Investigating the Effects of Network-Induced Delays on Networked Control Systems. Networked control is the current trend for industrial automation. The results of this project will be the first in the world to contribute directly to a deeper understanding of both negative and positive effects of network-induced delays on networked control systems. It will firmly place Australia at the forefront of this research by developing cutting edge technology for reliability and efficiency of industrial ne ....Investigating the Effects of Network-Induced Delays on Networked Control Systems. Networked control is the current trend for industrial automation. The results of this project will be the first in the world to contribute directly to a deeper understanding of both negative and positive effects of network-induced delays on networked control systems. It will firmly place Australia at the forefront of this research by developing cutting edge technology for reliability and efficiency of industrial networked-based control systems. This novel frontier technology will result in cost-saving and improved productivity for Australian industries, e.g. manufacturing industries, power stations, processing industries, automotive industries, vehicular networks and locomotives.Read moreRead less
Reducing Blackout Risk through Live Modelling and Monitoring. This project aims to reduce the risk of blackouts through the development of on-line systems for modelling and monitoring of loads and power system controllers. This project is a collaboration with Transgrid, Powerlink, Vencorp and ElectraNetSA, four Transmission companies renowned for innovation in the area of system stability. The project proposes to develop innovative algorithms and to implement these algorithms using advanced hard ....Reducing Blackout Risk through Live Modelling and Monitoring. This project aims to reduce the risk of blackouts through the development of on-line systems for modelling and monitoring of loads and power system controllers. This project is a collaboration with Transgrid, Powerlink, Vencorp and ElectraNetSA, four Transmission companies renowned for innovation in the area of system stability. The project proposes to develop innovative algorithms and to implement these algorithms using advanced hardware, software and communication systems to dynamically generate decision tools for safe and efficient power system operating conditions. These systems will also generate alarms if any risky operational situations arise.Read moreRead less
Optimum location of FACTS devices with advanced control scheme for improving the security of complex power grid. Prevention of blackouts is one of the highest priorities of the electricity industry. One of the fundamental reasons for the recent blackouts in long transmission network is inter-area oscillations. Queensland's long transmission network is a vital part of the Australian electricity grid and is vulnerable to inter-area oscillations. There is a need for a comprehensive approach to inve ....Optimum location of FACTS devices with advanced control scheme for improving the security of complex power grid. Prevention of blackouts is one of the highest priorities of the electricity industry. One of the fundamental reasons for the recent blackouts in long transmission network is inter-area oscillations. Queensland's long transmission network is a vital part of the Australian electricity grid and is vulnerable to inter-area oscillations. There is a need for a comprehensive approach to investigate the effect of inter-area oscillation that contributes to blackouts. Focussing the Queensland network, this project will provide a complete assessment tool for the optimum location of FACTS devices with modern and advanced control schemes in improving the security of complex interconnected power-grid. Read moreRead less
How a ubiquitous endosymbiont of insects protects against pathogens. The project intends to determine the mechanism that underpins pathogen protection in insects. Insects harbour microbial communities in their cells and guts and confer a range of benefits on their hosts. One bacterium, Wolbachia, protects insects against co-infecting pathogens. The release of Wolbachia into mosquito populations is currently being tested as a means to reduce dengue virus transmission to humans. Using innovative e ....How a ubiquitous endosymbiont of insects protects against pathogens. The project intends to determine the mechanism that underpins pathogen protection in insects. Insects harbour microbial communities in their cells and guts and confer a range of benefits on their hosts. One bacterium, Wolbachia, protects insects against co-infecting pathogens. The release of Wolbachia into mosquito populations is currently being tested as a means to reduce dengue virus transmission to humans. Using innovative evolutionary and genetic approaches, the project proposes to elucidate the mechanism of pathogen blocking and ascertain its broader consequences for the host. This knowledge may be critical for maintaining the effectiveness of the biocontrol approach in the field by informing the development of resistance management strategies.Read moreRead less
Epidemiology of pathogens in wildlife populations: significance for conservation, human health and livestock. Recent research shows that pathogens may play a central role in wildlife population dynamics. Emergent disease problems in humans and livestock may result from reservoir infections in wildlife. However, methods to determine the impact of pathogens on populations, as distinct from individuals within populations, are poorly developed, as are models necessary to evaluate alternative control ....Epidemiology of pathogens in wildlife populations: significance for conservation, human health and livestock. Recent research shows that pathogens may play a central role in wildlife population dynamics. Emergent disease problems in humans and livestock may result from reservoir infections in wildlife. However, methods to determine the impact of pathogens on populations, as distinct from individuals within populations, are poorly developed, as are models necessary to evaluate alternative control strategies for pathogens, particularly where reservoir hosts are involved. This project will develop these methods using four case studies: chyridiomycosis in frogs, Hendra virus in bats, Newcastle disease in wild birds and arboviruses in kangaroos and other macropods.Read moreRead less
