Protecting Occupants in Vehicle Rollover Crashes. This project addresses a public health issue involving rollover crashes. It will help prevent 340 deaths, 6000 injuries and save $3.6 billion annually in Australia and many fold this number internationally. A dynamic rollover crashworthiness test protocol, that ensures efficient and economical vehicle rollover protection systems are designed and manufactured, will be provided to consumer and regulatory bodies to consider and implement. In additio ....Protecting Occupants in Vehicle Rollover Crashes. This project addresses a public health issue involving rollover crashes. It will help prevent 340 deaths, 6000 injuries and save $3.6 billion annually in Australia and many fold this number internationally. A dynamic rollover crashworthiness test protocol, that ensures efficient and economical vehicle rollover protection systems are designed and manufactured, will be provided to consumer and regulatory bodies to consider and implement. In addition, much needed Occupational Health & Safety information regarding vehicle rollover crashworthiness, which provide a safe work place environment for professional drivers and employees using vehicles, will be supplied to industry fleet managers, defence and emergency services.Read moreRead less
An autonomously controlled ankle exoskeleton for gait rehabilitation. This project addresses a critical problem in gait rehabilitation; predicting unstable locomotion and designing interventions to augment limb-joint function. The project will develop an autonomous ankle-foot assistive device to actively increase ground clearance when high-risk foot trajectory is detected. Using wearable sensor data, machine learning algorithms will predict high-risk gait and compute an actuator-induced ankle to ....An autonomously controlled ankle exoskeleton for gait rehabilitation. This project addresses a critical problem in gait rehabilitation; predicting unstable locomotion and designing interventions to augment limb-joint function. The project will develop an autonomous ankle-foot assistive device to actively increase ground clearance when high-risk foot trajectory is detected. Using wearable sensor data, machine learning algorithms will predict high-risk gait and compute an actuator-induced ankle torque to maintain safe foot-ground clearance. A wearable autonomous joint-actuation system will contribute significantly to rehabilitation across a range of gait-impaired populations. The project's scientific and technological innovations will provide the opportunity for future developments in assistive technologies. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989384
Funder
Australian Research Council
Funding Amount
$233,000.00
Summary
High-speed, three-dimensional, x-ray fluoroscopy for accurate measurement of human joint motion. This proposal addresses one of the most difficult and long-standing problems in the field of biomechanics: How can human joint motion be measured accurately and non-invasively during common activities such as walking, stair ambulation and running? Low-dose, high-speed, three-dimensional, x-ray fluoroscopy provides an excellent solution to this problem and, in so doing, can play a pivotal role in heal ....High-speed, three-dimensional, x-ray fluoroscopy for accurate measurement of human joint motion. This proposal addresses one of the most difficult and long-standing problems in the field of biomechanics: How can human joint motion be measured accurately and non-invasively during common activities such as walking, stair ambulation and running? Low-dose, high-speed, three-dimensional, x-ray fluoroscopy provides an excellent solution to this problem and, in so doing, can play a pivotal role in healthcare, through clinical gait analysis and gait rehabilitation (diagnosis, prevention and treatment of movement disorders); in sports, through the development of personalized training programs for elite athletes; and in entertainment, through the creation of physics-based animations for the video/digital games industry.Read moreRead less
Predictive Biomechanics for Modelling Gait Stability and Falls Prediction. Efficient, adaptive locomotion is critical to our independence, but it is adversely affected by neuromuscular disorders due to trauma, ageing and other impairments that increase the risk of balance loss and falling. This project investigates the extraordinary possibilities of advancing from the traditional laboratory-based, retrospective, gait research paradigm, to real-world gait monitoring using predictive biomechanics. ....Predictive Biomechanics for Modelling Gait Stability and Falls Prediction. Efficient, adaptive locomotion is critical to our independence, but it is adversely affected by neuromuscular disorders due to trauma, ageing and other impairments that increase the risk of balance loss and falling. This project investigates the extraordinary possibilities of advancing from the traditional laboratory-based, retrospective, gait research paradigm, to real-world gait monitoring using predictive biomechanics. By employing artificial intelligence, wearable sensors' data will predict balance loss and alert the user. The outcome will be fundamental knowledge for developing wearable systems to reduce the catastrophic impact of falls, with public health cost savings and improved quality of life for people with restricted mobility.Read moreRead less
