An Empirically Derived Experimentally Validated Framework for Interactions in Information Environments. This project will investigate and design ways of interacting with the information infrastructure that maintain natural social interactions, take advantage of physical space and utilise our extensive human abilities to recognise and manipulate physical objects.
Expected outcomes include:
? a theoretical framework that describes the range of possible interactions that mediate information b ....An Empirically Derived Experimentally Validated Framework for Interactions in Information Environments. This project will investigate and design ways of interacting with the information infrastructure that maintain natural social interactions, take advantage of physical space and utilise our extensive human abilities to recognise and manipulate physical objects.
Expected outcomes include:
? a theoretical framework that describes the range of possible interactions that mediate information between the physical and virtual worlds.
? a prototype instrumented information environment that demonstrates and validates naturalistic information transactions identified in the framework.
This research is highly innovative in its field. It will use an iterative cycle of video observation, interaction analysis, user-centred device design, deployment and evaluation.
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Reconfigurable Computing Implementations of Reactive Systems. Reconfigurable computing combines programmable software with programmable hardware and shows real promise as an efficient implementation technology for real-time embedded computing applications. However, its use in real-time systems has been hampered by a lack of rigorous analysis of its benefits, and by a lack of a suitable methodology for the efficient specification, analysis and design of such systems. This project seeks to deve ....Reconfigurable Computing Implementations of Reactive Systems. Reconfigurable computing combines programmable software with programmable hardware and shows real promise as an efficient implementation technology for real-time embedded computing applications. However, its use in real-time systems has been hampered by a lack of rigorous analysis of its benefits, and by a lack of a suitable methodology for the efficient specification, analysis and design of such systems. This project seeks to develop such a methodology, and demonstrate its benefits through several proof-of-concept application implementations.Read moreRead less
Greatly improved rectification by molecular diodes. Society has already seen dramatic benefits from microtechnology, which has made possible most of the devices that we take for granted. The limits of miniaturisation using current technology are rapidly being reached, and the next stage is in the realm of nanotechnology. The goal of the field known as molecular electronics is to reach the point where electronic components are composed of single molecules or single molecular layers. In this fi ....Greatly improved rectification by molecular diodes. Society has already seen dramatic benefits from microtechnology, which has made possible most of the devices that we take for granted. The limits of miniaturisation using current technology are rapidly being reached, and the next stage is in the realm of nanotechnology. The goal of the field known as molecular electronics is to reach the point where electronic components are composed of single molecules or single molecular layers. In this field the smallest active component is the molecular diode, and this project is focussed on achieving practical performance from molecular diodes, as a crucial first step in achieving miniaturisation far beyond anything now possible.Read moreRead less
Developing a simple method for characterising the mechanical properties of nanowhiskers. This project aims to accurately measure mechanical properties of nanostructures, addressing a challenging issue in the ongoing development of nanotechnology. The success of this project will provide important advances in the understanding of the mechanical behaviour of nanowhiskers and assist in the further development of nanomaterials.
Non-contact Instrumentation for the Home Monitoring of Upper Airway Obstructions in Sleep. Over 800,000 Australians suffer from obstructive sleep apnoea costing billions of dollars annually to the nation. Obstructive sleep apnoea patients use twice the health resources compared to a normal person, and 7 times more likely to cause traffic accidents. In NSW alone up to 43000 accidents per year are due to obstructive sleep apnoea. Obstructive sleep apnoea is treatable and thus consequences such as ....Non-contact Instrumentation for the Home Monitoring of Upper Airway Obstructions in Sleep. Over 800,000 Australians suffer from obstructive sleep apnoea costing billions of dollars annually to the nation. Obstructive sleep apnoea patients use twice the health resources compared to a normal person, and 7 times more likely to cause traffic accidents. In NSW alone up to 43000 accidents per year are due to obstructive sleep apnoea. Obstructive sleep apnoea is treatable and thus consequences such as stroke and heart attacks are preventable. At present over 90% patients remain undiagnosed. Current diagnosis is expensive and requires hospitalization; no acceptable mass screening device exists. This project proposes an enabling technology for the population screening of obstructive sleep apnoea based on analysing snoring sounds. Outcomes of the project have the potential to revolutionize the diagnosis of obstructive sleep apnoea.Read moreRead less
