Optimal linear estimation under unknown nonlinear transform

Abstract

Linear regression studies the problem of estimating a model parameter β* ∈ Rp, from n observations \(yi,xi)\i=1n from linear model yi = xi,β* + εi. We consider a significant generalization in which the relationship between xi,β* and yi is noisy, quantized to a single bit, potentially nonlinear, noninvertible, as well as unknown. This model is known as the single-index model in statistics, and, among other things, it represents a significant generalization of one-bit compressed sensing. We propose a novel spectral-based estimation procedure and show that we can recover β* in settings (i.e., classes of link function f) where previous algorithms fail. In general, our algorithm requires only very mild restrictions on the (unknown) functional relationship between yi and xi,β* . We also consider the high dimensional setting where β* is sparse ,and introduce a two-stage nonconvex framework that addresses estimation challenges in high dimensional regimes where p n. For a broad class of link functions between xi,β* and yi, we establish minimax lower bounds that demonstrate the optimality of our estimators in both the classical and high dimensional regimes.