Model-Based Approach to Adaptive Channel Coding and Estimation for Future Wireless Communication Systems. The project aims to maximise capacity, data rate and user mobility in wireless communication systems and will advance Australia's fundamental knowledge base in this field so that it stays at the forefront of international research in mobile communications. The application of research outcomes by the Australian telecommunications industry will improve the extent and quality of mobile networks ....Model-Based Approach to Adaptive Channel Coding and Estimation for Future Wireless Communication Systems. The project aims to maximise capacity, data rate and user mobility in wireless communication systems and will advance Australia's fundamental knowledge base in this field so that it stays at the forefront of international research in mobile communications. The application of research outcomes by the Australian telecommunications industry will improve the extent and quality of mobile networks, increasing network capacity and the number of mobile phone subscribers in Australia. This project will also optimise the use of mobile network resources (such as bandwidth and power) in next generation mobile networks, which in turn will result in faster and more reliable services such as wireless Internet access for business and private use.Read moreRead less
New generation functional materials for 21st century applications: exploiting the properties of naphthalene diimides. This project melds the expertise of several research groups in the area of fluorescent material development. Based on a family of highly fluorescent molecules, the project will focus on designing new sensors, polymeric materials and molecular switching devices.
Optimum cross-layer design in wireless communication systems with channel uncertainty. For wireless communications to be part of Australia's information delivery infrastructure, including the National Broadband Network, requires improvements in reliability, speed and cost effectiveness over current technologies. The assembled world class research team has the objective to develop advanced design techniques to meet this challenge.
Reliable Communication in Wireless Cooperative Networks under Channel Uncertainty. The project addresses important problems in Breakthrough sciences and Frontier technologies within the national priority goals. It provides innovative solutions for wireless information technologies. The project's high-impact contributions will advance Australia’s knowledge base and publication of outcomes will elevate and maintain Australia's existing reputation in the field. The project provides 1) high-quality ....Reliable Communication in Wireless Cooperative Networks under Channel Uncertainty. The project addresses important problems in Breakthrough sciences and Frontier technologies within the national priority goals. It provides innovative solutions for wireless information technologies. The project's high-impact contributions will advance Australia’s knowledge base and publication of outcomes will elevate and maintain Australia's existing reputation in the field. The project provides 1) high-quality training for postgraduate students and 2) opportunities for collaborations with a prominent international partner investigator. The innovative solutions will address the ever-increasing demand for high-speed wireless Internet and multimedia.Read moreRead less
Early-Stage Medical Diagnostics by Plasmon-Mediated Gas Sensing. This project will investigate the use plasmonic absorption of light in metal nanostructures to activate the selective oxidation/reduction of a gas molecule on a semiconductor nanoparticle. This concept will be used with the aim of developing a sensing technique capable of measuring ultra-low concentrations (ppb) of breath markers for lung cancer detection. It is expected that porous sensing films of semiconductor and metal nanopart ....Early-Stage Medical Diagnostics by Plasmon-Mediated Gas Sensing. This project will investigate the use plasmonic absorption of light in metal nanostructures to activate the selective oxidation/reduction of a gas molecule on a semiconductor nanoparticle. This concept will be used with the aim of developing a sensing technique capable of measuring ultra-low concentrations (ppb) of breath markers for lung cancer detection. It is expected that porous sensing films of semiconductor and metal nanoparticles with well-defined light absorption properties will be fabricated. Superior selectivity will be achieved by matching the wavelength of the absorbed light with the required activation energy for oxidation/reduction. Successful outcomes will enable multi-analyte fingerprint identification by on-chip devices with applications ranging from portable medical diagnostics to national security.Read moreRead less
From Universal Induction to Intelligent Systems. The dream of creating artificial devices that (out)reach human intelligence is an old one. What makes this challenge so interesting? A solution would have enormous implications for our society, and there are arguments that the AI problem might be solved within a couple of decades. Specialized intelligent systems are actually already pervasive (finger print, handwriting, speech, and face recognition; spam filtering; search engines; computer chess; ....From Universal Induction to Intelligent Systems. The dream of creating artificial devices that (out)reach human intelligence is an old one. What makes this challenge so interesting? A solution would have enormous implications for our society, and there are arguments that the AI problem might be solved within a couple of decades. Specialized intelligent systems are actually already pervasive (finger print, handwriting, speech, and face recognition; spam filtering; search engines; computer chess; robots). This decade the first presumably complete mathematical theory of AI has been proposed. By working out this theory, this project will significantly contribute to the foundations of inductive inference and AI, and ultimately lead to smarter software and intelligent systems.Read moreRead less
Optimising throughput and Delay in network coded systems. This project addresses one main disadvantage of network coding: decoding delay. By solving this issue, we will unlock the true potential of network coding: delivery of high data rates in wireless and wireline networks. This will make network coding an attractive choice for live video streaming and mission-critical delay-sensitive applications.
Physical Layer Security for Wireless Machine-Type Communications. This project aims to provide new understanding and design guidelines to secure wireless communications among low-cost resource-constrained devices. This is achieved by advancing the fundamental theory of an emerging security paradigm named physical layer security. Expected outcomes of this project include a communication-theoretic framework to characterise the secrecy performance of communications over wireless networks, followed ....Physical Layer Security for Wireless Machine-Type Communications. This project aims to provide new understanding and design guidelines to secure wireless communications among low-cost resource-constrained devices. This is achieved by advancing the fundamental theory of an emerging security paradigm named physical layer security. Expected outcomes of this project include a communication-theoretic framework to characterise the secrecy performance of communications over wireless networks, followed by novel signal processing and transmission designs. The research outcomes should provide innovative solutions to safeguard commercial and industry Internet of Things networks, benefiting Australia's digital transformation.Read moreRead less
Non-commutative Fractal Geometry: New Invariants. This project capitilises on Australian strengths in mathematics, particularly non-commutative and fractal geometry. It will maintain and extend Australia's prominence in these subjects, providing excellent training and opportunities for young researchers. Given the wide range of applications of fractals, there is potential for future technological spin offs for Australia.
Development of microwave tomography techniques and inverse methods for biomedical imaging applications. Microwave tomography is a rapidly emerging imaging technology with highly significant applications in industry and medicine. In particular, given its sensitivity to differences between normal and malignant breast tissue, non-invasive microwave imaging has been the subject of intense research interest in the last ten years. In collaboration with workers at Chalmers University in Sweden, we wi ....Development of microwave tomography techniques and inverse methods for biomedical imaging applications. Microwave tomography is a rapidly emerging imaging technology with highly significant applications in industry and medicine. In particular, given its sensitivity to differences between normal and malignant breast tissue, non-invasive microwave imaging has been the subject of intense research interest in the last ten years. In collaboration with workers at Chalmers University in Sweden, we will develop and evaluate a scanning microwave imaging tomographic system with a number of potential industrial and biomedical applications. This appears to be a new Australian initiative.Read moreRead less