Statistical Inference for Linear Functionals of Online Least-squares SGD when t d1+δ
Abstract
Stochastic Gradient Descent (SGD) has become a cornerstone method in modern data science. However, deploying SGD in high-stakes applications necessitates rigorous quantification of its inherent uncertainty. In this work, we establish non-asymptotic Berry--Esseen bounds for linear functionals of online least-squares SGD, thereby providing a Gaussian Central Limit Theorem (CLT) in a growing-dimensional regime. Existing approaches to high-dimensional inference for projection parameters, such as~chang2023inference, rely on inverting empirical covariance matrices and require at least t d3/2 iterations to achieve finite-sample Berry--Esseen guarantees, rendering them computationally expensive and restrictive in the allowable dimensional scaling. In contrast, we show that a CLT holds for SGD iterates when the number of iterations grows as t d1+δ for any δ > 0, significantly extending the dimensional regime permitted by prior works while improving computational efficiency. The proposed online SGD-based procedure operates in O(td) time and requires only O(d) memory, in contrast to the O(td2 + d3) runtime of covariance-inversion methods. To render the theory practically applicable, we further develop an online variance estimator for the asymptotic variance appearing in the CLT and establish high-probability deviation bounds for this estimator. Collectively, these results yield the first fully online and data-driven framework for constructing confidence intervals for SGD iterates in the near-optimal scaling regime t d1+δ.
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