ClassImp(AliTRDresolution)
-Float_t AliTRDresolution::fPtThreshold = 1.; // GeV/c
UChar_t const AliTRDresolution::fgNproj[kNviews] = {
2, 2, 5, 5, 5,
2, 5, 11, 11, 11
,"TRDout2MC"
,"TRD2MC"
};
+// Configure segmentation for y resolution/residuals
+UChar_t AliTRDresolution::fgSegmentLevel = 0;
+Int_t const AliTRDresolution::fgkNresYsegm[3] = {
+ AliTRDgeometry::kNsector
+ ,AliTRDgeometry::kNsector*AliTRDgeometry::kNstack
+ ,AliTRDgeometry::kNdet
+};
+Char_t const *AliTRDresolution::fgkResYsegmName[3] = {
+ "Sector", "Stack", "Detector"};
+
UChar_t const AliTRDresolution::fgNcomp[kNprojs] = {
1, 1, //2,
- AliTRDresolution::kNyresSlices, 1, //2,
- AliTRDresolution::kNyresSlices, 1, 1, 1, 1, //5,
- AliTRDresolution::kNyresSlices, 1, 1, 1, 1, //5,
- AliTRDresolution::kNyresSlices, 1, 1, 1, 1, //5,
+ AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, //2,
+ 2*AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, 2, 2, 1, //5,
+ 2*AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, 2, 2, 1, //5,
+ 2*AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, 2, 2, 1, //5,
// MC
- AliTRDresolution::kNyresSlices, 1, //2,
- AliTRDresolution::kNyresSlices, 1, 1, 1, 1, //5,
- AliTRDresolution::kNyresSlices, 1, 1, 1, 1, 1, 1, 1, 11, 11, 11, //11
- AliTRDresolution::kNyresSlices, 1, 1, 1, 1, 1, 1, 1, 11, 11, 11, //11
- 6*AliTRDresolution::kNyresSlices, 6, 6, 6, 6, 6, 6, 6, 6*11, 6*11, 6*11 //11
+ AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, //2,
+ AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, 2, 2, 1, //5,
+ AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, 2, 2, 1, 1, 1, 1, 11, 11, 11, //11
+ AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 2, 2, 2, 1, 1, 1, 1, 11, 11, 11, //11
+ 6*AliTRDresolution::fgkNresYsegm[fgSegmentLevel], 6*2, 6*2, 6*2, 6, 6, 6, 6, 6*11, 6*11, 6*11 //11
};
Char_t const *AliTRDresolution::fgAxTitle[kNprojs][4] = {
// Charge
,{"dI/Impv", "x/x_{0}", "#delta I/I_{mpv}", "x[cm]"}
// Clusters to Kalman
,{"Cluster2Track residuals", "tg(#phi)", "y [#mum]", "#sigma_{y} [#mum]"}
- ,{"Cluster2Track pulls", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"Cluster2Track YZ pulls", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
// TRD tracklet to Kalman fit
,{"Tracklet2Track Y residuals", "tg(#phi)", "y [#mum]", "#sigma_{y} [#mum]"}
- ,{"Tracklet2Track Y pulls", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"Tracklet2Track YZ pulls", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
,{"Tracklet2Track Z residuals", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
,{"Tracklet2Track Z pulls", "tg(#theta)", "z", "#sigma_{z}"}
,{"Tracklet2Track Phi residuals", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
// TRDin 2 first TRD tracklet
,{"Tracklet2Track Y residuals @ TRDin", "tg(#phi)", "y [#mum]", "#sigma_{y} [#mum]"}
- ,{"Tracklet2Track Y pulls @ TRDin", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"Tracklet2Track YZ pulls @ TRDin", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
,{"Tracklet2Track Z residuals @ TRDin", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
,{"Tracklet2Track Z pulls @ TRDin", "tg(#theta)", "z", "#sigma_{z}"}
,{"Tracklet2Track Phi residuals @ TRDin", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
// TRDout 2 first TRD tracklet
,{"Tracklet2Track Y residuals @ TRDout", "tg(#phi)", "y [#mum]", "#sigma_{y} [#mum]"}
- ,{"Tracklet2Track Y pulls @ TRDout", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"Tracklet2Track YZ pulls @ TRDout", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
,{"Tracklet2Track Z residuals @ TRDout", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
,{"Tracklet2Track Z pulls @ TRDout", "tg(#theta)", "z", "#sigma_{z}"}
,{"Tracklet2Track Phi residuals @ TRDout", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
// MC cluster
,{"MC Cluster Y resolution", "tg(#phi)", "y [#mum]", "#sigma_{y} [#mum]"}
- ,{"MC Cluster Y pulls", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"MC Cluster YZ pulls", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
// MC tracklet
,{"MC Tracklet Y resolution", "tg(#phi)", "y [#mum]", "#sigma_{y}[#mum]"}
- ,{"MC Tracklet Y pulls", "tg(#phi)", "y", "#sigma_{y}"}
- ,{"MC Tracklet Cross Z resolution", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
- ,{"MC Tracklet Cross Z pulls", "tg(#theta)", "z", "#sigma_{z}"}
+ ,{"MC Tracklet YZ pulls", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
+ ,{"MC Tracklet Z resolution", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
+ ,{"MC Tracklet Z pulls", "tg(#theta)", "z", "#sigma_{z}"}
,{"MC Tracklet Phi resolution", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
// MC track TRDin
,{"MC Y resolution @ TRDin", "tg(#phi)", "y [#mum]", "#sigma_{y}[#mum]"}
- ,{"MC Y pulls @ TRDin", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"MC YZ pulls @ TRDin", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
,{"MC Z resolution @ TRDin", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
,{"MC Z pulls @ TRDin", "tg(#theta)", "z", "#sigma_{z}"}
,{"MC #Phi resolution @ TRDin", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
,{"MC P resolution @ TRDin", "p^{MC} [GeV/c]", "(p^{REC}-p^{MC})/p^{MC} [%]", "MC: #sigma^{TPC}(#Deltap/p^{MC}) [%]"}
// MC track TRDout
,{"MC Y resolution @ TRDout", "tg(#phi)", "y [#mum]", "#sigma_{y}[#mum]"}
- ,{"MC Y pulls @ TRDout", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"MC YZ pulls @ TRDout", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
,{"MC Z resolution @ TRDout", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
,{"MC Z pulls @ TRDout", "tg(#theta)", "z", "#sigma_{z}"}
,{"MC #Phi resolution @ TRDout", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
,{"MC P resolution @ TRDout", "p^{MC} [GeV/c]", "(p^{REC}-p^{MC})/p^{MC} [%]", "MC: #sigma^{TPC}(#Deltap/p^{MC}) [%]"}
// MC track in TRD
,{"MC Track Y resolution", "tg(#phi)", "y [#mum]", "#sigma_{y} [#mum]"}
- ,{"MC Track Y pulls", "tg(#phi)", "y", "#sigma_{y}"}
+ ,{"MC Track YZ pulls", AliTRDresolution::fgkResYsegmName[fgSegmentLevel], "y / z", "#sigma_{y}"}
,{"MC Track Z resolution", "tg(#theta)", "z [#mum]", "#sigma_{z} [#mum]"}
,{"MC Track Z pulls", "tg(#theta)", "z", "#sigma_{z}"}
,{"MC Track #Phi resolution", "tg(#phi)", "#phi [mrad]", "#sigma_{#phi} [mrad]"}
,fStatus(0)
,fIdxPlot(0)
,fIdxFrame(0)
+ ,fPtThreshold(1.)
,fReconstructor(NULL)
,fGeo(NULL)
,fDBPDG(NULL)
,fStatus(0)
,fIdxPlot(0)
,fIdxFrame(0)
+ ,fPtThreshold(1.)
,fReconstructor(NULL)
,fGeo(NULL)
,fDBPDG(NULL)
PostData(kTrkltToMC, fMCtrklt);
}
+//________________________________________________________
+Bool_t AliTRDresolution::Pulls(Double_t dyz[2], Double_t cov[3], Double_t tilt)
+{
+// Helper function to calculate pulls in the yz plane
+// using proper tilt rotation
+// Uses functionality defined by AliTRDseedV1.
