Minimax risks for sparse regressions: Ultra-high-dimensional phenomenons

Abstract

Consider the standard Gaussian linear regression model Y=Xθ+ε, where Y∈ Rn is a response vector and X∈ Rn*p is a design matrix. Numerous work have been devoted to building efficient estimators of θ when p is much larger than n. In such a situation, a classical approach amounts to assume that θ0 is approximately sparse. This paper studies the minimax risks of estimation and testing over classes of k-sparse vectors θ. These bounds shed light on the limitations due to high-dimensionality. The results encompass the problem of prediction (estimation of Xθ), the inverse problem (estimation of θ0) and linear testing (testing Xθ=0). Interestingly, an elbow effect occurs when the number of variables k(p/k) becomes large compared to n. Indeed, the minimax risks and hypothesis separation distances blow up in this ultra-high dimensional setting. We also prove that even dimension reduction techniques cannot provide satisfying results in an ultra-high dimensional setting. Moreover, we compute the minimax risks when the variance of the noise is unknown. The knowledge of this variance is shown to play a significant role in the optimal rates of estimation and testing. All these minimax bounds provide a characterization of statistical problems that are so difficult so that no procedure can provide satisfying results.