Integrated Sensing and Communication for 6G Wireless Networks. The project aims to investigate the open challenging research problems for realising high-speed sixth-generation wireless networks with seamless networked sensing capabilities via integrated sensing and communication (ISAC). The significance of this project is expected to generate new knowledge of ISAC exploiting advanced communication theory, signal processing theory and optimisation theory. Expected outcomes of this project include ....Integrated Sensing and Communication for 6G Wireless Networks. The project aims to investigate the open challenging research problems for realising high-speed sixth-generation wireless networks with seamless networked sensing capabilities via integrated sensing and communication (ISAC). The significance of this project is expected to generate new knowledge of ISAC exploiting advanced communication theory, signal processing theory and optimisation theory. Expected outcomes of this project include pragmatic robust beamforming, joint channel and sensing parameters estimation, resource allocation designs and a system-level analysis as the foundations and tools to unleash the full potential of ISAC. These should provide significant economic benefits to wireless service providers and mobile users worldwide.Read moreRead less
Intelligent Reflecting Surface-enabled High-speed 6G Wireless Networks. Intelligent reflecting surface (IRS) is a ground-breaking wireless technology essential for the development of future sixth-generation (6G) wireless communication networks. This project aims to develop fundamental communication theories and practical solutions to characterise and optimise IRS-based communication. The project expects to design novel channel estimation, robust beamforming, resource allocation and analytical fr ....Intelligent Reflecting Surface-enabled High-speed 6G Wireless Networks. Intelligent reflecting surface (IRS) is a ground-breaking wireless technology essential for the development of future sixth-generation (6G) wireless communication networks. This project aims to develop fundamental communication theories and practical solutions to characterise and optimise IRS-based communication. The project expects to design novel channel estimation, robust beamforming, resource allocation and analytical framework to address the significant scientific challenges for the development of IRS for enabling high-speed 6G networks. These outcomes are expected to contribute to a new type of wireless infrastructure which paves the way for building and transforming the Australian information and communications technology industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100787
Funder
Australian Research Council
Funding Amount
$435,450.00
Summary
Multi-Beam and Beam-Scanning Antenna Arrays for Intelligent Wireless System. This project aims to develop and validate the fundamental theory and pioneering multi-beam and beam-scanning transmissive and reflective antenna arrays for intelligent wireless systems. Advanced engineering methodologies will be developed to address the related technical challenges. The expected outcomes are multi-beam antenna supporting frequency-polarization multiplexed communication and two-dimensional dual-beam scan ....Multi-Beam and Beam-Scanning Antenna Arrays for Intelligent Wireless System. This project aims to develop and validate the fundamental theory and pioneering multi-beam and beam-scanning transmissive and reflective antenna arrays for intelligent wireless systems. Advanced engineering methodologies will be developed to address the related technical challenges. The expected outcomes are multi-beam antenna supporting frequency-polarization multiplexed communication and two-dimensional dual-beam scanning systems with continuous scan capability over a wide angular range. The developed low-cost and fully passive antennas will significantly improve the information capacity of the wireless network, providing reliable and highly secure wireless communication.Read moreRead less
Leaky Dielectric Platform for Integrated Terahertz Components. This project aims to realise integrated terahertz components including programmable filters, compact spectrometers, frequency-scanning antennas, and broadband/broadside high-gain antennas. These components are crucial in emerging terahertz integration for field applications and will supersede decades-old bulky free-space terahertz counterparts. Silicon will be a key material for all of these terahertz structures to achieve tunability ....Leaky Dielectric Platform for Integrated Terahertz Components. This project aims to realise integrated terahertz components including programmable filters, compact spectrometers, frequency-scanning antennas, and broadband/broadside high-gain antennas. These components are crucial in emerging terahertz integration for field applications and will supersede decades-old bulky free-space terahertz counterparts. Silicon will be a key material for all of these terahertz structures to achieve tunability and highest efficiency. Effective medium theory will enable performance, functionality, integrability, and structural simplicity. The expected outcomes are building blocks towards high-speed 6G infrastructure and high-resolution stand-off sensing to reap economic benefits at the dawn of terahertz engineering.Read moreRead less
Ultra-Fast and Secure Terahertz Communications for 6G Wireless Systems. This project aims to develop new theories and signal processing solutions for the cutting-edge technology of terahertz communications to enable the revolutionary sixth-generation wireless systems, by exploring and optimising the inherent benefits of the terahertz band. Anticipated outcomes are new analytical tools and practical guidelines for designing ultra-fast and secure wireless transmission at an unprecedented speed up ....Ultra-Fast and Secure Terahertz Communications for 6G Wireless Systems. This project aims to develop new theories and signal processing solutions for the cutting-edge technology of terahertz communications to enable the revolutionary sixth-generation wireless systems, by exploring and optimising the inherent benefits of the terahertz band. Anticipated outcomes are new analytical tools and practical guidelines for designing ultra-fast and secure wireless transmission at an unprecedented speed up to terabits per second (Tbps). This enables various emerging applications, such as holographic telepresence, Tbps WiFi and Tbps wireless data centres, to drive transformation in the telecommunications sector, boost industry productivity and support our intelligent information society in the 2030s.Read moreRead less
