Polynomial-Time Near-Optimal Estimation over Certain Type-2 Convex Bodies
Abstract
We develop polynomial-time algorithms for near-optimal minimax mean estimation under 2-squared loss in a Gaussian sequence model under convex constraints. The parameter space is an origin-symmetric, type-2 convex body K ⊂ Rn, and we assume additional regularity conditions: specifically, we assume K is well-balanced, i.e., there exist known radii r, R > 0 such that r B2 ⊂eq K ⊂eq R B2, as well as oracle access to the Minkowski gauge of K. Under these and some further assumptions on K, our procedures achieve the minimax rate up to small factors, depending poly-logarithmically on the dimension, while remaining computationally efficient. We further extend our methodology to the linear regression and robust heavy-tailed settings, establishing polynomial-time near-optimal estimators when the constraint set satisfies the regularity conditions above. To the best of our knowledge, these results provide the first general framework for attaining statistically near-optimal performance under such broad geometric constraints while preserving computational tractability.
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