Robotic gait assistive strategy for people with paraplegia: Generating balanced and human-like gait on a bipedal system. The outcomes of the project will contribute significantly to the fundamental understanding of bipedal mechanisms, robotics, and the dynamics of human gait. This research is unique in Australia and it will strengthen Australia's research standing in robotics and health-sciences. The immediate application of the outcomes will contribute significantly to the musculoskeletal and p ....Robotic gait assistive strategy for people with paraplegia: Generating balanced and human-like gait on a bipedal system. The outcomes of the project will contribute significantly to the fundamental understanding of bipedal mechanisms, robotics, and the dynamics of human gait. This research is unique in Australia and it will strengthen Australia's research standing in robotics and health-sciences. The immediate application of the outcomes will contribute significantly to the musculoskeletal and psychological health of people with spinal cord injury, as well as the basic locomotion capability around the house to carry out their daily tasks more independently and conveniently. Hence it will directly contribute to improving their quality of life and substantially reducing health-care costs and carer responsibilities in the community.Read moreRead less
Parallel-Link Mechanism Control using new Concept and Techniques. The new knowledge and techniques, as a result of this research project, will have direct relevance to many Australian industries. In particular, they provide opportunities to improve Australia's competitiveness through innovations for the manufacturing sector. For this sector, increasing global competition and tariff reductions pose serious challenges to its continuing international competitiveness. There is an urgent need to deve ....Parallel-Link Mechanism Control using new Concept and Techniques. The new knowledge and techniques, as a result of this research project, will have direct relevance to many Australian industries. In particular, they provide opportunities to improve Australia's competitiveness through innovations for the manufacturing sector. For this sector, increasing global competition and tariff reductions pose serious challenges to its continuing international competitiveness. There is an urgent need to develop cost effective innovative products. The outcomes of this research will produce a faster, more accurate, cheaper and optimally controlled parallel-link robot than currently available. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347673
Funder
Australian Research Council
Funding Amount
$186,000.00
Summary
Haptic Research Facility. There is an urgent need for the establishment of a unique Haptic research facility for virtual prototyping applications, assembly planning in a virtual environment, virtual maintenance analysis, collision detection, maintenance path planning and teleoperation, including laparoscopy. The realism of these applications can be substantially improved by the inclusion of a six degree-of-freedom force and torque feedback 'Haptic device', together with the Delmia simulation sui ....Haptic Research Facility. There is an urgent need for the establishment of a unique Haptic research facility for virtual prototyping applications, assembly planning in a virtual environment, virtual maintenance analysis, collision detection, maintenance path planning and teleoperation, including laparoscopy. The realism of these applications can be substantially improved by the inclusion of a six degree-of-freedom force and torque feedback 'Haptic device', together with the Delmia simulation suite, virtual prototyping / assembly software, to make working in three-dimension more natural, efficient and intuitive. The facility will support high quality fundamental research and development across Australia's manufacturing, automotive and aerospace industries as well as surgical applications. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347024
Funder
Australian Research Council
Funding Amount
$140,000.00
Summary
Research facility in micromanipulation. The aim of the program is to establish a unique joint facility between Monash and Deakin for micromanipulation research. The proposed facility will consist of complex/intelligent micromanipulation systems capable of motion accuracy of 0.01-0.1 micrometer (10-100 nm). This will be the only facility of its kind in Australia and will provide a key enabling technology in the research and development of advanced micromanipulation systems, robotic-assisted mic ....Research facility in micromanipulation. The aim of the program is to establish a unique joint facility between Monash and Deakin for micromanipulation research. The proposed facility will consist of complex/intelligent micromanipulation systems capable of motion accuracy of 0.01-0.1 micrometer (10-100 nm). This will be the only facility of its kind in Australia and will provide a key enabling technology in the research and development of advanced micromanipulation systems, robotic-assisted microsurgery, sensory-based and intelligent control of complex systems, micro assembly/manufacturing, telerobotics/telesurgery, kinematics and dynamics of micromanipulators, laser-based control, and biotechnology. The facility will support and enhance a number of high-quality, current and future research projects with recognised potential.Read moreRead less
A Novel Reconfigurable Unlimited Spherical Motion Generator. The main contribution of this research lies in the National Research Priority of Frontier Technologies for Building and Transforming Australian Industries. The main outcome is a strategy to produce unlimited spherical motion with high precision. It is an innovative solution that is applicable to many cutting edge research and industry problems. Immediate application is expected to produce a faithful motion simulation, for flight, astr ....A Novel Reconfigurable Unlimited Spherical Motion Generator. The main contribution of this research lies in the National Research Priority of Frontier Technologies for Building and Transforming Australian Industries. The main outcome is a strategy to produce unlimited spherical motion with high precision. It is an innovative solution that is applicable to many cutting edge research and industry problems. Immediate application is expected to produce a faithful motion simulation, for flight, astronaut, and vehicle control training. It would potentially improve the quality of human resources and the quality of Australian industry, both civil and military. This project would also enhance the Australian competitive technological edge in developing advanced mechatronic systems.Read moreRead less
