#include "TClonesArray.h"
#include "AliTPCseed.h"
#include "AliTPCReconstructor.h"
+#include "AliTPCClusterParam.h"
+#include "AliTPCCalPad.h"
+#include "AliTPCCalROC.h"
+#include "AliTPCcalibDB.h"
+#include "AliTPCParam.h"
+#include "AliMathBase.h"
+
+
ClassImp(AliTPCseed)
AliTPCtrack(),
fEsd(0x0),
fClusterOwner(kFALSE),
- fPoints(0x0),
- fEPoints(0x0),
fRow(0),
fSector(-1),
fRelativeSector(-1),
fCurrentSigmaY2(1e10),
fCurrentSigmaZ2(1e10),
+ fCMeanSigmaY2p30(-1.), //! current mean sigma Y2 - mean30%
+ fCMeanSigmaZ2p30(-1.), //! current mean sigma Z2 - mean30%
+ fCMeanSigmaY2p30R(-1.), //! current mean sigma Y2 - mean2%
+ fCMeanSigmaZ2p30R(-1.), //! current mean sigma Z2 - mean2%
+ //
fErrorY2(1e10),
fErrorZ2(1e10),
fCurrentCluster(0x0),
AliTPCtrack(s),
fEsd(0x0),
fClusterOwner(clusterOwner),
- fPoints(0x0),
- fEPoints(0x0),
fRow(0),
fSector(-1),
fRelativeSector(-1),
- fCurrentSigmaY2(1e10),
- fCurrentSigmaZ2(1e10),
+ fCurrentSigmaY2(-1),
+ fCurrentSigmaZ2(-1),
+ fCMeanSigmaY2p30(-1.), //! current mean sigma Y2 - mean30%
+ fCMeanSigmaZ2p30(-1.), //! current mean sigma Z2 - mean30%
+ fCMeanSigmaY2p30R(-1.), //! current mean sigma Y2 - mean2%
+ fCMeanSigmaZ2p30R(-1.), //! current mean sigma Z2 - mean2%
fErrorY2(1e10),
fErrorZ2(1e10),
fCurrentCluster(0x0),
AliTPCtrack(t),
fEsd(0x0),
fClusterOwner(kFALSE),
- fPoints(0x0),
- fEPoints(0x0),
fRow(0),
fSector(-1),
fRelativeSector(-1),
- fCurrentSigmaY2(1e10),
- fCurrentSigmaZ2(1e10),
+ fCurrentSigmaY2(-1),
+ fCurrentSigmaZ2(-1),
+ fCMeanSigmaY2p30(-1.), //! current mean sigma Y2 - mean30%
+ fCMeanSigmaZ2p30(-1.), //! current mean sigma Z2 - mean30%
+ fCMeanSigmaY2p30R(-1.), //! current mean sigma Y2 - mean2%
+ fCMeanSigmaZ2p30R(-1.), //! current mean sigma Z2 - mean2%
fErrorY2(1e10),
fErrorZ2(1e10),
fCurrentCluster(0x0),
AliTPCtrack(xr, alpha, xx, cc, index),
fEsd(0x0),
fClusterOwner(kFALSE),
- fPoints(0x0),
- fEPoints(0x0),
fRow(0),
fSector(-1),
fRelativeSector(-1),
- fCurrentSigmaY2(1e10),
- fCurrentSigmaZ2(1e10),
+ fCurrentSigmaY2(-1),
+ fCurrentSigmaZ2(-1),
+ fCMeanSigmaY2p30(-1.), //! current mean sigma Y2 - mean30%
+ fCMeanSigmaZ2p30(-1.), //! current mean sigma Z2 - mean30%
+ fCMeanSigmaY2p30R(-1.), //! current mean sigma Y2 - mean2%
+ fCMeanSigmaZ2p30R(-1.), //! current mean sigma Z2 - mean2%
fErrorY2(1e10),
fErrorZ2(1e10),
fCurrentCluster(0x0),
AliTPCseed::~AliTPCseed(){
//
// destructor
- if (fPoints) delete fPoints;
- fPoints =0;
- if (fEPoints) delete fEPoints;
- fEPoints = 0;
fNoCluster =0;
if (fClusterOwner){
for (Int_t icluster=0; icluster<160; icluster++){
fClusterOwner = param.fClusterOwner;
// leave out fPoint, they are also not copied in the copy ctor...
// but deleted in the dtor... strange...
- // fPoints =
- // fEPoints =
fRow = param.fRow;
fSector = param.fSector;
fRelativeSector = param.fRelativeSector;
return &fTrackPoints[i];
}
-void AliTPCseed::RebuildSeed()
-{
- //
- // rebuild seed to be ready for storing
- AliTPCclusterMI cldummy;
- cldummy.SetQ(0);
- AliTPCTrackPoint pdummy;
- pdummy.GetTPoint().SetShared(10);
- for (Int_t i=0;i<160;i++){
- AliTPCclusterMI * cl0 = fClusterPointer[i];
- AliTPCTrackPoint *trpoint = (AliTPCTrackPoint*)fPoints->UncheckedAt(i);
- if (cl0){
- trpoint->GetTPoint() = *(GetTrackPoint(i));
- trpoint->GetCPoint() = *cl0;
- trpoint->GetCPoint().SetQ(TMath::Abs(cl0->GetQ()));
- }
- else{
- *trpoint = pdummy;
- trpoint->GetCPoint()= cldummy;
- }
-
- }
-
-}
Double_t AliTPCseed::GetDensityFirst(Int_t n)
}
// Double_t y1=fP0, z1=fP1;
- Double_t c1=GetSnp(), r1=sqrt(1.- c1*c1);
- Double_t c2=c1 + GetC()*dx, r2=sqrt(1.- c2*c2);
+ Double_t c1=GetSnp(), r1=sqrt((1.-c1)*(1.+c1));
+ Double_t c2=c1 + GetC()*dx, r2=sqrt((1.-c2)*(1.+c2));
y = GetY();
z = GetZ();
//-----------------------------------------------------------------
Double_t p[2]={c->GetY(), c->GetZ()};
Double_t cov[3]={fErrorY2, 0., fErrorZ2};
+
+ Float_t dx = ((AliTPCclusterMI*)c)->GetX()-GetX();
+ if (TMath::Abs(dx)>0){
+ Float_t ty = TMath::Tan(TMath::ASin(GetSnp()));
+ Float_t dy = dx*ty;
+ Float_t dz = dx*TMath::Sqrt(1.+ty*ty)*GetTgl();
+ p[0] = c->GetY()-dy;
+ p[1] = c->GetZ()-dz;
+ }
return AliExternalTrackParam::GetPredictedChi2(p,cov);
}
//_____________________________________________________________________________
-Bool_t AliTPCseed::Update(const AliCluster *c, Double_t chisq, Int_t /*index*/)
+Bool_t AliTPCseed::Update(const AliCluster *c, Double_t chisq, Int_t index)
{
//-----------------------------------------------------------------
// This function associates a cluster with this track.
