用于超透镜设计的时域伴随优化，以提高宽带效率和均匀性。

Time-domain adjoint optimization for metalens design toward enhanced broadband efficiency and uniformity.

作者信息

Park Mingyu, Chung Haejun, Jung Kyung-Young

机构信息

Department of Electronic Engineering, Hanyang University, Seoul 04763, South Korea.

Department of Artificial Intelligence, Hanyang University, Seoul 04763, South Korea.

出版信息

iScience. 2025 Jun 25;28(7):112739. doi: 10.1016/j.isci.2025.112739. eCollection 2025 Jul 18.

DOI:10.1016/j.isci.2025.112739

PMID:40687828

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12274888/

Abstract

We propose a time-domain adjoint optimization method for achromatic metalens design, achieving high efficiency and near-uniform spectral response. Unlike frequency-domain approaches, which require simulations for each sampled frequency, our method evaluates the entire frequency band continuously with consistent simulation times. Dynamically adjusting design variables and incident pulses during iterations balances performance and spectral uniformity. For a numerical aperture (NA) of 0.99, absolute focusing efficiency improves by 20%-30% over frequency-domain designs, with average efficiency increasing from 27% to 45%. Computational efficiency is demonstrated with 4.98 s per iteration compared to 61.8 s for frequency-domain methods. Scalability analysis shows high versatility across NAs (0.8, 0.6, and 0.4) and lens sizes (6.75 μm-50 μm), maintaining 70%-80% focusing efficiency with linear simulation time growth. This methodological advancement in nanophotonics establishes an efficient framework for designing high-performance optical devices with broad applications in imaging, communications, diagnostics, and precision metrology.

摘要

我们提出了一种用于消色差超构透镜设计的时域伴随优化方法，可实现高效率和近乎均匀的光谱响应。与频域方法不同，频域方法需要对每个采样频率进行模拟，而我们的方法在一致的模拟时间内连续评估整个频带。在迭代过程中动态调整设计变量和入射脉冲可平衡性能和光谱均匀性。对于数值孔径（NA）为0.99的情况，与频域设计相比，绝对聚焦效率提高了20%-30%，平均效率从27%提高到45%。计算效率方面，每次迭代用时4.98秒，而频域方法为61.8秒。可扩展性分析表明，该方法在不同数值孔径（0.8、0.6和0.4）和透镜尺寸（6.75μm-50μm）下具有很高的通用性，随着模拟时间线性增长，聚焦效率保持在70%-80%。纳米光子学领域的这一方法进步为设计高性能光学器件建立了一个高效框架，在成像、通信、诊断和精密计量等领域具有广泛应用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/590f/12274888/c5021a42e57d/fx1.jpg

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用于超透镜设计的时域伴随优化，以提高宽带效率和均匀性。

Time-domain adjoint optimization for metalens design toward enhanced broadband efficiency and uniformity.

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