# Algorithm to compute a Voronoi diagram on a sphere?

I'm looking for a simple (if exists) algorithm to find the Voronoi diagram for a set of points on the surface of a sphere. Source code would be great. I'm a Delphi man (yes, I know...), but I eat C-code too. TIA Steven

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I don't have ACM document access but there's a paper on spherical Voronoi diagrams.

Or if you grok Fortran (bleah!) there's this site.

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There is a great paper from 2011 describing a plane sweep algorithm (based on Fortune's algorithm for the plane): e-lc.org/tmp/Xiaoyu__Zheng_2011_12_05_14_35_11.pdf –  math Jul 15 '13 at 13:09

I think the Voronoi plane for each point can be constructed using non-Euclidian geometry. What was normally a line on a 2d plane, is now a 'great circle' on the sphere (see Wikipedia:elliptic geometry). It is easy to find which points are on the wrong side of any great circle between two points, by simply rotating the sphere such that the dividing great circle is the equator, and then it's all points on the other hemisphere than the point you're constructing the Voronoi plane for.

This is not the entire answer, but this is where I'd start..

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Notice that Delaunay triangulation on a sphere is just the convex hull. Thus you can compute the 3D convex hull (e.g. using CGAL) and take the dual.

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concerning special sphere package, it is not yet ready. Hopefully in CGAL 4.3 –  olivier Dec 20 '12 at 10:34

There is a paper from INRIA about the Delaunay Triangulation (DT) of points lying on a sphere: CAROLI, Manuel, et al. Robust and Efﬁcient Delaunay triangulations of points on or close to a sphere. 2009. where they talk about an implementation in CGAL.

The paper refers to various available implementation of DT algorithms.

Quoting from the paper:

An easy and standard answer consists in computing the 3D convex hull of the points, which is notoriously equivalent.

for computing the convex hull the paper suggests:

1. Hull, a program for convex hulls.
2. Qhull.
3. Three-dimensional convex hulls. in FORTRAN.Three-dimensional convex hulls.
4. STRIPACK in FORTRAN.

The DT C++ class of CGAL has the method dual to get the Voronoi Diagram.

According to this post by Monique Teillaud (one of the author of the above mentioned paper) it seems to me that in November 2012 the implementation was not still ready.

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There's a nice Voronoi diagram example program here (including source code for Delphi 5/6).

I think "points on the surface of a sphere" means that you first have to remap them to 2D-coordinates, create the Voronoi diagram and then remap them to sphere surface coordinates. Are the two formulas from Wikipedia UV mapping article working here?

Also notice that the Voronoi diagram will have the wrong topology (it is inside a rectangle and does not "wrap around"), here it could help to copy all the points from (0,0)-(x, y) to the neighbour regions above (0, -y * 2)-(x, 0), below (0, y)-(x, y * 2), left (-x, 0)-(0, y) and right (x, 0)-(x*2, y). I hope you know what I mean, feel free to ask :)

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I thought about remapping to a 2D plane but that doesn't work; AFAIK there's no sphere-to-plane mapping which preserves distance. Simple example: distances between any pair of vertices a regular tetrahedron are the same, but you can't draw this in a 2D plane. Thanks for your reply anyway. –  stevenvh Feb 13 '09 at 14:06
@stevenvh: The Delaunay triangulation seems to work as is after mapping the sphere to a plane (with eg polar projection: great circles go to circles, and being inside circumscribed circle will work equally for spherical and planar triangles). Then you go back to the sphere and dualize the graph. This would probably work. –  Alexandre C. Apr 15 '11 at 19:00
@stevenh: Technically you don't have to preserve distances, you just have preserve the ordering of all distances. Of course, I don't think even this is possible. –  wnoise Aug 4 '11 at 21:00

CGAL is working on the "spherical kernel" package, which would allow to compute exactly these kind of things. Unfortunately, is not released yet, but maybe it will be in their next release, since they already mentioned it in a google tech talk in march

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Has it accomplished by now? –  math Jul 15 '13 at 13:04

Quoting from this reference: http://www.qhull.org/html/qdelaun.htm

To compute the Delaunay triangulation of points on a sphere, compute their convex hull. If the sphere is the unit sphere at the origin, the facet normals are the Voronoi vertices of the input.

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Generally, the convex hull is different problem than the Delaunay triangulation. But QHull's algorithm for the convex hull delivers also the Delaunay triangulation which in is dual to the Voronoi diagram. –  math Jul 15 '13 at 13:07

It's been a while since the question has been answered, but I've found two papers that implement Fortune's algorithm (efficiency O(N lg N), memory O(N)) over the surface of the sphere. Maybe a future viewer will find this information useful.

I'm working through them myself at the moment, so I can't explain it well. The basic idea is that Fortune's algorithm works on the surface of the sphere so long as you calculate the points' bounding parabolas correctly. Because the surface of the sphere wraps, you can also use a circular list to contain the beach line and not worry about handling cells at the edge of rectangular space. With that, you can sweep from the north pole of the sphere to the south and back up again, skipping to sites that introduce new points to the beach line (adding a parabola to the beach line) or the introduction of cell vertices (removing a parabola from the beach line).

Both papers expect a high level of comfort with linear algebra to understand the concepts, and they both keep losing me at the point they start explaining the algorithm itself. Neither provide source code, unfortunately.

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