Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453561
Funder
Australian Research Council
Funding Amount
$336,706.00
Summary
Integrated Precision Machining of Complex Profiles. High precision and high speed machining is of central importance to the development of a wide range of frontier technologies such as precision manufacturing, nano-materials fabrication, semiconductor and composite processing, vehicle production and steel structure manufacturing. The research significance has been well established by the world-leading projects and achievements. The proposed facility has distinct features and capability of high l ....Integrated Precision Machining of Complex Profiles. High precision and high speed machining is of central importance to the development of a wide range of frontier technologies such as precision manufacturing, nano-materials fabrication, semiconductor and composite processing, vehicle production and steel structure manufacturing. The research significance has been well established by the world-leading projects and achievements. The proposed facility has distinct features and capability of high loop-stiffness, high repeatability, universal profiling, organic integration of key machining operations, and great flexibility of both low and high speeds. These unique characteristics will enable the innovative development of many research programs which will otherwise be impossible to achieve.Read moreRead less
High-Performance Microwave and Millimetre Wave Antennae Based on Multi-layer Periodic Structures. Broadband communication has created a rapidly growing market for innovative microwave communication systems such as WiFi and WiMAX. Millimetre-wave technology is expected to deliver the next leap in communication technology with much faster wireless links for 3D TV etc. By developing innovative, low-cost, planar antennas with high performance, the proposed research will create opportunities for Aust ....High-Performance Microwave and Millimetre Wave Antennae Based on Multi-layer Periodic Structures. Broadband communication has created a rapidly growing market for innovative microwave communication systems such as WiFi and WiMAX. Millimetre-wave technology is expected to deliver the next leap in communication technology with much faster wireless links for 3D TV etc. By developing innovative, low-cost, planar antennas with high performance, the proposed research will create opportunities for Australian industry to compete in this growing global market with advanced, cost-effective, microwave and millimetre-wave products. The Australian research community will benefit from new methods, techniques and trained researchers, while Australian consumers will benefit from improved quality and low cost of services.Read moreRead less
Hybrid-resonator antennas for wireless communication networks. The rapid emergence of modern wireless communication systems has led to a requirement for small, lightweight antennas. In this project, a new, broadband, low-cost, small and lightweight antenna architecture will be developed for wireless systems. The new architecture is based on a novel hybrid-resonator concept: a dielectric resonator tightly coupled to a metal patch resonator. The rapid design and optimisation of new antennas will b ....Hybrid-resonator antennas for wireless communication networks. The rapid emergence of modern wireless communication systems has led to a requirement for small, lightweight antennas. In this project, a new, broadband, low-cost, small and lightweight antenna architecture will be developed for wireless systems. The new architecture is based on a novel hybrid-resonator concept: a dielectric resonator tightly coupled to a metal patch resonator. The rapid design and optimisation of new antennas will be achieved by developing several new theoretical methods. Antennas targeted for the Unlicensed National Information Infrastructure (UNII) band (5-6 GHz) commercial wireless communication systems will be designed, fabricated, tested and integrated with the systems.
