexA, vertexC;
777 Float_t dca0[2]={0,0};
778 Double_t dcaVertex[2]={0,0};
779 Int_t ntracks=event->GetNumberOfTracks();
780 if (ntracks==0) return;
781 if (ntracks > fCutTracks) return;
783 AliESDfriend *esdFriend=(AliESDfriend*)(((AliESDEvent*)event)->FindListObject("AliESDfriend"));
785 // Divide tracks to A and C side tracks - using the cluster indexes
786 TObjArray tracksA(ntracks);
787 TObjArray tracksC(ntracks);
789 AliESDVertex *vertexSPD = (AliESDVertex *)event->GetPrimaryVertexSPD();
790 AliESDVertex *vertex = (AliESDVertex *)event->GetPrimaryVertex();
791 AliESDVertex *vertexTracks = (AliESDVertex *)event->GetPrimaryVertexTracks();
792 Double_t vertexZA[10000], vertexZC[10000];
797 for (Int_t itrack=0;itrack<ntracks;itrack++) {
798 AliESDtrack *track = event->GetTrack(itrack);
799 AliESDfriendTrack *friendTrack = esdFriend->GetTrack(itrack);
800 if (!friendTrack) continue;
801 if (TMath::Abs(track->GetTgl())>kMaxTgl) continue;
802 if (TMath::Abs(track->Pt())<kMinPt) continue;
803 const AliExternalTrackParam * trackIn = track->GetInnerParam();
804 TObject *calibObject=0;
805 AliTPCseed *seed = 0;
807 for (Int_t l=0;(calibObject=friendTrack->GetCalibObject(l));++l) if ((seed=dynamic_cast<AliTPCseed*>(calibObject))) break;
809 for (Int_t irow=159;irow>0;irow--) {
810 AliTPCclusterMI *cl=seed->GetClusterPointer(irow);
812 if ((cl->GetDetector()%36)<18) nA++;
813 if ((cl->GetDetector()%36)>=18) nC++;
815 if ((nA>kMinClusters || nC>kMinClusters) && (nA*nC==0) ){
816 track->GetImpactParameters(dca0[0],dca0[1]);
817 if (TMath::Abs(dca0[0])>kMaxD0) continue;
818 if (TMath::Abs(dca0[1])>kMaxZ0) continue;
819 AliExternalTrackParam pTPCvertex(*trackIn);
820 if (!AliTracker::PropagateTrackToBxByBz(&pTPCvertex,4.+4.*TMath::Abs(dca0[0]),0.1,2,kTRUE)) continue;
821 pTPCvertex.PropagateToDCA(vertex,AliTracker::GetBz(), kMaxD, dcaVertex,0);
822 if (TMath::Abs(dcaVertex[0])>kMaxD) continue;
823 if (nA>kMinClusters &&nC==0) { tracksA.AddLast(pTPCvertex.Clone()); vertexZA[ntracksA++] = pTPCvertex.GetZ();}
824 if (nC>kMinClusters &&nA==0) {tracksC.AddLast(pTPCvertex.Clone()); vertexZC[ntracksC++] = pTPCvertex.GetZ();}
828 Double_t medianZA=TMath::Median(ntracksA, vertexZA); // tracks median
829 Double_t medianZC=TMath::Median(ntracksC, vertexZC); // tracks median
831 ntracksA= tracksA.GetEntriesFast();
832 ntracksC= tracksC.GetEntriesFast();
833 if (ntracksA>kMinTracks && ntracksC>kMinTracks){
834 deltaZ[counterZ%kBuffSize]=medianZA-medianZC;
836 Double_t medianDelta=(counterZ>=kBuffSize)? TMath::Median(kBuffSize, deltaZ): TMath::Median(counterZ, deltaZ);
837 if (TMath::Abs(medianDelta-(medianZA-medianZC))>kMaxZ) flags+=16;
838 // increse the error of cumulative vertex at the beginning of event
839 cumulVertexA.Covariance(0,0)+=kCumulCovarXY*kCumulCovarXY;
840 cumulVertexA.Covariance(1,1)+=kCumulCovarXY*kCumulCovarXY;
841 cumulVertexA.Covariance(2,2)+=kCumulCovarZ*kCumulCovarZ;
842 cumulVertexC.Covariance(0,0)+=kCumulCovarXY*kCumulCovarXY;
843 cumulVertexC.Covariance(1,1)+=kCumulCovarXY*kCumulCovarXY;
844 cumulVertexC.Covariance(2,2)+=kCumulCovarZ*kCumulCovarZ;
845 cumulVertexAC.Covariance(0,0)+=kCumulCovarXY*kCumulCovarXY;
846 cumulVertexAC.Covariance(1,1)+=kCumulCovarXY*kCumulCovarXY;
847 cumulVertexAC.Covariance(2,2)+=kCumulCovarZ*kCumulCovarZ;
849 for (Int_t iA=0; iA<ntracksA; iA++){
850 if (flags!=0) continue;
851 AliExternalTrackParam *aliTrack = (AliExternalTrackParam *)tracksA.At(iA);
852 if (TMath::Abs(aliTrack->GetZ()-medianZA)>kMaxZ) continue;
853 AliKFParticle part(*aliTrack,211);
856 for (Int_t iC=0; iC<ntracksC; iC++){
857 if (flags!=0) continue;
858 AliExternalTrackParam *aliTrack = (AliExternalTrackParam *)tracksC.At(iC);
859 if (TMath::Abs(aliTrack->GetZ()-medianZC)>kMaxZ) continue;
860 AliKFParticle part(*aliTrack,211);
864 if (vertexA.GetNDF()<kMinTracks) flags+=32;
865 if (vertexC.GetNDF()<kMinTracks) flags+=32;
866 if (TMath::Abs(vertexA.Z()-medianZA)>kMaxZ) flags+=1; //apply cuts
867 if (TMath::Abs(vertexC.Z()-medianZC)>kMaxZ) flags+=2;
868 if (TMath::Abs(vertexA.GetChi2()/vertexA.GetNDF()+vertexC.GetChi2()/vertexC.GetNDF())> kMaxChi2) flags+=4;
871 for (Int_t iA=0; iA<ntracksA; iA++){
872 if (flags!=0) continue;
873 AliExternalTrackParam *aliTrack = (AliExternalTrackParam *)tracksA.At(iA);
874 if (TMath::Abs(aliTrack->GetZ()-medianZA)>kMaxZ) continue;
875 AliKFParticle part(*aliTrack,211);
879 for (Int_t iC=0; iC<ntracksC; iC++){
880 if (flags!=0) continue;
881 AliExternalTrackParam *aliTrack = (AliExternalTrackParam *)tracksC.At(iC);
882 if (TMath::Abs(aliTrack->GetZ()-medianZC)>kMaxZ) continue;
883 AliKFParticle part(*aliTrack,211);
888 if (TMath::Abs(cumulVertexA.X()-vertexA.X())>kMaxDvertex) flags+=64;
889 if (TMath::Abs(cumulVertexA.Y()-vertexA.Y())>kMaxDvertex) flags+=64;
890 if (TMath::Abs(cumulVertexA.Z()-vertexA.Z())>kMaxDvertex) flags+=64;
892 if (TMath::Abs(cumulVertexC.X()-vertexC.X())>kMaxDvertex) flags+=64;
893 if (TMath::Abs(cumulVertexC.Y()-vertexC.Y())>kMaxDvertex) flags+=64;
894 if (TMath::Abs(cumulVertexC.Z()-vertexC.Z())>kMaxDvertex) flags+=64;
897 if ( flags==0 && cumulVertexC.GetNDF()>kMinTracksVertex&&cumulVertexA.GetNDF()>kMinTracksVertex){
898 Double_t cont[2]={0,fTime};
900 cont[0]= cumulVertexA.X();
901 fTPCVertex[0]->Fill(cont);
902 cont[0]= cumulVertexC.X();
903 fTPCVertex[1]->Fill(cont);
904 cont[0]= 0.5*(cumulVertexA.X()-cumulVertexC.X());
905 fTPCVertex[2]->Fill(cont);
906 cont[0]= 0.5*(cumulVertexA.X()+cumulVertexC.X())-vertexSPD->GetX();
907 fTPCVertex[3]->Fill(cont);
909 cont[0]= cumulVertexA.Y();
910 fTPCVertex[4]->Fill(cont);
911 cont[0]= cumulVertexC.Y();
912 fTPCVertex[5]->Fill(cont);
913 cont[0]= 0.5*(cumulVertexA.Y()-cumulVertexC.Y());
914 fTPCVertex[6]->Fill(cont);
915 cont[0]= 0.5*(cumulVertexA.Y()+cumulVertexC.Y())-vertexSPD->GetY();
916 fTPCVertex[7]->Fill(cont);
919 cont[0]= 0.5*(cumulVertexA.Z()+cumulVertexC.Z());
920 fTPCVertex[8]->Fill(cont);
921 cont[0]= 0.5*(cumulVertexA.Z()-cumulVertexC.Z());
922 fTPCVertex[9]->Fill(cont);
923 cont[0]= 0.5*(cumulVertexA.Z()-cumulVertexC.Z());
924 fTPCVertex[10]->Fill(cont);
925 cont[0]= 0.5*(cumulVertexA.Z()+cumulVertexC.Z())-vertexSPD->GetZ();
926 fTPCVertex[11]->Fill(cont);
928 Double_t correl[2]={0,0};
930 correl[0]=cumulVertexC.Z();
931 correl[1]=cumulVertexA.Z();
932 fTPCVertexCorrelation[0]->Fill(correl); // fill A side :TPC
933 correl[0]=cumulVertexA.Z();
934 correl[1]=cumulVertexC.Z();
935 fTPCVertexCorrelation[1]->Fill(correl); // fill C side :TPC
937 correl[0]=vertexSPD->GetZ();
938 correl[1]=cumulVertexA.Z()-correl[0];
939 fTPCVertexCorrelation[2]->Fill(correl); // fill A side :ITS
940 correl[1]=cumulVertexC.Z()-correl[0];
941 fTPCVertexCorrelation[3]->Fill(correl); // fill C side :ITS
