Williamson theorem

In the context of linear algebra and symplectic geometry, the Williamson theorem concerns the diagonalization of positive definite matrices through symplectic matrices.^[1]^[2]^[3]

More precisely, given a strictly positive-definite $2n\times 2n$ Hermitian real matrix $M\in \mathbb {R} ^{2n\times 2n}$ , the theorem ensures the existence of a real symplectic matrix $S\in \mathbf {Sp} (2n,\mathbb {R} )$ , and a diagonal positive real matrix $D\in \mathbb {R} ^{n\times n}$ , such that $SMS^{T}=I_{2}\otimes D\equiv D\oplus D,$ where $I_{2}$ denotes the 2x2 identity matrix.

Proof

The derivation of the result hinges on a few basic observations:

The real matrix $M^{-1/2}(J\otimes I_{n})M^{-1/2}$ , with $J\equiv {\begin{pmatrix}0&1\\-1&0\end{pmatrix}}$ , is well-defined and skew-symmetric.
Any skew-symmetric real matrix $A\in \mathbb {R} ^{2n\times 2n}$ can be block-diagonalized via orthogonal real matrices, meaning there is $O\in \mathbf {O} (2n)$ such that $OAO^{T}=I_{2}\otimes \Lambda$ with $\Lambda$ a real positive-definite diagonal matrix containing the singular values of $A$ .
For any orthogonal $O\in \mathbf {O} (2n)$ , the matrix $S=(I\otimes {\sqrt {D}})OM^{-1/2}$ is such that $SMS^{T}=I_{2}\otimes D$ .
If $O\in \mathbf {O} (2n)$ diagonalizes $M^{-1/2}(J\otimes I_{n})M^{-1/2}$ , meaning it satisfies $OM^{-1/2}(J\otimes I_{n})M^{-1/2}O^{T}=I_{2}\otimes \Lambda ,$ then $S=(I\otimes {\sqrt {D}})OM^{-1/2}$ is such that $S(J\otimes I_{n})S^{T}=J\otimes (D\Lambda ).$ Therefore, taking $D=\Lambda ^{-1}$ , the matrix $S$ is also a symplectic matrix, satisfying $S(J\otimes I_{n})S^{T}=J\otimes I_{n}$ .