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14 **************************************************************************/
16 //-------------------------------------------------------------------------
17 // Implementation of the cascade vertexer class
18 // Reads V0s and tracks, writes out cascade vertices
19 // Fills the ESD with the cascades
20 // Origin: Christian Kuhn, IReS, Strasbourg, christian.kuhn@ires.in2p3.fr
21 //-------------------------------------------------------------------------
23 //modified by R. Vernet 30/6/2006 : daughter label
24 //modified by R. Vernet 3/7/2006 : causality
25 //modified by I. Belikov 24/11/2006 : static setter for the default cuts
27 #include "AliESDEvent.h"
28 #include "AliESDcascade.h"
29 #include "AliCascadeVertexer.h"
31 ClassImp(AliCascadeVertexer)
35 AliCascadeVertexer::fgChi2max=33.; //maximal allowed chi2
37 AliCascadeVertexer::fgDV0min=0.05; //min V0 impact parameter
39 AliCascadeVertexer::fgMassWin=0.01; //"window" around the Lambda mass
41 AliCascadeVertexer::fgDBachMin=0.035; //min bachelor impact parameter
43 AliCascadeVertexer::fgDCAmax=0.10; //max DCA between the V0 and the track
45 AliCascadeVertexer::fgCPAmin=0.9985; //min cosine of the cascade pointing angle
47 AliCascadeVertexer::fgRmin=0.2; //min radius of the fiducial volume
49 AliCascadeVertexer::fgRmax=100.; //max radius of the fiducial volume
52 Int_t AliCascadeVertexer::V0sTracks2CascadeVertices(AliESDEvent *event) {
53 //--------------------------------------------------------------------
54 // This function reconstructs cascade vertices
55 // Adapted to the ESD by I.Belikov (Jouri.Belikov@cern.ch)
56 //--------------------------------------------------------------------
57 const AliESDVertex *vtxT3D=event->GetPrimaryVertex();
59 Double_t xPrimaryVertex=vtxT3D->GetXv();
60 Double_t yPrimaryVertex=vtxT3D->GetYv();
61 Double_t zPrimaryVertex=vtxT3D->GetZv();
63 Double_t b=event->GetMagneticField();
64 Int_t nV0=(Int_t)event->GetNumberOfV0s();
66 //stores relevant V0s in an array
69 for (i=0; i<nV0; i++) {
70 AliESDv0 *v=event->GetV0(i);
71 if (v->GetOnFlyStatus()) continue;
72 if (v->GetD(xPrimaryVertex,yPrimaryVertex,zPrimaryVertex)<fDV0min) continue;
75 nV0=vtcs.GetEntriesFast();
77 // stores relevant tracks in another array
78 Int_t nentr=(Int_t)event->GetNumberOfTracks();
79 TArrayI trk(nentr); Int_t ntr=0;
80 for (i=0; i<nentr; i++) {
81 AliESDtrack *esdtr=event->GetTrack(i);
82 ULong_t status=esdtr->GetStatus();
84 if ((status&AliESDtrack::kITSrefit)==0)
85 if ((status&AliESDtrack::kTPCrefit)==0) continue;
87 if (TMath::Abs(esdtr->GetD(xPrimaryVertex,yPrimaryVertex,b))<fDBachMin) continue;
92 Double_t massLambda=1.11568;
95 // Looking for the cascades...
97 for (i=0; i<nV0; i++) { //loop on V0s
99 AliESDv0 *v=(AliESDv0*)vtcs.UncheckedAt(i);
100 v->ChangeMassHypothesis(kLambda0); // the v0 must be Lambda
101 if (TMath::Abs(v->GetEffMass()-massLambda)>fMassWin) continue;
103 for (Int_t j=0; j<ntr; j++) {//loop on tracks
105 //Bo: if (bidx==v->GetNindex()) continue; //bachelor and v0's negative tracks must be different
106 if (bidx==v->GetIndex(0)) continue; //Bo: consistency 0 for neg
107 AliESDtrack *btrk=event->GetTrack(bidx);
108 if (btrk->GetSign()>0) continue; // bachelor's charge
110 AliESDv0 v0(*v), *pv0=&v0;
111 AliExternalTrackParam bt(*btrk), *pbt=&bt;
113 Double_t dca=PropagateToDCA(pv0,pbt,b);
114 if (dca > fDCAmax) continue;
116 AliESDcascade cascade(*pv0,*pbt,bidx);//constucts a cascade candidate
117 //PH if (cascade.GetChi2Xi() > fChi2max) continue;
119 Double_t x,y,z; cascade.GetXYZcascade(x,y,z); // Bo: bug correction
120 Double_t r2=x*x + y*y;
121 if (r2 > fRmax*fRmax) continue; // condition on fiducial zone
122 if (r2 < fRmin*fRmin) continue;
124 Double_t pxV0,pyV0,pzV0;
125 pv0->GetPxPyPz(pxV0,pyV0,pzV0);
126 if (x*pxV0+y*pyV0+z*pzV0 < 0) continue; //causality
128 Double_t x1,y1,z1; pv0->GetXYZ(x1,y1,z1);
129 if (r2 > (x1*x1+y1*y1)) continue;
131 if (cascade.GetCascadeCosineOfPointingAngle(xPrimaryVertex,yPrimaryVertex,zPrimaryVertex) <fCPAmin) continue; //condition on the cascade pointing angle
133 cascade.SetDcaXiDaughters(dca);
134 event->AddCascade(&cascade);
139 // Looking for the anti-cascades...