The genomics of adaptation in Wolbachia pipientis, an emerging biocontrol agent. Australians are increasingly exposed to insect-transmitted diseases such as dengue fever. Novel biocontrol methods using the bacterium Wolbachia aim to control insect populations to reduce disease transmission. Our research will be the first to investigate genomic variation and the process of adaptation to new insect hosts in Wolbachia. The novel data and understanding of evolutionary processes we generate will be c ....The genomics of adaptation in Wolbachia pipientis, an emerging biocontrol agent. Australians are increasingly exposed to insect-transmitted diseases such as dengue fever. Novel biocontrol methods using the bacterium Wolbachia aim to control insect populations to reduce disease transmission. Our research will be the first to investigate genomic variation and the process of adaptation to new insect hosts in Wolbachia. The novel data and understanding of evolutionary processes we generate will be critical for screening bacterial biocontrol candidates and designing biocontrol release strategies. It will also strengthen the position of Australian research as a world-leader in the fusion of post-genomics and applied microbiology. Read moreRead less
Networked control for distributed renewable energy systems integration. The project aims to develop novel networked and coordinated control methods that greatly increase the capacity of the existing Australian power networks to host growing amounts of roof-top photovoltaic (PV) generation and customer load. These methods reduce the current need for high levels of continuing capital investments by optimally managing the existing network assets to fully exploit the inherent capabilities of PV inve ....Networked control for distributed renewable energy systems integration. The project aims to develop novel networked and coordinated control methods that greatly increase the capacity of the existing Australian power networks to host growing amounts of roof-top photovoltaic (PV) generation and customer load. These methods reduce the current need for high levels of continuing capital investments by optimally managing the existing network assets to fully exploit the inherent capabilities of PV inverters and new distributed battery storages that are now appearing at the domestic and network level. The project plans to combine robust networked control with stochastic optimisation methods to extract the best value from existing and new assets, while improving the load and generation hosting capability, for a given level of reliability.Read moreRead less
A comparative genomics approach to understanding host-endosymbiont interactions. Australia's unique ecosystems are vulnerable to invasion by exotic pests that threaten agriculture and human health. The bacterial symbiont Wolbachia is found in many major pests of agricultural and medical importance. Our results will give insights into how Wolbachia spreads into host populations and improve its use as a tool to impair insect transmission of disease, e.g. as an agent to carry genes into an insect p ....A comparative genomics approach to understanding host-endosymbiont interactions. Australia's unique ecosystems are vulnerable to invasion by exotic pests that threaten agriculture and human health. The bacterial symbiont Wolbachia is found in many major pests of agricultural and medical importance. Our results will give insights into how Wolbachia spreads into host populations and improve its use as a tool to impair insect transmission of disease, e.g. as an agent to carry genes into an insect population that limit disease transmission. Our results will also make fundamental contributions to understanding host-parasite evolution, host-parasite communication, and insect developmental processes, and will be of interest to a large international community of researchers in this field. Read moreRead less
From shape to function: how structured RNA defines insect flaviviruses. The goal of this project is to obtain an understanding of how insect-specific flaviviruses (ISFs) utilise viral noncoding RNAs to enable their replication in mosquitoes. These viruses only replicate in mosquitoes, and not in humans or animals. They can be employed as the biocontrol agents for mosquito-borne diseases as they make mosquitoes incapable of disease transmission. However, it is currently unknown how exactly insect ....From shape to function: how structured RNA defines insect flaviviruses. The goal of this project is to obtain an understanding of how insect-specific flaviviruses (ISFs) utilise viral noncoding RNAs to enable their replication in mosquitoes. These viruses only replicate in mosquitoes, and not in humans or animals. They can be employed as the biocontrol agents for mosquito-borne diseases as they make mosquitoes incapable of disease transmission. However, it is currently unknown how exactly insect-specific flaviviruses affect mosquitoes and this information is vital for informed design of ISF-based interventions. The project will generate new knowledge on functions of noncoding RNAs in ISFs that are hypothesised to have immunomodulatory role in mosquitoes. It will also train students and ECRs.Read moreRead less
What is killing the honeybees? The role of RNA viruses. This project aims to determine if the Varroa mite, the most important parasite of honeybees, selects for virulent strains of RNA viruses. Before Varroa’s inevitable arrival in Australia, this project will disentangle the effect of Varroa and the bees’ immune system on the evolution of virulence of bee viruses. Australia’s honeybees are Varroa-naïve and don’t carry virulent viruses. There is a known association between Varroa and colonies dy ....What is killing the honeybees? The role of RNA viruses. This project aims to determine if the Varroa mite, the most important parasite of honeybees, selects for virulent strains of RNA viruses. Before Varroa’s inevitable arrival in Australia, this project will disentangle the effect of Varroa and the bees’ immune system on the evolution of virulence of bee viruses. Australia’s honeybees are Varroa-naïve and don’t carry virulent viruses. There is a known association between Varroa and colonies dying from viruses; however, it is not known what is cause and effect. This project will clarify Varroa’s exact role in the evolution of virulence in RNA viruses. The intended outcome is increased knowledge allowing the design of an effective treatment to prevent the death of honeybee colonies.Read moreRead less