#include "AliMathBase.h"
#include "AliTRDseed.h"
-#include "AliTRDcalibDB.h"
#include "AliTRDcluster.h"
#include "AliTRDtracker.h"
+#include "AliTRDtrackerV1.h"
ClassImp(AliTRDseed)
fY[i] = 0; // y position
fZ[i] = 0; // z position
fIndexes[i] = 0; // Indexes
- fClusters[i] = 0x0; // Clusters
+ fClusters[i] = NULL; // Clusters
fUsable[i] = 0; // Indication - usable cluster
}
}
//_____________________________________________________________________________
-void AliTRDseed::Copy(TObject &o) const
+AliTRDseed &AliTRDseed::operator=(const AliTRDseed &s)
{
//
- // Copy function
+ // Assignment operator
//
- AliTRDseed &seed = (AliTRDseed &)o;
- seed.fTilt = fTilt;
+ if (this != &s) {
+ ((AliTRDseed &) s).Copy(*this);
+ }
+
+ return *this;
+
+}
+
+//_____________________________________________________________________________
+void AliTRDseed::Copy(TObject &o) const
+{
+ //printf("AliTRDseed::Copy()\n");
+
+ AliTRDseed &seed = (AliTRDseed &)o;
+
+ seed.fTilt = fTilt;
seed.fPadLength = fPadLength;
seed.fX0 = fX0;
seed.fSigmaY = fSigmaY;
seed.fCC = fCC;
seed.fChi2 = fChi2;
seed.fChi2Z = fChi2Z;
-
- for (Int_t i = 0; i < knTimebins; i++) {
+ for (Int_t i = 0; i < knTimebins; i++) {
seed.fX[i] = fX[i];
seed.fY[i] = fY[i];
seed.fZ[i] = fZ[i];
fY[i] = 0; // Y position
fZ[i] = 0; // Z position
fIndexes[i] = 0; // Indexes
- fClusters[i] = 0x0; // Clusters
+ fClusters[i] = NULL; // Clusters
fUsable[i] = kFALSE;
}
// Cook 2 labels for seed
//
- AliTRDcalibDB *cal = AliTRDcalibDB::Instance();
- Int_t nTimeBins = cal->GetNumberOfTimeBins();
-
Int_t labels[200];
Int_t out[200];
Int_t nlab = 0;
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
if (!fClusters[i]) continue;
for (Int_t ilab = 0; ilab < 3; ilab++) {
if (fClusters[i]->GetLabel(ilab) >= 0) {
// Use clusters
//
- AliTRDcalibDB *cal = AliTRDcalibDB::Instance();
- Int_t nTimeBins = cal->GetNumberOfTimeBins();
-
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
if (!fClusters[i]) continue;
if (!(fClusters[i]->IsUsed())) fClusters[i]->Use();
}
// Update the seed.
//
+
+
+ // linear fit on the y direction with respect to the reference direction.
+ // The residuals for each x (x = xc - x0) are deduced from:
+ // dy = y - yt (1)
+ // the tilting correction is written :
+ // y = yc + h*(zc-zt) (2)
+ // yt = y0+dy/dx*x (3)
+ // zt = z0+dz/dx*x (4)
+ // from (1),(2),(3) and (4)
+ // dy = yc - y0 - (dy/dx + h*dz/dx)*x + h*(zc-z0)
+ // the last term introduces the correction on y direction due to tilting pads. There are 2 ways to account for this:
+ // 1. use tilting correction for calculating the y
+ // 2. neglect tilting correction here and account for it in the error parametrization of the tracklet.
