Sparse Pseudospectral Shattering
Abstract
The eigenvalues and eigenvectors of nonnormal matrices can be unstable under perturbations of their entries. This renders an obstacle to the analysis of numerical algorithms for non-Hermitian eigenvalue problems. A recent technique to handle this issue is pseudospectral shattering [BGVKS23], showing that adding a random perturbation to any matrix has a regularizing effect on the stability of the eigenvalues and eigenvectors. Prior work has analyzed the regularizing effect of dense Gaussian perturbations, where independent noise is added to every entry of a given matrix [BVKS20, BGVKS23, BKMS21, JSS21]. We show that the same effect can be achieved by adding a sparse random perturbation. In particular, we show that given any matrix of polynomially bounded norm: (a) perturbing random entries of by adding i.i.d. complex Gaussians yields and with high probability; (b) perturbing random entries of for any constant yields and with high probability. Here, denotes the condition number of the eigenvectors of the perturbed matrix and denotes its minimum eigenvalue gap. A key mechanism of the proof is to reduce the study of to control of the pseudospectral area and minimum eigenvalue gap of , which are further reduced to estimates on the least two singular values of shifts of . We obtain the required least singular value estimates via a streamlining of an argument of Tao and Vu [TV07] specialized to the case of sparse complex Gaussian perturbations. [Rest of abstract in pdf].
Cite
@article{arxiv.2411.19926,
title = {Sparse Pseudospectral Shattering},
author = {Rikhav Shah and Nikhil Srivastava and Edward Zeng},
journal= {arXiv preprint arXiv:2411.19926},
year = {2026}
}