# What is the computational complexity of the EM algorithm?

In general, and more specifically for Bernoulli mixture model (aka Latent Class Analysis).

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Since the EM algorithm is by nature iterative, you must decide on a termination criterion. If you fix an upper bound on the number of steps, runtime analysis is obviously easy. For other termination criteria (like convergence up to a constant difference), the situation must be analyzed specifically.

Long story short, the description "EM" does not include a termination criterion, so the question can't be answered as such.

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EM is pretty much the same as Lloyds variant of k-means. So each iteration takes O(n*k) distance computations. They are more complex distance computations, but in the end they are some variant of Mahalanobis distance.

However, k-means has a quite nice termination behavior. There are only k^n possible cluster assignments. Now if in each step, you choose one that is better, it will have to terminate the latest after trying out all k^n. But in reality, it usually terminates after at most a few dozen steps.

For EM, this is not as easy. Objects are not assigned to a single cluster, but as in fuzzy-c-means are assigned relatively to all clusters. And that's when you lose this termination guarantee.

So without any stopping threshold, EM would infinitely optimize the cluster assignments, up to an infinite precision (assuming you would implement it with infinite precision).

As such, the theoretical runtime of EM is: infinite.

Any threshold (and if it's just hardware floating point precision) will make it finish earlier. But it will be hard to get a theoretical limit here different than O(n*k*i) where i is the number of iterations (which could be infinite, but which you can also set to 0 if you don't want to do a single iteration).

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