Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning

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Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning

Mao Simei et al · Wiley · 2022

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Autor / responsable

Mao Simei et al

Editorial

Wiley

Año

2022

ISSN

2192-8614

ISSN

2192-8614

Idioma

eng

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Silicon photonics enables compact integrated photonic devices with versatile functionalities and mass manufacturing capability. However, the optimization of high-performance free-form optical devices is still challenging due to the complex light-matter interaction involved that requires time-consuming electromagnetic simulations. This problem becomes even more prominent when multiple devices are required, typically requiring separate iterative optimizations. To facilitate multi-task inverse design, we propose a topology optimization method based on deep neural network (DNN) in low-dimensional Fourier domain. The DNN takes target optical responses as inputs and predicts low-frequency Fourier components, which are then utilized to reconstruct device geometries. Removing high-frequency components for reduced design degree-of-freedom (DOF) helps control minimal features and speed up training. For demonstration, the proposed method is utilized for wavelength filter design. The trained DNN can design multiple filters instantly and concurrently with high accuracy. Totally different targets can also be further optimized through transfer learning on existing network with greatly reduced optimization rounds. Our approach can be also adapted to other free-form photonic devices, including a waveguide-coupled single-photon source that we demonstrate to prove generalizability. Such DNN-assisted topology optimization significantly reduces the time and resources required for multi-task optimization, enabling large-scale photonic device design in various applications.

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APA 7

al, M. S. E. (2022). Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning. https://doi.org/10.1515/nanoph-2022-0361

MLA

al, Mao Simei et. "Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning." 2022. https://doi.org/10.1515/nanoph-2022-0361.

Chicago

al, Mao Simei et. 2022. "Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning.". https://doi.org/10.1515/nanoph-2022-0361.

Harvard

al, M. S. E. 2022, Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning, Wiley, available at: https://doi.org/10.1515/nanoph-2022-0361 [Accessed 25 Jun. 2026].

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Título: Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning

Autor / colaboradores: Mao Simei et al

Editorial: Wiley

Año de publicación: 2022

ISSN: 2192-8614

ISSN: 2192-8614

Idioma: eng

Materias

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deep learning; inverse design; silicon photonics; topology optimization

Multi-task topology optimization of photonic devices in low-dimensional Fourier domain via deep learning

3-D near-field imaging of guided modes in nanophotonic waveguides

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