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I'm stuck at the following problem: Given a weighted digraph G, I'd like to construct the minimal subgraph of G that contains all negative (simple) cycles of G.

I do know how to find a negative cycle using Bellman-Ford, and I know that the number of simple cycles in a directed graph is exponential.

One naive way to approach the problem would be to simply iterate all simple cycles and pick those that are negative, but I have the feeling that there might be a polynomial-time algorithm. Most articles that I found through Google were about finding a (rather than all) negative cycle.

I'm hoping to find some experts here on stackoverflow that may give some hints towards a polynomial-time solution, or hints towards proving that it can't be solved in polynomial time.

Many thanks in advance!

Cheers, Robert

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this is probably more at home in Math or CStheory exchange. –  wich Sep 11 '12 at 9:08
    
@ninjagecko: [homework] tag is now being phased out; see meta. –  Mechanical snail Sep 24 '12 at 22:14

2 Answers 2

up vote 3 down vote accepted

For anyone interested in or stuck at a similar problem: it's NP-complete. Thanks to wich for pointing me to the thread in cstheory.

To see why it's NP-complete, first of all observe that the problem may be stated as follows: given a weighted directed graph G with N verices and an edge E on G, find out whether E lies on a (simple) negative cycle. If it does, E should be in the subgraph H. If it does not, it should not be in H.

Now, let edge E be E = (u, v) with weight w. We'd like to know whether there's a path from v to u with total weight W such that W + w < 0. If we could do this in polynomial time, we could also solve the Hamiltonian Cycle problem in polynomial time:

Assign to edge E a weight of N - 1.00001. Assign to all other edges in the graph a weight of -1. Now the graph's only negative cycle on which E lies, is the cycle that contains all vertices (that cycle has weight -0.00001) and is thus a Hamiltonian Cycle.

Many thanks for thinking along!

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Quick google gives me:

http://www.sciencedirect.com/science/article/pii/S0166218X01002013

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1  
Thanks for the answer, I had already found that article. The algorithm described in the article runs in exponential time (worst case). I'm hoping to find a polynomial algorithm (I might be way too optimistic here). –  robertdg Sep 11 '12 at 9:44
    
I haven't worked with anything similar, but to me it smells of an NP complete problem. –  wich Sep 11 '12 at 9:48
2  
cstheory.stackexchange.com/questions/11899/… might be of some help –  wich Sep 11 '12 at 9:52
    
Great, thanks. I'll check the reduction from Hamiltonian Path. Seems I was fooled by naive & wrong intuition. –  robertdg Sep 11 '12 at 11:38
    
Seems I can't upvote yet (just joined stackoverflow). So I'm upvoting textually :-) –  robertdg Sep 12 '12 at 11:21

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