Ultraprecision, high-capacity, and wide-gamut structural colors enabled by a mixture probability sampling network
Zeyong Wei, Weijie Xu, Siyu Dong, Xiaojia Liang, Jingyuan Zhu, Hui Zhang, Kaixuan Li, Lei Jin, Zhanshan Wang, Yuzhi Shi, Gang Yan, Cheng-Wei Qiu, Xinbin Cheng

TL;DR
This paper introduces a new machine learning method for designing nanophotonic structures with high precision and accuracy.
Contribution
A novel mixture probability sampling network is proposed to improve inverse design in nanophotonics.
Findings
The method achieves 99.9% precision in structural color design.
The mean absolute error is less than 0.002, demonstrating high accuracy.
The approach outperforms existing methods in handling complex structural configurations.
Abstract
The advancement of nanophotonic devices is significantly dependent on achieving high-precision inverse design capabilities, which are critical for identifying optimal structural configurations that enable enhanced and multifunctional performances. The process of inverse design confronts a one-to-many relationship due to the complex mapping between optical performance and structure. Though several approaches, including tandem networks, mixture density networks (MDN), and conditional generative adversarial networks, have shown promising outcomes, they still face accuracy limitations when confronted with structures with higher degrees of freedom. Here, we propose a sampling-enhanced MDN called a mixture probability sampling network (MPSN), that outputs mixture Gaussian distributions (MGDs) of structural parameters through an end-to-end framework. The results of multiple samples drawn from…
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Taxonomy
TopicsNeural Networks and Reservoir Computing · Metamaterials and Metasurfaces Applications · Photonic Crystals and Applications