+
const Float_t kRatio = 0.8;
const Int_t kClmin = 5;
const Float_t kmaxtan = 2;
- AliTRDcalibDB *cal = AliTRDcalibDB::Instance();
- Int_t nTimeBins = cal->GetNumberOfTimeBins();
-
if (TMath::Abs(fYref[1]) > kmaxtan){
//printf("Exit: Abs(fYref[1]) = %3.3f, kmaxtan = %3.3f\n", TMath::Abs(fYref[1]), kmaxtan);
return; // Track inclined too much
// Get 1 and second max probable coodinates in z
Int_t zouts[2*knTimebins];
Float_t allowedz[knTimebins]; // Allowed z for given time bin
+ memset(allowedz, 0, knTimebins*sizeof(Float_t));
Float_t yres[knTimebins]; // Residuals from reference
- Float_t anglecor = fTilt * fZref[1]; // Correction to the angle
+ //Float_t anglecor = fTilt * fZref[1]; // Correction to the angle
fN = 0;
fN2 = 0;
- for (Int_t i = 0; i < nTimeBins; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
yres[i] = 10000.0;
if (!fClusters[i]) continue;
- yres[i] = fY[i] - fYref[0] - (fYref[1] + anglecor) * fX[i]; // Residual y
+ if(!fClusters[i]->IsInChamber()) continue;
+ // Residual y
+ //yres[i] = fY[i] - fYref[0] - (fYref[1] + anglecor) * fX[i] + fTilt*(fZ[i] - fZref[0]);
+ yres[i] = fY[i] - fTilt*(fZ[i] - (fZref[0] - fX[i]*fZref[1]));
zints[fN] = Int_t(fZ[i]);
fN++;
}
//printf("Exit fN < kClmin: fN = %d\n", fN);
return;
}
- Int_t nz = AliTRDtracker::Freq(fN,zints,zouts,kFALSE);
+ Int_t nz = AliTRDtracker::Freq(fN, zints, zouts, kFALSE);
fZProb = zouts[0];
if (nz <= 1) zouts[3] = 0;
if (zouts[1] + zouts[3] < kClmin) {
}
// Z distance bigger than pad - length
- if (TMath::Abs(zouts[0]-zouts[2]) > 12.0) {
- zouts[3]=0;
- }
+ if (TMath::Abs(zouts[0]-zouts[2]) > 12.0) zouts[3] = 0;
Int_t breaktime = -1;
Bool_t mbefore = kFALSE;
//
// Find the break time allowing one chage on pad-rows
- // with maximal numebr of accepted clusters
+ // with maximal number of accepted clusters
//
fNChange = 1;
- for (Int_t i = 0; i < nTimeBins; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
cumul[i][0] = counts[0];
cumul[i][1] = counts[1];
if (TMath::Abs(fZ[i]-zouts[0]) < 2) counts[0]++;
if (TMath::Abs(fZ[i]-zouts[2]) < 2) counts[1]++;
}
Int_t maxcount = 0;
- for (Int_t i = 0; i < nTimeBins; i++) {
- Int_t after = cumul[nTimeBins][0] - cumul[i][0];
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
+ Int_t after = cumul[AliTRDtrackerV1::GetNTimeBins()][0] - cumul[i][0];
Int_t before = cumul[i][1];
if (after + before > maxcount) {
maxcount = after + before;
breaktime = i;
mbefore = kFALSE;
}
- after = cumul[nTimeBins-1][1] - cumul[i][1];
+ after = cumul[AliTRDtrackerV1::GetNTimeBins()-1][1] - cumul[i][1];
before = cumul[i][0];
if (after + before > maxcount) {
maxcount = after + before;
}
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
if (i > breaktime) allowedz[i] = mbefore ? zouts[2] : zouts[0];
if (i <= breaktime) allowedz[i] = (!mbefore) ? zouts[2] : zouts[0];
}
- if (((allowedz[0] > allowedz[nTimeBins]) && (fZref[1] < 0)) ||
- ((allowedz[0] < allowedz[nTimeBins]) && (fZref[1] > 0))) {
+ if (((allowedz[0] > allowedz[AliTRDtrackerV1::GetNTimeBins()]) && (fZref[1] < 0)) ||
+ ((allowedz[0] < allowedz[AliTRDtrackerV1::GetNTimeBins()]) && (fZref[1] > 0))) {
//
// Tracklet z-direction not in correspondance with track z direction
//
fNChange = 0;
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
allowedz[i] = zouts[0]; // Only longest taken
}
}
//
// Cross pad -row tracklet - take the step change into account
//
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
if (!fClusters[i]) continue;
+ if(!fClusters[i]->IsInChamber()) continue;
if (TMath::Abs(fZ[i] - allowedz[i]) > 2) continue;
- yres[i] = fY[i] - fYref[0] - (fYref[1] + anglecor) * fX[i]; // Residual y
- if (TMath::Abs(fZ[i] - fZProb) > 2) {
- if (fZ[i] > fZProb) yres[i] += fTilt * fPadLength;
