#include "AliHMPIDParam.h" //GetTrackPoint(),PropagateBack()
#include "AliHMPIDPid.h" //Recon(),reconHTA()
#include "AliHMPIDRecon.h" //Recon()
-#include "AliHMPIDRecoParam.h" //Recon()
+#include "AliHMPIDRecoParamV1.h" //Recon()
#include "AliHMPIDReconstructor.h"//Recon()
#include "AliHMPIDReconHTA.h" //ReconHTA()
+#include <AliLog.h> //Recon()
#include <AliESDEvent.h> //PropagateBack(),Recon()
#include <AliESDtrack.h> //Intersect()
#include <AliTracker.h>
#include <AliAlignObj.h> //GetTrackPoint()
#include <AliCDBManager.h> //PropageteBack()
#include <AliCDBEntry.h> //PropageteBack()
-#include "AliHMPIDRecoParam.h" //Recon()
-//.
+#include "TTreeStream.h" // debug streamer
+//
// HMPID base class fo tracking
//.
//.
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
AliHMPIDTracker::AliHMPIDTracker():
AliTracker(),
- fClu(new TObjArray(AliHMPIDParam::kMaxCh+1))
+ fClu(new TObjArray(AliHMPIDParam::kMaxCh+1)),
+ fDebugStreamer(0)
{
// ctor. Create TObjArray of TClonesArray of AliHMPIDCluster
//
//
fClu->SetOwner(kTRUE);
for(int i=AliHMPIDParam::kMinCh;i<=AliHMPIDParam::kMaxCh;i++) fClu->AddAt(new TClonesArray("AliHMPIDCluster"),i);
+ fDebugStreamer = new TTreeSRedirector("HMPIDdebug.root");
+
}//ctor
+
+
+AliHMPIDTracker::~AliHMPIDTracker(){
+ //
+ // destructor
+ //
+ delete fClu;
+ if (fDebugStreamer) delete fDebugStreamer;
+}
+
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Bool_t AliHMPIDTracker::GetTrackPoint(Int_t idx, AliTrackPoint& point) const
{
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Int_t AliHMPIDTracker::Recon(AliESDEvent *pEsd,TObjArray *pClus,TObjArray *pNmean, TObjArray *pQthre)
{
-// Static method to reconstruct Theta Ckov for all valid tracks of a given event.
+// Static method to reconstruct the Cherenkov angle for all valid tracks of a given event.
// Arguments: pEsd- pointer ESD; pClu- pointer to clusters for all chambers; pNmean - pointer to all function Nmean=f(time)
-// Returns: error code, 0 if no errors
-
+// Returns: error code, 0 if no errors
+//
+// Algortihm: Loop over tracks
+//
+// 1. Find the closest MIP cluster using fast tracks extrapolation method
+// 2. Propagate track to the MIP cluster using the STEER method
+// 3. Update the track information with MIP cluster (Improved angular and position resolution - to be used for Cherenkov angle calculation)
+// 4. Propagate back the constrained track to the radiator radius ( not exact yet)
+// 5. Propagation in the last 10 cm with the fast method
+// 6. Set ESDtrack information
+// 7. Calculate the Cherenkov angle
+
+ const Double_t kMaxSnp=0.9; //maximal snp for prolongation
+ const Double_t kdRadiator=10; // distance between radiator and the plane
