On Minimax Optimality of Sparse Bayes Predictive Density Estimates

Abstract

We study predictive density estimation under Kullback-Leibler loss in 0-sparse Gaussian sequence models. We propose proper Bayes predictive density estimates and establish asymptotic minimaxity in sparse models. A surprise is the existence of a phase transition in the future-to-past variance ratio r. For r < r0 = ( 5 - 1)/4, the natural discrete prior ceases to be asymptotically optimal. Instead, for subcritical r, a `bi-grid' prior with a central region of reduced grid spacing recovers asymptotic minimaxity. This phenomenon seems to have no analog in the otherwise parallel theory of point estimation of a multivariate normal mean under quadratic loss. For spike-and-slab priors to have any prospect of minimaxity, we show that the sparse parameter space needs also to be magnitude constrained. Within a substantial range of magnitudes, spike-and-slab priors can attain asymptotic minimaxity.