Non-invasive single-shot recovery of a point-spread function of a memory effect based scattering imaging system

Accessing the point-spread function (PSF) of a complex optical system is important for a variety of imaging applications. However, placing an invasive point source is often impractical, and estimating it blindly with multiple frames is slow and requires a complex nonlinear optimization. Here, we int...

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Veröffentlicht in:	Optics letters 2020-10, Vol.45 (19), p.5397-5400
Hauptverfasser:	Wu, Tengfei, Dong, Jonathan, Gigan, Sylvain
Format:	Artikel
Sprache:	eng
Schlagworte:	Deconvolution Image reconstruction Imaging techniques Light scattering Optimization Point sources Point spread functions Speckle patterns
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creator	Wu, Tengfei Dong, Jonathan Gigan, Sylvain
description	Accessing the point-spread function (PSF) of a complex optical system is important for a variety of imaging applications. However, placing an invasive point source is often impractical, and estimating it blindly with multiple frames is slow and requires a complex nonlinear optimization. Here, we introduce a simple single-shot method to noninvasively recover the accurate PSF of an isoplanatic imaging system, in the context of multiple light scattering. Our approach is based on the reconstruction of any unknown sparse hidden object using the autocorrelation imaging technique, followed by a deconvolution with a blur kernel derived from the statistics of a speckle pattern. A deconvolution on the camera image then retrieves the accurate PSF of the system, enabling further imaging applications. We demonstrate numerically and experimentally the effectiveness of this approach compared to previous deconvolution techniques.
doi_str_mv	10.1364/OL.400869
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source	OSA_美国光学学会数据库1
subjects	Deconvolution Image reconstruction Imaging techniques Light scattering Optimization Point sources Point spread functions Speckle patterns
title	Non-invasive single-shot recovery of a point-spread function of a memory effect based scattering imaging system
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