AliHMPIDRecon recon; //instance of reconstruction class, nothing important in ctor
AliHMPIDParam *pParam = AliHMPIDParam::Instance(); //Instance of AliHMPIDParam
Float_t xPc,yPc,xRa,yRa,theta,phi;
+
Double_t cluLORS[2]={0};
-// Double_t cluMARS[3]={0},trkMARS[3]={0};
-// Double_t bestcluMARS[3]={0,0,0};
-// Double_t radClu,radInitTrk;
Int_t nMipClusTot=0;
-// Double_t d3d=0;
+
Double_t qthre = 0; Double_t nmean=0; Int_t hvsec=0;
Int_t nClusCh[AliHMPIDParam::kMaxCh+1];
-
+
+ Bool_t tsRight = kTRUE;
+ UInt_t tsmin = (UInt_t)((TF1*)pQthre->At(0))->GetXmin(); //
+ UInt_t tsmax = (UInt_t)((TF1*)pQthre->At(0))->GetXmax(); //
+ UInt_t ts = pEsd->GetTimeStamp();
+
+ if(ts<tsmin || ts>tsmax) {
+ AliWarning(Form(" in HMPID time stamp out of range!!! Please check!!! ts = %i",ts));
+ tsRight = kFALSE;
+ }
+
for(Int_t iTrk=0;iTrk<pEsd->GetNumberOfTracks();iTrk++){ //loop on the ESD tracks in the event
-// Double_t bestChi2=99999;chi2=99999; //init. track matching params
+ // Double_t bestChi2=99999;chi2=99999; //init. track matching params
Double_t dmin=999999,bz=0,distCut=1,distParams[5]={1};
Bool_t isOkDcut=kFALSE;
if(!pTrk->IsOn(AliESDtrack::kTPCout)) continue;
if(pTrk->IsOn(AliESDtrack::kTPCrefit)) continue;
-
+ AliESDfriendTrack *ftrack= (AliESDfriendTrack *)pTrk->GetFriendTrack();
+ if (!ftrack) continue;
+ if (!ftrack->GetTPCOut()) continue;
AliHMPIDtrack *hmpTrk = new AliHMPIDtrack(*pTrk); //create a hmpid track to be used for propagation and matching
- bz=AliTracker::GetBz();
-//initial flags for HMPID ESD infos
+ AliHMPIDtrack *hmpTrkConstrained = 0; //create a hmpid track to be used for propagation and matching
+ hmpTrk->Set(ftrack->GetTPCOut()->GetX(), ftrack->GetTPCOut()->GetAlpha(),ftrack->GetTPCOut()->GetParameter(), ftrack->GetTPCOut()->GetCovariance());
+ //
+ bz=AliTracker::GetBz();
+
+ //initial flags for HMPID ESD infos
pTrk->SetHMPIDtrk(0,0,0,0); //no intersection found
pTrk->SetHMPIDmip(0,0,0,0); //store mip info in any case
pTrk->SetHMPIDcluIdx(99,99999); //chamber not found, mip not yet considered
pTrk->SetHMPIDsignal(AliHMPIDRecon::kNotPerformed); //ring reconstruction not yet performed
Int_t ipCh=IntTrkCha(pTrk,xPc,yPc,xRa,yRa,theta,phi); //find the intersected chamber for this track
- if(ipCh<0) continue; //no intersection at all, go after next track
+ if(ipCh<0) {delete hmpTrk;hmpTrk=0x0;continue;} //no intersection at all, go after next track
pTrk->SetHMPIDtrk(xPc,yPc,theta,phi); //store initial infos
pTrk->SetHMPIDcluIdx(ipCh,9999); //set chamber, index of cluster + cluster size
-// track intersects the chamber ipCh: find the MIP
+ // track intersects the chamber ipCh: find the MIP
