Everyday autism: bridging the gap between lab and life. Recent research demonstrates that autistic people, their families and professionals often feel that there remains a sharp divide between autism science and key aspects of everyday autistic life, despite significant public investment in that science. This proposed research investigates reasons for this divide and proposes ways in which it might be overcome. Expected outcomes include greater opportunities for autistic people to play active ro ....Everyday autism: bridging the gap between lab and life. Recent research demonstrates that autistic people, their families and professionals often feel that there remains a sharp divide between autism science and key aspects of everyday autistic life, despite significant public investment in that science. This proposed research investigates reasons for this divide and proposes ways in which it might be overcome. Expected outcomes include greater opportunities for autistic people to play active roles in the research process and more scientific experimentation that moves out of the laboratory and into more true-to-life settings. Bridging the gap between lab and life will result in better theory-building on autism, better translation of scientific discoveries and more robust policy recommendations.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100898
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
The brain that adapts itself - flexible processing in an ever-changing world. To cope with the changing world around us, our brains must constantly adapt themselves, reconfiguring an incredibly complex system to produce flexible behaviour. This project will develop innovative brain imaging techniques and use them to examine this process in vision, fundamental for understanding the human brain, and advancing neuroscience in Australia.
Making sense of the world: how does the brain process task-relevant information? Contributing to a global effort to understand the human brain, this project will develop and use innovative brain imaging techniques to ask how our brains make sense of the world. This project establishes collaboration with a world renowned research centre in Cambridge, UK, and will be fundamental for advancing basic science in Australia.
Learning from our mistakes: How and when complex decisions fail. The project aims to develop a novel mathematical framework, augmented by simulations and a set of experiments, to study when and how people commit errors. The modern environment bombards us with signals, such as radio and television advertisements as we sit at home or warning lights and car honks as we cross the road. Despite years of psychological research, it is not entirely clear how efficiently people cope with increasing amoun ....Learning from our mistakes: How and when complex decisions fail. The project aims to develop a novel mathematical framework, augmented by simulations and a set of experiments, to study when and how people commit errors. The modern environment bombards us with signals, such as radio and television advertisements as we sit at home or warning lights and car honks as we cross the road. Despite years of psychological research, it is not entirely clear how efficiently people cope with increasing amounts of information nor is it clear whether they process multiple signals simultaneously (in parallel) or one after the other (serial). The project offers new measures, based on the rate and pattern of error responses, to supplement the commonly used response times. The combination of a theoretical framework, based on mathematical and computational work, with empirical data to test the models, may deliver a better understanding of human performance and its limitations.Read moreRead less
Modelling human perceptual-motor interaction for human-machine applications. This project aims to develop a new modelling framework for identifying the perceptual-motor processes that underlie cooperative and competitive human interaction. The project will also determine whether this modelling framework can be combined with modern machine-learning methods to develop artificial agents capable of human level performance. Expected outcomes will include a practical methodology for rapidly generating ....Modelling human perceptual-motor interaction for human-machine applications. This project aims to develop a new modelling framework for identifying the perceptual-motor processes that underlie cooperative and competitive human interaction. The project will also determine whether this modelling framework can be combined with modern machine-learning methods to develop artificial agents capable of human level performance. Expected outcomes will include a practical methodology for rapidly generating models of effective human interaction that can be easily implemented in human-machine systems. This will provide a richer understanding of the fundamental perceptual-motor processes that support robust human interaction and enhanced the effectiveness of human-machine collaboration and training technologies.Read moreRead less
Choice models for learning and memory. Life is filled with familiar choices that often require quick decisions about objects in the environment and the contents of memory. This project examines how we learn to make rapid and accurate choices and how we quickly asses the level of confidence we have in recognition decisions based on our memories.
Discovery Early Career Researcher Award - Grant ID: DE140100499
Funder
Australian Research Council
Funding Amount
$393,087.00
Summary
The body in interaction – the impact of tracking the human body on visual object processing. For efficient and safe interactions with the world, our brain needs to constantly process the location and posture of the body as well as the characteristics of surrounding objects. Central questions in the field of cognitive science consider how tracking the human body influences object perception and which mechanisms support this perception in action. This project will use innovative virtual hand techn ....The body in interaction – the impact of tracking the human body on visual object processing. For efficient and safe interactions with the world, our brain needs to constantly process the location and posture of the body as well as the characteristics of surrounding objects. Central questions in the field of cognitive science consider how tracking the human body influences object perception and which mechanisms support this perception in action. This project will use innovative virtual hand technology to investigate the impact of body actions on concurrent visual perception. A better understanding of the demands that the body, in interaction, poses on our perceptual system will help to improve the design of complex work environments, such as computer interfaces and control panels.Read moreRead less