1 #ifndef ALIBTOJPSITOELECDFFITFCN_H
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2 #define ALIBTOJPSITOELECDFFITFCN_H
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3 /* Copyright(c) 1998-2009, ALICE Experiment at CERN, All rights reserved. *
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4 * See cxx source for full Copyright notice */
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6 //_________________________________________________________________________
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7 // Class AliBtoJPSItoEleCDFfitFCN
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8 // Definition of main function used in
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9 // unbinned log-likelihood fit for
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10 // the channel B -> JPsi + X -> e+e- + X
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12 // Origin: C.Di Giglio
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13 // Contact: Carmelo.Digiglio@ba.infn.it , Giuseppe.Bruno@ba.infn.it
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14 //_________________________________________________________________________
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17 #include <TDatabasePDG.h>
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20 #include "TRandom3.h"
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22 enum IntegralType {kBkg,
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27 enum PtBins {kallpt,
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28 kptbin1,kptbin2,kptbin3,
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29 kptbin4,kptbin5,kptbin6,
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30 kptbin7,kptbin8,kptbin9};
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31 //_________________________________________________________________________________________________
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32 class AliBtoJPSItoEleCDFfitFCN : public TNamed {
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35 AliBtoJPSItoEleCDFfitFCN();
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36 AliBtoJPSItoEleCDFfitFCN(const AliBtoJPSItoEleCDFfitFCN& source);
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37 AliBtoJPSItoEleCDFfitFCN& operator=(const AliBtoJPSItoEleCDFfitFCN& source);
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38 virtual ~AliBtoJPSItoEleCDFfitFCN();
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40 Double_t EvaluateLikelihood(const Double_t* pseudoproperdecaytime,
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41 const Double_t* invariantmass, const Int_t ncand);
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43 Double_t GetFPlus() const { return fFPlus; }
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44 Double_t GetFMinus() const { return fFMinus; }
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45 Double_t GetFSym() const { return fFSym; }
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46 Double_t GetRadius() const { return fParameters[0]; }
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47 Double_t GetTheta() const { return fParameters[1]; }
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48 Double_t GetPhi() const { return fParameters[2]; }
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49 Double_t GetLamPlus() const { return fParameters[3]; }
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50 Double_t GetLamMinus() const { return fParameters[4]; }
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51 Double_t GetLamSym() const { return fParameters[5]; }
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52 Double_t GetMassSlope() const { return fParameters[6]; }
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53 Double_t GetFractionJpsiFromBeauty() const { return fParameters[7]; }
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54 Double_t GetFsig() const { return fParameters[8]; }
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55 Double_t GetCrystalBallMmean() const { return fParameters[9]; }
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56 Double_t GetCrystalBallNexp() const { return fParameters[10]; }
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57 Double_t GetCrystalBallSigma() const { return fParameters[11]; }
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58 Double_t GetCrystalBallAlpha() const { return fParameters[12]; }
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59 Double_t GetCrystalBallNorm() const { return fParameters[13]; }
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60 Double_t GetSigmaResol() const { return fParameters[14]; }
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61 Double_t GetNResol() const { return fParameters[15]; }
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62 Double_t GetIntegral() const { return fIntegral; }
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63 Double_t GetIntegralFunB() const { return fintxFunB; }
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64 Double_t GetIntegralBkgPos() const { return fintxDecayTimeBkgPos; }
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65 Double_t GetIntegralBkgNeg() const { return fintxDecayTimeBkgNeg; }
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66 Double_t GetIntegralBkgSym() const { return fintxDecayTimeBkgSym; }
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67 Double_t GetIntegralMassSig() const { return fintmMassSig; }
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68 Double_t GetIntegralRes() const { return fintxRes; }
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69 Double_t GetIntegralMassBkg() const { return fintmMassBkg; }
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70 Bool_t GetCrystalBallParam() const { return fCrystalBallParam; }
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72 void SetFPlus(Double_t plus) {fFPlus = plus;}
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73 void SetFMinus(Double_t minus) {fFMinus = minus;}
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74 void SetFSym(Double_t sym) {fFSym = sym;}
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75 void SetRadius(Double_t radius) {fParameters[0] = radius;}
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76 void SetTheta(Double_t theta) {fParameters[1] = theta;}
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77 void SetPhi(Double_t phi) {fParameters[2] = phi;}
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78 void SetLamPlus(Double_t lamplus) {fParameters[3] = lamplus;}
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79 void SetLamMinus(Double_t lamminus) {fParameters[4] = lamminus;}
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80 void SetLamSym(Double_t lamsym) {fParameters[5] = lamsym;}
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81 void SetMassSlope(Double_t slope) {fParameters[6] = slope;}
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82 void SetFractionJpsiFromBeauty(Double_t B) {fParameters[7] = B;}
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83 void SetFsig(Double_t Fsig) {fParameters[8] = Fsig;}
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84 void SetCrystalBallMmean(Double_t CrystalBallMmean) {fParameters[9] = CrystalBallMmean;}
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85 void SetCrystalBallNexp(Double_t CrystalBallNexp) {fParameters[10] = CrystalBallNexp;}
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86 void SetCrystalBallSigma(Double_t CrystalBallSigma) {fParameters[11] = CrystalBallSigma;}