TClonesArray *pMipCluLst=(TClonesArray *)pClus->At(ipCh); //get the list of clusters
nMipClusTot = pMipCluLst->GetEntries(); //total number of clusters in the given chamber
nClusCh[ipCh] = nMipClusTot;
- if(nMipClusTot==0) continue;
+ if(nMipClusTot==0) {delete hmpTrk;hmpTrk=0x0;continue;}
- Int_t index=-1; //index of the "best" matching cluster
-
- for (Int_t iClu=0; iClu<nMipClusTot;iClu++) { //clusters loop
+ Int_t index=-1; //index of the "best" matching cluster
+ //
+ // 1. Find the closest MIP cluster using fast tracks extrapolation method
+ //
+ for (Int_t iClu=0; iClu<nMipClusTot;iClu++) { //clusters loop
- AliHMPIDCluster *pClu=(AliHMPIDCluster*)pMipCluLst->UncheckedAt(iClu); //get the cluster
-// evaluate qThre
- if(pQthre->GetEntriesFast()==pParam->kMaxCh+1) { // just for backward compatibility
- qthre=((TF1*)pQthre->At(pClu->Ch()))->Eval(pEsd->GetTimeStamp()); //
- } else { // in the past just 1 qthre
- hvsec = pParam->InHVSector(pClu->Y()); // per chamber
- if(hvsec>=0)
- qthre=((TF1*)pQthre->At(6*ipCh+hvsec))->Eval(pEsd->GetTimeStamp()); //
- } //
-//
+ AliHMPIDCluster *pClu=(AliHMPIDCluster*)pMipCluLst->UncheckedAt(iClu); //get the cluster
+ // evaluate qThre
+ if(tsRight){
+ if(pQthre->GetEntriesFast()==pParam->kMaxCh+1) {
+ qthre=((TF1*)pQthre->At(pClu->Ch()))->Eval(ts); //
+ } else { // in the past just 1 qthre
+ hvsec = pParam->InHVSector(pClu->Y()); // per chamber
+ if(hvsec>=0) qthre=((TF1*)pQthre->At(6*ipCh+hvsec))->Eval(ts); //
+ }
+ } else qthre = pParam->QCut();
+
+ //
if(pClu->Q()<qthre) continue; //charge compartible with MIP clusters
isOkQcut = kTRUE;
-//
- cluLORS[0]=pClu->X(); cluLORS[1]=pClu->Y(); //get the LORS coordinates of the cluster
+ //
+ cluLORS[0]=pClu->X(); cluLORS[1]=pClu->Y(); //get the LORS coordinates of the cluster
Double_t dist = TMath::Sqrt((xPc-cluLORS[0])*(xPc-cluLORS[0])+(yPc-cluLORS[1])*(yPc-cluLORS[1]));
if(dist<dmin) {
index=iClu;
bestHmpCluster=pClu;
}
- }
+ } // clusters loop
- if(!isOkQcut) {
+ // moved down
+ /*if(!isOkQcut) {
pTrk->SetHMPIDsignal(pParam->kMipQdcCut);
- continue;
- }
-
- Double_t radius = (pParam->Lors2Mars(ipCh,pParam->SizeAllX()/2,pParam->SizeAllY()/2)).Mag();
+ delete hmpTrk;hmpTrk=0x0; continue;
+ }*/
- if(!AliTracker::PropagateTrackToBxByBz(hmpTrk,radius,pTrk->GetMass(),1,kFALSE)) continue;
-
- if(!hmpTrk->PropagateTo(bestHmpCluster)) continue;
-
+ //
+ // 2. Propagate track to the MIP cluster using the STEER method
+ //
+
+ if(!bestHmpCluster) {delete hmpTrk;hmpTrk=0x0; delete hmpTrkConstrained;hmpTrkConstrained=0x0; continue;}
+
+ TVector3 vG = pParam->Lors2Mars(ipCh,bestHmpCluster->X(),bestHmpCluster->Y());
+ Double_t gx = vG[0];
+ Double_t gy = vG[1];
