Sparse representations and convex optimization as tools for LOFAR radio interferometric imaging
Abstract
Compressed sensing theory is slowly making its way to solve more and more astronomical inverse problems. We address here the application of sparse representations, convex optimization and proximal theory to radio interferometric imaging. First, we expose the theory behind interferometric imaging, sparse representations and convex optimization, and second, we illustrate their application with numerical tests with SASIR, an implementation of the FISTA, a Forward-Backward splitting algorithm hosted in a LOFAR imager. Various tests have been conducted in Garsden et al., 2015. The main results are: i) an improved angular resolution (super resolution of a factor ~2) with point sources as compared to CLEAN on the same data, ii) correct photometry measurements on a field of point sources at high dynamic range and iii) the imaging of extended sources with improved fidelity. SASIR provides better reconstructions (five time less residuals) of the extended emission as compared to CLEAN. With the advent of large radiotelescopes, there is scope for improving classical imaging methods with convex optimization methods combined with sparse representations.
Cite
@article{arxiv.1504.03896,
title = {Sparse representations and convex optimization as tools for LOFAR radio interferometric imaging},
author = {Julien N. Girard and Hugh Garsden and Jean Luc Starck and Stéphane Corbel and Arnaud Woiselle and Cyril Tasse and John P. McKean and Jérôme Bobin},
journal= {arXiv preprint arXiv:1504.03896},
year = {2015}
}
Comments
18 pages, 3 figures, INFIERI 2014 Published