+
+ Double_t t2(tilt*tilt);
+
+ // rotate along pad
+ Double_t cc[3];
+ cc[0] = cov[0] - 2.*tilt*cov[1] + t2*cov[2];
+ cc[1] = cov[1]*(1.-t2) + tilt*(cov[0] - cov[2]);
+ cc[2] = t2*cov[0] + 2.*tilt*cov[1] + cov[2];
+ // do sqrt
+ Double_t sqr[3]={0., 0., 0.};
+ if(AliTRDseedV1::GetCovSqrt(cc, sqr)) return kFALSE;
+ Double_t invsqr[3]={0., 0., 0.};
+ if(AliTRDseedV1::GetCovInv(sqr, invsqr)<1.e-40) return kFALSE;
+ Double_t tmp(dyz[0]);
+ dyz[0] = invsqr[0]*tmp + invsqr[1]*dyz[1];
+ dyz[1] = invsqr[1]*tmp + invsqr[2]*dyz[1];
+ return kTRUE;
+}
+
//________________________________________________________
TH1* AliTRDresolution::PlotCharge(const AliTRDtrackV1 *track)
{
}
ULong_t status = fkESD ? fkESD->GetStatus():0;
- Int_t sec(-1), stk(-1), det(-1);
- Double_t covR[7], cov[3], cc[3];
- Float_t pt, x0, y0, z0
- , dy[3]={0., 0., 0.}, dz[3]={0., 0., 0.}, dydx, dzdx;
- AliTRDseedV1 *fTracklet(NULL);
+ Int_t sgm[3];
+ Double_t covR[7], cov[3], dy[2], dz[2];
+ Float_t pt, x0, y0, z0, dydx, dzdx;
+ AliTRDseedV1 *fTracklet(NULL); TObjArray *clInfoArr(NULL);
for(Int_t ily=0; ily<AliTRDgeometry::kNlayer; ily++){
if(!(fTracklet = fkTrack->GetTracklet(ily))) continue;
if(!fTracklet->IsOK()) continue;
x0 = fTracklet->GetX0();
pt = fTracklet->GetPt();
- det = fTracklet->GetDetector();
- sec = AliTRDgeometry::GetSector(det);
- stk = sec * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(det);
+ sgm[2] = fTracklet->GetDetector();
+ sgm[0] = AliTRDgeometry::GetSector(sgm[2]);
+ sgm[1] = sgm[0] * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(sgm[2]);
+
// retrive the track angle with the chamber
y0 = fTracklet->GetYref(0);
z0 = fTracklet->GetZref(0);
Float_t zt = z0 - dx*dzdx;
dy[0] = yc-yt; dz[0]= zc-zt;
- // calculate residuals using tilt rotation
+ // rotate along pad
dy[1] = cost*(dy[0] - dz[0]*tilt);
dz[1] = cost*(dz[0] + dy[0]*tilt);
- if(pt>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx, dy[1], sec);
-
- // calculate covariance
- cov[0] = c->GetSigmaY2();
- cov[1] = c->GetSigmaYZ();
- cov[2] = c->GetSigmaZ2();
- // do rotation
- Double_t sy2(cov[0]), sz2(cov[2]);
+ if(pt>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx, dy[1], sgm[fgSegmentLevel]);
+
+ // tilt rotation of covariance for clusters
+ Double_t sy2(c->GetSigmaY2()), sz2(c->GetSigmaZ2());
cov[0] = (sy2+t2*sz2)*corr;
cov[1] = tilt*(sz2 - sy2)*corr;
cov[2] = (t2*sy2+sz2)*corr;
- // do sum
+ // sum with track covariance
cov[0]+=covR[0]; cov[1]+=covR[1]; cov[2]+=covR[2];
- // covariance in the rotated frame
- cc[0] = cov[0] - 2.*tilt*cov[1] + t2*cov[2];
- cc[1] = tilt*cov[0] + cov[1]*(1-t2) - tilt*cov[2];
- cc[2] = t2*cov[0] + 2.*tilt*cov[1] + cov[2];
-// // do sqrt
-// Double_t sqr[3]; AliTRDseedV1::GetCovSqrt(cc, sqr);
-// dy[2] = sqr[0]*dy[1] + sqr[1]*dz[1];
-// dz[2] = sqr[1]*dy[1] + sqr[2]*dz[1];
-// if(DebugLevel()>=1){
-// (*DebugStream()) << "ClusterPull"
-// <<"dy=" << dy[2]
-// <<"dz=" << dz[2]
-// <<"c0=" << cc[0]
-// <<"c1=" << cc[1]
-// <<"c2=" << cc[2]
-// <<"d0=" << sqr[0]
-// <<"d1=" << sqr[1]
-// <<"d2=" << sqr[2]
-// <<"tilt="<< tilt
-// << "\n";
-// }
-
- ((TH2I*)arr->At(1))->Fill(dydx, dy[2]);
+ Double_t dyz[2]= {dy[1], dz[1]};
+ Pulls(dyz, cov, tilt);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dyz[0], dyz[1]);
- if(DebugLevel()>=2){
- // Get z-position with respect to anode wire
- Int_t istk = fGeo->GetStack(c->GetDetector());
- AliTRDpadPlane *pp = fGeo->GetPadPlane(ily, istk);
- Float_t row0 = pp->GetRow0();
- Float_t d = row0 - zt + pp->GetAnodeWireOffset();
- d -= ((Int_t)(2 * d)) / 2.0;
- if (d > 0.25) d = 0.5 - d;
-
- AliTRDclusterInfo *clInfo = new AliTRDclusterInfo;
- fCl->Add(clInfo);
- clInfo->SetCluster(c);
- Float_t covF[] = {cov[0], cov[1], cov[2]};
- clInfo->SetGlobalPosition(yt, zt, dydx, dzdx, covF);
- clInfo->SetResolution(dy[1]);
- clInfo->SetAnisochronity(d);
- clInfo->SetDriftLength(dx);
- clInfo->SetTilt(tilt);
- (*DebugStream()) << "ClusterREC"
- <<"status=" << status
- <<"clInfo.=" << clInfo
- << "\n";
+ // Get z-position with respect to anode wire
+ Int_t istk = fGeo->GetStack(c->GetDetector());
+ AliTRDpadPlane *pp = fGeo->GetPadPlane(ily, istk);
+ Float_t row0 = pp->GetRow0();
+ Float_t d = row0 - zt + pp->GetAnodeWireOffset();
+ d -= ((Int_t)(2 * d)) / 2.0;
+ if (d > 0.25) d = 0.5 - d;
+
+ AliTRDclusterInfo *clInfo = new AliTRDclusterInfo;
+ fCl->Add(clInfo);
+ clInfo->SetCluster(c);
+ Float_t covF[] = {cov[0], cov[1], cov[2]};
+ clInfo->SetGlobalPosition(yt, zt, dydx, dzdx, covF);
+ clInfo->SetResolution(dy[1]);
+ clInfo->SetAnisochronity(d);
+ clInfo->SetDriftLength(dx);
+ clInfo->SetTilt(tilt);
+ if(DebugLevel()>=1){
+ if(!clInfoArr) clInfoArr=new TObjArray(AliTRDseedV1::kNclusters);
+ clInfoArr->Add(clInfo);
}
}
+ if(DebugLevel()>=1 && clInfoArr){
+ (*DebugStream()) << "cluster"
+ <<"status=" << status
+ <<"clInfo.=" << clInfoArr
+ << "\n";
+ }
}
- return (TH2I*)arr->At(0);
+ return (TH3S*)arr->At(0);
}
return NULL;
}
- Int_t sec(-1), stk(-1), det(-1);
+ Int_t sgm[3];
Double_t cov[3], covR[7]/*, sqr[3], inv[3]*/;
- Double_t pt, x, dx, dy[2], dz[2];
+ Double_t pt, phi, tht, x, dx, dy[2], dz[2];
AliTRDseedV1 *fTracklet(NULL);
- for(Int_t il=AliTRDgeometry::kNlayer; il--;){
+ for(Int_t il(0); il<AliTRDgeometry::kNlayer; il++){
if(!(fTracklet = fkTrack->GetTracklet(il))) continue;
if(!fTracklet->IsOK()) continue;
- det = fTracklet->GetDetector();
- sec = AliTRDgeometry::GetSector(det);
- stk = sec * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(det);
+ sgm[2] = fTracklet->GetDetector();
+ sgm[0] = AliTRDgeometry::GetSector(sgm[2]);
+ sgm[1] = sgm[0] * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(sgm[2]);
x = fTracklet->GetX();
dx = fTracklet->GetX0() - x;
pt = fTracklet->GetPt();
+ phi = fTracklet->GetYref(1);
+ tht = fTracklet->GetZref(1);
// compute dy and dz
dy[0]= fTracklet->GetYref(0)-dx*fTracklet->GetYref(1) - fTracklet->GetY();
dz[0]= fTracklet->GetZref(0)-dx*fTracklet->GetZref(1) - fTracklet->GetZ();
// calculate residuals using tilt rotation
dy[1]= cost*(dy[0] - dz[0]*tilt);
dz[1]= cost*(dz[0] + dy[0]*tilt);
- ((TH3S*)arr->At(0))->Fill(fTracklet->GetYref(1), dy[1], sec);
- if(rc) ((TH2I*)arr->At(2))->Fill(fTracklet->GetZref(1), dz[1]);
-
- if(DebugLevel()>=1){
- (*DebugStream()) << "trackletRes"
- << "dy0=" << dy[0]
- << "dz0=" << dz[0]
- << "dy1=" << dy[1]
- << "dz1=" << dz[1]
- << "tilt=" << tilt
- << "rc=" << rc
- << "ly=" << il
- << "\n";
- }
+ ((TH3S*)arr->At(0))->Fill(phi, dy[1], sgm[fgSegmentLevel]+rc*fgkNresYsegm[fgSegmentLevel]);
