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So let's say I have a list of N pairs of positive long coordinates (points).
How do I find the smallest rectangle containing all of them?
The rectangle can also have floating coordinates and be rotated in any angle and further shrunk... Not just X, Y, Width and Height!

Just an image I found on the web...

I already know how to find the smallest polygon or not rotated rectangle, but it's not what I need...I wish to know how to find the arbitrarily oriented minimum bounding box.

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"Vector composing algorithm" sounds like something out of CSI:Miami :P – tenfour Mar 15 '11 at 11:55
Wow. It'd be nice, but I don't think they will find any practical use for mine... – Vercas Mar 15 '11 at 11:59
Code Golf had a similar, though not exactly the same, question you might be able to adapt. – kojiro Mar 15 '11 at 12:11
+1 for the CSI quip – Fraser Mar 15 '11 at 12:15
@kojiro No, it's not even close to what I need. – Vercas Mar 15 '11 at 12:17
up vote 6 down vote accepted


The section "Minimum-area box" has various examples.

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Thank you! That file contains just the function I need! I also found more things that I need on that site! – Vercas Mar 15 '11 at 12:13
I knew it did as I used it this morning myself. Half the battle in finding something is knowing the correct terms! – Fraser Mar 15 '11 at 12:14
I'd knew the terms better if English was my natural language... – Vercas Mar 15 '11 at 12:29
Well I understood enough to know what you meant...even if google didn't ;) – Fraser Mar 15 '11 at 12:46
From the description, this doesn't appear accurate. A true minimum area box would most likely have a center that was not the average of the points. They seem to be using a shortcut to simply get something pretty close. – Mooing Duck Apr 4 '15 at 0:27

This wikipedia page notes that you can solve this problem by using the fact that the minimum rectangle must have an edge collinear with one of the edges of the convex hull.

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That Wikipedia page does not contain an algorithm; the "rotating calipers" page it links to does contain an algorithm, but not for this problem. Some actual links:,…. Note that this approach works for any reasonable definition of "minimum"; in particular it works for "minimum area" and "minimum perimeter"; these two often coincide but not always. – Gareth McCaughan Mar 15 '11 at 12:09
Thanks Gareth (and hi!) I've changed the wording of my answer. – user97370 Mar 15 '11 at 13:29
For each line-segment in the convex hull, you can calculate the area of the bounding rectangle using it, and choose the smallest. It runs O(n^2) in the number of points on the hull though. – Thomas Ahle Mar 15 '11 at 13:34
Hi, Paul. I thought it was probably the same Paul Hankin :-). Thomas, it actually turns out to be O(n) once you've got the convex hull, if you do it right. See, e.g., the first link in my comment above. – Gareth McCaughan Mar 15 '11 at 13:41

Maybe this paper can help: Smallest k point enclosing rectangle of arbitraty orientation

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Unfortunately, it doesn't help. – Vercas Mar 15 '11 at 12:23
That is exactly it... – Fraser Mar 15 '11 at 12:50
This paper addresses the harder problem of finding a bounding square. As you can see, the complexity is O(N²Log(N)), whereas the bounding rectangle is easily obtained in O(N Log(N)). – Yves Daoust May 18 '15 at 6:26

I don't know if this would be of help to you, but here's my thoughts on how I'd approach the problem.

You'll need functions to find your "corner-most" points (in your example, the left 2 and right 2 points). Given those 4 points, connect them with lines.

(Note in your example image, the top point would not be contained by the generated rectangle, so...) You'll then need a function to determine if the rectangle generated contains all given points; if not, extend the endpoints (in this case, the top 2 points of the generated rectangle) by N (which is either a single measure ... say a pixel, or if you're smart, the distance to the point that's out of bounds plus/minus one dependant on the direction) and re-evaluate.

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That will only work for axis align MBBs – Fraser Mar 15 '11 at 12:08
Good point; in that case, you'd need to derive the function (y=mx+b) representing the connection between the two points, and continue along that path -- along both sides of your original rectangle. – JNadal Mar 15 '11 at 12:12

Maybe this works for you:

  • find the center point of all your points (sum of all x / number of x's, same for y)
  • take the farthest point from the center as a corner point
  • project line through the 2nd farthest point in a 90° angle of the corner point
  • iterate over the points of the other side of the center point and find minimum
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I tried, up to the 2nd step... :( – Vercas Mar 15 '11 at 12:25
Step #3 and #4 is super confusing and make no sense to me – Mooing Duck Apr 4 '15 at 0:34

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