+ Double_t gz = vG[2];
+ Double_t alpha=TMath::ATan2(gy,gx);
+ Double_t radiusH=TMath::Sqrt(gy*gy+gx*gx);
+ if (!(hmpTrk->Rotate(alpha,kTRUE))) continue;
+ if(!AliTrackerBase::PropagateTrackToBxByBz(hmpTrk,radiusH,pTrk->GetMass(),1,kFALSE,kMaxSnp,-1)) {delete hmpTrk;hmpTrk=0x0; delete hmpTrkConstrained;hmpTrkConstrained=0x0; continue;}
+ //
+ // 3. Update the track with MIP cluster (Improved angular and position resolution - to be used for Cherenkov angle calculation)
+ //
+ AliExternalTrackParam trackC(*hmpTrk);
+ Double_t posC[2]={0,gz};
+ Double_t covC[3]={0.1*0.1, 0, 0.1*0.1};
+ trackC.Update(posC,covC);
+ //
+ // 4. Propagate back the constrained track to the radiator radius ( not exact yet)
+ //
+ hmpTrkConstrained = new AliHMPIDtrack(*pTrk);
+ hmpTrkConstrained->Set(trackC.GetX(), trackC.GetAlpha(),trackC.GetParameter(), trackC.GetCovariance());
+ if(!AliTrackerBase::PropagateTrackToBxByBz(hmpTrkConstrained,radiusH-kdRadiator,pTrk->GetMass(),1,kFALSE,kMaxSnp,1)) {delete hmpTrk;hmpTrk=0x0; delete hmpTrkConstrained;hmpTrkConstrained=0x0;continue;}
+ //
+ // 5. Propagation in the last 10 cm with the fast method
+ //
+ Float_t xPc0=0, yPc0=0;
+
+ IntTrkCha(ipCh, hmpTrk, xPc0,yPc0,xRa,yRa,theta,phi);
+ IntTrkCha(ipCh, hmpTrkConstrained, xPc,yPc,xRa,yRa,theta,phi);
+ //
+ // 6. Set ESDtrack information
+ //
Int_t cluSiz = bestHmpCluster->Size();
pTrk->SetHMPIDmip(bestHmpCluster->X(),bestHmpCluster->Y(),(Int_t)bestHmpCluster->Q(),0); //store mip info in any case
- pTrk->SetHMPIDcluIdx(ipCh,index+1000*cluSiz); //set chamber, index of cluster + cluster size
-
+ pTrk->SetHMPIDcluIdx(ipCh,index+1000*cluSiz); //set chamber, index of cluster + cluster size
+ pTrk->SetHMPIDtrk(xPc0,yPc0,theta,phi);
+ //
+ //
+ // Dump debug info if specified
+ //
+ if (AliHMPIDReconstructor::StreamLevel()>0) {
+ AliExternalTrackParam * trackTPC=new AliExternalTrackParam(*(ftrack->GetTPCOut()));
+ AliExternalTrackParam * trackCurrent=new AliExternalTrackParam(*pTrk);
+ if(!trackTPC->Rotate(alpha)) continue;
+ if(!trackCurrent->Rotate(alpha)) continue;
+ Bool_t statusTPC= AliTracker::PropagateTrackToBxByBz(trackTPC,radiusH,pTrk->GetMass(),1,kFALSE,kMaxSnp,-1);
+ Bool_t statusCurrent=AliTracker::PropagateTrackToBxByBz(trackCurrent,radiusH,pTrk->GetMass(),1,kFALSE,kMaxSnp,-1);
+ AliExternalTrackParam * trackTPCNB=new AliExternalTrackParam(*(ftrack->GetTPCOut()));
+ if(!trackTPCNB->Rotate(alpha)) continue;
+ Bool_t statusTPCNB=kTRUE;
+ Double_t bfield[3]={0,0,0};
+ for (Double_t radius=trackTPCNB->GetX(); radius<radiusH; radius+=1){
+ Double_t xyz[3];
+ trackTPCNB->GetXYZ(xyz);
+ GetBxByBz(xyz,bfield);
+ statusTPCNB&=trackTPCNB->PropagateToBxByBz(radius,bfield);
+ }