Influence of athletic footwear on lower limb biomechanics of pubertal girls. This project aims to determine whether athletic footwear with appropriate design features can help improve neuromuscular control and, in doing so, reduce the potentially deleterious forces on the knee and lower limb structures of pubertal girls. As girls reach puberty, they become less able to control the movement patterns of their lower limbs, particularly in high-demand tasks like running and jumping. Better-designed ....Influence of athletic footwear on lower limb biomechanics of pubertal girls. This project aims to determine whether athletic footwear with appropriate design features can help improve neuromuscular control and, in doing so, reduce the potentially deleterious forces on the knee and lower limb structures of pubertal girls. As girls reach puberty, they become less able to control the movement patterns of their lower limbs, particularly in high-demand tasks like running and jumping. Better-designed footwear for pubertal girls may improve movement patterns, decrease the likelihood of musculoskeletal injury and improve physical activity participation rates. Project outcomes may lead to the development of such footwear, and are also anticipated to expand our understanding of female developmental biomechanics.Read moreRead less
Athletic footwear for reducing knee loads in girls and women. This project aims to develop a novel athletic shoe that can reduce harmful knee loads during sport in adolescent girls and young women. As girls reach puberty, they become less able to control the movement patterns of their knees and lower limbs - particularly in high-demand tasks like jumping. The project will develop a new ASICS shoe that will be ‘field-tested’ during sporting activity with high ACL injury risk (netball) to evaluate ....Athletic footwear for reducing knee loads in girls and women. This project aims to develop a novel athletic shoe that can reduce harmful knee loads during sport in adolescent girls and young women. As girls reach puberty, they become less able to control the movement patterns of their knees and lower limbs - particularly in high-demand tasks like jumping. The project will develop a new ASICS shoe that will be ‘field-tested’ during sporting activity with high ACL injury risk (netball) to evaluate its effect on tibial shock (in-field surrogate measure of knee load) and player comfort compared to a conventional shoe. Expected outcomes include reduced healthcare costs associated with the treatment of serious knee injury, including surgical reconstruction and early-onset knee osteoarthritis.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989476
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Rollover Crash Research Infrastructure Capacity Building. Around 1 in every 3 vehicle occupants die in a crash where the vehicle rolls over. This crash mode also accounts for around 25% of spinal injuries and cost the community around $2.5 billion annually. There are no rollover crash standards or consumer crash tests. The equipment purchased will be used to develop a rollover crashworthiness test protocol that can be adopted by consumer testing groups, to understand the role of fatigue in preci ....Rollover Crash Research Infrastructure Capacity Building. Around 1 in every 3 vehicle occupants die in a crash where the vehicle rolls over. This crash mode also accounts for around 25% of spinal injuries and cost the community around $2.5 billion annually. There are no rollover crash standards or consumer crash tests. The equipment purchased will be used to develop a rollover crashworthiness test protocol that can be adopted by consumer testing groups, to understand the role of fatigue in precipitating rollover crashes, and to develop a driver fatigue metric. It is estimated this research will result in saving around 150 lives, reducing serious spinal and head injuries and save the Australian community around $800 million per annum.Read moreRead less
Bodies in space. By investigating how a change in shape of the human body can produce a change in spatial orientation, the project will bring a fundamental advance of knowledge in the intersection of applied mathematics, sports science and mechanical engineering. These knowledge advances will lead to a novel theory regarding the control of the aerial dynamics of athletes, specifically springboard and platform divers. When applied in collaboration with world class Australian athletes, this theory ....Bodies in space. By investigating how a change in shape of the human body can produce a change in spatial orientation, the project will bring a fundamental advance of knowledge in the intersection of applied mathematics, sports science and mechanical engineering. These knowledge advances will lead to a novel theory regarding the control of the aerial dynamics of athletes, specifically springboard and platform divers. When applied in collaboration with world class Australian athletes, this theory will result in innovative platform and springboard diving techniques and improved performance. The reach of new insights generated by this work extends to many other fields, including robotics, spacecraft dynamics and nano technology.Read moreRead less