Large deviations for the largest eigenvalue of generalized sample covariance matrices
Abstract
We establish a large-deviations principle for the largest eigenvalue of a generalized sample covariance matrix, meaning a matrix proportional to , where has i.i.d. real or complex entries and is not necessarily the identity. We treat the classical case when is Gaussian and is positive definite, but we also cover two orthogonal extensions: Either the entries of can instead be sharp sub-Gaussian, a class including Rademacher and uniform distributions, where we find the same rate function as for the Gaussian model; or can have negative eigenvalues if remains Gaussian. The latter case confirms formulas of Maillard in the physics literature. We also apply our techniques to the largest eigenvalue of a deformed Wigner matrix, real or complex, where we upgrade previous large-deviations estimates to a full large-deviations principle. Finally, we remove several technical assumptions present in previous related works.
Cite
@article{arxiv.2302.02847,
title = {Large deviations for the largest eigenvalue of generalized sample covariance matrices},
author = {Jonathan Husson and Benjamin McKenna},
journal= {arXiv preprint arXiv:2302.02847},
year = {2023}
}