Opening a New Era of High-Performance Microwave Devices. We propose a conceptually new method of manufacturing high-performance microwave components at the low-cost and short lead time using liquid form conductors and 3D printing technology. Innovation consists in developing surface roughness free waveguide- and coaxial-based RF and microwave devices, in one-single-piece. This technique can be further extended to create high-performance reconfigurable RF and microwave devices such as filters, an ....Opening a New Era of High-Performance Microwave Devices. We propose a conceptually new method of manufacturing high-performance microwave components at the low-cost and short lead time using liquid form conductors and 3D printing technology. Innovation consists in developing surface roughness free waveguide- and coaxial-based RF and microwave devices, in one-single-piece. This technique can be further extended to create high-performance reconfigurable RF and microwave devices such as filters, antennas, directional couplers, phase shifters and switches by manipulating the locations of the liquid conductors. Furthermore, the method will enable the management of heat generated in high-power applications. Australian telecommunication industry and defence will benefit from the outcome of this project.Read moreRead less
Reconfigurable Conformal Antenna Arrays for Broadband in the Sky Networks. The project aims to develop the theory and technology for a novel type of antennas, namely, reconfigurable conformal antenna arrays, for future broadband in the sky networks (BISNets). BISNets are essential to providing digital services to users on the move and in remote areas. The antenna would be conformal to the surface of the mounting platform, and its elements would be reconfigured in situ to generate the optimum rad ....Reconfigurable Conformal Antenna Arrays for Broadband in the Sky Networks. The project aims to develop the theory and technology for a novel type of antennas, namely, reconfigurable conformal antenna arrays, for future broadband in the sky networks (BISNets). BISNets are essential to providing digital services to users on the move and in remote areas. The antenna would be conformal to the surface of the mounting platform, and its elements would be reconfigured in situ to generate the optimum radiation characteristics to suit the radio environment. It is expected that the project would advance the scientific knowledge of space-borne wireless communications and sensing in general, and antennas in particular, and significantly enhance the performance and reduce the cost of BISNets.Read moreRead less
Micro-electro-mechanical Technologies and Tuneable Millimetre-wave Systems. The project aims to develop background theory and microelectromechanical (MEM)-based techniques for monolithic fabrication that integrate highly miniaturised three-dimensional waveguides with MEM systems. These technologies shall be used to design, develop and fabricate reconfigurable millimetre-wave devices. The project aims to bring together micromachining and millimetre-wave circuits to enable the realisation of recon ....Micro-electro-mechanical Technologies and Tuneable Millimetre-wave Systems. The project aims to develop background theory and microelectromechanical (MEM)-based techniques for monolithic fabrication that integrate highly miniaturised three-dimensional waveguides with MEM systems. These technologies shall be used to design, develop and fabricate reconfigurable millimetre-wave devices. The project aims to bring together micromachining and millimetre-wave circuits to enable the realisation of reconfigurable systems on chip. These technologies offer reduced size, cost and power consumption and high functionality, unachievable with conventional millimetre wave technology alone. The planned outcomes of the project are necessary to satisfy the sharply risen requirements for current and future fourth and fifth generation (4G and 5G) wireless communications systems.Read moreRead less
Digitally controlled mm-wave band selective devices and MEMS technology. This project aims to develop millimetre-wave frequency selective devices with programmable frequency response, using a silicon technology platform. It will design and make an entire radio system, including its tuneable antenna, at the wafer level. Wafer scale integration ensures the devices are compact and low cost, and can be inserted into smart watches for touchless gesture control, and minuscule devices, too small to be ....Digitally controlled mm-wave band selective devices and MEMS technology. This project aims to develop millimetre-wave frequency selective devices with programmable frequency response, using a silicon technology platform. It will design and make an entire radio system, including its tuneable antenna, at the wafer level. Wafer scale integration ensures the devices are compact and low cost, and can be inserted into smart watches for touchless gesture control, and minuscule devices, too small to be connected to the internet today. The project will demonstrate its devices in a wireless communication system operating at unprecedented data rates of over 100 Gb/s. These could transform terrestrial and satellite communication systems and propel Australia to the forefront of wireless communications.Read moreRead less
Novel Architecture for Next Generation Wireless Relay Networks. The proposed project will provide a diverse range of benefits for the nation, by providing future solutions to address a number of key telecommunication networking requirements in Australia. One such area is the provision of broadband connectivity to rural and remote regions of Australia. It is well known, that wireless relay networks could potentially provide low-cost networking infrastructure for rural and remote communities. The ....Novel Architecture for Next Generation Wireless Relay Networks. The proposed project will provide a diverse range of benefits for the nation, by providing future solutions to address a number of key telecommunication networking requirements in Australia. One such area is the provision of broadband connectivity to rural and remote regions of Australia. It is well known, that wireless relay networks could potentially provide low-cost networking infrastructure for rural and remote communities. The solutions developed in this project will enable a wider deployment of such networks, as they would increase the capacity of these networks both in terms of bandwidth and their coverage. This is of major benefit to Australia, due to our large desert land-mass and sparsely populated remote and rural communities.Read moreRead less
