Dynamic phased array antennas for terahertz detection and ranging. The project aims to create reciprocal electrically-tuneable phased array antennas for terahertz waves. The antennas will comprise varactor diodes, analogue phase shifters, and dielectric resonator arrays to rapidly transmit and receive beams with high directivity and performance. The intended outcome is an integrated platform for short-range terahertz detection and ranging. This platform could be used in personal radar and drone- ....Dynamic phased array antennas for terahertz detection and ranging. The project aims to create reciprocal electrically-tuneable phased array antennas for terahertz waves. The antennas will comprise varactor diodes, analogue phase shifters, and dielectric resonator arrays to rapidly transmit and receive beams with high directivity and performance. The intended outcome is an integrated platform for short-range terahertz detection and ranging. This platform could be used in personal radar and drone-based radar, and high-contrast standoff detection. The project could benefit public security and welfare.Read moreRead less
Safeguarding Future Wireless Communications with Physical Layer Security. Wireless communication is vulnerable to eavesdropping attacks since the transmitted signal enters an open wireless medium allowing anyone to overhear it. This project tackles the challenging problem of secure wireless transmissions through the advancement of a new security technology termed physical layer security. Theoretical frameworks are expected to be developed to understand how this new technology extracts the intri ....Safeguarding Future Wireless Communications with Physical Layer Security. Wireless communication is vulnerable to eavesdropping attacks since the transmitted signal enters an open wireless medium allowing anyone to overhear it. This project tackles the challenging problem of secure wireless transmissions through the advancement of a new security technology termed physical layer security. Theoretical frameworks are expected to be developed to understand how this new technology extracts the intrinsic security from the wireless medium to protect the confidentiality of information transmission. The research outcome is expected to provide for innovative solutions to safeguard Australia's future commercial, government and military wireless networks, and to give pivotal insights into the impact of this new technology on national security.Read moreRead less
Teaching old dogs new tricks: making ordinary glass both guide and modulate light in photonic chips. The continued revolution of telecoms, and other industries, by photonics demands active integrated photonics: chips that can switch, modulate and modify light. Currently this requires problematic materials. This project will innovatively combine breakthroughs in two areas: poling and laser writing, to produce active devices in standard silicate glass chips.
Supervised autonomy for autonomous underwater vehicles (AUVs) using limited bandwidth communication channels. The project aims to improve the feedback link between an autonomous underwater vehicle (AUV) and an operator by developing novel acoustic communication schemes that exploit developments in machine learning, network, and communication theory and represents a step towards truly autonomous and intelligent surveying using AUV systems.
Breaking bandwidth barriers: Non-volatile tuneable terahertz metamaterials. This project aims to investigate non-volatile tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tuneable metamaterial-based THz devices, such as filters and modulators, could generate significant downstream intellectual property for wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth between desktop devices. Expected outcomes inc ....Breaking bandwidth barriers: Non-volatile tuneable terahertz metamaterials. This project aims to investigate non-volatile tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tuneable metamaterial-based THz devices, such as filters and modulators, could generate significant downstream intellectual property for wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth between desktop devices. Expected outcomes include understanding the interaction between THz signals and phase change materials, tuneable metamaterials, and devices that can steer and modulate THz signals with unprecedented agility and compactness, enabling future high-bandwidth Bluetooth-like data transfer.Read moreRead less
Nonlinear optical effects with low-power non-laser light. This project aims to allow the use of low-cost, low-intensity light sources, such as light-emitting diodes and discharge lamps, to generate nonlinear optical signals in photonic devices. Nonlinear optical effects are vital for telecommunication and signal processing technologies and are presently possible only when the light is produced by a high-power laser. The expected outcome of this project is a theoretical and experimental framework ....Nonlinear optical effects with low-power non-laser light. This project aims to allow the use of low-cost, low-intensity light sources, such as light-emitting diodes and discharge lamps, to generate nonlinear optical signals in photonic devices. Nonlinear optical effects are vital for telecommunication and signal processing technologies and are presently possible only when the light is produced by a high-power laser. The expected outcome of this project is a theoretical and experimental framework that would underpin the development of a new nonlinear photonic technology that does not require lasers, representing a paradigm shift in how photonic devices are designed. This should benefit sensing, telecommunications and defence by cheaper and more efficient transmission of information via media such as the National Broadband Network.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100420
Funder
Australian Research Council
Funding Amount
$394,704.00
Summary
Large Scale Multiple Antennas for Energy-Efficient Heterogeneous Wireless Networks. This project investigates new network architectures for future wireless broadband inspired by recent advances in large scale multiple antenna technology and heterogeneous networks. The aim is to support flexible and scalable wireless services across diverse network regions with energy-efficient management of radio spectrum and interference. Targeted applications include smart energy metering, intelligent transpor ....Large Scale Multiple Antennas for Energy-Efficient Heterogeneous Wireless Networks. This project investigates new network architectures for future wireless broadband inspired by recent advances in large scale multiple antenna technology and heterogeneous networks. The aim is to support flexible and scalable wireless services across diverse network regions with energy-efficient management of radio spectrum and interference. Targeted applications include smart energy metering, intelligent transport systems, mobile health monitoring and green data centres. Outcomes of the research will be new wireless protocols and algorithms drawing upon the foundations of random matrix theory, game theory and large system analysis, which will offer fundamental insights into large scale multiple antennas for heterogeneous wireless networks.Read moreRead less
Telematics: Research & Development of Mobile Link for Telemedicine. This project is aimed at producing a reliable mobile video link between ambulance and hospital. In an emergency situation, video footage greatly assists the medical team in accurate deployment of resources to save lives. Motorola will be the industrial partner and this mobile telemedicine project fits into their telematics core business area. Together with Motorola, we will investigate video coding schemes, protocols and network ....Telematics: Research & Development of Mobile Link for Telemedicine. This project is aimed at producing a reliable mobile video link between ambulance and hospital. In an emergency situation, video footage greatly assists the medical team in accurate deployment of resources to save lives. Motorola will be the industrial partner and this mobile telemedicine project fits into their telematics core business area. Together with Motorola, we will investigate video coding schemes, protocols and network issues, to produce a commercially viable software/hardware solution. The outcome will be a working testbed that can be trialed at the Royal Adelaide Hospital. The IP generated will benefit Motorola's telematics directive and training will generate a potentially useful future employee.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100137
Funder
Australian Research Council
Funding Amount
$365,000.00
Summary
Efficient and sustainable wireless powered communication networks. This project aims to enable efficient wireless energy transfer and data communication for wireless powered communication (WPC) networks. WPC is a key technology to unlock the potential of Internet-of-Things (IoT) via prolonging the lifetime of energy-limited wireless communication devices. This project will design and develop a proof-of-concept WPC test-bed to evaluate and verify the proposed technologies. The outcomes of the pro ....Efficient and sustainable wireless powered communication networks. This project aims to enable efficient wireless energy transfer and data communication for wireless powered communication (WPC) networks. WPC is a key technology to unlock the potential of Internet-of-Things (IoT) via prolonging the lifetime of energy-limited wireless communication devices. This project will design and develop a proof-of-concept WPC test-bed to evaluate and verify the proposed technologies. The outcomes of the project are expected to advance the knowledge of WPC networks and contribute a new type of wireless infrastructure, as an essential part of the emerging digital society.Read moreRead less
Design of future cognitive radio relay networks. The project will aim to make fundamental advances in the design of spectrum-efficient cognitive radio relay networks. This will be facilitated by novel designs using game theory, multiple-antenna and cooperative relaying technologies. These designs will be essential to the future development of spectrum-efficient wireless communications.