Geant4 11.2.2
Toolkit for the simulation of the passage of particles through matter
Loading...
Searching...
No Matches
RotationX.cc
Go to the documentation of this file.
1// -*- C++ -*-
2// ---------------------------------------------------------------------------
3//
4// This file is a part of the CLHEP - a Class Library for High Energy Physics.
5//
6// This is the implementation of methods of the HepRotationX class which
7// were introduced when ZOOM PhysicsVectors was merged in.
8//
9
15
16#include <cmath>
17#include <stdlib.h>
18#include <iostream>
19
20namespace CLHEP {
21
22static inline double safe_acos (double x) {
23 if (std::abs(x) <= 1.0) return std::acos(x);
24 return ( (x>0) ? 0 : CLHEP::pi );
25}
26
28 its_d(proper(ddelta)), its_s(std::sin(ddelta)), its_c(std::cos(ddelta))
29{}
30
31HepRotationX & HepRotationX::set ( double ddelta ) {
32 its_d = proper(ddelta);
33 its_s = std::sin(its_d);
34 its_c = std::cos(its_d);
35 return *this;
36}
37
38double HepRotationX::phi() const {
39 if ( (its_d > 0) && (its_d < CLHEP::pi) ) {
40 return CLHEP::pi;
41 } else {
42 return 0.0;
43 }
44} // HepRotationX::phi()
45
46double HepRotationX::theta() const {
47 return std::fabs( its_d );
48} // HepRotationX::theta()
49
50double HepRotationX::psi() const {
51 if ( (its_d > 0) && (its_d < CLHEP::pi) ) {
52 return CLHEP::pi;
53 } else {
54 return 0.0;
55 }
56} // HepRotationX::psi()
57
59 return HepEulerAngles( phi(), theta(), psi() );
60} // HepRotationX::eulerAngles()
61
62
63// From the defining code in the implementation of CLHEP (in Rotation.cc)
64// it is clear that thetaX, phiX form the polar angles in the original
65// coordinate system of the new X axis (and similarly for phiY and phiZ).
66//
67// This code is taken directly from the original CLHEP. However, there are as
68// shown opportunities for significant speed improvement.
69
70double HepRotationX::phiX() const {
71 return (yx() == 0.0 && xx() == 0.0) ? 0.0 : std::atan2(yx(),xx());
72 // or ---- return 0;
73}
74
75double HepRotationX::phiY() const {
76 return (yy() == 0.0 && xy() == 0.0) ? 0.0 : std::atan2(yy(),xy());
77 // or ---- return (yy() == 0.0) ? 0.0 : std::atan2(yy(),xy());
78}
79
80double HepRotationX::phiZ() const {
81 return (yz() == 0.0 && xz() == 0.0) ? 0.0 : std::atan2(yz(),xz());
82 // or ---- return (yz() == 0.0) ? 0.0 : std::atan2(yz(),xz());
83}
84
85double HepRotationX::thetaX() const {
86 return safe_acos(zx());
87 // or ---- return CLHEP::halfpi;
88}
89
90double HepRotationX::thetaY() const {
91 return safe_acos(zy());
92}
93
94double HepRotationX::thetaZ() const {
95 return safe_acos(zz());
96 // or ---- return d;
97}
98
99void HepRotationX::setDelta ( double ddelta ) {
100 set(ddelta);
101}
102
104 (HepAxisAngle & rotation, Hep3Vector & boost) const {
105 boost.set(0,0,0);
106 rotation = axisAngle();
107}
108
110 (Hep3Vector & boost, HepAxisAngle & rotation) const {
111 boost.set(0,0,0);
112 rotation = axisAngle();
113}
114
116 (HepRotation & rotation, HepBoost & boost) const {
117 boost.set(0,0,0);
118 rotation = HepRotation(*this);
119}
120
122 (HepBoost & boost, HepRotation & rotation) const {
123 boost.set(0,0,0);
124 rotation = HepRotation(*this);
125}
126
127double HepRotationX::distance2( const HepRotationX & r ) const {
128 double answer = 2.0 * ( 1.0 - ( its_s * r.its_s + its_c * r.its_c ) ) ;
129 return (answer >= 0) ? answer : 0;
130}
131
132double HepRotationX::distance2( const HepRotation & r ) const {
