// License: GPL. For details, see LICENSE file. package org.openstreetmap.josm.data.projection.proj; import static java.lang.Math.PI; import static java.lang.Math.abs; import static java.lang.Math.asin; import static java.lang.Math.atan; import static java.lang.Math.cos; import static java.lang.Math.exp; import static java.lang.Math.log; import static java.lang.Math.pow; import static java.lang.Math.sin; import static java.lang.Math.sqrt; import static java.lang.Math.tan; import static org.openstreetmap.josm.tools.I18n.tr; import org.openstreetmap.josm.data.Bounds; import org.openstreetmap.josm.data.projection.Ellipsoid; import org.openstreetmap.josm.data.projection.ProjectionConfigurationException; import org.openstreetmap.josm.tools.Utils; /** * Implementation of the stereographic double projection, * also known as Oblique Stereographic and the Schreiber double stereographic projection. * * @author vholten * * Source: IOGP Publication 373-7-2 – Geomatics Guidance Note number 7, part 2, * Sec. 1.3.7.1 Oblique and Equatorial Stereographic, http://www.epsg.org/GuidanceNotes */ public class DoubleStereographic extends AbstractProj { private Ellipsoid ellps; private double n; private double c; private double chi0; private double r; private static final double EPSILON = 1e-12; @Override public String getName() { return tr("Double Stereographic"); } @Override public String getProj4Id() { return "sterea"; } @Override public void initialize(ProjParameters params) throws ProjectionConfigurationException { super.initialize(params); if (params.lat0 == null) throw new ProjectionConfigurationException(tr("Parameter ''{0}'' required.", "lat_0")); ellps = params.ellps; initialize(params.lat0); } private void initialize(double lat0) { double phi0 = Utils.toRadians(lat0); double e2 = ellps.e2; r = sqrt(1-e2) / (1 - e2*pow(sin(phi0), 2)); n = sqrt(1 + ellps.eb2 * pow(cos(phi0), 4)); double s1 = (1 + sin(phi0)) / (1 - sin(phi0)); double s2 = (1 - e * sin(phi0)) / (1 + e * sin(phi0)); double w1 = pow(s1 * pow(s2, e), n); double sinchi00 = (w1 - 1) / (w1 + 1); c = (n + sin(phi0)) * (1 - sinchi00) / ((n - sin(phi0)) * (1 + sinchi00)); double w2 = c * w1; chi0 = asin((w2 - 1) / (w2 + 1)); } @Override public double[] project(double phi, double lambda) { double nLambda = n * lambda; double sa = (1 + sin(phi)) / (1 - sin(phi)); double sb = (1 - e * sin(phi)) / (1 + e * sin(phi)); double w = c * pow(sa * pow(sb, e), n); double chi = asin((w - 1) / (w + 1)); double b = 1 + sin(chi) * sin(chi0) + cos(chi) * cos(chi0) * cos(nLambda); double x = 2 * r * cos(chi) * sin(nLambda) / b; double y = 2 * r * (sin(chi) * cos(chi0) - cos(chi) * sin(chi0) * cos(nLambda)) / b; return new double[] {x, y}; } @Override public double[] invproject(double x, double y) { double e2 = ellps.e2; double g = 2 * r * tan(PI/4 - chi0/2); double h = 4 * r * tan(chi0) + g; double i = atan(x/(h + y)); double j = atan(x/(g - y)) - i; double chi = chi0 + 2 * atan((y - x * tan(j/2)) / (2 * r)); double lambda = (j + 2*i) / n; double psi = 0.5 * log((1 + sin(chi)) / (c*(1 - sin(chi)))) / n; double phiprev = -1000; int iteration = 0; double phi = 2 * atan(exp(psi)) - PI/2; while (abs(phi - phiprev) > EPSILON) { if (++iteration > 10) throw new IllegalStateException("Too many iterations"); phiprev = phi; double psii = log(tan(phi/2 + PI/4) * pow((1 - e * sin(phi)) / (1 + e * sin(phi)), e/2)); phi = phi - (psii - psi) * cos(phi) * (1 - e2 * pow(sin(phi), 2)) / (1 - e2); } return new double[] {phi, lambda}; } @Override public Bounds getAlgorithmBounds() { return new Bounds(-89, -87, 89, 87, false); } }