942 correl[1]=0.5*(cumulVertexA.Z()+cumulVertexC.Z())-correl[0];
943 fTPCVertexCorrelation[4]->Fill(correl); // fill C side :ITS
946 TTreeSRedirector *cstream = GetDebugStreamer();
949 TCut cutChi2= "sqrt(vA.fChi2/vA.fNDF+vC.fChi2/vC.fNDF)<10"; // chi2 Cut e.g 10
950 TCut cutXY= "sqrt((vA.fP[0]-vC.fP[0])^2+(vA.fP[0]-vC.fP[1])^2)<5"; // vertex Cut
951 TCut cutZ= "abs(vA.fP[2]-mZA)<3&&abs(vC.fP[2]-mZC)<5"; // vertex Cut
952 tree->Draw("sqrt(vA.fChi2/vA.fNDF)","sqrt(vA.fChi2/vA.fNDF)<100","")
957 (*cstream)<<"vertexTPC"<<
958 "flags="<<flags<< // rejection flags
959 "vSPD.="<<vertexSPD<< // SPD vertex
960 "vT.="<<vertexTracks<< // track vertex
961 "v.="<<vertex<< // esd vertex
962 "mZA="<<medianZA<< // median Z position at vertex A side
963 "mZC="<<medianZC<< // median Z position at vertex C side
964 "mDelta="<<medianDelta<< // median delta A side -C side
965 "counter="<<counterZ<< // counter Z
967 "vA.="<<&vertexA<< // vertex A side
968 "vC.="<<&vertexC<< // vertex C side
969 "cvA.="<<&cumulVertexA<< // cumulative vertex A side
970 "cvC.="<<&cumulVertexC<< // cumulative vertex C side
971 "cvAC.="<<&cumulVertexAC<< // cumulative vertex A+C side
972 "nA="<<ntracksA<< // contributors
973 "nC="<<ntracksC<< // contributors
981 void AliTPCcalibTime::Analyze(){
983 // Special macro to analyze result of calibration and extract calibration entries
984 // Not yet ported to the Analyze function yet
988 THnSparse* AliTPCcalibTime::GetHistoDrift(const char* name) const
991 // Get histogram for given trigger mask
993 TIterator* iterator = fArrayDz->MakeIterator();
995 TString newName=name;
997 THnSparse* newHist=new THnSparseF(newName,"HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
998 THnSparse* addHist=NULL;
999 while((addHist=(THnSparseF*)iterator->Next())){
1000 // if(!addHist) continue;
1001 TString histName=addHist->GetName();
1002 if(!histName.Contains(newName)) continue;
1004 newHist->Add(addHist);
1009 TObjArray* AliTPCcalibTime::GetHistoDrift() const
1012 // return array of histograms
1017 TGraphErrors* AliTPCcalibTime::GetGraphDrift(const char* name){
1019 // Make a drift velocity (delta Z) graph
1021 THnSparse* histoDrift=GetHistoDrift(name);
1022 TGraphErrors* graphDrift=NULL;
1024 graphDrift=FitSlices(histoDrift,2,0,400,100,0.05,0.95, kTRUE);
1025 TString end=histoDrift->GetName();
1026 Int_t pos=end.Index("_");
1027 end=end(pos,end.Capacity()-pos);
1028 TString graphName=graphDrift->ClassName();
1030 graphName.ToUpper();
1031 graphDrift->SetName(graphName);
1036 TObjArray* AliTPCcalibTime::GetGraphDrift(){
1038 // make a array of drift graphs
1040 TObjArray* arrayGraphDrift=new TObjArray();
1041 TIterator* iterator=fArrayDz->MakeIterator();
1043 THnSparse* addHist=NULL;
1044 while((addHist=(THnSparseF*)iterator->Next())) arrayGraphDrift->AddLast(GetGraphDrift(addHist->GetName()));
1045 return arrayGraphDrift;
1048 AliSplineFit* AliTPCcalibTime::GetFitDrift(const char* name){
1050 // Make a fit AliSplinefit of drift velocity
1052 TGraph* graphDrift=GetGraphDrift(name);
1053 AliSplineFit* fitDrift=NULL;
1054 if(graphDrift && graphDrift->GetN()){
1055 fitDrift=new AliSplineFit();
1056 fitDrift->SetGraph(graphDrift);
1057 fitDrift->SetMinPoints(graphDrift->GetN()+1);
1058 fitDrift->InitKnots(graphDrift,2,0,0.001);
1059 fitDrift->SplineFit(0);
1060 TString end=graphDrift->GetName();
1061 Int_t pos=end.Index("_");
1062 end=end(pos,end.Capacity()-pos);
1063 TString fitName=fitDrift->ClassName();
1066 //fitDrift->SetName(fitName);
1074 Long64_t AliTPCcalibTime::Merge(TCollection *const li) {
1076 // Object specific merging procedure
1078 TIterator* iter = li->MakeIterator();
1079 AliTPCcalibTime* cal = 0;
1081 while ((cal = (AliTPCcalibTime*)iter->Next())) {
1082 if (!cal->InheritsFrom(AliTPCcalibTime::Class())) {
1083 Error("Merge","Attempt to add object of class %s to a %s", cal->ClassName(), this->ClassName());
1086 for (Int_t imeas=0; imeas<3; imeas++){
1087 if (cal->GetHistVdriftLaserA(imeas) && cal->GetHistVdriftLaserA(imeas)){
1088 fHistVdriftLaserA[imeas]->Add(cal->GetHistVdriftLaserA(imeas));
1089 fHistVdriftLaserC[imeas]->Add(cal->GetHistVdriftLaserC(imeas));
1093 if (fTPCVertexCorrelation[0] && cal->fTPCVertexCorrelation[0]){
1094 for (Int_t imeas=0; imeas<5; imeas++){
1095 if (fTPCVertexCorrelation[imeas] && cal->fTPCVertexCorrelation[imeas]) fTPCVertexCorrelation[imeas]->Add(cal->fTPCVertexCorrelation[imeas]);
1099 if (fTPCVertex[0] && cal->fTPCVertex[0])
1100 for (Int_t imeas=0; imeas<12; imeas++){
1101 if (fTPCVertex[imeas] && cal->fTPCVertex[imeas]) fTPCVertex[imeas]->Add(cal->fTPCVertex[imeas]);
1104 if (fMemoryMode>0) for (Int_t imeas=0; imeas<5; imeas++){
1106 if ( cal->GetResHistoTPCCE(imeas) && cal->GetResHistoTPCCE(imeas)){
1107 fResHistoTPCCE[imeas]->Add(cal->fResHistoTPCCE[imeas]);
1109 fResHistoTPCCE[imeas]=(THnSparse*)cal->fResHistoTPCCE[imeas]->Clone();
1113 if ((fMemoryMode>0) &&cal->GetResHistoTPCITS(imeas) && cal->GetResHistoTPCITS(imeas)){
1114 if (fMemoryMode>1 || (imeas%2)==1) fResHistoTPCITS[imeas]->Add(cal->fResHistoTPCITS[imeas]);
1115 if (fMemoryMode>1) fResHistoTPCvertex[imeas]->Add(cal->fResHistoTPCvertex[imeas]);
1118 if ((fMemoryMode>1) && cal->fResHistoTPCTRD[imeas]){
1119 if (fResHistoTPCTRD[imeas])
1120 fResHistoTPCTRD[imeas]->Add(cal->fResHistoTPCTRD[imeas]);
1122 fResHistoTPCTRD[imeas]=(THnSparse*)cal->fResHistoTPCTRD[imeas]->Clone();
1125 if ((fMemoryMode>1) && cal->fResHistoTPCTOF[imeas]){
1126 if (fResHistoTPCTOF[imeas])
1127 fResHistoTPCTOF[imeas]->Add(cal->fResHistoTPCTOF[imeas]);
1129 fResHistoTPCTOF[imeas]=(THnSparse*)cal->fResHistoTPCTOF[imeas]->Clone();
1132 if (cal->fArrayLaserA){
1133 fArrayLaserA->Expand(fArrayLaserA->GetEntriesFast()+cal->fArrayLaserA->GetEntriesFast());
1134 fArrayLaserC->Expand(fArrayLaserC->GetEntriesFast()+cal->fArrayLaserC->GetEntriesFast());
1135 for (Int_t ical=0; ical<cal->fArrayLaserA->GetEntriesFast(); ical++){
1136 if (cal->fArrayLaserA->UncheckedAt(ical)) fArrayLaserA->AddLast(cal->fArrayLaserA->UncheckedAt(ical)->Clone());
1137 if (cal->fArrayLaserC->UncheckedAt(ical)) fArrayLaserC->AddLast(cal->fArrayLaserC->UncheckedAt(ical)->Clone());
1142 TObjArray* addArray=cal->GetHistoDrift();
1143 if(!addArray) return 0;
1144 TIterator* iterator = addArray->MakeIterator();
1146 THnSparse* addHist=NULL;
1147 if ((fMemoryMode>1)) while((addHist=(THnSparseF*)iterator->Next())){
1148 // if(!addHist) continue;
1150 THnSparse* localHist=(THnSparseF*)fArrayDz->FindObject(addHist->GetName());
1152 localHist=new THnSparseF(addHist->GetName(),"HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
1153 fArrayDz->AddLast(localHist);
1155 localHist->Add(addHist);
