Sensing and Communications for Tactical Radio: Mapping the RF Weather. This project investigates sensing, localisation and communication strategies to improve the performance of modern tactical radio networks. Such networks face all of the well-known design challenges of mobile ad-hoc networks (MANETs) but with added complication of a contested and adversarial operating environment. By exploiting the power of radio nodes to sense the radio spectrum, as well as to communicate over it, a distribut ....Sensing and Communications for Tactical Radio: Mapping the RF Weather. This project investigates sensing, localisation and communication strategies to improve the performance of modern tactical radio networks. Such networks face all of the well-known design challenges of mobile ad-hoc networks (MANETs) but with added complication of a contested and adversarial operating environment. By exploiting the power of radio nodes to sense the radio spectrum, as well as to communicate over it, a distributed network of nodes can create a detailed picture of the surrounding radio-frequency (RF) environment: the nodes can work together to map the “RF weather”. In this project we will design advanced sensing and localisation methods to accurately map the RF spectrum, and then exploit this map in communication system design.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
Airborne Base Station Communication Systems: Capacity and Optimization. This project will fundamentally characterise and optimize information gathering, dissemination, and communication capacities of airborne base stations to enable low latency communications in rural and remote areas. New technologies such as precision farming, safe remote equipment operation in mining, and wide area surveillance and security, require low latency communications that are an order of magnitude beyond what is curr ....Airborne Base Station Communication Systems: Capacity and Optimization. This project will fundamentally characterise and optimize information gathering, dissemination, and communication capacities of airborne base stations to enable low latency communications in rural and remote areas. New technologies such as precision farming, safe remote equipment operation in mining, and wide area surveillance and security, require low latency communications that are an order of magnitude beyond what is currently available from satellite links. The expected outcome will be radically new base station deployment and flight path planning, and data transmission technologies. These will unlock new application technologies by enabling secure wide-spread communications coverage, delivering economic benefits to remote Australia.Read moreRead less
Empowering terahertz sources with silicon antennas. This Project aims to create dielectric antennas for high-frequency terahertz sources, i.e., resonant tunnelling diodes. Motivated by their end-use, the Project expects to deliver high-efficiency, high-gain low-profile cavity antennas for free-space operation and Yagi-Uda couplers for guided-mode operation. Silicon will be a key material for both types of terahertz structures to achieve highest efficiency. Effective medium theory will enable per ....Empowering terahertz sources with silicon antennas. This Project aims to create dielectric antennas for high-frequency terahertz sources, i.e., resonant tunnelling diodes. Motivated by their end-use, the Project expects to deliver high-efficiency, high-gain low-profile cavity antennas for free-space operation and Yagi-Uda couplers for guided-mode operation. Silicon will be a key material for both types of terahertz structures to achieve highest efficiency. Effective medium theory will enable performance, functionality, and integrability, while maintaining structural simplicity for cost benefits. The expected outcomes will replace decades-old costly hyper-hemispherical lenses for future terahertz systems in fixed wireless backbone beyond 5G and short-range see-through radar and imaging.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100651
Funder
Australian Research Council
Funding Amount
$414,000.00
Summary
Intelligent Backscatter Communications for Green and Secure IoT Networks . This project aims to develop novel technologies empowered by intelligent radio wave backscatter to address the significant problem of connecting a very large number of wireless devices with low energy consumption and limited communication channels for future Internet-of-Things (IoT) networks. This project expects to advance knowledge in the area of green communications by utilising ambient backscatter, a breakthrough wire ....Intelligent Backscatter Communications for Green and Secure IoT Networks . This project aims to develop novel technologies empowered by intelligent radio wave backscatter to address the significant problem of connecting a very large number of wireless devices with low energy consumption and limited communication channels for future Internet-of-Things (IoT) networks. This project expects to advance knowledge in the area of green communications by utilising ambient backscatter, a breakthrough wireless communications technology. This will significantly reduce energy costs, enhance spectrum usage efficiency, and improve communication security thus greatly benefiting Australian industry, society and economy. Expected outcomes of the project include key technologies that promote the development of future IoT networks.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
