/** * \file AzimuthalEquidistant.hpp * \brief Header for GeographicLib::AzimuthalEquidistant class * * Copyright (c) Charles Karney (2009-2019) and licensed * under the MIT/X11 License. For more information, see * https://geographiclib.sourceforge.io/ **********************************************************************/ #if !defined(GEOGRAPHICLIB_AZIMUTHALEQUIDISTANT_HPP) #define GEOGRAPHICLIB_AZIMUTHALEQUIDISTANT_HPP 1 #include #include namespace GeographicLib { /** * \brief Azimuthal equidistant projection * * Azimuthal equidistant projection centered at an arbitrary position on the * ellipsoid. For a point in projected space (\e x, \e y), the geodesic * distance from the center position is hypot(\e x, \e y) and the azimuth of * the geodesic from the center point is atan2(\e x, \e y). The Forward and * Reverse methods also return the azimuth \e azi of the geodesic at (\e x, * \e y) and reciprocal scale \e rk in the azimuthal direction which, * together with the basic properties of the projection, serve to specify * completely the local affine transformation between geographic and * projected coordinates. * * The conversions all take place using a Geodesic object (by default * Geodesic::WGS84()). For more information on geodesics see \ref geodesic. * * Example of use: * \include example-AzimuthalEquidistant.cpp * * GeodesicProj is a command-line utility * providing access to the functionality of AzimuthalEquidistant, Gnomonic, * and CassiniSoldner. **********************************************************************/ class GEOGRAPHICLIB_EXPORT AzimuthalEquidistant { private: typedef Math::real real; real eps_; Geodesic _earth; public: /** * Constructor for AzimuthalEquidistant. * * @param[in] earth the Geodesic object to use for geodesic calculations. * By default this uses the WGS84 ellipsoid. **********************************************************************/ explicit AzimuthalEquidistant(const Geodesic& earth = Geodesic::WGS84()); /** * Forward projection, from geographic to azimuthal equidistant. * * @param[in] lat0 latitude of center point of projection (degrees). * @param[in] lon0 longitude of center point of projection (degrees). * @param[in] lat latitude of point (degrees). * @param[in] lon longitude of point (degrees). * @param[out] x easting of point (meters). * @param[out] y northing of point (meters). * @param[out] azi azimuth of geodesic at point (degrees). * @param[out] rk reciprocal of azimuthal scale at point. * * \e lat0 and \e lat should be in the range [−90°, 90°]. * The scale of the projection is 1 in the "radial" direction, \e azi * clockwise from true north, and is 1/\e rk in the direction perpendicular * to this. A call to Forward followed by a call to Reverse will return * the original (\e lat, \e lon) (to within roundoff). **********************************************************************/ void Forward(real lat0, real lon0, real lat, real lon, real& x, real& y, real& azi, real& rk) const; /** * Reverse projection, from azimuthal equidistant to geographic. * * @param[in] lat0 latitude of center point of projection (degrees). * @param[in] lon0 longitude of center point of projection (degrees). * @param[in] x easting of point (meters). * @param[in] y northing of point (meters). * @param[out] lat latitude of point (degrees). * @param[out] lon longitude of point (degrees). * @param[out] azi azimuth of geodesic at point (degrees). * @param[out] rk reciprocal of azimuthal scale at point. * * \e lat0 should be in the range [−90°, 90°]. \e lat will * be in the range [−90°, 90°] and \e lon will be in the * range [−180°, 180°]. The scale of the projection is 1 in * the "radial" direction, \e azi clockwise from true north, and is 1/\e rk * in the direction perpendicular to this. A call to Reverse followed by a * call to Forward will return the original (\e x, \e y) (to roundoff) only * if the geodesic to (\e x, \e y) is a shortest path. **********************************************************************/ void Reverse(real lat0, real lon0, real x, real y, real& lat, real& lon, real& azi, real& rk) const; /** * AzimuthalEquidistant::Forward without returning the azimuth and scale. **********************************************************************/ void Forward(real lat0, real lon0, real lat, real lon, real& x, real& y) const { real azi, rk; Forward(lat0, lon0, lat, lon, x, y, azi, rk); } /** * AzimuthalEquidistant::Reverse without returning the azimuth and scale. **********************************************************************/ void Reverse(real lat0, real lon0, real x, real y, real& lat, real& lon) const { real azi, rk; Reverse(lat0, lon0, x, y, lat, lon, azi, rk); } /** \name Inspector functions **********************************************************************/ ///@{ /** * @return \e a the equatorial radius of the ellipsoid (meters). This is * the value inherited from the Geodesic object used in the constructor. **********************************************************************/ Math::real EquatorialRadius() const { return _earth.EquatorialRadius(); } /** * @return \e f the flattening of the ellipsoid. This is the value * inherited from the Geodesic object used in the constructor. **********************************************************************/ Math::real Flattening() const { return _earth.Flattening(); } /** * \deprecated An old name for EquatorialRadius(). **********************************************************************/ // GEOGRAPHICLIB_DEPRECATED("Use EquatorialRadius()") Math::real MajorRadius() const { return EquatorialRadius(); } ///@} }; } // namespace GeographicLib #endif // GEOGRAPHICLIB_AZIMUTHALEQUIDISTANT_HPP