Given a set of n points, can we find three points that describe a triangle with minimum area in O(n^2)? If yes, how, and if not, can we do better than O(n^3)?

I have found some papers that state that this problem is at least as hard as the problem that asks to find three collinear points (a triangle with area 0). These papers describe an O(n^2) solution to this problem by reducing it to an instance of the 3-sum problem. I couldn't find any solution for what I'm interested in however. See this (look for General Position) for such a paper and more information on 3-sum.


There are O(n2) algorithms for finding the minimum area triangle.

For instance you can find one here: http://www.cs.tufts.edu/comp/163/fall09/CG-lecture9-LA.pdf

If I understood that pdf correctly, the basic idea is as follows:

  1. For each pair of points AB you find the point that is closest to it.

  2. You construct a dual of the points so that lines <-> points. Line y = mx + c is mapped to point (m,c)

  3. In the dual, for a given point (which corresponds to a segment in original set of points) the nearest line vertically gives us the required point for 1.

Apparently 2 & 3 can be done in O(n2) time.

Also I doubt the papers showed 3SUM-hardness by reducing to 3SUM. It should be the other way round.

  • The paper I linked to seems to reduce to 3-sum. They reduce the problem to finding 3 values a b c such that a + b + c = 0. +1, will have to read carefully to understand. I'll accept a bit later if no one comes up with something better. – IVlad Oct 15 '10 at 18:00
  • I know this is an old post but I have two queries: 1) Can we do better if we know that the vertices are from a (1000,1000) grid? 2) If the question is changed to find minimum area of convex polygon(given n), what will be the asymptotic limit for that? – Naman Jul 17 '14 at 19:12

There's an algorithm that finds the required area with complexity O(n^2*log(n)).

For each point Pi in set do the following(without loss of generality we can assume that Pi is in the origin or translate the points to make it so).

Then for each points (x1,y1), (x2,y2) the triangle area will be 0.5*|x1*y2-x2*y1| so we need to minimize that value. Instead of iterating through all pairs of remaining points (which gives us O(N^3) complexity) we sort those points using predicate X1 * Y2 < X2 * Y1. It is claimed that to find triangle with minimal area we need to check only the pairs of adjacent points in the sorted array.

So the complexity of this procedure for each point is n*log(n) and the whole algorithm works in O(n^2*log(n))

P.S. Can't quickly find the proof that this algorithm is correct :(, hope will find it it later and post it then.

  • Can you please elaborate a bit? Why is the triangle area 0.5|x1*y2 - x2*y1|? This comes from a determinant if I'm not mistaken, but it won't give you the triangle area as it only uses two points instead of three. Also, why are you sorting for each point when it looks like each sort will be the same? And finally, you don't seem to include Pi anywhere in your algorithm; what role does each Pi play? – IVlad Oct 15 '10 at 10:03
  • @IVlad I think, for each point PI he converts every point (x, y) into (x - PI.x, y - PI.y). (thus, moving PI itself into coordinate origin) Algorithm looks plausible. – Nikita Rybak Oct 15 '10 at 10:13
  • @Nikita Rybak - oh, right, he did say translate the points. +1, looks good. – IVlad Oct 15 '10 at 10:19
  • @IVlad I've read about this algorithm recently and also found its implementation in internet (opita.net/node/402 - in russian) but could not find the proof yet – Vladimir Oct 15 '10 at 10:32
  • Looking at it again, there's a problem. Let's say, PI is (0, 0) and there're 3 more points: A(100, 100), B(2, 1), C(1, 2). It's clear that points B and C should be used, but sorted order will be B, A, C. – Nikita Rybak Oct 15 '10 at 10:41

The problem

Given a set of n points, can we find three points that describe a triangle with minimum area in O(n^2)? If yes, how, and if not, can we do better than O(n^3)

is better resolved in this paper: James King, A Survey of 3sum-Hard Problems, 2004

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