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Autores principales: Wang, Zhaolin, Ranasinghe, Kuranage Roche Rayan, de Abreu, Giuseppe Thadeu Freitas, Liu, Yuanwei
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2511.11225
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author Wang, Zhaolin
Ranasinghe, Kuranage Roche Rayan
de Abreu, Giuseppe Thadeu Freitas
Liu, Yuanwei
author_facet Wang, Zhaolin
Ranasinghe, Kuranage Roche Rayan
de Abreu, Giuseppe Thadeu Freitas
Liu, Yuanwei
contents The phenomenon of mutual coupling in continuous aperture arrays (CAPAs) is studied. First, a general physical model for the phenomenon that accounts for both polarization and surface dissipation losses is developed. Then, the unipolarized coupling kernel is characterized, revealing that polarization induces anisotropic coupling and invalidates the conventional half-wavelength spacing rule for coupling elimination. Next, the beamforming design problem for CAPAs with coupling is formulated as a functional optimization problem, leading to the derivation of optimal beamforming structures via the calculus of variations. To address the challenge of inverting the coupling kernel in the optimal structure, two methods are proposed: 1) the kernel approximation method, which yields a closed-form solution via wavenumber-domain transformation and GaussLegendre quadrature, and 2) the conjugate gradient method, which addresses an equivalent quadratic functional optimization problem iteratively. Furthermore, the optimal array gain and beampattern are analyzed at the large-aperture limit. Finally, the proposed continuous mutual coupling model is extended to spatially discrete arrays (SPDAs), and comprehensive numerical results are provided, demonstrating that: 1) coupled SPDA performance correctly converges to the CAPA limit, while uncoupled models are shown to violate physics, 2) polarization results in anisotropic array gain behavior, and 3) the coupled beampattern exhibits higher directivity than the uncoupled beampattern.
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institution arXiv
publishDate 2025
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spellingShingle Mutual Coupling in Continuous Aperture Arrays: Physical Modeling and Beamforming Design
Wang, Zhaolin
Ranasinghe, Kuranage Roche Rayan
de Abreu, Giuseppe Thadeu Freitas
Liu, Yuanwei
Information Theory
The phenomenon of mutual coupling in continuous aperture arrays (CAPAs) is studied. First, a general physical model for the phenomenon that accounts for both polarization and surface dissipation losses is developed. Then, the unipolarized coupling kernel is characterized, revealing that polarization induces anisotropic coupling and invalidates the conventional half-wavelength spacing rule for coupling elimination. Next, the beamforming design problem for CAPAs with coupling is formulated as a functional optimization problem, leading to the derivation of optimal beamforming structures via the calculus of variations. To address the challenge of inverting the coupling kernel in the optimal structure, two methods are proposed: 1) the kernel approximation method, which yields a closed-form solution via wavenumber-domain transformation and GaussLegendre quadrature, and 2) the conjugate gradient method, which addresses an equivalent quadratic functional optimization problem iteratively. Furthermore, the optimal array gain and beampattern are analyzed at the large-aperture limit. Finally, the proposed continuous mutual coupling model is extended to spatially discrete arrays (SPDAs), and comprehensive numerical results are provided, demonstrating that: 1) coupled SPDA performance correctly converges to the CAPA limit, while uncoupled models are shown to violate physics, 2) polarization results in anisotropic array gain behavior, and 3) the coupled beampattern exhibits higher directivity than the uncoupled beampattern.
title Mutual Coupling in Continuous Aperture Arrays: Physical Modeling and Beamforming Design
topic Information Theory
url https://arxiv.org/abs/2511.11225