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Microwave Detection of Structural Degradation in Maritime Industry. Novel applications of microwave technology to inspection systems in marine infrastructure will transform industry practice. By utilizing multi-mode antennas, the project aims to develop a gold-standard in microwave inspection, delivering more accurate and early detection of defects. The project aims will be achieved by combining innovative microwave technology, featuring multi-mode antennas and novel processing and imaging algor ....Microwave Detection of Structural Degradation in Maritime Industry. Novel applications of microwave technology to inspection systems in marine infrastructure will transform industry practice. By utilizing multi-mode antennas, the project aims to develop a gold-standard in microwave inspection, delivering more accurate and early detection of defects. The project aims will be achieved by combining innovative microwave technology, featuring multi-mode antennas and novel processing and imaging algorithms, with ground-breaking smart scanning and unmanned marine vehicle implementations. This innovative outcome obviates the need for current industry approaches based on inaccurate and tedious manual inspections, yielding massive cost savings and reductions in hazard associated with unanticipated structural failure.Read moreRead less
Running Hot: Increasing the Availability of World-Class Precision Timing . Precision clocks are a key enabler for many important technologies including navigation, radar, distributed computing and communications. Unfortunately, the very best clocks are currently bulky and very expensive. This project will take Australia’s multi-award winning sapphire clock technology and transform it so that its unmatched performance is available from a unit with an order of magnitude smaller size, power consum ....Running Hot: Increasing the Availability of World-Class Precision Timing . Precision clocks are a key enabler for many important technologies including navigation, radar, distributed computing and communications. Unfortunately, the very best clocks are currently bulky and very expensive. This project will take Australia’s multi-award winning sapphire clock technology and transform it so that its unmatched performance is available from a unit with an order of magnitude smaller size, power consumption and cost. This transformation will be driven on the back of a patented revolutionary step that allows operation of the sapphire clock at higher cryogenic temperatures. The new clock will have a wider range of applications delivering more computational power, higher bandwidth transmissions and better radar. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100003
Funder
Australian Research Council
Funding Amount
$318,900.00
Summary
Vector network analyser suite for advanced terahertz materials and devices. This project aims to establish terahertz measurement capabilities to further Australia's strength and momentum in terahertz research. This will comprise of two terahertz extension modules, working with a dedicated vector-network analyser, and high-precision probes and probe station. The project will enable point-feeding, monochromatic, coherent, and fine spectral-resolution measurement at an atmospheric window of 220-330 ....Vector network analyser suite for advanced terahertz materials and devices. This project aims to establish terahertz measurement capabilities to further Australia's strength and momentum in terahertz research. This will comprise of two terahertz extension modules, working with a dedicated vector-network analyser, and high-precision probes and probe station. The project will enable point-feeding, monochromatic, coherent, and fine spectral-resolution measurement at an atmospheric window of 220-330 GHz. The capabilities are essential for development of two-dimensional materials, active components, waveguides, and antennas towards a common goal of efficient integrated terahertz devices and systems. The project will serve emerging terahertz applications including standoff imaging and short-range high-speed data transmission. This will have broad impact in the areas of surveillance, biomedicine, security, and public safety and well-being.Read moreRead less
Microwave Head Monitor Using Compressed Sensing and Differential Techniques. The aim of this project is the design and development of a low-cost, non-ionising, and non-invasive microwave technology that can be used to diagnose and localise early brain injuries of premature newborn babies. It proposes to include a switched antenna array and wide-band microwave transceiver. The system aims to use a combination of compressed sensing and differential imaging techniques to produce, within a few secon ....Microwave Head Monitor Using Compressed Sensing and Differential Techniques. The aim of this project is the design and development of a low-cost, non-ionising, and non-invasive microwave technology that can be used to diagnose and localise early brain injuries of premature newborn babies. It proposes to include a switched antenna array and wide-band microwave transceiver. The system aims to use a combination of compressed sensing and differential imaging techniques to produce, within a few seconds, microwave images of the brain making it a real-time monitoring tool. By providing vital information about the brain at the incubator side, the proposed compact technology would avoid the risky move of critically ill babies to the expensive and bulky conventional scanners which, furthermore, cannot operate as frequent monitoring tools.Read moreRead less
Portable microwave systems for imaging and monitoring of the human body. The proposal focuses on the design and development of portable equipment which uses microwave techniques to detect brain and lungs abnormalities such as stroke and pulmonary edema. The proposed equipment can be used by first response paramedical teams and in rural medical clinics, where access to traditional diagnostic tools is limited.
