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In a typical clustering problem, the probability of a data point x is p(x) = sum_k p(k)p(x|k), where k is a latent variable specifying the cluster that x belongs to. We can use EM algorithm to maximize the log likelihood of the objective function for the training data set: sum_n log (sum_k p(k)(p(x|k))).

I wonder if EM algorithm can solve the problem with two sets of latent variables, i.e. p(x) = sum_k sum_l p(x|k, l)p(k)p(l)? If so, how can we do that?

What if all of the probability distributions are sigmoid functions?

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This should be just the straightforward application of the EM algorithm as a way of solving hidden data problems - the hidden data is the underlying value of k and l at each step. In the E step you work out the expected log likelihood, considering each possible value of the pair (k,l), using the probability of this, given the data and the current parameter settings as a weight. In the M state you find the parameters that maximise this expected log likelihood. This is very similar to just encoding the pair (k,l) as a single index, m, except that there is more structure in p(k)p(l) than there is in p(m), which will affect the M step very slightly.

If the probabilities are sigmoid - any any other probability distribution - the justification of the EM algorithm still holds: that each step increases or leaves unchanged the log likelihood. However you may find that the M-step becomes more expensive if the optimisation problem gets harder.

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Hi mcdowella, many thanks for your answer. So what you mean is to combine p(k)p(l) as p(k,l), and treat p(k,l) as one hidden data? –  user3107656 Dec 17 '13 at 10:14
    
You can simplify the problem by combining k and l and treating (k,l) as a single hidden data. If you do this you have the choice of fitting p(k,l) as an arbitrary collection of probabilities - in which case the estimation will be exactly like the single parameter case - or as p(k,l)=p(k)p(l) in which case you have fewer parameters to fit and the estimation will be slightly different but should be fairly straightforward. A good check on EM is to check that the likelihood increases with each iteration until convergence. You can also test it on made-up data for which you know the right answer. –  mcdowella Dec 17 '13 at 11:04

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