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Does anyone know an algorithm for the following problem:

Given a undirected connected graph find the number of ways in which 2 distinct edges can be cut such that the graph becomes disconnected.

I think a part of the problem (which I know an algorithm for) is calculating the number of ways in which 1 line can be cut so that it becomes disconnected. Then computing how these can be grouped with other lines gets the value (M-K)*K + K*(K-1)/2, M = no. of edges, K = no. of 1 edge cuts.

The part that I don't know how to do is finding the number of other ways to cut 2 line, for example in the graph that has only the cycle 1 - 2 - 3 - 1 any combination of the edges is a valid way of cutting lines to make the graph disconnected.

I coded the part of the program that finds all the 1 edge cuts and then I split the graph into biconnected components by removing those edges. I tried writing something for the second part, made 2 versions for that, but none of them got the right answer on every test.

Additional information about this homework problem: * The number of edges is < 100,000 * The number of vertexes is < 2000 * The program should run maximum 2 seconds on any graph with the above restrictions * There can be multiple edges between 2 vertexes.

I can do the first part in O(N+M). I guess the complexity for the second part should be maximum O(N*M).

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3 Answers 3

up vote 7 down vote accepted

You are looking for all edge cuts containing two edges. Such edge cuts only exist if the graph is at most 2-edge-connected.

The paper "Efficient algorithm for finding all minimal edge cuts of a nonoriented graph" by Karzanov and Timofeev contains an algorithm for computing all minimal edge cuts of a graph. From a brief look, it seems to me as if the algorithm can also be used to find cuts with a specified number of edges (for example, 2 edges). The complexity of the algorithm is O(lambda n^2), where lambda is the number of edges in the desired cuts (in your case, 2) and n is the number of vertices.

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N^2 would be a very good complexity for the problem. I'll read about that algorithm :). –  Razvi Jul 17 '09 at 15:14

The trivial solution: for all pairs of edges remove them from the graph and see if it is still connected. It's O(n^3) but should work.

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I would need something faster, the number of edges is < 100000 and the number of vertexes is < 2000 –  Razvi Jul 17 '09 at 14:27
How do you know you need something faster? Implement this first and see how it works. It is clear that you need at least O(n^2), otherwise you will fail to consider some pair of vertices and we could construct a graph where that particular pair of vertices disconnects the graph. Since you also have to determine connectivity I bet the O(N^3) is close to optimal if not optimal. –  Larry Watanabe Jul 17 '09 at 15:01
How much do you think the program will run for the number of edges = 100 000? –  Razvi Jul 17 '09 at 15:13
Well, 100 000^3 = 1 000 000 000 000 000 = 10^15. Assuming "1" is equal to a microsecond (not a bad assumption) that gives your 31 years. I guess you need something faster. –  Marcin Jul 18 '09 at 10:34

This problem is an extension of the 2-edge connectivity problem. To make sure that any edge (v, w) in the Graph is not a bridge, we find a back-edge from vertices adjacent to w and including w going to ancestor of v. Here, ancestor means the vertices which were discovered before v. Now, if there is only one such back-edge then that back-edge and (v, w) when removed will make the graph disconnected.

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