# Maximum-perimeter bounding rectangle for a set of points

I've been struggling for quite a while with this seemingly simple problem. I am given a set of points (which I have further simplified down to a convex hull) and my task is to find a rectangle (not necessarily axis-aligned) that encompasses all of them, has no extra space around (so that it is tight-fitting around the points) and has the maximum possible perimeter. It was no trouble for me to find the minimal one, but this has proven to be a tougher nut to crack. When searching for the minimal bounding rectangle, I was able to use the assumption that one of the rectangle's sides was always aligned with one of the hull's sides, but here I don't see any such case here. Am I missing something painfully obvious? The only way I could come up so far is to test antipodal pairs of points if they can project onto the sides of the rectangle and use some trig to maximize the function, but I just lost myself in the calculations.

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Can you post a link to the algorithm that you used? I suspect that it may be as simple as rotating the minimum bounding rectangle by 45 degrees and expanding it to fit the points – Zim-Zam O'Pootertoot Apr 25 '13 at 3:11
(min(x), max(y)), (max(x), min(y)) – BLUEPIXY Apr 25 '13 at 11:11