+ statusTPCNB&=trackTPCNB->PropagateToBxByBz(radiusH,bfield);
+ //
+ Double_t tanAlpha=TMath::Tan(TMath::ASin(trackTPC->GetSnp()));
+ Double_t deltaC= trackTPC->GetC(AliTrackerBase::GetBz())-ftrack->GetTPCOut()->GetC(AliTrackerBase::GetBz());
+ //
+ AliExternalTrackParam * trackTPCConstrained= new AliExternalTrackParam(*trackTPC);
+ Double_t pos[2]={0,gz};
+ Double_t cov[3]={0.1*0.1, 0, 0.1*0.1};
+ Double_t chi2C = trackTPCConstrained->GetPredictedChi2(pos,cov);
+ trackTPCConstrained->Update(pos,cov);
+ (*fDebugStreamer)<<"track"<<
+ "rH="<<radiusH<< // radius of cluster
+ "angle="<<tanAlpha<< // tan of the local inlination angle
+ "dC="<<deltaC<< // delta of the curvature
+ "trackTPC.="<<trackTPC<< // TPC outer param extrapolated to the HMPID
+ "trackTPCNB.="<<trackTPCNB<< // TPC track prpagated with material budget correction
+ "chi2C="<<chi2C<<
+ "trackTPCC.="<<trackTPCConstrained<< // TPC outer param extrapolated to the HMPID constrained
+ "trackCurrent.="<<trackCurrent<< // current track extrapolated to the HMPID
+ "sTPC="<<statusTPC<< // status for the current TPC track
+ "sCurrent="<<statusCurrent<< // status for the current global track
+ "cl.="<<bestHmpCluster<< // HMPID cluster
+ //
+ "t.="<<pTrk<< // curent esd track
+ "ft.="<<ftrack<< // friend track
+ "hmpTrk.="<<hmpTrk<< // hmpid tracks as used in the following code
+ "hmpTrkC.="<<hmpTrkConstrained<< // constrained hmpid tracks as used in the following code
+ "gx="<<gx<< // global cluster position X
+ "gy="<<gy<< // Y
+ "gz="<<gz<< // Z
+ "\n";
+ }
+ //
+ //
+ //
+ if(!isOkQcut) {
+ pTrk->SetHMPIDsignal(pParam->kMipQdcCut);
+ delete hmpTrk;hmpTrk=0x0;
+ delete hmpTrkConstrained;hmpTrkConstrained=0x0;
+ continue;
+ }
+
if(AliHMPIDReconstructor::GetRecoParam()) //retrieve distance cut
{
- AliHMPIDReconstructor::GetRecoParam()->PrintParameters();
if(AliHMPIDReconstructor::GetRecoParam()->IsFixedDistCut()==kTRUE) //distance cut is fixed number
{
distCut=AliHMPIDReconstructor::GetRecoParam()->GetHmpTrackMatchingDist();
}
}
else {distCut=pParam->DistCut();}
-
+
+ //dmin recalculated
+
+ dmin = TMath::Sqrt((xPc0-bestHmpCluster->X())*(xPc0-bestHmpCluster->X())+(yPc0-bestHmpCluster->Y())*(yPc0-bestHmpCluster->Y()));
+
if(dmin < distCut) {
isOkDcut = kTRUE;
- }
-
-
+ }
+ //isOkDcut = kTRUE; // switch OFF cut
if(!isOkDcut) {
pTrk->SetHMPIDsignal(pParam->kMipDistCut); //closest cluster with enough charge is still too far from intersection
if(isOkQcut*isOkDcut) isMatched = kTRUE; // MIP-Track matched !!
- if(!isMatched) continue; // If matched continue...
+ if(!isMatched) {delete hmpTrk;hmpTrk=0x0;delete hmpTrkConstrained;hmpTrkConstrained=0x0;continue;} // If matched continue...
