# Propagate ratings in a graph structure

I have the following problem:

``````Consider a weighted direct graph.
Each node has a rating and the weighted edges represents
the "influence" of a node on its neighbors.
When a node rating change, the neighbors will see their own rating modified (positively or negatively)
``````

How to propagate a new rating on one node?
I think this should be a standard algorithm but which one?

This is a general question but in practice I am using Python ;)

Thanks

[EDIT]
The rating is a simple float value between 0 to 1: [0.0,1.0]
There is certainly a convergence issue: I want just limit the propagation to a few iteration...

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Can you elaborate on "node rating change"? (how does it change?) It reminds me page rank algorithm a lot. –  amit Dec 14 '12 at 9:48
P.S. There is no guarantee for convergence unless we know some details on the graph, and most importantly what I asked above - how does a rating change for a node. –  amit Dec 14 '12 at 9:57

There is an easy standard way to do it as follows:

``````let G=(V,E) be the graph
let w:E->R be a weight function such that w(e) = weight of edge e
let A be an array such that A[v] = rating(v)
let n be the required number of iterations

for i from 1 to n (inclusive) do:
for each vertex v in V:
A'[v] = calculateNewRating(v,A,w) #use the array A for the old values and w
A <- A' #assign A with the new values which are stored in A'
return A
``````

However, for some cases - you might have better algorithms based on the features of the graph and how the rating for each node is recalculated. For example:

1. Assume `rating'(v) = sum(rating(u) * w(u,v)) for each (u,v) in E`, and you get a variation of Page Rank, which is guaranteed to converge to the principle eigenvector if the graph is strongly connected (Perron-Forbenius theorem), so calculating the final value is simple.
2. Assume `rating'(v) = max{ rating(u) | for each (u,v) in E}`, then it is also guaranteed to converge and can be solved linearly using strongly connected components. This thread discusses this case.
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This simple version looks like at my fist plan, thanks to confirm me this :) My problem looks like the Page Rank you described. I will investigate this lead further. Thanks a lot –  Alban Soupper Dec 14 '12 at 13:35