#include <TRefArray.h>
#include "AliMCParticle.h"
+#include "AliExternalTrackParam.h"
ClassImp(AliMCParticle)
fParticle(0),
fTrackReferences(0),
fNTrackRef(0),
- fLabel(-1)
+ fLabel(-1),
+ fMother(-1),
+ fFirstDaughter(-1),
+ fLastDaughter(-1)
{
// Constructor
}
fParticle(part),
fTrackReferences(rarray),
fNTrackRef(0),
- fLabel(index)
+ fLabel(index),
+ fMother(-1),
+ fFirstDaughter(-1),
+ fLastDaughter(-1)
{
// Constructor
if (rarray != 0) {
fParticle(0),
fTrackReferences(0),
fNTrackRef(0),
- fLabel(-1)
+ fLabel(-1),
+ fMother(-1),
+ fFirstDaughter(-1),
+ fLastDaughter(-1)
{
// Copy constructor
}
AliMCParticle& AliMCParticle::operator=(const AliMCParticle& mcPart)
{
-
+// Copy constructor
if (this!=&mcPart) {
AliVParticle::operator=(mcPart);
}
+Float_t AliMCParticle::GetTPCTrackLength(Float_t bz, Float_t ptmin, Int_t &counter, Float_t deadWidth){
+ //
+ // return track length in geometrically active volume of TPC.
+ // z nad rphi acceptance is included
+ // doesn't take into account dead channel and ExB
+ // Intput:
+ // trackRefs
+ // bz - magnetic field
+ // deadWidth - dead zone in r-phi
+ // Additional output:
+ // counter - number of circles
+
+ if (fNTrackRef == 0) return 0.;
+
+ const Float_t kRMin = 90;
+ const Float_t kRMax = 245;
+ const Float_t kZMax = 250;
+ const Float_t kMinPt= ptmin;
+
+ Float_t length =0;
+ Int_t nrefs = fNTrackRef;
+
+
+ AliExternalTrackParam param;
+ Double_t cv[21];
+ for (Int_t i = 0; i < 21; i++) cv[i]=0;
+ counter=0;
+ //
+ //
+
+ AliTrackReference *ref0 = (AliTrackReference*) (fTrackReferences->At(0));
+ Float_t direction = 0;
+ //
+ for (Int_t iref = 1; iref < nrefs; iref++){
+ AliTrackReference *ref = (AliTrackReference*) (fTrackReferences->At(iref));
+ if (!ref) continue;
+ if (!ref0 || ref0->DetectorId()!= AliTrackReference::kTPC){
+ ref0 = ref;
+ direction = ((ref0->X() * ref0->Px() + ref0->Y() * ref0->Py()) > 0)? 1. : -1.;
+ continue;
+ }
+
+ Float_t newdirection = ((ref->X() * ref->Px() + ref->Y() * ref->Py()) > 0)? 1. : -1.;
+ if (newdirection*direction<0) {
+ counter++; //circle counter
+ direction = newdirection;
+ continue;
+ }
+ if (counter>0) continue;
+ if (ref0->Pt() < kMinPt) break;
+ Float_t radius0 = TMath::Max(TMath::Min(ref0->R(),kRMax),kRMin);;
+ Float_t radius1 = TMath::Max(TMath::Min(ref->R(),kRMax),kRMin);
+ Double_t xyz[3] = {ref0->X(), ref0->Y(), ref0->Z()};
+ Double_t pxyz[3]= {ref0->Px(), ref0->Py(), ref0->Pz()};
+ Double_t alpha;
+ param.Set(xyz,pxyz,cv,TMath::Nint(fParticle->GetPDG()->Charge()/3.));
+
+ for (Float_t radius = radius0; radius < radius1; radius+=1){
+ param.GetXYZAt(radius, bz, xyz);
+ if (TMath::Abs(xyz[2]) > kZMax) continue;
+ Float_t gradius = TMath::Sqrt(xyz[1] * xyz[1] + xyz[0] * xyz[0]);
+ if (gradius > kRMax) continue;
+ alpha = TMath::ATan2(xyz[1],xyz[0]);
+ if (alpha<0) alpha += TMath::TwoPi();
+ //
+ Int_t sector = Int_t(9 * alpha / TMath::Pi());
+ Float_t lalpha = alpha - ((sector + 0.5) * TMath::Pi() / 9.);
+ Float_t dedge = (TMath::Tan(TMath::Pi() / 18.) - TMath::Abs(TMath::Tan(lalpha))) * gradius;
+ if (dedge>deadWidth) length++;
+ }
+ if (ref->DetectorId()!= AliTrackReference::kTPC) break;
+ ref0 = ref;
+ }
+ return length;
+}