AI for space research delivers back-to-back success in global satellite challenge
South Australia鈥檚 leadership in space innovation has been recognised, with a team led by the Australian Institute for Machine Learning securing first place in a global AI competition organised by the European Space Agency and Stanford University鈥檚 Space Rendezvous Laboratory.
The , which concluded last month, saw international teams compete to build custom AI software that can estimate the pose (position and orientation) of a satellite in orbit using only an image.
In the competition, a dataset of labelled computer-generated images was provided to each team to train their AI models. The models were then tested and benchmarked for accuracy on real photographs of a scale model of the satellite produced by the at Stanford University. Machine learning researchers refer to this as solving the domain gap problem 鈥 training AI on labelled data from one source (domain) and then successfully deploying it on unlabelled data in another domain.
The subject of the challenge, a microwave oven-sized satellite named , was launched by the Swedish Space Corporation in 2010 and was shut down permanently in 2013.
Team 罢补苍驳辞鲍苍肠丑补颈苍别诲鈥a collaboration between AIML's and European space startup 鈥competed against 35 other groups to place first and third in the competition鈥檚 two categories, repeating the University鈥檚 previous success placing first in the .
Team members included research student Mohsi Jawaid, postdoctoral researcher Dr Bo Chen, SmartSat CRC Professorial Chair of Sentient Satellites Professor Tat-Jun Chin, and Augustinas Zinys and Marius Klimavicius from Blackswan Space.
A sample image of a scale model of the Tango satellite which is designed to mimic the softer reflected lighting conditions of satellites in orbit.
The ability of AI systems to accurately determine the pose of satellites, spacecraft, orbital debris and asteroids is crucial for autonomous spacecraft, or in missions where direct human control is costly and/or error prone.
AIML research student Mohsi Jawaid said that AI-based computer vision systems provide a compelling sensing and perception solution for autonomous space missions.
鈥淎nd it鈥檚 not just satellites, it could be any space bodies, space junk, asteroids. You want to get accurate vision of it so you can approach it safely.鈥
The team took an agile approach to the challenge, with different members taking charge through different phases of the project. Dr Bo Chen has helped build AIML鈥檚 track record in AI in space, having also played an instrumental role in winning the 2019 challenge.
Professor Tat-Jun Chin said that competition in AI for space technology is growing.
鈥淭he latest competition was much tighter, no doubt due to the growth in interest in space and AI over the last few years,鈥 Professor Chin said.
鈥淐hallenges like this give our students and researchers real, applied scenarios to test their skills. They also demonstrate the quality of our work to international clients and partners.鈥
The team also acknowledged the generous support of the University鈥檚 High Performance Computing service in providing access to the Phoenix supercomputer, which was a major contributing factor to the team鈥檚 success.
The Space Rendezvous Laboratory (SLAB) at Stanford University created a dataset of images using a half-scale model under lighting conditions designed to mimic the real satellite's orbital environment.