+ ((TH3S*)arr->At(2))->Fill(tht, dz[1], rc);
// compute covariance matrix
fTracklet->GetCovAt(x, cov);
fTracklet->GetCovRef(covR);
cov[0] += covR[0]; cov[1] += covR[1]; cov[2] += covR[2];
-/* // Correct PULL calculation by considering off
- // diagonal elements in the covariance matrix
- // compute square root matrix
- if(AliTRDseedV1::GetCovInv(cov, inv)==0.) continue;
- if(AliTRDseedV1::GetCovSqrt(inv, sqr)<0.) continue;
- Double_t y = sqr[0]*dy+sqr[1]*dz;
- Double_t z = sqr[1]*dy+sqr[2]*dz;
- ((TH3*)h)->Fill(y, z, fTracklet->GetYref(1));*/
-
- ((TH2I*)arr->At(1))->Fill(fTracklet->GetYref(1), dy[0]/TMath::Sqrt(cov[0]));
- if(fTracklet->IsRowCross()) ((TH2I*)arr->At(3))->Fill(fTracklet->GetZref(1), dz[0]/TMath::Sqrt(cov[2]));
-
- ((TH2I*)arr->At(4))->Fill(fTracklet->GetYref(1), TMath::ATan((fTracklet->GetYref(1)-fTracklet->GetYfit(1))/(1-fTracklet->GetYref(1)*fTracklet->GetYfit(1))));
+ Double_t dyz[2]= {dy[1], dz[1]};
+ Pulls(dyz, cov, tilt);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dyz[0], dyz[1]);
+ ((TH3S*)arr->At(3))->Fill(tht, dyz[1], rc);
+
+ Double_t dphi((phi-fTracklet->GetYfit(1))/(1-phi*fTracklet->GetYfit(1)));
+ Double_t dtht((tht-fTracklet->GetZfit(1))/(1-tht*fTracklet->GetZfit(1)));
+ ((TH2I*)arr->At(4))->Fill(phi, TMath::ATan(dphi));
+
+ if(DebugLevel()>=1){
+ UChar_t err(fTracklet->GetErrorMsg());
+ (*DebugStream()) << "tracklet"
+ <<"pt=" << pt
+ <<"phi=" << phi
+ <<"tht=" << tht
+ <<"det=" << sgm[2]
+ <<"dy0=" << dy[0]
+ <<"dz0=" << dz[0]
+ <<"dy=" << dy[1]
+ <<"dz=" << dz[1]
+ <<"dphi="<< dphi
+ <<"dtht="<< dtht
+ <<"dyp=" << dyz[0]
+ <<"dzp=" << dyz[1]
+ <<"rc=" << rc
+ <<"err=" << err
+ << "\n";
+ }
}
AliWarning("Tracklet did not match Track.");
return NULL;
}
- Int_t det(-1), stk(-1), sec(-1);
- det = fTracklet->GetDetector();
- sec = AliTRDgeometry::GetSector(det);
- stk = sec * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(det);
+ Int_t sgm[3];
+ sgm[2] = fTracklet->GetDetector();
+ sgm[0] = AliTRDgeometry::GetSector(sgm[2]);
+ sgm[1] = sgm[0] * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(sgm[2]);
Double_t tilt(fTracklet->GetTilt())
,t2(tilt*tilt)
,corr(1./(1. + t2))
,cost(TMath::Sqrt(corr));
+ Bool_t rc(fTracklet->IsRowCross());
const Int_t kNPAR(5);
Double_t parR[kNPAR]; memcpy(parR, tin->GetParameter(), kNPAR*sizeof(Double_t));
//COV.Print(); PAR.Print();
//TODO Double_t dydx = TMath::Sqrt(1.-parR[2]*parR[2])/parR[2];
- Double_t dy[3]={parR[0] - fTracklet->GetY(), 0., 0.}
- ,dz[3]={parR[1] - fTracklet->GetZ(), 0., 0.}
+ Double_t dy[2]={parR[0] - fTracklet->GetY(), 0.}
+ ,dz[2]={parR[1] - fTracklet->GetZ(), 0.}
,dphi(TMath::ASin(PAR[2])-TMath::ATan(fTracklet->GetYfit(1)));
// calculate residuals using tilt rotation
dy[1] = cost*(dy[0] - dz[0]*tilt);
dz[1] = cost*(dz[0] + dy[0]*tilt);
TObjArray *arr = (TObjArray*)fContainer->At(kTrackIn);
- if(1./PAR[4]>fPtThreshold) ((TH3S*)arr->At(0))->Fill(fTracklet->GetYref(1), dy[1], sec);
- ((TH2I*)arr->At(2))->Fill(fTracklet->GetZref(1), dz[1]);
+ if(1./PAR[4]>fPtThreshold) ((TH3S*)arr->At(0))->Fill(fTracklet->GetYref(1), dy[1], sgm[fgSegmentLevel]+rc*fgkNresYsegm[fgSegmentLevel]);
+ ((TH3S*)arr->At(2))->Fill(fTracklet->GetZref(1), dz[1], rc);
((TH2I*)arr->At(4))->Fill(fTracklet->GetYref(1), dphi);
-
- ((TH2I*)arr->At(1))->Fill(fTracklet->GetYref(1), dy[0]/TMath::Sqrt(COV(0,0)+cov[0]));
- ((TH2I*)arr->At(3))->Fill(fTracklet->GetZref(1), dz[0]/TMath::Sqrt(COV(1,1)+cov[2]));
+ Double_t dyz[2] = {dy[1], dz[1]};
+ Double_t cc[3] = {COV(0,0)+cov[0], COV(0,1)+cov[1], COV(1,1)+cov[2]};
+ Pulls(dyz, cc, tilt);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dyz[0], dyz[1]);
+ ((TH3S*)arr->At(3))->Fill(fTracklet->GetZref(1), dyz[1], rc);
// register reference histo for mini-task
h = (TH2I*)arr->At(0);
- if(DebugLevel()>=1){
+ if(DebugLevel()>=2){
(*DebugStream()) << "trackIn"
<< "x=" << x
<< "P=" << &PAR
// fill histos
arr = (TObjArray*)fContainer->At(kMCtrackIn);
// y resolution/pulls
- if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, PARMC[0]-PAR[0], sec);
- ((TH2I*)arr->At(1))->Fill(dydx0, (PARMC[0]-PAR[0])/TMath::Sqrt(COV(0,0)));
+ if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, PARMC[0]-PAR[0], sgm[fgSegmentLevel]);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], (PARMC[0]-PAR[0])/TMath::Sqrt(COV(0,0)), (PARMC[1]-PAR[1])/TMath::Sqrt(COV(1,1)));
// z resolution/pulls
- ((TH2I*)arr->At(2))->Fill(dzdx0, PARMC[1]-PAR[1]);
- ((TH2I*)arr->At(3))->Fill(dzdx0, (PARMC[1]-PAR[1])/TMath::Sqrt(COV(1,1)));
+ ((TH3S*)arr->At(2))->Fill(dzdx0, PARMC[1]-PAR[1], 0);
+ ((TH3S*)arr->At(3))->Fill(dzdx0, (PARMC[1]-PAR[1])/TMath::Sqrt(COV(1,1)), 0);
// phi resolution/snp pulls
((TH2I*)arr->At(4))->Fill(dydx0, TMath::ASin(PARMC[2])-TMath::ASin(PAR[2]));
((TH2I*)arr->At(5))->Fill(dydx0, (PARMC[2]-PAR[2])/TMath::Sqrt(COV(2,2)));
// if(sp>0.) ((TH3S*)arr->At(11))->Fill(p0, (p0-p)/TMath::Sqrt(sp), sign*sIdx);
// fill debug for MC
- if(DebugLevel()>=1){
+ if(DebugLevel()>=3){
(*DebugStream()) << "trackInMC"
<< "P=" << &PARMC
<< "\n";
AliWarning("Tracklet did not match Track position.");
return NULL;
}
- Int_t det(-1), stk(-1), sec(-1);
- det = fTracklet->GetDetector();
- sec = AliTRDgeometry::GetSector(det);
- stk = sec * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(det);
+ Int_t sgm[3];
+ sgm[2] = fTracklet->GetDetector();
+ sgm[0] = AliTRDgeometry::GetSector(sgm[2]);
+ sgm[1] = sgm[0] * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(sgm[2]);
Double_t tilt(fTracklet->GetTilt())
,t2(tilt*tilt)
,corr(1./(1. + t2))
,cost(TMath::Sqrt(corr));
+ Bool_t rc(fTracklet->IsRowCross());
const Int_t kNPAR(5);
Double_t parR[kNPAR]; memcpy(parR, tout->GetParameter(), kNPAR*sizeof(Double_t));
// calculate residuals using tilt rotation
dy[1] = cost*(dy[0] - dz[0]*tilt);
dz[1] = cost*(dz[0] + dy[0]*tilt);
- if(DebugLevel()>=1){
- (*DebugStream()) << "trackOutRes"
- << "dy0=" << dy[0]
- << "dz0=" << dz[0]
- << "dy1=" << dy[1]
- << "dz1=" << dz[1]
- << "tilt=" << tilt
- << "\n";
- }
TObjArray *arr = (TObjArray*)fContainer->At(kTrackOut);
- if(1./PAR[4]>fPtThreshold) ((TH3S*)arr->At(0))->Fill(fTracklet->GetYref(1), 1.e2*dy[1], sec); // scale to fit general residual range !!!
- ((TH2I*)arr->At(2))->Fill(fTracklet->GetZref(1), dz[1]);
+ if(1./PAR[4]>fPtThreshold) ((TH3S*)arr->At(0))->Fill(fTracklet->GetYref(1), 1.e2*dy[1], sgm[fgSegmentLevel]+rc*fgkNresYsegm[fgSegmentLevel]); // scale to fit general residual range !!!
