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Deep Neural Networks for Image-Based Dietary Assessment
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Unfolded Proximal Neural Networks for Robust Image Gaussian Denoising.

Hoang Trieu Vy Le, Audrey Repetti, Nelly Pustelnik

    IEEE Transactions on Image Processing : a Publication of the IEEE Signal Processing Society
    |August 7, 2024
    PubMed
    Summary
    This summary is machine-generated.

    This study introduces a unified framework for proximal neural networks (PNNs) for Gaussian denoising. Accelerated algorithms within this framework enable skip connections, enhancing robustness and denoising efficiency for inverse imaging problems.

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    Area of Science:

    • Computational imaging
    • Machine learning for image processing
    • Optimization theory

    Background:

    • Inverse imaging problems commonly use Maximum a Posteriori (MAP) estimation via minimization.
    • Iterative proximal algorithms are effective for non-smooth functions and linear operators in these tasks.
    • Deep learning integration, specifically proximal neural networks (PNNs), has improved estimate quality.

    Purpose of the Study:

    • To propose a unified framework for building PNNs tailored for Gaussian denoising.
    • To explore the benefits of accelerated inertial proximal algorithms for PNN architectures.
    • To evaluate the robustness and efficiency of the proposed PNN framework.

    Main Methods:

    • Unrolling proximal algorithms (dual-FB and primal-dual Chambolle-Pock) into fixed-iteration neural networks.
    • Implementing accelerated inertial versions to introduce skip connections in neural network layers.
    • Developing and applying various learning strategies to the PNN framework.
    • Assessing Lipschitz property for robustness and denoising performance.

    Main Results:

    • Demonstrated that accelerated inertial algorithms facilitate skip connections in PNN layers.
    • Investigated different learning strategies, showing their impact on robustness and denoising efficiency.
    • Validated the PNN framework's performance on Gaussian denoising tasks.
    • Assessed the robustness of the developed PNNs within a forward-backward algorithm for image deblurring.

    Conclusions:

    • The proposed unified framework effectively builds PNNs for Gaussian denoising using proximal algorithms.
    • Accelerated versions of these algorithms offer architectural advantages like skip connections.
    • The PNNs exhibit promising robustness and efficiency, adaptable to various image restoration and deblurring tasks.