1158 for(Int_t i=0;i<10;i++) if (cal->GetCosmiMatchingHisto(i)) fCosmiMatchingHisto[i]->Add(cal->GetCosmiMatchingHisto(i));
1162 for (Int_t itype=0; itype<3; itype++){
1167 if (itype==0) {arr0=fAlignITSTPC; arr1=cal->fAlignITSTPC;}
1168 if (itype==1) {arr0=fAlignTRDTPC; arr1=cal->fAlignTRDTPC;}
1169 if (itype==2) {arr0=fAlignTOFTPC; arr1=cal->fAlignTOFTPC;}
1170 if (!arr1) continue;
1171 if (!arr0) arr0=new TObjArray(arr1->GetEntriesFast());
1172 if (arr1->GetEntriesFast()>arr0->GetEntriesFast()){
1173 arr0->Expand(arr1->GetEntriesFast());
1175 for (Int_t i=0;i<arr1->GetEntriesFast(); i++){
1176 AliRelAlignerKalman *kalman1 = (AliRelAlignerKalman *)arr1->UncheckedAt(i);
1177 AliRelAlignerKalman *kalman0 = (AliRelAlignerKalman *)arr0->UncheckedAt(i);
1178 if (!kalman1) continue;
1179 if (!kalman0) {arr0->AddAt(new AliRelAlignerKalman(*kalman1),i); continue;}
1180 kalman0->SetRejectOutliers(kFALSE);
1181 kalman0->Merge(kalman1);
1189 Bool_t AliTPCcalibTime::IsPair(const AliExternalTrackParam *tr0, const AliExternalTrackParam *tr1){
1191 // 0. Same direction - OPOSITE - cutDir +cutT
1192 TCut cutDir("cutDir","dir<-0.99")
1194 TCut cutT("cutT","abs(Tr1.fP[3]+Tr0.fP[3])<0.03")
1197 TCut cutD("cutD","abs(Tr0.fP[0]+Tr1.fP[0])<5")
1199 TCut cutPt("cutPt","abs(Tr1.fP[4]+Tr0.fP[4])<1&&abs(Tr0.fP[4])+abs(Tr1.fP[4])<10");
1202 const Double_t *p0 = tr0->GetParameter();
1203 const Double_t *p1 = tr1->GetParameter();
1204 fCosmiMatchingHisto[0]->Fill(p0[0]+p1[0]);
1205 fCosmiMatchingHisto[1]->Fill(p0[1]-p1[1]);
1206 fCosmiMatchingHisto[2]->Fill(tr1->GetAlpha()-tr0->GetAlpha()+TMath::Pi());
1207 fCosmiMatchingHisto[3]->Fill(p0[3]+p1[3]);
1208 fCosmiMatchingHisto[4]->Fill(p0[4]+p1[4]);
1210 if (TMath::Abs(p0[3]+p1[3])>fCutTheta) return kFALSE;
1211 if (TMath::Abs(p0[0]+p1[0])>fCutMaxD) return kFALSE;
1212 if (TMath::Abs(p0[1]-p1[1])>fCutMaxDz) return kFALSE;
1213 Double_t d0[3], d1[3];
1214 tr0->GetDirection(d0);
1215 tr1->GetDirection(d1);
1216 if (d0[0]*d1[0] + d0[1]*d1[1] + d0[2]*d1[2] >fCutMinDir) return kFALSE;
1218 fCosmiMatchingHisto[5]->Fill(p0[0]+p1[0]);
1219 fCosmiMatchingHisto[6]->Fill(p0[1]-p1[1]);
1220 fCosmiMatchingHisto[7]->Fill(tr1->GetAlpha()-tr0->GetAlpha()+TMath::Pi());
1221 fCosmiMatchingHisto[8]->Fill(p0[3]+p1[3]);
1222 fCosmiMatchingHisto[9]->Fill(p0[4]+p1[4]);
1226 Bool_t AliTPCcalibTime::IsCross(const AliESDtrack *const tr0, const AliESDtrack *const tr1){
1228 // check if the cosmic pair of tracks crossed A/C side
1230 Bool_t result= tr0->GetOuterParam()->GetZ()*tr1->GetOuterParam()->GetZ()<0;
1231 if (result==kFALSE) return result;
1236 Bool_t AliTPCcalibTime::IsSame(const AliESDtrack *const tr0, const AliESDtrack *const tr1){
1238 // track crossing the CE
1239 // 0. minimal number of clusters
1240 // 1. Same sector +-1
1241 // 2. Inner and outer track param on opposite side
1242 // 3. Outer and inner track parameter close each to other
1244 Bool_t result=kTRUE;
1246 // inner and outer on opposite sides in z
1248 const Int_t knclCut0 = 30;
1249 const Double_t kalphaCut = 0.4;
1251 // 0. minimal number of clusters
1253 if (tr0->GetTPCNcls()<knclCut0) return kFALSE;
1254 if (tr1->GetTPCNcls()<knclCut0) return kFALSE;
1256 // 1. alpha cut - sector+-1
1258 if (TMath::Abs(tr0->GetOuterParam()->GetAlpha()-tr1->GetOuterParam()->GetAlpha())>kalphaCut) return kFALSE;
1262 if (tr0->GetOuterParam()->GetZ()*tr0->GetInnerParam()->GetZ()>0) result&=kFALSE;
1263 if (tr1->GetOuterParam()->GetZ()*tr1->GetInnerParam()->GetZ()>0) result&=kFALSE;
1264 if (result==kFALSE){
1269 const Double_t *p0I = tr0->GetInnerParam()->GetParameter();
1270 const Double_t *p1I = tr1->GetInnerParam()->GetParameter();
1271 const Double_t *p0O = tr0->GetOuterParam()->GetParameter();
1272 const Double_t *p1O = tr1->GetOuterParam()->GetParameter();
1274 if (TMath::Abs(p0I[0]-p1I[0])>fCutMaxD) result&=kFALSE;
1275 if (TMath::Abs(p0I[1]-p1I[1])>fCutMaxDz) result&=kFALSE;
1276 if (TMath::Abs(p0I[2]-p1I[2])>fCutTheta) result&=kFALSE;
1277 if (TMath::Abs(p0I[3]-p1I[3])>fCutTheta) result&=kFALSE;
1278 if (TMath::Abs(p0O[0]-p1O[0])>fCutMaxD) result&=kFALSE;
1279 if (TMath::Abs(p0O[1]-p1O[1])>fCutMaxDz) result&=kFALSE;
1280 if (TMath::Abs(p0O[2]-p1O[2])>fCutTheta) result&=kFALSE;
1281 if (TMath::Abs(p0O[3]-p1O[3])>fCutTheta) result&=kFALSE;
1283 result=kTRUE; // just to put break point here
1289 void AliTPCcalibTime::ProcessSame(const AliESDtrack *const track, AliESDfriendTrack *const friendTrack, const AliESDEvent *const event){
1291 // Process TPC tracks crossing CE
1293 // 0. Select only track crossing the CE
1294 // 1. Cut on the track length
1295 // 2. Refit the the track on A and C side separatelly
1296 // 3. Fill time histograms
1297 const Int_t kMinNcl=100;
1298 const Int_t kMinNclS=25; // minimul number of clusters on the sides
1299 const Double_t pimass=TDatabasePDG::Instance()->GetParticle("pi+")->Mass();
1300 const Double_t kMaxDy=1; // maximal distance in y
1301 const Double_t kMaxDsnp=0.05; // maximal distance in snp
1302 const Double_t kMaxDtheta=0.05; // maximal distance in theta
1304 if (!friendTrack->GetTPCOut()) return;
1306 // 0. Select only track crossing the CE
1308 if (track->GetInnerParam()->GetZ()*friendTrack->GetTPCOut()->GetZ()>0) return;
1310 // 1. cut on track length
1312 if (track->GetTPCNcls()<kMinNcl) return;
1314 // 2. Refit track sepparatel on A and C side
1316 TObject *calibObject;
1317 AliTPCseed *seed = 0;
1318 for (Int_t l=0;(calibObject=friendTrack->GetCalibObject(l));++l) {
1319 if ((seed=dynamic_cast<AliTPCseed*>(calibObject))) break;
1323 AliExternalTrackParam trackIn(*track->GetInnerParam());
1324 AliExternalTrackParam trackOut(*track->GetOuterParam());
1325 Double_t cov[3]={0.01,0.,0.01}; //use the same errors
1326 Double_t xyz[3]={0,0.,0.0};
1328 Int_t nclIn=0,nclOut=0;
1329 trackIn.ResetCovariance(1000.);
1330 trackOut.ResetCovariance(1000.);
1335 for (Int_t irow=0;irow<159;irow++) {
1336 AliTPCclusterMI *cl=seed->GetClusterPointer(irow);
1338 if (cl->GetX()<80) continue;
1340 if (cl->GetDetector()%36<18) sideIn=1;
1341 if (cl->GetDetector()%36>=18) sideIn=-1;
1343 if (sideIn== -1 && (cl->GetDetector()%36)<18) break;
1344 if (sideIn== 1 &&(cl->GetDetector()%36)>=18) break;
1345 Int_t sector = cl->GetDetector();
1346 Float_t dalpha = TMath::DegToRad()*(sector%18*20.+10.)-trackIn.GetAlpha();
1347 if (TMath::Abs(dalpha)>0.01){
1348 if (!trackIn.Rotate(TMath::DegToRad()*(sector%18*20.+10.))) break;
1350 Double_t r[3]={cl->GetX(),cl->GetY(),cl->GetZ()};
1351 trackIn.GetXYZ(xyz);
1352 bz = AliTracker::GetBz(xyz);
1353 AliTracker::PropagateTrackToBxByBz(&trackIn,r[0],1.,pimass,kFALSE);
1354 if (!trackIn.PropagateTo(r[0],bz)) break;
1356 trackIn.Update(&r[1],cov);
1362 for (Int_t irow=159;irow>0;irow--) {
1363 AliTPCclusterMI *cl=seed->GetClusterPointer(irow);
1365 if (cl->GetX()<80) continue;
1367 if (cl->GetDetector()%36<18) sideOut=1;
1368 if (cl->GetDetector()%36>=18) sideOut=-1;
1369 if (sideIn==sideOut) break;
1371 if (sideOut== -1 && (cl->GetDetector()%36)<18) break;
1372 if (sideOut== 1 &&(cl->GetDetector()%36)>=18) break;
1374 Int_t sector = cl->GetDetector();
1375 Float_t dalpha = TMath::DegToRad()*(sector%18*20.+10.)-trackOut.GetAlpha();
1376 if (TMath::Abs(dalpha)>0.01){
1377 if (!trackOut.Rotate(TMath::DegToRad()*(sector%18*20.+10.))) break;
1379 Double_t r[3]={cl->GetX(),cl->GetY(),cl->GetZ()};
1380 trackOut.GetXYZ(xyz);
1381 bz = AliTracker::GetBz(xyz);
1382 AliTracker::PropagateTrackToBxByBz(&trackOut,r[0],1.,pimass,kFALSE);
1383 if (!trackOut.PropagateTo(r[0],bz)) break;
1385 trackOut.Update(&r[1],cov);
1387 trackOut.Rotate(trackIn.GetAlpha());
1388 Double_t meanX = (trackIn.GetX()+trackOut.GetX())*0.5;
1389 trackIn.PropagateTo(meanX,bz);
1390 trackOut.PropagateTo(meanX,bz);
1391 if (TMath::Abs(trackIn.GetY()-trackOut.GetY())>kMaxDy) return;
1392 if (TMath::Abs(trackIn.GetSnp()-trackOut.GetSnp())>kMaxDsnp) return;
1393 if (TMath::Abs(trackIn.GetTgl()-trackOut.GetTgl())>kMaxDtheta) return;
1394 if (TMath::Min(nclIn,nclOut)>kMinNclS){
1395 FillResHistoTPCCE(&trackIn,&trackOut);
1397 TTreeSRedirector *cstream = GetDebugStreamer();
1400 trackIn.GetXYZ(gxyz.GetMatrixArray());
1401 TTimeStamp tstamp(fTime);
1402 (*cstream)<<"tpctpc"<<
1403 "run="<<fRun<< // run number
1404 "event="<<fEvent<< // event number
1405 "time="<<fTime<< // time stamp of event
1406 "trigger="<<fTrigger<< // trigger
1407 "mag="<<fMagF<< // magnetic field
1409 "sideIn="<<sideIn<< // side at inner part
1410 "sideOut="<<sideOut<< // side at puter part
1411 "xyz.="<<&gxyz<< // global position
1412 "tIn.="<<&trackIn<< // refitterd track in
1413 "tOut.="<<&trackOut<< // refitter track out
1414 "nclIn="<<nclIn<< //
1415 "nclOut="<<nclOut<< //
1419 // 3. Fill time histograms
1420 // Debug stremaer expression
1421 // chainTPCTPC->Draw("(tIn.fP[1]-tOut.fP[1])*sign(-tIn.fP[3]):tIn.fP[3]","min(nclIn,nclOut)>30","")
1422 if (TMath::Min(nclIn,nclOut)>kMinNclS){
1423 fDz = trackOut.GetZ()-trackIn.GetZ();
1424 if (trackOut.GetTgl()<0) fDz*=-1.;
1425 TTimeStamp tstamp(fTime);
1426 Double_t ptrelative0 = AliTPCcalibDB::GetPTRelative(tstamp,fRun,0);
1427 Double_t ptrelative1 = AliTPCcalibDB::GetPTRelative(tstamp,fRun,1);
1428 Double_t vecDrift[4]={fTime,(ptrelative0+ptrelative1)/2.0,fDz/500.0,event->GetRunNumber()};
1430 // fill histograms per trigger class and itegrated
1432 THnSparse* curHist=NULL;
1433 for (Int_t itype=0; itype<2; itype++){
1434 TString name="MEAN_VDRIFT_CROSS_";
1436 name+=event->GetFiredTriggerClasses();
1441 curHist=(THnSparseF*)fArrayDz->FindObject(name);
1443 curHist=new THnSparseF(name,"HistVdrift;time;p/T ratio;Vdrift;run",4,fBinsVdrift,fXminVdrift,fXmaxVdrift);
1444 fArrayDz->AddLast(curHist);
1446 curHist->Fill(vecDrift);
1452 void AliTPCcalibTime::ProcessAlignITS(AliESDtrack *const track, const AliESDfriendTrack *const friendTrack, const AliESDEvent *const event, AliESDfriend *const esdFriend){
1454 // Process track - Update TPC-ITS alignment
1456 // 0. Apply standartd cuts
1457 // 1. Recalucluate the current statistic median/RMS
1458 // 2. Apply median+-rms cut
1459 // 3. Update kalman filter
1461 const Int_t kMinTPC = 80; // minimal number of TPC cluster
1462 const Int_t kMinITS = 3; // minimal number of ITS cluster
1463 const Double_t kMinZ = 10; // maximal dz distance
1464 const Double_t kMaxDy = 2.; // maximal dy distance
1465 const Double_t kMaxAngle= 0.07; // maximal angular distance
1466 const Double_t kSigmaCut= 5; // maximal sigma distance to median
1467 const Double_t kVdErr = 0.1; // initial uncertainty of the vd correction
1468 const Double_t kT0Err = 3.; // initial uncertainty of the T0 time
1469 const Double_t kVdYErr = 0.05; // initial uncertainty of the vd correction
1470 const Double_t kOutCut = 1.0; // outlyer cut in AliRelAlgnmentKalman
1471 const Double_t kMinPt = 0.3; // minimal pt
1472 const Double_t kMax1Pt=0.5; //maximal 1/pt distance
1473 const Int_t kN=50; // deepnes of history
1474 static Int_t kglast=0;
1475 static Double_t* kgdP[4]={new Double_t[kN], new Double_t[kN], new Double_t[kN], new Double_t[kN]};
1477 // 0. Apply standard cuts
1479 Int_t dummycl[1000];
1480 if (track->GetTPCNcls()<kMinTPC) return; // minimal amount of clusters cut
1481 if (!track->IsOn(AliESDtrack::kTPCrefit)) return;
1482 if (!track->GetInnerParam()) return;
1483 if (!track->GetOuterParam()) return;
1484 if (track->GetInnerParam()->Pt()<kMinPt) return;
1485 // exclude crossing track
1486 if (track->GetOuterParam()->GetZ()*track->GetInnerParam()->GetZ()<0) return;
1487 if (TMath::Abs(track->GetInnerParam()->GetZ())<kMinZ/3.) return;
1488 if (track->GetInnerParam()->GetX()>90) return;
1490 AliExternalTrackParam &pTPC=(AliExternalTrackParam &)(*(track->GetInnerParam()));
1492 AliExternalTrackParam pITS; // ITS standalone if possible
1493 AliExternalTrackParam pITS2; //TPC-ITS track
1494 if (friendTrack->GetITSOut()){
1495 pITS2=(*(friendTrack->GetITSOut())); //TPC-ITS track - snapshot ITS out
1496 pITS2.Rotate(pTPC.GetAlpha());
1497 AliTracker::PropagateTrackToBxByBz(&pITS2,pTPC.GetX(),0.1,0.1,kFALSE);
1500 AliESDfriendTrack *itsfriendTrack=0;
1502 // try to find standalone ITS track corresponing to the TPC if possible
1504 Bool_t hasAlone=kFALSE;
1505 Int_t ntracks=event->GetNumberOfTracks();
1506 for (Int_t i=0; i<ntracks; i++){
1507 AliESDtrack * trackITS = event->GetTrack(i);
1508 if (!trackITS) continue;
1509 if (trackITS->GetITSclusters(dummycl)<kMinITS) continue; // minimal amount of clusters
1510 itsfriendTrack = esdFriend->GetTrack(i);
1511 if (!itsfriendTrack) continue;
1512 if (!itsfriendTrack->GetITSOut()) continue;
1514 if (TMath::Abs(pTPC.GetTgl()-itsfriendTrack->GetITSOut()->GetTgl())> kMaxAngle) continue;
1515 if (TMath::Abs(pTPC.GetSigned1Pt()-itsfriendTrack->GetITSOut()->GetSigned1Pt())> kMax1Pt) continue;
1516 pITS=(*(itsfriendTrack->GetITSOut()));
1518 pITS.Rotate(pTPC.GetAlpha());
1519 AliTracker::PropagateTrackToBxByBz(&pITS,pTPC.GetX(),0.1,0.1,kFALSE);
1520 if (TMath::Abs(pTPC.GetY()-pITS.GetY())> kMaxDy) continue;
1521 if (TMath::Abs(pTPC.GetSnp()-pITS.GetSnp())> kMaxAngle) continue;
1525 if (track->GetITSclusters(dummycl)<kMinITS) return;
1526 pITS=pITS2; // use combined track if it has ITS
1529 if (TMath::Abs(pITS.GetY()-pTPC.GetY()) >kMaxDy) return;
1530 if (TMath::Abs(pITS.GetSnp()-pTPC.GetSnp())>kMaxAngle) return;
1531 if (TMath::Abs(pITS.GetTgl()-pTPC.GetTgl())>kMaxAngle) return;
1533 // 1. Update median and RMS info