+ ((TH3S*)arr->At(2))->Fill(fTracklet->GetZref(1), dz[1], rc);
((TH2I*)arr->At(4))->Fill(fTracklet->GetYref(1), dphi);
- ((TH2I*)arr->At(1))->Fill(fTracklet->GetYref(1), dy[0]/TMath::Sqrt(COV(0,0)+cov[0]));
- ((TH2I*)arr->At(3))->Fill(fTracklet->GetZref(1), dz[0]/TMath::Sqrt(COV(1,1)+cov[2]));
-
+ Double_t dyz[2] = {dy[1], dz[1]};
+ Double_t cc[3] = {COV(0,0)+cov[0], COV(0,1)+cov[1], COV(1,1)+cov[2]};
+ Pulls(dyz, cc, tilt);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dyz[0], dyz[1]);
+ ((TH3S*)arr->At(3))->Fill(fTracklet->GetZref(1), dyz[1], rc);
// register reference histo for mini-task
h = (TH2I*)arr->At(0);
- if(DebugLevel()>=1){
+ if(DebugLevel()>=2){
(*DebugStream()) << "trackOut"
<< "x=" << x
<< "P=" << &PAR
// fill histos
arr = (TObjArray*)fContainer->At(kMCtrackOut);
// y resolution/pulls
- if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, PARMC[0]-PAR[0], sec);
- ((TH2I*)arr->At(1))->Fill(dydx0, (PARMC[0]-PAR[0])/TMath::Sqrt(COV(0,0)));
+ if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, PARMC[0]-PAR[0], sgm[fgSegmentLevel]);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], (PARMC[0]-PAR[0])/TMath::Sqrt(COV(0,0)), (PARMC[1]-PAR[1])/TMath::Sqrt(COV(1,1)));
// z resolution/pulls
- ((TH2I*)arr->At(2))->Fill(dzdx0, PARMC[1]-PAR[1]);
- ((TH2I*)arr->At(3))->Fill(dzdx0, (PARMC[1]-PAR[1])/TMath::Sqrt(COV(1,1)));
+ ((TH3S*)arr->At(2))->Fill(dzdx0, PARMC[1]-PAR[1], 0);
+ ((TH3S*)arr->At(3))->Fill(dzdx0, (PARMC[1]-PAR[1])/TMath::Sqrt(COV(1,1)), 0);
// phi resolution/snp pulls
((TH2I*)arr->At(4))->Fill(dydx0, TMath::ASin(PARMC[2])-TMath::ASin(PAR[2]));
((TH2I*)arr->At(5))->Fill(dydx0, (PARMC[2]-PAR[2])/TMath::Sqrt(COV(2,2)));
// if(sp>0.) ((TH3S*)arr->At(11))->Fill(p0, (p0-p)/TMath::Sqrt(sp), sign*sIdx);
// fill debug for MC
- if(DebugLevel()>=1){
+ if(DebugLevel()>=3){
(*DebugStream()) << "trackOutMC"
<< "P=" << &PARMC
<< "\n";
Int_t pdg = fkMC->GetPDG(),
sIdx(AliTRDpidUtil::Pdg2Pid(TMath::Abs(pdg))+1), // species index
sign(0),
- det(-1),
- stk(-1),
- sec(-1),
+ sgm[3],
label(fkMC->GetLabel());
if(!fDBPDG) fDBPDG=TDatabasePDG::Instance();
TParticlePDG *ppdg(fDBPDG->GetParticle(pdg));
Float_t pt0, x0, y0, z0, dx, dy, dz, dydx0, dzdx0;
Double_t covR[7]/*, cov[3]*/;
- if(DebugLevel()>=1){
+ if(DebugLevel()>=3){
TVectorD dX(12), dY(12), dZ(12), Pt(12), dPt(12), cCOV(12*15);
fkMC->PropagateKalman(&dX, &dY, &dZ, &Pt, &dPt, &cCOV);
(*DebugStream()) << "MCkalman"
if(!(fTracklet = fkTrack->GetTracklet(ily)))/* ||
!fTracklet->IsOK())*/ continue;
- det = fTracklet->GetDetector();
- sec = AliTRDgeometry::GetSector(det);
- Int_t istk = AliTRDgeometry::GetStack(det);
- stk = sec * AliTRDgeometry::kNstack + istk;
+ sgm[2] = fTracklet->GetDetector();
+ sgm[0] = AliTRDgeometry::GetSector(sgm[2]);
+ sgm[1] = sgm[0] * AliTRDgeometry::kNstack + AliTRDgeometry::GetStack(sgm[2]);
Double_t tilt(fTracklet->GetTilt())
,t2(tilt*tilt)
,corr(1./(1. + t2))
x0 = fTracklet->GetX0();
//radial shift with respect to the MC reference (radial position of the pad plane)
x= fTracklet->GetX();
+ Bool_t rc(fTracklet->IsRowCross());
if(!fkMC->GetDirections(x0, y0, z0, dydx0, dzdx0, pt0, s)) continue;
xAnode = fTracklet->GetX0();
// MC track position at reference radial position
dx = x0 - x;
- if(DebugLevel()>=1){
+ if(DebugLevel()>=4){
(*DebugStream()) << "MC"
- << "det=" << det
+ << "det=" << sgm[2]
<< "pdg=" << pdg
<< "sgn=" << sign
<< "pt=" << pt0
arr = (TObjArray*)((TObjArray*)fContainer->At(kMCtrack))->At(ily);
// y resolution/pulls
- if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, dy, sec);
- if(DebugLevel()>=1){
- (*DebugStream()) << "trackMCRes"
- << "dy=" << dy
- << "dz=" << dz
- << "tilt=" << tilt
- << "\n";
- }
- ((TH2I*)arr->At(1))->Fill(dydx0, dy/TMath::Sqrt(covR[0]));
+ if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, dy, sgm[fgSegmentLevel]);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dy/TMath::Sqrt(covR[0]), dz/TMath::Sqrt(covR[2]));
// z resolution/pulls
- ((TH2I*)arr->At(2))->Fill(dzdx0, dz);
- ((TH2I*)arr->At(3))->Fill(dzdx0, dz/TMath::Sqrt(covR[2]));
+ ((TH3S*)arr->At(2))->Fill(dzdx0, dz, 0);
+ ((TH3S*)arr->At(3))->Fill(dzdx0, dz/TMath::Sqrt(covR[2]), 0);
// phi resolution/ snp pulls
Double_t dtgp = (dydx - dydx0)/(1.- dydx*dydx0);
((TH2I*)arr->At(4))->Fill(dydx0, TMath::ATan(dtgp));
((TH3S*)((TObjArray*)arr->At(10)))->Fill(p0, p/p0-1., sign*sIdx);
// Fill Debug stream for Kalman track
- if(DebugLevel()>=1){
+ if(DebugLevel()>=4){
(*DebugStream()) << "MCtrack"
<< "pt=" << pt
<< "x=" << x
dx = x0 - x;
ymc = y0 - dx*dydx0;
zmc = z0 - dx*dzdx0;
- Bool_t rc(tt.IsRowCross());
dy = y-ymc;
dz = z-zmc;
+ Float_t dphi = (dydx - dydx0);
+ dphi /= (1.- dydx*dydx0);
// add tracklet residuals for y and dydx
arr = (TObjArray*)fContainer->At(kMCtracklet);
- if(!rc){
- Float_t dphi = (dydx - dydx0);
- dphi /= (1.- dydx*dydx0);
-
- if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, dy, sec);
- if(tt.GetS2Y()>0.) ((TH2I*)arr->At(1))->Fill(dydx0, dy/TMath::Sqrt(tt.GetS2Y()));
- ((TH2I*)arr->At(4))->Fill(dydx0, TMath::ATan(dphi));
- } else {
- // add tracklet residuals for z
- ((TH2I*)arr->At(2))->Fill(dzdl0, dz);
- if(tt.GetS2Z()>0.) ((TH2I*)arr->At(3))->Fill(dzdl0, dz/TMath::Sqrt(tt.GetS2Z()));
- }
+
+ if(pt0>fPtThreshold) ((TH3S*)arr->At(0))->Fill(dydx0, dy, sgm[fgSegmentLevel]);
+ if(tt.GetS2Y()>0. && tt.GetS2Z()>0.) ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dy/TMath::Sqrt(tt.GetS2Y()), dz/TMath::Sqrt(tt.GetS2Z()));
+ ((TH3S*)arr->At(2))->Fill(dzdl0, dz, rc);
+ if(tt.GetS2Z()>0.) ((TH3S*)arr->At(3))->Fill(dzdl0, dz/TMath::Sqrt(tt.GetS2Z()), rc);
+ ((TH2I*)arr->At(4))->Fill(dydx0, TMath::ATan(dphi));
// Fill Debug stream for tracklet
- if(DebugLevel()>=1){
+ if(DebugLevel()>=4){
Float_t s2y = tt.GetS2Y();
Float_t s2z = tt.GetS2Z();
(*DebugStream()) << "MCtracklet"
<< "\n";
}
- AliTRDpadPlane *pp = fGeo->GetPadPlane(ily, istk);
+ AliTRDpadPlane *pp = fGeo->GetPadPlane(ily, AliTRDgeometry::GetStack(sgm[2]));
Float_t zr0 = pp->GetRow0() + pp->GetAnodeWireOffset();
//Double_t exb = AliTRDCommonParam::Instance()->GetOmegaTau(1.5);
// Fill Histograms
if(q>20. && q<250. && pt0>fPtThreshold){
- ((TH3S*)arr->At(0))->Fill(dydx0, dy, sec);
- ((TH2I*)arr->At(1))->Fill(dydx0, dy/TMath::Sqrt(c->GetSigmaY2()));
+ ((TH3S*)arr->At(0))->Fill(dydx0, dy, sgm[fgSegmentLevel]);
+ ((TH3S*)arr->At(1))->Fill(sgm[fgSegmentLevel], dy/TMath::Sqrt(c->GetSigmaY2()), dz/TMath::Sqrt(c->GetSigmaZ2()));
}
// Fill calibration container
clInfo->SetDriftLength(dx-.5*AliTRDgeometry::CamHght());
clInfo->SetTilt(tilt);
fMCcl->Add(clInfo);
- if(DebugLevel()>=2){
+ if(DebugLevel()>=5){
if(!clInfoArr) clInfoArr=new TObjArray(AliTRDseedV1::kNclusters);
clInfoArr->Add(clInfo);
}
}
// Fill Debug Tree
- if(DebugLevel()>=2 && clInfoArr){
+ if(DebugLevel()>=5 && clInfoArr){
(*DebugStream()) << "MCcluster"
<<"clInfo.=" << clInfoArr
<< "\n";
AliWarning("Please provide a canvas to draw results.");
return kFALSE;
}
- Int_t selection[100], n(0); //
+ Int_t selection[100], n(0), selStart(0); //
Int_t ly0(0), dly(5);
//Int_t ly0(1), dly(2); // used for SA
TList *l(NULL); TVirtualPad *pad(NULL);
xy[0] = -.3; xy[1] = -100.; xy[2] = .3; xy[3] = 1000.;
pad = (TVirtualPad*)l->At(0); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kCluster, 0, 1, n, selection)) break;
pad=(TVirtualPad*)l->At(1); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kCluster, 0, 1, n, selection)) break;
return kTRUE;
case 2: // cluster2track residuals
xy[0] = -.3; xy[1] = -100.; xy[2] = .3; xy[3] = 1000.;
pad = (TVirtualPad*)l->At(0); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kCluster, 0, 1, n, selection)) break;
- xy[0] = -.3; xy[1] = -0.5; xy[2] = .3; xy[3] = 2.5;
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-0.5; xy[3] = 2.5;
pad=(TVirtualPad*)l->At(1); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
- if(!GetGraph(&xy[0], kCluster, 1)) break;
+ if(!GetGraphArray(xy, kCluster, 1, 1)) break;
return kTRUE;
case 3: // kTrack y
- gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
- xy[0] = -.3; xy[1] = -50.; xy[2] = .3; xy[3] = 300.;
