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    Area of Science:

    • Optics and Photonics
    • Image Processing
    • Computational Science

    Background:

    • Fringe patterns are crucial in optical metrology for measuring surface topography and deformations.
    • Accurate computation of phase maps from fringe patterns is essential for quantitative analysis.
    • Existing methods may struggle with discontinuities or noise in fringe data.

    Purpose of the Study:

    • To develop a robust computational method for deriving discontinuous phase maps from fringe patterns.
    • To leverage total variation regularization for improved phase map reconstruction.
    • To validate the proposed method using both synthetic and real-world fringe data.

    Main Methods:

    • A novel approach based on minimizing a total variation regularization cost function is proposed.
    • The method formulates phase map computation as an optimization problem.
    • Numerical simulations and experiments with real fringe data were conducted for performance evaluation.

    Main Results:

    • The proposed method successfully computes discontinuous phase maps from fringe patterns.
    • Numerical experiments demonstrated the effectiveness and accuracy of the technique.
    • The method showed reliable performance on both synthetic and real experimental data.

    Conclusions:

    • Minimizing total variation regularization provides an effective strategy for discontinuous phase map computation.
    • The developed method offers a reliable tool for fringe pattern analysis in various applications.
    • This approach enhances the accuracy and robustness of phase retrieval from optical measurements.