ClassImp(AliAnalysisTaskPID)
+const Double_t AliAnalysisTaskPID::fgkEpsilon = 1e-8; // Double_t threshold above zero
+const Double_t AliAnalysisTaskPID::fgkOneOverSqrt2 = 0.707106781186547462; // = 1. / TMath::Sqrt2();
+const Double_t AliAnalysisTaskPID::fgkSigmaReferenceForTransitionPars = 0.05; // Reference sigma chosen to calculate transition parameters
+
//________________________________________________________________________
AliAnalysisTaskPID::AliAnalysisTaskPID()
: AliAnalysisTaskPIDV0base()
virtual void SetUpPIDcombined();\r
\r
static const Int_t fgkNumJetAxes = 3; // Number of additional axes for jets\r
- static const Double_t fgkEpsilon = 1e-8; // Double_t threshold above zero\r
+ static const Double_t fgkEpsilon; // Double_t threshold above zero\r
static const Int_t fgkMaxNumGenEntries = 1000; // Maximum number of generated detector responses per track and delta(Prime) and associated species\r
\r
private:\r
- static const Double_t fgkOneOverSqrt2 = 0.707106781186547462; // = 1. / TMath::Sqrt2();\r
+ static const Double_t fgkOneOverSqrt2; // = 1. / TMath::Sqrt2();\r
\r
AliPIDCombined* fPIDcombined; //! PID combined object\r
\r
TF1* fConvolutedGausDeltaPrime; // Gaus convoluted with exponential tail to generate detector response (deltaPrime)\r
\r
Double_t fConvolutedGaussTransitionPars[3]; // Parameter for transition from gaussian parameters to asymmetric shape\r
- static const Double_t fgkSigmaReferenceForTransitionPars = 0.05; // Reference sigma chosen to calculate transition parameters\r
+ static const Double_t fgkSigmaReferenceForTransitionPars; // Reference sigma chosen to calculate transition parameters\r
\r
Double_t fEtaAbsCutLow; // Lower cut value on |eta|\r
Double_t fEtaAbsCutUp; // Upper cut value on |eta|\r