+ gPad->Divide(3, 2, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0] = -.3; xy[1] = -20.; xy[2] = .3; xy[3] = 100.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrack, 0, 1, n, selection)) break;
+
((TVirtualPad*)l->At(1))->cd();
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kTrack, 0, 1, n, selection)) break;
+
+ ((TVirtualPad*)l->At(2))->cd();
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrack, 0, 1, n, selection)) break;
+
+ ((TVirtualPad*)l->At(3))->cd();
+ selStart=fgkNresYsegm[fgSegmentLevel]; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kTrack, 0, 1, n, selection, "[RC]")) break;
+
+ ((TVirtualPad*)l->At(4))->cd();
+ selStart=fgkNresYsegm[fgSegmentLevel]/3+fgkNresYsegm[fgSegmentLevel]; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kTrack, 0, 1, n, selection, "[RC]")) break;
+
+ ((TVirtualPad*)l->At(5))->cd();
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3+fgkNresYsegm[fgSegmentLevel]; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kTrack, 0, 1, n, selection, "[RC]")) break;
return kTRUE;
- case 4: // kTrack y
+ case 4: // kTrack z
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
- xy[0] = -.3; xy[1] = -50.; xy[2] = .3; xy[3] = 300.;
+
+ xy[0] = -1.; xy[1] = -150.; xy[2] = 1.; xy[3] = 1000.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
- if(!GetGraphArray(xy, kTrack, 0, 1, n, selection)) break;
- xy[0] = -.3; xy[1] = -0.5; xy[2] = .3; xy[3] = 2.5;
+ selection[0]=1;
+ if(!GetGraphArray(xy, kTrack, 2, 1, 1, selection)) break;
+
+ xy[0] = -1.; xy[1] = -1500.; xy[2] = 1.; xy[3] = 10000.;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(xy, kTrack, 1)) break;
+ selection[0]=0;
+ if(!GetGraphArray(xy, kTrack, 2, 1, 1, selection)) break;
+
return kTRUE;
- case 5: // kTrack z
+ case 5: // kTrack pulls
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
- xy[0] = -1.; xy[1] = -1000.; xy[2] = 1.; xy[3] = 4000.;
+
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-.5; xy[3] = 2.5;
((TVirtualPad*)l->At(0))->cd();
- if(!GetGraph(&xy[0], kTrack , 2)) break;
+ if(!GetGraphArray(xy, kTrack, 1, 1)) break;
+
xy[0] = -1.; xy[1] = -0.5; xy[2] = 1.; xy[3] = 2.5;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(&xy[0], kTrack , 3)) break;
+ if(!GetGraphArray(xy, kTrack, 3, 1)) break;
return kTRUE;
case 6: // kTrack phi
xy[0] = -.3; xy[1] = -5.; xy[2] = .3; xy[3] = 50.;
xy[0] = -.3; xy[1] = -1500.; xy[2] = .3; xy[3] = 5000.;
pad = ((TVirtualPad*)l->At(0)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrackIn, 0, 1, n, selection)) break;
pad=((TVirtualPad*)l->At(1)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrackIn, 0, 1, n, selection)) break;
return kTRUE;
case 8: // kTrackIn y
xy[0] = -.3; xy[1] = -1500.; xy[2] = .3; xy[3] = 5000.;
pad = ((TVirtualPad*)l->At(0)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrackIn, 0, 1, n, selection)) break;
- xy[0] = -.3; xy[1] = -0.5; xy[2] = .3; xy[3] = 2.5;
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-.5; xy[3] = 2.5;
pad=((TVirtualPad*)l->At(1)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- if(!GetGraph(&xy[0], kTrackIn, 1)) break;
+ if(!GetGraphArray(xy, kTrackIn, 1, 1)) break;
return kTRUE;
case 9: // kTrackIn z
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0] = -1.; xy[1] = -1000.; xy[2] = 1.; xy[3] = 4000.;
pad = ((TVirtualPad*)l->At(0)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- if(!GetGraph(&xy[0], kTrackIn, 2)) break;
+ selection[0]=1;
+ if(!GetGraphArray(xy, kTrackIn, 2, 1, 1, selection)) break;
xy[0] = -1.; xy[1] = -0.5; xy[2] = 1.; xy[3] = 2.5;
pad = ((TVirtualPad*)l->At(1)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- if(!GetGraph(&xy[0], kTrackIn, 3)) break;
+ if(!GetGraphArray(xy, kTrackIn, 3, 1)) break;
return kTRUE;
case 10: // kTrackIn phi
xy[0] = -.3; xy[1] = -5.; xy[2] = .3; xy[3] = 50.;
xy[0] = -.3; xy[1] = -50.; xy[2] = .3; xy[3] = 150.;
pad = ((TVirtualPad*)l->At(0)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrackOut, 0, 1, n, selection)) break;
pad=((TVirtualPad*)l->At(1)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrackOut, 0, 1, n, selection)) break;
return kTRUE;
case 12: // kTrackOut y
xy[0] = -.3; xy[1] = -50.; xy[2] = .3; xy[3] = 150.;
pad = ((TVirtualPad*)l->At(0)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kTrackOut, 0, 1, n, selection)) break;
- xy[0] = -.3; xy[1] = -0.5; xy[2] = .3; xy[3] = 2.5;
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-.5; xy[3] = 2.5;
pad=((TVirtualPad*)l->At(1)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- if(!GetGraph(&xy[0], kTrackOut, 1)) break;
+ if(!GetGraphArray(xy, kTrackOut, 1, 1)) break;
return kTRUE;
case 13: // kTrackOut z
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0] = -1.; xy[1] = -1000.; xy[2] = 1.; xy[3] = 4000.;
pad = ((TVirtualPad*)l->At(0)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- if(!GetGraph(&xy[0], kTrackOut, 2)) break;
+ if(!GetGraphArray(xy, kTrackOut, 2, 1)) break;
xy[0] = -1.; xy[1] = -0.5; xy[2] = 1.; xy[3] = 2.5;
pad = ((TVirtualPad*)l->At(1)); pad->cd();
pad->SetMargin(0.1, 0.1, 0.1, 0.01);
- if(!GetGraph(&xy[0], kTrackOut, 3)) break;
+ if(!GetGraphArray(xy, kTrackOut, 3, 1)) break;
return kTRUE;
case 14: // kTrackOut phi
xy[0] = -.3; xy[1] = -5.; xy[2] = .3; xy[3] = 50.;
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.3; xy[1]=-50.; xy[2]=.3; xy[3]=650.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCcluster, 0, 1, n, selection)) break;
((TVirtualPad*)l->At(1))->cd();
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCcluster, 0, 1, n, selection)) break;
return kTRUE;
case 16: // kMCcluster
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.3; xy[1]=-50.; xy[2]=.3; xy[3]=650.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCcluster, 0, 1, n, selection)) break;
((TVirtualPad*)l->At(1))->cd();
- xy[0]=-.3; xy[1]=-0.5; xy[2]=.3; xy[3]=2.5;
- if(!GetGraph(xy, kMCcluster, 1)) break;
+ xy[0]=-.5; xy[1]=-0.5; xy[2]=fgkNresYsegm[fgSegmentLevel]-.5; xy[3]=2.5;
+ if(!GetGraphArray(xy, kMCcluster, 1, 1)) break;
return kTRUE;
case 17: //kMCtracklet [y]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.3; xy[1]=-50.; xy[2]=.3; xy[3] =500.;
((TVirtualPad*)l->At(0))->cd();
- if(!GetGraphArray(xy, kMCtracklet, 0)) break;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtracklet, 0, 1, n, selection)) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtracklet, 0, 1, n, selection)) break;
+ return kTRUE;
+ case 18: //kMCtracklet [y]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0]=-.3; xy[1]=-50.; xy[2]=.3; xy[3] =500.;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtracklet, 0, 1, n, selection)) break;
((TVirtualPad*)l->At(1))->cd();
- xy[0]=-.3; xy[1]=-0.5; xy[2]=.3; xy[3]=2.5;
- if(!GetGraph(xy, kMCtracklet, 1)) break;
+ xy[0]=-.5; xy[1]=-0.5; xy[2]=fgkNresYsegm[fgSegmentLevel]-.5; xy[3]=2.5;
+ if(!GetGraphArray(xy, kMCtracklet, 1, 1)) break;
return kTRUE;
- case 18: //kMCtracklet [z]
+ case 19: //kMCtracklet [z]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-100.; xy[2]=1.; xy[3] =2500.;
((TVirtualPad*)l->At(0))->cd();
- if(!GetGraph(&xy[0], kMCtracklet, 2)) break;
+ if(!GetGraphArray(xy, kMCtracklet, 2)) break;
xy[0] = -1.; xy[1] = -0.5; xy[2] = 1.; xy[3] = 2.5;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(&xy[0], kMCtracklet, 3)) break;
+ if(!GetGraphArray(xy, kMCtracklet, 3)) break;
return kTRUE;
- case 19: //kMCtracklet [phi]
+ case 20: //kMCtracklet [phi]
xy[0]=-.3; xy[1]=-3.; xy[2]=.3; xy[3] =25.;
if(!GetGraph(&xy[0], kMCtracklet, 4)) break;
return kTRUE;
- case 20: //kMCtrack [y]
+ case 21: //kMCtrack [y] ly [0]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0]=-.2; xy[1]=-50.; xy[2]=.2; xy[3] =400.;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*0.); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer1")) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*0.5); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer1")) break;
+ return kTRUE;
