# Non-intersecting line segments while minimizing the cumulative length

I would like to find a better algorithm to solve the following problem:

There are N starting points (purple) and N target points (green) in 2D. I want an algorithm that connects starting points to target points by a line segment (brown) without any of these segments intersecting (red) and while minimizing the cumulative length of all segments.

My first effort in C++ was permuting all possible states, find intersection-free states, and among those the state with minimum total segment length O(n!) . But I think there has to be a better way.

Any idea? Or good keywords for search?

• Maybe some type of topological sort? Mar 25, 2012 at 19:11
• I don't know the answer either but I would create any solution (ignoring conflicts) and then resolve conflict individually: when two lines conflict, it seems that switching one pair of end points resolves the conflict. I'm not sure how to guarantee progress, though. Mar 25, 2012 at 19:15
• @DietmarKühl: Switching endpoints could cause a different conflict to appear. Mar 25, 2012 at 19:17
• @OliCharlesworth: yes, I realize this. That is the part about guaranteeing progress: it won't work if things are resolved in a form creating a cycle. Mar 25, 2012 at 19:21
• @Masoud M: Up to how many point-pairs do you expect to handle? Mar 25, 2012 at 19:48

This is Minimum Euclidean Matching in 2D. The link contains a bibliography of what's known about this problem. Given that you want to minimize the total length, the non-intersection constraint is redundant, as the length of any pair of segments that cross can be reduced by uncrossing them.

• @Walkerneo, it's not crossing your legs, because the distance between your feet, and the distance between your hips is shorter than the length of your legs. Mar 26, 2012 at 0:34
• @qq3: Strictly speaking, I think that this is Bipartite Minimum Euclidian Matching, a subset mentioned in your link. Mar 27, 2012 at 14:22
• @dmckee: qq3 said that the non-intersecting rule was redundant under the minimum total length constraint, not "in conflict" with it (mathematically, these are very different things). And for Bipartite problems (which this one is) locally-separable improvements are also always globally valid improvements, so the local length-crossing rule applies globally also. (I am not sure if this applies to the non-Bipartite cases though, Bipartite is much simpler). Mar 27, 2012 at 14:30
• @RBarryYoung> Ah....my comment (which I will now delete) no longer makes sense because the comment I was responding to has been deleted. We are in agreement. Mar 27, 2012 at 15:11

You can select a random connection, then each time delete one cross by changing the connections of its endpoints. This operation reduces the total length (by triangle inequality). Since the number of ways of lines crossing each other is finite, in a finite number of steps we arrive at a noncrossing solution. In practice, it should converge quickly.

• @MasoudM. I'm 100% sure that switching crosses finally will stop (total length decreases). If you care about the time (how many times you should do this), because your program runs on finite machines(PCs), they doesn't have something like epsilon (which could be very small), their accuracy is predefined (for example 30 bit), so it can be completed soon, Also you can add some heuristics in each step, to have better selection in changes. I suggest you implement this (you need some bases in all other algorithms like finding intersection and changing some of them are necessary in all algorithms). Mar 26, 2012 at 14:27
• Total length decreases but its finite because it at least will be zero. Mar 26, 2012 at 14:29
• @MasoudM. One useful heuristic is find all conflicts in each step and resolve them, then again search for conflicts, Also if you read qq3's suggested papers, of-course you will get better answer than this. Mar 26, 2012 at 20:15
• @MasoudM. Also if you interested in this way of problem solving, this names "Invariance" in mathematics and computer science, you can take a look at KTH course around this. Mar 26, 2012 at 20:27
• @AaronJohnSabu, I actually expect to see the randomized expected time of n^2 or n^3. n! cannot be even the worse case I believe, since to make the worst case, one has to start from some position X and visit almost all possible combinations while resolving the crosses. This sounds impossible and too pessimistic. Mar 23, 2021 at 13:40

Looks like a you could use a BSP-type algorithm.

Following qq3's answer which says the intersection constraint is redundant, there is just one more step. Assigning starting points to end points while minimizing total length. Fortunately there is a polynomial time algorithm for this:

Hungarian algorithm is a combinatorial optimization algorithm that solves the the assignment problem in polynomial time.

It reduces time order from O(n!) to O(n3).