Synthetic Aperture Radio Holography for High Resolution Remote Sensing. This project aims to develop fundamental theory and enabling technology for a novel radio remote sensing system using a breakthrough synthetic aperture radio holography concept. Such a system would leapfrog current capabilities to produce high-resolution, day-and-night and weather-independent 3-D images for many applications (eg geoscience and climate change research, environmental and agricultural monitoring, defence and se ....Synthetic Aperture Radio Holography for High Resolution Remote Sensing. This project aims to develop fundamental theory and enabling technology for a novel radio remote sensing system using a breakthrough synthetic aperture radio holography concept. Such a system would leapfrog current capabilities to produce high-resolution, day-and-night and weather-independent 3-D images for many applications (eg geoscience and climate change research, environmental and agricultural monitoring, defence and security-related target detection, and planetary exploration). Expected project outcomes include advanced sensing and data processing knowledge and a prototype demonstrating the developed analogue and digital hardware.Read moreRead less
Developing hole spin quantum bits in industrially fabricated silicon chips. This is a joint proposal to combine IMEC’s technology and facilities for silicon chip fabrication with UNSW’s expertise in quantum devices to optimise the design and fabrication techniques used to manufacture silicon based hole spin qubits on an industrial scale in a full 300mm wafer fabrication line. IMEC is a world-leading research and innovation hub in nanoelectronics and digital technologies, with a €1billion semico ....Developing hole spin quantum bits in industrially fabricated silicon chips. This is a joint proposal to combine IMEC’s technology and facilities for silicon chip fabrication with UNSW’s expertise in quantum devices to optimise the design and fabrication techniques used to manufacture silicon based hole spin qubits on an industrial scale in a full 300mm wafer fabrication line. IMEC is a world-leading research and innovation hub in nanoelectronics and digital technologies, with a €1billion semiconductor chip fabrication facility, while UNSW has unparalleled cryogenic equipment and theoretical expertise for the study of electrons and holes in semiconductor devices. The outcomes will open up new routes to spin-based quantum computing based on holes. Read moreRead less
Radio Frequency Camera for Low-Complexity and High-Resolution Radar Imaging. This project aims to develop the theory and enabling techniques to realise a low-complexity and high-resolution radar imaging system with uncoordinated illumination. New scientific breakthroughs include fundamental radar imaging theory, advanced radio frequency frontend design and fast signal processing algorithms. These will lead to a paradigm shift in active and passive imaging technologies. A proof-of-concept prototy ....Radio Frequency Camera for Low-Complexity and High-Resolution Radar Imaging. This project aims to develop the theory and enabling techniques to realise a low-complexity and high-resolution radar imaging system with uncoordinated illumination. New scientific breakthroughs include fundamental radar imaging theory, advanced radio frequency frontend design and fast signal processing algorithms. These will lead to a paradigm shift in active and passive imaging technologies. A proof-of-concept prototype of the proposed imaging system with 77 GHz millimetre wave will be developed to demonstrate its feasibility and performance. The expected outcomes include Australia’s scientific and technological leadership in radar imaging and enhanced capability in emergency response, defence, public safety, and healthcare industries.Read moreRead less
Beamforming with acoustic vector sensors for audio user interfaces. We aim to create new Audio User Interfaces (AUIs) for the automatic separation and annotation of audio from complex sound scenes using acoustic vector sensor beamforming technology. Specifically, we will develop: speech AUIs for noisy, multi-talker, reverberant environments; and sound transcription AUIs for the deaf. Ultimately, users will be able to walk into a room, hold conversations and leave with a searchable, automatically ....Beamforming with acoustic vector sensors for audio user interfaces. We aim to create new Audio User Interfaces (AUIs) for the automatic separation and annotation of audio from complex sound scenes using acoustic vector sensor beamforming technology. Specifically, we will develop: speech AUIs for noisy, multi-talker, reverberant environments; and sound transcription AUIs for the deaf. Ultimately, users will be able to walk into a room, hold conversations and leave with a searchable, automatically-generated transcript of the audio events, tagged with metadata. The application of these technologies will create new possibilities for recording audio in the music, radio, TV industries, and future home based audio communication systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100062
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Silicon LPCVD Facility for Nanoelectronics, Quantum Computing & Solar Cells. Silicon low-pressure chemical vapor deposition facility:
This project aims to complete Australia’s first manufacturing line for nanoscale devices. It aims to establish a low-pressure chemical vapour deposition system to complete the existing silicon complementary metal-oxide semiconductor process line. It is currently impossible to fabricate many devices compatible with industrial manufacture, limiting device reliabili ....Silicon LPCVD Facility for Nanoelectronics, Quantum Computing & Solar Cells. Silicon low-pressure chemical vapor deposition facility:
This project aims to complete Australia’s first manufacturing line for nanoscale devices. It aims to establish a low-pressure chemical vapour deposition system to complete the existing silicon complementary metal-oxide semiconductor process line. It is currently impossible to fabricate many devices compatible with industrial manufacture, limiting device reliability and path to commercialisation. The tool is designed to incorporate four furnace tubes for growing thin layers of electronic materials, including polycrystalline-silicon, epitaxial silicon, and silicon-nitride. One unique aspect will be growth of isotopically-enriched silicon-28 that is essential for spin-based quantum computing. The tool would support a wide range of projects nationally in silicon micro/nano-systems, advanced photovoltaics, and quantum technologies.Read moreRead less
