BOSS 7.0.5
BESIII Offline Software System
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EvtVubNLO.hh
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1//--------------------------------------------------------------------------
2//
3// Environment:
4// This software is part of the EvtGen package developed jointly
5// for the BaBar and CLEO collaborations. If you use all or part
6// of it, please give an appropriate acknowledgement.
7//
8// Copyright Information: See EvtGen/COPYRIGHT
9// Copyright (C) 1998 Caltech, UCSB
10//
11// Module: EvtGen/EvtVubNLO.hh
12//
13// Description:
14// Class to generate inclusive B to X_u l nu decays according to various
15// decay models. Implemtented are ACCM, parton-model and a QCD model.
16//
17// Modification history:
18//
19// Sven Menke January 17, 2001 Module created
20//
21//------------------------------------------------------------------------
22
23#ifndef EVTVUBNLO_HH
24#define EVTVUBNLO_HH
25
26#include <vector>
28
29class EvtParticle;
30class RandGeneral;
31
33
34public:
35
37 virtual ~EvtVubNLO();
38
39 void getName(std::string& name);
40
42
43 void initProbMax();
44
45 void init();
46
47 void decay(EvtParticle *p);
48
49
50private:
51
52 // cache
53 double _lbar;
54 double _mupi2;
55
56 double _mb; // the b-quark pole mass in GeV
57 double _mB;
58 double _lambdaSF;
59 double _b; // Parameter for the Fermi Motion
60 double _kpar;
61 double _mui; // renormalization scale (preferred value=1.5 GeV)
62 double _SFNorm; // SF normalization
63 double _dGMax; // max dGamma*p2 value;
64 int _nbins;
65 int _idSF;// which shape function?
66 double * _masses;
67 double * _weights;
68
69 double _gmax;
70 int _ngood,_ntot;
71
72
73 double tripleDiff(double pp, double pl, double pm);
74 double SFNorm(const std::vector<double> &coeffs);
75 static double integrand(double omega, const std::vector<double> &coeffs);
76 double F10(const std::vector<double> &coeffs);
77 static double F1Int(double omega,const std::vector<double> &coeffs);
78 double F20(const std::vector<double> &coeffs);
79 static double F2Int(double omega,const std::vector<double> &coeffs);
80 double F30(const std::vector<double> &coeffs);
81 static double F3Int(double omega,const std::vector<double> &coeffs);
82 static double g1(double y, double z);
83 static double g2(double y, double z);
84 static double g3(double y, double z);
85
86 static double Gamma(double z);// Euler Gamma Function
87 static double dgamma(double t, const std::vector<double> &c){ return pow(t,c[0]-1)*exp(-t);}
88 static double Gamma(double z, double tmax);
89
90 // theory parameters
91 inline double mu_i(){return _mui;} // intermediate scale
92 inline double mu_bar(){return _mui;}
93 inline double mu_h(){return _mb/sqrt(2.0);} // high scale
94 inline double lambda1(){return -_mupi2;}
95
96 // expansion coefficients for RGE
97 static double beta0(int nf=4){return 11.-2./3.*nf;}
98 static double beta1(int nf=4){return 34.*3.-38./3.*nf;}
99 static double beta2(int nf=4){return 1428.5-5033./18.*nf+325./54.*nf*nf;}
100 static double gamma0(){return 16./3.;}
101 static double gamma1(int nf=4){return 4./3.*(49.85498-40./9.*nf);}
102 static double gamma2(int nf=4){return 64./3.*(55.07242-8.58691*nf-nf*nf/27.);} /* zeta3=1.20206 */
103 static double gammap0(){return -20./3.;}
104 static double gammap1(int nf=4){return -32./3.*(6.92653-0.9899*nf);} /* ?? zeta3=1.202 */
105
106
107 // running constants
108
109 static double alphas(double mu) ;
110 static double C_F(double mu){return (4.0/3.0)*alphas(mu)/4./EvtConst::pi;}
111