- Bool_t isOk = hmpTrk->Update(bestHmpCluster,0.1,0);
- if(!isOk) continue;
- pTrk->SetOuterHmpParam(hmpTrk,AliESDtrack::kHMPIDout);
+ Bool_t isOk = kTRUE;
+ if(!isOk) {delete hmpTrk;hmpTrk=0x0; delete hmpTrkConstrained;hmpTrkConstrained=0x0; continue;}
+ pTrk->SetOuterHmpParam(hmpTrkConstrained,AliESDtrack::kHMPIDout);
FillResiduals(hmpTrk,bestHmpCluster,kFALSE);
+ Int_t iRad = pParam->Radiator(yRa); //evaluate the radiator involved
//evaluate nMean
- if(pNmean->GetEntries()==21) { //for backward compatibility
- nmean=((TF1*)pNmean->At(3*ipCh))->Eval(pEsd->GetTimeStamp()); //C6F14 Nmean for this chamber
- } else {
- Int_t iRad = pParam->Radiator(yRa); //evaluate the radiator involved
- if(iRad < 0) {
+ if(tsRight){
+ if(pNmean->GetEntries()==21) { //for backward compatibility
+ nmean=((TF1*)pNmean->At(3*ipCh))->Eval(ts); //C6F14 Nmean for this chamber
+ } else {
+ if(iRad < 0) {
nmean = -1;
- } else {
- Double_t tLow = ((TF1*)pNmean->At(6*ipCh+2*iRad ))->Eval(pEsd->GetTimeStamp()); //C6F14 low temp for this chamber
- Double_t tHigh = ((TF1*)pNmean->At(6*ipCh+2*iRad+1))->Eval(pEsd->GetTimeStamp()); //C6F14 high temp for this chamber
- Double_t tExp = pParam->FindTemp(tLow,tHigh,yRa); //estimated temp for that chamber at that y
- nmean = pParam->NIdxRad(AliHMPIDParam::Instance()->GetEPhotMean(),tExp); //mean ref idx @ a given temp
- }
- if(nmean < 0){ //track didn' t pass through the radiator
+ } else {
+ Double_t tLow = ((TF1*)pNmean->At(6*ipCh+2*iRad ))->Eval(ts); //C6F14 low temp for this chamber
+ Double_t tHigh = ((TF1*)pNmean->At(6*ipCh+2*iRad+1))->Eval(ts); //C6F14 high temp for this chamber
+ Double_t tExp = pParam->FindTemp(tLow,tHigh,yRa); //estimated temp for that chamber at that y
+ nmean = pParam->NIdxRad(AliHMPIDParam::Instance()->GetEPhotMean(),tExp); //mean ref idx @ a given temp
+ }
+ if(nmean < 0){ //track didn' t pass through the radiator
pTrk->SetHMPIDsignal(AliHMPIDRecon::kNoRad); //set the appropriate flag
pTrk->SetHMPIDcluIdx(ipCh,index+1000*cluSiz); //set index of cluster
+ delete hmpTrk;hmpTrk=0x0;
+ delete hmpTrkConstrained;hmpTrkConstrained=0x0;
continue;
- }
- }
+ }
+ }
+ } else nmean = pParam->MeanIdxRad();
+ //
+ // 7. Calculate the Cherenkov angle
//
- recon.SetImpPC(xPc,yPc); //store track impact to PC
+ recon.SetImpPC(xPc0,yPc0); //store track impact to PC
recon.CkovAngle(pTrk,(TClonesArray *)pClus->At(ipCh),index,nmean,xRa,yRa); //search for Cerenkov angle of this track
+ Double_t thetaCkov = pTrk->GetHMPIDsignal();
+ if (AliHMPIDReconstructor::StreamLevel()>0) {
+ AliExternalTrackParam * trackTPC=new AliExternalTrackParam(*(ftrack->GetTPCOut()));
+ AliExternalTrackParam * trackCurrent=new AliExternalTrackParam(*pTrk);
+ if(!trackTPC->Rotate(alpha)) continue;
+ if(!trackCurrent->Rotate(alpha)) continue;
+ Bool_t statusTPC= AliTracker::PropagateTrackToBxByBz(trackTPC,radiusH,pTrk->GetMass(),1,kFALSE,kMaxSnp,-1);
