Scalable precision wide-field imaging in radio interferometry: I. uSARA validated on ASKAP data

TL;DR

This paper introduces uSARA, a new imaging algorithm for radio interferometry, demonstrating its ability to produce high-resolution, high-dynamic range images from ASKAP data that outperform traditional methods like WSClean.

Contribution

The paper presents the uSARA optimization algorithm and validates its effectiveness on ASKAP data, achieving superior resolution and sensitivity compared to existing imaging techniques.

Findings

uSARA produces images with super-resolution and enhanced diffuse emission sensitivity.

uSARA images reveal previously unseen structures in complex radio sources.

Validation shows uSARA images have better morphology, flux, and spectral index accuracy.

Abstract

As Part I of a paper series showcasing a new imaging framework, we consider the recently proposed unconstrained Sparsity Averaging Reweighted Analysis (uSARA) optimisation algorithm for wide-field, high-resolution, high-dynamic range, monochromatic intensity imaging. We reconstruct images from real radio-interferometric observations obtained with the Australian Square Kilometre Array Pathfinder (ASKAP) and present these results in comparison to the widely-used, state-of-the-art imager WSClean. Selected fields come from the ASKAP Early Science and Evolutionary Map of the Universe (EMU) Pilot surveys and contain several complex radio sources: the merging cluster system Abell 3391-95, the merging cluster SPT-CL 2023-5535, and many extended, or bent-tail, radio galaxies, including the X-shaped radio galaxy PKS 2014-558 and the ``dancing ghosts'', known collectively as PKS 2130-538. The modern framework behind uSARA utilises parallelisation and automation to solve for the w-effect and efficiently compute the measurement operator, allowing for wide-field reconstruction over the full field-of-view of individual ASKAP beams (up to 3.3 deg each). The precision capability of uSARA produces images with both super-resolution and enhanced sensitivity to diffuse components, surpassing traditional CLEAN algorithms which typically require a compromise between such yields. Our resulting monochromatic uSARA-ASKAP images of the selected data highlight both extended, diffuse emission and compact, filamentary emission at very high resolution (up to 2.2 arcsec), revealing never-before-seen structure. Here we present a validation of our uSARA-ASKAP images by comparing the morphology of reconstructed sources, measurements of diffuse flux, and spectral index maps with those obtained from images made with WSClean.