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Lena Gorelick, Olga Veksler, Yuri Boykov

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    Summary
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    We introduce shape convexity as a novel regularization for image segmentation. This method efficiently optimizes non-submodular potentials, offering robust segmentation without shrinking bias.

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    Area of Science:

    • Computer Vision
    • Image Processing
    • Computational Geometry

    Background:

    • Convexity is a significant feature in human visual perception.
    • Image segmentation algorithms often benefit from incorporating shape priors.
    • Existing regularization methods may introduce biases like shrinking.

    Purpose of the Study:

    • To propose shape convexity as a novel high-order regularization constraint for binary image segmentation.
    • To develop an efficient optimization method for convexity-based potentials in discrete settings.
    • To evaluate the performance and advantages of the convexity prior against traditional methods.

    Main Methods:

    • Representing object convexity as sum of three-clique potentials in discrete optimization.
    • Employing an iterative trust region approach for optimizing non-submodular potentials.
    • Utilizing dynamic programming for efficient evaluation and approximation of cliques.
    • Developing a second-order approximation model for enhanced accuracy.

    Main Results:

    • The proposed method efficiently optimizes non-submodular potentials using an iterative trust region approach.
    • Dynamic programming enables linear-time evaluation and approximation of three-cliques.
    • Experiments show the convexity prior's general usefulness on synthetic and real image data.
    • The convexity prior demonstrates robustness to scale changes and parameter selection, avoiding shrinking bias.

    Conclusions:

    • Shape convexity is an effective high-order regularization for binary image segmentation.
    • The developed optimization technique efficiently handles non-submodular potentials.
    • The convexity prior offers advantages over standard length regularization, including no shrinking bias and scale robustness.