virtual void SetAProjectile(Float_t a = 208) {fAProjectile = a;}
virtual void SetATarget(Float_t a = 208) {fATarget = a;}
virtual void SetEnergyCMS(Float_t energy = 5500.) {fEnergyCMS = energy;}
- virtual void SetImpactParameterRange(Float_t bmin = 0., Float_t bmax = 0.)
+ virtual void SetImpactParameterRange(Float_t bmin = 0., Float_t bmax = 0.)
{fMinImpactParam=bmin; fMaxImpactParam=bmax;}
protected:
Float_t fMinImpactParam; // minimum impact parameter
Float_t fMaxImpactParam; // maximum impact parameter
- static Double_t fitData (Double_t *xx, Double_t *par);
+ static Double_t FitData (Double_t *xx, Double_t *par);
static Double_t WSforNorm (Double_t *xx, Double_t *par);
static Double_t WSz (Double_t *xx, Double_t *par);
static Double_t TA (Double_t *xx, Double_t *par);
static Double_t TAxTB (Double_t *xx, Double_t *par);
static Double_t TAB (Double_t *xx, Double_t *par);
- static TF1 *fDataPt; // d^{2}#sigma^{pp}/(dp_t dy) from data fit
- static TF1 *fWSzA; // Wood Saxon parameterisation for nucleus A
- static TF1 *fWSzB; // Wood Saxon parameterisation for nucleus B
- static TF1 *fTA; // nuclear thickness function T_A(b) (1/fm**2)
- static TF1 *fTB; // nuclear thickness function T_B(phi)=T_B(sqtr(s**2+b**2-2*s*b*cos(phi)))
- static TF1 *fTAxTB; // s * TA(s) * 2 * Integral(0,phiMax) TB(phi(s,b))
- static TF1 *fTAB; // overlap function T_AB(b) (1/fm**2)
+ static TF1 *fgDataPt; // d^{2}#sigma^{pp}/(dp_t dy) from data fit
+ static TF1 *fgWSzA; // Wood Saxon parameterisation for nucleus A
+ static TF1 *fgWSzB; // Wood Saxon parameterisation for nucleus B
+ static TF1 *fgTA; // nuclear thickness function T_A(b) (1/fm**2)
+ static TF1 *fgTB; // nuclear thickness function T_B(phi)=T_B(sqtr(s**2+b**2-2*s*b*cos(phi)))
+ static TF1 *fgTAxTB; // s * TA(s) * 2 * Integral(0,phiMax) TB(phi(s,b))
+ static TF1 *fgTAB; // overlap function T_AB(b) (1/fm**2)
private: