Design of Planar Multilayer Devices for Optical Filtering Using Surrogate Model Based on Artificial Neural Network

Optics Pub Date : 2024-03-01 DOI:10.3390/opt5010009

D. Rego, Fabrício G. S. Silva, Rodrigo C. Gusmão, Vitaly F. Rodriguez-Esquerre

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Abstract

Artificial intelligence paradigms hold significant potential to advance nanophotonics. This study presents a novel approach to designing a plasmonic absorber using an artificial neural network as a surrogate model in conjunction with a genetic algorithm. The methodology involved numerical simulations of multilayered metal–dielectric plasmonic structures to establish a dataset for training an artificial neural network (ANN). The results demonstrate the proficiency of the trained ANN in predicting reflectance spectra and its ability to generalize intricate relationships between desired performance and geometric configurations, with values of correlation higher than 98% in comparison with ground-truth electromagnetic simulations. Furthermore, the ANN was employed as a surrogate model in a genetic algorithm (GA) loop to achieve target optical behaviors. The proposed methodology provides a powerful means of inverse designing multilayered metal–dielectric devices tailored for visible band wavelength filtering. This research demonstrates that the integration of AI-driven approaches in nanophotonics leads to efficient and effective design strategies.

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利用基于人工神经网络的代用模型设计用于光学滤波的平面多层设备

人工智能范式在推动纳米光子学发展方面具有巨大潜力。本研究提出了一种设计等离子体吸收器的新方法，使用人工神经网络作为代用模型，并结合遗传算法。该方法包括对多层金属电介质质子结构进行数值模拟，以建立用于训练人工神经网络（ANN）的数据集。结果表明，训练有素的人工神经网络能熟练预测反射光谱，并能归纳出所需性能与几何配置之间错综复杂的关系，与地面实况电磁模拟的相关性值高于 98%。此外，在遗传算法（GA）循环中，还将 ANN 用作替代模型，以实现目标光学行为。所提出的方法为反向设计多层金属-电介质器件提供了一种强大的手段，该器件专为可见波段波长滤波而量身定制。这项研究表明，在纳米光子学中集成人工智能驱动的方法，可带来高效和有效的设计策略。

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来源期刊

Optics

CiteScore

2.20

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0.00%

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