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Given a convex polygon, how do I find the 3 points that define a triangle with the greatest area.

Related: Is it true that the circumcircle of that triangle would also define the minimum bounding circle of the polygon?

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is this homework? –  Asaph Oct 25 '09 at 16:57
    
No, I working on collision detection of polygonal shapes for iPhone games. The minimum bounding circle would let me cull the set of potentially colliding shapes before doing more expensive polygon-polygon intersection tests. In the process, I'm learning computational geometry algorithms and translating them into Objective-C. In the future I will probably just use a physics library but I want to know how it works from the ground up. –  willc2 Oct 25 '09 at 18:56
    
I've found that putting too much detail in a question is bad as people tend to answer the most interesting (implied) questions rather than the stated one if it's "too simple". As a newbie, nothing's simple. –  willc2 Oct 25 '09 at 19:01
    
Note the answer of the secondary question but not the primary. Sorry to call you out Stephan, it's my fault for trying for a two-fer. –  willc2 Oct 25 '09 at 19:13

3 Answers 3

up vote 23 down vote accepted

Yes, you can do significantly better than brute-force.

By brute-force I assume you mean checking all triples of points, and picking the one with maximum area. This runs in O(n3) time, but it turns out that it is possible to do it in not just O(n2) but in O(n) time!

By first sorting the points / computing the convex hull (in O(n log n) time) if necessary, we can assume we have the convex polygon/hull with the points cyclically sorted in the order they appear in the polygon. Call the points 1, 2, 3, … , n. Let (variable) points A, B, and C, start as 1, 2, and 3 respectively (in the cyclic order). We will move A, B, C until ABC is the maximum-area triangle. (The idea is similar to the rotating calipers method, as used when computing the diameter (farthest pair).)

With A and B fixed, advance C (e.g. initially, with A=1, B=2, C is advanced through C=3, C=4, …) as long as the area of the triangle increases, i.e., as long as Area(A,B,C) ≤ Area(A,B,C+1). This point C will be the one that maximizes Area(ABC) for those fixed A and B. (In other words, the function Area(ABC) is unimodal as a function of C.)

Next, advance B (without changing A and C) if that increases the area. If so, again advance C as above. Then advance B again if possible, etc. This will give the maximum area triangle with A as one of the vertices. (The part up to here should be easy to prove, and simply doing this separately for each A would give O(n2). But read on.) Now advance A again, if it improves the area, etc. (The correctness of this part is a bit harder to prove, left as an exercise :-))

Although this has three "nested" loops, note that B and C always advance "forward", and they advance at most 2n times in total (similarly A advances at most n times), so the whole thing runs in O(n) time.

Code fragment, in Python (translation to C should be straightforward):

 # Assume points have been sorted already, as 0...(n-1)
 A = 0; B = 1; C = 2
 bA= A; bB= B; bC= C #The "best" triple of points
 while True: #loop A

   while True: #loop B
     while area(A, B, C) <= area(A, B, (C+1)%n): #loop C
       C = (C+1)%n
     if area(A, B, C) <= area(A, (B+1)%n, C): 
       B = (B+1)%n
       continue
     else:
       break

   if area(A, B, C) > area(bA, bB, bC):
     bA = A; bB = B; bC = C

   A = (A+1)%n
   if A==B: B = (B+1)%n
   if B==C: C = (C+1)%n
   if A==0: break

This algorithm is proved in Dobkin and Snyder, On a general method for maximizing and minimizing among certain geometric problems, FOCS 1979, and the code above is a direct translation of their ALGOL-60 code. Apologies for the while-if-break constructions; it ought to be possible to transform them into simpler while loops.

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2  
+1 very nicely written up. –  Stephen Canon Oct 25 '09 at 20:22
1  
is this really O(n) ? –  Ninja420 Aug 24 '13 at 19:31
    
@Ninja420: Yes it is. I've already given a proof in the answer above; you can also read the linked paper for a more detailed one. –  ShreevatsaR Aug 25 '13 at 9:34
    
Related question, would be good if you could provide a detailed description here, stackoverflow.com/questions/18423040/… –  Ninja420 Aug 25 '13 at 14:12
1  
@Ninja420: Ah I see. Yes, the fact that B and C advance only 2n times each must have seemed obvious to me when I wrote the answer, but it's seeming subtle now... clearly I'm getting older! I'll think about it and post an answer at the other question when it's clear to me again. –  ShreevatsaR Aug 26 '13 at 9:54

answering your related question:

The circumcircle of the triangle is not necessarily the minimum bounding circle of the polygon. To see this, consider a very flat isosceles triangle, say with vertices at (0,0), (10,0) and (5,1). The minimum bounding circle has center (5,0) and radius 5, but this circle doesn't touch the vertex at (5,1), so it's not the circumcircle. (The circumcircle has center (5,-12) and radius 13)

edit:

Choosing the smaller of the circumcircle or the circle containing the antipodal points of the diameter of the polygon also doesn't suffice, because it is possible to construct polygons that have points outside the circumcircle of the maximal triangle. Consider the pentagon with vertices at:

(-5,  0)
(-4, -1)
( 5,  0)
( 4,  1)
(-4,  1)

The maximal triangle has vertices at (-4,-1), (5, 0), and (-4, 1). Its circumcircle does not include the point at (-5, 0).

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How about if I take the smaller of: the Circumcircle (of the largest triangle) or a circle centered between the antipodal points? –  willc2 Oct 25 '09 at 19:28
    
Cool, that's a clever counterexample. I suspected that such would exist, but didn't come up with one... BTW I think it's possible to prove that that the minimal bounding circle will either have some pair as diameter, or be the circumcircle of some triangle. –  ShreevatsaR Oct 25 '09 at 20:47
    
Yes, I believe that that is true. –  Stephen Canon Oct 25 '09 at 21:25

from http://www.wolframalpha.com/input/?i=triangle The area of the triangle = sqrt((a+b-c)(a-b+c)(-a+b+c)*(a+b+c)) / 4 If you use c connected to the end points of your convex polygon and if a and b would touch your convex polygon you could iterate around your polygon allowing a to grow and b to shrink until you find your maximum area. I would start mid point and try each direction for a larger area.

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