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Is there any algorithm that can approximate the given polygon with n non overlapping rectangles that gives the maximum coverage? By maximum coverage I mean, the sum of the rectangle areas are maximized. Rectangles are not necessarily equal sized.

The polygons I am dealing are convex. If exact solution is hard/expensive to find (which I am expecting it to be), simple good heuristics are welcome too.

Edit I always thought of approximating the polygon with rectangles inside polygon, but solutions with rectangles not totally inside polygons are also fine. If that is the case, maximization of the area becomes minimization of the area.

Edit 2 I forgot to mention that these rectangles are orthogonal rectangles, i.e. aligned with axises.

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Can you maybe provide some more information? I would like to know, what information you want to gain (number of rectangles, total area sum, % of wasted 'space'). Additionally there is also something you have to specify: Do you want the maximum area coverage with the minimum number of rectangles? Because with a lot of 1mm^2 rectangles you could approximate the area pretty good. If so, this sounds like en.wikipedia.org/wiki/Multi-objective_optimization. Maybe you can project your problem onto a multiple knapsack-problem. –  Slomo Jun 6 '12 at 14:39
@Slomo: I will give the polygon and number of rectangles as input. Is that enough? –  nimcap Jun 6 '12 at 14:58
Well yes, thank you. Based on this, the first idea of Jens Schauder seems reasonable. As you have only convex polygons, the biggest rectangle will be in the center. So you can recursively find the maximum rectangle of the next smaller area left over. Your recursion will end when you hit your nth rectangle (input). –  Slomo Jun 6 '12 at 15:24
There's an interesting solution for regular polygons here stackoverflow.com/questions/3296102/… –  smirkingman Jun 7 '12 at 7:24
A very good method for the the largest orthogonal rectangle here cgm.cs.mcgill.ca/~athens/cs507/Projects/2003/DanielSud –  smirkingman Jun 7 '12 at 7:37

3 Answers 3

One approach would be to create a (in the general case rectangular) bounding box for your polygon. Calculate the difference between the area of the bounding box and the area of the polygon. If the difference is small enough, you're done, if not, continue ...

Divide the box into 4 equal-sized rectangles, 2x2. Figure out which of these rectangles is entirely inside the polygon. Calculate the difference between the total area of the rectangles inside the polygon and of the polygon. If the difference is small enough you're done, if not continue ...

Divide each of the 4 rectangles into 4 sub-rectangles ... if at any stage you find that a rectangle is either fully inside or fully outside your polygon you can remove it from the list of rectangles to subdivide at the next iteration.

In other words, use a quadtree to divide the space containing your polygon and develop it to the extent necessary to meet your accuracy criteria.

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  1. Create a queue of polygons, Q, to be processed
  2. Add the initial polygon to Q

  3. Remove a polygon P from Q

  4. Find the longest side A of P
  5. Rotate P so that A is on the X-axis
  6. If P is a triangle, split it with a perpendicular line in the centre of A: enter image description here
  7. Add the two halves G and H to Q and goto 3
  8. (Now, P has 4 or more sides)
  9. If X and/or Y are acute:

enter image description here

10 . Take the next longest side of P, A, and goto 5

11 . Project a red rectangle up from A. Find the 2 points where it intersects P, B and C: enter image description here

12 . Choose the longer(B) and finalise the green rectangle

13 . Add the remaining figures (D, E and F) to Q

14 . Goto 3

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A first idea, maybe others can improve on it.

  • place a squaresomewhere inside the polygon, as far as possible away from any edges.
  • iteratively 1.) grow it, 2.) move it and turn it to maximize its distance from edges. until you can't grow it any more
  • start from the beginning, while considering edges of placed rectangles as edges of the polygon.
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