Discovery Early Career Researcher Award - Grant ID: DE170101203
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Multi-functional antenna arrays for secure and reliable wireless systems. This project aims to develop and validate the fundamental theory and engineering techniques for fully reconfigurable antenna arrays. Multi-functional antennae deliver highly-secure and reliable wireless communications for Australia’s digital economy. Such an antenna array, a critical component of wireless multi-functional systems, can provide full flexibilities of the frequency, polarisation and radiation pattern to satisf ....Multi-functional antenna arrays for secure and reliable wireless systems. This project aims to develop and validate the fundamental theory and engineering techniques for fully reconfigurable antenna arrays. Multi-functional antennae deliver highly-secure and reliable wireless communications for Australia’s digital economy. Such an antenna array, a critical component of wireless multi-functional systems, can provide full flexibilities of the frequency, polarisation and radiation pattern to satisfy the systems’ different requirements. This project is expected to advance the scientific knowledge of several frontiers of antenna research and enhance spectrum usage efficiency, highly-secure wireless communications and compact and reliable military wireless platforms, thus benefiting Australian industry, society and national defence.Read moreRead less
Running Hot: Increasing the Availability of World-Class Precision Timing . Precision clocks are a key enabler for many important technologies including navigation, radar, distributed computing and communications. Unfortunately, the very best clocks are currently bulky and very expensive. This project will take Australia’s multi-award winning sapphire clock technology and transform it so that its unmatched performance is available from a unit with an order of magnitude smaller size, power consum ....Running Hot: Increasing the Availability of World-Class Precision Timing . Precision clocks are a key enabler for many important technologies including navigation, radar, distributed computing and communications. Unfortunately, the very best clocks are currently bulky and very expensive. This project will take Australia’s multi-award winning sapphire clock technology and transform it so that its unmatched performance is available from a unit with an order of magnitude smaller size, power consumption and cost. This transformation will be driven on the back of a patented revolutionary step that allows operation of the sapphire clock at higher cryogenic temperatures. The new clock will have a wider range of applications delivering more computational power, higher bandwidth transmissions and better radar. Read moreRead less
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
Robust signal processing theory for synthesis and analysis of spatial wavefields. This project will develop breakthrough signal processing techniques applied to wireless communication, defence and surveillance, entertainment systems, and acoustic imaging. The outcomes will produce new products. The project will also provide high quality research training for gifted postgraduate students and postdoctoral researchers.
New multi-function wideband microwave and radio frequency signal conditioning based on photonic approaches. The demand for more bandwidth, more functionality and higher sensitivity creates unprecedented challenges for optimally conditioning wideband signals. The project leverages breakthroughs in photonics to develop new programmable microwave processors, with benefits to Australia in radar/antenna systems for defence and broadband wireless networks.
On-chip radio frequency photonics for advanced signal processing. This project proposes new integrated photonic modules to tackle challenges in on-chip photonic processing of wideband radio frequency signals. It will develop enhanced electromagnetically induced transparency for RF frequency filtering, compact all-in-one phase shifter for adaptive beamforming and programmable signal processing, and distributed and cascaded signal processing functions in photonic links. The outcomes are new high-p ....On-chip radio frequency photonics for advanced signal processing. This project proposes new integrated photonic modules to tackle challenges in on-chip photonic processing of wideband radio frequency signals. It will develop enhanced electromagnetically induced transparency for RF frequency filtering, compact all-in-one phase shifter for adaptive beamforming and programmable signal processing, and distributed and cascaded signal processing functions in photonic links. The outcomes are new high-performance integrated microwave photonic signal processors, which will enhance the generation, processing, and distribution of microwave and millimetre-wave signals in radio astronomy, wireless and satellite communications, and produce significant improvements in radar/antenna systems.Read moreRead less
Passive Positioning and Tracking of Flying Objects Using Satellite Signals. Along with the deployment of low Earth orbit satellite constellations for global satellite Internet services, such as Starlink, Ku/Ka/V band microwave signals from space will be available anywhere on Earth 24/7. Utilising the microwave signals, this project aims to investigate a high-resolution cost-effective solution to position and track un-cooperative flying objects, and expects to generate new knowledge in the area o ....Passive Positioning and Tracking of Flying Objects Using Satellite Signals. Along with the deployment of low Earth orbit satellite constellations for global satellite Internet services, such as Starlink, Ku/Ka/V band microwave signals from space will be available anywhere on Earth 24/7. Utilising the microwave signals, this project aims to investigate a high-resolution cost-effective solution to position and track un-cooperative flying objects, and expects to generate new knowledge in the area of remote sensing and to make Australia the leader in passive flying objects positioning and tracking. This should provide significant benefits, such as enabling new applications for future drone delivery systems or aerial taxi services, and benefiting the air transport industry, the defence industry, and bird conservation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100413
Funder
Australian Research Council
Funding Amount
$384,000.00
Summary
Hybrid nanowire-nanoantenna infrared photodetectors. This project aims to demonstrate room temperature hybrid nanowire-nanoantenna infrared photodetectors by integrating plasmonic nanoantennas on semiconductor nanowire arrays. It is expected that such novel device architectures will not only bring enhanced performance in responsivity, detectivity, and photoresponse bandwidth, but also additional functionalities such as selective wavelength and tunable polarisation, which may significantly outper ....Hybrid nanowire-nanoantenna infrared photodetectors. This project aims to demonstrate room temperature hybrid nanowire-nanoantenna infrared photodetectors by integrating plasmonic nanoantennas on semiconductor nanowire arrays. It is expected that such novel device architectures will not only bring enhanced performance in responsivity, detectivity, and photoresponse bandwidth, but also additional functionalities such as selective wavelength and tunable polarisation, which may significantly outperform current infrared technology. The outcomes will provide a new device platform for next-generation, large-scale, reduced-cost, high-performance imaging systems in self-driving navigation, object identification, spectroscopy, and other high-end defence and civilian applications.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