// Boost.Geometry // Copyright (c) 2016 Oracle and/or its affiliates. // Contributed and/or modified by Adam Wulkiewicz, on behalf of Oracle // Use, modification and distribution is subject to the Boost Software License, // Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) #ifndef BOOST_GEOMETRY_FORMULAS_THOMAS_DIRECT_HPP #define BOOST_GEOMETRY_FORMULAS_THOMAS_DIRECT_HPP #include #include #include #include #include #include #include #include namespace boost { namespace geometry { namespace formula { /*! \brief The solution of the direct problem of geodesics on latlong coordinates, Forsyth-Andoyer-Lambert type approximation with second order terms. \author See - Technical Report: PAUL D. THOMAS, MATHEMATICAL MODELS FOR NAVIGATION SYSTEMS, 1965 http://www.dtic.mil/docs/citations/AD0627893 - Technical Report: PAUL D. THOMAS, SPHEROIDAL GEODESICS, REFERENCE SYSTEMS, AND LOCAL GEOMETRY, 1970 http://www.dtic.mil/docs/citations/AD0703541 */ template < typename CT, bool EnableCoordinates = true, bool EnableReverseAzimuth = false, bool EnableReducedLength = false, bool EnableGeodesicScale = false > class thomas_direct { static const bool CalcQuantities = EnableReducedLength || EnableGeodesicScale; static const bool CalcCoordinates = EnableCoordinates || CalcQuantities; static const bool CalcRevAzimuth = EnableReverseAzimuth || CalcCoordinates || CalcQuantities; public: typedef result_direct result_type; template static inline result_type apply(T const& lo1, T const& la1, Dist const& distance, Azi const& azimuth12, Spheroid const& spheroid) { result_type result; CT const lon1 = lo1; CT const lat1 = la1; if ( math::equals(distance, Dist(0)) || distance < Dist(0) ) { result.lon2 = lon1; result.lat2 = lat1; return result; } CT const c0 = 0; CT const c1 = 1; CT const c2 = 2; CT const c4 = 4; CT const a = CT(get_radius<0>(spheroid)); CT const b = CT(get_radius<2>(spheroid)); CT const f = detail::flattening(spheroid); CT const one_minus_f = c1 - f; CT const pi = math::pi(); CT const pi_half = pi / c2; // keep azimuth small - experiments show low accuracy // if the azimuth is closer to (+-)180 deg. CT azi12_alt = azimuth12; CT lat1_alt = lat1; bool alter_result = vflip_if_south(lat1, azimuth12, lat1_alt, azi12_alt); CT const theta1 = math::equals(lat1_alt, pi_half) ? lat1_alt : math::equals(lat1_alt, -pi_half) ? lat1_alt : atan(one_minus_f * tan(lat1_alt)); CT const sin_theta1 = sin(theta1); CT const cos_theta1 = cos(theta1); CT const sin_a12 = sin(azi12_alt); CT const cos_a12 = cos(azi12_alt); CT const M = cos_theta1 * sin_a12; // cos_theta0 CT const theta0 = acos(M); CT const sin_theta0 = sin(theta0); CT const N = cos_theta1 * cos_a12; CT const C1 = f * M; // lower-case c1 in the technical report CT const C2 = f * (c1 - math::sqr(M)) / c4; // lower-case c2 in the technical report CT const D = (c1 - C2) * (c1 - C2 - C1 * M); CT const P = C2 * (c1 + C1 * M / c2) / D; // special case for equator: // sin_theta0 = 0 <=> lat1 = 0 ^ |azimuth12| = pi/2 // NOTE: in this case it doesn't matter what's the value of cos_sigma1 because // theta1=0, theta0=0, M=1|-1, C2=0 so X=0 and Y=0 so d_sigma=d // cos_a12=0 so N=0, therefore // lat2=0, azi21=pi/2|-pi/2 // d_eta = atan2(sin_d_sigma, cos_d_sigma) // H = C1 * d_sigma CT const cos_sigma1 = math::equals(sin_theta0, c0) ? c1 : normalized1_1(sin_theta1 / sin_theta0); CT const sigma1 = acos(cos_sigma1); CT const d = distance / (a * D); CT const u = 2 * (sigma1 - d); CT const cos_d = cos(d); CT const sin_d = sin(d); CT const cos_u = cos(u); CT const sin_u = sin(u); CT const W = c1 - c2 * P * cos_u; CT const V = cos_u * cos_d - sin_u * sin_d; CT const X = math::sqr(C2) * sin_d * cos_d * (2 * math::sqr(V) - c1); CT const Y = c2 * P * V * W * sin_d; CT const d_sigma = d + X - Y; CT const sin_d_sigma = sin(d_sigma); CT const cos_d_sigma = cos(d_sigma); if (BOOST_GEOMETRY_CONDITION(CalcRevAzimuth)) { result.reverse_azimuth = atan2(M, N * cos_d_sigma - sin_theta1 * sin_d_sigma); if (alter_result) { vflip_rev_azi(result.reverse_azimuth, azimuth12); } } if (BOOST_GEOMETRY_CONDITION(CalcCoordinates)) { CT const S_sigma = c2 * sigma1 - d_sigma; CT const cos_S_sigma = cos(S_sigma); CT const d_eta = atan2(sin_d_sigma * sin_a12, cos_theta1 * cos_d_sigma - sin_theta1 * sin_d_sigma * cos_a12); CT const H = C1 * (c1 - C2) * d_sigma - C1 * C2 * sin_d_sigma * cos_S_sigma; CT const d_lambda = d_eta - H; result.lon2 = lon1 + d_lambda; if (! math::equals(M, c0)) { CT const sin_a21 = sin(result.reverse_azimuth); CT const tan_theta2 = (sin_theta1 * cos_d_sigma + N * sin_d_sigma) * sin_a21 / M; result.lat2 = atan(tan_theta2 / one_minus_f); } else { CT const sigma2 = S_sigma - sigma1; //theta2 = asin(cos(sigma2)) <=> sin_theta0 = 1 CT const tan_theta2 = cos(sigma2) / sin(sigma2); result.lat2 = atan(tan_theta2 / one_minus_f); } if (alter_result) { result.lat2 = -result.lat2; } } if (BOOST_GEOMETRY_CONDITION(CalcQuantities)) { typedef differential_quantities quantities; quantities::apply(lon1, lat1, result.lon2, result.lat2, azimuth12, result.reverse_azimuth, b, f, result.reduced_length, result.geodesic_scale); } return result; } private: static inline bool vflip_if_south(CT const& lat1, CT const& azi12, CT & lat1_alt, CT & azi12_alt) { CT const c2 = 2; CT const pi = math::pi(); CT const pi_half = pi / c2; if (azi12 > pi_half) { azi12_alt = pi - azi12; lat1_alt = -lat1; return true; } else if (azi12 < -pi_half) { azi12_alt = -pi - azi12; lat1_alt = -lat1; return true; } return false; } static inline void vflip_rev_azi(CT & rev_azi, CT const& azimuth12) { CT const c0 = 0; CT const pi = math::pi(); if (rev_azi == c0) { rev_azi = azimuth12 >= 0 ? pi : -pi; } else if (rev_azi > c0) { rev_azi = pi - rev_azi; } else { rev_azi = -pi - rev_azi; } } static inline CT normalized1_1(CT const& value) { CT const c1 = 1; return value > c1 ? c1 : value < -c1 ? -c1 : value; } }; }}} // namespace boost::geometry::formula #endif // BOOST_GEOMETRY_FORMULAS_THOMAS_DIRECT_HPP