//-----------------------------------------------------------------
+//
// Implementation of the TPC seed class
// This class is used by the AliTPCtrackerMI class
// Origin: Marian Ivanov, CERN, Marian.Ivanov@cern.ch
fSeed2(-1),
fMAngular(0),
fCircular(0),
- fClusterMap(159),
- fSharedMap(159)
+ fPoolID(-1)
{
//
for (Int_t i=0;i<160;i++) SetClusterIndex2(i,-3);
fDEDX[i] = 0.;
fSDEDX[i] = 1e10;
fNCDEDX[i] = 0;
+ fNCDEDXInclThres[i] = 0;
}
+ fDEDX[4] = 0;
for (Int_t i=0;i<12;i++) fOverlapLabels[i] = -1;
- // for (Int_t i=0;i<160;i++) fClusterMap[i]=kFALSE;
- //for (Int_t i=0;i<160;i++) fSharedMap[i]=kFALSE;
- fClusterMap.ResetAllBits(kFALSE);
- fSharedMap.ResetAllBits(kFALSE);
-
}
AliTPCseed::AliTPCseed(const AliTPCseed &s, Bool_t clusterOwner):
fSeed2(-1),
fMAngular(0),
fCircular(0),
- fClusterMap(s.fClusterMap),
- fSharedMap(s.fSharedMap)
+ fPoolID(-1)
{
//---------------------
// dummy copy constructor
fDEDX[i] = s.fDEDX[i];
fSDEDX[i] = s.fSDEDX[i];
fNCDEDX[i] = s.fNCDEDX[i];
+ fNCDEDXInclThres[i] = s.fNCDEDXInclThres[i];
}
+ fDEDX[4] = s.fDEDX[4];
for (Int_t i=0;i<12;i++) fOverlapLabels[i] = s.fOverlapLabels[i];
}
fSeed2(-1),
fMAngular(0),
fCircular(0),
- fClusterMap(159),
- fSharedMap(159)
+ fPoolID(-1)
{
//
// Constructor from AliTPCtrack
fDEDX[i] = 0.;
fSDEDX[i] = 1e10;
fNCDEDX[i] = 0;
+ fNCDEDXInclThres[i] = 0;
}
+ fDEDX[4] = 0;
for (Int_t i=0;i<12;i++) fOverlapLabels[i] = -1;
-
- //for (Int_t i=0;i<160;i++) fClusterMap[i]=kFALSE;
- //for (Int_t i=0;i<160;i++) fSharedMap[i]=kFALSE;
- fClusterMap.ResetAllBits(kFALSE);
- fSharedMap.ResetAllBits(kFALSE);
-
}
AliTPCseed::AliTPCseed(Double_t xr, Double_t alpha, const Double_t xx[5],
fSeed2(-1),
fMAngular(0),
fCircular(0),
- fClusterMap(159),
- fSharedMap(159)
+ fPoolID(-1)
{
//
// Constructor
fDEDX[i] = 0.;
fSDEDX[i] = 1e10;
fNCDEDX[i] = 0;
+ fNCDEDXInclThres[i] = 0;
}
+ fDEDX[4] = 0;
for (Int_t i=0;i<12;i++) fOverlapLabels[i] = -1;
}
{
//
// assignment operator
+ // don't touch pool ID
//
if(this!=¶m){
AliTPCtrack::operator=(param);
fEsd =param.fEsd;
- for(Int_t i = 0;i<160;++i)fClusterPointer[i] = param.fClusterPointer[i]; // this is not allocated by AliTPCSeed
fClusterOwner = param.fClusterOwner;
+ if (!fClusterOwner) for(Int_t i = 0;i<160;++i)fClusterPointer[i] = param.fClusterPointer[i];
+ else for(Int_t i = 0;i<160;++i) {
+ delete fClusterPointer[i];
+ fClusterPointer[i] = new AliTPCclusterMI(*(param.fClusterPointer[i]));
+ }
// leave out fPoint, they are also not copied in the copy ctor...
