Restricted Eigenvalue from Stable Rank with Applications to Sparse Linear Regression

TL;DR

This paper introduces a new method for constructing random design matrices with guaranteed Restricted Eigenvalue conditions, enabling better analysis and application of sparse linear regression in high-dimensional settings.

Contribution

It presents a novel ensemble of dependent random matrices derived from a fixed matrix with stable rank properties, satisfying RE conditions with high probability.

Findings

Constructed matrices satisfy RE condition with high probability

Enables compressed design matrices with lower storage requirements

Applicable to sparse regression with compressed data

Abstract

High-dimensional settings, where the data dimension ($d$) far exceeds the number of observations ($n$), are common in many statistical and machine learning applications. Methods based on $\ell_1$-relaxation, such as Lasso, are very popular for sparse recovery in these settings. Restricted Eigenvalue (RE) condition is among the weakest, and hence the most general, condition in literature imposed on the Gram matrix that guarantees nice statistical properties for the Lasso estimator. It is natural to ask: what families of matrices satisfy the RE condition? Following a line of work in this area, we construct a new broad ensemble of dependent random design matrices that have an explicit RE bound. Our construction starts with a fixed (deterministic) matrix $X \in \mathbb{R}^{n \times d}$ satisfying a simple stable rank condition, and we show that a matrix drawn from the distribution $X \Phi^\top \Phi$, where $\Phi \in \mathbb{R}^{m \times d}$ is a subgaussian random matrix, with high probability, satisfies the RE condition. This construction allows incorporating a fixed matrix that has an easily {\em verifiable} condition into the design process, and allows for generation of {\em compressed} design matrices that have a lower storage requirement than a standard design matrix. We give two applications of this construction to sparse linear regression problems, including one to a compressed sparse regression setting where the regression algorithm only has access to a compressed representation of a fixed design matrix $X$.