//-----------------------------------------------------------------
- Double_t p[2]={c->GetY(), c->GetZ()};
- Double_t cov[3]={fErrorY2, 0., fErrorZ2};
+ Int_t n=GetNumberOfClusters();
+ Int_t idx=GetClusterIndex(n); // save the current cluster index
+
+ AliCluster cl(*c); cl.SetSigmaY2(fErrorY2); cl.SetSigmaZ2(fErrorZ2);
+ Float_t dx = ((AliTPCclusterMI*)c)->GetX()-GetX();
+ if (TMath::Abs(dx)>0){
+ Float_t ty = TMath::Tan(TMath::ASin(GetSnp()));
+ Float_t dy = dx*ty;
+ Float_t dz = dx*TMath::Sqrt(1.+ty*ty)*GetTgl();
+ cl.SetY(c->GetY()-dy);
+ cl.SetZ(c->GetZ()-dz);
+ }
- if (!AliExternalTrackParam::Update(p,cov)) return kFALSE;
+ if (!AliTPCtrack::Update(&cl,chisq,index)) return kFALSE;
+
+ if (fCMeanSigmaY2p30<0){
+ fCMeanSigmaY2p30= c->GetSigmaY2(); //! current mean sigma Y2 - mean30%
+ fCMeanSigmaZ2p30= c->GetSigmaZ2(); //! current mean sigma Z2 - mean30%
+ fCMeanSigmaY2p30R = 1; //! current mean sigma Y2 - mean5%
+ fCMeanSigmaZ2p30R = 1; //! current mean sigma Z2 - mean5%
+ }
+ //
+ fCMeanSigmaY2p30= 0.70*fCMeanSigmaY2p30 +0.30*c->GetSigmaY2();
+ fCMeanSigmaZ2p30= 0.70*fCMeanSigmaZ2p30 +0.30*c->GetSigmaZ2();
+ if (fCurrentSigmaY2>0){
+ fCMeanSigmaY2p30R = 0.7*fCMeanSigmaY2p30R +0.3*c->GetSigmaY2()/fCurrentSigmaY2;
+ fCMeanSigmaZ2p30R = 0.7*fCMeanSigmaZ2p30R +0.3*c->GetSigmaZ2()/fCurrentSigmaZ2;
+ }
- Int_t n=GetNumberOfClusters();
- // fIndex[n]=index;
- SetNumberOfClusters(n+1);
- SetChi2(GetChi2()+chisq);
+ SetClusterIndex(n,idx); // restore the current cluster index
return kTRUE;
}
//_____________________________________________________________________________
-Float_t AliTPCseed::CookdEdx(Double_t low, Double_t up,Int_t i1, Int_t i2, Bool_t onlyused) {
+Float_t AliTPCseed::CookdEdx(Double_t low, Double_t up,Int_t i1, Int_t i2, Bool_t /* onlyused */) {
//-----------------------------------------------------------------
// This funtion calculates dE/dX within the "low" and "up" cuts.
//-----------------------------------------------------------------
+ AliTPCParam *param = AliTPCcalibDB::Instance()->GetParameters();
+ Int_t row0 = param->GetNRowLow();
+ Int_t row1 = row0+param->GetNRowUp1();
+ Int_t row2 = row1+param->GetNRowUp2();
+ //
+ //
+ //
+ fDEDX[0] = CookdEdxNorm(low,up,0 ,i1 ,i2, kTRUE,kFALSE,2,0);
+ fDEDX[1] = CookdEdxNorm(low,up,0 ,0 ,row0,kTRUE,kFALSE,2,0);
+ fDEDX[2] = CookdEdxNorm(low,up,0 ,row0,row1,kTRUE,kFALSE,2,0);
+ fDEDX[3] = CookdEdxNorm(low,up,0 ,row1,row2,kTRUE,kFALSE,2,0);
+ //
+ fSDEDX[0] = CookdEdxNorm(low,up,0 ,i1 ,i2, kTRUE,kFALSE,2,1);
+ fSDEDX[1] = CookdEdxNorm(low,up,0 ,0 ,row0,kTRUE,kFALSE,2,1);
+ fSDEDX[2] = CookdEdxNorm(low,up,0 ,row0,row1,kTRUE,kFALSE,2,1);
+ fSDEDX[3] = CookdEdxNorm(low,up,0 ,row1,row2,kTRUE,kFALSE,2,1);
+ //
+ fNCDEDX[0] = TMath::Nint(CookdEdxNorm(low,up,0 ,i1 ,i2, kTRUE,kFALSE,2,2));
+ fNCDEDX[1] = TMath::Nint(CookdEdxNorm(low,up,0 ,0 ,row0,kTRUE,kFALSE,2,2));
+ fNCDEDX[2] = TMath::Nint(CookdEdxNorm(low,up,0 ,row0,row1,kTRUE,kFALSE,2,2));
+ fNCDEDX[3] = TMath::Nint(CookdEdxNorm(low,up,0 ,row1,row2,kTRUE,kFALSE,2,2));
+
+ SetdEdx(fDEDX[0]);
+ return fDEDX[0];
- Float_t amp[200];
- Float_t angular[200];
- Float_t weight[200];
- Int_t index[200];
- //Int_t nc = 0;
- // TClonesArray & arr = *fPoints;
- Float_t meanlog = 100.;
+// return CookdEdxNorm(low,up,0,i1,i2,1,0,2);
+
+
+// Float_t amp[200];
+// Float_t angular[200];
+// Float_t weight[200];
+// Int_t index[200];
+// //Int_t nc = 0;
+// Float_t meanlog = 100.;
- Float_t mean[4] = {0,0,0,0};
- Float_t sigma[4] = {1000,1000,1000,1000};
- Int_t nc[4] = {0,0,0,0};
- Float_t norm[4] = {1000,1000,1000,1000};
- //
- //
- fNShared =0;
-
- for (Int_t of =0; of<4; of++){
- for (Int_t i=of+i1;i<i2;i+=4)
- {
- Int_t index = fIndex[i];
- if (index<0||index&0x8000) continue;
-
- //AliTPCTrackPoint * point = (AliTPCTrackPoint *) arr.At(i);
- AliTPCTrackerPoint * point = GetTrackPoint(i);
- //AliTPCTrackerPoint * pointm = GetTrackPoint(i-1);
- //AliTPCTrackerPoint * pointp = 0;
- //if (i<159) pointp = GetTrackPoint(i+1);
-
- if (point==0) continue;
- AliTPCclusterMI * cl = fClusterPointer[i];
- if (cl==0) continue;
- if (onlyused && (!cl->IsUsed(10))) continue;
- if (cl->IsUsed(11)) {
- fNShared++;
- continue;
- }
- Int_t type = cl->GetType();
- //if (point->fIsShared){
- // fNShared++;
- // continue;
- //}
- //if (pointm)
- // if (pointm->fIsShared) continue;
- //if (pointp)
- // if (pointp->fIsShared) continue;
-
- if (type<0) continue;
- //if (type>10) continue;
- //if (point->GetErrY()==0) continue;
- //if (point->GetErrZ()==0) continue;
-
- //Float_t ddy = (point->GetY()-cl->GetY())/point->GetErrY();
- //Float_t ddz = (point->GetZ()-cl->GetZ())/point->GetErrZ();
- //if ((ddy*ddy+ddz*ddz)>10) continue;
-
-
- // if (point->GetCPoint().GetMax()<5) continue;
- if (cl->GetMax()<5) continue;
- Float_t angley = point->GetAngleY();
- Float_t anglez = point->GetAngleZ();
-
- Float_t rsigmay2 = point->GetSigmaY();
- Float_t rsigmaz2 = point->GetSigmaZ();
- /*
- Float_t ns = 1.;
- if (pointm){
- rsigmay += pointm->GetTPoint().GetSigmaY();
- rsigmaz += pointm->GetTPoint().GetSigmaZ();
- ns+=1.;
- }
- if (pointp){
- rsigmay += pointp->GetTPoint().GetSigmaY();
- rsigmaz += pointp->GetTPoint().GetSigmaZ();
- ns+=1.;
- }
- rsigmay/=ns;
- rsigmaz/=ns;
- */
-
- Float_t rsigma = TMath::Sqrt(rsigmay2*rsigmaz2);