// but deleted in the dtor... strange...
fRow = param.fRow;
fDEDX[i] = param.fDEDX[i];
fSDEDX[i] = param.fSDEDX[i];
fNCDEDX[i] = param.fNCDEDX[i];
+ fNCDEDXInclThres[i] = param.fNCDEDXInclThres[i];
}
+ fDEDX[4] = param.fDEDX[4];
for(Int_t i = 0;i<AliPID::kSPECIES;++i)fTPCr[i] = param.fTPCr[i];
fSeedType = param.fSeedType;
fMAngular = param.fMAngular;
fCircular = param.fCircular;
for(int i = 0;i<160;++i)fTrackPoints[i] = param.fTrackPoints[i];
- fClusterMap = param.fClusterMap;
- fSharedMap = param.fSharedMap;
}
return (*this);
}
*/
if (all){
- for (Int_t i=0;i<200;i++) SetClusterIndex2(i,-3);
- for (Int_t i=0;i<160;i++) fClusterPointer[i]=0;
+ for (Int_t i=200;i--;) SetClusterIndex2(i,-3);
+ if (!fClusterOwner) for (Int_t i=160;i--;) fClusterPointer[i]=0;
+ else for (Int_t i=160;i--;) {delete fClusterPointer[i]; fClusterPointer[i]=0;}
}
}
fDEDX[1] = CookdEdxAnalytical(low,up,useTot ,0 ,row0, 0);
fDEDX[2] = CookdEdxAnalytical(low,up,useTot ,row0,row1, 0);
fDEDX[3] = CookdEdxAnalytical(low,up,useTot ,row1,row2, 0);
+ fDEDX[4] = CookdEdxAnalytical(low,up,useTot ,row0,row2, 0); // full OROC truncated mean
//
fSDEDX[0] = CookdEdxAnalytical(low,up,useTot ,i1 ,i2, 1);
fSDEDX[1] = CookdEdxAnalytical(low,up,useTot ,0 ,row0, 1);
fSDEDX[2] = CookdEdxAnalytical(low,up,useTot ,row0,row1, 1);
fSDEDX[3] = CookdEdxAnalytical(low,up,useTot ,row1,row2, 1);
//
- fNCDEDX[0] = TMath::Nint(CookdEdxAnalytical(low,up,useTot ,i1 ,i2, 2));
- fNCDEDX[1] = TMath::Nint(CookdEdxAnalytical(low,up,useTot ,0 ,row0, 2));
- fNCDEDX[2] = TMath::Nint(CookdEdxAnalytical(low,up,useTot ,row0,row1, 2));
- fNCDEDX[3] = TMath::Nint(CookdEdxAnalytical(low,up,useTot ,row1,row2, 2));
-
+ fNCDEDX[0] = TMath::Nint(GetTPCClustInfo(2, 1, i1 , i2));
+ fNCDEDX[1] = TMath::Nint(GetTPCClustInfo(2, 1, 0 , row0));
+ fNCDEDX[2] = TMath::Nint(GetTPCClustInfo(2, 1, row0, row1));
+ fNCDEDX[3] = TMath::Nint(GetTPCClustInfo(2, 1, row1, row2));
+ //
+ fNCDEDXInclThres[0] = TMath::Nint(GetTPCClustInfo(2, 2, i1 , i2));
+ fNCDEDXInclThres[1] = TMath::Nint(GetTPCClustInfo(2, 2, 0 , row0));
+ fNCDEDXInclThres[2] = TMath::Nint(GetTPCClustInfo(2, 2, row0, row1));
+ fNCDEDXInclThres[3] = TMath::Nint(GetTPCClustInfo(2, 2, row1, row2));
+ //
SetdEdx(fDEDX[0]);
return fDEDX[0];
return GetY() + (xk-GetX())*(c1+c2)/(r1+r2);
}
-void AliTPCseed::SetClusterMapBit(int ibit, Bool_t state)
-{
- fClusterMap[ibit] = state;
-}
-Bool_t AliTPCseed::GetClusterMapBit(int ibit)
-{
- return fClusterMap[ibit];
-}
-void AliTPCseed::SetSharedMapBit(int ibit, Bool_t state)
-{
- fSharedMap[ibit] = state;
-}
-Bool_t AliTPCseed::GetSharedMapBit(int ibit)
-{
- return fSharedMap[ibit];
-}
-
-
-
