Understanding and predicting submarine hydrofoil noise. Australia needs to develop a more sophisticated underwater flow-induced noise research and development capability if it is to achieve its ambitious naval plans set out under the Defence White Paper. This project will develop an experimentally validated model to predict submarine noise for the purposes of submarine design, operation and procurement.
Port Stephens Flood Tide Delta: Shoreline Management Issues. The results of this project will contribute substantially to the knowledge of flood tide delta morphodynamics and specifically to those deltas exposed to ocean waves which are most typical throughout eastern and southern Australia. The model generated by the project will be used to test solutions to the problems in Port Stephens and more generally to similar systems elsewhere in Australia. The model will permit the assessment of the re ....Port Stephens Flood Tide Delta: Shoreline Management Issues. The results of this project will contribute substantially to the knowledge of flood tide delta morphodynamics and specifically to those deltas exposed to ocean waves which are most typical throughout eastern and southern Australia. The model generated by the project will be used to test solutions to the problems in Port Stephens and more generally to similar systems elsewhere in Australia. The model will permit the assessment of the responses of the deltas and shoreline to climate change, changing wave climate and reinvigorated sediment budgets, thereby addressing National Research priority-Responding to climate change and variability. The project will is provide training for one APDI and two APAIs in a range of skills.Read moreRead less
The future of shipping: achieving autonomous navigation. This project aims to develop autonomous decision systems and onshore control stations to support the design and operation of unmanned cargo ships. Blending observations, numerical models, virtual reality and machine learning, the project will develop algorithms for unsupervised navigation and embed these in an advanced ship simulator platform capable of responding to environmental conditions and optimising sea freight transport capabilitie ....The future of shipping: achieving autonomous navigation. This project aims to develop autonomous decision systems and onshore control stations to support the design and operation of unmanned cargo ships. Blending observations, numerical models, virtual reality and machine learning, the project will develop algorithms for unsupervised navigation and embed these in an advanced ship simulator platform capable of responding to environmental conditions and optimising sea freight transport capabilities. The expected outcomes will enable the integration of automated controls in ships, including remote-control capabilities. This will support Australia’s transition towards an autonomous shipping industry, delivering greater reliability, efficiency, productivity and safety.Read moreRead less
ACTIVE CONTROL OF SURFACE OCEAN SHIPS. This research is to design nonlinear robust adaptive control systems using active actuators (flaps, fins and rudders) for course keeping and path tracking of surface ocean ships, which are inherently nonlinear and with uncertainties. The outcome of the research will lead to the development of non-linear control strategies, which result in simple-to-implement and effective controllers. These controllers are robust to the environmental disturbances and uncert ....ACTIVE CONTROL OF SURFACE OCEAN SHIPS. This research is to design nonlinear robust adaptive control systems using active actuators (flaps, fins and rudders) for course keeping and path tracking of surface ocean ships, which are inherently nonlinear and with uncertainties. The outcome of the research will lead to the development of non-linear control strategies, which result in simple-to-implement and effective controllers. These controllers are robust to the environmental disturbances and uncertainties, adapt to unknown parameters of the ship and actuators. Only a few control gains are required to be tuned. The success of this project will significantly increase the international competiveness of Australian shipbuilding industry.Read moreRead less
Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturat ....Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturation of the sector which is dominated by component companies. This system for underwater surveillance is obviously important to a country with a large coastline to defend. This project will build Australia's global reputation renowned for research excellence in fibre and fibre devices.Read moreRead less
Calculus in the real world: transforming the way we teach mathematics in primary education. This project will demonstrate that, with the aid of computers, primary school students can solve university-level advanced mathematics problems. After studying with multi-media teaching materials and specialised software, the students will undertake a university engineering examination - and pass with flying colours!
An end-to-end ocean weather information system for the blue economy. This project aims to develop a state-of-the-art ocean weather information system for marine industries. The project will design an end-to-end solution that integrates ocean observations, operational forecasting, and data delivery. By addressing industry needs, this project will provide a rapid pathway from research to economic benefit.
Measuring and Managing the Impact of Lost Organisational Knowledge. This research should produce significant economic and social benefits for many sectors, and the theoretical model potentially has practical benefits for all organisations. It addresses a widespread problem across the public service: the country's ageing demographic, which is affecting its efficiency and sustainability. It will improve the Royal Australian Navy's capacity to maintain national security, and help it to manage indus ....Measuring and Managing the Impact of Lost Organisational Knowledge. This research should produce significant economic and social benefits for many sectors, and the theoretical model potentially has practical benefits for all organisations. It addresses a widespread problem across the public service: the country's ageing demographic, which is affecting its efficiency and sustainability. It will improve the Royal Australian Navy's capacity to maintain national security, and help it to manage industry better. This will create cost savings and improve risk management, and thereby also contribute to one of the ARC's priority research areas: Safeguarding Australia.Read moreRead less
Australian coastal observation network: monitoring and forecasting coastal erosion in a changing climate. Australia's coastline is one of this country's greatest natural, economic and cultural resources. The asset value of existing beach-front infrastructure is immeasurable. Climate change is driving sea-level rise and changing regional wave climates, resulting in coastal erosion and increasing the threat to coastal sustainability. This research launches a strategic university-industry-governmen ....Australian coastal observation network: monitoring and forecasting coastal erosion in a changing climate. Australia's coastline is one of this country's greatest natural, economic and cultural resources. The asset value of existing beach-front infrastructure is immeasurable. Climate change is driving sea-level rise and changing regional wave climates, resulting in coastal erosion and increasing the threat to coastal sustainability. This research launches a strategic university-industry-government alliance to address the considerable and growing pressure for solutions to observe and forecast accelerating shoreline erosion. The new knowledge, greater cross-sector collaboration and international linkages to be fast-tracked by this project will inform and build the capacity of Australia's coastal managers to confront the challenges of a changing climate.Read moreRead less
Performance and design optimisation of oscillating water column ocean wave energy converters. This project will develop an optimised design for ocean wave energy extraction devices, known as oscillating water columns. This will significantly reduce energy conversion losses from oscillating water columns and contribute towards making them internationally competitive with other renewable energy technologies.