Random two-frame interferometry based on deep learning

Ziqiang Li; Xinyang Li; Rongguang Liang

doi:10.1364/OE.397904

Random two-frame interferometry based on deep learning

Ziqiang Li, Xinyang Li, Rongguang Liang

Optical Sciences

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

14 Scopus citations

Abstract

A two-frame phase-shifting interferometric wavefront reconstruction method based on deep learning is proposed. By learning from a large number of simulation data based on a physical model, the wrapped phase can be calculated accurately from two interferograms with an unknown phase step. The phase step can be any value excluding the integral multiples of π and the size of interferograms can be flexible. This method does not need a pre-filtering to subtract the direct-current term, but only needs a simple normalization. Comparing with other two-frame methods in both simulations and experiments, the proposed method can achieve better performance.

Original language	English (US)
Pages (from-to)	24747-24760
Number of pages	14
Journal	Optics Express
Volume	28
Issue number	17
DOIs	https://doi.org/10.1364/OE.397904
State	Published - Aug 17 2020

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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title = "Random two-frame interferometry based on deep learning",

abstract = "A two-frame phase-shifting interferometric wavefront reconstruction method based on deep learning is proposed. By learning from a large number of simulation data based on a physical model, the wrapped phase can be calculated accurately from two interferograms with an unknown phase step. The phase step can be any value excluding the integral multiples of π and the size of interferograms can be flexible. This method does not need a pre-filtering to subtract the direct-current term, but only needs a simple normalization. Comparing with other two-frame methods in both simulations and experiments, the proposed method can achieve better performance.",

author = "Ziqiang Li and Xinyang Li and Rongguang Liang",

note = "Publisher Copyright: {\textcopyright} 2020 Optical Society of America under the terms of the OSA Open Access Publishing Agreement",

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N2 - A two-frame phase-shifting interferometric wavefront reconstruction method based on deep learning is proposed. By learning from a large number of simulation data based on a physical model, the wrapped phase can be calculated accurately from two interferograms with an unknown phase step. The phase step can be any value excluding the integral multiples of π and the size of interferograms can be flexible. This method does not need a pre-filtering to subtract the direct-current term, but only needs a simple normalization. Comparing with other two-frame methods in both simulations and experiments, the proposed method can achieve better performance.

AB - A two-frame phase-shifting interferometric wavefront reconstruction method based on deep learning is proposed. By learning from a large number of simulation data based on a physical model, the wrapped phase can be calculated accurately from two interferograms with an unknown phase step. The phase step can be any value excluding the integral multiples of π and the size of interferograms can be flexible. This method does not need a pre-filtering to subtract the direct-current term, but only needs a simple normalization. Comparing with other two-frame methods in both simulations and experiments, the proposed method can achieve better performance.

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Random two-frame interferometry based on deep learning

Abstract

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