112 // Shape Functions
113
114 inline double lambda_SF(){ return _lambdaSF;}
115 double lambda_bar(double omega0);
116 inline double lambda2(){return 0.12;}
117 double mu_pi2(double omega0);
118 inline double lambda(double mu=0){ return _mB-_mb;}
119
120 // specail for gaussian SF
121 static double cGaus(double b){return pow(Gamma(1+b/2.)/Gamma((1+b)/2.),2);}
122
123 double M0(double mui,double omega0);
124 static double shapeFunction(double omega, const std::vector<double> &coeffs);
125 static double expShapeFunction(double omega, const std::vector<double> &coeffs);
126 static double gausShapeFunction(double omega, const std::vector<double> &coeffs);
127 // SSF (not yet implemented)
128 double subS(const std::vector<double> &coeffs );
129 double subT(const std::vector<double> &coeffs);
130 double subU(const std::vector<double> &coeffs);
131 double subV(const std::vector<double> &coeffs);
132
133
134 // Sudakov
135
136 inline double S0(double a, double r){return -gamma0()/4/a/pow(beta0(),2)*(1/r-1+log(r));}
137 inline double S1(double a, double r){return gamma0()/4./pow(beta0(),2)*(
138 pow(log(r),2)*beta1()/2./beta0()+(gamma1()/gamma0()-beta1()/beta0())*(1.-r+log(r))
139 );}
140 inline double S2(double a, double r){return gamma0()*a/4./pow(beta0(),2)*(
141 -0.5*pow((1-r),2)*(
142 pow(beta1()/beta0(),2)-beta2()/beta0()-beta1()/beta0()*gamma1()/gamma0()+gamma2()/gamma0()
143 )
144 +(pow(beta1()/beta0(),2)-beta2()/beta0())*(1-r)*log(r)
145 +(beta1()/beta0()*gamma1()/gamma0()-beta2()/beta0())*(1-r+r*log(r))
146 );}
147 inline double dSudakovdepsi(double mu1, double mu2){return S2(alphas(mu1)/(4*EvtConst::pi),alphas(mu2)/alphas(mu1));}
148 inline double Sudakov(double mu1, double mu2, double epsi=0){double fp(4*EvtConst::pi);return S0(alphas(mu1)/fp,alphas(mu2)/alphas(mu1))+S1(alphas(mu1)/fp,alphas(mu2)/alphas(mu1))+epsi*dSudakovdepsi(mu1,mu2);}
149
150 // RG
151 inline double dGdepsi(double mu1, double mu2){return 1./8./EvtConst::pi*(alphas(mu2)-alphas(mu1))*(gamma1()/beta0()-beta1()*gamma0()/pow(beta0(),2));}
152 inline double aGamma(double mu1, double mu2, double epsi=0){return gamma0()/2/beta0()*log(alphas(mu2)/alphas(mu1))+epsi*dGdepsi( mu1, mu2);}
153 inline double dgpdepsi(double mu1, double mu2){return 1./8./EvtConst::pi*(alphas(mu2)-alphas(mu1))*(gammap1()/beta0()-beta1()*gammap0()/pow(beta0(),2));}
154 inline double agammap(double mu1, double mu2, double epsi=0){return gammap0()/2/beta0()*log(alphas(mu2)/alphas(mu1))+epsi*dgpdepsi( mu1, mu2);}
155 inline double U1(double mu1, double mu2, double epsi=0){return exp(2*(Sudakov(mu1,mu2,epsi)-agammap(mu1,mu2,epsi)-aGamma(mu1,mu2,epsi)*log(_mb/mu1)));}
156 inline double U1lo(double mu1, double mu2){return U1(mu1,mu2);}
157 inline double U1nlo(double mu1, double mu2){return U1(mu1,mu2)*(1+2*(dSudakovdepsi(mu1,mu2)-dgpdepsi( mu1, mu2)-log(_mb/mu1)*dGdepsi( mu1, mu2)));}
158 inline double alo(double mu1, double mu2){return -2*aGamma(mu1,mu2);}
159 inline double anlo(double mu1, double mu2){return -2*dGdepsi(mu1,mu2);}
160
161};
162
163#endif
164
TF1 * g1
EvtComplex exp(const EvtComplex &c)
Definition: EvtComplex.hh:252
TTree * t
Definition: binning.cxx:23
static const double pi
Definition: EvtConst.hh:28
void getName(std::string &name)
Definition: EvtVubNLO.cc:51
void initProbMax()
Definition: EvtVubNLO.cc:167
virtual ~EvtVubNLO()
Definition: EvtVubNLO.cc:39
EvtDecayBase * clone()
Definition: EvtVubNLO.cc:57
void init()
Definition: EvtVubNLO.cc:64
void decay(EvtParticle *p)
Definition: EvtVubNLO.cc:173
double y[1000]
const double b
Definition: slope.cxx:9