1535 TVectorD vecDelta(5),vecMedian(5), vecRMS(5);
1536 TVectorD vecDeltaN(5);
1537 Double_t sign=(pITS.GetParameter()[1]>0)? 1.:-1.;
1539 for (Int_t i=0;i<4;i++){
1540 vecDelta[i]=(pITS.GetParameter()[i]-pTPC.GetParameter()[i])*sign;
1541 kgdP[i][kglast%kN]=vecDelta[i];
1544 Int_t entries=(kglast<kN)?kglast:kN;
1545 for (Int_t i=0;i<4;i++){
1546 vecMedian[i] = TMath::Median(entries,kgdP[i]);
1547 vecRMS[i] = TMath::RMS(entries,kgdP[i]);
1550 vecDeltaN[i] = (vecDelta[i]-vecMedian[i])/vecRMS[i];
1551 vecDeltaN[4]+= TMath::Abs(vecDeltaN[i]); //sum of abs residuals
1555 // 2. Apply median+-rms cut
1557 if (kglast<3) return; //median and RMS to be defined
1558 if ( vecDeltaN[4]/4.>kSigmaCut) return;
1560 // 3. Update alignment
1562 Int_t htime = (fTime-fTimeKalmanBin/2)/fTimeKalmanBin; //time bins number
1563 if (fAlignITSTPC->GetEntriesFast()<htime){
1564 fAlignITSTPC->Expand(htime*2+20);
1566 AliRelAlignerKalman* align = (AliRelAlignerKalman*)fAlignITSTPC->At(htime);
1568 // make Alignment object if doesn't exist
1569 align=new AliRelAlignerKalman();
1570 align->SetRunNumber(fRun);
1571 (*align->GetStateCov())(6,6)=kVdErr*kVdErr;
1572 (*align->GetStateCov())(7,7)=kT0Err*kT0Err;
1573 (*align->GetStateCov())(8,8)=kVdYErr*kVdYErr;
1574 align->SetOutRejSigma(kOutCut+kOutCut*kN);
1575 align->SetRejectOutliers(kFALSE);
1577 align->SetTPCvd(AliTPCcalibDB::Instance()->GetParameters()->GetDriftV()/1000000.);
1578 align->SetMagField(fMagF);
1579 fAlignITSTPC->AddAt(align,htime);
1581 align->AddTrackParams(&pITS,&pTPC);
1582 Double_t averageTime = fTime;
1583 if (align->GetTimeStamp()>0&&align->GetNUpdates()>0){
1584 averageTime=((Double_t(align->GetTimeStamp())*Double_t(align->GetNUpdates())+Double_t(fTime)))/(Double_t(align->GetNUpdates())+1.);
1586 align->SetTimeStamp(Int_t(averageTime));
1588 align->SetRunNumber(fRun );
1589 Float_t dca[2],cov[3];
1590 track->GetImpactParameters(dca,cov);
1591 if (TMath::Abs(dca[0])<kMaxDy){
1592 FillResHistoTPCITS(&pTPC,&pITS);
1593 FillResHistoTPC(track);
1596 Int_t nupdates=align->GetNUpdates();
1597 align->SetOutRejSigma(kOutCut+kOutCut*kN/Double_t(nupdates));
1598 align->SetRejectOutliers(kFALSE);
1599 TTreeSRedirector *cstream = GetDebugStreamer();
1600 if (cstream && align->GetState() && align->GetState()->GetNrows()>2 ){
1601 TVectorD gpTPC(3), gdTPC(3);
1602 TVectorD gpITS(3), gdITS(3);
1603 pTPC.GetXYZ(gpTPC.GetMatrixArray());
1604 pTPC.GetDirection(gdTPC.GetMatrixArray());
1605 pITS.GetXYZ(gpITS.GetMatrixArray());
1606 pITS.GetDirection(gdITS.GetMatrixArray());
1607 (*cstream)<<"itstpc"<<
1608 "run="<<fRun<< // run number
1609 "event="<<fEvent<< // event number
1610 "time="<<fTime<< // time stamp of event
1611 "trigger="<<fTrigger<< // trigger
1612 "mag="<<fMagF<< // magnetic field
1614 "hasAlone="<<hasAlone<< // has ITS standalone ?
1615 "track.="<<track<< // track info
1616 "nmed="<<kglast<< // number of entries to define median and RMS
1617 "vMed.="<<&vecMedian<< // median of deltas
1618 "vRMS.="<<&vecRMS<< // rms of deltas
1619 "vDelta.="<<&vecDelta<< // delta in respect to median
1620 "vDeltaN.="<<&vecDeltaN<< // normalized delta in respect to median
1621 "a.="<<align<< // current alignment
1622 "pITS.="<<&pITS<< // track param ITS
1623 "pITS2.="<<&pITS2<< // track param ITS+TPC
1624 "pTPC.="<<&pTPC<< // track param TPC
1625 "gpTPC.="<<&gpTPC<< // global position TPC
1626 "gdTPC.="<<&gdTPC<< // global direction TPC
1627 "gpITS.="<<&gpITS<< // global position ITS
1628 "gdITS.="<<&gdITS<< // global position ITS
1636 void AliTPCcalibTime::ProcessAlignTRD(AliESDtrack *const track, const AliESDfriendTrack *const friendTrack){
1638 // Process track - Update TPC-TRD alignment
1640 // 0. Apply standartd cuts
1641 // 1. Recalucluate the current statistic median/RMS
1642 // 2. Apply median+-rms cut
1643 // 3. Update kalman filter
1645 const Int_t kMinTPC = 80; // minimal number of TPC cluster
1646 const Int_t kMinTRD = 50; // minimal number of TRD cluster
1647 const Double_t kMinZ = 20; // maximal dz distance
1648 const Double_t kMaxDy = 5.; // maximal dy distance
1649 const Double_t kMaxAngle= 0.1; // maximal angular distance
1650 const Double_t kSigmaCut= 10; // maximal sigma distance to median
1651 const Double_t kVdErr = 0.1; // initial uncertainty of the vd correction
1652 const Double_t kT0Err = 3.; // initial uncertainty of the T0 time
1653 const Double_t kVdYErr = 0.05; // initial uncertainty of the vd correction
1654 const Double_t kOutCut = 1.0; // outlyer cut in AliRelAlgnmentKalman
1655 const Double_t kRefX = 275; // reference X
1656 const Int_t kN=50; // deepnes of history
1657 static Int_t kglast=0;
1658 static Double_t* kgdP[4]={new Double_t[kN], new Double_t[kN], new Double_t[kN], new Double_t[kN]};
1660 // 0. Apply standard cuts
1662 Int_t dummycl[1000];
1663 if (track->GetTRDclusters(dummycl)<kMinTRD) return; // minimal amount of clusters
1664 if (track->GetTPCNcls()<kMinTPC) return; // minimal amount of clusters cut
1665 if (!friendTrack->GetTRDIn()) return;
1666 if (!track->IsOn(AliESDtrack::kTRDrefit)) return;
1667 if (!track->IsOn(AliESDtrack::kTRDout)) return;
1668 if (!track->GetInnerParam()) return;
1669 if (!friendTrack->GetTPCOut()) return;
1670 // exclude crossing track
1671 if (friendTrack->GetTPCOut()->GetZ()*track->GetInnerParam()->GetZ()<0) return;
1672 if (TMath::Abs(track->GetInnerParam()->GetZ())<kMinZ) return;
1674 AliExternalTrackParam &pTPC=(AliExternalTrackParam &)(*(friendTrack->GetTPCOut()));
1675 AliTracker::PropagateTrackToBxByBz(&pTPC,kRefX,0.1,0.1,kFALSE);
1676 AliExternalTrackParam pTRD(*(friendTrack->GetTRDIn()));
1677 pTRD.Rotate(pTPC.GetAlpha());
1678 // pTRD.PropagateTo(pTPC.GetX(),fMagF);
1679 AliTracker::PropagateTrackToBxByBz(&pTRD,pTPC.GetX(),0.1,0.1,kFALSE);
1681 ((Double_t*)pTRD.GetCovariance())[2]+=3.*3.; // increas sys errors
1682 ((Double_t*)pTRD.GetCovariance())[9]+=0.1*0.1; // increse sys errors
1684 if (TMath::Abs(pTRD.GetY()-pTPC.GetY()) >kMaxDy) return;
1685 if (TMath::Abs(pTRD.GetSnp()-pTPC.GetSnp())>kMaxAngle) return;
1686 // if (TMath::Abs(pTRD.GetTgl()-pTPC.GetTgl())>kMaxAngle) return;
1688 // 1. Update median and RMS info
1690 TVectorD vecDelta(5),vecMedian(5), vecRMS(5);
1691 TVectorD vecDeltaN(5);
1692 Double_t sign=(pTRD.GetParameter()[1]>0)? 1.:-1.;
1694 for (Int_t i=0;i<4;i++){
1695 vecDelta[i]=(pTRD.GetParameter()[i]-pTPC.GetParameter()[i])*sign;
1696 kgdP[i][kglast%kN]=vecDelta[i];
1699 Int_t entries=(kglast<kN)?kglast:kN;
1700 for (Int_t i=0;i<4;i++){
1701 vecMedian[i] = TMath::Median(entries,kgdP[i]);
1703 vecRMS[i] = TMath::RMS(entries,kgdP[i]);
1706 vecDeltaN[i] = (vecDelta[i]-vecMedian[i])/vecRMS[i];
1707 vecDeltaN[4]+= TMath::Abs(vecDeltaN[i]); //sum of abs residuals
