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Computer-generated holography (CGH) has enabled the formation of arbitrary images through complex spatial light modulation. The optimization of spatial light modulators (SLMs) and diffractive optical elements (DOEs) is aimed to solve the well-known phase retrieval problem. This paper proposes a physically constrained artificial neural network (ANN) designed to solve the phase retrieval problem for CGH. We show that through careful selection of model structural parameters and by limiting the scope of model optimization, we can encode Fresnel Diffraction equations directly into an ANN. We train the proposed model to overfit to a single image, i.e., the model finds the SLM phase delays required to produce the desired image. The proposed model performs well with outputs that qualitatively compare well with ideal images. The method proposed in this work holds value for those who require confidence that their machine learning techniques are physically realizable.
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Marshall Lindsay, Scott D. Kovaleski, Charlie Veal, Derek T. Anderson, Stanton R. Price, "Machine learning assisted holography," Proc. SPIE 11731, Computational Imaging VI, 1173103 (12 April 2021); https://doi.org/10.1117/12.2585836