/** * \file UTMUPS.hpp * \brief Header for GeographicLib::UTMUPS class * * Copyright (c) Charles Karney (2008-2019) and licensed * under the MIT/X11 License. For more information, see * https://geographiclib.sourceforge.io/ **********************************************************************/ #if !defined(GEOGRAPHICLIB_UTMUPS_HPP) #define GEOGRAPHICLIB_UTMUPS_HPP 1 #include namespace GeographicLib { /** * \brief Convert between geographic coordinates and UTM/UPS * * UTM and UPS are defined * - J. W. Hager, J. F. Behensky, and B. W. Drew, * * The Universal Grids: Universal Transverse Mercator (UTM) and Universal * Polar Stereographic (UPS), Defense Mapping Agency, Technical Manual * TM8358.2 (1989). * . * Section 2-3 defines UTM and section 3-2.4 defines UPS. This document also * includes approximate algorithms for the computation of the underlying * transverse Mercator and polar stereographic projections. Here we * substitute much more accurate algorithms given by * GeographicLib:TransverseMercator and GeographicLib:PolarStereographic. * These are the algorithms recommended by the NGA document * - * The Universal Grids and the Transverse Mercator and Polar Stereographic * Map Projections, NGA.SIG.0012_2.0.0_UTMUPS (2014). * * In this implementation, the conversions are closed, i.e., output from * Forward is legal input for Reverse and vice versa. The error is about 5nm * in each direction. However, the conversion from legal UTM/UPS coordinates * to geographic coordinates and back might throw an error if the initial * point is within 5nm of the edge of the allowed range for the UTM/UPS * coordinates. * * The simplest way to guarantee the closed property is to define allowed * ranges for the eastings and northings for UTM and UPS coordinates. The * UTM boundaries are the same for all zones. (The only place the * exceptional nature of the zone boundaries is evident is when converting to * UTM/UPS coordinates requesting the standard zone.) The MGRS lettering * scheme imposes natural limits on UTM/UPS coordinates which may be * converted into MGRS coordinates. For the conversion to/from geographic * coordinates these ranges have been extended by 100km in order to provide a * generous overlap between UTM and UPS and between UTM zones. * * The NGA software package * geotrans * also provides conversions to and from UTM and UPS. Version 2.4.2 (and * earlier) suffers from some drawbacks: * - Inconsistent rules are used to determine the whether a particular UTM or * UPS coordinate is legal. A more systematic approach is taken here. * - The underlying projections are not very accurately implemented. * * The GeographicLib::UTMUPS::EncodeZone encodes the UTM zone and hemisphere * to allow UTM/UPS coordinated to be displayed as, for example, "38N 444500 * 3688500". According to NGA.SIG.0012_2.0.0_UTMUPS the use of "N" to denote * "north" in the context is not allowed (since a upper case letter in this * context denotes the MGRS latitude band). Consequently, as of version * 1.36, EncodeZone uses the lower case letters "n" and "s" to denote the * hemisphere. In addition EncodeZone accepts an optional final argument \e * abbrev, which, if false, results in the hemisphere being spelled out as in * "38north". * * Example of use: * \include example-UTMUPS.cpp **********************************************************************/ class GEOGRAPHICLIB_EXPORT UTMUPS { private: typedef Math::real real; static const int falseeasting_[4]; static const int falsenorthing_[4]; static const int mineasting_[4]; static const int maxeasting_[4]; static const int minnorthing_[4]; static const int maxnorthing_[4]; static const int epsg01N = 32601; // EPSG code for UTM 01N static const int epsg60N = 32660; // EPSG code for UTM 60N static const int epsgN = 32661; // EPSG code for UPS N static const int epsg01S = 32701; // EPSG code for UTM 01S static const int epsg60S = 32760; // EPSG code for UTM 60S static const int epsgS = 32761; // EPSG code for UPS S static real CentralMeridian(int zone) { return real(6 * zone - 183); } // Throw an error if easting or northing are outside standard ranges. If // throwp = false, return bool instead. static bool CheckCoords(bool utmp, bool northp, real x, real y, bool msgrlimits = false, bool throwp = true); UTMUPS(); // Disable constructor public: /** * In this class we bring together the UTM and UPS coordinates systems. * The UTM divides the earth between latitudes −80° and 84° * into 60 zones