Parameter estimation for genetic time-series data: Theory and methods. This project aims to develop a novel computational framework for solving parameter estimation problems in evolutionary modelling by leveraging genetic time-series data measured by Next-Generation Sequencing technologies. It will foster international collaboration, cutting across disciplines. By introducing new techniques from signal processing and tools from random matrix theory commonly employed for mobile wireless communica ....Parameter estimation for genetic time-series data: Theory and methods. This project aims to develop a novel computational framework for solving parameter estimation problems in evolutionary modelling by leveraging genetic time-series data measured by Next-Generation Sequencing technologies. It will foster international collaboration, cutting across disciplines. By introducing new techniques from signal processing and tools from random matrix theory commonly employed for mobile wireless communications, it seeks to design scalable inference methods for resolving mutational fitness effects from genetic time-series measurements of complex evolving populations. This would enable new understanding of complex adaptive systems, such as pathogen evolution, host-immune dynamics, and acquisition of drug resistance. Read moreRead less
Low-Complexity Capacity-Scalable Multiple Antenna Wireless Communications. The project aims to develop innovative solutions for low-complexity, capacity-scalable multiple antenna wireless communications, in order to meet future data rate requirements whilst maintaining a practical system at a sustainable cost. By leveraging delay-Doppler domain channel properties and geometric reciprocity, pragmatic transceiver technologies and innovative delay-Doppler domain signal processing algorithms for cha ....Low-Complexity Capacity-Scalable Multiple Antenna Wireless Communications. The project aims to develop innovative solutions for low-complexity, capacity-scalable multiple antenna wireless communications, in order to meet future data rate requirements whilst maintaining a practical system at a sustainable cost. By leveraging delay-Doppler domain channel properties and geometric reciprocity, pragmatic transceiver technologies and innovative delay-Doppler domain signal processing algorithms for channel prediction and multi-user transmissions will be developed. The outcomes of the project are expected to significantly improve users' data rates with low system complexity and reduced signalling overhead for future wireless communications.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100228
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Low Temperature Co-fired Ceramic Device Fabrication Facility. Low temperature co-fired ceramic device fabrication facility:
This project seeks to establish a low temperature co-fired ceramics fabrication facility. New kinds of ‘meso-scale’ structurable ceramic processes are filling the technological and dimensional gap between microsystems in silicon and macro microsystems, as the platform can now structure microdevices in the range from a few micrometres to millimetres. This facility would pro ....Low Temperature Co-fired Ceramic Device Fabrication Facility. Low temperature co-fired ceramic device fabrication facility:
This project seeks to establish a low temperature co-fired ceramics fabrication facility. New kinds of ‘meso-scale’ structurable ceramic processes are filling the technological and dimensional gap between microsystems in silicon and macro microsystems, as the platform can now structure microdevices in the range from a few micrometres to millimetres. This facility would provide a resource for Australian researchers to create novel electronic materials and devices that will be key to achieving breakthroughs in micro/nano-technologies and telecommunications. This project expects to support cutting-edge research into multilayer ceramic microsystems such as microelectromechanical systems, wireless sensors and actuators, radio frequency and microwave devices, microfluidic packaging, interfacing and implantation of ultra-fast photoelectrons and acoustic wave devices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100124
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Coherent detection based characterisation facility for ultra broadband photonic and RF systems. The new infrastructure will allow detection of ultrahigh-speed optical and wireless signals. The facility adopts coherent detection based technologies providing superior performance in resolution, sensitivity, and bandwidth. It will play an important role in supporting research activities to accommodate phenomenal Internet growth.
Wireless Cellular Connectivity for Large Scale Critical Applications. Fostered by continuous technology advances, a vision of the Industrial Internet is emerging, in which equipment, machines, and industrial robots are interconnected to each other and to the cloud, allowing remote control of industrial processes and critical infrastructure, to intelligently optimise their behaviour with minimal human intervention. Moving from the state-of-the-art small pilot projects to a global Industrial Inte ....Wireless Cellular Connectivity for Large Scale Critical Applications. Fostered by continuous technology advances, a vision of the Industrial Internet is emerging, in which equipment, machines, and industrial robots are interconnected to each other and to the cloud, allowing remote control of industrial processes and critical infrastructure, to intelligently optimise their behaviour with minimal human intervention. Moving from the state-of-the-art small pilot projects to a global Industrial Internet requires wireless systems with consistent high reliability, low latency and massive connectivity. In this project we will develop new communication-theoretic principles and technologies for wireless networks meeting the demands of critical industrial and infrastructure applications in the Industrial Internet era.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100162
Funder
Australian Research Council
Funding Amount
$405,000.00
Summary
Intelligent wireless access for Internet of Things. This project aims to develop and validate fundamental theories and techniques for a novel intelligent wireless access paradigm to enhance the efficiency in frequency usage. This innovative approach will be one of the critical enablers for massive device access necessary for future wireless network evolution to support the growing Internet-of-Things. It will enable co-working devices to autonomously sense the local radio frequency landscape, det ....Intelligent wireless access for Internet of Things. This project aims to develop and validate fundamental theories and techniques for a novel intelligent wireless access paradigm to enhance the efficiency in frequency usage. This innovative approach will be one of the critical enablers for massive device access necessary for future wireless network evolution to support the growing Internet-of-Things. It will enable co-working devices to autonomously sense the local radio frequency landscape, determining how to avoid interference, and exploiting opportunities to intelligently and efficiently access the available radio resources. This will lead to enhanced efficiency in radio resource usage. The project will significantly improve the efficiency of current radio resource utilisation and offer solutions to a challenge of national significance.Read moreRead less