mirror of
https://github.com/ClemensFischer/XAML-Map-Control.git
synced 2026-02-06 15:54:14 +01:00
184 lines
6.6 KiB
C#
184 lines
6.6 KiB
C#
using System;
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#if WPF
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using System.Windows;
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using System.Windows.Media;
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#elif AVALONIA
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using Avalonia;
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#endif
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namespace MapControl
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{
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/// <summary>
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/// Transverse Mercator Projection. See
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/// https://en.wikipedia.org/wiki/Transverse_Mercator_projection,
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/// https://en.wikipedia.org/wiki/Universal_Transverse_Mercator_coordinate_system,
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/// https://en.wikipedia.org/wiki/Transverse_Mercator_projection#Convergence.
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/// </summary>
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public class TransverseMercatorProjection : MapProjection
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{
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private double a1; // α1
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private double a2; // α2
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private double a3; // α3
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private double b1; // β1
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private double b2; // β2
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private double b3; // β3
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private double d1; // δ1
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private double d2; // δ2
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private double d3; // δ3
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private double f1; // A/a
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private double f2; // 2*sqrt(n)/(1+n)
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public TransverseMercatorProjection()
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{
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Flattening = Wgs84Flattening;
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}
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public double Flattening
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{
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get;
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set
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{
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field = value;
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var n = field / (2d - field);
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var n2 = n * n;
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var n3 = n * n2;
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a1 = n / 2d - n2 * 2d / 3d + n3 * 5d / 16d;
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a2 = n2 * 13d / 48d - n3 * 3d / 5d;
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a3 = n3 * 61d / 240d;
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b1 = n / 2d - n2 * 2d / 3d + n3 * 37d / 96d;
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b2 = n2 / 48d + n3 / 15d;
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b3 = n3 * 17d / 480d;
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d1 = n * 2d - n2 * 2d / 3d - n3 * 2d;
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d2 = n2 * 7d / 3d - n3 * 8d / 5d;
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d3 = n3 * 56d / 15d;
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f1 = (1d + n2 / 4d + n2 * n2 / 64d) / (1d + n);
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f2 = 2d * Math.Sqrt(n) / (1d + n);
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}
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}
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public double ScaleFactor { get; set; } = 0.9996;
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public double FalseEasting { get; set; } = 5e5;
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public double FalseNorthing { get; set; }
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public override double GridConvergence(double latitude, double longitude)
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{
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// φ
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var phi = latitude * Math.PI / 180d;
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// λ - λ0
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var dLambda = (longitude - CentralMeridian) * Math.PI / 180d;
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// γ calculation for the sphere is sufficiently accurate
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//
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return Math.Atan(Math.Tan(dLambda) * Math.Sin(phi)) * 180d / Math.PI;
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}
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public override Matrix RelativeTransform(double latitude, double longitude)
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{
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// φ
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var phi = latitude * Math.PI / 180d;
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var sinPhi = Math.Sin(phi);
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// λ - λ0
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var dLambda = (longitude - CentralMeridian) * Math.PI / 180d;
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var cosLambda = Math.Cos(dLambda);
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var tanLambda = Math.Tan(dLambda);
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// t
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var t = Math.Sinh(Atanh(sinPhi) - f2 * Atanh(f2 * sinPhi));
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var u = Math.Sqrt(1d + t * t);
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// ξ'
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var xi_ = Math.Atan2(t, cosLambda);
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// η'
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var eta_ = Atanh(Math.Sin(dLambda) / u);
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// σ
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var sigma = 1 +
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2d * a1 * Math.Cos(2d * xi_) * Math.Cosh(2d * eta_) +
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4d * a2 * Math.Cos(4d * xi_) * Math.Cosh(4d * eta_) +
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6d * a3 * Math.Cos(6d * xi_) * Math.Cosh(6d * eta_);
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// τ
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var tau =
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2d * a1 * Math.Sin(2d * xi_) * Math.Sinh(2d * eta_) +
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4d * a2 * Math.Sin(4d * xi_) * Math.Sinh(4d * eta_) +
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6d * a3 * Math.Sin(6d * xi_) * Math.Sinh(6d * eta_);
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var n = Flattening / (2d - Flattening);
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var m = (1d - n) / (1d + n) * Math.Tan(phi);
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var k = ScaleFactor * f1 * Math.Sqrt((1d + m * m) * (sigma * sigma + tau * tau) / (t * t + cosLambda * cosLambda));
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// γ, grid convergence
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var gamma = Math.Atan2(tau * u + sigma * t * tanLambda, sigma * u - tau * t * tanLambda);
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var transform = new Matrix(k, 0d, 0d, k, 0d, 0d);
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transform.Rotate(-gamma * 180d / Math.PI);
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return transform;
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}
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public override Point LocationToMap(double latitude, double longitude)
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{
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// φ
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var phi = latitude * Math.PI / 180d;
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var sinPhi = Math.Sin(phi);
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// t
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var t = Math.Sinh(Atanh(sinPhi) - f2 * Atanh(f2 * sinPhi));
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// λ - λ0
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var dLambda = (longitude - CentralMeridian) * Math.PI / 180d;
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// ξ'
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var xi_ = Math.Atan2(t, Math.Cos(dLambda));
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// η'
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var eta_ = Atanh(Math.Sin(dLambda) / Math.Sqrt(1d + t * t));
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// k0 * A
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var k0A = ScaleFactor * EquatorialRadius * f1;
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var x = FalseEasting + k0A * (eta_ +
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a1 * Math.Cos(2d * xi_) * Math.Sinh(2d * eta_) +
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a2 * Math.Cos(4d * xi_) * Math.Sinh(4d * eta_) +
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a3 * Math.Cos(6d * xi_) * Math.Sinh(6d * eta_));
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var y = FalseNorthing + k0A * (xi_ +
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a1 * Math.Sin(2d * xi_) * Math.Cosh(2d * eta_) +
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a2 * Math.Sin(4d * xi_) * Math.Cosh(4d * eta_) +
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a3 * Math.Sin(6d * xi_) * Math.Cosh(6d * eta_));
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return new Point(x, y);
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}
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public override Location MapToLocation(double x, double y)
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{
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// k0 * A
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var k0A = ScaleFactor * EquatorialRadius * f1;
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// ξ
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var xi = (y - FalseNorthing) / k0A;
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// η
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var eta = (x - FalseEasting) / k0A;
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// ξ'
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var xi_ = xi -
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b1 * Math.Sin(2d * xi) * Math.Cosh(2d * eta) -
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b2 * Math.Sin(4d * xi) * Math.Cosh(4d * eta) -
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b3 * Math.Sin(6d * xi) * Math.Cosh(6d * eta);
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// η'
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var eta_ = eta -
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b1 * Math.Cos(2d * xi) * Math.Sinh(2d * eta) -
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b2 * Math.Cos(4d * xi) * Math.Sinh(4d * eta) -
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b3 * Math.Cos(6d * xi) * Math.Sinh(6d * eta);
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// χ
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var chi = Math.Asin(Math.Sin(xi_) / Math.Cosh(eta_));
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// φ
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var phi = chi +
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d1 * Math.Sin(2d * chi) +
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d2 * Math.Sin(4d * chi) +
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d3 * Math.Sin(6d * chi);
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// λ - λ0
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var dLambda = Math.Atan2(Math.Sinh(eta_), Math.Cos(xi_));
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return new Location(
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phi * 180d / Math.PI,
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dLambda * 180d / Math.PI + CentralMeridian);
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}
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#if NETFRAMEWORK
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private static double Atanh(double x) => Math.Log((1d + x) / (1d - x)) / 2d;
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#else
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private static double Atanh(double x) => Math.Atanh(x);
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#endif
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}
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}
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