numbered 1 thru 60. Zone assign zone number 0 to the UPS * regions, covering the two poles. Within UTMUPS, non-negative zone * numbers refer to one of the "physical" zones, 0 for UPS and [1, 60] for * UTM. Negative "pseudo-zone" numbers are used to select one of the * physical zones. **********************************************************************/ enum zonespec { /** * The smallest pseudo-zone number. **********************************************************************/ MINPSEUDOZONE = -4, /** * A marker for an undefined or invalid zone. Equivalent to NaN. **********************************************************************/ INVALID = -4, /** * If a coordinate already include zone information (e.g., it is an MGRS * coordinate), use that, otherwise apply the UTMUPS::STANDARD rules. **********************************************************************/ MATCH = -3, /** * Apply the standard rules for UTM zone assigment extending the UTM zone * to each pole to give a zone number in [1, 60]. For example, use UTM * zone 38 for longitude in [42°, 48°). The rules include the * Norway and Svalbard exceptions. **********************************************************************/ UTM = -2, /** * Apply the standard rules for zone assignment to give a zone number in * [0, 60]. If the latitude is not in [−80°, 84°), then * use UTMUPS::UPS = 0, otherwise apply the rules for UTMUPS::UTM. The * tests on latitudes and longitudes are all closed on the lower end open * on the upper. Thus for UTM zone 38, latitude is in [−80°, * 84°) and longitude is in [42°, 48°). **********************************************************************/ STANDARD = -1, /** * The largest pseudo-zone number. **********************************************************************/ MAXPSEUDOZONE = -1, /** * The smallest physical zone number. **********************************************************************/ MINZONE = 0, /** * The zone number used for UPS **********************************************************************/ UPS = 0, /** * The smallest UTM zone number. **********************************************************************/ MINUTMZONE = 1, /** * The largest UTM zone number. **********************************************************************/ MAXUTMZONE = 60, /** * The largest physical zone number. **********************************************************************/ MAXZONE = 60, }; /** * The standard zone. * * @param[in] lat latitude (degrees). * @param[in] lon longitude (degrees). * @param[in] setzone zone override (optional). If omitted, use the * standard rules for picking the zone. If \e setzone is given then use * that zone if it is non-negative, otherwise apply the rules given in * UTMUPS::zonespec. * @exception GeographicErr if \e setzone is outside the range * [UTMUPS::MINPSEUDOZONE, UTMUPS::MAXZONE] = [−4, 60]. * * This is exact. **********************************************************************/ static int StandardZone(real lat, real lon, int setzone = STANDARD); /** * Forward projection, from geographic to UTM/UPS. * * @param[in] lat latitude of point (degrees). * @param[in] lon longitude of point (degrees). * @param[out] zone the UTM zone (zero means UPS). * @param[out] northp hemisphere (true means north, false means south). * @param[out] x easting of point (meters). * @param[out] y northing of point (meters). * @param[out] gamma meridian convergence at point (degrees). * @param[out] k scale of projection at point. * @param[in] setzone zone override (optional). * @param[in] mgrslimits if true enforce the stricter MGRS limits on the * coordinates (default = false). * @exception GeographicErr if \e lat is not in [−90°, * 90°]. * @exception GeographicErr if the resulting \e x or \e y is out of allowed * range (see Reverse); in this case, these arguments are unchanged. * * If \e setzone is omitted, use the standard rules for picking the zone. * If \e setzone is given then use that zone if it is non-negative, * otherwise apply the rules given in UTMUPS::zonespec. The accuracy of * the conversion is about 5nm. * * The northing \e y jumps by UTMUPS::UTMShift() when crossing the equator * in the southerly direction. Sometimes it is useful to remove this * discontinuity in \e y by extending the "northern" hemisphere using * UTMUPS::Transfer: * \code double lat = -1, lon = 123; int zone; bool northp; double