Engineering the next generation of portable microwave scanners. This project aims to engineer a disruptive technology based on microwave hybrid imaging for biomedical applications. The project will deliver superfine resolution images using a combination of uniform near-field microwave irradiation and infrared imaging. The project will explore novel microwave antenna design, and engineer a portable platform for diagnostic applications. The proposed low-cost, non-invasive, and safe microwave techn ....Engineering the next generation of portable microwave scanners. This project aims to engineer a disruptive technology based on microwave hybrid imaging for biomedical applications. The project will deliver superfine resolution images using a combination of uniform near-field microwave irradiation and infrared imaging. The project will explore novel microwave antenna design, and engineer a portable platform for diagnostic applications. The proposed low-cost, non-invasive, and safe microwave technology will offer significant advantages over conventional diagnostic platforms. Among many potential applications, this innovation will introduce the first portable microwave scanner that can be used for the early detection of skin cancer.Read moreRead less
Portable Microwave Imaging Technology Using Reconfigurable Radar. The aim of this project is the design and development of a portable microwave imaging system to investigate the viability of microwave techniques for early heart failure detection. It will employ conformal antenna arrays integrated with compact reconfigurable radar to obtain super-resolution images that enable the early detection of heart failure. Because of its low-cost, non-ionising and non-invasive properties, it can be used fr ....Portable Microwave Imaging Technology Using Reconfigurable Radar. The aim of this project is the design and development of a portable microwave imaging system to investigate the viability of microwave techniques for early heart failure detection. It will employ conformal antenna arrays integrated with compact reconfigurable radar to obtain super-resolution images that enable the early detection of heart failure. Because of its low-cost, non-ionising and non-invasive properties, it can be used frequently for real-time monitoring, thus providing a significant advantage over conventional imaging equipment and hence paving the way for its broader applications. Moreover, portability of the technology is expected to enable its use for self-monitoring, leading to a significant reduction in health care costs.Read moreRead less
Engineering high-efficiency all-dielectric antennas for terahertz channels. This project aims to create unconventional antenna platforms to support terahertz links. The project expects to deliver high-efficiency, high-gain dielectric resonator antennas and dielectric rod antenna arrays fed by dielectric wave-guides. The expected outcomes of this project will build critical components for future terahertz communication infrastructure. These antennas will support demands in point-to-point wireless ....Engineering high-efficiency all-dielectric antennas for terahertz channels. This project aims to create unconventional antenna platforms to support terahertz links. The project expects to deliver high-efficiency, high-gain dielectric resonator antennas and dielectric rod antenna arrays fed by dielectric wave-guides. The expected outcomes of this project will build critical components for future terahertz communication infrastructure. These antennas will support demands in point-to-point wireless transmission between mobile base stations, within data centres, and at information kiosks.Read moreRead less
Reconfigurable antennas for satellite on-the-move communications. Reconfigurable antennas for satellite on-the-move communications. This project aims to design and develop low-cost reconfigurable end-user antennas that could be integrated with low-earth-orbit satellites so regional and remote Australians can access broadband. While broadband is taking its place alongside water and electricity as essential infrastructure, people in regional Australia lack genuine broadband services. These antenna ....Reconfigurable antennas for satellite on-the-move communications. Reconfigurable antennas for satellite on-the-move communications. This project aims to design and develop low-cost reconfigurable end-user antennas that could be integrated with low-earth-orbit satellites so regional and remote Australians can access broadband. While broadband is taking its place alongside water and electricity as essential infrastructure, people in regional Australia lack genuine broadband services. These antennas are expected to give these communities reliable access to e-health services and distance education, and make their businesses more productive with access to new markets. The proposed antennas should also make broadband services available in the air, at sea, or on the move.Read moreRead less