1711 // 2. Apply median+-rms cut
1713 if (kglast<3) return; //median and RMS to be defined
1714 if ( vecDeltaN[4]/4.>kSigmaCut) return;
1716 // 3. Update alignment
1718 //Int_t htime = fTime/3600; //time in hours
1719 Int_t htime = (Int_t)(fTime-fTimeKalmanBin/2)/fTimeKalmanBin; //time in half hour
1720 if (fAlignTRDTPC->GetEntriesFast()<htime){
1721 fAlignTRDTPC->Expand(htime*2+20);
1723 AliRelAlignerKalman* align = (AliRelAlignerKalman*)fAlignTRDTPC->At(htime);
1725 // make Alignment object if doesn't exist
1726 align=new AliRelAlignerKalman();
1727 align->SetRunNumber(fRun);
1728 (*align->GetStateCov())(6,6)=kVdErr*kVdErr;
1729 (*align->GetStateCov())(7,7)=kT0Err*kT0Err;
1730 (*align->GetStateCov())(8,8)=kVdYErr*kVdYErr;
1731 align->SetOutRejSigma(kOutCut+kOutCut*kN);
1732 align->SetRejectOutliers(kFALSE);
1733 align->SetTPCvd(AliTPCcalibDB::Instance()->GetParameters()->GetDriftV()/1000000.);
1734 align->SetMagField(fMagF);
1735 fAlignTRDTPC->AddAt(align,htime);
1737 align->AddTrackParams(&pTRD,&pTPC);
1738 //align->SetTimeStamp(fTime);
1739 Double_t averageTime = fTime;
1740 if (align->GetTimeStamp()>0 && align->GetNUpdates()>0) {
1741 averageTime = (((Double_t)fTime) + ((Double_t)align->GetTimeStamp())*align->GetNUpdates()) / (align->GetNUpdates() + 1.);
1742 //printf("align->GetTimeStamp() %d, align->GetNUpdates() %d \n", align->GetTimeStamp(), align->GetNUpdates());
1744 align->SetTimeStamp((Int_t)averageTime);
1746 //printf("fTime %d, averageTime %d \n", fTime, (Int_t)averageTime);
1748 align->SetRunNumber(fRun );
1749 Float_t dca[2],cov[3];
1750 track->GetImpactParameters(dca,cov);
1751 if (TMath::Abs(dca[0])<kMaxDy){
1752 FillResHistoTPCTRD(&pTPC,&pTRD); //only primaries
1755 Int_t nupdates=align->GetNUpdates();
1756 align->SetOutRejSigma(kOutCut+kOutCut*kN/Double_t(nupdates));
1757 align->SetRejectOutliers(kFALSE);
1758 TTreeSRedirector *cstream = GetDebugStreamer();
1759 if (cstream && align->GetState() && align->GetState()->GetNrows()>2 ){
1760 TVectorD gpTPC(3), gdTPC(3);
1761 TVectorD gpTRD(3), gdTRD(3);
1762 pTPC.GetXYZ(gpTPC.GetMatrixArray());
1763 pTPC.GetDirection(gdTPC.GetMatrixArray());
1764 pTRD.GetXYZ(gpTRD.GetMatrixArray());
1765 pTRD.GetDirection(gdTRD.GetMatrixArray());
1766 (*cstream)<<"trdtpc"<<
1767 "run="<<fRun<< // run number
1768 "event="<<fEvent<< // event number
1769 "time="<<fTime<< // time stamp of event
1770 "trigger="<<fTrigger<< // trigger
1771 "mag="<<fMagF<< // magnetic field
1773 "nmed="<<kglast<< // number of entries to define median and RMS
1774 "vMed.="<<&vecMedian<< // median of deltas
1775 "vRMS.="<<&vecRMS<< // rms of deltas
1776 "vDelta.="<<&vecDelta<< // delta in respect to median
1777 "vDeltaN.="<<&vecDeltaN<< // normalized delta in respect to median
1778 "t.="<<track<< // ful track - find proper cuts
1779 "a.="<<align<< // current alignment
1780 "pTRD.="<<&pTRD<< // track param TRD
1781 "pTPC.="<<&pTPC<< // track param TPC
1782 "gpTPC.="<<&gpTPC<< // global position TPC
1783 "gdTPC.="<<&gdTPC<< // global direction TPC
1784 "gpTRD.="<<&gpTRD<< // global position TRD
1785 "gdTRD.="<<&gdTRD<< // global position TRD
1791 void AliTPCcalibTime::ProcessAlignTOF(AliESDtrack *const track, const AliESDfriendTrack *const friendTrack){
1794 // Process track - Update TPC-TOF alignment
1796 // -1. Make a TOF "track"
1797 // 0. Apply standartd cuts
1798 // 1. Recalucluate the current statistic median/RMS
1799 // 2. Apply median+-rms cut
1800 // 3. Update kalman filter
1802 const Int_t kMinTPC = 80; // minimal number of TPC cluster
1803 // const Double_t kMinZ = 10; // maximal dz distance
1804 const Double_t kMaxDy = 5.; // maximal dy distance
1805 const Double_t kMaxAngle= 0.05; // maximal angular distance
1806 const Double_t kSigmaCut= 5; // maximal sigma distance to median
1807 const Double_t kVdErr = 0.1; // initial uncertainty of the vd correction
1808 const Double_t kT0Err = 3.; // initial uncertainty of the T0 time
1809 const Double_t kVdYErr = 0.05; // initial uncertainty of the vd correction
1811 const Double_t kOutCut = 1.0; // outlyer cut in AliRelAlgnmentKalman
1812 const Int_t kN=50; // deepnes of history
1813 static Int_t kglast=0;
1814 static Double_t* kgdP[4]={new Double_t[kN], new Double_t[kN], new Double_t[kN], new Double_t[kN]};
1816 // -1. Make a TOF track-
1817 // Clusters are not in friends - use alingment points
1819 if (track->GetTOFsignal()<=0) return;
1820 if (!friendTrack->GetTPCOut()) return;
1821 if (!track->GetInnerParam()) return;
1822 if (!friendTrack->GetTPCOut()) return;
1823 const AliTrackPointArray *points=friendTrack->GetTrackPointArray();
1824 if (!points) return;
1825 AliExternalTrackParam pTPC(*(friendTrack->GetTPCOut()));
1826 AliExternalTrackParam pTOF(pTPC);
1827 Double_t mass = TDatabasePDG::Instance()->GetParticle("mu+")->Mass();
1828 Int_t npoints = points->GetNPoints();
1829 AliTrackPoint point;
1832 for (Int_t ipoint=0;ipoint<npoints;ipoint++){
1833 points->GetPoint(point,ipoint);
1836 Double_t r=TMath::Sqrt(xyz[0]*xyz[0]+xyz[1]*xyz[1]);
1837 if (r<350) continue;
1838 if (r>400) continue;
1839 AliTracker::PropagateTrackToBxByBz(&pTPC,r,mass,2.,kTRUE);
1840 AliTracker::PropagateTrackToBxByBz(&pTPC,r,mass,0.1,kTRUE);
1841 AliTrackPoint lpoint = point.Rotate(pTPC.GetAlpha());
1842 pTPC.PropagateTo(lpoint.GetX(),fMagF);
1844 ((Double_t*)pTOF.GetParameter())[0] =lpoint.GetY();
1845 ((Double_t*)pTOF.GetParameter())[1] =lpoint.GetZ();
1846 ((Double_t*)pTOF.GetCovariance())[0]+=3.*3./12.;
1847 ((Double_t*)pTOF.GetCovariance())[2]+=3.*3./12.;
1848 ((Double_t*)pTOF.GetCovariance())[5]+=0.1*0.1;
1849 ((Double_t*)pTOF.GetCovariance())[9]+=0.1*0.1;
1852 if (naccept==0) return; // no tof match clusters
1854 // 0. Apply standard cuts
1856 if (track->GetTPCNcls()<kMinTPC) return; // minimal amount of clusters cut
1857 // exclude crossing track
1858 if (friendTrack->GetTPCOut()->GetZ()*track->GetInnerParam()->GetZ()<0) return;
1860 if (TMath::Abs(pTOF.GetY()-pTPC.GetY()) >kMaxDy) return;
1861 if (TMath::Abs(pTOF.GetSnp()-pTPC.GetSnp())>kMaxAngle) return;
1862 if (TMath::Abs(pTOF.GetTgl()-pTPC.GetTgl())>kMaxAngle) return;
1864 // 1. Update median and RMS info
1866 TVectorD vecDelta(5),vecMedian(5), vecRMS(5);
1867 TVectorD vecDeltaN(5);
1868 Double_t sign=(pTOF.GetParameter()[1]>0)? 1.:-1.;
1870 for (Int_t i=0;i<4;i++){
1871 vecDelta[i]=(pTOF.GetParameter()[i]-pTPC.GetParameter()[i])*sign;
1872 kgdP[i][kglast%kN]=vecDelta[i];
1875 Int_t entries=(kglast<kN)?kglast:kN;
1877 for (Int_t i=0;i<4;i++){
1878 vecMedian[i] = TMath::Median(entries,kgdP[i]);
1879 vecRMS[i] = TMath::RMS(entries,kgdP[i]);
1882 vecDeltaN[i] = (vecDelta[i]-vecMedian[i])/(vecRMS[i]+1.);