-
- Float_t ampc = 0; // normalization to the number of electrons
- if (i>64){
- // ampc = 1.*point->GetCPoint().GetMax();
- ampc = 1.*cl->GetMax();
- //ampc = 1.*point->GetCPoint().GetQ();
- // AliTPCClusterPoint & p = point->GetCPoint();
- // Float_t dy = TMath::Abs(Int_t( TMath::Abs(p.GetY()/0.6)) - TMath::Abs(p.GetY()/0.6)+0.5);
- // Float_t iz = (250.0-TMath::Abs(p.GetZ())+0.11)/0.566;
- //Float_t dz =
- // TMath::Abs( Int_t(iz) - iz + 0.5);
- //ampc *= 1.15*(1-0.3*dy);
- //ampc *= 1.15*(1-0.3*dz);
- // Float_t zfactor = (AliTPCReconstructor::GetCtgRange()-0.0004*TMath::Abs(point->GetCPoint().GetZ()));
- //ampc *=zfactor;
- }
- else{
- //ampc = 1.0*point->GetCPoint().GetMax();
- ampc = 1.0*cl->GetMax();
- //ampc = 1.0*point->GetCPoint().GetQ();
- //AliTPCClusterPoint & p = point->GetCPoint();
- // Float_t dy = TMath::Abs(Int_t( TMath::Abs(p.GetY()/0.4)) - TMath::Abs(p.GetY()/0.4)+0.5);
- //Float_t iz = (250.0-TMath::Abs(p.GetZ())+0.11)/0.566;
- //Float_t dz =
- // TMath::Abs( Int_t(iz) - iz + 0.5);
-
- //ampc *= 1.15*(1-0.3*dy);
- //ampc *= 1.15*(1-0.3*dz);
- // Float_t zfactor = (1.02-0.000*TMath::Abs(point->GetCPoint().GetZ()));
- //ampc *=zfactor;
-
- }
- ampc *= 2.0; // put mean value to channel 50
- //ampc *= 0.58; // put mean value to channel 50
- Float_t w = 1.;
- // if (type>0) w = 1./(type/2.-0.5);
- // Float_t z = TMath::Abs(cl->GetZ());
- if (i<64) {
- ampc /= 0.6;
- //ampc /= (1+0.0008*z);
- } else
- if (i>128){
- ampc /=1.5;
- //ampc /= (1+0.0008*z);
- }else{
- //ampc /= (1+0.0008*z);
- }
+// Float_t mean[4] = {0,0,0,0};
+// Float_t sigma[4] = {1000,1000,1000,1000};
+// Int_t nc[4] = {0,0,0,0};
+// Float_t norm[4] = {1000,1000,1000,1000};
+// //
+// //
+// fNShared =0;
+
+// Float_t gainGG = 1;
+// if (AliTPCcalibDB::Instance()->GetParameters()){
+// gainGG= AliTPCcalibDB::Instance()->GetParameters()->GetGasGain()/20000.; //relative gas gain
+// }
+
+
+// for (Int_t of =0; of<4; of++){
+// for (Int_t i=of+i1;i<i2;i+=4)
+// {
+// Int_t clindex = fIndex[i];
+// if (clindex<0||clindex&0x8000) continue;
+
+// //AliTPCTrackPoint * point = (AliTPCTrackPoint *) arr.At(i);
+// AliTPCTrackerPoint * point = GetTrackPoint(i);
+// //AliTPCTrackerPoint * pointm = GetTrackPoint(i-1);
+// //AliTPCTrackerPoint * pointp = 0;
+// //if (i<159) pointp = GetTrackPoint(i+1);
+
+// if (point==0) continue;
+// AliTPCclusterMI * cl = fClusterPointer[i];
+// if (cl==0) continue;
+// if (onlyused && (!cl->IsUsed(10))) continue;
+// if (cl->IsUsed(11)) {
+// fNShared++;
+// continue;
+// }
+// Int_t type = cl->GetType();
+// //if (point->fIsShared){
+// // fNShared++;
+// // continue;
+// //}
+// //if (pointm)
+// // if (pointm->fIsShared) continue;
+// //if (pointp)
+// // if (pointp->fIsShared) continue;
+
+// if (type<0) continue;
+// //if (type>10) continue;
+// //if (point->GetErrY()==0) continue;
+// //if (point->GetErrZ()==0) continue;
+
+// //Float_t ddy = (point->GetY()-cl->GetY())/point->GetErrY();
+// //Float_t ddz = (point->GetZ()-cl->GetZ())/point->GetErrZ();
+// //if ((ddy*ddy+ddz*ddz)>10) continue;
+
+
+// // if (point->GetCPoint().GetMax()<5) continue;
+// if (cl->GetMax()<5) continue;
+// Float_t angley = point->GetAngleY();
+// Float_t anglez = point->GetAngleZ();
+
+// Float_t rsigmay2 = point->GetSigmaY();
+// Float_t rsigmaz2 = point->GetSigmaZ();
+// /*
+// Float_t ns = 1.;
+// if (pointm){
+// rsigmay += pointm->GetTPoint().GetSigmaY();
+// rsigmaz += pointm->GetTPoint().GetSigmaZ();
+// ns+=1.;
+// }
+// if (pointp){
+// rsigmay += pointp->GetTPoint().GetSigmaY();
+// rsigmaz += pointp->GetTPoint().GetSigmaZ();
+// ns+=1.;
+// }
+// rsigmay/=ns;
+// rsigmaz/=ns;
+// */
+
+// Float_t rsigma = TMath::Sqrt(rsigmay2*rsigmaz2);
+
+// Float_t ampc = 0; // normalization to the number of electrons
+// if (i>64){
+// // ampc = 1.*point->GetCPoint().GetMax();
+// ampc = 1.*cl->GetMax();
+// //ampc = 1.*point->GetCPoint().GetQ();
+// // AliTPCClusterPoint & p = point->GetCPoint();
+// // Float_t dy = TMath::Abs(Int_t( TMath::Abs(p.GetY()/0.6)) - TMath::Abs(p.GetY()/0.6)+0.5);
+// // Float_t iz = (250.0-TMath::Abs(p.GetZ())+0.11)/0.566;
+// //Float_t dz =
+// // TMath::Abs( Int_t(iz) - iz + 0.5);
+// //ampc *= 1.15*(1-0.3*dy);
+// //ampc *= 1.15*(1-0.3*dz);
+// // Float_t zfactor = (AliTPCReconstructor::GetCtgRange()-0.0004*TMath::Abs(point->GetCPoint().GetZ()));
+// //ampc *=zfactor;
+// }
+// else{
+// //ampc = 1.0*point->GetCPoint().GetMax();
+// ampc = 1.0*cl->GetMax();
+// //ampc = 1.0*point->GetCPoint().GetQ();
+// //AliTPCClusterPoint & p = point->GetCPoint();
+// // Float_t dy = TMath::Abs(Int_t( TMath::Abs(p.GetY()/0.4)) - TMath::Abs(p.GetY()/0.4)+0.5);
+// //Float_t iz = (250.0-TMath::Abs(p.GetZ())+0.11)/0.566;
+// //Float_t dz =
+// // TMath::Abs( Int_t(iz) - iz + 0.5);
+
+// //ampc *= 1.15*(1-0.3*dy);
+// //ampc *= 1.15*(1-0.3*dz);
+// // Float_t zfactor = (1.02-0.000*TMath::Abs(point->GetCPoint().GetZ()));
+// //ampc *=zfactor;
+
+// }
+// ampc *= 2.0; // put mean value to channel 50
+// //ampc *= 0.58; // put mean value to channel 50
+// Float_t w = 1.;
+// // if (type>0) w = 1./(type/2.-0.5);
+// // Float_t z = TMath::Abs(cl->GetZ());
+// if (i<64) {
+// ampc /= 0.6;
+// //ampc /= (1+0.0008*z);
+// } else
+// if (i>128){
+// ampc /=1.5;