Read moreRead less
Integration of Wireless LAN and GPRS/UMTS Cellular Systems. Integration of wireless local area networks with cellular mobile systems provides a feasible, reliable, and cost-effective way for high-speed mobile Internet access in wide area networks. In this project in collaboration with Australia's second largest telecommunications company; Optus, we will develop network architecture and essential access and mobility techniques for such a system. The project's outcomes will enable Optus to expand ....Integration of Wireless LAN and GPRS/UMTS Cellular Systems. Integration of wireless local area networks with cellular mobile systems provides a feasible, reliable, and cost-effective way for high-speed mobile Internet access in wide area networks. In this project in collaboration with Australia's second largest telecommunications company; Optus, we will develop network architecture and essential access and mobility techniques for such a system. The project's outcomes will enable Optus to expand its broadband mobile Internet service to all parts and population of the country including rural and regional areas and subsequently export the breakthrough technology resulted from the project to overseas.Read moreRead less
Broadband and Multiband Antenna Systems. Wireless communication has become essential in the modern information society and this has created a rapidly growing, multi-billion dollar market for innovative wireless products. Australia has a strong potential to gain from this market, as demonstrated by world-leading products, e.g. wireless computer microchips. By developing innovative antenna systems with new capabilities, the proposed research will create opportunities for Australian industry to com ....Broadband and Multiband Antenna Systems. Wireless communication has become essential in the modern information society and this has created a rapidly growing, multi-billion dollar market for innovative wireless products. Australia has a strong potential to gain from this market, as demonstrated by world-leading products, e.g. wireless computer microchips. By developing innovative antenna systems with new capabilities, the proposed research will create opportunities for Australian industry to compete in the global wireless market with advanced, low-cost, high-performance, and universal products. The Australian research community will benefit from new theoretical techniques and trained researchers, while wireless users will benefit from improved quality and low cost of services.Read moreRead less
Channel Adaptive Space-Time (CAST) Coding and Processing for Wireless Downlink Packet Services. Recently, the capacity of the broadcast channel with multiple antennas is investigated. Various space-time (ST) processing techniques to adapt channel conditions are utilized to increase capacity. Precoding becomes vital to deal with interferers and cooperation problems efficiently. ST codes will be investigated in conjunction with precoding. We aim to investigate channel adaptive ST coding and precod ....Channel Adaptive Space-Time (CAST) Coding and Processing for Wireless Downlink Packet Services. Recently, the capacity of the broadcast channel with multiple antennas is investigated. Various space-time (ST) processing techniques to adapt channel conditions are utilized to increase capacity. Precoding becomes vital to deal with interferers and cooperation problems efficiently. ST codes will be investigated in conjunction with precoding. We aim to investigate channel adaptive ST coding and precoding techniques to achieve the maximum capacity with practical quality of service requirements. Although the capacity is extensively investigated, implementation methods are relatively less investigated. This project is to fill the cap between implementation (ST coding and precoding methods as outcomes) and theory (capacity analysis).Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100068
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Bioinspired liposome-based smart sensors. This project aims to develop a liposome-based biosensor technology that mimics cell sensory systems. Selective detection of compounds is increasingly important for food, health and environmental monitoring. Biosensor development faces long-standing challenges such as response time, sensitivity, specificity, and multiplexing. On the other hand, cells can sense and discriminate multiple biomolecules in seconds with high sensitivity and specificity. This pr ....Bioinspired liposome-based smart sensors. This project aims to develop a liposome-based biosensor technology that mimics cell sensory systems. Selective detection of compounds is increasingly important for food, health and environmental monitoring. Biosensor development faces long-standing challenges such as response time, sensitivity, specificity, and multiplexing. On the other hand, cells can sense and discriminate multiple biomolecules in seconds with high sensitivity and specificity. This project aims to harness cells’ exquisite biological properties to improve current detection techniques. It will integrate liposome-based sensors with microfluidics to perform analytical tasks ranging from food safety to diagnostics.Read moreRead less
Novel Multistage and Iterative Receivers for Wireless Communication Systems. The project is set up to develop novel detection techniques with the aim of improving the reliability and capacity in a range of wireless telecommunications services. Potential applications of the project outcomes are in cellular mobile, wireless LANs and mobile computing.
Adaptive Turbo Receivers for Mobile Data Communications. Next generation mobile networks will be required to offer high data-rate high mobility communications, in addition to current voice services. This project will determine the bounds of achievable performance of such networks by developing and analysing new optimal and near optimal adaptive receivers. In particular we will extend a revolutionary new technique called turbo processing, to achieve joint equalization and decoding with unknown ....Adaptive Turbo Receivers for Mobile Data Communications. Next generation mobile networks will be required to offer high data-rate high mobility communications, in addition to current voice services. This project will determine the bounds of achievable performance of such networks by developing and analysing new optimal and near optimal adaptive receivers. In particular we will extend a revolutionary new technique called turbo processing, to achieve joint equalization and decoding with unknown rapidly time varying channels. The overall aim is to dramatically improve mobility and throughput of wireless data communication systems.Read moreRead less
Space-Time Coding and Receiver Structures for High Speed Wireless Communications. The aims of the project are to to devise space-time coding techniques and cost effective receiver structures for applications in future wireless data networks. We expect that new space-time codes would enable an increase in spectral efficiency by two orders of magnitude compared with the existing systems and allow the introduction of advanced multimedia services.