Float_t AliTPCseed::CookdEdxNorm(Double_t low, Double_t up, Int_t type, Int_t i1, Int_t i2, Bool_t shapeNorm,Int_t posNorm, Int_t padNorm, Int_t returnVal){
return mean;
}
-Float_t AliTPCseed::CookdEdxAnalytical(Double_t low, Double_t up, Int_t type, Int_t i1, Int_t i2, Int_t returnVal, Int_t rowThres){
+Float_t AliTPCseed::CookdEdxAnalytical(Double_t low, Double_t up, Int_t type, Int_t i1, Int_t i2, Int_t returnVal, Int_t rowThres, Int_t mode){
//
// calculates dedx using the cluster
// i1-i2 - the pad-row range used for calculation
//
// posNorm - usage of pos normalization
- // returnVal - 0 return mean
- // - 1 return RMS
- // - 2 return number of clusters
- //
+ // returnVal - 0 return mean
+ // - 1 return RMS
+ // - 2 return number of clusters
+ // - 3 ratio
+ // - 4 mean upper half
+ // - 5 mean - lower half
+ // - 6 third moment
+ // mode - 0 - linear
+ // - 1 - logatithmic
// rowThres - number of rows before and after given pad row to check for clusters below threshold
//
// normalization parametrization taken from AliTPCClusterParam
if (AliTPCcalibDB::Instance()->GetParameters()){
gainGG= AliTPCcalibDB::Instance()->GetParameters()->GetGasGain()/20000; //relative gas gain
}
- //
- // extract time-dependent correction for pressure and temperature variations
- //
- UInt_t runNumber = 1;
- Float_t corrTimeGain = 1;
- TObjArray * timeGainSplines = 0x0;
- //
- AliTPCTransform * trans = AliTPCcalibDB::Instance()->GetTransform();
- const AliTPCRecoParam * recoParam = AliTPCcalibDB::Instance()->GetTransform()->GetCurrentRecoParam();
- if (trans) {
+ //
+ // extract time-dependent correction for pressure and temperature variations
+ //
+ UInt_t runNumber = 1;
+ Float_t corrTimeGain = 1;
+ TObjArray * timeGainSplines = 0x0;
+ TGraphErrors * grPadEqual = 0x0;
+ TGraphErrors* grChamberGain[3]={0x0,0x0,0x0};
+ //
+ AliTPCTransform * trans = AliTPCcalibDB::Instance()->GetTransform();
+ const AliTPCRecoParam * recoParam = AliTPCcalibDB::Instance()->GetTransform()->GetCurrentRecoParam();
+ //
+ if (recoParam->GetNeighborRowsDedx() == 0) rowThres = 0;
+ //
+ if (trans) {
runNumber = trans->GetCurrentRunNumber();
//AliTPCcalibDB::Instance()->SetRun(runNumber);
timeGainSplines = AliTPCcalibDB::Instance()->GetTimeGainSplinesRun(runNumber);
AliSplineFit * fitFPcosmic = (AliSplineFit *) timeGainSplines->At(1);
if (fitMIP) {
corrTimeGain = AliTPCcalibDButil::EvalGraphConst(fitMIP, time); /*fitMIP->Eval(time);*/
- } else {
+ } else {
if (fitFPcosmic) corrTimeGain = AliTPCcalibDButil::EvalGraphConst(fitFPcosmic, time); /*fitFPcosmic->Eval(time); */
}
+ //
+ if (type==1) grPadEqual = (TGraphErrors * ) timeGainSplines->FindObject("TGRAPHERRORS_MEANQMAX_PADREGIONGAIN_BEAM_ALL");