+// //ampc /= (1+0.0008*z);
+// }else{
+// //ampc /= (1+0.0008*z);
+// }
- if (type<0) { //amp at the border - lower weight
- // w*= 2.;
+// if (type<0) { //amp at the border - lower weight
+// // w*= 2.;
- continue;
- }
- if (rsigma>1.5) ampc/=1.3; // if big backround
- amp[nc[of]] = ampc;
- angular[nc[of]] = TMath::Sqrt(1.+angley*angley+anglez*anglez);
- weight[nc[of]] = w;
- nc[of]++;
- }
+// continue;
+// }
+// if (rsigma>1.5) ampc/=1.3; // if big backround
+// amp[nc[of]] = ampc;
+// amp[nc[of]] /=gainGG;
+// angular[nc[of]] = TMath::Sqrt(1.+angley*angley+anglez*anglez);
+// weight[nc[of]] = w;
+// nc[of]++;
+// }
- TMath::Sort(nc[of],amp,index,kFALSE);
- Float_t sumamp=0;
- Float_t sumamp2=0;
- Float_t sumw=0;
- //meanlog = amp[index[Int_t(nc[of]*0.33)]];
- meanlog = 50;
- for (Int_t i=int(nc[of]*low+0.5);i<int(nc[of]*up+0.5);i++){
- Float_t ampl = amp[index[i]]/angular[index[i]];
- ampl = meanlog*TMath::Log(1.+ampl/meanlog);
- //
- sumw += weight[index[i]];
- sumamp += weight[index[i]]*ampl;
- sumamp2 += weight[index[i]]*ampl*ampl;
- norm[of] += angular[index[i]]*weight[index[i]];
- }
- if (sumw<1){
- SetdEdx(0);
- }
- else {
- norm[of] /= sumw;
- mean[of] = sumamp/sumw;
- sigma[of] = sumamp2/sumw-mean[of]*mean[of];
- if (sigma[of]>0.1)
- sigma[of] = TMath::Sqrt(sigma[of]);
- else
- sigma[of] = 1000;
+// TMath::Sort(nc[of],amp,index,kFALSE);
+// Float_t sumamp=0;
+// Float_t sumamp2=0;
+// Float_t sumw=0;
+// //meanlog = amp[index[Int_t(nc[of]*0.33)]];
+// meanlog = 50;
+// for (Int_t i=int(nc[of]*low+0.5);i<int(nc[of]*up+0.5);i++){
+// Float_t ampl = amp[index[i]]/angular[index[i]];
+// ampl = meanlog*TMath::Log(1.+ampl/meanlog);
+// //
+// sumw += weight[index[i]];
+// sumamp += weight[index[i]]*ampl;
+// sumamp2 += weight[index[i]]*ampl*ampl;
+// norm[of] += angular[index[i]]*weight[index[i]];
+// }
+// if (sumw<1){
+// SetdEdx(0);
+// }
+// else {
+// norm[of] /= sumw;
+// mean[of] = sumamp/sumw;
+// sigma[of] = sumamp2/sumw-mean[of]*mean[of];
+// if (sigma[of]>0.1)
+// sigma[of] = TMath::Sqrt(sigma[of]);
+// else
+// sigma[of] = 1000;
- mean[of] = (TMath::Exp(mean[of]/meanlog)-1)*meanlog;
- //mean *=(1-0.02*(sigma/(mean*0.17)-1.));
- //mean *=(1-0.1*(norm-1.));
- }
- }
-
- Float_t dedx =0;
- fSdEdx =0;
- fMAngular =0;
- // mean[0]*= (1-0.05*(sigma[0]/(0.01+mean[1]*0.18)-1));
- // mean[1]*= (1-0.05*(sigma[1]/(0.01+mean[0]*0.18)-1));
+// mean[of] = (TMath::Exp(mean[of]/meanlog)-1)*meanlog;
+// //mean *=(1-0.02*(sigma/(mean*0.17)-1.));
+// //mean *=(1-0.1*(norm-1.));
+// }
+// }
+
+// Float_t dedx =0;
+// fSdEdx =0;
+// fMAngular =0;
+// // mean[0]*= (1-0.05*(sigma[0]/(0.01+mean[1]*0.18)-1));
+// // mean[1]*= (1-0.05*(sigma[1]/(0.01+mean[0]*0.18)-1));
- // dedx = (mean[0]* TMath::Sqrt((1.+nc[0]))+ mean[1]* TMath::Sqrt((1.+nc[1])) )/
- // ( TMath::Sqrt((1.+nc[0]))+TMath::Sqrt((1.+nc[1])));
-
- Int_t norm2 = 0;
- Int_t norm3 = 0;
- for (Int_t i =0;i<4;i++){
- if (nc[i]>2&&nc[i]<1000){
- dedx += mean[i] *nc[i];
- fSdEdx += sigma[i]*(nc[i]-2);
- fMAngular += norm[i] *nc[i];
- norm2 += nc[i];
- norm3 += nc[i]-2;
- }
- fDEDX[i] = mean[i];
- fSDEDX[i] = sigma[i];
- fNCDEDX[i]= nc[i];
- }
-
- if (norm3>0){
- dedx /=norm2;
- fSdEdx /=norm3;
- fMAngular/=norm2;
- }
- else{
- SetdEdx(0);
- return 0;
- }
- // Float_t dedx1 =dedx;
- /*
- dedx =0;
- for (Int_t i =0;i<4;i++){
- if (nc[i]>2&&nc[i]<1000){
- mean[i] = mean[i]*(1-0.12*(sigma[i]/(fSdEdx)-1.));
- dedx += mean[i] *nc[i];
- }
- fDEDX[i] = mean[i];
- }
- dedx /= norm2;
- */
+// // dedx = (mean[0]* TMath::Sqrt((1.+nc[0]))+ mean[1]* TMath::Sqrt((1.+nc[1])) )/
+// // ( TMath::Sqrt((1.+nc[0]))+TMath::Sqrt((1.+nc[1])));
+
+// Int_t norm2 = 0;
+// Int_t norm3 = 0;
+// for (Int_t i =0;i<4;i++){
+// if (nc[i]>2&&nc[i]<1000){
+// dedx += mean[i] *nc[i];
+// fSdEdx += sigma[i]*(nc[i]-2);
+// fMAngular += norm[i] *nc[i];
+// norm2 += nc[i];
+// norm3 += nc[i]-2;
+// }
+// fDEDX[i] = mean[i];
+// fSDEDX[i] = sigma[i];
+// fNCDEDX[i]= nc[i];
+// }
+
+// if (norm3>0){
+// dedx /=norm2;
+// fSdEdx /=norm3;
+// fMAngular/=norm2;
+// }
+// else{
+// SetdEdx(0);
+// return 0;
+// }
+// // Float_t dedx1 =dedx;
+// /*
+// dedx =0;
+// for (Int_t i =0;i<4;i++){
+// if (nc[i]>2&&nc[i]<1000){
+// mean[i] = mean[i]*(1-0.12*(sigma[i]/(fSdEdx)-1.));
+// dedx += mean[i] *nc[i];
+// }
+// fDEDX[i] = mean[i];
+// }
+// dedx /= norm2;
+// */
- SetdEdx(dedx);
- return dedx;
-}
-Double_t AliTPCseed::Bethe(Double_t bg){
- //
- // This is the Bethe-Bloch function normalised to 1 at the minimum
- //
- Double_t bg2=bg*bg;
- Double_t bethe;
- if (bg<3.5e1)
- bethe=(1.+ bg2)/bg2*(log(5940*bg2) - bg2/(1.+ bg2));
- else // Density effect ( approximately :)
- bethe=1.15*(1.+ bg2)/bg2*(log(3.5*5940*bg) - bg2/(1.+ bg2));
- return bethe/11.091;
+// SetdEdx(dedx);
+// return dedx;
}
void AliTPCseed::CookPID()
Double_t mass=AliPID::ParticleMass(j);
Double_t mom=GetP();
Double_t dedx=fdEdx/fMIP;
- Double_t bethe=Bethe(mom/mass);
+ Double_t bethe=AliMathBase::BetheBlochAleph(mom/mass);
Double_t sigma=fRes*bethe;
if (sigma>0.001){
if (TMath::Abs(dedx-bethe) > fRange*sigma) {
}
}
-/*
-void AliTPCseed::CookdEdx2(Double_t low, Double_t up) {
- //-----------------------------------------------------------------
- // This funtion calculates dE/dX within the "low" and "up" cuts.
