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I have a set of 2D points inside a finite 2D region of space (let's say a world-aligned rectangle to keep things simple for now). What would be an exceedingly efficient way to insert a new point into the set that has a relatively large distance to its new closest neighbour?

I could slowly build a Delaunay triangulation and limit my search to the largest triangles only, but I was hoping someone has a different (better) idea.

Goodwill, David


Forgot to mention that I need to do this thousands of times, every time taking all the previous points into account. I'm looking for an algorithm that doesn't slow down to a crawl as my point set grows.

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So you arbitrarily insert the new point somewhere in the space and then move it so that it is at the largest distance possible from it's nearest neighbor? Please explain how you insert a new point. –  Jacob Nov 9 '09 at 4:21
@Jacob, I'm not inserting the point anywhere yet. I merely want to find a place to insert one so that the distance between the newly inserted point and the nearest neighbour is relatively large. –  David Rutten Nov 9 '09 at 11:17

1 Answer 1

up vote 3 down vote accepted

Use the Bowyer-Watson or other incremental algorithm to maintain the Voronoi diagram. The vertexes of the Voronoi diagram are candidate points, keep all the candidate points in a priority queue ordered by distance to the source points. That should be pretty fast, and optimal (at least, optimal at each step).

Were you looking for something faster and less optimal?

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One might want to add the detail that one would want to check as candidate points the intersections of voronoi edges with the boundary of the region of interest. –  balint.miklos Nov 9 '09 at 9:06
Thanks Keith, that actually is the same approach as I already mentioned (Delaunay triangulation excircle center points are the same as the vertices of a Voronoi map). But at least there's no cool trick I'm missing. –  David Rutten Nov 9 '09 at 11:16

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