Resilient Remote Environment Emulation for Human-to-Machine Communication. Human-to-machine haptic communication allow humans to immersively interact with remotely-located robots/machines. Current networks cannot support its technical demands, thereby limiting the achievable human-machine distance. This project aims to develop cloudlet intelligence together with a programmable resilient network to realise reliable remote environment emulation, a concept where the physical environment at the remo ....Resilient Remote Environment Emulation for Human-to-Machine Communication. Human-to-machine haptic communication allow humans to immersively interact with remotely-located robots/machines. Current networks cannot support its technical demands, thereby limiting the achievable human-machine distance. This project aims to develop cloudlet intelligence together with a programmable resilient network to realise reliable remote environment emulation, a concept where the physical environment at the remote machine is emulated close to the human. A key outcome will be the first reliable remote environment emulation platform that achieves vast human-machine distances on current networks. Enabling immersive human-machine experience will significantly benefit many sectors, from education through to industrial manufacturing.Read moreRead less
Next-Generation Solvers for Complex Microwave Engineering Problems. This project aims to design a complementary physics-guided, data-driven method that can accurately solve complex microwave engineering problems in a timely manner. The primary bottleneck so far preventing that approach, which is the disparity between the trained theoretical model and reality, will be overcome using a multi-frequency complex-valued domain adaptation technique. The method will use deep neural networks to reliably ....Next-Generation Solvers for Complex Microwave Engineering Problems. This project aims to design a complementary physics-guided, data-driven method that can accurately solve complex microwave engineering problems in a timely manner. The primary bottleneck so far preventing that approach, which is the disparity between the trained theoretical model and reality, will be overcome using a multi-frequency complex-valued domain adaptation technique. The method will use deep neural networks to reliably learn the physical concepts of microwave engineering problems. This project will have significant economic and societal benefits, such as supporting the efficient design, installation and operation of communication systems, mining, infrastructure inspection, security, remote sensing, and microwave imaging. Read moreRead less
Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project ....Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project aims may enable speeds of up to 100 times greater than achievable today, in a variety of fibre optic systems. Connectivity is key to our society, so benefits may arise in both future-proofing key Australian data infrastructure, and in providing a roadmap to support exponential capacity growth over the coming decades.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100016
Funder
Australian Research Council
Funding Amount
$432,572.00
Summary
Wireless Communications for Human-Machine Collaboration. Industry 5.0 is a new industry transformation vision where the focus lies on the interaction between humans and machines. Wireless human-machine collaboration (HMC) will play a central role in a wide range of industrial applications in Industry 5.0. This project aims to develop new fundamental theories of wireless HMC and enable novel wireless communications designs to accommodate the stringent and dynamic requirements of HMC with performa ....Wireless Communications for Human-Machine Collaboration. Industry 5.0 is a new industry transformation vision where the focus lies on the interaction between humans and machines. Wireless human-machine collaboration (HMC) will play a central role in a wide range of industrial applications in Industry 5.0. This project aims to develop new fundamental theories of wireless HMC and enable novel wireless communications designs to accommodate the stringent and dynamic requirements of HMC with performance guarantees. The project will provide innovative solutions to advanced manufacturing, remote healthcare, mining, and warehousing and will benefit Australia’s digital transformation.Read moreRead less
Industry Laureate Fellowships - Grant ID: IL230100116
Funder
Australian Research Council
Funding Amount
$3,359,464.00
Summary
Breaking through the manufacturing ‘glass ceiling’ for ZBLAN glass fibres. This project aims to develop innovative methods to improve the purity and manufacture scale of fluoride glass (ZBLAN) optical fibres to deliver faster and more efficient internet. This project expects to produce ZBLAN fibres with lower light loss than the best fibres to date by integrating innovations in glass science, materials purification, process automation and space manufacturing. Expected outcomes include industrial ....Breaking through the manufacturing ‘glass ceiling’ for ZBLAN glass fibres. This project aims to develop innovative methods to improve the purity and manufacture scale of fluoride glass (ZBLAN) optical fibres to deliver faster and more efficient internet. This project expects to produce ZBLAN fibres with lower light loss than the best fibres to date by integrating innovations in glass science, materials purification, process automation and space manufacturing. Expected outcomes include industrial scale production of ZBLAN fibres with 10 times better performance than existing production. The project should provide innovative new manufacturing methods and improved economic and social prosperity by increasing the availability of ZBLAN for a wealth of applications touching many aspects of Australian lives.Read moreRead less