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The smallest singular value of inhomogenous random rectangular matrices

Probability 2025-07-28 v2 Metric Geometry

Abstract

Let ARN×nA \in \mathbb{R}^{N \times n} (NnN \geq n) be a random matrix with with independent entries that have mean 0 variance 1 and bounded 2+β2+\beta moment. We show that the smallest singular value σn(A)\sigma_n(A) satisfies Pr(σn(A)ε(N+1n))(Cε)Nn+1+ecN, \Pr \left(\sigma_n(A) \leq \varepsilon(\sqrt{N+1} - \sqrt{n})\right) \leq (C\varepsilon)^{N-n+1} + e^{-cN}, for all ε>0\varepsilon > 0, where c,Cc,C depend only on β\beta and the 2+β2+\beta moment. This extends earlier results of Rudelson and Vershynin, who showed that such lower tail estimates held for rectangular matrices with i.i.d. mean 0 subgaussian entries. When the 2+β2+\beta moment assumption is replaced with a uniform anti-concentration assumption, supzPr(Xz<a)<b\sup_z \Pr\left(|X-z| < a\right) < b, we show that Pr(σn(A)ε(N+1n))(Cεlog(1/ε))Nn+1+ecN, \Pr\left(\sigma_n(A) \leq \varepsilon(\sqrt{N+1} - \sqrt{n})\right) \leq (C\varepsilon\log(1/\varepsilon))^{N-n+1} + e^{-cN}, where c,Cc,C now depend only on aa and bb. This extends more recent work of Livshyts, whose showed that such lower tail estimates held for rectrangular matrices with i.i.d. rows. To prove these results we employ a number of new technical ingredients, including a new deviation inequality for the regularized Hilbert-Schmidt norm and a recently proven small ball estimate for the distance between a random vector and a subspace spanned by an inhomogeneous rectangular matrix.

Keywords

Cite

@article{arxiv.2408.14389,
  title  = {The smallest singular value of inhomogenous random rectangular matrices},
  author = {Max Dabagia and Manuel Fernandez},
  journal= {arXiv preprint arXiv:2408.14389},
  year   = {2025}
}

Comments

introduced some new notation, simplified a number of proofs and fixed some typos and misprints. Updated Theorem 8 and 9 to be slightly more general

R2 v1 2026-06-28T18:24:09.907Z