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Private Covariance Approximation and Eigenvalue-Gap Bounds for Complex Gaussian Perturbations

Data Structures and Algorithms 2023-06-30 v1 Cryptography and Security Machine Learning Numerical Analysis Numerical Analysis Probability

Abstract

We consider the problem of approximating a d×dd \times d covariance matrix MM with a rank-kk matrix under (ε,δ)(\varepsilon,\delta)-differential privacy. We present and analyze a complex variant of the Gaussian mechanism and show that the Frobenius norm of the difference between the matrix output by this mechanism and the best rank-kk approximation to MM is bounded by roughly O~(kd)\tilde{O}(\sqrt{kd}), whenever there is an appropriately large gap between the kk'th and the k+1k+1'th eigenvalues of MM. This improves on previous work that requires that the gap between every pair of top-kk eigenvalues of MM is at least d\sqrt{d} for a similar bound. Our analysis leverages the fact that the eigenvalues of complex matrix Brownian motion repel more than in the real case, and uses Dyson's stochastic differential equations governing the evolution of its eigenvalues to show that the eigenvalues of the matrix MM perturbed by complex Gaussian noise have large gaps with high probability. Our results contribute to the analysis of low-rank approximations under average-case perturbations and to an understanding of eigenvalue gaps for random matrices, which may be of independent interest.

Keywords

Cite

@article{arxiv.2306.16648,
  title  = {Private Covariance Approximation and Eigenvalue-Gap Bounds for Complex Gaussian Perturbations},
  author = {Oren Mangoubi and Nisheeth K. Vishnoi},
  journal= {arXiv preprint arXiv:2306.16648},
  year   = {2023}
}

Comments

This is the full version of a paper which was accepted to COLT 2023

R2 v1 2026-06-28T11:17:30.230Z