+ if (type==0) grPadEqual = (TGraphErrors * ) timeGainSplines->FindObject("TGRAPHERRORS_MEANQTOT_PADREGIONGAIN_BEAM_ALL");
+ const char* names[3]={"SHORT","MEDIUM","LONG"};
+ for (Int_t iPadRegion=0; iPadRegion<3; ++iPadRegion)
+ grChamberGain[iPadRegion]=(TGraphErrors*)timeGainSplines->FindObject(Form("TGRAPHERRORS_MEAN_CHAMBERGAIN_%s_BEAM_ALL",names[iPadRegion]));
}
- }
+ }
const Float_t kClusterShapeCut = 1.5; // IMPPRTANT TO DO: move value to AliTPCRecoParam
const Float_t ktany = TMath::Tan(TMath::DegToRad()*10);
//
for (Int_t irow=i1; irow<i2; irow++){
AliTPCclusterMI* cluster = GetClusterPointer(irow);
- if (!cluster) {
+ if (!cluster && irow > 1 && irow < 157) {
Bool_t isClBefore = kFALSE;
Bool_t isClAfter = kFALSE;
for(Int_t ithres = 1; ithres <= rowThres; ithres++) {
if (clusterAfter) isClAfter = kTRUE;
}
if (isClBefore && isClAfter) nclBelowThr++;
- continue;
}
+ if (!cluster) continue;
//
//
if (TMath::Abs(cluster->GetY())>cluster->GetX()*ktany-kedgey) continue; // edge cluster
// pad region equalization outside of cluster param
//
Float_t gainEqualPadRegion = 1;
- if (timeGainSplines) { //1 - max charge or 0- total charge in cluster
- TGraphErrors * grPadEqual = 0x0;
- if (type==1) grPadEqual = (TGraphErrors * ) timeGainSplines->FindObject("TGRAPHERRORS_MEANQMAX_PADREGIONGAIN_BEAM_ALL");
- if (type==0) grPadEqual = (TGraphErrors * ) timeGainSplines->FindObject("TGRAPHERRORS_MEANQTOT_PADREGIONGAIN_BEAM_ALL");
- if (grPadEqual) gainEqualPadRegion = grPadEqual->Eval(ipad);
- }
+ if (grPadEqual && recoParam->GetUseGainCorrectionTime()>0) gainEqualPadRegion = grPadEqual->Eval(ipad);
+ //
+ // chamber-by-chamber equalization outside gain map
+ //
+ Float_t gainChamber = 1;
+ if (grChamberGain[ipad] && recoParam->GetUseGainCorrectionTime()>0) gainChamber = grChamberGain[ipad]->Eval(cluster->GetDetector());
//
amp[ncl]=charge;
amp[ncl]/=gainGG;
amp[ncl]/=gainPad;
amp[ncl]/=corrPos;
amp[ncl]/=gainEqualPadRegion;
+ amp[ncl]/=gainChamber;
//
ncl++;
}
- if (type>3) return ncl;
+ if (type==2) return ncl;
TMath::Sort(ncl,amp, indexes, kFALSE);
//
if (ncl<10) return 0;
//
Float_t suma=0;
Float_t suma2=0;
+ Float_t suma3=0;
+ Float_t sumaS=0;
Float_t sumn=0;
+ // upper,and lower part statistic
+ Float_t sumL=0, sumL2=0, sumLN=0;
+ Float_t sumD=0, sumD2=0, sumDN=0;
+
Int_t icl0=TMath::Nint((ncl + nclBelowThr)*low);
Int_t icl1=TMath::Nint((ncl + nclBelowThr)*up);
+ Int_t iclm=TMath::Nint((ncl + nclBelowThr)*(low +(up+low)*0.5));
+ //
for (Int_t icl=icl0; icl<icl1;icl++){
- suma+=ampWithBelow[icl];
- suma2+=ampWithBelow[icl]*ampWithBelow[icl];
- sumn++;
+ if (ampWithBelow[icl]<0.1) continue;
+ Double_t camp=ampWithBelow[icl]/corrTimeGain;
+ if (mode==1) camp= TMath::Log(camp);
