# How to find the largest circle that lies within boundaries?

Given sets of 2D points which are the boundaries of an irregular shape, a shape which may not be convex and may have internal holes, is there an algorithm to find the largest circle that fits within the boundaries?

I've done a good bit of searching, and I do find algorithms that are close, such as the largest empty circle problem, but none that I have found so far match the constraints I have.

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possible duplicate of Maximum circle inside a non-convex polygon – aioobe Sep 8 '11 at 13:31
Do you want easiest to implement or you want best computing performance? What will be be maximum number of points? – Michał Šrajer Sep 8 '11 at 13:37
That problem looks like a genetic algorithm would generate a good, though possibly not the best, solution rapidly. – rossum Sep 8 '11 at 15:25
@aioobe: It is not directly a duplicate in that that algorithm applies to polygons, whereas my boundaries are irregular sets of points. However thanks for pointing it out, because I think I can adapt it. – drb Sep 8 '11 at 15:37
@Michał: maximum number of points will generally be in the low hundreds. I think easiest to implement will be good enough. – drb Sep 8 '11 at 15:38

Problem is not good defined since set of points don't bound any area. Boundary you mention should be some curve, probably polygon. Without that you can't say that there are internal holes, and also can't ask for circle to be within boundary. With this definition, you can create circle of any size on "outside" that touches few set points.

If you use polygon to specify boundary, Aioobe's link is good one. If you redefine problem to find maximal radius circle touching at least 3 points of given set, than it is same as checking for circumcircles of Dalaunay triangulation.

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A very dumb algorithm :) (likely something faster is possible)

The largest circle should touch at least 3 objects (object is either vertex or line).

So you can count all combinations O(n^3), build a circle for each one, check that it lies inside of the area (O(n)) and select the largest one. Totally - O(n^4).

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This answer has exactly zero information content. – Jim Mischel Sep 10 '11 at 20:01