Two-frame advanced iterative self-tuning algorithm for accurate phase retrieval

Two-frame advanced iterative self-tuning algorithm for accurate phase retrieval

•An approach that leverages the iterative method to cope with spatially varying background intensity and modulation amplitude.•The two-frame advanced iterative self-tuning algorithm, uses the spatial mean algorithm paired with an iterative procedure to search the phase step from two captured fringe...

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Bibliographic Details
Published in:Optics and lasers in engineering Vol. 169; p. 107715
Main Authors: He, Zhouxuan, Du, Hubing, Gu, Feifei, Hu, Bingqing, Wang, Feng, Zhao, Zixin, Zhang, Gaopeng
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-10-2023
Subjects:
Fringe analysis
Interferometry
Phase retrieval
Phase shift
Phase shift
Phase retrieval
120.2650
050.5080
Fringe analysis
120.3180
Interferometry
100.5070
Online Access:Get full text
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Summary:•An approach that leverages the iterative method to cope with spatially varying background intensity and modulation amplitude.•The two-frame advanced iterative self-tuning algorithm, uses the spatial mean algorithm paired with an iterative procedure to search the phase step from two captured fringe patterns.•It represents a novel approach to reliable and practical without pre-filtering due to the cancelation of simultaneously obtaining the phase shifts and measured phase through iterative operation in the spatial–temporal domain. Two-shot random phase-shifting interferometry has been actively investigated and improved owing to more demanding requirements in investigating dynamic phenomena or sensing some transient events. Given the background intensity and phase step knowledge, a reconstruction algorithm can be used to recover a complex-valued signal from intensity-only measurements. Most algorithms assume the background intensity and modulation amplitude in a frame of interferogram are constant variables; however, in realistic systems, they vary laterally and axially across the field of view. The model can be used but often appears less precise. In this work, we propose an approach that leverages the iterative method to cope with spatially varying background intensity and modulation amplitude. Our approach, termed the two-frame advanced iterative self-tuning algorithm, uses the spatial mean algorithm paired with an iterative procedure to search the phase step from two captured fringe patterns. It represents a novel approach to reliable and practical two-step phase-shifting interferometry without pre-filtering due to the cancelation of simultaneously obtaining the phase shifts and measured phase through iterative operation in the spatial–temporal domain. Experimental results obtained using the proposed method indicate that it is a simple and robust solution for phase extraction from a two-frame unknown phase shift fringe pattern with spatially varying background intensity and modulation amplitude.
ISSN:0143-8166
1873-0302
DOI:10.1016/j.optlaseng.2023.107715