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The Bentley-Ottmann algorithm is used for the computation of intersection of line segments.

However, instead of finding the intersecting points of all the lines among themselves, I want to find the intersecting points between two groups of lines. This is to say that for every line in line group A, I want to know the intersection points between those lines and the lines in group B.

Is there anyway I can extend the Bentley-Ottmann algorithm for this? I already have the existing Bentley-Ottmann algorithm implemented ( in the library of CGAL), and I am not keen to modify it. I am, however, am keen to find ways to reuse it and extend it.

Edit: Any other algorithms ( not necessarily based on Bentley- Ottmann) are welcome. It would be better if those algorithms are already implemented in the existing library.

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2 Answers 2

up vote 3 down vote accepted

You could find all intersections between all lines in A+B, then remove intersections between lines in the same set. You're not increasing the complexity by much and this allows you to use CGAL's library function unmodified with only a simple wrapper function.

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@Thanks marcog, a related question: is there any other algorithm that does this? Preferably it should be found in existing computational geometry libraty. –  Graviton Dec 30 '10 at 1:42
@Ngu I'm not aware of any that'll be as efficient. Your added condition is not making it much easier to solve. Even if you tried adapting bentley-otterman, you'd still have to process events when lines from the same set intersect to keep them sorted in y. –  marcog Dec 30 '10 at 1:48

Where Bentley-Ottman keeps a tree of line segments ordered by their current vertical position, couldn't you keep two trees, one each for groups A and B? Then where the original algorithm checks the neighbors above and below the current point, you'd check the A-neighbor above against the B-neighbor below, and vice versa.

This is based on a quick skim of the Wikipedia article; I haven't written much geometrical code in the past decade.

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