+ Bool_t statusCurrent=AliTracker::PropagateTrackToBxByBz(trackCurrent,radiusH,pTrk->GetMass(),1,kFALSE,kMaxSnp,-1);
+ Double_t tanAlpha=TMath::Tan(TMath::ASin(trackTPC->GetSnp()));
+ Double_t deltaC= trackTPC->GetC(AliTrackerBase::GetBz())-ftrack->GetTPCOut()->GetC(AliTrackerBase::GetBz());
+ //
+ AliExternalTrackParam * trackTPCNB=new AliExternalTrackParam(*(ftrack->GetTPCOut()));
+ if(!trackTPCNB->Rotate(alpha)) continue;
+ Bool_t statusTPCNB=kTRUE;
+ Double_t bfield[3]={0,0,0};
+ for (Double_t radius=trackTPCNB->GetX(); radius<radiusH; radius+=1){
+ Double_t xyz[3];
+ trackTPCNB->GetXYZ(xyz);
+ GetBxByBz(xyz,bfield);
+ statusTPCNB&=trackTPCNB->PropagateToBxByBz(radius,bfield);
+ }
+ statusTPCNB&=trackTPCNB->PropagateToBxByBz(radiusH,bfield);
+
+ AliExternalTrackParam * trackTPCConstrained= new AliExternalTrackParam(*trackTPC);
+ Double_t pos[2]={0,gz};
+ Double_t cov[3]={0.1*0.1, 0, 0.1*0.1};
+ Double_t chi2C = trackTPCConstrained->GetPredictedChi2(pos,cov);
+ trackTPCConstrained->Update(pos,cov);
+ (*fDebugStreamer)<<"track2"<<
+ "rH="<<radiusH<< // radius of cluster
+ "angle="<<tanAlpha<< // tan of the local inlination angle
+ "dC="<<deltaC<< // delta of the curvature
+ "trackTPC.="<<trackTPC<< // TPC outer param extrapolated to the HMPID
+ "trackTPCNB.="<<trackTPCNB<< // TPC outer param extrapolated to the HMPID
+ "chi2C="<<chi2C<<
+ "trackTPCC.="<<trackTPCConstrained<< // TPC outer param extrapolated to the HMPID constrained
+ "trackCurrent.="<<trackCurrent<< // current track extrapolated to the HMPID
+ "sTPC="<<statusTPC<< // status for the current TPC track
+ "sCurrent="<<statusCurrent<< // status for the current global track
+ "cl.="<<bestHmpCluster<< // HMPID cluster
+ //
+ "t.="<<pTrk<< // curent esd track
+ "ft.="<<ftrack<< // friend track
+ "hmpTrk.="<<hmpTrk<< // hmpid tracks as used in the following code
+ "hmpTrkC.="<<hmpTrkConstrained<< // constrained hmpid tracks as used in the following code
+ "gx="<<gx<< // global cluster position X
+ "gy="<<gy<< // Y
+ "gz="<<gz<< // Z
+ "thetaCkov="<<thetaCkov<< // Cherenkov angle
+ "\n";
+ }
+
+ if(pTrk->GetHMPIDsignal()<0) {
+ delete hmpTrk;hmpTrk=0x0;
+ delete hmpTrkConstrained; hmpTrkConstrained=0x0;
+ continue;}
+
AliHMPIDPid pID;
Double_t prob[5];
pID.FindPid(pTrk,5,prob);
pTrk->SetHMPIDpid(prob);
// Printf(" Prob e- %6.2f mu %6.2f pi %6.2f k %6.2f p %6.2f",prob[0]*100,prob[1]*100,prob[2]*100,prob[3]*100,prob[4]*100);
-
- delete hmpTrk;hmpTrk=0x0;
+ delete hmpTrk; hmpTrk=0x0;
+ delete hmpTrkConstrained; hmpTrkConstrained=0x0;
}//iTrk
return 0; // error code: 0=no error;
AliHMPIDReconHTA reconHTA; //instance of reconstruction class, nothing important in ctor
AliHMPIDParam *pParam = AliHMPIDParam::Instance(); //Instance of AliHMPIDParam
-
+
+ Bool_t tsRight = kTRUE;
+
