Higher Degree by Research Application Portal

TitleMachine Learning Methods for Imaging with Interferometres
SupervisorProf Andreas Wicenec
CourseDoctor of Philosophy
Research areaPhysical Sciences
Project description

Radio Interferometry is undergoing an epoch-defining expansion, with many next-generation instruments in final planning or under commissioning (e.g., SKA, ngVLA, ngEHT and their pathfinders). Nevertheless, with these great opportunities come some great challenges, and perhaps most pressingly, we must update our computational approaches to match the updated infrastructure.

Machine Learning approaches are ideal for addressing these ‘big data’ questions, with many new applications being discovered almost daily. The opportunities are practically infinite. One particularly promising approach is the use of Graphical Neural Networks (GNNs).

The traditional approach for imaging radio-interferometric data has been to convert the 3D temporally sampled data to a 2D regular grid, then Fourier transform and iteratively correct for the instrumental effects. However, this approach’s multitude of approximations limits its accuracy and scalability. GNNs provide a powerful alternative by directly operating on the irregular data domains sampled by the interferometer.

GNNs extend neural networks to process data represented as graphs, capturing node features and graph topology. For interferometers, the visibilities can be described as node features on a graph defined by the antenna locations and baseline connections. This provides a morphological match between the data domain and the machine learning framework, massively enhancing convergence compared to operating on gridded data.

We would apply GNN imaging to real data from the SKA pathfinders (MWA, ASKAP) and early science (or simulated) SKA datasets, testing the limits of current computation capabilities. We expect this to become a major focus for the SKA Data Processing pipeline, particularly for scales beyond AA2 in 2026.

The outcome of the PhD would be an innovative new approach to robust, scalable imaging in the SKA era, enabling crucial science applications for SKA, ngVLA, and ngEHT. This experience would provide valuable expertise in cutting-edge GNN development with prospects for broader academic and industry applications

Opportunity statusClosed
Open date01 Aug 2024
Close date30 Sep 2024
SchoolGraduate Research School
Contact

Professor Andreas Wicenec | andreas.wicenec@uwa.edu.au

Director, Data Intensive Astronomy

Dr Richard Dodson | richard.dodson@uwa.edu.au

Senior Research Fellow

Dr O. Ivy Wong | ivy.wong@icrar.org

Adjunct Senior Research Fellow

Course typeDoctorates
Description

The Doctor of Philosophy (PhD) is a program of independent, supervised research that is assessed solely on the basis of a thesis, sometimes including a creative work component, that is examined externally. The work presented for a PhD must be a substantial and original contribution to scholarship, demonstrating mastery of the subject of interest as well as an advance in that field of knowledge. 

Visit the course webpage for full details of this course including admission requirements, course rules and the relevant CRICOS code/s.

Duration4 years