- //-----------------------------------------------------------------
-
- Float_t amp[200];
- Float_t angular[200];
- Float_t weight[200];
- Int_t index[200];
- Bool_t inlimit[200];
- for (Int_t i=0;i<200;i++) inlimit[i]=kFALSE;
- for (Int_t i=0;i<200;i++) amp[i]=10000;
- for (Int_t i=0;i<200;i++) angular[i]= 1;;
-
-
- //
- Float_t meanlog = 100.;
- Int_t indexde[4]={0,64,128,160};
-
- Float_t amean =0;
- Float_t asigma =0;
- Float_t anc =0;
- Float_t anorm =0;
-
- Float_t mean[4] = {0,0,0,0};
- Float_t sigma[4] = {1000,1000,1000,1000};
- Int_t nc[4] = {0,0,0,0};
- Float_t norm[4] = {1000,1000,1000,1000};
- //
- //
- fNShared =0;
-
- // for (Int_t of =0; of<3; of++){
- // for (Int_t i=indexde[of];i<indexde[of+1];i++)
- for (Int_t i =0; i<160;i++)
- {
- AliTPCTrackPoint * point = GetTrackPoint(i);
- if (point==0) continue;
- if (point->fIsShared){
- fNShared++;
- continue;
- }
- Int_t type = point->GetCPoint().GetType();
- if (type<0) continue;
- if (point->GetCPoint().GetMax()<5) continue;
- Float_t angley = point->GetTPoint().GetAngleY();
- Float_t anglez = point->GetTPoint().GetAngleZ();
- Float_t rsigmay = point->GetCPoint().GetSigmaY();
- Float_t rsigmaz = point->GetCPoint().GetSigmaZ();
- Float_t rsigma = TMath::Sqrt(rsigmay*rsigmaz);
-
- Float_t ampc = 0; // normalization to the number of electrons
- if (i>64){
- ampc = point->GetCPoint().GetMax();
- }
- else{
- ampc = point->GetCPoint().GetMax();
- }
- ampc *= 2.0; // put mean value to channel 50
- // ampc *= 0.565; // put mean value to channel 50
-
- Float_t w = 1.;
- Float_t z = TMath::Abs(point->GetCPoint().GetZ());
- if (i<64) {
- ampc /= 0.63;
- } else
- if (i>128){
- ampc /=1.51;
- }
- if (type<0) { //amp at the border - lower weight
- continue;
- }
- if (rsigma>1.5) ampc/=1.3; // if big backround
- angular[i] = TMath::Sqrt(1.+angley*angley+anglez*anglez);
- amp[i] = ampc/angular[i];
- weight[i] = w;
- anc++;
- }
-
- TMath::Sort(159,amp,index,kFALSE);
- for (Int_t i=int(anc*low+0.5);i<int(anc*up+0.5);i++){
- inlimit[index[i]] = kTRUE; // take all clusters
- }
-
- // meanlog = amp[index[Int_t(anc*0.3)]];
- meanlog =10000.;
- for (Int_t of =0; of<3; of++){
- Float_t sumamp=0;
- Float_t sumamp2=0;
- Float_t sumw=0;
- for (Int_t i=indexde[of];i<indexde[of+1];i++)
- {
- if (inlimit[i]==kFALSE) continue;
- Float_t ampl = amp[i];
- ///angular[i];
- ampl = meanlog*TMath::Log(1.+ampl/meanlog);
- //
- sumw += weight[i];
- sumamp += weight[i]*ampl;
- sumamp2 += weight[i]*ampl*ampl;
- norm[of] += angular[i]*weight[i];
- nc[of]++;
- }
- if (sumw<1){
- SetdEdx(0);
- }
- else {
- norm[of] /= sumw;
- mean[of] = sumamp/sumw;
- sigma[of] = sumamp2/sumw-mean[of]*mean[of];
- if (sigma[of]>0.1)
- sigma[of] = TMath::Sqrt(sigma[of]);
- else
- sigma[of] = 1000;
- mean[of] = (TMath::Exp(mean[of]/meanlog)-1)*meanlog;
- }
- }
-
- Float_t dedx =0;
- fSdEdx =0;
- fMAngular =0;
- //
- Int_t norm2 = 0;
- Int_t norm3 = 0;
- Float_t www[3] = {12.,14.,17.};
- //Float_t www[3] = {1.,1.,1.};
-
- for (Int_t i =0;i<3;i++){
- if (nc[i]>2&&nc[i]<1000){
- dedx += mean[i] *nc[i]*www[i]/sigma[i];
- fSdEdx += sigma[i]*(nc[i]-2)*www[i]/sigma[i];
- fMAngular += norm[i] *nc[i];
- norm2 += nc[i]*www[i]/sigma[i];
- norm3 += (nc[i]-2)*www[i]/sigma[i];
- }
- fDEDX[i] = mean[i];
- fSDEDX[i] = sigma[i];
- fNCDEDX[i]= nc[i];
- }
-
- if (norm3>0){
- dedx /=norm2;
- fSdEdx /=norm3;
- fMAngular/=norm2;
- }
- else{
- SetdEdx(0);
- return;
- }
- // Float_t dedx1 =dedx;
-
- dedx =0;
- Float_t norm4 = 0;
- for (Int_t i =0;i<3;i++){
- if (nc[i]>2&&nc[i]<1000&&sigma[i]>3){
- //mean[i] = mean[i]*(1+0.08*(sigma[i]/(fSdEdx)-1.));
- dedx += mean[i] *(nc[i])/(sigma[i]);
- norm4 += (nc[i])/(sigma[i]);
- }
- fDEDX[i] = mean[i];
- }
- if (norm4>0) dedx /= norm4;
-
-
-
- SetdEdx(dedx);
-
- //mi deDX
-
-}
-*/
Double_t AliTPCseed::GetYat(Double_t xk) const {
//-----------------------------------------------------------------
// This function calculates the Y-coordinate of a track at the plane x=xk.
