# Geoalgorithm for finding coordinates of point from a known location by distance and bearing

I'd like to use Google maps static API to display a map with a path overlay indicating a boundary.

AFAICT the static API doesn't support polygons, so I intend to circumvent this by drawing the boundary using paths.

To do this I need to determine the points to draw the straight lines (paths) between; so I'd like an algorithm that returns the geographic location (i.e. WGS84 coordinates) a given bearing and distance from a known point.

Can anyone point me to such an algorithm. Preferably in C#, but other languages are acceptable?

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It will be radians. Anything working with pi in angles is radians. –  Pete Kirkham Mar 29 '09 at 18:25
Many thanks Pete. –  Ben Mar 29 '09 at 18:27

You can draw polygon on a KML file, and then show the KML on Google maps.

Here's KML on Google maps (From Google KML Samples) check the "Google Campus - Polygons" section in the content.

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I have very limited experience with KML, but would this work with static maps? –  Ben Mar 29 '09 at 18:45
You can pass the KML file as a param of the static map. –  Shay Erlichmen Mar 29 '09 at 18:53

In (I think) every language I know, radians. Note that I think your example code is giving you co-ordinates based on a sphere, not on WGS84. Here's Java code for converting between co-ordinate systems.

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I implemented and tested it in C#, using Degrees as input/output instead of radians:

``````    static readonly double FullCircleDegrees = 360d;
static readonly double HalfCircleDegrees = FullCircleDegrees / 2d;

{
var lat1 = center.Lat * DegreesToRadians;
var lng1 = center.Lng * DegreesToRadians;
var lng = 0d;
if (Math.Cos(lat) == 0)
{
lng = lng1;
}
else
{
lng = ((lng1 + Math.PI - Math.Asin(Math.Sin(azimuth * DegreesToRadians) * Math.Sin(radius) / Math.Cos(lat1))) % (2 * Math.PI)) - Math.PI;
}
}
``````
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It works with 80% accuracy comparing to Great Circle Distance –  Jader Dias Jun 19 '09 at 18:52

Take a look at Gavaghan Geodesy C# library, it should be what you're looking for. And it's free.

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Found this (here: http://williams.best.vwh.net/avform.htm#LL):

A point {lat,lon} is a distance d out on the tc radial from point 1 if:

``````lat=asin(sin(lat1)*cos(d)+cos(lat1)*sin(d)*cos(tc))
IF (cos(lat)=0)
lon=lon1      // endpoint a pole
ELSE
lon=mod(lon1-asin(sin(tc)*sin(d)/cos(lat))+pi,2*pi)-pi
ENDIF
``````