- if (fZ[i] < fZProb) yres[i] -= fTilt * fPadLength;
- }
+ // Residual y
+ //yres[i] = fY[i] - fYref[0] - (fYref[1] + anglecor) * fX[i] /*+ fTilt*(fZ[i] - fZref[0])*/;
+ yres[i] = fY[i] - fTilt*(fZ[i] - (fZref[0] - fX[i]*fZref[1]));
+/* if (TMath::Abs(fZ[i] - fZProb) > 2) {
+ if (fZ[i] > fZProb) yres[i] += fTilt * fPadLength;
+ if (fZ[i] < fZProb) yres[i] -= fTilt * fPadLength;
+ }*/
}
}
Double_t yres2[knTimebins];
Double_t mean;
Double_t sigma;
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
if (!fClusters[i]) continue;
+ if(!fClusters[i]->IsInChamber()) continue;
if (TMath::Abs(fZ[i] - allowedz[i]) > 2) continue;
yres2[fN2] = yres[i];
fN2++;
fMeanz = 0;
fMPads = 0;
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
fUsable[i] = kFALSE;
if (!fClusters[i]) continue;
- if (TMath::Abs(fZ[i] - allowedz[i]) > 2) continue;
- if (TMath::Abs(yres[i] - mean) > 4.0 * sigma) continue;
+ if (!fClusters[i]->IsInChamber()) continue;
+ if (TMath::Abs(fZ[i] - allowedz[i]) > 2){fClusters[i] = NULL; continue;}
+ if (TMath::Abs(yres[i] - mean) > 4.0 * sigma){fClusters[i] = NULL; continue;}
fUsable[i] = kTRUE;
fN2++;
fMPads += fClusters[i]->GetNPads();
if (fClusters[i]->GetNPads() > 4) weight = 0.5;
if (fClusters[i]->GetNPads() > 5) weight = 0.2;
+
Double_t x = fX[i];
+ //printf("x = %7.3f dy = %7.3f fit %7.3f\n", x, yres[i], fY[i]-yres[i]);
+
sumw += weight;
sumwx += x * weight;
sumwx2 += x*x * weight;
fYfitR[1] = (sumw * sumwxy - sumwx * sumwy) / det;
fSigmaY2 = 0;
- for (Int_t i = 0; i < nTimeBins+1; i++) {
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins()+1; i++) {
if (!fUsable[i]) continue;
Float_t delta = yres[i] - fYfitR[0] - fYfitR[1] * fX[i];
fSigmaY2 += delta*delta;
}
fSigmaY2 = TMath::Sqrt(fSigmaY2 / Float_t(fN2-2));
+ // TEMPORARY UNTIL covariance properly calculated
+ fSigmaY2 = TMath::Max(fSigmaY2, Float_t(.1));
fZfitR[0] = (sumwx2 * sumwz - sumwx * sumwxz) / det;
fZfitR[1] = (sumw * sumwxz - sumwx * sumwz) / det;
fZfit[0] = (sumwx2 * sumwz - sumwx * sumwxz) / det;
fZfit[1] = (sumw * sumwxz - sumwx * sumwz) / det;
- fYfitR[0] += fYref[0] + correction;
- fYfitR[1] += fYref[1];
+// fYfitR[0] += fYref[0] + correction;
+// fYfitR[1] += fYref[1];
fYfit[0] = fYfitR[0];
- fYfit[1] = fYfitR[1];
-
+ fYfit[1] = -fYfitR[1];
+
+ //printf("y0 = %7.3f tgy = %7.3f z0 = %7.3f tgz = %7.3f \n", fYfitR[0], fYfitR[1], fZfitR[0], fZfitR[1]);
+
UpdateUsed();
}
// Update used seed
//
- AliTRDcalibDB *cal = AliTRDcalibDB::Instance();
- Int_t nTimeBins = cal->GetNumberOfTimeBins();
-
fNUsed = 0;
- for (Int_t i = 0; i < nTimeBins; i++) {
- if (!fClusters[i]) {
- continue;
- }
- if ((fClusters[i]->IsUsed())) {
- fNUsed++;
- }
+ for (Int_t i = 0; i < AliTRDtrackerV1::GetNTimeBins(); i++) {
+ if (!fClusters[i]) continue;
+ if(!fUsable[i]) continue;
+ if ((fClusters[i]->IsUsed())) fNUsed++;
}
}
TLinearFitter fitterT2(4,"hyp4");
fitterT2.StoreData(kTRUE);
- AliTRDcalibDB *cal = AliTRDcalibDB::Instance();
- Int_t nTimeBins = cal->GetNumberOfTimeBins();
-
Float_t xref2 = (cseed[2].fX0 + cseed[3].fX0) * 0.5; // Reference x0 for z
Int_t npointsT = 0;
if (!cseed[iLayer].IsOK()) continue;
Double_t tilt = cseed[iLayer].fTilt;
- for (Int_t itime = 0; itime < nTimeBins+1; itime++) {
+ for (Int_t itime = 0; itime < AliTRDtrackerV1::GetNTimeBins()+1; itime++) {
if (!cseed[iLayer].fUsable[itime]) continue;
// x relative to the midle chamber
if (-params[2]*params[0] + params[1]*params[1] + 1 > 0) {
Double_t rm1 = params[0] / TMath::Sqrt(-params[2]*params[0] + params[1]*params[1] + 1);
if (1.0/(rm1*rm1) - (x-x0) * (x-x0) > 0.0) {
- Double_t res = (x - x0) / TMath::Sqrt(1.0 / (rm1*rm1) - (x-x0)*(x-x0));
+ Double_t res = (x - x0) / TMath::Sqrt((1./rm1-(x-x0))*(1./rm1+(x-x0)));
if (params[0] < 0) res *= -1.0;
dy = res;
}