//-----------------------------------------------------------------
if (TMath::Abs(GetSnp())>AliTPCReconstructor::GetMaxSnpTrack()) return 0.; //patch 01 jan 06
- Double_t c1=GetSnp(), r1=TMath::Sqrt(1.- c1*c1);
+ Double_t c1=GetSnp(), r1=TMath::Sqrt((1.-c1)*(1.+c1));
Double_t c2=c1+GetC()*(xk-GetX());
if (TMath::Abs(c2)>AliTPCReconstructor::GetMaxSnpTrack()) return 0;
- Double_t r2=TMath::Sqrt(1.- c2*c2);
+ Double_t r2=TMath::Sqrt((1.-c2)*(1.+c2));
return GetY() + (xk-GetX())*(c1+c2)/(r1+r2);
}
{
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){
+
+ //
+ // calculates dedx using the cluster
+ // low - up specify trunc mean range - default form 0-0.7
+ // type - 1 - max charge or 0- total charge in cluster
+ // //2- max no corr 3- total+ correction
+ // i1-i2 - the pad-row range used for calculation
+ // shapeNorm - kTRUE -taken from OCDB
+ //
+ // posNorm - usage of pos normalization
+ // padNorm - pad type normalization
+ // returnVal - 0 return mean
+ // - 1 return RMS
+ // - 2 return number of clusters
+ //
+ // normalization parametrization taken from AliTPCClusterParam
+ //
+ AliTPCClusterParam * parcl = AliTPCcalibDB::Instance()->GetClusterParam();
+ AliTPCParam * param = AliTPCcalibDB::Instance()->GetParameters();
+ if (!parcl) return 0;
+ if (!param) return 0;
+ Int_t row0 = param->GetNRowLow();
+ Int_t row1 = row0+param->GetNRowUp1();
+
+ Float_t amp[160];
+ Int_t indexes[160];
+ Int_t ncl=0;
+ //
+ //
+ Float_t gainGG = 1; // gas gain factor -always enabled
+ Float_t gainPad = 1; // gain map - used always
+ Float_t corrShape = 1; // correction due angular effect, diffusion and electron attachment
+ Float_t corrPos = 1; // local position correction - if posNorm enabled
+ Float_t corrPadType = 1; // pad type correction - if padNorm enabled
+ Float_t corrNorm = 1; // normalization factor - set Q to channel 50
+ //
+ //
+ //
+ if (AliTPCcalibDB::Instance()->GetParameters()){
+ gainGG= AliTPCcalibDB::Instance()->GetParameters()->GetGasGain()/20000; //relative gas gain
+ }
+
+ const Float_t ktany = TMath::Tan(TMath::DegToRad()*10);
+ const Float_t kedgey =3.;
+ //
+ //
+ for (Int_t irow=i1; irow<i2; irow++){
+ AliTPCclusterMI* cluster = GetClusterPointer(irow);
+ if (!cluster) continue;
+ if (TMath::Abs(cluster->GetY())>cluster->GetX()*ktany-kedgey) continue; // edge cluster
+ Float_t charge= (type%2)? cluster->GetMax():cluster->GetQ();
+ Int_t ipad= 0;
+ if (irow>=row0) ipad=1;
+ if (irow>=row1) ipad=2;
+ //
+ //
+ //
+ AliTPCCalPad * gainMap = AliTPCcalibDB::Instance()->GetDedxGainFactor();
+ if (gainMap) {
+ //
+ // Get gainPad - pad by pad calibration
+ //
+ Float_t factor = 1;
+ AliTPCCalROC * roc = gainMap->GetCalROC(cluster->GetDetector());
+ if (irow < row0) { // IROC
+ factor = roc->GetValue(irow, TMath::Nint(cluster->GetPad()));
+ } else { // OROC
+ factor = roc->GetValue(irow - row0, TMath::Nint(cluster->GetPad()));
+ }
+ if (factor>0.5) gainPad=factor;
+ }
+ //
+ //do position and angular normalization
+ //
+ if (shapeNorm){
+ if (type<=1){
+ //
+ AliTPCTrackerPoint * point = GetTrackPoint(irow);
+ Float_t ty = TMath::Abs(point->GetAngleY());
+ Float_t tz = TMath::Abs(point->GetAngleZ()*TMath::Sqrt(1+ty*ty));
+
+ Float_t dr = (250.-TMath::Abs(cluster->GetZ()))/250.;
+ corrShape = parcl->Qnorm(ipad,type,dr,ty,tz);
+ }
+ }
+
+ if (posNorm>0){
+ //
+ // Do position normalization - relative distance to
+ // center of pad- time bin
+ // Work in progress
+ // corrPos = parcl->QnormPos(ipad,type, cluster->GetPad(),
+ // cluster->GetTimeBin(), cluster->GetZ(),
+ // cluster->GetSigmaY2(),cluster->GetSigmaZ2(),
+ // cluster->GetMax(),cluster->GetQ());
+ // scaled response function
+ Float_t yres0 = parcl->GetRMS0(0,ipad,0,0)/param->GetPadPitchWidth(cluster->GetDetector());
+ Float_t zres0 = parcl->GetRMS0(1,ipad,0,0)/param->GetZWidth();
+ //
+
+ AliTPCTrackerPoint * point = GetTrackPoint(irow);
+ Float_t ty = TMath::Abs(point->GetAngleY());
+ Float_t tz = TMath::Abs(point->GetAngleZ()*TMath::Sqrt(1+ty*ty));
+
+ if (type==1) corrPos =
+ parcl->QmaxCorrection(cluster->GetDetector(), cluster->GetRow(),cluster->GetPad(),
+ cluster->GetTimeBin(),ty,tz,yres0,zres0,0.4);
+ if (type==0) corrPos =
+ parcl->QtotCorrection(cluster->GetDetector(), cluster->GetRow(),cluster->GetPad(),
+ cluster->GetTimeBin(),ty,tz,yres0,zres0,cluster->GetQ(),2.5,0.4);
+ if (posNorm==3){
+ Float_t dr = (250.-TMath::Abs(cluster->GetZ()))/250.;
+ Double_t signtgl = (cluster->GetZ()*point->GetAngleZ()>0)? 1:-1;
+ Double_t p2 = TMath::Abs(TMath::Sin(TMath::ATan(ty)));
+ Float_t corrHis = parcl->QnormHis(ipad,type,dr,p2,TMath::Abs(point->GetAngleZ())*signtgl);
+ if (corrHis>0) corrPos*=corrHis;
+ }
+
+ }
+
+ if (padNorm==1){
+ //taken from OCDB
+ if (type==0 && parcl->fQpadTnorm) corrPadType = (*parcl->fQpadTnorm)[ipad];
+ if (type==1 && parcl->fQpadTnorm) corrPadType = (*parcl->fQpadMnorm)[ipad];
+
+ }
+ if (padNorm==2){
+ corrPadType =param->GetPadPitchLength(cluster->GetDetector(),cluster->GetRow());
+ //use hardwired - temp fix
+ if (type==0) corrNorm=3.;
+ if (type==1) corrNorm=1.;
+ }
+ //
+ amp[ncl]=charge;
+ amp[ncl]/=gainGG;
+ amp[ncl]/=gainPad;
+ amp[ncl]/=corrShape;
+ amp[ncl]/=corrPadType;
+ amp[ncl]/=corrPos;
+ amp[ncl]/=corrNorm;
+ //
+ ncl++;
+ }
+
+ if (type>3) return ncl;
+ TMath::Sort(ncl,amp, indexes, kFALSE);
+
+ if (ncl<10) return 0;
+
+ Float_t suma=0;
+ Float_t suma2=0;
+ Float_t sumn=0;
+ Int_t icl0=TMath::Nint(ncl*low);
+ Int_t icl1=TMath::Nint(ncl*up);
+ for (Int_t icl=icl0; icl<icl1;icl++){
+ suma+=amp[indexes[icl]];
+ suma2+=amp[indexes[icl]]*amp[indexes[icl]];
+ sumn++;
+ }
+ Float_t mean =suma/sumn;
+ Float_t rms =TMath::Sqrt(TMath::Abs(suma2/sumn-mean*mean));
+ if (returnVal==1) return rms;
+ if (returnVal==2) return ncl;
+ return mean;
+}
+
