26 June 2017 Computational wavelength resolution for in-line lensless holography: phase-coded diffraction patterns and wavefront group-sparsity
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Proceedings Volume 10335, Digital Optical Technologies 2017; 1033509 (2017) https://doi.org/10.1117/12.2269327
Event: SPIE Digital Optical Technologies, 2017, Munich, Germany
Abstract
In-line lensless holography is considered with a random phase modulation at the object plane. The forward wavefront propagation is modelled using the Fourier transform with the angular spectrum transfer function. The multiple intensities (holograms) recorded by the sensor are random due to the random phase modulation and noisy with Poissonian noise distribution. It is shown by computational experiments that high-accuracy reconstructions can be achieved with resolution going up to the two thirds of the wavelength. With respect to the sensor pixel size it is a super-resolution with a factor of 32. The algorithm designed for optimal superresolution phase/amplitude reconstruction from Poissonian data is based on the general methodology developed for phase retrieval with a pixel-wise resolution in V. Katkovnik, ”Phase retrieval from noisy data based on sparse approximation of object phase and amplitude”, http://www.cs.tut.fi/~lasip/DDT/index3.html.
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Vladimir Katkovnik, Vladimir Katkovnik, Igor Shevkunov, Igor Shevkunov, Nikolay V. Petrov, Nikolay V. Petrov, Karen Egiazarian, Karen Egiazarian, } "Computational wavelength resolution for in-line lensless holography: phase-coded diffraction patterns and wavefront group-sparsity", Proc. SPIE 10335, Digital Optical Technologies 2017, 1033509 (26 June 2017); doi: 10.1117/12.2269327; https://doi.org/10.1117/12.2269327
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