+ if (icl<icl1){
+ suma+=camp;
+ suma2+=camp*camp;
+ suma3+=camp*camp*camp;
+ sumaS+=TMath::Power(TMath::Abs(camp),1./3.);
+ sumn++;
+ }
+ if (icl>iclm){
+ sumL+=camp;
+ sumL2+=camp*camp;
+ sumLN++;
+ }
+ if (icl<=iclm){
+ sumD+=camp;
+ sumD2+=camp*camp;
+ sumDN++;
+ }
}
+ //
+ Float_t mean = 0;
+ Float_t meanL = 0;
+ Float_t meanD = 0; // lower half mean
+ if (sumn > 1e-30) mean =suma/sumn;
+ if (sumLN > 1e-30) meanL =sumL/sumLN;
+ if (sumDN > 1e-30) meanD =(sumD/sumDN);
+ /*
Float_t mean =suma/sumn;
- Float_t rms =TMath::Sqrt(TMath::Abs(suma2/sumn-mean*mean));
+ Float_t meanL = sumL/sumLN;
+ Float_t meanD =(sumD/sumDN); // lower half mean
+ */
+
+ Float_t rms = 0;
+ Float_t mean2=0;
+ Float_t mean3=0;
+ Float_t meanS=0;
+
+ if(sumn>0){
+ rms = TMath::Sqrt(TMath::Abs(suma2/sumn-mean*mean));
+ mean2=suma2/sumn;
+ mean3=suma3/sumn;
+ meanS=sumaS/sumn;
+ }
+
+ if (mean2>0) mean2=TMath::Power(TMath::Abs(mean2),1./2.);
+ if (mean3>0) mean3=TMath::Power(TMath::Abs(mean3),1./3.);
+ if (meanS>0) meanS=TMath::Power(TMath::Abs(meanS),3.);
//
- mean /= corrTimeGain;
- rms /= corrTimeGain;
+ if (mode==1) mean=TMath::Exp(mean);
+ if (mode==1) meanL=TMath::Exp(meanL); // upper truncation
+ if (mode==1) meanD=TMath::Exp(meanD); // lower truncation
+ //
+ delete [] ampWithBelow;
+
+
//
if (returnVal==1) return rms;
if (returnVal==2) return ncl;
+ if (returnVal==3) return Double_t(nclBelowThr)/Double_t(nclBelowThr+ncl);
+ if (returnVal==4) return meanL;
+ if (returnVal==5) return meanD;
+ if (returnVal==6) return mean2;
+ if (returnVal==7) return mean3;
+ if (returnVal==8) return meanS;
return mean;
}
Int_t imin=158, imax=0;
for (Int_t i=0;i<160;i++) {
AliTPCclusterMI *c=track->GetClusterPointer(i);
- if (!c) continue;
+ if (!c || (track->GetClusterIndex(i) & 0x8000)) continue;
if (sector<0) sector = c->GetDetector();
if (c->GetX()<xmin) xmin=c->GetX();
if (c->GetX()>xmax) xmax=c->GetX();
//
for (Int_t i=imin; i<=imax; i++){
AliTPCclusterMI *c=track->GetClusterPointer(i);
- if (!c) continue;
+ if (!c || (track->GetClusterIndex(i) & 0x8000)) continue;
// if (RejectCluster(c,track)) continue;
sector = (c->GetDetector()%18);
if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
//
for (Int_t i=imax; i>=imin; i--){
AliTPCclusterMI *c=track->GetClusterPointer(i);
- if (!c) continue;
+ if (!c || (track->GetClusterIndex(i) & 0x8000)) continue;
//if (RejectCluster(c,track)) continue;
sector = (c->GetDetector()%18);
if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
//
for (Int_t i=imin; i<=imax; i++){
AliTPCclusterMI *c=track->GetClusterPointer(i);
- if (!c) continue;
+ if (!c || (track->GetClusterIndex(i) & 0x8000)) continue;
sector = (c->GetDetector()%18);
