Fourier-transform-only method for random phase shifting interferometry

IF 2 4区物理与天体物理 Q3 OPTICS

Journal of Optics Pub Date : 2024-02-08 DOI:10.1088/2040-8986/ad237c

Alperen Saltik, Sueda Saylan, Onur Tokel

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引用次数: 0

Abstract

An accurate and computationally simple phase shifting interferometry (PSI) method is developed to reconstruct phase maps without a priori knowledge of the phase shift. Previous methods developed for random PSI either do not address general sources of error or require complex iterative processes and increased computational time. Here we demonstrate a novel method that is able to extract the phase using only Fourier transform (FT). With spatial FT analysis, randomly phase-shifted data is reordered to allow performing temporal FT on the intensity, which is a function of the phase shift. Since the entire process, including order analysis and phase calculation, is based only on Fourier analysis, it is rapid, easy to implement, and addresses general sources of error. The method exhibits high performance in experiments containing random phase shifts. Moreover, simulations incorporating common experimental error sources such as random intensity noise, intensity harmonics, and phase shift errors demonstrate that the proposed method performs as good as or better than the state-of-the-art phase reconstruction techniques in terms of accuracy and time.

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随机移相干涉测量的纯傅里叶变换方法

我们开发了一种精确且计算简单的移相干涉测量（PSI）方法，可在不预先知道相移的情况下重建相位图。以前开发的随机 PSI 方法要么没有解决一般的误差来源，要么需要复杂的迭代过程和更长的计算时间。在这里，我们展示了一种仅使用傅立叶变换（FT）就能提取相位的新方法。通过空间傅立叶变换分析，对随机相移数据进行重新排序，以便对强度执行时间傅立叶变换，强度是相移的函数。由于包括阶次分析和相位计算在内的整个过程都只基于傅立叶分析，因此该方法快速、易于实施，并能解决一般的误差来源。该方法在包含随机相移的实验中表现出很高的性能。此外，包含随机强度噪声、强度谐波和相移误差等常见实验误差源的模拟结果表明，所提出的方法在精度和时间方面与最先进的相位重建技术不相上下，甚至更好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Optics OPTICS-

CiteScore

4.50

自引率

4.80%

发文量

237

审稿时长

1.9 months

期刊介绍： Journal of Optics publishes new experimental and theoretical research across all areas of pure and applied optics, both modern and classical. Research areas are categorised as: Nanophotonics and plasmonics Metamaterials and structured photonic materials Quantum photonics Biophotonics Light-matter interactions Nonlinear and ultrafast optics Propagation, diffraction and scattering Optical communication Integrated optics Photovoltaics and energy harvesting We discourage incremental advances, purely numerical simulations without any validation, or research without a strong optics advance, e.g. computer algorithms applied to optical and imaging processes, equipment designs or material fabrication.