# Is the problem of finding the simple path with maximum cost in a weighted undirected graph with the same number of vertex and edges NP-Complete?

Hello and thanks again for reading this.

I need to know now if the problem of finding the simple path with maximum cost in a weighted undirected graph with the same number of vertex and edges is NP-Complete or not?

Input: Graph G = (V,E) with V (vertex) = E (edges)

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

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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That's a strange description. Do you mean that the graph is a tree? – Nikita Rybak Dec 29 '10 at 21:39
@Nikita it does not look like a tree. Three with N nodes has N - 1 edges, I guess. – Michael Dec 29 '10 at 21:53
It is not a tree at all. It is a graph with the same number of vertex and edges. For example the graph with vertex 1 2 3, with edges between 1-2 2-3 3-1. It has 3 vertex and 3 edges. – Alejandro Barreiro Dec 29 '10 at 22:14

If the graph is not necessarily connected, then any instance of the longest path problem can be reduced to this problem by adding extra isolated vertices to the input graph to make the number of nodes and edges the same. If this isn't thyroid case, and the graph must be connected, then the input graph must have exactly one cycle, since a graph with n-1 edges is a tree. IF you find this cycle with a DFS and contract it to a single node, you then have a tree. It's easy to do longest path computations here; just consider all pairs of edges and get the cost of the unique path between them. If you take this path ans then expand it in the original graph by walking around the cycle where you originally went through the contracted node, I think you get the longest path in polynomial time.

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This problem is called the Longest Path Problem, and is NP-complete.

The restriction `|V| = |E|` doesn't help at all. You can solve an arbitrary graph by adding unconnected vertices until you satisfy the relation.

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I'm not sure your reasoning is correct here. Yes, you can add vertices, but you might have to add exponentially many, so it's not a polynomial reduction. – sepp2k Dec 29 '10 at 21:56
What with the tree diameter ? This is longest path in a tree and can be computed in polynomial time. – Michael Dec 29 '10 at 21:57
@sepp2k, you have to add at most |E| vertices, that's linear in the input size. – Keith Randall Dec 29 '10 at 22:11
@Michael, this is not in a tree. – Keith Randall Dec 29 '10 at 22:11