double lat_geoc, radius;
double result;
- lat_geoc = FG_PI_2 - atan2( sqrt(cp.x()*cp.x() + cp.y()*cp.y()), cp.z() );
+ lat_geoc = SGD_PI_2 - atan2( sqrt(cp.x()*cp.x() + cp.y()*cp.y()), cp.z() );
radius = sqrt( cp.x()*cp.x() + cp.y()*cp.y() + cp.z()*cp.z() );
- if( ( (FG_PI_2 - lat_geoc) < ONE_SECOND ) // near North pole
- || ( (FG_PI_2 + lat_geoc) < ONE_SECOND ) ) // near South pole
+ if( ( (SGD_PI_2 - lat_geoc) < SG_ONE_SECOND ) // near North pole
+ || ( (SGD_PI_2 + lat_geoc) < SG_ONE_SECOND ) ) // near South pole
{
- result = radius - EQUATORIAL_RADIUS_M*E;
+ result = radius - SG_EQUATORIAL_RADIUS_M*E;
} else {
t_lat = tan(lat_geoc);
- x_alpha = E*EQUATORIAL_RADIUS_M/sqrt(t_lat*t_lat + E*E);
- mu_alpha = atan2(sqrt(RESQ_M - x_alpha*x_alpha),E*x_alpha);
+ x_alpha = E*SG_EQUATORIAL_RADIUS_M/sqrt(t_lat*t_lat + E*E);
+ mu_alpha = atan2(sqrt(SG_EQ_RAD_SQUARE_M - x_alpha*x_alpha),E*x_alpha);
if (lat_geoc < 0) {
mu_alpha = - mu_alpha;
}