Sample-efficient inverse design of freeform nanophotonic devices with physics-informed reinforcement learning

Park Chaejin; Kim Sanmun; Jung Anthony W.; Park Juho; Seo Dongjin; Kim Yongha; Park Chanhyung; Park Chan Y.; Jang Min Seok

doi:10.1515/nanoph-2023-0852

Nanophotonics (Feb 2024)

Sample-efficient inverse design of freeform nanophotonic devices with physics-informed reinforcement learning

Park Chaejin,
Kim Sanmun,
Jung Anthony W.,
Park Juho,
Seo Dongjin,
Kim Yongha,
Park Chanhyung,
Park Chan Y.,
Jang Min Seok

Affiliations

Park Chaejin: School of Electrical Engineering, 34968Korea Advanced Institute of Science and Technology, Daejeon34141, Republic of Korea
Kim Sanmun: School of Electrical Engineering, 34968Korea Advanced Institute of Science and Technology, Daejeon34141, Republic of Korea
Jung Anthony W.: KC Machine Learning Lab, Seoul06181, Republic of Korea
Park Juho: School of Electrical Engineering, 34968Korea Advanced Institute of Science and Technology, Daejeon34141, Republic of Korea
Seo Dongjin: School of Electrical Engineering, 34968Korea Advanced Institute of Science and Technology, Daejeon34141, Republic of Korea
Kim Yongha: KC Machine Learning Lab, Seoul06181, Republic of Korea
Park Chanhyung: School of Electrical Engineering, 34968Korea Advanced Institute of Science and Technology, Daejeon34141, Republic of Korea
Park Chan Y.: KC Machine Learning Lab, Seoul06181, Republic of Korea
Jang Min Seok: School of Electrical Engineering, 34968Korea Advanced Institute of Science and Technology, Daejeon34141, Republic of Korea

DOI: https://doi.org/10.1515/nanoph-2023-0852
Journal volume & issue: Vol. 13, no. 8
pp. 1483 – 1492

Abstract

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Finding an optimal device structure in the vast combinatorial design space of freeform nanophotonic design has been an enormous challenge. In this study, we propose physics-informed reinforcement learning (PIRL) that combines the adjoint-based method with reinforcement learning to improve the sample efficiency by an order of magnitude compared to conventional reinforcement learning and overcome the issue of local minima. To illustrate these advantages of PIRL over other conventional optimization algorithms, we design a family of one-dimensional metasurface beam deflectors using PIRL, exceeding most reported records. We also explore the transfer learning capability of PIRL that further improves sample efficiency and demonstrate how the minimum feature size of the design can be enforced in PIRL through reward engineering. With its high sample efficiency, robustness, and ability to seamlessly incorporate practical device design constraints, our method offers a promising approach to highly combinatorial freeform device optimization in various physical domains.

Published in Nanophotonics

ISSN: 2192-8606 (Print); 2192-8614 (Online)
Publisher: De Gruyter
Country of publisher: Germany
LCC subjects: Science: Physics
Website: https://www.degruyter.com/journal/key/nanoph/html#submit

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