+ UInt_t tsmin = (UInt_t)((TF1*)pQthre->At(0))->GetXmin(); //
+ UInt_t tsmax = (UInt_t)((TF1*)pQthre->At(0))->GetXmax(); //
+ UInt_t ts = pEsd->GetTimeStamp();
+
+ if(ts<tsmin || ts>tsmax) {
+ AliWarning(Form(" in HMPID time stamp out of range!!! Please check!!! ts = %i",ts));
+ tsRight = kFALSE;
+ }
+
for(Int_t iTrk=0;iTrk<pEsd->GetNumberOfTracks();iTrk++){ //loop on the ESD tracks in the event
AliESDtrack *pTrk = pEsd->GetTrack(iTrk); //here it is simulated or just empty track
Int_t hvsec;
Double_t qthre=0;
+
// evaluate qThre
+ if(tsRight){
if(pQthre->GetEntriesFast()==pParam->kMaxCh+1) { // just for backward compatibility
- qthre=((TF1*)pQthre->At(chMip))->Eval(pEsd->GetTimeStamp()); //
+ qthre=((TF1*)pQthre->At(chMip))->Eval(ts); //
} else { // in the past just 1 qthre
hvsec = pParam->InHVSector(yMip); // per chamber
- if(hvsec>=0) qthre=((TF1*)pQthre->At(6*chMip+hvsec))->Eval(pEsd->GetTimeStamp()); //
- }
+ if(hvsec>=0) qthre=((TF1*)pQthre->At(6*chMip+hvsec))->Eval(ts); //
+ }
+ } else qthre = pParam->QCut();
//
if(qMip<qthre) {
- pTrk->SetHMPIDmip(xMip,yMip,(Int_t)qMip,0); //store mip info in any case
+ pTrk->SetHMPIDmip(xMip,yMip,(Int_t)qMip,0); //store mip info in any case
pTrk->SetHMPIDcluIdx(chMip,indMip+1000*cluMipSiz);
pTrk->SetHMPIDsignal(pParam->kMipQdcCut);
return 1; //charge compatible with MIP clusters
Double_t yRa = yMip; //just an approx...
Double_t nmean;
+
+ Int_t iRad = pParam->Radiator(yRa); //evaluate the radiator involved
+
//evaluate nMean
+ if(tsRight){
if(pNmean->GetEntries()==21) { //for backward compatibility
- nmean=((TF1*)pNmean->At(3*chMip))->Eval(pEsd->GetTimeStamp()); //C6F14 Nmean for this chamber
+ nmean=((TF1*)pNmean->At(3*chMip))->Eval(ts); //C6F14 Nmean for this chamber
} else {
- Int_t iRad = pParam->Radiator(yRa); //evaluate the radiator involved
if(iRad < 0) {
nmean = -1;
} else {
- Double_t tLow = ((TF1*)pNmean->At(6*chMip+2*iRad ))->Eval(pEsd->GetTimeStamp()); //C6F14 low temp for this chamber
- Double_t tHigh = ((TF1*)pNmean->At(6*chMip+2*iRad+1))->Eval(pEsd->GetTimeStamp()); //C6F14 high temp for this chamber
+ Double_t tLow = ((TF1*)pNmean->At(6*chMip+2*iRad ))->Eval(ts); //C6F14 low temp for this chamber
+ Double_t tHigh = ((TF1*)pNmean->At(6*chMip+2*iRad+1))->Eval(ts); //C6F14 high temp for this chamber
Double_t tExp = pParam->FindTemp(tLow,tHigh,yRa); //estimated temp for that chamber at that y
nmean = pParam->NIdxRad(AliHMPIDParam::Instance()->GetEPhotMean(),tExp); //mean ref idx @ a given temp
}
if(nmean < 0){ //track didn' t pass through the radiator
pTrk->SetHMPIDsignal(AliHMPIDRecon::kNoRad); //set the appropriate flag
return 1;
- }
- }
+ }
+ }
+ } else nmean = pParam->MeanIdxRad();
//
if(!reconHTA.CkovHiddenTrk(pTrk,(TClonesArray *)pClus->At(ipCh),indMip,nmean)) { //search for track parameters and Cerenkov angle of this track
AliHMPIDPid pID;