There are a few algorithms around for finding the minimal bounding rectangle containing a given (convex) polygon.

Does anybody know about an algorithm for finding the minimal-area bounding quadrilateral (any quadrilateral, not just rectangles)?

I've searched the internet for several hours now, but while I found a few theoretical papers on the matter, I did not find a single implementation...

EDIT: People at Mathoverflow pointed me to an article with a mathematical solution (my post there), but for which I did not find an actual implementation. I decided to go with the Monte Carlo Method from Carl, but will dive into the paper and report here, when I have the time...

Thanks all!

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Could you please clarify with an example? And are we doing your homework for you? –  Jarrett Meyer Jan 12 '10 at 10:03
Source of the problem: I have digitized photos of parts of a product. All the parts are quadrilaterals. The product is flexible (and uneven) and the photos are taken from many different perspectives, so the digitized product parts become polygons. For further computational work on the digitized object, I need to auto-detect the best matching quadrilateral which is per definition of the project the minimum-area quadrilateral. As the photos are hires, a polygon has around 300 vertices. –  Carsten Jan 12 '10 at 11:04
The smallest quadrilateral ? Or one that is small enough ? I suspect that some sort of detection of the edge points followed by clustering into 4 groups followed by line-of-best-fit for each group might work. –  High Performance Mark Jan 12 '10 at 11:38
In real life "one small enough" will be sufficient. But because I want to know a solution and ideally not iterate through numbers of possibilites, my question is about the smallest quadrilateral... –  Carsten Jan 12 '10 at 14:09
Is there necessarily a unique solution? Consider a regular hexagon with area 3. You can bound it with a square, rhombus, or trapezoid of area 4. –  Jason Orendorff Jan 12 '10 at 16:32

### The Monte Carlo approach

Thanks for the clarifying comments on the problem. I've taken away that what's required is not a mathematically correct result but a "fit" that's better than any comparable fits for other shapes.

Rather than pouring a lot of algorithmic brain power at the problem, I'd let the computer worry about it. Generate groups of 4 random points; check that the quad formed by convexly joining those 4 points does not intersect the polygon, and compute the quad's area. Repeat 1 million times, retrieve the quad with the smallest area.

You can apply some constraints to make your points not completely random; this can dramatically improve convergence.

### Monte Carlo, improved

I've been convinced that throwing 4 points randomly on the plane is a highly inefficient start even for a brute-force solution. Thus, the following refinement:

• For each trial, randomly select p distinct vertices and q distinct sides of the polygon such that p + q = 4.
• For each of the q sides, construct a line passing through that side's endpoints.
• For each of the p vertices, construct a line passing through that vertex and with a randomly assigned slope.
• Verify that the 4 lines indeed form a quadrilateral, and that this quadrilateral contains (and does not intersect!) the polygon. If these tests fail, don't pursue this iteration any further.
• If this quadrilateral's area is the minimum of all areas seen so far, remember the area and the coordinates of the quadrilateral's vertices.
• Repeat an arbitrary number of times, and return the "best" quadrilateral found.

As opposed to always requiring 8 random numbers (x and y coordinates for each of 4 points), this solution requires only (4 + p) random numbers. Also, the lines produced are not blindly floundering in the plane but are each touching the polygon. This ensures that the quadrilaterals are from the outset at least very close to the polygon.

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For real life Monte Carlo might and will work. But if it's possible to compute an exact solution, I would prefer it (also out of "scientific curiosity" I'd like to know)... –  Carsten Jan 12 '10 at 15:26
Perhaps obvious, but there are some simple optimizations you can apply to the quadrilateral afterward to make sure you haven't left any low-hanging fruit. Each edge should touch the original polygon. A single side can be wiggled back and forth without changing the slope of any other sides. The same ideas could be applied after any approximation algorithm. –  Jason Orendorff Jan 12 '10 at 17:12
@Jason Orendorff: Right you are. Actually, I think the more effective course would be to combine my other solution with the Monte Carlo approach, so as to reap the benefits of your optimizations earlier. I've updated my answer to that effect. Thanks for your input! –  Carl Smotricz Jan 12 '10 at 18:25
I guess you could now remove the element of randomness and you'd have an O(n^4) algorithm. Try every combination of vertices and sides. For each combination that makes a quadrilateral, write a formula for the area in terms of the p slope values and solve for the values that produce the minimum area. –  Jason Orendorff Jan 12 '10 at 22:50
Hmm. With p=1 that would be trivial. But with p=2 we'd already have to find valleys on a hilly plane, and with p=3 or p=4 we'd have 3, 4 unknowns... and I'm not clever enough to find bumps in a 5-dimensional solid. I'm not sure there are numeric solutions to that kinda stuff. –  Carl Smotricz Jan 12 '10 at 23:00

A stingy algorithm

Start with your convex polygon. While there are more than 4 points, find the pair of neighboring points that's cheapest to consolidate, and consolidate them, reducing the number of points in your polygon by 1.

