memory consumption measures only memory used by preprocessor
[u/mrichter/AliRoot.git] / PWG3 / vertexingOld / AliD0toKpi.h
1 #ifndef AliD0toKpi_H
2 #define AliD0toKpi_H
3 /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4  * See cxx source for full Copyright notice                               */
5
6 //-------------------------------------------------------------------------
7 //                          Class AliD0toKpi
8 //                 Reconstructed D0 -> K^- pi^+ class
9 //      
10 // Note: the two decay tracks are labelled: 0 (positive track)
11 //                                          1 (negative track)
12 //
13 //         Origin: A. Dainese    andrea.dainese@lnl.infn.it                  
14 //-------------------------------------------------------------------------
15
16 #include <TObject.h>
17 #include <TMath.h>
18 #include <TString.h>
19
20 //----------------------------------------------------------------------------
21 //     Some constants (masses + parameterized TOF PID)
22 //
23 // particle masses
24 const Double_t kMD0 = 1.8645;  // D0  mass
25 const Double_t kMK  = 0.49368; // K+  mass
26 const Double_t kMPi = 0.13957; // pi+ mass
27
28 //  --- TOF tagging probabilities --- 
29 //  central HIJING
30 //  B = 0.4 T
31 //  tracking errors in TPC included
32 //  With TRD
33 //
34 //  *** Pb-Pb dNch/dy=6000 *** 
35 //
36 //  PIONS
37 const Int_t kPiBinsPbPb = 10;
38 const Double_t kPiBinWidthPbPb = 0.250;
39 const Double_t kPiTagPiPbPb[kPiBinsPbPb] = {0.211421,0.652184,0.624421,0.614727,0.610777,0.628015,0.631520,0.630324,0.637551,0.575235};
40 const Double_t kPiTagNidPbPb[kPiBinsPbPb] = {0.788579,0.347816,0.375579,0.385273,0.389223,0.371985,0.368480,0.369676,0.362449,0.424765};
41 //  KAONS
42 const Int_t kKBinsPbPb = 10;
43 const Double_t kKBinWidthPbPb = 0.250;
44 const Double_t kKTagKPbPb[kKBinsPbPb] = {0.000000,0.101255,0.397662,0.467586,0.517008,0.555023,0.584185,0.519029,0.464117,0.247308};
45 const Double_t kKTagPiPbPb[kKBinsPbPb] = {0.102049,0.289930,0.101930,0.057771,0.040286,0.028567,0.053108,0.094369,0.066302,0.247308};
46 const Double_t kKTagNidPbPb[kKBinsPbPb] = {0.897951,0.608815,0.500408,0.474643,0.442705,0.416410,0.362707,0.386603,0.469580,0.505383};
47 //  PROTONS
48 const Int_t kPBinsPbPb = 9;
49 const Double_t kPBinWidthPbPb = 0.500;
50 const Double_t kPTagPPbPb[kPBinsPbPb] = {0.017940,0.350681,0.535286,0.583264,0.562935,0.560524,0.545992,0.598060,0.351245};
51 const Double_t kPTagPiPbPb[kPBinsPbPb] = {0.195955,0.094949,0.039962,0.026039,0.007556,0.016986,0.030333,0.000000,0.000000};
52 const Double_t kPTagNidPbPb[kPBinsPbPb] = {0.786105,0.554370,0.424751,0.390697,0.429508,0.422491,0.423675,0.401940,0.648755};
53 //
54 // pp PYTHIA 
55 //
56 // *** cuts for pp ***
57 //
58 //  PIONS
59 const Int_t kPiBinsPP = 10;
60 const Double_t kPiBinWidthPP = 0.250;
61 const Double_t kPiTagPiPP[kPiBinsPP] = {0.194528,0.447097,0.603364,0.646413,0.647125,0.669157,0.688139,0.682564,0.689910,0.665710};
62 const Double_t kPiTagNidPP[kPiBinsPP] = {0.805472,0.552903,0.396636,0.353587,0.352875,0.330843,0.311861,0.317436,0.310090,0.334290};
63 //  KAONS
64 const Int_t kKBinsPP = 10;
65 const Double_t kKBinWidthPP = 0.250;
