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DECONVOLUTION OF INTERFEROMETRIC DATA USING INTERIOR POINT ITERATIVE ALGORITHMS.

Authors :
Theys, C.
Lantéri, H.
Aime, C.
Source :
EAS Publications Series. 2016, Vol. 78/79, p211-231. 21p.
Publication Year :
2016

Abstract

We address the problem of deconvolution of astronomical images that could be obtained with future large interferometers in space. The presentation is made in two complementary parts. The first part gives an introduction to the image deconvolution with linear and nonlinear algorithms. The emphasis is made on nonlinear iterative algorithms that verify the constraints of non-negativity and constant flux. The Richardson-Lucy algorithm appears there as a special case for photon counting conditions. More generally, the algorithm published recently by Lanteri et al. (2015) is based on scale invariant divergences without assumption on the statistic model of the data. The two proposed algorithms are interior-point algorithms, the latter being more efficient in terms of speed of calculation. These algorithms are applied to the deconvolution of simulated images corresponding to an interferometric system of 16 diluted telescopes in space. Two non-redundant configurations, one disposed around a circle and the other on an hexagonal lattice, are compared for their effectiveness on a simple astronomical object. The comparison is made in the direct and Fourier spaces. Raw "dirty" images have many artifacts due to replicas of the original object. Linear methods cannot remove these replicas while iterative methods clearly show their efficacy in these examples. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
16334760
Volume :
78/79
Database :
Academic Search Index
Journal :
EAS Publications Series
Publication Type :
Academic Journal
Accession number :
117872197
Full Text :
https://doi.org/10.1051/eas/1678010