Algorithms for mean-field variational inference via polyhedral optimization in the Wasserstein space
Abstract
We develop a theory of finite-dimensional polyhedral subsets over the Wasserstein space and optimization of functionals over them via first-order methods. Our main application is to the problem of mean-field variational inference, which seeks to approximate a distribution π over Rd by a product measure π. When π is strongly log-concave and log-smooth, we provide (1) approximation rates certifying that π is close to the minimizer π of the KL divergence over a polyhedral set P, and (2) an algorithm for minimizing KL(·\|π) over P based on accelerated gradient descent over d. As a byproduct of our analysis, we obtain the first end-to-end analysis for gradient-based algorithms for MFVI.
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