CGEM BOSS 6.6.5.f
BESIII Offline Software System
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EvtKine.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/EvtKine.hh
12//
13// Description:routines to calc. decay angles.
14//
15// Modification history:
16//
17// DJL/RYD September 25, 1996 Module created
18//
19//------------------------------------------------------------------------
20
21#ifndef EVTKINE_HH
22#define EVTKINE_HH
23
24class EvtVector4R;
25class EvtComplex;
26
27double EvtDecayAngle(const EvtVector4R&, const EvtVector4R&,
28 const EvtVector4R&);
29
30double EvtDecayAngleChi(const EvtVector4R&, const EvtVector4R&,
31 const EvtVector4R&, const EvtVector4R&,
32 const EvtVector4R& );
33
34//
35// This routine calculates the cosine of the angle between
36// the normal of the decay plane and the flight direction of particle q
37// in the parent frame.
38//
39double EvtDecayPlaneNormalAngle(const EvtVector4R& p,const EvtVector4R& q,
40 const EvtVector4R& d1,const EvtVector4R& d2);
41
42
43
44// Added by AJB
45//
46// Calculate phi (between 0 and 2 pi) of the daughter given the 4-momentum of
47// the grandparent, parent, resonance and the daughter. g, p, q and d need to
48// be in the same rest frame. Note that for the first level of the tree there
49// is no grandparent and thus <0,0,0,1> should be passed in for g. When there
50// is no parent the angles need to be calculated by simply by calculating polar
51// and azymuthal angles in the rest frame of the resonance (since this will
52// generally be the root particle and is generally at rest the polar and
53// azymuthal angels can simply be calculated.
54//
55double EvtDecayAnglePhi( const EvtVector4R& g, const EvtVector4R& p,
56 const EvtVector4R& q, const EvtVector4R& d );
57
58// Wigner big-D function in Jackson convention
59//
60// XXX NOTE XXX
61// - EvtDecayAngle returns the cos \theta and EvtdFunction requires theta
62// - In EvtdFunction j m1 and m2 are really 2 * j, 2 * m1, 2*m2 to deal with
63// spin 1/2 particles
64//
65EvtComplex wignerD( int j, int m1, int m2, double phi, double theta,
66 double gamma );
67
68
69#endif
70
71
72
73
74
75
76
EvtDecayAngleChi
double EvtDecayAngleChi(const EvtVector4R &, const EvtVector4R &, const EvtVector4R &, const EvtVector4R &, const EvtVector4R &)
Definition: EvtKine.cc:49
EvtDecayPlaneNormalAngle
double EvtDecayPlaneNormalAngle(const EvtVector4R &p, const EvtVector4R &q, const EvtVector4R &d1, const EvtVector4R &d2)
Definition: EvtKine.cc:94
wignerD
EvtComplex wignerD(int j, int m1, int m2, double phi, double theta, double gamma)
Definition: EvtKine.cc:132
EvtDecayAngle
double EvtDecayAngle(const EvtVector4R &, const EvtVector4R &, const EvtVector4R &)
Definition: EvtKine.cc:33
EvtDecayAnglePhi
double EvtDecayAnglePhi(const EvtVector4R &g, const EvtVector4R &p, const EvtVector4R &q, const EvtVector4R &d)
Definition: EvtKine.cc:111
q
****INTEGER imax DOUBLE PRECISION m_pi *DOUBLE PRECISION m_amfin DOUBLE PRECISION m_Chfin DOUBLE PRECISION m_Xenph DOUBLE PRECISION m_sinw2 DOUBLE PRECISION m_GFermi DOUBLE PRECISION m_MfinMin DOUBLE PRECISION m_ta2 INTEGER m_out INTEGER m_KeyFSR INTEGER m_KeyQCD *COMMON c_Semalib $ !copy of input $ !CMS energy $ !beam mass $ !final mass $ !beam charge $ !final charge $ !smallest final mass $ !Z mass $ !Z width $ !EW mixing angle $ !Gmu Fermi $ alphaQED at q
Definition: KKsem.h:33