Developing innovative methodologies to understand nano-adhesion/friction. The project seeks to improve the measurement of nanoscale adhesion and friction. The understanding of adhesion and friction between a nanowhisker and a substrate is crucial for developing next-generation nanodevices. However, the current methods for measuring nanoscale adhesion and friction are inaccurate and can produce contradictory results, due to the extreme challenges in mastering sophisticated measuring techniques an ....Developing innovative methodologies to understand nano-adhesion/friction. The project seeks to improve the measurement of nanoscale adhesion and friction. The understanding of adhesion and friction between a nanowhisker and a substrate is crucial for developing next-generation nanodevices. However, the current methods for measuring nanoscale adhesion and friction are inaccurate and can produce contradictory results, due to the extreme challenges in mastering sophisticated measuring techniques and the lack of understanding of their underlying mechanisms. This project aims to develop innovative ‘push-peel’ and ‘push-slide’ methods to accurately measure those properties and to further understand their fundamental origins. Successful outcomes from this study would not only solve a long-standing problem in the application of nanowhiskers, but also generate new nanosurface science.Read moreRead less
Biocompatible Electro-Ionic Signal Transduction. Bioelectronics is a new frontier field concerned with integrating electrical control systems and biological entities for applications such as in-situ bio-monitoring and cellular-level control and interrogation of tissue. Electrical signals in biology are mostly carried by ion currents, whilst conventional electronics rely on electrons. This project addresses the critical challenge of bioelectronics; the development of biocompatible electrical inte ....Biocompatible Electro-Ionic Signal Transduction. Bioelectronics is a new frontier field concerned with integrating electrical control systems and biological entities for applications such as in-situ bio-monitoring and cellular-level control and interrogation of tissue. Electrical signals in biology are mostly carried by ion currents, whilst conventional electronics rely on electrons. This project addresses the critical challenge of bioelectronics; the development of biocompatible electrical interfaces capable of transducing ion-and-electron currents. This project will specifically study the complex transport physics of conducting biomacromolecules and develop new interface devices, with an ultimate goal is to create a simple and generic transducing element for cellular-level electrical communication. Read moreRead less
Understanding of nanostructures and magnetic properties of Ge-based diluted magnetic semiconductors for spintronic devices. The success of growing high-quality germanium-based diluted magnetic semiconductors will position Australian fundamental & applied research at the world forefront of magnetic semiconductors. This multi-disciplinary research will not only secure a number of high-impact publications in leading international journals, but also has the potential to generate patentable technolog ....Understanding of nanostructures and magnetic properties of Ge-based diluted magnetic semiconductors for spintronic devices. The success of growing high-quality germanium-based diluted magnetic semiconductors will position Australian fundamental & applied research at the world forefront of magnetic semiconductors. This multi-disciplinary research will not only secure a number of high-impact publications in leading international journals, but also has the potential to generate patentable technologies which might bring potential economic benefits to Australia. In addition, the project will strengthen the collaboration between Australian researchers and world-renowned scientists and will allow Australian researchers to access world-best fabrication facilities. All these will enhance the international competitive profile of Australia in the field of spintronics.Read moreRead less
Controllable growth of magnetic semiconductor quantum dots for future spintronic and optoelectronic devices. This project aims to develop high quality magnetic semiconductor materials for next generation magnetic and optoelectronic devices. Outcomes of this project will lead to advanced applications in light-emitting diodes and information technology, such as high density hard drivers and low dissipation quantum computers.
A Virtual Electromagnetic Compatibility (EMC) Lab Based on Advanced Computer Modeling and Simulation Techniques. The proposed project will provide a framework of electromagnetic compatibility computer modelling technologies for an electromagnetic compatibility/electromagnetic interference problem-solving environment. It will result in theoretical and practical contributions to the field of electromagnetic compatibility/electromagnetic interference and computational electromagnetics. The project ....A Virtual Electromagnetic Compatibility (EMC) Lab Based on Advanced Computer Modeling and Simulation Techniques. The proposed project will provide a framework of electromagnetic compatibility computer modelling technologies for an electromagnetic compatibility/electromagnetic interference problem-solving environment. It will result in theoretical and practical contributions to the field of electromagnetic compatibility/electromagnetic interference and computational electromagnetics. The project will provide an innovative technology to industry and societies with following major benefits: a) increased productivity and minimized the product risk with low failure rate, b) quicker project management cycles through such cost-effective electromagnetic compatibility computer modelling and simulation techniques based virtual Electromagnetic Compatibility Lab. and c) improved electromagnetic compatibility/electromagnetic interference problem solving environment and techniques for scientific research and commercial applications.Read moreRead less