The bigger picture is that I'm using QHULL to compute the convex hull of points on the sphere (which is a Delaunay Tesselation of the sphere's surface), and projecting Voronoi cells computed from the convex hull up to the surface of the sphere and then computing the area of associated with each node using spherical triangles http://mathworld.wolfram.com/SphericalTriangle.html (splitting each convex hull triangle into 6 fractional triangles and computing the area of the fractional spherical triangles separately, I'm getting the interior angle as the arc cosine of the dot product of unit vectors tangent to the surface of the sphere pointing from nodes to Voronoi vertexes and triangle edge midpoints), but I can deal with that complexity.

The problem I'm encountering is that for some very bad sample designs, the Voronoi vertex is outside the delaunay triangle yes it's possible see http://www.mathopenref.com/trianglecircumcenter.html but I wasn't expecting it, and I don't know that this answer Compute the size of Voronoi regions from Delaunay triangulation? applies to the case when Voronoi vertices are outside the triangle. I'm getting points with negative areas (using the spherical triangle approach based on connecting Voronoi vertexes to triangle edge midpoints and the triangle node to define fractional triangles)

Is the area closer to node than a Voronoi vertex that is outside the triangle (and closer to that node than the other 2 nodes of the same triangle) closer to that node than any other node in the delaunay tesselation? If so should I forget about connecting Voronoi vertices to the triangle edge midpoints and directly connect the Voronoi vertices of adjacent triangles and use that to compute the (spherical surface) area of the Voronoi region? This would still be simple to do because....

in MATLAB (where I'm prototyping the code, before I port it to C++) I get K (from convhulln) as a NK by 3 matrix of node indexes and can connect the Voronoi vertexes like this

```
KS=sort(K,2);
iK=(1:NK)';
edges=sortrows([KS(:,1:2) iK; KS(:,[1 3]) iK; KS(:,2:3) iK]);
edges=reshape(edges(:,3),2,1.5*NK); %a consequence of this is that there will always be an even number of triangles on the convex hull of a sphere, otherwise Voronoi cells are not defined, which they must be because the convex hull is defined
```

"edges" contains the indexes of convex hull triangles which defines the Voronoi vertices? the 2 nodes that would have areas associated with that edge of a Voronoi cell are the ones in the first 2 columns of edges before they are discarded so like I said, that would be a simple modification, but I'm not sure it's mathematically correct. Do you know if it is?