Block perturbation of symplectic matrices in Williamson's theorem

Abstract

Williamson's theorem states that for any 2n × 2n real positive definite matrix A, there exists a 2n × 2n real symplectic matrix S such that STAS=D D, where D is an n× n diagonal matrix with positive diagonal entries which are known as the symplectic eigenvalues of A. Let H be any 2n × 2n real symmetric matrix such that the perturbed matrix A+H is also positive definite. In this paper, we show that any symplectic matrix S diagonalizing A+H in Williamson's theorem is of the form S=S Q+O(\|H\|), where Q is a 2n × 2n real symplectic as well as orthogonal matrix. Moreover, Q is in symplectic block diagonal form with the block sizes given by twice the multiplicities of the symplectic eigenvalues of A. Consequently, we show that S and S can be chosen so that \|S-S\|=O(\|H\|). Our results hold even if A has repeated symplectic eigenvalues. This generalizes the stability result of symplectic matrices for non-repeated symplectic eigenvalues given by Idel, Gaona, and Wolf [Linear Algebra Appl., 525:45-58, 2017].