I'm trying to make an algorithm that will find the most efficient ordering for eliminating nodes in a small Bayesian network (represented by a DAG). All of the nodes are boolean and can take two possible states, with the exception of nodes with no successors (these nodes must have a single observed value; otherwise marginalizing them out is the same as removing them).

My original plan was that I would recursively choose a remaining variable that has no remaining predecessors and, for each of its possible states, propagate the value through the graph. This would result in all possible topological orderings.

Given a topological ordering, I wanted to find the cost of marginalizing.

For instance, this graph:

`U --> V --> W --> X --> Y --> Z`

has only one such ordering (U,V,W,X,Y,Z).

We can factorize the joint density g(U,V,W,X,Y,Z) = f1(U) f2(V,U) f3(W,V) f4(X,W) f5(Y,X) f6(Z,Y)

So the marginalization corresponding to this ordering will be

∑(∑(∑(∑(∑(∑(g(W,X,Y,Z),Z),Y),X),W),V),U) =

∑(∑(∑(∑(∑(∑(f1(U) f2(V,U) f3(W,V) f4(X,W) f5(Y,X) f6(Z,Y),Z),Y),X),W),V),U) =

∑(f1(U)

∑(f2(V,U)

∑(f3(W,V)

∑(f4(X,W)

∑(f5(Y,X)

∑(f6(Z,Y),Z)

,Y)

,X)

,W)

,V)

,U)

For this graph, `U --> V`

can be turned into a symbolic function of V in 4 steps (all U **x** all V. Given that, `V --> W`

can likewise be turned into a symbolic function in 4 steps. So overall, it will take 18 steps (4+4+4+4+2 because Z has only one state).

Here is my question: how can I determine the fastest number of steps that this sum can be computed for this ordering?

Thanks a lot for your help!