I'm working on an efficient algorithm to "hide" all the pairs of intersecting rectangles laid out in 2D in a set of `N`

rectangles (axis aligned).
All the rectangles have the same width and height.

Suppose my starting set of rectangles laid out in 2D is
`R={r_1,r_2,...,r_n}`

where `r_i`

are all the rectangles, `r_i`

has the boolean attribute `visible`

.

I want to find the subset S of R such that for every `r_i`

, `r_j`

belonging to S `r_i,_r_j`

don't intersect.

A first trivial solution is the brute force-maximal independent set approach.
First I iterate over `N(N-1)/2`

rectangles (a given rectangle doesn't intersect with itself) and check if they intersects or not. Contemporaneously I also put all the rectangles in the set `R`

as the nodes of a graph `G=(V,E)`

. Edges in that graphs are represented by the pairs of intersecting triangles.

The set of non intersecting rectangles is then **one maximal independent set** of the graph.

I think this is not the fastest approach, although correct. I've read in some discussion for example how sorting in advance the list of rectangles by their x coordinate would speed up the computation of intersecting rectangle pairs to `O(nlog(n) )`

(rather than brute force `O(n^2)`

.

Now I'm asking, do someone know a better algorithms for such problem (both for the computation of intersecting pairs in a set of rectangles and for the filtering of those rectangles?)

Reformulating the problem as SAT problem can also be interesting, although this idea just came up to my mind. The problem would be here to find that permutation of `visible`

attributes such that no visible rectangle intersects another one.