+Float_t AliTPCseed::CookdEdxAnalytical(Double_t low, Double_t up, Int_t type, Int_t i1, Int_t i2, Int_t returnVal){
+
+ //
+ // calculates dedx using the cluster
+ // low - up specify trunc mean range - default form 0-0.7
+ // type - 1 - max charge or 0- total charge in cluster
+ // //2- max no corr 3- total+ correction
+ // 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
+ //
+ // normalization parametrization taken from AliTPCClusterParam
+ //
+ AliTPCClusterParam * parcl = AliTPCcalibDB::Instance()->GetClusterParam();
+ AliTPCParam * param = AliTPCcalibDB::Instance()->GetParameters();
+ if (!parcl) return 0;
+ if (!param) return 0;
+ Int_t row0 = param->GetNRowLow();
+ Int_t row1 = row0+param->GetNRowUp1();
+
+ Float_t amp[160];
+ Int_t indexes[160];
+ Int_t ncl=0;
+ //
+ //
+ Float_t gainGG = 1; // gas gain factor -always enabled
+ Float_t gainPad = 1; // gain map - used always
+ Float_t corrPos = 1; // local position correction - if posNorm enabled
+ Float_t corrNorm = 1; // normalization factor - set Q to channel 50
+ //
+ //
+ //
+ if (AliTPCcalibDB::Instance()->GetParameters()){
+ gainGG= AliTPCcalibDB::Instance()->GetParameters()->GetGasGain()/20000; //relative gas gain
+ }
+
+ const Float_t ktany = TMath::Tan(TMath::DegToRad()*10);
+ const Float_t kedgey =3.;
+ //
+ //
+ for (Int_t irow=i1; irow<i2; irow++){
+ AliTPCclusterMI* cluster = GetClusterPointer(irow);
+ if (!cluster) continue;
+ if (TMath::Abs(cluster->GetY())>cluster->GetX()*ktany-kedgey) continue; // edge cluster
+ Float_t charge= (type%2)? cluster->GetMax():cluster->GetQ();
+ Int_t ipad= 0;
+ if (irow>=row0) ipad=1;
+ if (irow>=row1) ipad=2;
+ //
+ //
+ //
+ AliTPCCalPad * gainMap = AliTPCcalibDB::Instance()->GetDedxGainFactor();
+ if (gainMap) {
+ //
+ // Get gainPad - pad by pad calibration
+ //
+ Float_t factor = 1;
+ AliTPCCalROC * roc = gainMap->GetCalROC(cluster->GetDetector());
+ if (irow < row0) { // IROC
+ factor = roc->GetValue(irow, TMath::Nint(cluster->GetPad()));
+ } else { // OROC
+ factor = roc->GetValue(irow - row0, TMath::Nint(cluster->GetPad()));
+ }
+ if (factor>0.5) gainPad=factor;
+ }
+
+ //
+ // Do position normalization - relative distance to
+ // center of pad- time bin
+
+ AliTPCTrackerPoint * point = GetTrackPoint(irow);
+ Float_t ty = TMath::Abs(point->GetAngleY());
+ Float_t tz = TMath::Abs(point->GetAngleZ()*TMath::Sqrt(1+ty*ty));
+ Float_t yres0 = parcl->GetRMS0(0,ipad,0,0)/param->GetPadPitchWidth(cluster->GetDetector());
+ Float_t zres0 = parcl->GetRMS0(1,ipad,0,0)/param->GetZWidth();
+
+ yres0 *=parcl->GetQnormCorr(ipad, type,0);
+ zres0 *=parcl->GetQnormCorr(ipad, type,1);
+ Float_t effLength=parcl->GetQnormCorr(ipad, type,4)*0.5;
+ Float_t effDiff =(parcl->GetQnormCorr(ipad, type,2)+parcl->GetQnormCorr(ipad, type,3))*0.5;
+ //
+ if (type==1) {
+ corrPos = parcl->GetQnormCorr(ipad, type,5)*
+ parcl->QmaxCorrection(cluster->GetDetector(), cluster->GetRow(),cluster->GetPad(),
+ cluster->GetTimeBin(),ty,tz,yres0,zres0,effLength,effDiff);
+ Float_t drm = 0.5-TMath::Abs(cluster->GetZ()/250.);
+ corrPos*=(1+parcl->GetQnormCorr(ipad, type+2,0)*drm);
+ corrPos*=(1+parcl->GetQnormCorr(ipad, type+2,1)*ty*ty);
+ corrPos*=(1+parcl->GetQnormCorr(ipad, type+2,2)*tz*tz);
+ //
+ }
+ if (type==0) {
+ corrPos = parcl->GetQnormCorr(ipad, type,5)*
+ parcl->QtotCorrection(cluster->GetDetector(), cluster->GetRow(),cluster->GetPad(),
+ cluster->GetTimeBin(),ty,tz,yres0,zres0,cluster->GetQ(),2.5,effLength,effDiff);
+
+ Float_t drm = 0.5-TMath::Abs(cluster->GetZ()/250.);
+ corrPos*=(1+parcl->GetQnormCorr(ipad, type+2,0)*drm);
+ corrPos*=(1+parcl->GetQnormCorr(ipad, type+2,1)*ty*ty);
+ corrPos*=(1+parcl->GetQnormCorr(ipad, type+2,2)*tz*tz);
+ //
+ }
+
+ //
+ amp[ncl]=charge;
+ amp[ncl]/=gainGG;
+ amp[ncl]/=gainPad;
+ amp[ncl]/=corrPos;
+ //
+ ncl++;
+ }
+
+ if (type>3) return ncl;
+ TMath::Sort(ncl,amp, indexes, kFALSE);
+
+ if (ncl<10) return 0;
+
+ Float_t suma=0;
+ Float_t suma2=0;
+ Float_t sumn=0;
+ Int_t icl0=TMath::Nint(ncl*low);
+ Int_t icl1=TMath::Nint(ncl*up);
+ for (Int_t icl=icl0; icl<icl1;icl++){
+ suma+=amp[indexes[icl]];
+ suma2+=amp[indexes[icl]]*amp[indexes[icl]];
+ sumn++;
+ }
+ Float_t mean =suma/sumn;
+ Float_t rms =TMath::Sqrt(TMath::Abs(suma2/sumn-mean*mean));
+ if (returnVal==1) return rms;
+ if (returnVal==2) return ncl;
+ return mean;
+}
+
+
+
+
+Float_t AliTPCseed::CookShape(Int_t type){
+ //
+ //
+ //
+ //-----------------------------------------------------------------
+ // This funtion calculates dE/dX within the "low" and "up" cuts.
+ //-----------------------------------------------------------------
+ Float_t means=0;
+ Float_t meanc=0;
+ for (Int_t i =0; i<160;i++) {
+ AliTPCTrackerPoint * point = GetTrackPoint(i);
+ if (point==0) continue;
+
+ AliTPCclusterMI * cl = fClusterPointer[i];
+ if (cl==0) continue;
+
+ Float_t rsigmay = TMath::Sqrt(point->GetSigmaY());
+ Float_t rsigmaz = TMath::Sqrt(point->GetSigmaZ());
+ Float_t rsigma = (rsigmay+rsigmaz)*0.5;
+ if (type==0) means+=rsigma;
+ if (type==1) means+=rsigmay;
+ if (type==2) means+=rsigmaz;
+ meanc++;
+ }
+ Float_t mean = (meanc>0)? means/meanc:0;
+ return mean;
+}
+
+
+
+Int_t AliTPCseed::RefitTrack(AliTPCseed *seed, AliExternalTrackParam * parin, AliExternalTrackParam * parout){
+ //
+ // Refit the track
+ // return value - number of used clusters
+ //
+ //
+ const Int_t kMinNcl =10;
+ AliTPCseed *track=new AliTPCseed(*seed);
+ Int_t sector=-1;
+ // reset covariance
+ //
+ Double_t covar[15];
+ for (Int_t i=0;i<15;i++) covar[i]=0;
+ covar[0]=10.*10.;
+ covar[2]=10.*10.;
+ covar[5]=10.*10./(64.*64.);
+ covar[9]=10.*10./(64.*64.);
+ covar[14]=1*1;
+ //
+
+ Float_t xmin=1000, xmax=-10000;
+ Int_t imin=158, imax=0;
+ for (Int_t i=0;i<160;i++) {
+ AliTPCclusterMI *c=track->GetClusterPointer(i);
+ if (!c) continue;