+ case 22: //kMCtrack [y] ly [1]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0]=-.2; xy[1]=-50.; xy[2]=.2; xy[3] =400.;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*1.); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer2")) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*1.5); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer2")) break;
+ return kTRUE;
+ case 23: //kMCtrack [y] ly [2]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0]=-.2; xy[1]=-50.; xy[2]=.2; xy[3] =400.;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*2.); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer3")) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*2.5); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer3")) break;
+ return kTRUE;
+ case 24: //kMCtrack [y] ly [3]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.2; xy[1]=-50.; xy[2]=.2; xy[3] =400.;
((TVirtualPad*)l->At(0))->cd();
- if(!GetGraphArray(xy, kMCtrack, 0)) break;
- xy[0] = -.2; xy[1] = -0.5; xy[2] = .2; xy[3] = 3.5;
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*3.); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer4")) break;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraphArray(xy, kMCtrack, 1)) break;
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*3.5); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer4")) break;
return kTRUE;
- case 21: //kMCtrack [z]
+ case 25: //kMCtrack [y] ly [4]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0]=-.2; xy[1]=-50.; xy[2]=.2; xy[3] =400.;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*4.); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer5")) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*4.5); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer5")) break;
+ return kTRUE;
+ case 26: //kMCtrack [y] ly [5]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0]=-.2; xy[1]=-50.; xy[2]=.2; xy[3] =400.;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*5.); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer6")) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=Int_t(fgkNresYsegm[fgSegmentLevel]*5.5); for(n=0; n<fgkNresYsegm[fgSegmentLevel]/2; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 0, 1, n, selection, "Layer6")) break;
+ return kTRUE;
+ case 27: //kMCtrack [y pulls]
+ gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-.5; xy[3] = 5.5;
+ ((TVirtualPad*)l->At(0))->cd();
+ selStart=0; for(n=0; n<6; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 1, 1, n, selection)) break;
+ ((TVirtualPad*)l->At(1))->cd();
+ selStart=6; for(n=0; n<6; n++) selection[n]=selStart+n;
+ if(!GetGraphArray(xy, kMCtrack, 1, 1, n, selection)) break;
+ return kTRUE;
+ case 28: //kMCtrack [z]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-1500.; xy[2]=1.; xy[3] =6000.;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraphArray(xy, kMCtrack, 3)) break;
return kTRUE;
- case 22: //kMCtrack [phi/snp]
+ case 29: //kMCtrack [phi/snp]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.2; xy[1]=-0.5; xy[2]=.2; xy[3] =10.;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraphArray(xy, kMCtrack, 5)) break;
return kTRUE;
- case 23: //kMCtrack [theta/tgl]
+ case 30: //kMCtrack [theta/tgl]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-0.5; xy[2]=1.; xy[3] =5.;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraphArray(xy, kMCtrack, 7)) break;
return kTRUE;
- case 24: //kMCtrack [pt]
+ case 31: //kMCtrack [pt]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
pad = (TVirtualPad*)l->At(0); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
if(!GetGraphArray(xy, kMCtrack, 8, kTRUE, n, selection, "#mu#pm")) break;
pad->Modified(); pad->Update(); pad->SetLogx();
return kTRUE;
- case 25: //kMCtrack [pt]
+ case 32: //kMCtrack [pt]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
pad = (TVirtualPad*)l->At(0); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
if(!GetGraphArray(xy, kMCtrack, 8, kTRUE, n, selection, "e#pm")) break;
pad->Modified(); pad->Update(); pad->SetLogx();
return kTRUE;
- case 26: //kMCtrack [1/pt] pulls
+ case 33: //kMCtrack [1/pt] pulls
xy[0] = 0.; xy[1] = -1.; xy[2] = 2.; xy[3] = 3.5;
//xy[0] = 0.; xy[1] = -1.; xy[2] = 2.; xy[3] = 4.5; // SA
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
}
if(!GetGraphArray(xy, kMCtrack, 9, kTRUE, n, selection, "#mu#pm")) break;
return kTRUE;
- case 27: //kMCtrack [1/pt] pulls
+ case 34: //kMCtrack [1/pt] pulls
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
pad = (TVirtualPad*)l->At(0); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
xy[0] = 0.; xy[1] = -2.; xy[2] = 2.; xy[3] = 4.5;
if(!GetGraphArray(xy, kMCtrack, 9, kTRUE, n, selection, "e#pm")) break;
return kTRUE;
- case 28: //kMCtrack [p]
+ case 35: //kMCtrack [p]
xy[0] = 0.2; xy[1] = -.7; xy[2] = 7.; xy[3] = 4.;
//xy[0] = 0.2; xy[1] = -1.5; xy[2] = 7.; xy[3] = 10.;
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
if(!GetGraphArray(xy, kMCtrack, 10, kTRUE, n, selection, "#mu#pm")) break;
pad->Modified(); pad->Update(); pad->SetLogx();
return kTRUE;
- case 29: //kMCtrack [p]
+ case 36: //kMCtrack [p]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
pad = (TVirtualPad*)l->At(0); pad->cd();
pad->SetMargin(0.125, 0.015, 0.1, 0.015);
if(!GetGraphArray(xy, kMCtrack, 10, kTRUE, n, selection, "e#pm")) break;
pad->Modified(); pad->Update(); pad->SetLogx();
return kTRUE;
- case 30: // kMCtrackIn [y]
+ case 37: // kMCtrackIn [y]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.25; xy[1]=-1000.; xy[2]=.25; xy[3] =3000.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCtrackIn, 0, 1, n, selection)) break;
((TVirtualPad*)l->At(1))->cd();
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(&xy[0], kMCtrackIn, 0, 1, n, selection)) break;
return kTRUE;
- case 31: // kMCtrackIn [y]
+ case 38: // kMCtrackIn [y]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.25; xy[1]=-1000.; xy[2]=.25; xy[3] =3000.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCtrackIn, 0, 1, n, selection)) break;
- xy[0] = -.25; xy[1] = -0.5; xy[2] = .25; xy[3] = 2.5;
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-.5; xy[3] = 2.5;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(&xy[0], kMCtrackIn, 1)) break;
+ if(!GetGraphArray(xy, kMCtrackIn, 1, 1)) break;
return kTRUE;
- case 32: // kMCtrackIn [z]
+ case 39: // kMCtrackIn [z]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-500.; xy[2]=1.; xy[3] =800.;
((TVirtualPad*)l->At(0))->cd();
- if(!GetGraph(&xy[0], kMCtrackIn, 2)) break;
+ if(!GetGraphArray(xy, kMCtrackIn, 2, 1)) break;
xy[0] = -1.; xy[1] = -0.5; xy[2] = 1.; xy[3] = 2.5;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(&xy[0], kMCtrackIn, 3)) break;
+ if(!GetGraphArray(xy, kMCtrackIn, 3, 1)) break;
return kTRUE;
- case 33: // kMCtrackIn [phi|snp]
+ case 40: // kMCtrackIn [phi|snp]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.25; xy[1]=-0.5; xy[2]=.25; xy[3] =2.5;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraph(&xy[0], kMCtrackIn, 5)) break;
return kTRUE;
- case 34: // kMCtrackIn [theta|tgl]
+ case 41: // kMCtrackIn [theta|tgl]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-1.; xy[2]=1.; xy[3] =4.;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraph(&xy[0], kMCtrackIn, 7)) break;
return kTRUE;
- case 35: // kMCtrackIn [pt]
+ case 42: // kMCtrackIn [pt]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0] = 0.2; xy[1] = -.8; xy[2] = 7.; xy[3] = 6.;
//xy[0] = 0.2; xy[1] = -1.5; xy[2] = 7.; xy[3] = 10.; // SA
n=0; selection[n++]=0; selection[n++]=4; selection[n++]=6; selection[n++]=10;
if(!GetGraphArray(xy, kMCtrackIn, 8, 1, n, selection)) break;
return kTRUE;
- case 36: //kMCtrackIn [1/pt] pulls
+ case 43: //kMCtrackIn [1/pt] pulls
xy[0] = 0.; xy[1] = -1.; xy[2] = 2.; xy[3] = 3.5;
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
pad = (TVirtualPad*)l->At(0); pad->cd();
n=0; selection[n++]=0; selection[n++]=4; selection[n++]=6; selection[n++]=10;
if(!GetGraphArray(xy, kMCtrackIn, 9, 1, n, selection)) break;
return kTRUE;
- case 37: // kMCtrackIn [p]
+ case 44: // kMCtrackIn [p]
