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I am playing around with implementing a junction tree algorithm for belief propagation on a Bayesian Network. I'm struggling a bit with triangulating the graph so the junction trees can be formed.

I understand that finding the optimal triangulation is NP-complete, but can you point me to a general purpose algorithm that results in a 'good enough' triangulation for relatively simple Bayesian Networks?

This is a learning exercise (hobby, not homework), so I don't care much about space/time complexity as long as the algorithm results in a triangulated graph given any undirected graph. Ultimately, I'm trying to understand how exact inference algorithms work before I even try doing any sort of approximation.

I'm tinkering in Python using NetworkX, but any pseudo-code description of such an algorithm using typical graph traversal terminology would be valuable.


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1 Answer 1

up vote 3 down vote accepted

If Xi is a possible variable (node) to be deleted then,

  • S(i) will be the size of the clique created by deleting this variable
  • C(i) will be the sum of the size of the cliques of the subgraph given by Xi and its adjacent nodes


In each case select a variable Xi among the set of possible variables to be deleted with minimal S(i)/C(i)

Reference: Heuristic Algorithms for the Triangulation of Graphs

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When you say "size of the clique(s)", do you mean the variables you've already connected to one another due to a deletion? I.e. if a graph contains a 5-clique, does your method recognize this on the first iteration or does it initially treat all variables as 1-cliques? I want to avoid calling a method that finds maximal cliques each time I need to compute C(i). –  Oliver Nov 9 '10 at 9:21

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