Repetitive control systems in networked environments. Repetitive control is used in many industry applications to track periodic references and reject periodic disturbances. The development of digital technology brings in more networked control systems, greatly improving distributed manufacturing, which creates new design challenges due to network-induced constraints such as delay, data packet dropouts and cyber-attacks. This project aims to provide new understanding of dynamic behaviours of rep ....Repetitive control systems in networked environments. Repetitive control is used in many industry applications to track periodic references and reject periodic disturbances. The development of digital technology brings in more networked control systems, greatly improving distributed manufacturing, which creates new design challenges due to network-induced constraints such as delay, data packet dropouts and cyber-attacks. This project aims to provide new understanding of dynamic behaviours of repetitive control systems in networked environments, and develop a new theory for the analysis and design of networked repetitive control, subject to network induced constraints. The new control systems should reduce the cost of automation systems and will significantly enhance their performance, allowing Australian industry to remain economically competitive.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101128
Funder
Australian Research Council
Funding Amount
$399,235.00
Summary
Control and filtering of distributed systems with communication-scheduling. This project aims to develop an analysis and design framework to enhance the reliability of the next-generation advanced manufacturing systems with security vulnerability and communication scheduling. Reliable control and filtering of distributed systems is an emerging area of automation and control engineering in the tide of the 4th industrial revolution. Expected outcomes of this project include obtaining analysis crit ....Control and filtering of distributed systems with communication-scheduling. This project aims to develop an analysis and design framework to enhance the reliability of the next-generation advanced manufacturing systems with security vulnerability and communication scheduling. Reliable control and filtering of distributed systems is an emerging area of automation and control engineering in the tide of the 4th industrial revolution. Expected outcomes of this project include obtaining analysis criteria uncovering the effect from communication scheduling and cyber-attacks, and developing a novel framework based on co-design perspective to realize the distributed system design, while being applied in the cooperative control of various robots or manipulators in unmanned factories.Read moreRead less
Personalised assistive robotic systems: Optimised collaborative teaming . Robotic assistance for humans performing physical tasks provides significant benefits in various sectors from advanced manufacturing and defence through to rehabilitation, prosthetics and aged care. However, most robotic systems are designed with an average user in mind rather than tailored to the individual. This innovative project will focus on developing new techniques for adapting the interface between human and robot ....Personalised assistive robotic systems: Optimised collaborative teaming . Robotic assistance for humans performing physical tasks provides significant benefits in various sectors from advanced manufacturing and defence through to rehabilitation, prosthetics and aged care. However, most robotic systems are designed with an average user in mind rather than tailored to the individual. This innovative project will focus on developing new techniques for adapting the interface between human and robotic systems, leading to personalised physical interactions that outperform traditional approaches in achieving a shared performance goal even in unstructured environments. The tools developed will be demonstrated using state-of-the-art facilities, and will leverage the unique skill sets of the international project team.Read moreRead less
Haptic exploration and manipulation of micro/nano scale environment. The proposed research is novel and innovative in character and it has potential benefits in many frontier areas utilising micro/nano manipulation systems. These include micromanufacturing and instrumentation, microbiology, microsurgery and nanotechnology. The outcomes of this project will add to the growth of world-class Australian engineering science, and consolidate Australia's position in innovative technologies and internat ....Haptic exploration and manipulation of micro/nano scale environment. The proposed research is novel and innovative in character and it has potential benefits in many frontier areas utilising micro/nano manipulation systems. These include micromanufacturing and instrumentation, microbiology, microsurgery and nanotechnology. The outcomes of this project will add to the growth of world-class Australian engineering science, and consolidate Australia's position in innovative technologies and international R&D. This highly challenging project will provide training for postdoctorate researchers, postgraduate and honours students. These researchers will gain expertise in many areas including micro/nano manipulation, sensing and control, system design and analysis, virtual reality and experimental techniques.Read moreRead less
High-Fidelity Modelling for Robotic-Assisted Minimally Invasive Needle Insertion. This project will develop robotic-assisted needle insertion and greatly improve minimally invasive surgery. It will also enhance the establishment of intellectual property for Australian medicine and produce important benefits to the healthcare sector. The proposed symbiotic integration of the systems will advance modelling technologies, and further create new capabilities for a wide range of science and engineerin ....High-Fidelity Modelling for Robotic-Assisted Minimally Invasive Needle Insertion. This project will develop robotic-assisted needle insertion and greatly improve minimally invasive surgery. It will also enhance the establishment of intellectual property for Australian medicine and produce important benefits to the healthcare sector. The proposed symbiotic integration of the systems will advance modelling technologies, and further create new capabilities for a wide range of science and engineering applications. The established methodologies and systems will also provide great potential benefits in many other areas, including microbiology, life sciences and bio/nano-technology. The project's outcomes will further consolidate Australia's position in innovative technologies and international research and development.Read moreRead less