English

Ensemble-based estimates of eigenvector error for empirical covariance matrices

Statistics Theory 2018-03-02 v2 Disordered Systems and Neural Networks Probability Applications Statistics Theory

Abstract

Covariance matrices are fundamental to the analysis and forecast of economic, physical and biological systems. Although the eigenvalues {λi}\{\lambda_i\} and eigenvectors {ui}\{{\bf u}_i\} of a covariance matrix are central to such endeavors, in practice one must inevitably approximate the covariance matrix based on data with finite sample size nn to obtain empirical eigenvalues {λ~i}\{\tilde{\lambda}_i\} and eigenvectors {u~i}\{\tilde{{\bf u}}_i\}, and therefore understanding the error so introduced is of central importance. We analyze eigenvector error uiu~i2\|{\bf u}_i - \tilde{{\bf u}}_i \|^2 while leveraging the assumption that the true covariance matrix having size pp is drawn from a matrix ensemble with known spectral properties---particularly, we assume the distribution of population eigenvalues weakly converges as pp\to\infty to a spectral density ρ(λ)\rho(\lambda) and that the spacing between population eigenvalues is similar to that for the Gaussian orthogonal ensemble. Our approach complements previous analyses of eigenvector error that require the full set of eigenvalues to be known, which can be computationally infeasible when pp is large. To provide a scalable approach for uncertainty quantification of eigenvector error, we consider a fixed eigenvalue λ\lambda and approximate the distribution of the expected square error r=E[uiu~i2]r= \mathbb{E}\left[\| {\bf u}_i - \tilde{{\bf u}}_i \|^2\right] across the matrix ensemble for all ui{\bf u}_i associated with λi=λ\lambda_i=\lambda. We find, for example, that for sufficiently large matrix size pp and sample size n>pn>p, the probability density of rr scales as 1/nr21/nr^2. This power-law scaling implies that eigenvector error is extremely heterogeneous---even if rr is very small for most eigenvectors, it can be large for others with non-negligible probability. We support this and further results with numerical experiments.

Keywords

Cite

@article{arxiv.1612.08804,
  title  = {Ensemble-based estimates of eigenvector error for empirical covariance matrices},
  author = {Dane Taylor and Juan G. Restrepo and Francois G. Meyer},
  journal= {arXiv preprint arXiv:1612.08804},
  year   = {2018}
}

Comments

24 pages, 8 figures

R2 v1 2026-06-22T17:35:40.311Z