x, y, gamma, k; GeographicLib::UTMUPS::Forward(lat, lon, zone, northp, x, y, gamma, k); GeographicLib::UTMUPS::Transfer(zone, northp, x, y, zone, true, x, y, zone); northp = true; \endcode **********************************************************************/ static void Forward(real lat, real lon, int& zone, bool& northp, real& x, real& y, real& gamma, real& k, int setzone = STANDARD, bool mgrslimits = false); /** * Reverse projection, from UTM/UPS to geographic. * * @param[in] zone the UTM zone (zero means UPS). * @param[in] northp hemisphere (true means north, false means south). * @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] gamma meridian convergence at point (degrees). * @param[out] k scale of projection at point. * @param[in] mgrslimits if true enforce the stricter MGRS limits on the * coordinates (default = false). * @exception GeographicErr if \e zone, \e x, or \e y is out of allowed * range; this this case the arguments are unchanged. * * The accuracy of the conversion is about 5nm. * * UTM eastings are allowed to be in the range [0km, 1000km], northings are * allowed to be in in [0km, 9600km] for the northern hemisphere and in * [900km, 10000km] for the southern hemisphere. However UTM northings * can be continued across the equator. So the actual limits on the * northings are [-9100km, 9600km] for the "northern" hemisphere and * [900km, 19600km] for the "southern" hemisphere. * * UPS eastings and northings are allowed to be in the range [1200km, * 2800km] in the northern hemisphere and in [700km, 3300km] in the * southern hemisphere. * * These ranges are 100km larger than allowed for the conversions to MGRS. * (100km is the maximum extra padding consistent with eastings remaining * non-negative.) This allows generous overlaps between zones and UTM and * UPS. If \e mgrslimits = true, then all the ranges are shrunk by 100km * so that they agree with the stricter MGRS ranges. No checks are * performed besides these (e.g., to limit the distance outside the * standard zone boundaries). **********************************************************************/ static void Reverse(int zone, bool northp, real x, real y, real& lat, real& lon, real& gamma, real& k, bool mgrslimits = false); /** * UTMUPS::Forward without returning convergence and scale. **********************************************************************/ static void Forward(real lat, real lon, int& zone, bool& northp, real& x, real& y, int setzone = STANDARD, bool mgrslimits = false) { real gamma, k; Forward(lat, lon, zone, northp, x, y, gamma, k, setzone, mgrslimits); } /** * UTMUPS::Reverse without returning convergence and scale. **********************************************************************/ static void Reverse(int zone, bool northp, real x, real y, real& lat, real& lon, bool mgrslimits = false) { real gamma, k; Reverse(zone, northp, x, y, lat, lon, gamma, k, mgrslimits); } /** * Transfer UTM/UPS coordinated from one zone to another. * * @param[in] zonein the UTM zone for \e xin and \e yin (or zero for UPS). * @param[in] northpin hemisphere for \e xin and \e yin (true means north, * false means south). * @param[in] xin easting of point (meters) in \e zonein. * @param[in] yin northing of point (meters) in \e zonein. * @param[in] zoneout the requested UTM zone for \e xout and \e yout (or * zero for UPS). * @param[in] northpout hemisphere for \e xout output and \e yout. * @param[out] xout easting of point (meters) in \e zoneout. * @param[out] yout northing of point (meters) in \e zoneout. * @param[out] zone the actual UTM zone for \e xout and \e yout (or zero * for UPS); this equals \e zoneout if \e zoneout ≥ 0. * @exception GeographicErr if \e zonein is out of range (see below). * @exception GeographicErr if \e zoneout is out of range (see below). * @exception GeographicErr if \e xin or \e yin fall outside their allowed * ranges (see UTMUPS::Reverse). * @exception GeographicErr if \e xout or \e yout fall outside their * allowed ranges (see UTMUPS::Reverse). * * \e zonein must be in the range [UTMUPS::MINZONE, UTMUPS::MAXZONE] = [0, * 60] with \e zonein = UTMUPS::UPS, 0, indicating UPS. \e zonein may * also be UTMUPS::INVALID. * * \e zoneout must be in the range [UTMUPS::MINPSEUDOZONE, UTMUPS::MAXZONE] * = [-4, 60]. If \e zoneout < UTMUPS::MINZONE then the rules give in * the documentation of UTMUPS::zonespec are applied, and \e zone is set to * the actual zone used for output. * * (\e xout, \e yout) can overlap with (\e xin, \e yin). **********************************************************************/ static void Transfer(int zonein, bool northpin, real xin, real yin, int zoneout, bool northpout, real& xout, real& yout, int& zone); /** * Decode a UTM/UPS zone string. * * @param[in] zonestr string representation of zone and hemisphere. * @param[out] zone the UTM zone (zero means UPS). * @param[out] northp hemisphere (true means north, false means south). * @exception GeographicErr if \e zonestr is malformed. * * For UTM, \e zonestr has the form of a zone number in the range * [UTMUPS::MINUTMZONE, UTMUPS::MAXUTMZONE] = [1, 60] followed by a * hemisphere letter, n or s (or "north" or "south" spelled out). For UPS, * it consists just of the hemisphere letter (or the spelled out * hemisphere). The returned value of \e zone is UTMUPS::UPS = 0 for UPS. * Note well that "38s" indicates the southern hemisphere of zone 38 and * not latitude band S, 32° ≤ \e lat < 40°. n, 01s, 2n, 38s, * south, 3north are legal. 0n, 001s, +3n, 61n, 38P are illegal. INV is a * special value for which the returned value of \e is UTMUPS::INVALID. **********************************************************************/ static void DecodeZone(const std::string& zonestr, int& zone, bool& northp); /** * Encode a UTM/UPS zone string. * * @param[in] zone the UTM zone (zero means UPS). * @param[in] northp hemisphere (true means north, false means south). * @param[in] abbrev if true (the default) use abbreviated (n/s) notation * for hemisphere; otherwise spell out the hemisphere (north/south) * @exception GeographicErr if \e zone is out of range (see below). * @exception std::bad_alloc if memoy for the string can't be allocated. * @return string representation of zone and hemisphere. * * \e zone must be in the range [UTMUPS::MINZONE, UTMUPS::MAXZONE] = [0, * 60] with \e zone = UTMUPS::UPS, 0, indicating UPS (but the resulting * string does not contain "0"). \e zone may also be UTMUPS::INVALID, in * which case the returned string is "inv". This reverses * UTMUPS::DecodeZone. **********************************************************************/ static std::string EncodeZone(int zone, bool northp, bool abbrev = true); /** * Decode EPSG. * * @param[in] epsg the EPSG code. * @param[out] zone the UTM zone (zero means UPS). * @param[out] northp hemisphere (true means north, false means south). * * EPSG (European Petroleum Survery Group) codes are a way to refer to many * different projections. DecodeEPSG decodes those referring to UTM or UPS * projections for the WGS84 ellipsoid. If the code does not refer to one * of these projections, \e zone is set to UTMUPS::INVALID. See * https://www.spatialreference.org/ref/epsg/ **********************************************************************/ static void DecodeEPSG(int epsg, int& zone, bool& northp); /** * Encode zone as EPSG. * * @param[in] zone the UTM zone (zero means UPS). * @param[in] northp hemisphere (true means north, false means south). * @return EPSG code (or -1 if \e zone is not in the range * [UTMUPS::MINZONE, UTMUPS::MAXZONE] = [0, 60]) * * Convert \e zone and \e northp to the corresponding EPSG (European * Petroleum Survery Group) codes **********************************************************************/ static int EncodeEPSG(int zone, bool northp); /** * @return shift (meters) necessary to align north and south halves of a * UTM zone (107). **********************************************************************/ static Math::real UTMShift(); /** \name Inspector functions **********************************************************************/ ///@{ /** * @return \e a the equatorial radius of the WGS84 ellipsoid (meters). * * (The WGS84 value is returned because the UTM and UPS projections are * based on this ellipsoid.) **********************************************************************/ static Math::real EquatorialRadius() { return Constants::WGS84_a(); } /** * @return \e f the flattening of the WGS84 ellipsoid. * * (The WGS84 value is returned because the UTM and UPS projections are * based on this ellipsoid.) **********************************************************************/ static Math::real Flattening() { return Constants::WGS84_f(); } /** * \deprecated An old name for EquatorialRadius(). **********************************************************************/ // GEOGRAPHICLIB_DEPRECATED("Use EquatorialRadius()") static Math::real MajorRadius() { return EquatorialRadius(); } ///@} }; } // namespace GeographicLib #endif // GEOGRAPHICLIB_UTMUPS_HPP