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Added support for Albers Equal-Area projection
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@ -92,7 +92,8 @@ HEADERS += src/config.h \
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src/ellipsoid.h \
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src/ozf.h \
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src/datum.h \
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src/maplist.h
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src/maplist.h \
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src/albersequal.h
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SOURCES += src/main.cpp \
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src/gui.cpp \
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src/poi.cpp \
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@ -158,7 +159,8 @@ SOURCES += src/main.cpp \
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src/ellipsoid.cpp \
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src/ozf.cpp \
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src/datum.cpp \
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src/maplist.cpp
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src/maplist.cpp \
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src/albersequal.cpp
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RESOURCES += gpxsee.qrc
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TRANSLATIONS = lang/gpxsee_cs.ts \
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lang/gpxsee_sv.ts \
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190
src/albersequal.cpp
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190
src/albersequal.cpp
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@ -0,0 +1,190 @@
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#include "ellipsoid.h"
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#include "rd.h"
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#include "albersequal.h"
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#ifndef M_PI_2
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#define M_PI_2 1.57079632679489661923
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#endif // M_PI_2
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#define ONE_MINUS_SQR(x) (1.0 - (x) * (x))
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#define ALBERS_Q(slat, one_minus_sqr_es_sin, es_sin) \
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(_one_minus_es2 * ((slat) / (one_minus_sqr_es_sin) - \
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(1 / (_two_es)) * log((1 - (es_sin)) / (1 + (es_sin)))))
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#define ALBERS_M(clat, one_minus_sqr_es_sin) \
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((clat) / sqrt(one_minus_sqr_es_sin))
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AlbersEqual::AlbersEqual(const Ellipsoid &ellipsoid, double standardParallel1,
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double standardParallel2, double latitudeOrigin, double longitudeOrigin,
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double falseEasting, double falseNorthing)
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{
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double sin_lat, sin_lat1, sin_lat2, cos_lat1, cos_lat2;
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double m1, m2, sqr_m1, sqr_m2;
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double q0, q1, q2;
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double es_sin, es_sin1, es_sin2;
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double one_minus_sqr_es_sin1, one_minus_sqr_es_sin2;
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double nq0;
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double sp1, sp2;
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_e = ellipsoid;
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_latitudeOrigin = deg2rad(latitudeOrigin);
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_longitudeOrigin = deg2rad(longitudeOrigin);
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_falseEasting = falseEasting;
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_falseNorthing = falseNorthing;
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sp1 = deg2rad(standardParallel1);
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sp2 = deg2rad(standardParallel2);
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if (_latitudeOrigin > M_PI)
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_latitudeOrigin -= M_PI * 2.0;
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_es2 = 2 * _e.flattening() - _e.flattening() * _e.flattening();
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_es = sqrt(_es2);
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_one_minus_es2 = 1 - _es2;
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_two_es = 2 * _es;
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sin_lat = sin(_latitudeOrigin);
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es_sin = _es * sin_lat;
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q0 = ALBERS_Q(sin_lat, ONE_MINUS_SQR(es_sin), es_sin);
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sin_lat1 = sin(sp1);
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cos_lat1 = cos(sp1);
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es_sin1 = _es * sin_lat1;
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one_minus_sqr_es_sin1 = ONE_MINUS_SQR(es_sin1);
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m1 = ALBERS_M(cos_lat1, one_minus_sqr_es_sin1);
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q1 = ALBERS_Q(sin_lat1, one_minus_sqr_es_sin1, es_sin1);
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sqr_m1 = m1 * m1;
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if (fabs(sp1 - sp2) > 1.0e-10) {
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sin_lat2 = sin(sp2);
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cos_lat2 = cos(sp2);
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es_sin2 = _es * sin_lat2;
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one_minus_sqr_es_sin2 = ONE_MINUS_SQR(es_sin2);
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m2 = ALBERS_M(cos_lat2, one_minus_sqr_es_sin2);
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q2 = ALBERS_Q(sin_lat2, one_minus_sqr_es_sin2, es_sin2);
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sqr_m2 = m2 * m2;
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_n = (sqr_m1 - sqr_m2) / (q2 - q1);
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} else
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_n = sin_lat1;
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_C = sqr_m1 + _n * q1;
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_a_over_n = _e.radius() / _n;
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nq0 = _n * q0;
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_rho0 = (_C < nq0) ? 0 : _a_over_n * sqrt(_C - nq0);
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}
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QPointF AlbersEqual::ll2xy(const Coordinates &c) const
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{
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double dlam;
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double sin_lat;
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double es_sin;
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double q;
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double rho;
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double theta;
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double nq;
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dlam = deg2rad(c.lon()) - _longitudeOrigin;
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if (dlam > M_PI)
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dlam -= 2.0 * M_PI;
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if (dlam < -M_PI)
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dlam += 2.0 * M_PI;
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sin_lat = sin(deg2rad(c.lat()));
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es_sin = _es * sin_lat;
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q = ALBERS_Q(sin_lat, ONE_MINUS_SQR(es_sin), es_sin);
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nq = _n * q;
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rho = (_C < nq) ? 0 : _a_over_n * sqrt(_C - nq);
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theta = _n * dlam;
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return QPointF(rho * sin(theta) + _falseEasting,
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_rho0 - rho * cos(theta) + _falseNorthing);
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}
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Coordinates AlbersEqual::xy2ll(const QPointF &p) const
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{
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double dy, dx;
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double rho0_minus_dy;
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double q, qc, q_over_2;
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double rho, rho_n;
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double phi, delta_phi = 1.0;
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double sin_phi;
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double es_sin, one_minus_sqr_es_sin;
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double theta = 0.0;
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int count = 30;
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double tolerance = 4.85e-10;
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double lat, lon;
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dy = p.y() - _falseNorthing;
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dx = p.x() - _falseEasting;
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rho0_minus_dy = _rho0 - dy;
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rho = sqrt(dx * dx + rho0_minus_dy * rho0_minus_dy);
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if (_n < 0) {
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rho *= -1.0;
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dy *= -1.0;
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dx *= -1.0;
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rho0_minus_dy *= -1.0;
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}
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if (rho != 0.0)
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theta = atan2(dx, rho0_minus_dy);
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rho_n = rho * _n;
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q = (_C - (rho_n * rho_n) / (_e.radius() * _e.radius())) / _n;
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qc = 1 - ((_one_minus_es2) / (_two_es)) * log((1.0 - _es) / (1.0 + _es));
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if (fabs(fabs(qc) - fabs(q)) > 1.0e-6) {
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q_over_2 = q / 2.0;
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if (q_over_2 > 1.0)
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lat = M_PI_2;
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else if (q_over_2 < -1.0)
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lat = -M_PI_2;
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else {
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phi = asin(q_over_2);
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if (_es < 1.0e-10)
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lat = phi;
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else {
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while ((fabs(delta_phi) > tolerance) && count) {
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sin_phi = sin(phi);
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es_sin = _es * sin_phi;
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one_minus_sqr_es_sin = ONE_MINUS_SQR(es_sin);
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delta_phi = (one_minus_sqr_es_sin * one_minus_sqr_es_sin)
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/ (2.0 * cos(phi)) * (q / (_one_minus_es2) - sin_phi
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/ one_minus_sqr_es_sin + (log((1.0 - es_sin)
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/ (1.0 + es_sin)) / (_two_es)));
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phi += delta_phi;
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count --;
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}
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lat = phi;
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}
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if (lat > M_PI_2)
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lat = M_PI_2;
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else if (lat < -M_PI_2)
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lat = -M_PI_2;
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}
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} else {
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if (q >= 0.0)
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lat = M_PI_2;
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else
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lat = -M_PI_2;
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}
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lon = _longitudeOrigin + theta / _n;
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if (lon > M_PI)
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lon -= M_PI * 2;
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if (lon < -M_PI)
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lon += M_PI * 2;
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if (lon > M_PI)
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lon = M_PI;
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else if (lon < -M_PI)
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lon = -M_PI;
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return Coordinates(rad2deg(lon), rad2deg(lat));
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}
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36
src/albersequal.h
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36
src/albersequal.h
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@ -0,0 +1,36 @@
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#ifndef ALBERSEQUAL_H
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#define ALBERSEQUAL_H
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#include "projection.h"
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class Ellipsoid;
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class AlbersEqual : public Projection
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{
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public:
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AlbersEqual(const Ellipsoid &ellipsoid, double standardParallel1,
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double standardParallel2, double latitudeOrigin, double longitudeOrigin,
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double falseEasting, double falseNorthing);
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virtual QPointF ll2xy(const Coordinates &c) const;
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virtual Coordinates xy2ll(const QPointF &p) const;
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private:
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Ellipsoid _e;
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double _latitudeOrigin;
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double _longitudeOrigin;
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double _falseEasting;
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double _falseNorthing;
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double _rho0;
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double _C;
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double _n;
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double _es;
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double _es2;
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double _a_over_n;
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double _one_minus_es2;
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double _two_es;
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};
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#endif // ALBERSEQUAL_H
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@ -18,6 +18,7 @@
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#include "transversemercator.h"
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#include "utm.h"
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#include "lambertconic.h"
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#include "albersequal.h"
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#include "ozf.h"
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#include "offlinemap.h"
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@ -25,8 +26,6 @@
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// Abridged Molodensky transformation
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static Coordinates toWGS84(Coordinates c, const Datum &datum)
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{
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Ellipsoid WGS84(WGS84_RADIUS, WGS84_FLATTENING);
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double dX = datum.dx();
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double dY = datum.dy();
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double dZ = datum.dz();
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@ -38,9 +37,9 @@ static Coordinates toWGS84(Coordinates c, const Datum &datum)
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double ssqlat = slat * slat;
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double from_f = datum.ellipsoid().flattening();
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double df = WGS84.flattening() - from_f;
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double df = WGS84_FLATTENING - from_f;
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double from_a = datum.ellipsoid().radius();
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double da = WGS84.radius() - from_a;
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double da = WGS84_RADIUS - from_a;
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double from_esq = datum.ellipsoid().flattening()
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* (2.0 - datum.ellipsoid().flattening());
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double adb = 1.0 / (1.0 - from_f);
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@ -219,6 +218,10 @@ bool OfflineMap::createProjection(const QString &datum,
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setup.standardParallel1, setup.standardParallel2,
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setup.latitudeOrigin, setup.longitudeOrigin, setup.scale,
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setup.falseEasting, setup.falseNorthing);
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else if (projection == "Albers Equal Area")
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_projection = new AlbersEqual(d.ellipsoid(), setup.standardParallel1,
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setup.standardParallel2, setup.latitudeOrigin, setup.longitudeOrigin,
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setup.falseEasting, setup.falseNorthing);
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else if (projection == "(UTM) Universal Transverse Mercator") {
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if (setup.zone)
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_projection = new UTM(d.ellipsoid(), setup.zone);
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