66 const Double_t kKTagKPP[kKBinsPP] = {0.000000,0.173393,0.439690,0.519423,0.587025,0.605372,0.586021,0.650139,0.444444,0.299363};
67 const Double_t kKTagPiPP[kKBinsPP] = {0.000000,0.001495,0.000000,-0.000000,-0.000000,0.000000,0.032258,0.060572,0.101449,0.242038};
68 const Double_t kKTagNidPP[kKBinsPP] = {1.000000,0.825112,0.560310,0.480577,0.412975,0.394628,0.381720,0.289289,0.454106,0.458599};
69 //  PROTONS
70 const Int_t kPBinsPP = 9;
71 const Double_t kPBinWidthPP = 0.500;
72 const Double_t kPTagPPP[kPBinsPP] = {0.029404,0.438640,0.613710,0.665152,0.634961,0.657711,0.703704,0.685714,0.235294};
73 const Double_t kPTagPiPP[kPBinsPP] = {0.000000,0.000000,0.000000,-0.000000,0.000000,0.000000,-0.000000,0.014286,-0.000000};
74 const Double_t kPTagNidPP[kPBinsPP] = {0.970596,0.561360,0.386290,0.334848,0.365039,0.342289,0.296296,0.300000,0.764706};
75
76
77
78
79 //-----------------------------------------------------------------------------
80 class AliD0toKpi : public TObject {
81  public:
82   //
83   AliD0toKpi();
84   AliD0toKpi(Int_t ev,Int_t trkNum[2],  
85              Double_t v1[3],Double_t v2[3],Double_t dca,
86              Double_t mom[6],Double_t d0[2]);
87   virtual ~AliD0toKpi();
88
89   Double_t Alpha() const { return (Ql(0)-Ql(1))/(Ql(0)+Ql(1)); }
90   void     ApplyPID(TString pidScheme="TOFparamPbPb");
91   Double_t ChildrenRelAngle() const; 
92   void     ComputeWgts();
93   void     CorrectWgt4BR(Double_t factor);
94   Double_t CosPointing() const;
95   Double_t CosPointingXY() const;
96   void     CosThetaStar(Double_t &ctsD0,Double_t &ctsD0bar) const;
97   Double_t Ct() const {return Length()*kMD0/P();}
98   Double_t Energy() const { return TMath::Sqrt(P()*P()+kMD0*kMD0); }
99   Double_t Eta() const;
100   Double_t EtaChild(Int_t child) const;
101   Int_t    EventNo() const {return TMath::Abs(fEvent);}
102   Double_t GetDCA() const { return 10000.*fDCA; }
103   Int_t    GetTrkNum(Int_t child) const { return fTrkNum[child]; }
104   Double_t Getd0Child(Int_t child) const { return fd0[child]; }
105   Int_t    GetPdgChild(Int_t child) const { return fPdg[child]; }
106   Int_t    GetPdgMum(Int_t child) const {return fMum[child]; }
107   void     GetWgts(Double_t &WgtD0,Double_t &WgtD0bar,TString sample) const;
108   void     GetPrimaryVtx(Double_t vtx[3]) const 
109     { vtx[0]=fV1x; vtx[1]=fV1y; vtx[2]=fV1z; }
110   void     GetSecondaryVtx(Double_t vtx[3]) const 
111     { vtx[0]=fV2x; vtx[1]=fV2y; vtx[2]=fV2z; }
112
113   Double_t ImpPar() const;
114   void     InvMass(Double_t &mD0,Double_t &mD0bar) const;
115   Bool_t   IsSignal() const { if(fSignal) return kTRUE; return kFALSE; } 
116   Double_t Length() const
117     { return TMath::Sqrt((fV1x-fV2x)*(fV1x-fV2x)
118                          +(fV1y-fV2y)*(fV1y-fV2y)+(fV1z-fV2z)*(fV1z-fV2z)); }
119   Double_t P()  const { return TMath::Sqrt(Pt()*Pt()+Pz()*Pz()); } 
120   Double_t PChild(Int_t child)   const { return TMath::Sqrt(fPx[child]*fPx[child]+fPy[child]*fPy[child]+fPz[child]*fPz[child]); } 
121   Double_t ProdImpParams() const { return fd0[0]*fd0[1]; } 
122   Double_t Pt() const { return TMath::Sqrt(Px()*Px()+Py()*Py()); }
123   Double_t PtChild(Int_t child)  const { return TMath::Sqrt(fPx[child]*fPx[child]+fPy[child]*fPy[child]); } 
