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Extrapolated speckle-correlation imaging with an untrained deep neural network.

Ryosuke Mashiko, Jun Tanida, Makoto Naruse

    Applied Optics
    |December 1, 2023
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    Summary
    This summary is machine-generated.

    We developed a novel deep image prior method to improve speckle-correlation imaging for non-sparse objects. This technique enhances the field of view for observing objects through scattering media.

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    Area of Science:

    • Optics and Photonics
    • Computational Imaging
    • Machine Learning for Imaging

    Background:

    • Speckle-correlation imaging recovers objects through scattering media using the memory effect.
    • Current methods are limited by the memory effect's field of view and often assume sparse objects due to ill-posedness.
    • Extending the field of view typically involves extrapolating speckle correlation during reconstruction.

    Purpose of the Study:

    • To overcome the limitations of conventional speckle-correlation imaging for non-sparse objects.
    • To extend the field of view in speckle-correlation imaging beyond the memory effect limit.
    • To introduce a regularization method that addresses the ill-posed nature of imaging non-sparse objects.

    Main Methods:

    • Implemented a deep image prior, utilizing an untrained convolutional neural network, to regularize image statistics.
    • Integrated the deep image prior into the speckle-correlation imaging reconstruction process.
    • Experimentally validated the proposed method for imaging through scattering media.

    Main Results:

    • Successfully demonstrated speckle-correlation imaging of spatially non-sparse objects.
    • Showcased the ability to extend the field of view beyond the inherent memory effect limitations.
    • Validated the efficacy of the deep image prior in improving image reconstruction quality.

    Conclusions:

    • The proposed deep image prior method significantly enhances speckle-correlation imaging capabilities.
    • This advancement allows for the observation of complex, non-sparse objects through scattering media.
    • The method shows promise for broader applications in imaging through scattering environments.