Matrix decompositions in quantum optics: Takagi/Autonne, Bloch–Messiah/Euler, Iwasawa, and Williamson

Martin Houde; Will McCutcheon; Nicolás Quesada

doi:10.1139/cjp-2024-0070

Matrix decompositions in quantum optics: Takagi/Autonne, Bloch–Messiah/Euler, Iwasawa, and Williamson

Martin Houde, Will McCutcheon, Nicolás Quesada

School of Engineering & Physical Sciences

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

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Abstract

In this tutorial, we summarize four important matrix decompositions commonly used in quantum optics, namely the Takagi/Autonne, Bloch–Messiah/Euler, Iwasawa, and Williamson decompositions. The first two of these decompositions are specialized versions of the singular-value decomposition when applied to symmetric or symplectic matrices. The third factors any symplectic matrix in a unique way in terms of matrices that belong to different subgroups of the symplectic group. The last one instead gives the symplectic diagonalization of real, positive definite matrices of even size. While proofs of the existence of these decompositions exist in the literature, we review explicit constructions to implement these decompositions using standard linear algebra packages and functionalities such as singular-value, polar, Schur, and QR decompositions, and matrix square roots and inverses.

Original language	English
Pages (from-to)	497-507
Number of pages	11
Journal	Canadian Journal of Physics
Volume	102
Issue number	10
Early online date	17 Jul 2024
DOIs	https://doi.org/10.1139/cjp-2024-0070
Publication status	Published - Oct 2024

Keywords

Bloch–Messiah
Iwasawa
Takagi-Autonne
Williamson
matrix decomposition
quantum optics

ASJC Scopus subject areas

General Physics and Astronomy

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Matrix decompositions in quantum optics: Takagi/Autonne, Bloch–Messiah/Euler, Iwasawa, and Williamson

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