10 #pragma implementation
13 #include "CLHEP/Vector/BoostY.h"
14 #include "CLHEP/Vector/Boost.h"
15 #include "CLHEP/Vector/Rotation.h"
16 #include "CLHEP/Vector/LorentzRotation.h"
22 HepBoostY & HepBoostY::set (
double bbeta) {
23 double b2 = bbeta*bbeta;
25 std::cerr <<
"HepBoostY::set() - "
26 <<
"Beta supplied to set HepBoostY represents speed >= c." << std::endl;
28 gamma_ = 1.0 / std::sqrt(1.0 - b2);
32 gamma_ = 1.0 / std::sqrt(1.0 - b2);
38 HepRep4x4 HepBoostY::rep4x4()
const {
39 double bg = beta_*gamma_;
40 return HepRep4x4( 1, 0, 0, 0,
46 HepRep4x4Symmetric HepBoostY::rep4x4Symmetric()
const {
47 double bg = beta_*gamma_;
48 return HepRep4x4Symmetric ( 1, 0, 0, 0,
56 void HepBoostY::decompose (HepRotation & rotation, HepBoost & boost)
const {
57 HepAxisAngle vdelta = HepAxisAngle();
58 rotation = HepRotation(vdelta);
59 Hep3Vector bbeta = boostVector();
60 boost = HepBoost(bbeta);
63 void HepBoostY::decompose (HepAxisAngle & rotation, Hep3Vector & boost)
const {
64 rotation = HepAxisAngle();
65 boost = boostVector();
68 void HepBoostY::decompose (HepBoost & boost, HepRotation & rotation)
const {
69 HepAxisAngle vdelta = HepAxisAngle();
70 rotation = HepRotation(vdelta);
71 Hep3Vector bbeta = boostVector();
72 boost = HepBoost(bbeta);
75 void HepBoostY::decompose (Hep3Vector & boost, HepAxisAngle & rotation)
const {
76 rotation = HepAxisAngle();
77 boost = boostVector();
82 double HepBoostY::distance2(
const HepBoost & b )
const {
83 return b.distance2(*
this);
86 double HepBoostY::distance2(
const HepRotation & r )
const {
88 double dr2 = r.norm2();
92 double HepBoostY::distance2(
const HepLorentzRotation & lt )
const {
96 double db2 = distance2(b1);
97 double dr2 = r1.norm2();
101 bool HepBoostY::isNear (
const HepRotation & r,
double epsilon)
const {
102 double db2 = norm2();
103 if (db2 > epsilon*epsilon)
return false;
104 double dr2 = r.norm2();
105 return (db2+dr2 <= epsilon*epsilon);
108 bool HepBoostY::isNear (
const HepLorentzRotation & lt,
109 double epsilon )
const {
112 double db2 = distance2(b1);
114 if (db2 > epsilon*epsilon)
return false;
115 double dr2 = r1.norm2();
121 void HepBoostY::rectify() {
126 double b2 = beta_*beta_;
128 beta_ = 1.0 - 1.0e-8;
131 gamma_ = 1.0 / std::sqrt(1.0 - b2);
139 return HepBoostY ( (beta()+b.beta()) / (1+beta()*b.beta()) );
142 HepLorentzRotation me (*
this);
146 HepLorentzRotation me (*
this);
150 HepLorentzRotation me (*
this);
157 os <<
"Boost in Y direction (beta = " << beta_
158 <<
", gamma = " << gamma_ <<
") ";
G4ErrorMatrix operator*(const G4ErrorMatrix &m1, const G4ErrorMatrix &m2)
void print(G4double elem)
double epsilon(double density, double temperature)