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Displacement-agnostic coherent imaging through scatter with an interpretable deep neural network

Yunzhe Li, Shiyi Cheng, Yujia Xue, Lei Tian

2020Optics Express45 citationsDOIOpen Access PDF

Abstract

Coherent imaging through scatter is a challenging task. Both model-based and data-driven approaches have been explored to solve the inverse scattering problem. In our previous work, we have shown that a deep learning approach can make high-quality and highly generalizable predictions through unseen diffusers. Here, we propose a new deep neural network model that is agnostic to a broader class of perturbations including scatterer change, displacements, and system defocus up to 10× depth of field. In addition, we develop a new analysis framework for interpreting the mechanism of our deep learning model and visualizing its generalizability based on an unsupervised dimension reduction technique. We show that our model can unmix the scattering-specific information and extract the object-specific information and achieve generalization under different scattering conditions. Our work paves the way to a robust and interpretable deep learning approach to imaging through scattering media.

Topics & Concepts

Artificial intelligenceDeep learningComputer scienceGeneralizationGeneralizability theoryArtificial neural networkInverse problemScatteringPattern recognition (psychology)Dimension (graph theory)Dimensionality reductionDeep neural networksInverse scattering problemFeature (linguistics)OpticsReduction (mathematics)Forward scatterUnsupervised learningComputer visionSupervised learningImage processingFeature learningFeature extractionRandom lasers and scattering mediaMicrowave Imaging and Scattering AnalysisMetamaterials and Metasurfaces Applications