Universality of regularized regression estimators in high dimensions
本文证明,对于一类广泛的正则化回归估计量,若其在标准高斯设计下满足某种结构性质,则在一般非高斯独立同分布设计下也成立,并以岭回归、Lasso和稳健回归为例验证了风险渐近和分布的普适性。
The Convex Gaussian Min–Max Theorem (CGMT) has emerged as a prominent theoretical tool for analyzing the precise stochastic behavior of various statistical estimators in the so-called high-dimensional proportional regime, where the sample size and the signal dimension are of the same order. However, a well-recognized limitation of the existing CGMT machinery rests in its stringent requirement on the exact Gaussianity of the design matrix, therefore rendering the obtained precise high-dimensional asymptotics, largely a specific Gaussian theory in various important statistical models. This paper provides a structural universality framework for a broad class of regularized regression estimators that is particularly compatible with the CGMT machinery. Here, universality means that if a “structure” is satisfied by the regression estimator μˆG for a standard Gaussian design G, then it will also be satisfied by μˆA for a general non-Gaussian design A with independent entries. In particular, we show that with a good enough ℓ∞ bound for the regression estimator μˆA, any “structural property” that can be detected via the CGMT for μˆG also holds for μˆA under a general design A with independent entries. As a proof of concept, we demonstrate our new universality framework in three key examples of regularized regression estimators: the Ridge, Lasso and regularized robust regression estimators, where new universality properties of risk asymptotics and/or distributions of regression estimators and other related quantities are proved. As a major statistical implication of the Lasso universality results, we validate inference procedures using the degrees-of-freedom adjusted debiased Lasso under general design and error distributions. We also provide a counterexample, showing that universality properties for regularized regression estimators do not extend to general isotropic designs. The proof of our universality results relies on new comparison inequalities for the optimum of a broad class of cost functions and Gordon’s max–min (or min–max) costs, over arbitrary structure sets subject to ℓ∞ constraints. These results may be of independent interest and broader applicability.