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87 void SetCrystalBallAlpha(Double_t CrystalBallAlpha) {fParameters[12] = CrystalBallAlpha;}
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88 void SetCrystalBallNorm(Double_t CrystalBallNorm) {fParameters[13] = CrystalBallNorm;}
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89 void SetSigmaResol(Double_t SigmaResol) {fParameters[14] = SigmaResol;}
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90 void SetNResol(Double_t NResol) {fParameters[15] = NResol;}
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92 void SetAllParameters(const Double_t* parameters);
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93 void SetIntegral(Double_t integral) { fIntegral = integral; }
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94 void SetIntegralFunB(Double_t integral) { fintxFunB = integral; }
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95 void SetIntegralBkgPos(Double_t integral) { fintxDecayTimeBkgPos = integral; }
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96 void SetIntegralBkgNeg(Double_t integral) { fintxDecayTimeBkgNeg = integral; }
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97 void SetIntegralBkgSym(Double_t integral) { fintxDecayTimeBkgSym = integral; }
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98 void SetIntegralMassSig(Double_t integral) { fintmMassSig = integral; }
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99 void SetIntegralRes(Double_t integral) { fintxRes = integral; }
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100 void SetIntegralMassBkg(Double_t integral) { fintmMassBkg = integral; }
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102 void SetCsiMC(const TH1F* MCtemplate) {fhCsiMC = (TH1F*)MCtemplate->Clone("fhCsiMC");}
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104 void SetResolutionConstants();
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105 void SetMassWndHigh(Double_t limit) { fMassWndHigh = TDatabasePDG::Instance()->GetParticle(443)->Mass() + limit ;}
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106 void SetMassWndLow(Double_t limit) { fMassWndLow = TDatabasePDG::Instance()->GetParticle(443)->Mass() - limit ;}
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107 void SetCrystalBallFunction(Bool_t okCB) {fCrystalBallParam = okCB;}
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109 void ConvertFromSpherical() { fFPlus = TMath::Power((fParameters[0]*TMath::Cos(fParameters[1])),2.);
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110 fFMinus = TMath::Power((fParameters[0]*TMath::Sin(fParameters[1])*TMath::Sin(fParameters[2])),2.);
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111 fFSym = TMath::Power((fParameters[0]*TMath::Sin(fParameters[1])*TMath::Cos(fParameters[2])),2.);}
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113 void ComputeIntegral();
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115 void ReadMCtemplates(Int_t BinNum);
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117 void PrintStatus();
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121 Double_t fParameters[16]; /* par[0] = fRadius;
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124 par[3] = fOneOvLamPlus;
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125 par[4] = fOneOvLamMinus;
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126 par[5] = fOneOvLamSym;
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127 par[6] = fMassBkgSlope;
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128 par[7] = fFractionJpsiFromBeauty;
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130 par[9] = fCrystalBallMmean;
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131 par[10] = fCrystalBallNexp;
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132 par[11] = fCrystalBallSigma;
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133 par[12] = fCrystalBallAlpha;
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134 par[13] = fCrystalBallNorm;
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135 par[14] = fSigmaResol;
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136 par[15] = fNResol; */
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139 Double_t fFPlus; // parameters of the log-likelihood function
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140 Double_t fFMinus; // Slopes of the x distributions of the background
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141 Double_t fFSym; // functions
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143 Double_t fIntegral; // integral values of log-likelihood function terms
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144 Double_t fintxFunB;
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145 Double_t fintxDecayTimeBkgPos;
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146 Double_t fintxDecayTimeBkgNeg;
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147 Double_t fintxDecayTimeBkgSym;
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148 Double_t fintmMassSig;
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150 Double_t fintmMassBkg;
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151 TH1F *fhCsiMC; // X distribution used as MC template for JPSI from B
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152 Double_t fResolutionConstants[5]; // constants for the parametrized resolution function R(X)
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153 Double_t fMassWndHigh; // JPSI Mass window higher limit
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154 Double_t fMassWndLow; // JPSI Mass window lower limit
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155 Bool_t fCrystalBallParam; // Boolean to switch to Crystall Ball parameterisation
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159 Double_t EvaluateCDFfunc(Double_t x, Double_t m) const ;
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161 Double_t EvaluateCDFfuncNorm(Double_t x, Double_t m) const ;
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165 Double_t EvaluateCDFfuncSignalPart(Double_t x, Double_t m) const ; // Signal part
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167 Double_t EvaluateCDFDecayTimeSigDistr(Double_t x) const ;
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169 Double_t EvaluateCDFInvMassSigDistr(Double_t m) const ;
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171 Double_t EvaluateCDFfuncBkgPart(Double_t x,Double_t m) const ; // Background part
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173 Double_t EvaluateCDFDecayTimeBkgDistr(Double_t x) const ;
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175 Double_t EvaluateCDFInvMassBkgDistr(Double_t m) const ;
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179 Double_t FunB(Double_t x) const ;
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181 Double_t FunP(Double_t x) const ;
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183 Double_t CsiMC(Double_t x) const ;
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185 Double_t FunBkgPos(Double_t x) const ;
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187 Double_t FunBkgNeg(Double_t x) const ;
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189 Double_t FunBkgSym(Double_t x) const ;
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191 Double_t ResolutionFunc(Double_t x) const ;
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193 ClassDef (AliBtoJPSItoEleCDFfitFCN,1); // Unbinned log-likelihood fit
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