# Graph search with weight limit

I have a undirected, weighted graph with objects of an arbitrary type as nodes. The weight of an edge between two nodes A and B is the similarity of these two nodes in the interval (0, 1]. A similarity of 0 leads to no connection between to nodes, so the graph may be partitioned.

Given a target weight w and a start-node S, which is an algorithm to find all nodes that have a weight > w. Subnodes (seen from S) should have the product of all weights on the path. I.e:

``````S --(0.9)-- N1 --(0.9)-- N2 --(0.6) -- N3
``````

Starting with S the nodes will have the following similarity values:

``````N1: 0.9
N2: 0.9 * 0.9 = 0.81
N3: 0.9 * 0.9 * 0.6 = 0.486
``````

So given S and the target weight 0.5 the search should return N1 and N3. Wheres a search starting from N2 would return S, N1 and N3.

Are their any algorithms that fit my needs?

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from S, with w=0.5 it should return N1 and N2 ? not N1 and N3 ? –  Ricky Bobby Aug 18 '11 at 13:50
Is the graph consistent? I.e. if there are multiple paths from Ni to Nj will the products from the edges on the two graphs be the same? [Assuming of course that we don't traverse any edge more than once which would clearly lead to problems for non-1 weights.] –  borrible Aug 18 '11 at 14:00

note the following:

1. `log(p1 * p2) = log(p1) + log(p2)`
2. if `p1 < p2` then `log(p1) < log(p2)` and thus: `-log(p1) > -log(p2)`

Claim [based on the 1,2 mentioned above]: finding the most similar route from s to t, is actually finding the minimum path from s to t, where weights are `-log` of original.

I suggest the following algorithm, based on Dijkstra's algorithm and the above claim.

``````1. define for each edge e: w'(e) = -log(w(e)) //well defined because w(e) > 0
2. run Dijkstra's algorithm on the graph with the modified weights.
3. return all vertices v that their weight is dijkstra(v) < -log(needed)
``````
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+1 This is exactly what I was going to say. :-) –  templatetypedef Aug 19 '11 at 7:53