Inverse design of plasmonic metasurfaces by convolutional neural network

Ronghui  Lin; Yanfen Zhai; Chenxin Xiong; Xiaohang Li

doi:https://doi.org/10.1364/OL.387404

Inverse design of plasmonic metasurfaces by convolutional neural network

Ronghui Lin, Yanfen Zhai, Chenxin Xiong, Xiaohang Li

Research output: Contribution to journal › Article › peer-review

Abstract

Artificial neural networks have shown effectiveness in the inverse design of nanophotonic structures; however, the numerical accuracy and algorithm efficiency are not analyzed adequately in previous reports. In this Letter, we demonstrate the convolutional neural network as an inverse design tool to achieve high numerical accuracy in plasmonic metasurfaces. A comparison of the convolutional neural networks and the fully connected neural networks show that convolutional neural networks have higher generalization capabilities. We share practical guidelines for optimizing the neural network and analyzed the hierarchy of accuracy in the multi-parameter inverse design of plasmonic metasurfaces. A high inverse design accuracy of ±8nm for the critical geometrical parameters is demonstrated.

Original language	English
Pages (from-to)	1362
Number of pages	1365
Journal	OPTICS LETTERS
DOIs	https://doi.org/10.1364/OL.387404
Publication status	Published - 15 Mar 2020
Externally published	Yes

Keywords

Absorption spectroscopy
Fano resonance
Inverse problems
Neural networks
Surface plasmons
Systems design

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title = "Inverse design of plasmonic metasurfaces by convolutional neural network",

abstract = "Artificial neural networks have shown effectiveness in the inverse design of nanophotonic structures; however, the numerical accuracy and algorithm efficiency are not analyzed adequately in previous reports. In this Letter, we demonstrate the convolutional neural network as an inverse design tool to achieve high numerical accuracy in plasmonic metasurfaces. A comparison of the convolutional neural networks and the fully connected neural networks show that convolutional neural networks have higher generalization capabilities. We share practical guidelines for optimizing the neural network and analyzed the hierarchy of accuracy in the multi-parameter inverse design of plasmonic metasurfaces. A high inverse design accuracy of ±8nm for the critical geometrical parameters is demonstrated.",

keywords = "Absorption spectroscopy, Fano resonance, Inverse problems, Neural networks, Surface plasmons, Systems design",

author = "Ronghui Lin and Yanfen Zhai and Chenxin Xiong and Xiaohang Li",

year = "2020",

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doi = "https://doi.org/10.1364/OL.387404",

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AU - Lin, Ronghui

AU - Zhai, Yanfen

AU - Xiong, Chenxin

AU - Li, Xiaohang

PY - 2020/3/15

Y1 - 2020/3/15

N2 - Artificial neural networks have shown effectiveness in the inverse design of nanophotonic structures; however, the numerical accuracy and algorithm efficiency are not analyzed adequately in previous reports. In this Letter, we demonstrate the convolutional neural network as an inverse design tool to achieve high numerical accuracy in plasmonic metasurfaces. A comparison of the convolutional neural networks and the fully connected neural networks show that convolutional neural networks have higher generalization capabilities. We share practical guidelines for optimizing the neural network and analyzed the hierarchy of accuracy in the multi-parameter inverse design of plasmonic metasurfaces. A high inverse design accuracy of ±8nm for the critical geometrical parameters is demonstrated.

AB - Artificial neural networks have shown effectiveness in the inverse design of nanophotonic structures; however, the numerical accuracy and algorithm efficiency are not analyzed adequately in previous reports. In this Letter, we demonstrate the convolutional neural network as an inverse design tool to achieve high numerical accuracy in plasmonic metasurfaces. A comparison of the convolutional neural networks and the fully connected neural networks show that convolutional neural networks have higher generalization capabilities. We share practical guidelines for optimizing the neural network and analyzed the hierarchy of accuracy in the multi-parameter inverse design of plasmonic metasurfaces. A high inverse design accuracy of ±8nm for the critical geometrical parameters is demonstrated.

KW - Absorption spectroscopy

KW - Fano resonance

KW - Inverse problems

KW - Neural networks

KW - Surface plasmons

KW - Systems design

U2 - https://doi.org/10.1364/OL.387404

DO - https://doi.org/10.1364/OL.387404

M3 - Article

SP - 1362

JO - OPTICS LETTERS

JF - OPTICS LETTERS

ER -

Inverse design of plasmonic metasurfaces by convolutional neural network

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