Scheduling and quality of service in Long Term Evolution telecommunications. There is an explosion of mobile telecommunications with over 50 billion connections expected by 2020. The next generation of mobile broadband will be based on a new technology known as Long Term Evolution (LTE) and, in this context, the goal of this project is to improve the efficiency of these systems by developing new techniques for scheduling.
Integrated Feedback Control in Future Wireless Communication Networks. The aim of this project is to develop and analyse new feedback control methods to address emerging challenges in future wireless communication networks such as 5G. This new generation of mobile communications promises exceptional bandwidth, high reliability and low link delay. To achieve these leaps in performance, a paradigm shift to massive multiple-input-multiple-output (MIMO) antenna systems, very high frequency systems a ....Integrated Feedback Control in Future Wireless Communication Networks. The aim of this project is to develop and analyse new feedback control methods to address emerging challenges in future wireless communication networks such as 5G. This new generation of mobile communications promises exceptional bandwidth, high reliability and low link delay. To achieve these leaps in performance, a paradigm shift to massive multiple-input-multiple-output (MIMO) antenna systems, very high frequency systems and small cells is required. Critical feedback loops in areas such as narrow 3D beam steering for mobile users, control of multiflow systems must be developed to enable 5G communications to be successfully deployed. This new generation of communications is also expected to open up new control application domains, such as the use of vehicle-to-vehicle networks.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100032
Funder
Australian Research Council
Funding Amount
$2,527,475.00
Summary
Ultralow latency wireless systems. Ultralow latency wireless systems. This project aims to develop theories and practical methods to design wireless communication systems for future generations of internet services. Emerging smart environments and infrastructure could solve major problems facing the world today, by saving energy, reducing pollution, improving health and increasing road safety. However, scientists to date do not know how to build wireless networks with almost zero latency and ult ....Ultralow latency wireless systems. Ultralow latency wireless systems. This project aims to develop theories and practical methods to design wireless communication systems for future generations of internet services. Emerging smart environments and infrastructure could solve major problems facing the world today, by saving energy, reducing pollution, improving health and increasing road safety. However, scientists to date do not know how to build wireless networks with almost zero latency and ultrahigh reliability, needed for machine-to-machine communications. An expected outcome of this project is new criteria and methodologies to design such wireless systems, which would affect future wireless systems and grids.Read moreRead less
Control of networked multi-agent systems. Networked multi-agent systems find wide applications in smart electricity grids, transportation networks, networked security systems, environmental monitoring networks and hospital resource schedulers. This project aims to develop advanced theories and techniques to model and control these systems for high performance and resource efficiency.
Communication networks for smart electricity grids. A smart grid will improve the efficiency of EnergyAustralia's electricity grid by minimizing cost and greenhouse gas emissions. A smart grid architecture will be researched and developed by using advanced communications and control engineering techniques offering significant economic, industrial, social and environmental benefits to Australia.