Overlaps, Eigenvalue Gaps, and Pseudospectrum under real Ginibre and Absolutely Continuous Perturbations
Abstract
Let be an matrix with real i.i.d. entries, let be a real matrix with , and let . We show that with probability , has all of its eigenvalue condition numbers bounded by and eigenvector condition number bounded by . Furthermore, we show that for any , the probability that has two eigenvalues within distance at most of each other is In fact, we show the above statements hold in the more general setting of non-Gaussian perturbations with real, independent, absolutely continuous entries with a finite moment assumption and appropriate normalization. This extends the previous work [Banks et al. 2019] which proved an eigenvector condition number bound of for the simpler case of {\em complex} i.i.d. Gaussian matrix perturbations. The case of real perturbations introduces several challenges stemming from the weaker anticoncentration properties of real vs. complex random variables. A key ingredient in our proof is new lower tail bounds on the small singular values of the complex shifts which recover the tail behavior of the complex Ginibre ensemble when . This yields sharp control on the area of the pseudospectrum in terms of the pseudospectral parameter , which is sufficient to bound the overlaps and eigenvector condition number via a limiting argument.
Keywords
Cite
@article{arxiv.2005.08930,
title = {Overlaps, Eigenvalue Gaps, and Pseudospectrum under real Ginibre and Absolutely Continuous Perturbations},
author = {Jess Banks and Jorge Garza Vargas and Archit Kulkarni and Nikhil Srivastava},
journal= {arXiv preprint arXiv:2005.08930},
year = {2020}
}
Comments
Concurrent independent work by Jain et al. is mentioned in Remark 1.1