# Is it possible to find a simple path in a weighted undirected graph with maximum cost in polynomial time? Is this problem NP?

Hello and thank you for reading this.

I need to know if it is possible to find a simple path with maximum cost in any weighted undirected graph.

I mean to find THE MOST expensive path of all for any pair of vertex.

Input: Graph G = (V,E)

Output: The cost of the most expensive path in the graph G.

Is this problem NP-Complete?, I think it is. Could you provide any reference to an article where I can review this.

Thank you very much for your time.

Sincerely,

Alex.

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You're not the first to think of this problem. In fact, it was the first link in the google search results.

edit
Guys, un-weighted graph is a special case of weighted graph: all edges have weight 1 :)

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But I need to know this for a weighted graph, not the longest path in any graph. I a NO weighted graph I can clearly see why it is NP Complete. –  Alejandro Barreiro Dec 29 '10 at 20:52
Thanks for your time :) –  Alejandro Barreiro Dec 29 '10 at 20:52
How is that link not for a wieghted graph? There is no longest path if there is no weight... –  Chad La Guardia Dec 29 '10 at 20:54
@Alehandro: Unweighted graphs are a special case of weighted graphs (an unweighted graph being the same as a weighted graph where every edge has the weight 1), so if a problem is NP-hard for unweighted graphs it is at least NP-hard for weighted graphs (assuming it's solvable at all for weighted graphs). –  sepp2k Dec 29 '10 at 20:59
@Alejandro: If you have a graph where every edge has cost one than the maximum cost path is the one with most vertices in it. That's what makes it a special case. –  sepp2k Dec 29 '10 at 21:05

This is similar to traveling salesman, except your heuristic is the Max and not Min. Read up on the traveling salesman.

The problem is NP complete because it can be derived from a problem that is already proven to be NP-Complete (Traveling salesman). The answer is checkable in polynomial time, but an answer cannot be found in polynomial time.

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No, it's not. Travelling salesman is required to visit all nodes, while here it might be useful to omit some. I do agree that it's NP, though. –  Nikita Rybak Dec 29 '10 at 20:41
ah, i see he says simple path. You are right, its not travelling salesman, although it would be a good place to start. –  Chad La Guardia Dec 29 '10 at 20:43
Imagine many loops going through single central node. You can visit that node only once. –  Nikita Rybak Dec 29 '10 at 20:47
I think we would need to insist that there are no cycles, considering we could generate a path of length infinity. –  Chad La Guardia Dec 29 '10 at 20:56
It's a simple path. The restriction against cycles is already there. –  jball Dec 29 '10 at 20:57