133 double sum = r.xx() +
134 yy() * r.yy() + yz() * r.yz()
135 + zy() * r.zy() + zz() * r.zz();
136 double answer = 3.0 - sum;
137 return (answer >= 0 ) ? answer : 0;
138}
139
140double HepRotationX::distance2( const HepLorentzRotation & lt ) const {
141 HepAxisAngle a;
142 Hep3Vector b;
143 lt.decompose(b, a);
144 double bet = b.beta();
145 double bet2 = bet*bet;
146 HepRotation r(a);
147 return bet2/(1-bet2) + distance2(r);
148}
149
150double HepRotationX::distance2( const HepBoost & lt ) const {
151 return distance2( HepLorentzRotation(lt));
152}
153
154double HepRotationX::howNear( const HepRotationX & r ) const {
155 return std::sqrt(distance2(r));
156}
157double HepRotationX::howNear( const HepRotation & r ) const {
158 return std::sqrt(distance2(r));
159}
160double HepRotationX::howNear( const HepBoost & b ) const {
161 return std::sqrt(distance2(b));
162}
163double HepRotationX::howNear( const HepLorentzRotation & lt ) const {
164 return std::sqrt(distance2(lt));
165}
166bool HepRotationX::isNear(const HepRotationX & r,double epsilon)const{
167 return (distance2(r) <= epsilon*epsilon);
168}
169bool HepRotationX::isNear(const HepRotation & r,double epsilon) const{
170 return (distance2(r) <= epsilon*epsilon);
171}
172bool HepRotationX::isNear( const HepBoost & lt,double epsilon) const {
173 return (distance2(lt) <= epsilon*epsilon);
174}
175
177 double epsilon ) const {
178 return (distance2(lt) <= epsilon*epsilon);
179}
180
181double HepRotationX::norm2() const {
182 return 2.0 - 2.0 * its_c;
183}
184
185std::ostream & HepRotationX::print( std::ostream & os ) const {
186 os << "\nRotation about X (" << its_d <<
187 ") [cos d = " << its_c << " sin d = " << its_s << "]\n";
188 return os;
189}
190
191} // namespace CLHEP
192
G4double epsilon(G4double density, G4double temperature)
double beta() const
void set(double x, double y, double z)
HepBoost & set(double betaX, double betaY, double betaZ)
Definition Boost.cc:20
void decompose(Hep3Vector &boost, HepAxisAngle &rotation) const
double phiX() const
Definition RotationX.cc:70
double xy() const
double thetaZ() const
Definition RotationX.cc:94
double xx() const
double phiY() const
Definition RotationX.cc:75
double yz() const
static double proper(double delta)
double zy() const
HepRotationX & set(double delta)
Definition RotationX.cc:31
HepEulerAngles eulerAngles() const
Definition RotationX.cc:58
double psi() const
Definition RotationX.cc:50
double howNear(const HepRotationX &r) const
Definition RotationX.cc:154
void setDelta(double delta)
Definition RotationX.cc:99
double yy() const
double phi() const
Definition RotationX.cc:38
double thetaY() const
Definition RotationX.cc:90
double xz() const
double phiZ() const
Definition RotationX.cc:80
double thetaX() const
Definition RotationX.cc:85
void decompose(HepAxisAngle &rotation, Hep3Vector &boost) const
Definition RotationX.cc:104
HepAxisAngle axisAngle() const
std::ostream & print(std::ostream &os) const
Definition RotationX.cc:185
bool isNear(const HepRotationX &r, double epsilon=Hep4RotationInterface::tolerance) const
Definition RotationX.cc:166
double theta() const
Definition RotationX.cc:46
double zz() const
double distance2(const HepRotationX &r) const
Definition RotationX.cc:127
double norm2() const
Definition RotationX.cc:181
double yx() const
double zx() const
double zz() const
double yz() const
double zy() const
double xx() const
double yy() const