Convolutional neural network for estimating physical parameters from Newton’s rings

Peihang Li; Ming Feng Lu; Chen Chen Ji; Jin Min Wu; Zhe Liu; Chenyang Wang; Feng Zhang; Ran Tao

doi:10.1364/AO.422012

Convolutional neural network for estimating physical parameters from Newton’s rings

Peihang Li, Ming Feng Lu^*, Chen Chen Ji, Jin Min Wu, Zhe Liu, Chenyang Wang, Feng Zhang, Ran Tao

^*Corresponding author for this work

School of Information and Electronics

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

4 Citations (Scopus)

Abstract

By analyzing Newton’s rings, often encountered in interferometry, the parameters of spherical surfaces such as the rings’ center and the curvature radius can be estimated. First, the classical convolutional neural networks, visual geometry group (VGG) network and U-Net, are applied to parameter estimation of Newton’s rings. After these models are trained, the rings’ center and curvature radius can be obtained simultaneously. Compared with previous analysis methods of Newton’s rings, it is shown that the proposed method has higher precision, better immunity to noise, and lower time consumption. For a Newton’s rings pattern of 640 × 480 pixels comprising −5 dB Gaussian noise or 60% salt-and-pepper noise, the parameters can be estimated by the VGG model in 0.01 s, the error of the rings’ center is less than one pixel, and the error of curvature radius is lower than 0.5%.

Original language	English
Pages (from-to)	3964-3970
Number of pages	7
Journal	Applied Optics
Volume	60
Issue number	13
DOIs	https://doi.org/10.1364/AO.422012
Publication status	Published - 1 May 2021

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title = "Convolutional neural network for estimating physical parameters from Newton{\textquoteright}s rings",

abstract = "By analyzing Newton{\textquoteright}s rings, often encountered in interferometry, the parameters of spherical surfaces such as the rings{\textquoteright} center and the curvature radius can be estimated. First, the classical convolutional neural networks, visual geometry group (VGG) network and U-Net, are applied to parameter estimation of Newton{\textquoteright}s rings. After these models are trained, the rings{\textquoteright} center and curvature radius can be obtained simultaneously. Compared with previous analysis methods of Newton{\textquoteright}s rings, it is shown that the proposed method has higher precision, better immunity to noise, and lower time consumption. For a Newton{\textquoteright}s rings pattern of 640 × 480 pixels comprising −5 dB Gaussian noise or 60% salt-and-pepper noise, the parameters can be estimated by the VGG model in 0.01 s, the error of the rings{\textquoteright} center is less than one pixel, and the error of curvature radius is lower than 0.5%.",

author = "Peihang Li and Lu, {Ming Feng} and Ji, {Chen Chen} and Wu, {Jin Min} and Zhe Liu and Chenyang Wang and Feng Zhang and Ran Tao",

note = "Publisher Copyright: {\textcopyright} 2021 Optical Society of America.",

year = "2021",

month = may,

day = "1",

doi = "10.1364/AO.422012",

language = "English",

volume = "60",

pages = "3964--3970",

journal = "Applied Optics",

issn = "1559-128X",

publisher = "Optica Publishing Group",

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TY - JOUR

T1 - Convolutional neural network for estimating physical parameters from Newton’s rings

AU - Li, Peihang

AU - Lu, Ming Feng

AU - Ji, Chen Chen

AU - Wu, Jin Min

AU - Liu, Zhe

AU - Wang, Chenyang

AU - Zhang, Feng

AU - Tao, Ran

PY - 2021/5/1

Y1 - 2021/5/1

N2 - By analyzing Newton’s rings, often encountered in interferometry, the parameters of spherical surfaces such as the rings’ center and the curvature radius can be estimated. First, the classical convolutional neural networks, visual geometry group (VGG) network and U-Net, are applied to parameter estimation of Newton’s rings. After these models are trained, the rings’ center and curvature radius can be obtained simultaneously. Compared with previous analysis methods of Newton’s rings, it is shown that the proposed method has higher precision, better immunity to noise, and lower time consumption. For a Newton’s rings pattern of 640 × 480 pixels comprising −5 dB Gaussian noise or 60% salt-and-pepper noise, the parameters can be estimated by the VGG model in 0.01 s, the error of the rings’ center is less than one pixel, and the error of curvature radius is lower than 0.5%.

AB - By analyzing Newton’s rings, often encountered in interferometry, the parameters of spherical surfaces such as the rings’ center and the curvature radius can be estimated. First, the classical convolutional neural networks, visual geometry group (VGG) network and U-Net, are applied to parameter estimation of Newton’s rings. After these models are trained, the rings’ center and curvature radius can be obtained simultaneously. Compared with previous analysis methods of Newton’s rings, it is shown that the proposed method has higher precision, better immunity to noise, and lower time consumption. For a Newton’s rings pattern of 640 × 480 pixels comprising −5 dB Gaussian noise or 60% salt-and-pepper noise, the parameters can be estimated by the VGG model in 0.01 s, the error of the rings’ center is less than one pixel, and the error of curvature radius is lower than 0.5%.

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Convolutional neural network for estimating physical parameters from Newton’s rings

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