Rapid deep-learning-assisted design method for 2-bit coding metasurfaces

Jiahui Fu; Yuping Zhang; Zhongxin Dou; Zhihu Yang; Meng Liu; Huiyun Zhang

doi:10.1364/AO.487867

Applied Optics
Vol. 62,
Issue 13,
pp. 3502-3511
(2023)
•https://doi.org/10.1364/AO.487867

Rapid deep-learning-assisted design method for 2-bit coding metasurfaces

Jiahui Fu, Yuping Zhang, Zhongxin Dou, Zhihu Yang, Meng Liu, and Huiyun Zhang

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Jiahui Fu, Yuping Zhang, Zhongxin Dou, Zhihu Yang, Meng Liu, and Huiyun Zhang, "Rapid deep-learning-assisted design method for 2-bit coding metasurfaces," Appl. Opt. 62, 3502-3511 (2023)

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Abstract

This paper proposes a deep-learning-assisted design method for 2-bit coding metasurfaces. This method uses a skip connection module and the idea of an attention mechanism in squeeze-and-excitation networks based on a fully connected network and a convolutional neural network. The accuracy limit of the basic model is further improved. The convergence ability of the model increased nearly 10 times, and the mean-square error loss function converges to 0.000168. The forward prediction accuracy of the deep-learning-assisted model is 98%, and the accuracy of inverse design results is 97%. This approach offers the advantages of an automatic design process, high efficiency, and low computational cost. It can serve users who lack metasurface design experience.

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Data availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Unit Cell	00	01	10	11
l (µm)	7	8	9	9
$d$ (µm)	3	2	1	5
Phase	$π$	$π / 2$	0	$- π / 2$

Model Structure	MSE
Baseline	0.001463
$B a s e l i n e + s k i p$ connection	0.001454
$B a s e l i n e + s k i p$ $c o n n e c t i o n + S E N e t$	0.000168

Model Structure	MSE
FC	0.000195
$C N N + F C$	0.000168

Unit Cell	00	01	10	11
l (µm)	7	8	9	9
$d$ (µm)	3	2	1	5
Phase	$π$	$π / 2$	0	$- π / 2$

Model Structure	MSE
Baseline	0.001463
$B a s e l i n e + s k i p$ connection	0.001454
$B a s e l i n e + s k i p$ $c o n n e c t i o n + S E N e t$	0.000168

Abstract

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Tables (3)

Equations (5)

Applied Optics