if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
//continue;
}
+
+//_______________________________________________________________________
+Float_t AliTPCseed::GetTPCClustInfo(Int_t nNeighbours, Int_t type, Int_t row0, Int_t row1)
+{
+ //
+ // TPC cluster information
+ // type 0: get fraction of found/findable clusters with neighbourhood definition
+ // 1: found clusters
+ // 2: findable (number of clusters above and below threshold)
+ //
+ // definition of findable clusters:
+ // a cluster is defined as findable if there is another cluster
+ // within +- nNeighbours pad rows. The idea is to overcome threshold
+ // effects with a very simple algorithm.
+ //
+
+ const Float_t kClusterShapeCut = 1.5; // IMPPRTANT TO DO: move value to AliTPCRecoParam
+ const Float_t ktany = TMath::Tan(TMath::DegToRad()*10);
+ const Float_t kedgey =3.;
+
+ Float_t ncl = 0;
+ Float_t nclBelowThr = 0; // counts number of clusters below threshold
+
+ for (Int_t irow=row0; irow<row1; irow++){
+ AliTPCclusterMI* cluster = GetClusterPointer(irow);
+
+ if (!cluster && irow > 1 && irow < 157) {
+ Bool_t isClBefore = kFALSE;
+ Bool_t isClAfter = kFALSE;
+ for(Int_t ithres = 1; ithres <= nNeighbours; ithres++) {
+ AliTPCclusterMI * clusterBefore = GetClusterPointer(irow - ithres);
+ if (clusterBefore) isClBefore = kTRUE;
+ AliTPCclusterMI * clusterAfter = GetClusterPointer(irow + ithres);
+ if (clusterAfter) isClAfter = kTRUE;
+ }
+ if (isClBefore && isClAfter) nclBelowThr++;
+ }
+ if (!cluster) continue;
+ //
+ //
+ if (TMath::Abs(cluster->GetY())>cluster->GetX()*ktany-kedgey) continue; // edge cluster
+ //
+ AliTPCTrackerPoint * point = GetTrackPoint(irow);
+ if (point==0) continue;
+ Float_t rsigmay = TMath::Sqrt(point->GetSigmaY());
+ if (rsigmay > kClusterShapeCut) continue;
+ //
+ if (cluster->IsUsed(11)) continue; // remove shared clusters for PbPb
+ ncl++;
+ }
+
+ if(ncl<10)
+ return 0;
+ if(type==0)
+ if(nclBelowThr+ncl>0)
+ return ncl/(nclBelowThr+ncl);
+ if(type==1)
+ return ncl;
+ if(type==2)
+ return ncl+nclBelowThr;
+ return 0;
+}
+//_______________________________________________________________________
+Int_t AliTPCseed::GetNumberOfClustersIndices() {
+ Int_t ncls = 0;
+ for (int i=0; i < 160; i++) {
+ if ((fIndex[i] & 0x8000) == 0)
+ ncls++;
+ }
+ return ncls;
+}
+
+//_______________________________________________________________________
+void AliTPCseed::Clear(Option_t*)
+{
+ // formally seed may allocate memory for clusters (althought this should not happen for
+ // the seeds in the pool). Hence we need this method for fwd. compatibility
+ if (fClusterOwner) for (int i=160;i--;) {delete fClusterPointer[i]; fClusterPointer[i] = 0;}
+}