Real-time signal processing and distributed robotic telescope networking for co-detection of gravitational waves and their optical counterparts. An international collaboration of scientists will employ a global network of telescopes and detectors to search for ripples in space-time. The project will use novel computational tools to study exotic phenomena in the distant Universe.
An automatic markerless three-dimensional (3D) motion analysis system for aquatic environments. Australia's sporting performance on the international stage forms an integral part of the psyche of Australians. This project applies latest 3D imaging and biomechanical techniques to quantify swimmers' movement patterns, thereby ensuring Australia's continued elite sporting success and consolidating its current lead in world class technologies.
Foundations and advanced algorithms for topological image processing. Building on new links between the mathematical discipline of homology and digital images, this project develops a new class of topology-driven image analysis techniques that will improve the accuracy and reliability of predictions made from the powerful new generation of three dimensional microscopes.
A networked robotic telescope array for coincident detection of transient phenomena in the optical, gravitational wave, neutrino and radio spectra. An international collaboration of scientists will employ a global network of rapid response robotic telescopes and detectors to study exotic transient phenomena in the early Universe. Potential spin-offs include the application of novel image analysis techniques for identifying and tracking dangerous space junk.
The physics of planetary creation with the James Webb Space Telescope. This project aims to investigate the physics of solar system assembly. Understanding the origins of the Earth and our Solar System is one of the challenges for contemporary astronomy. By understanding the diverse chemistry and physical conditions on exoplanets, the project aims to directly address the question of if and where life is harbored around distant stars. This project will participate in the 2018 launch of the James ....The physics of planetary creation with the James Webb Space Telescope. This project aims to investigate the physics of solar system assembly. Understanding the origins of the Earth and our Solar System is one of the challenges for contemporary astronomy. By understanding the diverse chemistry and physical conditions on exoplanets, the project aims to directly address the question of if and where life is harbored around distant stars. This project will participate in the 2018 launch of the James Webb Space Telescope (JWST), which will carry an Australian-designed interferometer.Read moreRead less
Extreme events: mining the radio sky for gamma-ray bursts with intelligent algorithms. Gamma-ray bursts and supernova explosions are some of the most extreme events in the Universe, and working out what causes them, and other transient phenomena, will give us new physical insights. The project will search, using next generation telescopes and intelligent algorithms, to find these 'needles in a haystack'.
The radio transient sky in real time. This project plans to use three new Australian telescopes to conduct the most comprehensive search ever made for transient sources. Transient phenomena (astronomical objects that appear and disappear or change rapidly) are laboratories for exploring some of the most extreme processes in the Universe. Radio astronomy is on the verge of a revolution in the study of transients, made possible by new technology. The project aims to leverage the learnings from the ....The radio transient sky in real time. This project plans to use three new Australian telescopes to conduct the most comprehensive search ever made for transient sources. Transient phenomena (astronomical objects that appear and disappear or change rapidly) are laboratories for exploring some of the most extreme processes in the Universe. Radio astronomy is on the verge of a revolution in the study of transients, made possible by new technology. The project aims to leverage the learnings from the new technology by developing intelligent algorithms able to extract weak signals from massive datasets to find rare and exotic objects ranging from extra-solar planets to gamma-ray bursts, exploring the unknown in ways that have previously not been possible. These algorithms may have broad impact in astronomy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100051
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A robotic telescope imaging system for rapid response spectroscopy of gamma ray bursts. This project will build and employ a rapid response optical spectrograph on the robotic Zadko Telescope, triggered by satellite and ground based observatories. The instruments will be used to probe the most energetic explosions in the universe and to test non-standard quantum and relativity theories using coincident multi-wavelength observations.
Discovery Early Career Researcher Award - Grant ID: DE220101402
Funder
Australian Research Council
Funding Amount
$415,000.00
Summary
Multi-scale, multi-modal X-ray imaging using speckle. This project aims to develop new X-ray imaging methods that capture multiple next-generation image modalities at an unprecedented range of length and time scales. While conventional X-ray imaging is routinely used in medicine and industry, it can only visualise high-density materials like bone. To reveal low-density objects like biological soft tissue and microstructure like tiny cracks, the project plans to extract two complementary image mo ....Multi-scale, multi-modal X-ray imaging using speckle. This project aims to develop new X-ray imaging methods that capture multiple next-generation image modalities at an unprecedented range of length and time scales. While conventional X-ray imaging is routinely used in medicine and industry, it can only visualise high-density materials like bone. To reveal low-density objects like biological soft tissue and microstructure like tiny cracks, the project plans to extract two complementary image modalities using a robust setup that does not rely on large-scale facilities. Significant benefits from the developed methods are expected for leading-edge research in fields including biomedicine, materials science and palaeontology, and industries such as security, medical diagnostics and manufacturing.Read moreRead less
The worlds next door: terrestrial exoplanets with the TOLIMAN space mission. This project aims to to explore our nearest neighbour star system, Alpha Centauri, for the first time probing for exoplanets with physical characteristics that resemble those of Earth. The finding of any such world, with the potential to support a biosphere like our own and lying only 4 light-years away, would profoundly alter our view of our place in the universe. The primary outcome of this project will be the design, ....The worlds next door: terrestrial exoplanets with the TOLIMAN space mission. This project aims to to explore our nearest neighbour star system, Alpha Centauri, for the first time probing for exoplanets with physical characteristics that resemble those of Earth. The finding of any such world, with the potential to support a biosphere like our own and lying only 4 light-years away, would profoundly alter our view of our place in the universe. The primary outcome of this project will be the design, construction, launch and operation of a novel and innovative space telescope: the TOLIMAN mission. This profoundly benefits the Australian space and university sectors, partnering them with international agencies to deliver marquee science with global impact: the search for our first stepping stone to interstellar space.Read moreRead less