1883 vecDeltaN[4]+= TMath::Abs(vecDeltaN[i]); //sum of abs residuals
1884 if (TMath::Abs(vecDeltaN[i])>kSigmaCut) isOK=kFALSE;
1888 // 2. Apply median+-rms cut
1890 if (kglast<10) return; //median and RMS to be defined
1893 // 3. Update alignment
1895 //Int_t htime = fTime/3600; //time in hours
1896 Int_t htime = (Int_t)(fTime-fTimeKalmanBin)/fTimeKalmanBin; //time bin
1897 if (fAlignTOFTPC->GetEntriesFast()<htime){
1898 fAlignTOFTPC->Expand(htime*2+20);
1900 AliRelAlignerKalman* align = (AliRelAlignerKalman*)fAlignTOFTPC->At(htime);
1902 // make Alignment object if doesn't exist
1903 align=new AliRelAlignerKalman();
1904 align->SetRunNumber(fRun);
1905 (*align->GetStateCov())(6,6)=kVdErr*kVdErr;
1906 (*align->GetStateCov())(7,7)=kT0Err*kT0Err;
1907 (*align->GetStateCov())(8,8)=kVdYErr*kVdYErr;
1908 align->SetOutRejSigma(kOutCut+kOutCut*kN);
1909 align->SetRejectOutliers(kFALSE);
1910 align->SetTPCvd(AliTPCcalibDB::Instance()->GetParameters()->GetDriftV()/1000000.);
1911 align->SetMagField(fMagF);
1912 fAlignTOFTPC->AddAt(align,htime);
1914 align->AddTrackParams(&pTOF,&pTPC);
1915 Float_t dca[2],cov[3];
1916 track->GetImpactParameters(dca,cov);
1917 if (TMath::Abs(dca[0])<kMaxDy){
1918 FillResHistoTPCTOF(&pTPC,&pTOF);
1920 //align->SetTimeStamp(fTime);
1921 Double_t averageTime = fTime;
1922 if (align->GetTimeStamp()>0 && align->GetNUpdates()>0) {
1923 averageTime = (((Double_t)fTime) + ((Double_t)align->GetTimeStamp())*align->GetNUpdates()) / (align->GetNUpdates() + 1.);
1924 //printf("align->GetTimeStamp() %d, align->GetNUpdates() %d \n", align->GetTimeStamp(), align->GetNUpdates());
1926 align->SetTimeStamp((Int_t)averageTime);
1928 //printf("fTime %d, averageTime %d \n", fTime, (Int_t)averageTime);
1930 align->SetRunNumber(fRun );
1932 Int_t nupdates=align->GetNUpdates();
1933 align->SetOutRejSigma(kOutCut+kOutCut*kN/Double_t(nupdates));
1934 align->SetRejectOutliers(kFALSE);
1935 TTreeSRedirector *cstream = GetDebugStreamer();
1936 if (cstream && align->GetState() && align->GetState()->GetNrows()>2 ){
1937 TVectorD gpTPC(3), gdTPC(3);
1938 TVectorD gpTOF(3), gdTOF(3);
1939 pTPC.GetXYZ(gpTPC.GetMatrixArray());
1940 pTPC.GetDirection(gdTPC.GetMatrixArray());
1941 pTOF.GetXYZ(gpTOF.GetMatrixArray());
1942 pTOF.GetDirection(gdTOF.GetMatrixArray());
1943 (*cstream)<<"toftpc"<<
1944 "run="<<fRun<< // run number
1945 "event="<<fEvent<< // event number
1946 "time="<<fTime<< // time stamp of event
1947 "trigger="<<fTrigger<< // trigger
1948 "mag="<<fMagF<< // magnetic field
1950 "nmed="<<kglast<< // number of entries to define median and RMS
1951 "vMed.="<<&vecMedian<< // median of deltas
1952 "vRMS.="<<&vecRMS<< // rms of deltas
1953 "vDelta.="<<&vecDelta<< // delta in respect to median
1954 "vDeltaN.="<<&vecDeltaN<< // normalized delta in respect to median
1955 "t.="<<track<< // ful track - find proper cuts
1956 "a.="<<align<< // current alignment
1957 "pTOF.="<<&pTOF<< // track param TOF
1958 "pTPC.="<<&pTPC<< // track param TPC
1959 "gpTPC.="<<&gpTPC<< // global position TPC
1960 "gdTPC.="<<&gdTPC<< // global direction TPC
1961 "gpTOF.="<<&gpTOF<< // global position TOF
1962 "gdTOF.="<<&gdTOF<< // global position TOF
1968 void AliTPCcalibTime::BookDistortionMaps(){
1970 // Book ndimensional histograms of distortions/residuals
1971 // Only primary tracks are selected for analysis
1974 Double_t xminTrack[5], xmaxTrack[5];
1976 TString axisName[5];
1977 TString axisTitle[5];
1980 axisName[0] ="#Delta";
1981 axisTitle[0] ="#Delta";
1984 xminTrack[1] =-1.1; xmaxTrack[1]=1.1;
1985 axisName[1] ="tanTheta";
1986 axisTitle[1] ="tan(#Theta)";
1989 xminTrack[2] =-TMath::Pi(); xmaxTrack[2]=TMath::Pi();
1991 axisTitle[2] ="#phi";
1994 xminTrack[3] =-1.; xmaxTrack[3]=1.; // 0.33 GeV cut
1996 axisTitle[3] ="snp";
1999 xminTrack[4] =120.; xmaxTrack[4]=215.; // crossing radius for CE only
2001 axisTitle[4] ="r(cm)";
2004 xminTrack[0] =-1.5; xmaxTrack[0]=1.5; //
2005 fResHistoTPCCE[0] = new THnSparseS("TPCCE#Delta_{Y} (cm)","#Delta_{Y} (cm)", 5, binsTrack,xminTrack, xmaxTrack);
2006 fResHistoTPCITS[0] = new THnSparseS("TPCITS#Delta_{Y} (cm)","#Delta_{Y} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2007 fResHistoTPCvertex[0] = new THnSparseS("TPCVertex#Delta_{Y} (cm)","#Delta_{Y} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2008 xminTrack[0] =-1.5; xmaxTrack[0]=1.5; //
2009 fResHistoTPCTRD[0] = new THnSparseS("TPCTRD#Delta_{Y} (cm)","#Delta_{Y} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2010 xminTrack[0] =-5; xmaxTrack[0]=5; //
2011 fResHistoTPCTOF[0] = new THnSparseS("TPCTOF#Delta_{Y} (cm)","#Delta_{Y} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2014 xminTrack[0] =-3.; xmaxTrack[0]=3.; //
2015 fResHistoTPCCE[1] = new THnSparseS("TPCCE#Delta_{Z} (cm)","#Delta_{Z} (cm)", 5, binsTrack,xminTrack, xmaxTrack);
2016 fResHistoTPCITS[1] = new THnSparseS("TPCITS#Delta_{Z} (cm)","#Delta_{Z} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2017 fResHistoTPCvertex[1] = new THnSparseS("TPCVertex#Delta_{Z} (cm)","#Delta_{Z} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2018 fResHistoTPCTRD[1] = new THnSparseS("TPCTRD#Delta_{Z} (cm)","#Delta_{Z} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2019 xminTrack[0] =-5.; xmaxTrack[0]=5.; //
2020 fResHistoTPCTOF[1] = new THnSparseS("TPCTOF#Delta_{Z} (cm)","#Delta_{Z} (cm)", 4, binsTrack,xminTrack, xmaxTrack);
2023 xminTrack[0] =-0.015; xmaxTrack[0]=0.015; //
2024 fResHistoTPCCE[2] = new THnSparseS("TPCCE#Delta_{#phi}","#Delta_{#phi}", 5, binsTrack,xminTrack, xmaxTrack);
2025 fResHistoTPCITS[2] = new THnSparseS("TPCITS#Delta_{#phi}","#Delta_{#phi}", 4, binsTrack,xminTrack, xmaxTrack);
2026 fResHistoTPCvertex[2] = new THnSparseS("TPCITSv#Delta_{#phi}","#Delta_{#phi}", 4, binsTrack,xminTrack, xmaxTrack);
2027 fResHistoTPCTRD[2] = new THnSparseS("TPCTRD#Delta_{#phi}","#Delta_{#phi}", 4, binsTrack,xminTrack, xmaxTrack);
2028 fResHistoTPCTOF[2] = new THnSparseS("TPCTOF#Delta_{#phi}","#Delta_{#phi}", 4, binsTrack,xminTrack, xmaxTrack);
2031 xminTrack[0] =-0.025; xmaxTrack[0]=0.025; //
2032 fResHistoTPCCE[3] = new THnSparseS("TPCCE#Delta_{#theta}","#Delta_{#theta}", 5, binsTrack,xminTrack, xmaxTrack);
2033 fResHistoTPCITS[3] = new THnSparseS("TPCITS#Delta_{#theta}","#Delta_{#theta}", 4, binsTrack,xminTrack, xmaxTrack);
2034 fResHistoTPCvertex[3] = new THnSparseS("TPCITSv#Delta_{#theta}","#Delta_{#theta}", 4, binsTrack,xminTrack, xmaxTrack);
2035 fResHistoTPCTRD[3] = new THnSparseS("TPCTRD#Delta_{#theta}","#Delta_{#theta}", 4, binsTrack,xminTrack, xmaxTrack);
2036 fResHistoTPCTOF[3] = new THnSparseS("TPCTOF#Delta_{#theta}","#Delta_{#theta}", 4, binsTrack,xminTrack, xmaxTrack);
2039 xminTrack[0] =-0.2; xmaxTrack[0]=0.2; //