Broadband to the bush: Polarization as a new resource in wireless cross-layer design. 'Broadband to the Bush' is a national priority - more than 1.6 million homes, small businesses and not-for-profit organizations in rural, regional, and remote Australia are set to benefit from broadband access to phone networks and the internet. The immediate challenges lie in overcoming poor download speeds and area coverage, as well as expensive access. This research will deliver cost and power-efficient re ....Broadband to the bush: Polarization as a new resource in wireless cross-layer design. 'Broadband to the Bush' is a national priority - more than 1.6 million homes, small businesses and not-for-profit organizations in rural, regional, and remote Australia are set to benefit from broadband access to phone networks and the internet. The immediate challenges lie in overcoming poor download speeds and area coverage, as well as expensive access. This research will deliver cost and power-efficient receiver architectures to provide end-user utility, and will train postgraduate researchers across traditional discipline boundaries in mathematics and engineering. The project represents an important contribution to frontier technologies in information and communications technology for building and transforming Australian industries.Read moreRead less
ARROW - the route to better Photonic Crystal Fibres. The Frontier Technology based on Photonic crystal fibres (PCFs) will be a vital component of next generation photonic networks and devices. Australia is among the 5 leading nations in PCF research. However we are now at a pivotal stage in the development of PCFs: their production is close to maturity, and it is now up to PCF designers to make the difference. The proposed project will provide the Australian scientific community as well as Austr ....ARROW - the route to better Photonic Crystal Fibres. The Frontier Technology based on Photonic crystal fibres (PCFs) will be a vital component of next generation photonic networks and devices. Australia is among the 5 leading nations in PCF research. However we are now at a pivotal stage in the development of PCFs: their production is close to maturity, and it is now up to PCF designers to make the difference. The proposed project will provide the Australian scientific community as well as Australian photonics companies with advanced PCF designing capabilities, giving Australia an opportunity to take a leading position in PCF development and commercialisation. Read moreRead less
Fabrication and design of spun and chiral microstructured fibres. Novel optical fibre devices and especially sensors have established and growing markets in sectors as diverse as medical, aerospace & defence, energy, scientific and process control. This project will build on our existing success in developing microstructured polymer optical fibres (mPOF), and create major new opportunities, both in fundamental science and in applications that could be commercialised. Australia is currently leadi ....Fabrication and design of spun and chiral microstructured fibres. Novel optical fibre devices and especially sensors have established and growing markets in sectors as diverse as medical, aerospace & defence, energy, scientific and process control. This project will build on our existing success in developing microstructured polymer optical fibres (mPOF), and create major new opportunities, both in fundamental science and in applications that could be commercialised. Australia is currently leading the world in mPOF. This project builds on these past successes but moves beyond telecommunications into biophotonics with potential applications in magnetic field sensors, biological sensors, optical tweezers, polarisation emulators and new types of linear and nonlinear modes. Read moreRead less
Terabit mm-Wave Backbones for Integrated Space and Terrestrial Networks. This project aims to develop the theory and enabling techniques to achieve high-speed millimeter wave (mm-wave) backbones for integrated space and terrestrial networks. New scientific breakthroughs will be in fundamental transmission theory, efficient self-interference cancellation and spatial multiplexing techniques using hybrid antenna arrays. These will enable Terabits per second wireless transmission that is 10 times fa ....Terabit mm-Wave Backbones for Integrated Space and Terrestrial Networks. This project aims to develop the theory and enabling techniques to achieve high-speed millimeter wave (mm-wave) backbones for integrated space and terrestrial networks. New scientific breakthroughs will be in fundamental transmission theory, efficient self-interference cancellation and spatial multiplexing techniques using hybrid antenna arrays. These will enable Terabits per second wireless transmission that is 10 times faster than current technologies. A proof-of-concept prototype will be developed to demonstrate the feasibility and performance of the new system architecture and algorithms, thus paving the way for commercialisation. The developed technology will enhance Australia’s information infrastructure as well as defence capacity.Read moreRead less
Optimisation-based analysis and synthesis of sparse systems in signal processing and communication. This project will make onceptual advances in the areas of signal processing and communication. A major benefit of this project will be its direct applications to digital industry - perhaps the major electrical industry of our era. The project will also aim to build a world class research activity at the University of New South Wales to focus attention on low-cost signal processing and communicatio ....Optimisation-based analysis and synthesis of sparse systems in signal processing and communication. This project will make onceptual advances in the areas of signal processing and communication. A major benefit of this project will be its direct applications to digital industry - perhaps the major electrical industry of our era. The project will also aim to build a world class research activity at the University of New South Wales to focus attention on low-cost signal processing and communication, increase capacity for contract research, enhance nternational collaboration with leading researchers in the area, and produce quality PhD graduates in the field of signal processing and communication.Read moreRead less