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Bibliographic Details
Main Authors: Virally, Paul, Chao, Pengning, Amaolo, Alessio, Rodriguez, Alejandro, Molesky, Sean
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.01128
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author Virally, Paul
Chao, Pengning
Amaolo, Alessio
Rodriguez, Alejandro
Molesky, Sean
author_facet Virally, Paul
Chao, Pengning
Amaolo, Alessio
Rodriguez, Alejandro
Molesky, Sean
contents We develop a general method to bound the ordered singular values (channel amplitudes) of the electromagnetic Green function for arbitrarily structured linear photonic systems. The approach yields computable, quantitatively predictive, upper bounds on the $n^{th}$ singular value that capture the complexity of multi-channel tradeoffs from the device perspective. As an illustration of the practical value of the framework, indexed channel bounds are obtained for multi-wavelength scale three-dimensional volumes (up to $64\,λ^3$) and applied to common application classes related to waveguides, metasurfaces, and planewave detection. These results are immediately applicable to the calculation of information theoretic objectives such as Shannon capacity and Fisher information.
format Preprint
id arxiv_https___arxiv_org_abs_2510_01128
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle How many channels can a photonic system support?
Virally, Paul
Chao, Pengning
Amaolo, Alessio
Rodriguez, Alejandro
Molesky, Sean
Optics
We develop a general method to bound the ordered singular values (channel amplitudes) of the electromagnetic Green function for arbitrarily structured linear photonic systems. The approach yields computable, quantitatively predictive, upper bounds on the $n^{th}$ singular value that capture the complexity of multi-channel tradeoffs from the device perspective. As an illustration of the practical value of the framework, indexed channel bounds are obtained for multi-wavelength scale three-dimensional volumes (up to $64\,λ^3$) and applied to common application classes related to waveguides, metasurfaces, and planewave detection. These results are immediately applicable to the calculation of information theoretic objectives such as Shannon capacity and Fisher information.
title How many channels can a photonic system support?
topic Optics
url https://arxiv.org/abs/2510.01128