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I have some earth-centered coordinate points given as latitude and longitude (WGS-84).

How can i convert them to Cartesian coordinates (x,y,z) with the origin at the center of the earth?

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6 Answers 6

up vote 20 down vote accepted

I have recently done something similar to this using the "Haversine Formula" on WGS-84 data, which is a derivative of the "Law of Haversines" with very satisfying results.

Yes, WGS-84 assumes the Earth is an ellipsoid, but I believe you only get about a 0.5% average error using an approach like the "Haversine Formula", which may be an acceptable amount of error in your case. You will always have some amount of error unless you're talking about a distance of a few feet and even then there is theoretically curvature of the Earth... If you require more rigidly WGS-84 compatible approach checkout the "Vincenty Formula."

I understand where starblue is coming from, but good software engineering is often about trade offs, so it all depends on the accuracy you require for what you are doing. For example, the result calculated from "Manhattan Distance Formula" versus the result from the "Distance Formula" can be better for certain situations as it is computationally less expensive. Think "which point is closest?" scenarios where you don't need a precise distance measurement.

Regarding, the "Haversine Formula" it is easy to implement and is nice because it is uses "Spherical Trigonometry" instead of a "Law of Cosines" based approach which is based on two-dimensional trigonometry, therefore you get a nice balance of accuracy over complexity.

A gentlemen by the name of Chris Veness has a great website at http://www.movable-type.co.uk/scripts/latlong.html that explains some the concepts you are interested in and demonstrates various programmatic implementations; this should answer your x/y conversion question as well.

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0.5% error - 0.5% of what? In the context of this question it could be the radius of the earth, so 0.5% could be 30 km :) –  MarkJ Jul 27 '09 at 16:50
1  
Checked out your link. The 0.5% quote is for error in the great-circle distance between two points so not strictly relevant to this question. I would think when converting lat-long to Cartesian coordinates with the origin at the centre of the earth, the errors from assuming a spherical earth could be significant. It's not clear what the questionner wants to do with the Cartesian coordinates. Either it's just more convenient to work in them for some bizarre reason, or perhaps it's some requirement for data export? If the latter, accuracy would be important. –  MarkJ Jul 27 '09 at 16:56

Here's the answer I found:

Just to make the definition complete, in the Cartesian coordinate system:

  • the x-axis goes through long,lat (0,0), so longitude 0 meets the equator;
  • the y-axis goes through (0,90);
  • and the z-axis goes through the poles.

The conversion is:

x = R * cos(lat) * cos(lon)

y = R * cos(lat) * sin(lon)

z = R *sin(lat)

Where R is the approximate radius of earth (e.g. 6371KM).

If your trigonometric functions expect radians (which they probably do), you will need to convert your longitude and latitude to radians first. You obviously need a decimal representation, not degrees\minutes\seconds (see e.g. here about conversion).

The formula for back conversion:

   lat = asin(z / R)
   lon = atan2(y, x)

asin is of course arc sine. read about atan2 in wikipedia. Don’t forget to convert back from radians to degrees.

This page gives c# code for this (note that it is very different from the formulas), and also some explanation and nice diagram of why this is correct,

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6  
-1 This is wrong. You are assuming the earth is a sphere, while WGS-84 assumes an ellipsoid. –  starblue Jul 26 '09 at 20:21
7  
@starblue: I'm not sure you are in a position to label the given answer "right" or "wrong". The spherical approximation (to get ECEF-style x,y,z coords) using available lat/lngs (that are referenced to WGS-84) is either "adequate" for the original poster's needs, or "not adequate". For distance and bearing estimates, I'd bet this simple conversion is fine. If he is launching satellites, maybe not. After all, WGS-84 itself is "wrong"... in that it is not a perfect model of the earth's surface; all ellipsoidal models are approximations. Too bad the OP didn't tell us what he was trying to do. –  Dan H Jul 6 '12 at 13:54
5  
@Dan H The question asks for WGS-84, and if you answer something else you should at least discuss the differences/error, which this answer doesn't. –  starblue Jul 6 '12 at 20:48
    
@daphna-shezaf can't make a back conversion... I have done also the back from radians to degrees, but result is not the same... –  Gelo Volro Oct 11 '13 at 8:48

Why implement something which has already been implemented and test-proven?

C#, for one, has the NetTopologySuite which is the .NET port of the JTS Topology Suite.

Specifically, you have a severe flaw in your calculation. The earth is not a perfect sphere, and the approximation of the earth's radius might not cut it for precise measurements.