+ if (sector<0) sector = c->GetDetector();
+ if (c->GetX()<xmin) xmin=c->GetX();
+ if (c->GetX()>xmax) xmax=c->GetX();
+ if (i<imin) imin=i;
+ if (i>imax) imax=i;
+ }
+ if(imax-imin<kMinNcl) {
+ delete track;
+ return 0 ;
+ }
+ // Not succes to rotate
+ if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
+ delete track;
+ return 0;
+ }
+ //
+ //
+ // fit from inner to outer row
+ //
+ AliExternalTrackParam paramIn;
+ AliExternalTrackParam paramOut;
+ Bool_t isOK=kTRUE;
+ Int_t ncl=0;
+ //
+ //
+ //
+ for (Int_t i=imin; i<=imax; i++){
+ AliTPCclusterMI *c=track->GetClusterPointer(i);
+ if (!c) continue;
+ // if (RejectCluster(c,track)) continue;
+ sector = (c->GetDetector()%18);
+ if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
+ //continue;
+ }
+ Double_t r[3]={c->GetX(),c->GetY(),c->GetZ()};
+ Double_t cov[3]={0.01,0.,0.01}; //TODO: correct error parametrisation
+ if (!track->PropagateTo(r[0])) {
+ isOK=kFALSE;
+ }
+ if ( !((static_cast<AliExternalTrackParam*>(track)->Update(&r[1],cov)))) isOK=kFALSE;
+ }
+ if (!isOK) { delete track; return 0;}
+ track->AddCovariance(covar);
+ //
+ //
+ //
+ for (Int_t i=imax; i>=imin; i--){
+ AliTPCclusterMI *c=track->GetClusterPointer(i);
+ if (!c) continue;
+ //if (RejectCluster(c,track)) continue;
+ sector = (c->GetDetector()%18);
+ if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
+ //continue;
+ }
+ Double_t r[3]={c->GetX(),c->GetY(),c->GetZ()};
+ Double_t cov[3]={0.01,0.,0.01}; //TODO: correct error parametrisation
+ if (!track->PropagateTo(r[0])) {
+ isOK=kFALSE;
+ }
+ if ( !((static_cast<AliExternalTrackParam*>(track)->Update(&r[1],cov)))) isOK=kFALSE;
+ }
+ //if (!isOK) { delete track; return 0;}
+ paramIn = *track;
+ track->AddCovariance(covar);
+ //
+ //
+ for (Int_t i=imin; i<=imax; i++){
+ AliTPCclusterMI *c=track->GetClusterPointer(i);
+ if (!c) continue;
+ sector = (c->GetDetector()%18);
+ if (!track->Rotate(TMath::DegToRad()*(sector%18*20.+10.)-track->GetAlpha())) {
+ //continue;
+ }
+ ncl++;
+ //if (RejectCluster(c,track)) continue;
+ Double_t r[3]={c->GetX(),c->GetY(),c->GetZ()};
+ Double_t cov[3]={0.01,0.,0.01}; //TODO: correct error parametrisation
+ if (!track->PropagateTo(r[0])) {
+ isOK=kFALSE;
+ }
+ if ( !((static_cast<AliExternalTrackParam*>(track)->Update(&r[1],cov)))) isOK=kFALSE;
+ }
+ //if (!isOK) { delete track; return 0;}
+ paramOut=*track;
+ //
+ //
+ //
+ if (parin) (*parin)=paramIn;
+ if (parout) (*parout)=paramOut;
+ return ncl;
+}
+
+
+
+Bool_t AliTPCseed::RefitTrack(AliTPCseed* /*seed*/, Bool_t /*out*/){
+ //
+ //
+ //
+ return kFALSE;
+}
+
+
+
+
+
+
+void AliTPCseed::GetError(AliTPCclusterMI* cluster, AliExternalTrackParam * param,
+ Double_t& erry, Double_t &errz)
+{
+ //
+ // Get cluster error at given position
+ //
+ AliTPCClusterParam *clusterParam = AliTPCcalibDB::Instance()->GetClusterParam();
+ Double_t tany,tanz;
+ Double_t snp1=param->GetSnp();
+ tany=snp1/TMath::Sqrt((1.-snp1)*(1.+snp1));
+ //
+ Double_t tgl1=param->GetTgl();
+ tanz=tgl1/TMath::Sqrt((1.-snp1)*(1.+snp1));
+ //
+ Int_t padSize = 0; // short pads
+ if (cluster->GetDetector() >= 36) {
+ padSize = 1; // medium pads
+ if (cluster->GetRow() > 63) padSize = 2; // long pads
+ }
+
+ erry = clusterParam->GetError0Par( 0, padSize, (250.0 - TMath::Abs(cluster->GetZ())), TMath::Abs(tany) );
+ errz = clusterParam->GetError0Par( 1, padSize, (250.0 - TMath::Abs(cluster->GetZ())), TMath::Abs(tanz) );
+}
+
+
+void AliTPCseed::GetShape(AliTPCclusterMI* cluster, AliExternalTrackParam * param,
+ Double_t& rmsy, Double_t &rmsz)
+{
+ //
+ // Get cluster error at given position
+ //
+ AliTPCClusterParam *clusterParam = AliTPCcalibDB::Instance()->GetClusterParam();
+ Double_t tany,tanz;
+ Double_t snp1=param->GetSnp();
+ tany=snp1/TMath::Sqrt((1.-snp1)*(1.+snp1));
+ //
+ Double_t tgl1=param->GetTgl();
+ tanz=tgl1/TMath::Sqrt((1.-snp1)*(1.+snp1));
+ //
+ Int_t padSize = 0; // short pads
+ if (cluster->GetDetector() >= 36) {
+ padSize = 1; // medium pads
+ if (cluster->GetRow() > 63) padSize = 2; // long pads
+ }
+
+ rmsy = clusterParam->GetRMSQ( 0, padSize, (250.0 - TMath::Abs(cluster->GetZ())), TMath::Abs(tany), TMath::Abs(cluster->GetMax()) );
+ rmsz = clusterParam->GetRMSQ( 1, padSize, (250.0 - TMath::Abs(cluster->GetZ())), TMath::Abs(tanz) ,TMath::Abs(cluster->GetMax()));
+}
+
+
+
+Double_t AliTPCseed::GetQCorrGeom(Float_t ty, Float_t tz){
+ //Geoetrical
+ //ty - tangent in local y direction
+ //tz - tangent
+ //
+ Float_t norm=TMath::Sqrt(1+ty*ty+tz*tz);
+ return norm;
+}
+
+Double_t AliTPCseed::GetQCorrShape(Int_t ipad, Int_t type,Float_t z, Float_t ty, Float_t tz, Float_t /*q*/, Float_t /*thr*/){
+ //
+ // Q normalization
+ //
+ // return value = Q Normalization factor
+ // Normalization - 1 - shape factor part for full drift
+ // 1 - electron attachment for 0 drift
+
+ // Input parameters:
+ //
+ // ipad - 0 short pad
+ // 1 medium pad
+ // 2 long pad
+ //
+ // type - 0 qmax
+ // - 1 qtot
+ //
+ //z - z position (-250,250 cm)
+ //ty - tangent in local y direction
+ //tz - tangent
+ //
+
+ AliTPCClusterParam * paramCl = AliTPCcalibDB::Instance()->GetClusterParam();
+ AliTPCParam * paramTPC = AliTPCcalibDB::Instance()->GetParameters();
+
+ if (!paramCl) return 1;
+ //
+ Double_t dr = 250.-TMath::Abs(z);
+ Double_t sy = paramCl->GetRMS0( 0,ipad, dr, TMath::Abs(ty));
+ Double_t sy0= paramCl->GetRMS0(0,ipad, 250, 0);
+ Double_t sz = paramCl->GetRMS0( 1,ipad, dr, TMath::Abs(tz));
+ Double_t sz0= paramCl->GetRMS0(1,ipad, 250, 0);
+
+ Double_t sfactorMax = TMath::Sqrt(sy0*sz0/(sy*sz));
+
+
+ Double_t dt = 1000000*(dr/paramTPC->GetDriftV()); //time in microsecond
+ Double_t attProb = TMath::Exp(-paramTPC->GetAttCoef()*paramTPC->GetOxyCont()*dt);
+ //
+ //
+ if (type==0) return sfactorMax*attProb;
+
+ return attProb;
+
+
+}
+