DIMENSION FREE RIDGE REGRESSION

Article

Cheng, Chen; Montanari, Andrea

Stanford University; Stanford University

ANNALS OF STATISTICS

0090-5364

10.1214/24-AOS2449

2024

2879-2912

Random matrix theory has become a widely useful tool in high-dimensional statistics and theoretical machine learning. However, random matrix theory is largely focused on the proportional asymptotics in which the number of columns grows proportionally to the number of rows of the data matrix. This is not always the most natural setting in statistics where columns correspond to covariates and rows to samples. With the objective to move beyond the proportional asymptotics, we revisit ridge regression (l(2)-penalized least squares) on i.i.d. data (x(i), y(i)), i <= n, where x(i) is a feature vector and y(i) = + epsilon(i) is an element of R is a response. We allow the feature vector to be high-dimensional, or even infinite-dimensional, in which case it belongs to a separable Hilbert space, and assume either z(i) := Sigma(-1/2)x(i) to have i.i.d. entries, or to satisfy a certain convex concentration property. Within this setting, we establish nonasymptotic bounds that approximate the bias and variance of ridge regression in terms of the bias and variance of an equivalent sequence model (a regression model with diagonal design matrix). The approximation is up to multiplicative factors bounded by (1 +/-Delta) for some explicitly small Delta. Previously, such an approximation result was known only in the proportional regime and only up to additive errors: in particular, it did not allow to characterize the behavior of the excess risk when this converges to 0. Our general theory recovers earlier results in the proportional regime (with better error rates). As a new application, we obtain a completely explicit and sharp characterization of ridge regression for Hilbert covariates with regularly varying spectrum. Finally, we analyze the overparametrized near-interpolation setting and obtain sharp benign overfitting guarantees.