124   Double_t Px() const { return (fPx[0]+fPx[1]); }
125   Double_t Py() const { return (fPy[0]+fPy[1]); }
126   Double_t Pz() const { return (fPz[0]+fPz[1]); }
127   Double_t Ql(Int_t child) const;
128   Double_t Qt() const;
129   Double_t Rapidity() const { return 0.5*TMath::Log((Energy()+Pz())/(Energy()-Pz()+1.e-13)); }
130   Bool_t   Select(const Double_t* cuts,Int_t& okD0,Int_t& okD0bar) const;
131   void     SetPrimaryVtx(Double_t vtx[3]) 
132     { fV1x=vtx[0]; fV1y=vtx[1]; fV1z=vtx[2]; }
133   void     SetSignal() { fSignal =  kTRUE; }
134   void     SetTOFmasses(Double_t mass[2]) 
135     { fTOFmass[0]=mass[0]; fTOFmass[1]=mass[1]; }
136   void     SetPIDresponse(Double_t resp0[5],Double_t resp1[5]); 
137   void     SetPdgCodes(Int_t pdg[2]) {fPdg[0]=pdg[0];fPdg[1]=pdg[1]; }
138   void     SetMumPdgCodes(Int_t mum[2]) {fMum[0]=mum[0];fMum[1]=mum[1]; }
139   Double_t LinearInterpolation(Double_t p,Int_t nBins,Double_t Bin,
140                                const Double_t *values) const;
141   //
142  private:
143   //
144   Bool_t   fSignal; // TRUE if signal, FALSE if background (for simulation)
145   Int_t    fEvent;  // number of the event this D0 comes from
146                     // -1 if the D0 comes from ev. mixing
147
148   Int_t fTrkNum[2]; // numbers of the two decay tracks
149
150   Double_t fV1x; // X-position of the primary vertex of the event
151   Double_t fV1y; // Y-position of the primary vertex of the event
152   Double_t fV1z; // Z-position of the primary vertex of the event
153   Double_t fV2x; // X-position of the reconstructed secondary vertex
154   Double_t fV2y; // Y-position of the reconstructed secondary vertex
155   Double_t fV2z; // Z-position of the reconstructed secondary vertex
156   Double_t fDCA; // DCA of the two tracks
157
158   Double_t fPx[2];  // X,Y,Z
159   Double_t fPy[2];  // momenta of the two tracks
160   Double_t fPz[2];  // at the reconstructed vertex  
161
162   Double_t fd0[2];  //  impact parameters in the bending plane
163
164   Int_t fPdg[2];  // PDG codes of the two tracks (for sim.)
165   Int_t fMum[2];  // PDG codes of the mothers    (for sim.)
166
167   Double_t fTagPi[2];  // probability to be tagged as pion 
168   Double_t fTagKa[2];  // probability to be tagged as kaon 
169   Double_t fTagPr[2];  // probability to be tagged as proton 
170   Double_t fTagNid[2]; // probability to be tagged as "non-identified" 
171
172   Double_t fPIDrespEl[2]; // det. response to be electron
173   Double_t fPIDrespMu[2]; // det. response to be muon
174   Double_t fPIDrespPi[2]; // det. response to be pion
175   Double_t fPIDrespKa[2]; // det. response to be kaon
176   Double_t fPIDrespPr[2]; // det. response to be proton
177   Double_t fTOFmass[2]; // mass estimated by the TOF (-1000. if track not reached TOF)
178
179   Double_t fWgtAD0,fWgtAD0bar; // weights for the 3 samples
180   Double_t fWgtBD0,fWgtBD0bar; // weights for the 3 samples 
181   Double_t fWgtCD0,fWgtCD0bar; // A: (K,Pi)+(K,?) B: (?,Pi) C: (?,?)
182   Double_t fWgtDD0,fWgtDD0bar; // D: all other pairs
183
184   ClassDef(AliD0toKpi,1)  // Reconstructed D0 candidate class
185 };
186
187 #endif
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