Matrix Perturbation Theory in the Tangent Space of Isospectral Matrices

Abstract

Eigenvalue and eigenvector perturbation theory is a fundamental topic in several disciplines, including numerical linear algebra, quantum physics, and related fields. The central problem is to understand how the eigenvalues and eigenvectors of a matrix A ∈ Cn × n change under the addition of a perturbation matrix E ∈ Cn × n. Much of the existing literature focuses on structured perturbations. For example, in [C.-K. Li and R.-C. Li, Linear Algebra Appl. 2005], the matrix A is assumed to be Hermitian and block diagonal, while the perturbation E is Hermitian and block off-diagonal. In this work, we investigate a different structured setting in which the perturbation has the commutator form E = AB - BA for some matrix B, which we show to be a generalization of the block diagonal structure considered by Li and Li. First, we extend their main result by showing that the perturbation of the i-th eigenvalue of A, denoted by λi, is of order \|E\|2 / ηi, where ηi = j ≠ i |λi - λj| is the spectral gap associated with λi. Second, we provide a detailed analysis of the role played by the matrix B in the perturbation of the eigenvectors. This analysis is further generalized to the case of block-diagonal matrices with multiple eigenvalues, as well as to perturbed singular values and eigenvalues of Jordan blocks.