Dynamic multifunctional metasurfaces: an inverse design deep learning approach

Lei, Zhi-Dan; Xu, Yi-Duo; Lei, Cheng; Zhao, Yan; Wang, Du

doi:10.1364/prj.505991

Photon. Res.

2023

DOI: 10.1364/prj.505991

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Dynamic multifunctional metasurfaces: an inverse design deep learning approach

Zhi-Dan Lei,

Yi-Duo Xu,

Cheng Lei

et al.

Abstract: Optical metasurfaces (OMs) offer unprecedented control over electromagnetic waves, enabling advanced optical multiplexing. The emergence of deep learning has opened new avenues for designing OMs. However, existing deep learning methods for OMs primarily focus on forward design, which limits their design capabilities, lacks global optimization, and relies on prior knowledge. Additionally, most OMs are static, with fixed functionalities once processed. To overcome these limitations, we propose an inverse design … Show more

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Generative Inverse Design of Metamaterials with Functional Responses by Interpretable Learning

Chen,

Sun,

Lee

et al. 2024

Advanced Intelligent Systems

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Metamaterials with functional responses can exhibit varying properties under different conditions (e.g., wave‐based responses or deformation‐induced property variation). This work addresses rapid inverse design of such metamaterials to meet target qualitative functional behaviors, a challenge due to its intractability and nonunique solutions. Unlike data‐intensive and noninterpretable deep‐learning‐based methods, this work proposes the random‐forest‐based interpretable generative inverse design (RIGID), a single‐shot inverse design method for fast generation of metamaterials with on‐demand functional behaviors. RIGID leverages the interpretability of a random forest‐based “design → response” forward model, eliminating the need for a more complex “response → design” inverse model. Based on the likelihood of target satisfaction derived from the trained random forest, one can sample a desired number of design solutions using Markov chain Monte Carlo methods. RIGID is validated on acoustic and optical metamaterial design problems, each with fewer than 250 training samples. Compared to the genetic algorithm‐based design generation approach, RIGID generates satisfactory solutions that cover a broader range of the design space, allowing for better consideration of additional figures of merit beyond target satisfaction. This work offers a new perspective on solving on‐demand inverse design problems, showcasing the potential for incorporating interpretable machine learning into generative design under small data constraints.

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Generative Inverse Design of Metamaterials with Functional Responses by Interpretable Learning

Chen,

Sun,

Lee

et al. 2024

Advanced Intelligent Systems

View full text Add to dashboard Cite

show abstract

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Dynamic multifunctional metasurfaces: an inverse design deep learning approach

Cited by 1 publication

References 75 publications

Generative Inverse Design of Metamaterials with Functional Responses by Interpretable Learning

Generative Inverse Design of Metamaterials with Functional Responses by Interpretable Learning

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