# How can I inscribe a rectangle or circle inside an arbitrary quadrilateral

This may be a more math focused question, but wanted to ask here because it is in a CS context. I'm looking to inscribe a rectangle inside another (arbitrary) quad with the inscribed quad having the largest height and width possible. Since I think the algorithm will be similar, I'm looking to see if I can do this with a circle as well.

To be more clear hear is what I mean by the bounding quadrilateral as an example.

Here are 2 examples of the inscribed maximization I'm trying to achieve:

I have done some preliminary searching but have not found anything definitive. It seems that some form of dynamic programming could be the solution. It seems that this should be a linear optimization problem that should be more common than I have found, and perhaps I'm searching for the wrong terms.

Notes: For the inscribed square assume that we know a target w/h ratio we are looking for (e.g. 4:3). For the quad, assume that the sides will not cross and that it will be concave (if that simplifies the calculation).

-
Re. the circle: You can treat the quadrangle as a cut-off triangle. I.e. for each edge of the quadrangle, make the adjacent edges longer until they meet. Inscribe a circle into your new triangle. Check if it fits into your original quadrangle. The biggest circle thus obtained should be the optimal one. Obviously you will need to take care of quadrangles with parallel edges separately. –  toochin Feb 6 '11 at 14:26
You might have a difficult time with any arbitrary quadrilateral if you allow convex quads and those whose segments overlap. Do you mean any arbitrary convex quadrilateral? –  Jim Mischel Feb 6 '11 at 14:37
Can the rectangle also be rotated, or does it have to be parallel to the "horizont" ? –  kohlehydrat Feb 6 '11 at 15:07
The rectangle cannot be rotated that is inscribed, this should make it a bit easier. The sides should not overlap. I think I can say that the external quad will be convex as well. I can see how a concave quad could make things more difficult. –  Scott Feb 7 '11 at 17:45

1) Circle.
For a triangle, this is a standard math question from school program.
For quadrilateral, you can notice that maximum inner circle will touch at least three of its sides. So, take every combination of three sides and solve the problem for each triangle.
A case of parallel sides have to be considered separately (since they don't form a triangle), but it's not terribly difficult.

2) Rectangle.
You can't have "largest height and width", you need to choose another criteria. E.g., on your picture I can increase width by reducing height and vice versa.

-
For the circle case, exhaustive search will work, but keep in mind that's O(n!) and may only be practical for small polygons. A 20-sided polygon will have over 1100 combinations. –  payne Feb 6 '11 at 15:37
@payne 'quadrilateral' usually implies `n = 4` :) –  Nikita Rybak Feb 6 '11 at 16:15
Of course! I read too quickly. :-) –  payne Feb 6 '11 at 19:03
The first suggestion will not work when the sides are parallel, which will be quite often. It relies on extending the sides until they meet and form a triangle. If parallel, they will not meet. –  Scott Feb 7 '11 at 17:50
assume for response 2) that you know the ratio you want to maintain (e.g. 4:3) –  Scott Feb 7 '11 at 17:55