xy[0] = 0.2; xy[1] = -.8; xy[2] = 7.; xy[3] = 6.;
//xy[0] = 0.2; xy[1] = -1.5; xy[2] = 7.; xy[3] = 10.;
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
n=0; selection[n++]=0; selection[n++]=4; selection[n++]=6; selection[n++]=10;
if(!GetGraphArray(xy, kMCtrackIn, 10, 1, n, selection)) break;
return kTRUE;
- case 38: // kMCtrackOut [y]
+ case 45: // kMCtrackOut [y]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.3; xy[1]=-50.; xy[2]=.3; xy[3] =400.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=0; selection[n++]=1; selection[n++]=2; selection[n++]=3;selection[n++]=4;selection[n++]=5;
+ selStart=0; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCtrackOut, 0, 1, n, selection)) break;
((TVirtualPad*)l->At(1))->cd();
- n=0; selection[n++]=6; selection[n++]=7; selection[n++]=8; selection[n++]=9;selection[n++]=10;selection[n++]=11;
+ selStart=fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(&xy[0], kMCtrackOut, 0, 1, n, selection)) break;
return kTRUE;
- case 39: // kMCtrackOut [y]
+ case 46: // kMCtrackOut [y]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.3; xy[1]=-50.; xy[2]=.3; xy[3] =400.;
((TVirtualPad*)l->At(0))->cd();
- n=0; selection[n++]=12; selection[n++]=13; selection[n++]=14; selection[n++]=15;selection[n++]=16;selection[n++]=17;
+ selStart=2*fgkNresYsegm[fgSegmentLevel]/3; for(n=0; n<fgkNresYsegm[fgSegmentLevel]/3; n++) selection[n]=selStart+n;
if(!GetGraphArray(xy, kMCtrackOut, 0, 1, n, selection)) break;
- xy[0] = -.25; xy[1] = -0.5; xy[2] = .25; xy[3] = 2.5;
+ xy[0] = -.5; xy[1] = -0.5; xy[2] = fgkNresYsegm[fgSegmentLevel]-.5; xy[3] = 2.5;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(&xy[0], kMCtrackOut, 1)) break;
+ if(!GetGraphArray(xy, kMCtrackOut, 1, 1)) break;
return kTRUE;
- case 40: // kMCtrackOut [z]
+ case 47: // kMCtrackOut [z]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-500.; xy[2]=1.; xy[3] =1500.;
((TVirtualPad*)l->At(0))->cd();
- if(!GetGraph(&xy[0], kMCtrackOut, 2)) break;
+ if(!GetGraphArray(xy, kMCtrackOut, 2, 1)) break;
xy[0] = -1.; xy[1] = -0.5; xy[2] = 1.; xy[3] = 2.5;
((TVirtualPad*)l->At(1))->cd();
- if(!GetGraph(&xy[0], kMCtrackOut, 3)) break;
+ if(!GetGraphArray(xy, kMCtrackOut, 3, 1)) break;
return kTRUE;
- case 41: // kMCtrackOut [phi|snp]
+ case 48: // kMCtrackOut [phi|snp]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-.25; xy[1]=-0.5; xy[2]=.25; xy[3] =2.5;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraph(&xy[0], kMCtrackOut, 5)) break;
return kTRUE;
- case 42: // kMCtrackOut [theta|tgl]
+ case 49: // kMCtrackOut [theta|tgl]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0]=-1.; xy[1]=-1.; xy[2]=1.; xy[3] =4.;
((TVirtualPad*)l->At(0))->cd();
((TVirtualPad*)l->At(1))->cd();
if(!GetGraph(&xy[0], kMCtrackOut, 7)) break;
return kTRUE;
- case 43: // kMCtrackOut [pt]
+ case 50: // kMCtrackOut [pt]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0] = 0.2; xy[1] = -.8; xy[2] = 7.; xy[3] = 6.;
pad=(TVirtualPad*)l->At(0); pad->cd(); pad->SetLogx();
n=0; selection[n++]=0; selection[n++]=4; selection[n++]=6; selection[n++]=10;
if(!GetGraphArray(xy, kMCtrackOut, 8, 1, n, selection)) break;
return kTRUE;
- case 44: //kMCtrackOut [1/pt] pulls
+ case 51: //kMCtrackOut [1/pt] pulls
xy[0] = 0.; xy[1] = -1.; xy[2] = 2.; xy[3] = 3.5;
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
pad = (TVirtualPad*)l->At(0); pad->cd();
n=0; selection[n++]=0; selection[n++]=4; selection[n++]=6; selection[n++]=10;
if(!GetGraphArray(xy, kMCtrackOut, 9, 1, n, selection)) break;
return kTRUE;
- case 45: // kMCtrackOut [p]
+ case 52: // kMCtrackOut [p]
gPad->Divide(2, 1, 1.e-5, 1.e-5); l=gPad->GetListOfPrimitives();
xy[0] = 0.2; xy[1] = -.8; xy[2] = 7.; xy[3] = 6.;
pad = ((TVirtualPad*)l->At(0));pad->cd();pad->SetLogx();
gm->SetName(Form("m_%d%02d%02d", ig, ic, is));
// this is important for labels in the legend
if(ic==0) {
- gs->SetTitle(Form("Sector %02d", is%kNyresSlices));
- gm->SetTitle(Form("Sector %02d", is%kNyresSlices));
+ gs->SetTitle(Form("%s %02d", fgkResYsegmName, is%fgkNresYsegm[fgSegmentLevel]));
+ gm->SetTitle(Form("%s %02d", fgkResYsegmName, is%fgkNresYsegm[fgSegmentLevel]));
+ } else if(ic==1) {
+ gs->SetTitle(Form("%s Ly[%d]", is%2 ?"z":"y", is/2));
+ gm->SetTitle(Form("%s Ly[%d]", is%2?"z":"y", is/2));
+ } else if(ic==2||ic==3) {
+ gs->SetTitle(Form("%s Ly[%d]", is%2 ?"RC":"no RC", is/2));
+ gm->SetTitle(Form("%s Ly[%d]", is%2?"RC":"no RC", is/2));
} else if(ic<=7) {
- gs->SetTitle(Form("Layer %d", is%AliTRDgeometry::kNlayer));
- gm->SetTitle(Form("Layer %d", is%AliTRDgeometry::kNlayer));
+ gs->SetTitle(Form("Layer[%d]", is%AliTRDgeometry::kNlayer));
+ gm->SetTitle(Form("Layer[%d]", is%AliTRDgeometry::kNlayer));
} else {
gs->SetTitle(Form("%s @ ly[%d]", fgParticle[is0], il0));
gm->SetTitle(Form("%s @ ly[%d]", fgParticle[is0], il0));
//Process3DL(kCharge, 0, &fl);
// Clusters residuals
Process3D(kCluster, 0, &fg, 1.e4);
- Process2D(kCluster, 1, &fg);
+ Process3Dlinked(kCluster, 1, &fg);
fNRefFigures = 3;
// Tracklet residual/pulls
Process3D(kTrack , 0, &fg, 1.e4);
- Process2D(kTrack , 1, &fg);
- Process2D(kTrack , 2, &fg, 1.e4);
- Process2D(kTrack , 3, &fg);
+ Process3Dlinked(kTrack , 1, &fg);
+ Process3D(kTrack , 2, &fg, 1.e4);
+ Process3D(kTrack , 3, &fg);
Process2D(kTrack , 4, &fg, 1.e3);
fNRefFigures = 7;
// TRDin residual/pulls
Process3D(kTrackIn, 0, &fg, 1.e4);
- Process2D(kTrackIn, 1, &fg);
- Process2D(kTrackIn, 2, &fg, 1.e4);
- Process2D(kTrackIn, 3, &fg);
+ Process3Dlinked(kTrackIn, 1, &fg);
+ Process3D(kTrackIn, 2, &fg, 1.e4);
+ Process3D(kTrackIn, 3, &fg);
Process2D(kTrackIn, 4, &fg, 1.e3);
fNRefFigures = 11;
// TRDout residual/pulls
Process3D(kTrackOut, 0, &fg, 1.e3); // scale to fit - see PlotTrackOut
- Process2D(kTrackOut, 1, &fg);
- Process2D(kTrackOut, 2, &fg, 1.e4);
- Process2D(kTrackOut, 3, &fg);
+ Process3Dlinked(kTrackOut, 1, &fg);
+ Process3D(kTrackOut, 2, &fg, 1.e4);
+ Process3D(kTrackOut, 3, &fg);
Process2D(kTrackOut, 4, &fg, 1.e3);
fNRefFigures = 15;
// CLUSTER Y RESOLUTION/PULLS
Process3D(kMCcluster, 0, &fg, 1.e4);
- Process2D(kMCcluster, 1, &fg, 1.);
+ Process3Dlinked(kMCcluster, 1, &fg, 1.);
fNRefFigures = 17;
// TRACKLET RESOLUTION/PULLS
Process3D(kMCtracklet, 0, &fg, 1.e4); // y
- Process2D(kMCtracklet, 1, &fg, 1.); // y pulls
- Process2D(kMCtracklet, 2, &fg, 1.e4); // z
- Process2D(kMCtracklet, 3, &fg, 1.); // z pulls
+ Process3Dlinked(kMCtracklet, 1, &fg, 1.); // y pulls
+ Process3D(kMCtracklet, 2, &fg, 1.e4); // z
+ Process3D(kMCtracklet, 3, &fg, 1.); // z pulls
Process2D(kMCtracklet, 4, &fg, 1.e3); // phi
- fNRefFigures = 20;
+ fNRefFigures = 21;
// TRACK RESOLUTION/PULLS
Process3Darray(kMCtrack, 0, &fg, 1.e4); // y
- Process2Darray(kMCtrack, 1, &fg); // y PULL
- Process2Darray(kMCtrack, 2, &fg, 1.e4); // z
- Process2Darray(kMCtrack, 3, &fg); // z PULL
+ Process3DlinkedArray(kMCtrack, 1, &fg); // y PULL
+ Process3Darray(kMCtrack, 2, &fg, 1.e4); // z
+ Process3Darray(kMCtrack, 3, &fg); // z PULL
Process2Darray(kMCtrack, 4, &fg, 1.e3); // phi
Process2Darray(kMCtrack, 5, &fg); // snp PULL
Process2Darray(kMCtrack, 6, &fg, 1.e3); // theta
Process3Darray(kMCtrack, 8, &fg, 1.e2); // pt resolution
Process3Darray(kMCtrack, 9, &fg); // 1/pt pulls
Process3Darray(kMCtrack, 10, &fg, 1.e2); // p resolution
- fNRefFigures = 30;
+ fNRefFigures+=16;
// TRACK TRDin RESOLUTION/PULLS
Process3D(kMCtrackIn, 0, &fg, 1.e4);// y resolution
- Process2D(kMCtrackIn, 1, &fg); // y pulls
- Process2D(kMCtrackIn, 2, &fg, 1.e4);// z resolution
- Process2D(kMCtrackIn, 3, &fg); // z pulls
+ Process3Dlinked(kMCtrackIn, 1, &fg); // y pulls
+ Process3D(kMCtrackIn, 2, &fg, 1.e4);// z resolution
+ Process3D(kMCtrackIn, 3, &fg); // z pulls
Process2D(kMCtrackIn, 4, &fg, 1.e3);// phi resolution
Process2D(kMCtrackIn, 5, &fg); // snp pulls
Process2D(kMCtrackIn, 6, &fg, 1.e3);// theta resolution
Process3D(kMCtrackIn, 8, &fg, 1.e2);// pt resolution
Process3D(kMCtrackIn, 9, &fg); // 1/pt pulls
Process3D(kMCtrackIn, 10, &fg, 1.e2);// p resolution
- fNRefFigures = 38;
+ fNRefFigures+=8;
// TRACK TRDout RESOLUTION/PULLS