If in some cases it's acceptable to use homebrew functions, GIS is a good example of a field in which it is much preferred to use a reliable, test-proven library.

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+1. Using a reliable library is more accurate than a homebrew function and also easier. –  MarkJ Jul 27 '09 at 16:49
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How does NetTopologySuite convert from long/late to cartesion? –  vinayan Jan 10 '13 at 16:54
    
NTS doesn't include coordinate conversion capabilities, maybe you need Proj.NET projnet.codeplex.com –  D_Guidi Jun 10 at 14:24
Coordinate[] coordinates = new Coordinate[3];
coordinates[0] = new Coordinate(102, 26);
coordinates[1] = new Coordinate(103, 25.12);
coordinates[2] = new Coordinate(104, 16.11);
CoordinateSequence coordinateSequence = new CoordinateArraySequence(coordinates);

Geometry geo = new LineString(coordinateSequence, geometryFactory);

CoordinateReferenceSystem wgs84 = DefaultGeographicCRS.WGS84;
CoordinateReferenceSystem cartesinaCrs = DefaultGeocentricCRS.CARTESIAN;

MathTransform mathTransform = CRS.findMathTransform(wgs84, cartesinaCrs, true);

Geometry geo1 = JTS.transform(geo, mathTransform);
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Would you be able to elaborate? I created a simple application that tiers to transform a single coordinate using your approach. It always fails though as the dimensions of the source (2) and the dimensions of the target (3) differ, resulting in an exception java.lang.IllegalArgumentException: dimension must be <= 3 –  oschrenk May 25 '12 at 12:48
    
Hmmm... I've looked at JTS for a bit. The lines upto and including the new LineString() look like JTS. But I don't see the CRS and Transform stuff in JTS. So: are they there and I'm missing them? Were there, and removed in 1.12? Or: is that a different library? –  Dan H Jul 6 '12 at 3:15

If you care about getting coordinates based on an ellipsoid rather than a sphere, take a look at http://en.wikipedia.org/wiki/Geodetic_system#From_geodetic_to_ECEF - it gives the formulae as well as the WGS84 constants you need for the conversion.

The formulae there also take into account the altitude relative to the reference ellipsoid surface (useful if you are getting altitude data from a GPS device).

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Theory for convert GPS(WGS84) to Cartesian coordinates http://en.wikipedia.org/wiki/Geodetic_system#From_geodetic_to_ECEF

The following is what I am using:

  • Longitude in GPS(WGS84) and Cartesian coordinates are the same.
  • Latitude need be converted by WGS 84 ellipsoid parameters semi-major axis is 6378137 m, and
  • Reciprocal of flattening is 298.257223563.

I attached a VB code I wrote:

Imports System.Math

'Input GPSLatitude is WGS84 Latitude,h is altitude above the WGS 84 ellipsoid

Public Function GetSphericalLatitude(ByVal GPSLatitude As Double, ByVal h As Double) As Double

        Dim A As Double = 6378137 'semi-major axis 
        Dim f As Double = 1 / 298.257223563  '1/f Reciprocal of flattening
        Dim e2 As Double = f * (2 - f)
        Dim Rc As Double = A / (Sqrt(1 - (e2 ^ 2) * (Sin(GPSLatitude * PI / 180) ^ 2)))
        Dim p As Double = (Rc + h) * Cos(GPSLatitude * PI / 180)
        Dim z As Double = (Rc * (1 - e2 ^ 2) + h) * Sin(GPSLatitude * PI / 180)
        Dim r As Double = Sqrt(p ^ 2 + z ^ 2)
        Dim SphericalLatitude As Double =  Asin(z / r) * 180 / PI
        Return SphericalLatitude
End Function

Please notice that the h is altitude above the WGS 84 ellipsoid.

Usually GPS will give us H of above MSL height. The MSL height has to be converted to height h above the WGS 84 ellipsoid by using the geopotential model EGM96 (Lemoine et al, 1998).
This is done by interpolating a grid of the geoid height file with a spatial resolution of 15 arc-minutes.

Or if you have some level professional GPS has Altitude H (msl,heigh above mean sea level) and UNDULATION,the relationship between the geoid and the ellipsoid (m) of the chosen datum output from internal table. you can get h = H(msl) + undulation

To XYZ by Cartesian coordinates:

x = R * cos(lat) * cos(lon)

y = R * cos(lat) * sin(lon)

z = R *sin(lat)
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