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We have the following input for the algorithm:

A graph G with no cycles (aka a spanning-tree) where each node has an associated weight.

I want to find an independent set S such that:

  • No two elements in S form an edge in G
  • There is no other possible subset which satisfies the above condition, for which there is a greater weight than S[0] + S[1] + ... + S[n-1] (where len(S)==n).

This is the high-level pseudocode I have so far:

MaxWeightNodes(SpanningTree S):
    output = {0}
        o = max(node in S)
        output = output (union) o
        S = S \ (o + adjacentNodes(o))
    End While
    Return output   

Can someone tell me off the bat whether I've made any errors, or if this algorithm will give me the result I want?

share|improve this question
why not try implementing it to prove the correctness of your algorithm? – TravellingGeek Mar 25 '13 at 4:05
@GeraldSv As the problems grow, usually the best solution is to prove an algorithm works, prior to any implementation. Spend weeks/months implementing something, to find out a simple corner case could have been identified, goes quite upsetting -- didn't take me so long, but I've already faced this sort of issue (: – Rubens Mar 25 '13 at 4:14
@GeraldSv You don't implement algorithms to prove their correctness, you do it formally. Suggesting otherwise doesn't seem good advise to me. – G. Bach Mar 25 '13 at 5:33
up vote 5 down vote accepted

The algorithm is not valid, since you'll soon face a case when excluding the adjacent nodes of an initial maximum may be the best local solution, but not the best global decision.

For example, output = []:

      /    \
   100      20
   /  \    /  \
  80  90  10   30

output = [100]:

      /    \
     x      20
   /  \    /  \
  x    x  10   30

output = [100, 30]:

      /    \
     x      x
   /  \    /  \
  x    x  10   x

output = [100, 30, 10]:

      /    \
     x      x
   /  \    /  \
  x    x  x    x

While we know there are better solutions.

This means you're down on a greedy algorithm, without an optimal substructure.

share|improve this answer

I think the weights of the vertices make greedy solutions difficult. If all weights are equal, you can try choosing a set of levels of the tree (which obviously is easiest with a full k-ary tree, but spanning trees generally don't fall into that class). Maybe it'll be useful for greedy approximation to think about the levels as having a combined weight, since you can always choose all vertices of the same level of the tree (independent of which vertex you root it at) to go into the same independent set; there can't be an edge between two vertices of the same level. I'm not offering a solution because this seems like a difficult problem to me. The main problems seem to be the weights and the fact that you can't assume that you're dealing with full trees.

EDIT: actually, always choosing all vertices of one level seems to be a bad idea as well, as Rubens's example helps visualize; imagine the vertex on the second level on the right of his tree had a weight of 200.

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