I have been researching RBMs for a couple months, using Python along the way, and have read all your papers. I am having a problem, and I thought, what the hey? Why not go to the source? I thought I would at least take the chance you may have time to reply.

My question is regarding the Log-Likelihood in a Restricted Boltzmann Machine. I have read that finding the exact log-likelihood in all but very small models is intractable, hence the introduction of contrastive divergence, PCD, pseudo log-likelihood etc. My question is, how do you find the exact log-likelihood in even a small model?

I have come across several definitions of this formula, and all seem to be different. In Tielemen’s 2008 paper “Training Restricted Boltzmann Machines using Approximations To the Likelihood Gradient”, he performs a log-likelihood version of the test to compare to the other types of approximations, but does not say the formula he used. The closest thing I can find is the probabilities using the energy function over the partition function, but I have not been able to code this, as I don’t completely understand the syntax.

In Bengio et al “Representation Learning: A Review and New Perspectives”, the equation for the log-likelihood is: sum_t=1 to T (log P(X^T, theta)) which is equal to sum_t=1 to T(log * sum_h in {0,1}^d_h(P(x^(t), h; theta)) where T is training examples. This is (14) on page 11.

The only problem is that none of the other variables are defined. I assume x is the training data instance, but what is the superscript (t)? I also assume theta are the latent variables h, W, v… But how do you translate this into code?

I guess what I’m asking is can you give me a code (Python, pseudo-code, or any language) algorithm for finding the log-likelihood of a given model so I can understand what the variables stand for? That way, in simple cases, I can find the exact log-likelihood and then compare them to my approximations to see how well my approximations really are.