A framework to compute resonances arising from multiple scattering

arXiv - PHYS - Optics Pub Date : 2024-09-09 DOI:arxiv-2409.05563

Jan David Fischbach, Fridtjof Betz, Nigar Asadova, Pietro Tassan, Darius Urbonas, Thilo Stöferle, Rainer F. Mahrt, Sven Burger, Carsten Rockstuhl, Felix Binkowski, Thomas Jebb Sturges

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Abstract

A sample refinement strategy suitable for accurately locating a large number of poles is introduced. We tie the AAA algorithm into an automatic differentiation framework to efficiently differentiate multi-scattering resonance calculations. The resulting resonance solver allows for efficient gradient-based optimization, demonstrated here by the inverse design of an integrated exciton-polariton cavity. This contribution serves as an important step towards efficient resonance calculations in a variety of multi-scattering scenarios, such as inclusions in stratified media, periodic lattices, and scatterers with arbitrary shapes. A sample refinement strategy suitable for accurately locating a large number of poles is introduced. We tie the AAA algorithm into an automatic differentiation framework to efficiently differentiate multi-scattering resonance calculations. The resulting resonance solver allows for efficient gradient-based optimization, demonstrated here by the inverse design of an integrated exciton-polariton cavity. This contribution serves as an important step towards efficient resonance calculations in a variety of multi-scattering scenarios, such as inclusions in stratified media, periodic lattices, and scatterers with arbitrary shapes.

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计算多重散射共振的框架

介绍了一种适用于精确定位大量极点的样本细化策略。我们将 AAA 算法与自动微分框架相结合，以高效微分多散射共振计算。由此产生的共振求解器允许进行基于梯度的高效优化，这里通过反向设计一个集成的激子-极化子腔来证明这一点。这一贡献是在各种多散射情况下实现高效共振计算的重要一步，如分层介质中的夹杂物、周期晶格和任意形状的散射体。我们介绍了一种适用于精确定位大量极点的样本细化策略。我们将 AAA 算法与自动微分框架相结合，以高效地微分多散射共振计算。由此产生的共振求解器允许进行基于梯度的高效优化，并在此通过反向设计集成的激子-极化子腔进行了演示。这是在多种多散射情况下（如分层介质中的夹杂物、周期晶格和任意形状的散射体）进行高效共振计算的重要一步。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Optics

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