#include "ellipsoid.h" #include "krovak.h" Krovak::Krovak(const Ellipsoid *ellipsoid, double standardParallel, double azimuth, double scale, double centerLatitude, double longitudeOrigin, double falseEasting, double falseNorthing) { double phiC = deg2rad(centerLatitude); double sinPhiC = sin(phiC); double sinPhiC2 = sinPhiC * sinPhiC; double cosPhiC = cos(phiC); double cosPhiC2 = cosPhiC * cosPhiC; double cosPhiC4 = cosPhiC2 * cosPhiC2; double alphaC = deg2rad(azimuth); _phiP = deg2rad(standardParallel); _e = sqrt(ellipsoid->es()); _a = ellipsoid->radius() * sqrt(1.0 - ellipsoid->es()) / (1.0 - ellipsoid->es() * sinPhiC2); _b = sqrt(1.0 + (ellipsoid->es() * cosPhiC4 / (1.0 - ellipsoid->es()))); double gamma0 = asin(sinPhiC / _b); _t0 = tan(M_PI_4 + gamma0 / 2.0) * pow((1.0 + _e * sinPhiC) / (1.0 - _e * sinPhiC), _e*_b / 2.0) / pow(tan(M_PI_4 + phiC/2.0), _b); _n = sin(_phiP); _r0 = scale * _a / tan(_phiP); _fe = falseEasting; _fn = falseNorthing; _cosAlphaC = cos(alphaC); _sinAlphaC = sin(alphaC); _lambda0 = deg2rad(longitudeOrigin); } PointD Krovak::ll2xy(const Coordinates &c) const { double phi = deg2rad(c.lat()); double lambda = deg2rad(c.lon()); double eSinPhi = _e * sin(phi); double U = 2.0 * (atan(_t0 * pow(tan(phi/2.0 + M_PI_4), _b) / pow((1.0 + eSinPhi) / (1.0 - eSinPhi), _e * _b/2.0)) - M_PI_4); double cosU = cos(U); double V = _b * (_lambda0 - lambda); double T = asin(_cosAlphaC * sin(U) + _sinAlphaC * cosU * cos(V)); double D = asin(cosU * sin(V) / cos(T)); double theta = _n * D; double r = _r0 * pow(tan(M_PI_4 + _phiP/2.0), _n) / pow(tan(T/2.0 + M_PI_4), _n); return PointD(r * sin(theta) + _fe, r * cos(theta) + _fn); } Coordinates Krovak::xy2ll(const PointD &p) const { double Xp = p.y() - _fn; double Yp = p.x() - _fe; double Xp2 = Xp * Xp; double Yp2 = Yp * Yp; double r = sqrt(Xp2 + Yp2); double theta = atan(Yp / Xp); double D = theta / sin(_phiP); double T = 2.0 * (atan(pow(_r0 / r, 1.0/_n) * tan(M_PI_4 + _phiP/2.0)) - M_PI_4); double U = asin(_cosAlphaC * sin(T) - _sinAlphaC * cos(T) * cos(D)); double V = asin(cos(T) * sin(D) / cos(U)); double phi = U; for (int i = 0; i < 3; i++) phi = 2.0 * (atan(pow(_t0, -1.0/_b) * pow(tan(U/2.0 + M_PI_4), 1.0/_b) * pow((1.0 + _e * sin(phi))/(1.0 - _e * sin(phi)), _e/2.0)) - M_PI_4); return Coordinates(rad2deg(_lambda0 - V/_b), rad2deg(phi)); } bool Krovak::operator==(const CT &ct) const { const Krovak *other = dynamic_cast(&ct); return (other != 0 && _e == other->_e && _a == other->_a && _b == other->_b && _t0 == other->_t0 && _r0 == other->_r0 && _phiP == other->_phiP && _cosAlphaC == other->_cosAlphaC && _sinAlphaC == other->_sinAlphaC && _lambda0 == other->_lambda0 && _fe == other->_fe && _fn == other->_fn); } bool KrovakNE::operator==(const CT &ct) const { const KrovakNE *other = dynamic_cast(&ct); return (other != 0 && _k == other->_k); }