2040 fResHistoTPCCE[4] = new THnSparseS("TPCCE#Delta_{1/pt}","#Delta_{1/pt}", 5, binsTrack,xminTrack, xmaxTrack);
2041 fResHistoTPCITS[4] = new THnSparseS("TPCITS#Delta_{1/pt}","#Delta_{1/pt}", 4, binsTrack,xminTrack, xmaxTrack);
2042 fResHistoTPCvertex[4] = new THnSparseS("TPCITSv#Delta_{1/pt}","#Delta_{1/pt}", 4, binsTrack,xminTrack, xmaxTrack);
2043 fResHistoTPCTRD[4] = new THnSparseS("TPCTRD#Delta_{1/pt}","#Delta_{1/pt}", 4, binsTrack,xminTrack, xmaxTrack);
2044 fResHistoTPCTOF[4] = new THnSparseS("TPCTOF#Delta_{1/pt}","#Delta_{1/pt}", 4, binsTrack,xminTrack, xmaxTrack);
2046 for (Int_t ivar=0;ivar<4;ivar++){
2047 for (Int_t ivar2=0;ivar2<5;ivar2++){
2048 fResHistoTPCCE[ivar]->GetAxis(ivar2)->SetName(axisName[ivar2].Data());
2049 fResHistoTPCCE[ivar]->GetAxis(ivar2)->SetTitle(axisTitle[ivar2].Data());
2051 fResHistoTPCITS[ivar]->GetAxis(ivar2)->SetName(axisName[ivar2].Data());
2052 fResHistoTPCITS[ivar]->GetAxis(ivar2)->SetTitle(axisTitle[ivar2].Data());
2053 fResHistoTPCTRD[ivar]->GetAxis(ivar2)->SetName(axisName[ivar2].Data());
2054 fResHistoTPCTRD[ivar]->GetAxis(ivar2)->SetTitle(axisTitle[ivar2].Data());
2055 fResHistoTPCvertex[ivar]->GetAxis(ivar2)->SetName(axisName[ivar2].Data());
2056 fResHistoTPCvertex[ivar]->GetAxis(ivar2)->SetTitle(axisTitle[ivar2].Data());
2061 // Book vertex: time histograms
2063 Int_t binsVertex[2]={500, fTimeBins};
2064 Double_t aminVertex[2]={-5,fTimeStart};
2065 Double_t amaxVertex[2]={5, fTimeEnd};
2066 const char* hnames[12]={"TPCXAside", "TPCXCside","TPCXACdiff","TPCXAPCdiff",
2067 "TPCYAside", "TPCYCside","TPCYACdiff","TPCYAPCdiff",
2068 "TPCZAPCside", "TPCZAMCside","TPCZACdiff","TPCZAPCdiff"};
2069 const char* anames[12]={"x (cm) - A side ", "x (cm) - C side","#Delta_{x} (cm) - TPC-A-C","#Delta_{x} (cm) - TPC-Common",
2070 "y (cm) - A side ", "y (cm) - C side","#Delta_{x} (cm) - TPC-A-C","#Delta_{y} (cm) - TPC-Common",
2071 "z (cm)", "#Delta_{Z} (cm) A-C side","#Delta_{x} (cm) - TPC-A-C","#Delta_{Z} (cm) TPC-common"};
2072 for (Int_t ihis=0; ihis<12; ihis++) {
2073 if (ihis>=8) aminVertex[0]=-20.;
2074 if (ihis>=8) amaxVertex[0]=20.;
2075 fTPCVertex[ihis]=new THnSparseF(hnames[ihis],hnames[ihis],2,binsVertex,aminVertex,amaxVertex);
2076 fTPCVertex[ihis]->GetAxis(1)->SetTitle("Time");
2077 fTPCVertex[ihis]->GetAxis(0)->SetTitle(anames[ihis]);
2080 Int_t binsVertexC[2]={40, 300};
2081 Double_t aminVertexC[2]={-20,-30};
2082 Double_t amaxVertexC[2]={20,30};
2083 const char* hnamesC[5]={"TPCA_TPC","TPCC_TPC","TPCA_ITS","TPCC_ITS","TPC_ITS"};
2084 for (Int_t ihis=0; ihis<5; ihis++) {
2085 fTPCVertexCorrelation[ihis]=new THnSparseF(hnamesC[ihis],hnamesC[ihis],2,binsVertexC,aminVertexC,amaxVertexC);
2086 fTPCVertexCorrelation[ihis]->GetAxis(1)->SetTitle("z (cm)");
2087 fTPCVertexCorrelation[ihis]->GetAxis(0)->SetTitle("z (cm)");
2092 void AliTPCcalibTime::FillResHistoTPCCE(const AliExternalTrackParam * pTPCIn, const AliExternalTrackParam * pTPCOut ){
2094 // fill residual histograms pTPCOut-pTPCin - trac crossing CE
2097 if (fMemoryMode<2) return;
2100 pTPCIn->GetXYZ(xyz);
2101 Double_t phi= TMath::ATan2(xyz[1],xyz[0]);
2102 histoX[1]= pTPCIn->GetTgl();
2104 histoX[3]= pTPCIn->GetSnp();
2105 histoX[4]= pTPCIn->GetX();
2106 AliExternalTrackParam lout(*pTPCOut);
2107 lout.Rotate(pTPCIn->GetAlpha());
2108 lout.PropagateTo(pTPCIn->GetX(),fMagF);
2110 for (Int_t ihisto=0; ihisto<5; ihisto++){
2111 histoX[0]=lout.GetParameter()[ihisto]-pTPCIn->GetParameter()[ihisto];
2112 fResHistoTPCCE[ihisto]->Fill(histoX);
2115 void AliTPCcalibTime::FillResHistoTPCITS(const AliExternalTrackParam * pTPCIn, const AliExternalTrackParam * pITSOut ){
2117 // fill residual histograms pTPCIn-pITSOut
2118 // Histogram is filled only for primary tracks
2122 pTPCIn->GetXYZ(xyz);
2123 Double_t phi= TMath::ATan2(xyz[1],xyz[0]);
2124 histoX[1]= pTPCIn->GetTgl();
2126 histoX[3]= pTPCIn->GetSnp();
2127 AliExternalTrackParam lits(*pITSOut);
2128 lits.Rotate(pTPCIn->GetAlpha());
2129 lits.PropagateTo(pTPCIn->GetX(),fMagF);
2131 for (Int_t ihisto=0; ihisto<5; ihisto++){
2132 histoX[0]=pTPCIn->GetParameter()[ihisto]-lits.GetParameter()[ihisto];
2133 fResHistoTPCITS[ihisto]->Fill(histoX);
2138 void AliTPCcalibTime::FillResHistoTPC(const AliESDtrack * pTrack){
2140 // fill residual histograms pTPC - vertex
2141 // Histogram is filled only for primary tracks
2143 if (fMemoryMode<2) return;
2145 const AliExternalTrackParam * pTPCIn = pTrack->GetInnerParam();
2146 AliExternalTrackParam pTPCvertex(*(pTrack->GetInnerParam()));
2148 AliExternalTrackParam lits(*pTrack);
2149 if (TMath::Abs(pTrack->GetY())>3) return; // beam pipe
2150 pTPCvertex.Rotate(lits.GetAlpha());
2151 //pTPCvertex.PropagateTo(pTPCvertex->GetX(),fMagF);
2152 AliTracker::PropagateTrackToBxByBz(&pTPCvertex,lits.GetX(),0.1,2,kFALSE);
2153 AliTracker::PropagateTrackToBxByBz(&pTPCvertex,lits.GetX(),0.1,0.1,kFALSE);
2155 pTPCIn->GetXYZ(xyz);
2156 Double_t phi= TMath::ATan2(xyz[1],xyz[0]);
2157 histoX[1]= pTPCIn->GetTgl();
2159 histoX[3]= pTPCIn->GetSnp();
2161 Float_t dca[2], cov[3];
2162 pTrack->GetImpactParametersTPC(dca,cov);
2163 for (Int_t ihisto=0; ihisto<5; ihisto++){
2164 histoX[0]=pTPCvertex.GetParameter()[ihisto]-lits.GetParameter()[ihisto];
2165 // if (ihisto<2) histoX[0]=dca[ihisto];
2166 fResHistoTPCvertex[ihisto]->Fill(histoX);
2171 void AliTPCcalibTime::FillResHistoTPCTRD(const AliExternalTrackParam * pTPCOut, const AliExternalTrackParam * pTRDIn ){
2173 // fill resuidual histogram TPCout-TRDin
2175 if (fMemoryMode<2) return;
2178 pTPCOut->GetXYZ(xyz);
2179 Double_t phi= TMath::ATan2(xyz[1],xyz[0]);
2180 histoX[1]= pTPCOut->GetTgl();
2182 histoX[3]= pTPCOut->GetSnp();
2184 AliExternalTrackParam ltrd(*pTRDIn);
2185 ltrd.Rotate(pTPCOut->GetAlpha());
2186 // ltrd.PropagateTo(pTPCOut->GetX(),fMagF);
2187 AliTracker::PropagateTrackToBxByBz(<rd,pTPCOut->GetX(),0.1,0.1,kFALSE);
2189 for (Int_t ihisto=0; ihisto<5; ihisto++){
2190 histoX[0]=pTPCOut->GetParameter()[ihisto]-ltrd.GetParameter()[ihisto];
2191 fResHistoTPCTRD[ihisto]->Fill(histoX);
2196 void AliTPCcalibTime::FillResHistoTPCTOF(const AliExternalTrackParam * pTPCOut, const AliExternalTrackParam * pTOFIn ){
2198 // fill resuidual histogram TPCout-TOFin
2199 // track propagated to the TOF position
2200 if (fMemoryMode<2) return;
2204 AliExternalTrackParam ltpc(*pTPCOut);
2205 ltpc.Rotate(pTOFIn->GetAlpha());
2206 AliTracker::PropagateTrackToBxByBz(<pc,pTOFIn->GetX(),0.1,0.1,kFALSE);
2209 Double_t phi= TMath::ATan2(xyz[1],xyz[0]);
2210 histoX[1]= ltpc.GetTgl();
2212 histoX[3]= ltpc.GetSnp();
2214 for (Int_t ihisto=0; ihisto<2; ihisto++){
2215 histoX[0]=ltpc.GetParameter()[ihisto]-pTOFIn->GetParameter()[ihisto];
2216 fResHistoTPCTOF[ihisto]->Fill(histoX);