Biological pattern generator for control and optimization of locomotion systems. This proposal exploits the interdisciplinary nature of systems and control area and incorporates biology science. It is expected to generate a synergy between biology science and control engineering and to advance scientific understanding in both fields. The proposed research will have impact on new innovations in a variety of fields. This will bring economic benefits for Australia. It will help to develop engineers ....Biological pattern generator for control and optimization of locomotion systems. This proposal exploits the interdisciplinary nature of systems and control area and incorporates biology science. It is expected to generate a synergy between biology science and control engineering and to advance scientific understanding in both fields. The proposed research will have impact on new innovations in a variety of fields. This will bring economic benefits for Australia. It will help to develop engineers for industry who have team-oriented problem-solving skills in a multidisciplinary working environment. It will also stimulate students' intellectual curiosity into engineering and science through a series of innovative interdisciplinary research/educational activities.Read moreRead less
Detection and Quantification of General Fetal Movements from Accelerometer Measurements using Nonstationary Signal Processing Techniques. There are approximately 1,750 fetal deaths per year in Australian with about one-third occurring late in gestation and without an apparent cause. The development of an automated system capable of long-term monitoring of fetal health will result in accurate diagnoses and prediction of future outcome. This will, in turn, allow early intervention by the clinicia ....Detection and Quantification of General Fetal Movements from Accelerometer Measurements using Nonstationary Signal Processing Techniques. There are approximately 1,750 fetal deaths per year in Australian with about one-third occurring late in gestation and without an apparent cause. The development of an automated system capable of long-term monitoring of fetal health will result in accurate diagnoses and prediction of future outcome. This will, in turn, allow early intervention by the clinician to reduce fetal deaths and enhance the chances of good outcomes with resultant savings in social and financial costs to the community. The development of such equipment would spawn future research into intervention treatments and contribute to Australia's position as a world leader in computerised health monitoring systems.Read moreRead less
Multi-Channel Time-Frequency Analysis for EEG Neonatal Seizure Characterization. This project researches new signal processing methodologies for a multi-channel characterization of seizures for use in diagnosing newborn brain dysfunctions. The outcomes will result in important immediate clinical benefits for sick newborn babies and will fundamentally facilitate research progress in the development of neuroprotectants and anticonvulsants. The success of this project will contribute in minimizing ....Multi-Channel Time-Frequency Analysis for EEG Neonatal Seizure Characterization. This project researches new signal processing methodologies for a multi-channel characterization of seizures for use in diagnosing newborn brain dysfunctions. The outcomes will result in important immediate clinical benefits for sick newborn babies and will fundamentally facilitate research progress in the development of neuroprotectants and anticonvulsants. The success of this project will contribute in minimizing the social financial costs by diagnosing brain disorders in the initial stage of life and preventing further damage. This has the potential to result in a standard diagnostic equipment in neonatal intensive care units and medical research centres.Read moreRead less
Design of Neonatal Seizure Diagnosis Methods Using Time-Frequency Signal Processing Techniques. Seizures occur in approximately 0.5% of all newborns. They are often the only indicator of an early dysfunction in central nervous system (CNS). Their occurrence raises concerns about the underlying cause, its effect on the brain, and the appropriate treatment. Newborn seizures are mostly sub-clinical and only detected through the Electroencephalogram. For an efficient diagnosis, seizure classificatio ....Design of Neonatal Seizure Diagnosis Methods Using Time-Frequency Signal Processing Techniques. Seizures occur in approximately 0.5% of all newborns. They are often the only indicator of an early dysfunction in central nervous system (CNS). Their occurrence raises concerns about the underlying cause, its effect on the brain, and the appropriate treatment. Newborn seizures are mostly sub-clinical and only detected through the Electroencephalogram. For an efficient diagnosis, seizure classification systems were proposed based on visual observations. This project proposes developing a novel approach to automate the classification process using time-frequency (TF) signal processing techniques based on the multi-channel characteristics of the seizure; namely: A) TF signature B) origin, and C) propagation behaviour.Read moreRead less
Biologically Inspired Binaural Coupling for Selective Machine Hearing. This project aims to investigate biologically-inspired binaural coupling models in the context of the deep learning paradigm by formulating desirable higher level auditory structures as neural network sub-systems. This project expects to generate new knowledge for developing the next generation of robust speech processing systems that are capable of mimicking the selecting listening ability of humans when faced with realistic ....Biologically Inspired Binaural Coupling for Selective Machine Hearing. This project aims to investigate biologically-inspired binaural coupling models in the context of the deep learning paradigm by formulating desirable higher level auditory structures as neural network sub-systems. This project expects to generate new knowledge for developing the next generation of robust speech processing systems that are capable of mimicking the selecting listening ability of humans when faced with realistic noisy speech signals and the ‘cocktail party problem’ using innovative binaural feedback systems. This work should provide significant benefits, including improved voice biometrics and selective auditory attention capabilities in machines.Read moreRead less