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I have a tree where each edge is assigned a weight (a real number that can be positive or negative). I need an algorithm to find a simple path of maximum total weight (that is, a simple path where the sum of the weights of the edges in the path is maximum). There's no restriction on what node the path starts or ends.

I have a possible algorithm, but I am not sure it works and I am looking for a proof. Here it is:

  1. Select an arbitrary node u and run DFS(u) to find the maximum weight simple path that starts at u. Let (u, v) be this path.
  2. Run DFS(v) to find the maximum weight simple path that starts at v. Let this path be (v, z).

Then (v, z) is a simple path of maximum weight. This algorithm is linear in the size of the graph. Can anyone tell me if it works, and if so, give a proof?

Note: The Longest Path Problem is NP-Hard for a general graph with cycles. However, I only consider trees here.

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closed as off topic by Veger, John Koerner, Mario, Erno de Weerd, Mark Jan 15 '13 at 19:12

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I suppose math SE is a better place to discuss algorithms and proofs –  Veger Jan 15 '13 at 13:34
    
@Veger: I wasn't sure where it would fit better. I have seen good answers on algorithms and proofs here, more than at Math.SE. In any case, I just posted a duplicate of this question at math.SE. –  becko Jan 15 '13 at 13:41

3 Answers 3

up vote 1 down vote accepted

If you allow negative weights then consider the following example:

a<->b : -5000
a<->c : 1
b<->d : 1
b<->e : 1

The longest path is d<->b<->e with length 2

Arbitrarily pick a to start. DFS returns c with a distance of 1. Second DFS returns a with a distance of 1. However a<->c is not the longest path.

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As you say, the longest path problem is NP-Hard in general. I am talking about a tree here, not a general graph with cycles. –  becko Jan 15 '13 at 13:43
    
@becko Indeed, I missed that rather important part. –  Khaur Jan 15 '13 at 13:44
    
@becko I edited my answer to provide a counter-example if you allow negative weights. –  Khaur Jan 15 '13 at 14:28
    
+1 Nice and simple counter example. Thanks. –  becko Jan 15 '13 at 19:31

here's a proof that it works. The algorithm finds a pair of nodes x0,y0 such that max_x d(x,x0) = max_y d(x0,y) (that is, x0 and y0 are each others' farthest nodes). For any such pair, d(x0,y0) is the diameter. Proof: let x*,y* be two nodes s.t. d(x*,y*) is the diameter. there exist nodes r and s such so that the paths look like x0--r--s--y0 and x*--r--s--y*. Suppose d(x0,y0) < d(x*,y*), then either d(x0,y*) > d(x0,y0) or d(y*,x0) > d(y0,x0), contradicting the fact that x0 and y0 are each others' farthest points. therefore d(x0,y0)=d(x*,y*)

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If you are sure there are no cycles in the graph, I would try something like:

function findLongestPath(tree)
begin

   all_paths := {}

   for each neighbour 
      all_paths.append(create_path(this_node, findLongestPath(three - current_node))

   sort_descending(all_paths)
   return  all_paths[0];
end

The algorithm can be further optimised to store just the best path instead of a set (removes the need of storing all possible paths and sorting).

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