141 for (i=0; i<nV0; i++) { //loop on V0s
142 AliESDv0 *v=(AliESDv0*)vtcs.UncheckedAt(i);
143 v->ChangeMassHypothesis(kLambda0Bar); //the v0 must be anti-Lambda
144 if (TMath::Abs(v->GetEffMass()-massLambda)>fMassWin) continue;
146 for (Int_t j=0; j<ntr; j++) {//loop on tracks
148 //Bo: if (bidx==v->GetPindex()) continue; //bachelor and v0's positive tracks must be different
149 if (bidx==v->GetIndex(1)) continue; //Bo: consistency 1 for pos
150 AliESDtrack *btrk=event->GetTrack(bidx);
151 if (btrk->GetSign()<0) continue; // bachelor's charge
153 AliESDv0 v0(*v), *pv0=&v0;
154 AliESDtrack bt(*btrk), *pbt=&bt;
156 Double_t dca=PropagateToDCA(pv0,pbt,b);
157 if (dca > fDCAmax) continue;
159 AliESDcascade cascade(*pv0,*pbt,bidx); //constucts a cascade candidate
160 //PH if (cascade.GetChi2Xi() > fChi2max) continue;
162 Double_t x,y,z; cascade.GetXYZcascade(x,y,z); // Bo: bug correction
163 Double_t r2=x*x + y*y;
164 if (r2 > fRmax*fRmax) continue; // condition on fiducial zone
165 if (r2 < fRmin*fRmin) continue;
167 Double_t pxV0,pyV0,pzV0;
168 pv0->GetPxPyPz(pxV0,pyV0,pzV0);
169 if (x*pxV0+y*pyV0+z*pzV0 < 0) continue; //causality
171 Double_t x1,y1,z1; pv0->GetXYZ(x1,y1,z1);
172 if (r2 > (x1*x1+y1*y1)) continue;
174 if (cascade.GetCascadeCosineOfPointingAngle(xPrimaryVertex,yPrimaryVertex,zPrimaryVertex) < fCPAmin) continue; //condition on the cascade pointing angle
176 cascade.SetDcaXiDaughters(dca);
177 event->AddCascade(&cascade);
183 Info("V0sTracks2CascadeVertices","Number of reconstructed cascades: %d",ncasc);
189 Double_t AliCascadeVertexer::Det(Double_t a00, Double_t a01, Double_t a10, Double_t a11) const {
190 //--------------------------------------------------------------------
191 // This function calculates locally a 2x2 determinant
192 //--------------------------------------------------------------------
193 return a00*a11 - a01*a10;
196 Double_t AliCascadeVertexer::Det(Double_t a00,Double_t a01,Double_t a02,
197 Double_t a10,Double_t a11,Double_t a12,
198 Double_t a20,Double_t a21,Double_t a22) const {
199 //--------------------------------------------------------------------
200 // This function calculates locally a 3x3 determinant
201 //--------------------------------------------------------------------
202 return a00*Det(a11,a12,a21,a22)-a01*Det(a10,a12,a20,a22)+a02*Det(a10,a11,a20,a21);
208 Double_t AliCascadeVertexer::PropagateToDCA(AliESDv0 *v, AliExternalTrackParam *t, Double_t b) {
209 //--------------------------------------------------------------------
210 // This function returns the DCA between the V0 and the track
211 //--------------------------------------------------------------------
212 Double_t alpha=t->GetAlpha(), cs1=TMath::Cos(alpha), sn1=TMath::Sin(alpha);
213 Double_t r[3]; t->GetXYZ(r);
214 Double_t x1=r[0], y1=r[1], z1=r[2];
215 Double_t p[3]; t->GetPxPyPz(p);
216 Double_t px1=p[0], py1=p[1], pz1=p[2];
218 Double_t x2,y2,z2; // position and momentum of V0
219 Double_t px2,py2,pz2;
222 v->GetPxPyPz(px2,py2,pz2);
226 Double_t dd= Det(x2-x1,y2-y1,z2-z1,px1,py1,pz1,px2,py2,pz2);
227 Double_t ax= Det(py1,pz1,py2,pz2);
228 Double_t ay=-Det(px1,pz1,px2,pz2);
229 Double_t az= Det(px1,py1,px2,py2);
231 Double_t dca=TMath::Abs(dd)/TMath::Sqrt(ax*ax + ay*ay + az*az);
234 Double_t t1 = Det(x2-x1,y2-y1,z2-z1,px2,py2,pz2,ax,ay,az)/
235 Det(px1,py1,pz1,px2,py2,pz2,ax,ay,az);
237 x1 += px1*t1; y1 += py1*t1; //z1 += pz1*t1;
240 //propagate track to the points of DCA
243 if (!t->PropagateTo(x1,b)) {
244 Error("PropagateToDCA","Propagation failed !");