English

Inference in High-Dimensional Linear Regression via Lattice Basis Reduction and Integer Relation Detection

Statistics Theory 2023-09-19 v1 Probability Machine Learning Statistics Theory

Abstract

We focus on the high-dimensional linear regression problem, where the algorithmic goal is to efficiently infer an unknown feature vector βRp\beta^*\in\mathbb{R}^p from its linear measurements, using a small number nn of samples. Unlike most of the literature, we make no sparsity assumption on β\beta^*, but instead adopt a different regularization: In the noiseless setting, we assume β\beta^* consists of entries, which are either rational numbers with a common denominator QZ+Q\in\mathbb{Z}^+ (referred to as QQ-rationality); or irrational numbers supported on a rationally independent set of bounded cardinality, known to learner; collectively called as the mixed-support assumption. Using a novel combination of the PSLQ integer relation detection, and LLL lattice basis reduction algorithms, we propose a polynomial-time algorithm which provably recovers a βRp\beta^*\in\mathbb{R}^p enjoying the mixed-support assumption, from its linear measurements Y=XβRnY=X\beta^*\in\mathbb{R}^n for a large class of distributions for the random entries of XX, even with one measurement (n=1)(n=1). In the noisy setting, we propose a polynomial-time, lattice-based algorithm, which recovers a βRp\beta^*\in\mathbb{R}^p enjoying QQ-rationality, from its noisy measurements Y=Xβ+WRnY=X\beta^*+W\in\mathbb{R}^n, even with a single sample (n=1)(n=1). We further establish for large QQ, and normal noise, this algorithm tolerates information-theoretically optimal level of noise. We then apply these ideas to develop a polynomial-time, single-sample algorithm for the phase retrieval problem. Our methods address the single-sample (n=1)(n=1) regime, where the sparsity-based methods such as LASSO and Basis Pursuit are known to fail. Furthermore, our results also reveal an algorithmic connection between the high-dimensional linear regression problem, and the integer relation detection, randomized subset-sum, and shortest vector problems.

Keywords

Cite

@article{arxiv.1910.10890,
  title  = {Inference in High-Dimensional Linear Regression via Lattice Basis Reduction and Integer Relation Detection},
  author = {David Gamarnik and Eren C. Kızıldağ and Ilias Zadik},
  journal= {arXiv preprint arXiv:1910.10890},
  year   = {2023}
}

Comments

56 pages. Parts of the material of this manuscript were presented at NeurIPS 2018, and ISIT 2019. This submission subsumes the content of arXiv:1803.06716

R2 v1 2026-06-23T11:53:17.382Z