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Abstract
We propose a reconstruction method for coherence holography using deep neural networks. cGAN and U-NET models were developed to reconstruct 3D complex objects from recorded interferograms. Our proposed methods, dubbed deep coherence holography (DCH), predict the non-diffracted fields or the sub-objects included in the 3D object from the captured interferograms, yielding better reconstructed objects than the traditional analytical imaging methods in terms of accuracy, resolution, and time. The DCH needs one image per sub-object as opposed to $N$ images for the traditional sin-fit algorithm, and hence the total reconstruction time is reduced by $N \times$. Furthermore, with noisy interferograms the DCH amplitude mean square reconstruction error (MSE) is $5 \times 10^4 \times $ and $10^4 \times$ and phase MSE is ${10}^{2}\times$ and $3 \times 10^3 \times$ better than Fourier fringe and sin-fit algorithms, respectively. The amplitude peak signal to noise ratio (PSNR) is $3 \times$ and $2 \times$ and phase PSNR is $5 \times$ and $3 \times$ better than Fourier fringe and sin-fit algorithms, respectively. The reconstruction resolution is the same as sin-fit but $2 \times$ better than the Fourier fringe analysis technique.
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