Process3D(kMCtrackOut, 0, &fg, 1.e4);// y resolution
- Process2D(kMCtrackOut, 1, &fg); // y pulls
- Process2D(kMCtrackOut, 2, &fg, 1.e4);// z resolution
- Process2D(kMCtrackOut, 3, &fg); // z pulls
+ Process3Dlinked(kMCtrackOut, 1, &fg); // y pulls
+ Process3D(kMCtrackOut, 2, &fg, 1.e4);// z resolution
+ Process3D(kMCtrackOut, 3, &fg); // z pulls
Process2D(kMCtrackOut, 4, &fg, 1.e3);// phi resolution
Process2D(kMCtrackOut, 5, &fg); // snp pulls
Process2D(kMCtrackOut, 6, &fg, 1.e3);// theta resolution
Process3D(kMCtrackOut, 8, &fg, 1.e2);// pt resolution
Process3D(kMCtrackOut, 9, &fg); // 1/pt pulls
Process3D(kMCtrackOut, 10, &fg, 1.e2);// p resolution
- fNRefFigures = 46;
+ fNRefFigures+=8;
return kTRUE;
}
arr->SetName(name); arr->SetOwner();
TH1 *h(NULL); char hname[100], htitle[300];
- const Int_t kNro(kNyresSlices), kNphi(48), kNdy(60);
- Float_t Phi=-.48, Dy=-.15, RO=-0.5;
- Float_t binsPhi[kNphi+1], binsDy[kNdy+1], binsRO[kNro+1];
- for(Int_t i=0; i<kNphi+1; i++,Phi+=.02) binsPhi[i]=Phi;
- for(Int_t i=0; i<kNdy+1; i++,Dy+=5.e-3) binsDy[i]=Dy;
- for(Int_t i=0;i<kNro+1; i++,RO+=1.) binsRO[i]=RO;
-
// tracklet resolution/pull in y direction
sprintf(hname, "%s_%s_Y", GetNameId(), name);
- sprintf(htitle, "Y res for \"%s\" @ %s;tg(#phi);#Delta y [cm];sector", GetNameId(), name);
+ sprintf(htitle, "Y res for \"%s\" @ %s;tg(#phi);#Delta y [cm];%s", GetNameId(), name, fgkResYsegmName[fgSegmentLevel]);
if(!(h = (TH3S*)gROOT->FindObject(hname))){
h = new TH3S(hname, htitle,
- kNphi, binsPhi, kNdy, binsDy, kNro, binsRO);
+ 48, -.48, .48, 60, -.15, .15, 2*fgkNresYsegm[fgSegmentLevel], -0.5, 2*fgkNresYsegm[fgSegmentLevel]-0.5);
} else h->Reset();
arr->AddAt(h, 0);
- sprintf(hname, "%s_%s_Ypull", GetNameId(), name);
- sprintf(htitle, "Y pull for \"%s\" @ %s;tg(#phi);#Delta y / #sigma_{y};entries", GetNameId(), name);
- if(!(h = (TH2I*)gROOT->FindObject(hname))){
- h = new TH2I(hname, htitle, 21, -.33, .33, 100, -4.5, 4.5);
+ sprintf(hname, "%s_%s_YZpull", GetNameId(), name);
+ sprintf(htitle, "YZ pull for \"%s\" @ %s;%s;#Delta y / #sigma_{y};#Delta z / #sigma_{z}", GetNameId(), name, fgkResYsegmName[fgSegmentLevel]);
+ if(!(h = (TH3S*)gROOT->FindObject(hname))){
+ h = new TH3S(hname, htitle, fgkNresYsegm[fgSegmentLevel], -0.5, fgkNresYsegm[fgSegmentLevel]-0.5, 100, -4.5, 4.5, 100, -4.5, 4.5);
} else h->Reset();
arr->AddAt(h, 1);
// tracklet resolution/pull in z direction
sprintf(hname, "%s_%s_Z", GetNameId(), name);
- sprintf(htitle, "Z res for \"%s\" @ %s;tg(#theta);#Delta z [cm];entries", GetNameId(), name);
- if(!(h = (TH2I*)gROOT->FindObject(hname))){
- h = new TH2I(hname, htitle, 50, -1., 1., 100, -1.5, 1.5);
+ sprintf(htitle, "Z res for \"%s\" @ %s;tg(#theta);#Delta z [cm];row cross", GetNameId(), name);
+ if(!(h = (TH3S*)gROOT->FindObject(hname))){
+ h = new TH3S(hname, htitle, 50, -1., 1., 100, -1.5, 1.5, 2, -0.5, 1.5);
} else h->Reset();
arr->AddAt(h, 2);
sprintf(hname, "%s_%s_Zpull", GetNameId(), name);
- sprintf(htitle, "Z pull for \"%s\" @ %s;tg(#theta);#Delta z / #sigma_{z};entries", GetNameId(), name);
- if(!(h = (TH2I*)gROOT->FindObject(hname))){
- h = new TH2I(hname, htitle, 50, -1., 1., 100, -5.5, 5.5);
+ sprintf(htitle, "Z pull for \"%s\" @ %s;tg(#theta);#Delta z / #sigma_{z};row cross", GetNameId(), name);
+ if(!(h = (TH3S*)gROOT->FindObject(hname))){
+ h = new TH3S(hname, htitle, 50, -1., 1., 100, -5.5, 5.5, 2, -0.5, 1.5);
+ h->GetZaxis()->SetBinLabel(1, "no RC");
+ h->GetZaxis()->SetBinLabel(2, "RC");
} else h->Reset();
arr->AddAt(h, 3);
if((n=g[1]->GetN())) for(;n--;) g[1]->RemovePoint(n);
AliDebug(4, Form("%s: g[%s %s]", pn, g[0]->GetName(), g[0]->GetTitle()));
- for(Int_t ibin = 1; ibin <= h2->GetNbinsX(); ibin++){
- Double_t x = h2->GetXaxis()->GetBinCenter(ibin);
- TH1D *h = h2->ProjectionY(pn, ibin, ibin);
+ const Int_t kINTEGRAL=1;
+ for(Int_t ibin = 0; ibin < Int_t(h2->GetNbinsX()/kINTEGRAL); ibin++){
+ Int_t abin(ibin*kINTEGRAL+1),bbin(abin+kINTEGRAL-1),mbin(abin+Int_t(kINTEGRAL/2));
+ Double_t x = h2->GetXaxis()->GetBinCenter(mbin);
+ TH1D *h = h2->ProjectionY(pn, abin, bbin);
if((n=(Int_t)h->GetEntries())<100) continue;
h->Fit(f, "QN");
TGraphErrors *g[2];
TAxis *az = h3->GetZaxis();
- for(Int_t iz=1; iz<=az->GetNbins(); iz++){
- if(!(g[0] = (TGraphErrors*)gm->At(iz-1))) return kFALSE;
- if(!(g[1] = (TGraphErrors*)gs->At(iz-1))) return kFALSE;
- az->SetRange(iz, iz);
+ for(Int_t iz(0); iz<gm->GetEntriesFast(); iz++){
+ if(!(g[0] = (TGraphErrors*)gm->At(iz))) return kFALSE;
+ if(!(g[1] = (TGraphErrors*)gs->At(iz))) return kFALSE;
+ az->SetRange(iz+1, iz+1);
if(!Process((TH2*)h3->Project3D("yx"), f, k, g)) return kFALSE;
}
}
+//________________________________________________________
+Bool_t AliTRDresolution::Process3Dlinked(ETRDresolutionPlot plot, Int_t idx, TF1 *f, Float_t k)
+{
+ //
+ // Do the processing
+ //
+
+ if(!fContainer || !fGraphS || !fGraphM) return kFALSE;
+
+ // retrive containers
+ TH3S *h3(NULL);
+ if(idx<0){
+ if(!(h3= (TH3S*)(fContainer->At(plot)))) return kFALSE;
+ } else{
+ TObjArray *a0(NULL);
+ if(!(a0=(TObjArray*)(fContainer->At(plot)))) return kFALSE;
+ if(!(h3=(TH3S*)a0->At(idx))) return kFALSE;
+ }
+ AliDebug(2, Form("p[%d] idx[%d] h[%s] %s", plot, idx, h3->GetName(), h3->GetTitle()));
+
+ TObjArray *gm, *gs;
+ if(!(gm = (TObjArray*)((TObjArray*)(fGraphM->At(plot)))->At(idx))) return kFALSE;
+ if(!(gs = (TObjArray*)((TObjArray*)(fGraphS->At(plot)))->At(idx))) return kFALSE;
+ TGraphErrors *g[2];
+
+ if(!(g[0] = (TGraphErrors*)gm->At(0))) return kFALSE;
+ if(!(g[1] = (TGraphErrors*)gs->At(0))) return kFALSE;
+ if(!Process((TH2*)h3->Project3D("yx"), f, k, g)) return kFALSE;
+
+ if(!(g[0] = (TGraphErrors*)gm->At(1))) return kFALSE;
+ if(!(g[1] = (TGraphErrors*)gs->At(1))) return kFALSE;
+ if(!Process((TH2*)h3->Project3D("zx"), f, k, g)) return kFALSE;
+
+ return kTRUE;
+}
+
+
//________________________________________________________
Bool_t AliTRDresolution::Process3DL(ETRDresolutionPlot plot, Int_t idx, TF1 *f, Float_t k)
{
AliDebug(4, Form(" idx[%d] h[%s] %s", ia, h3->GetName(), h3->GetTitle()));
TAxis *az = h3->GetZaxis();
for(Int_t iz=1; iz<=az->GetNbins(); iz++, in++){
+ if(in >= gm->GetEntriesFast()) break;
if(!(g[0] = (TGraphErrors*)gm->At(in))) return kFALSE;
if(!(g[1] = (TGraphErrors*)gs->At(in))) return kFALSE;
az->SetRange(iz, iz);
return kTRUE;
}
+//________________________________________________________
+Bool_t AliTRDresolution::Process3DlinkedArray(ETRDresolutionPlot plot, Int_t idx, TF1 *f, Float_t k)
+{
+ //
+ // Do the processing
+ //
+
+ if(!fContainer || !fGraphS || !fGraphM) return kFALSE;
+ //printf("Process4D : processing plot[%d] idx[%d]\n", plot, idx);
+
+ // retrive containers
+ TObjArray *arr = (TObjArray*)(fContainer->At(plot));
+ if(!arr) return kFALSE;
+ AliDebug(2, Form("p[%d] idx[%d] arr[%s]", plot, idx, arr->GetName()));
+
+ TObjArray *gm, *gs;
+ if(!(gm = (TObjArray*)((TObjArray*)(fGraphM->At(plot)))->At(idx))) return kFALSE;
+ if(!(gs = (TObjArray*)((TObjArray*)(fGraphS->At(plot)))->At(idx))) return kFALSE;
+
+ TGraphErrors *g[2]; TH3S *h3(NULL); TObjArray *a0(NULL);
+ Int_t in(0);
+ for(Int_t ia(0); ia<arr->GetEntriesFast(); ia++){
+ if(!(a0 = (TObjArray*)arr->At(ia))) continue;
+ if(!(h3 = (TH3S*)a0->At(idx))) return kFALSE;
+ AliDebug(4, Form(" idx[%d] h[%s] %s", ia, h3->GetName(), h3->GetTitle()));
+ if(!(g[0] = (TGraphErrors*)gm->At(in))) return kFALSE;
+ if(!(g[1] = (TGraphErrors*)gs->At(in))) return kFALSE;
+ if(!Process((TH2*)h3->Project3D("yx"), f, k, g)) return kFALSE;
+ in++;
+
+ if(!(g[0] = (TGraphErrors*)gm->At(in))) return kFALSE;
+ if(!(g[1] = (TGraphErrors*)gs->At(in))) return kFALSE;
+ if(!Process((TH2*)h3->Project3D("zx"), f, k, g)) return kFALSE;
+ in++;
+ }
+ AliDebug(2, Form("Projections [%d] from [%d]", in, gs->GetEntriesFast()));
+
+ return kTRUE;
+}
+
//________________________________________________________
Bool_t AliTRDresolution::GetGraph(Float_t *bb, ETRDresolutionPlot ip, Int_t idx, Bool_t kLEG, const Char_t *explain)
{
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff