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181 lines
No EOL
6.4 KiB
JavaScript
181 lines
No EOL
6.4 KiB
JavaScript
/**
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* Contains methods for transforming point on sphere to
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* Cartesian coordinates using various projections.
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* @class
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*/
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jvm.Proj = {
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degRad: 180 / Math.PI,
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radDeg: Math.PI / 180,
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radius: 6381372,
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sgn: function(n){
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if (n > 0) {
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return 1;
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} else if (n < 0) {
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return -1;
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} else {
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return n;
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}
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},
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/**
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* Converts point on sphere to the Cartesian coordinates using Miller projection
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* @param {Number} lat Latitude in degrees
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* @param {Number} lng Longitude in degrees
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* @param {Number} c Central meridian in degrees
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*/
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mill: function(lat, lng, c){
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return {
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x: this.radius * (lng - c) * this.radDeg,
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y: - this.radius * Math.log(Math.tan((45 + 0.4 * lat) * this.radDeg)) / 0.8
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};
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},
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/**
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* Inverse function of mill()
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* Converts Cartesian coordinates to point on sphere using Miller projection
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* @param {Number} x X of point in Cartesian system as integer
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* @param {Number} y Y of point in Cartesian system as integer
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* @param {Number} c Central meridian in degrees
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*/
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mill_inv: function(x, y, c){
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return {
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lat: (2.5 * Math.atan(Math.exp(0.8 * y / this.radius)) - 5 * Math.PI / 8) * this.degRad,
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lng: (c * this.radDeg + x / this.radius) * this.degRad
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};
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},
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/**
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* Converts point on sphere to the Cartesian coordinates using Mercator projection
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* @param {Number} lat Latitude in degrees
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* @param {Number} lng Longitude in degrees
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* @param {Number} c Central meridian in degrees
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*/
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merc: function(lat, lng, c){
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return {
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x: this.radius * (lng - c) * this.radDeg,
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y: - this.radius * Math.log(Math.tan(Math.PI / 4 + lat * Math.PI / 360))
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};
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},
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/**
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* Inverse function of merc()
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* Converts Cartesian coordinates to point on sphere using Mercator projection
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* @param {Number} x X of point in Cartesian system as integer
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* @param {Number} y Y of point in Cartesian system as integer
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* @param {Number} c Central meridian in degrees
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*/
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merc_inv: function(x, y, c){
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return {
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lat: (2 * Math.atan(Math.exp(y / this.radius)) - Math.PI / 2) * this.degRad,
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lng: (c * this.radDeg + x / this.radius) * this.degRad
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};
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},
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/**
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* Converts point on sphere to the Cartesian coordinates using Albers Equal-Area Conic
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* projection
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* @see <a href="http://mathworld.wolfram.com/AlbersEqual-AreaConicProjection.html">Albers Equal-Area Conic projection</a>
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* @param {Number} lat Latitude in degrees
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* @param {Number} lng Longitude in degrees
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* @param {Number} c Central meridian in degrees
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*/
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aea: function(lat, lng, c){
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var fi0 = 0,
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lambda0 = c * this.radDeg,
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fi1 = 29.5 * this.radDeg,
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fi2 = 45.5 * this.radDeg,
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fi = lat * this.radDeg,
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lambda = lng * this.radDeg,
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n = (Math.sin(fi1)+Math.sin(fi2)) / 2,
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C = Math.cos(fi1)*Math.cos(fi1)+2*n*Math.sin(fi1),
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theta = n*(lambda-lambda0),
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ro = Math.sqrt(C-2*n*Math.sin(fi))/n,
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ro0 = Math.sqrt(C-2*n*Math.sin(fi0))/n;
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return {
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x: ro * Math.sin(theta) * this.radius,
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y: - (ro0 - ro * Math.cos(theta)) * this.radius
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};
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},
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/**
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* Converts Cartesian coordinates to the point on sphere using Albers Equal-Area Conic
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* projection
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* @see <a href="http://mathworld.wolfram.com/AlbersEqual-AreaConicProjection.html">Albers Equal-Area Conic projection</a>
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* @param {Number} x X of point in Cartesian system as integer
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* @param {Number} y Y of point in Cartesian system as integer
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* @param {Number} c Central meridian in degrees
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*/
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aea_inv: function(xCoord, yCoord, c){
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var x = xCoord / this.radius,
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y = yCoord / this.radius,
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fi0 = 0,
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lambda0 = c * this.radDeg,
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fi1 = 29.5 * this.radDeg,
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fi2 = 45.5 * this.radDeg,
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n = (Math.sin(fi1)+Math.sin(fi2)) / 2,
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C = Math.cos(fi1)*Math.cos(fi1)+2*n*Math.sin(fi1),
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ro0 = Math.sqrt(C-2*n*Math.sin(fi0))/n,
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ro = Math.sqrt(x*x+(ro0-y)*(ro0-y)),
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theta = Math.atan( x / (ro0 - y) );
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return {
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lat: (Math.asin((C - ro * ro * n * n) / (2 * n))) * this.degRad,
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lng: (lambda0 + theta / n) * this.degRad
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};
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},
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/**
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* Converts point on sphere to the Cartesian coordinates using Lambert conformal
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* conic projection
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* @see <a href="http://mathworld.wolfram.com/LambertConformalConicProjection.html">Lambert Conformal Conic Projection</a>
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* @param {Number} lat Latitude in degrees
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* @param {Number} lng Longitude in degrees
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* @param {Number} c Central meridian in degrees
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*/
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lcc: function(lat, lng, c){
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var fi0 = 0,
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lambda0 = c * this.radDeg,
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lambda = lng * this.radDeg,
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fi1 = 33 * this.radDeg,
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fi2 = 45 * this.radDeg,
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fi = lat * this.radDeg,
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n = Math.log( Math.cos(fi1) * (1 / Math.cos(fi2)) ) / Math.log( Math.tan( Math.PI / 4 + fi2 / 2) * (1 / Math.tan( Math.PI / 4 + fi1 / 2) ) ),
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F = ( Math.cos(fi1) * Math.pow( Math.tan( Math.PI / 4 + fi1 / 2 ), n ) ) / n,
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ro = F * Math.pow( 1 / Math.tan( Math.PI / 4 + fi / 2 ), n ),
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ro0 = F * Math.pow( 1 / Math.tan( Math.PI / 4 + fi0 / 2 ), n );
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return {
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x: ro * Math.sin( n * (lambda - lambda0) ) * this.radius,
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y: - (ro0 - ro * Math.cos( n * (lambda - lambda0) ) ) * this.radius
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};
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},
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/**
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* Converts Cartesian coordinates to the point on sphere using Lambert conformal conic
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* projection
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* @see <a href="http://mathworld.wolfram.com/LambertConformalConicProjection.html">Lambert Conformal Conic Projection</a>
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* @param {Number} x X of point in Cartesian system as integer
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* @param {Number} y Y of point in Cartesian system as integer
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* @param {Number} c Central meridian in degrees
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*/
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lcc_inv: function(xCoord, yCoord, c){
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var x = xCoord / this.radius,
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y = yCoord / this.radius,
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fi0 = 0,
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lambda0 = c * this.radDeg,
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fi1 = 33 * this.radDeg,
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fi2 = 45 * this.radDeg,
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n = Math.log( Math.cos(fi1) * (1 / Math.cos(fi2)) ) / Math.log( Math.tan( Math.PI / 4 + fi2 / 2) * (1 / Math.tan( Math.PI / 4 + fi1 / 2) ) ),
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F = ( Math.cos(fi1) * Math.pow( Math.tan( Math.PI / 4 + fi1 / 2 ), n ) ) / n,
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ro0 = F * Math.pow( 1 / Math.tan( Math.PI / 4 + fi0 / 2 ), n ),
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ro = this.sgn(n) * Math.sqrt(x*x+(ro0-y)*(ro0-y)),
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theta = Math.atan( x / (ro0 - y) );
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return {
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lat: (2 * Math.atan(Math.pow(F/ro, 1/n)) - Math.PI / 2) * this.degRad,
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lng: (lambda0 + theta / n) * this.degRad
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};
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}
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}; |