By "consolidate", I just mean extending the two edges on either side until they meet at a point, and taking that point to replace the two.

By "cheapest", I mean the pair for which consolidation adds the smallest amount of area to the polygon.

``````Before:                       After consolidating P and Q:

P'
/\
P____Q                         /  \
/    \                        /    \
/      \                      /      \
/        \                    /        \
``````

Runs in O(n log n). But this produces only an approximation, and I'm not entirely happy with it. The better the algorithm does at producing a nice regular pentagon, the more area the last consolidation must eat up.

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Are you sure that it's only an approximation? It's not obvious to me either way. –  Stephen Canon Jan 12 '10 at 16:57
Well, take a regular octagon and distort it slightly so the algorithm is sure to consolidate points 1 and 2 first, then points 4 and 5. The algorithm produces a pointy kite shape instead of the desired near-square. –  Jason Orendorff Jan 12 '10 at 17:00
Ah, yes. That's a nice example. –  Stephen Canon Jan 12 '10 at 21:27

I think the oriented bounding box should be pretty close (though it's actually a rectangle). Here is the standard reference paper on oriented bounding boxes: Gottschalk's paper (PDF)

Look at section 3 (Fitting an OBB).

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Ah, I think I found the weakness there: The paper qualifies OBBs as rectanguloids (in 3-space), which would be equivalent to rectangles in 2D. But this would be a restriction from the OP's requirement that the bounding quadrilaterals in fact be general quadrilaterals. I suspect oriented rectangles would be considerably easier to compute, so the algorithms given in the paper would not be general enough. –  Carl Smotricz Jan 12 '10 at 18:11

I think a 2D OBB around the points is a good starting place. That will probably give a "good" (but not best) fit; if you find you still need a tighter bound, you can extend the fit to quadrilaterals.

First off, you should compute the convex hull of your input points. That gives you fewer points to deal with, and doesn't change the answer at all.

I'd stay away from the covariance-based method that's referenced on Gottschalk's paper elsewhere. That doesn't always give the best fit, and can go very wrong for very simple input (e.g. a square).

In 2D, the "rotating calipers" approach described at http://cgm.cs.mcgill.ca/~orm/maer.html should give the exact best-fit OBB. The problem is also easy to think about as a 1D minimization problem:

1. For a given angle, rotate the x and y axes by this angle. This gives you two orthogonal vectors.
2. For each point, project onto both axes. Keep track of the min and max projection on each axis.
3. The area of the OBB is (max1-min1)*(max2-min2), and you can easily compute the points of the OBB from the angle and the min and max projections.
4. Repeat, sampling the interval [0, pi/2] as finely as you want, and keeping track of the best angle.

John Ratcliffe's blog (http://codesuppository.blogspot.com/2006/06/best-fit-oriented-bounding-box.html) has some code that does this sampling approach in 3D; you should be able to adapt it to your 2D case if you get stuck. Warning: John sometimes posts mildly NSFW pictures on his blog posts, but that particular link is fine.

If you're still not happy with the results after getting this working, you could modify the approach a bit; there are two improvements that I can think of:

1. Instead of picking orthogonal axes as mentioned above, you could pick two non-orthogonal axes. This would give you the best-fitting rhombus. To go about this, you'd essentially do a 2D search over [0, pi] x [0, pi].
2. Use the best-fit OBB as the starting point for a more detailed search. For example, you could take the 4 points from the OBB, move one of them until the line touches a point, and then repeat for the other points.

Hope that helps. Sorry the information overload :)

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I believe that each side of the minimal-area bounding quadrilateral will pass through at least 2 of the vertices of your polygon. If this assumption is true, it should be easy to perform a brute force search for the solution.

• Generate the unique set of lines which are defined by 2 of your vertices and do not intersect the polygon.
• Examine each set of 4 lines to determine which produces the minimal-area bounding quadrilateral.

UPDATED: The assumption that each side of the bounding quad will pass through at least 2 vertices is false, but a related set of lines may provided a basis for a solution. At the very least, each side of the bounding quad will pass through one of the vertices used to define the unique set of the lines which are defined by 2 vertices and do not intersect the polygon.

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Upon further reflection, my assumption may not even hold true for a regular pentagon, so this probably isn't the answer. –  chrisribe Jan 13 '10 at 13:42