Information-theoretic minimax and submodular optimization algorithms for multivariate Markov chains

Abstract

We study an information-theoretic minimax problem for finite multivariate Markov chains on d-dimensional product state spaces. Given a family B=\P1,…,Pn\ of π-stationary transition matrices and a class F = F(S) of factorizable models induced by a partition S of the coordinate set [d], we seek to minimize the worst-case information loss by analyzing Q∈ FP∈ B DKLπ(P\|Q), where DKLπ(P\|Q) is the π-weighted KL divergence from Q to P. We recast the above minimax problem into concave maximization over the n-probability-simplex via strong duality and Pythagorean identities that we derive. This leads us to formulate an information-theoretic game and show that a mixed strategy Nash equilibrium always exists; and propose a projected subgradient algorithm to approximately solve the minimax problem with provable guarantee. By transforming the minimax problem into an orthant submodular function in S, this motivates us to consider a max-min-max submodular optimization problem and investigate a two-layer subgradient-greedy procedure to approximately solve this generalization. Numerical experiments for Markov chains on the Curie-Weiss and Bernoulli-Laplace models illustrate the practicality of these proposed algorithms and reveals sparse optimal structures in these examples.

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