Scaling Up Satellite Communications for the Internet of Things. The Internet of Things (IoT) is a revolution in sensing and automation that is becoming vital for industries including farming and mining. However, in remote areas, it is especially challenging to connect the large numbers of devices needed. This project will develop novel signal processing and communications approaches to deliver high quality data services to vast numbers of remote IoT devices, distributed over continental scales c ....Scaling Up Satellite Communications for the Internet of Things. The Internet of Things (IoT) is a revolution in sensing and automation that is becoming vital for industries including farming and mining. However, in remote areas, it is especially challenging to connect the large numbers of devices needed. This project will develop novel signal processing and communications approaches to deliver high quality data services to vast numbers of remote IoT devices, distributed over continental scales connected via low earth orbit (LEO) satellite constellations. It will provide the tools for LEO satellite service providers to dimension their networks and assist IoT providers to scale their remote sensor networks and IoT deployments, with ever increasing demand on the limited satellite bandwidth.Read moreRead less
Photonics Platform to Transform Mobile Fronthaul Infrastructure. Future wireless systems of mobile networks and defence platforms will need to offer high-speed, low-delay, reliable connectivity and high bandwidth. With the explosive growth of wireless systems, this creates significant challenges in fronthaul - the link connecting antennas with the signal processors and core network. This project aims to design and develop an innovative fronthaul for wireless systems based on a dynamically reconf ....Photonics Platform to Transform Mobile Fronthaul Infrastructure. Future wireless systems of mobile networks and defence platforms will need to offer high-speed, low-delay, reliable connectivity and high bandwidth. With the explosive growth of wireless systems, this creates significant challenges in fronthaul - the link connecting antennas with the signal processors and core network. This project aims to design and develop an innovative fronthaul for wireless systems based on a dynamically reconfigurable, software-defined photonic platform capable of meeting diverse requirements. The outcomes of this project will help build a scalable fronthaul solution to overcome fundamental challenges and realise cost-effective pathways for transforming how future wireless networks and defence platforms are realised.Read moreRead less
Object-based motion estimation for highly efficient streaming video. This project aims to develop motion and shape estimation tools that allow video content to be predicted at any point in time using frame data that is available at other points in time. Applications of this include video coding, frame synthesis for temporal re-sampling. The project expects to develop algorithms for jointly estimating compact motion and shape descriptions of video content. These descriptions will allow quality re ....Object-based motion estimation for highly efficient streaming video. This project aims to develop motion and shape estimation tools that allow video content to be predicted at any point in time using frame data that is available at other points in time. Applications of this include video coding, frame synthesis for temporal re-sampling. The project expects to develop algorithms for jointly estimating compact motion and shape descriptions of video content. These descriptions will allow quality refinement by progressively adding spatial and temporal detail. It is expected that these compact descriptions will lead to significantly more flexible and efficient transmission of video content over modern communications networks.Read moreRead less
Novel Techniques for Uncoordinated Massive Access in the Internet of Things. The IoT (internet of things) is the backbone of intelligent transportation, healthcare, energy and smart home systems. To accommodate the exponentially increasing number of IoT devices, a dramatic paradigm shift towards non-orthogonal uncoordinated (grant-free) massive access is underway, where devices transmit data opportunistically over shared channel resources. This project aims to develop new receivers for such unc ....Novel Techniques for Uncoordinated Massive Access in the Internet of Things. The IoT (internet of things) is the backbone of intelligent transportation, healthcare, energy and smart home systems. To accommodate the exponentially increasing number of IoT devices, a dramatic paradigm shift towards non-orthogonal uncoordinated (grant-free) massive access is underway, where devices transmit data opportunistically over shared channel resources. This project aims to develop new receivers for such uncoordinated massive access, where the receivers will be trained to identify transmitting devices, recover their data, and resolve any collisions. These outcomes are expected to emerge as a game changer in IoT communications, benefiting national and international industry to meet future telecommunications needs for the IoT.Read moreRead less