Probing cross modal interactions in the perception of object motion and self-motion. How the brain integrates information from the different senses is not yet understood. This project aims first, to uncover how the brain integrates sound and visual information when perceiving moving objects and second, to probe more complex sensory interactions between sound, vision, and our vestibular senses when perceiving self-motion. This project will expand Australia's knowledge base, strengthen collabora ....Probing cross modal interactions in the perception of object motion and self-motion. How the brain integrates information from the different senses is not yet understood. This project aims first, to uncover how the brain integrates sound and visual information when perceiving moving objects and second, to probe more complex sensory interactions between sound, vision, and our vestibular senses when perceiving self-motion. This project will expand Australia's knowledge base, strengthen collaborative ties between Australia and Japan, and provide unique training opportunities for Australian and Japanese students. Publication of research in top-ranking journals will further promote Australian science abroad. Results will lead to improvements in the design of human-machine interfaces in both industry and entertainment.Read moreRead less
Motion and Spatial Coding in Vision. The results of this project will have implications for the design and implementation of artificial visual systems. Completion of this project will depend upon international collaboration - forging links between a young Australian investigator and outstanding overseas scientists as well as providing excellent training opportunities. Subsequent publication of the research in top-ranking international journals will further promote Australian science abroad.
Rod-cone interaction under mesopic illumination. Visual function and performance can be degraded under dim light levels. This occurs in many indoor settings, emergency and traffic lighting conditions. Approximately 45% of all Australian traffic fatalities occur under dim light. The research program uses a frontier technology to determine how vision is degraded under dim lighting and provide accurate parameters to better design mesopic lighting environments to maximize visual function and perform ....Rod-cone interaction under mesopic illumination. Visual function and performance can be degraded under dim light levels. This occurs in many indoor settings, emergency and traffic lighting conditions. Approximately 45% of all Australian traffic fatalities occur under dim light. The research program uses a frontier technology to determine how vision is degraded under dim lighting and provide accurate parameters to better design mesopic lighting environments to maximize visual function and performance. This work will help to evaluate new energy-efficient lighting systems and optimise traffic lighting for early recognition of obstacles and dangerous situations. Read moreRead less
Psychophysical Assessment of Receptoral and Post-Receptoral Visual Function. Visual function and performance can be degraded under dim light levels. This occurs in many indoor settings, emergency lighting and road traffic lighting conditions. Approximately 45% of all Australian road traffic fatalities occur under dim lighting conditions. My data will be unique, as it will provide accurate parameters to better design mesopic lighting environments to maximize visual function and performance. This ....Psychophysical Assessment of Receptoral and Post-Receptoral Visual Function. Visual function and performance can be degraded under dim light levels. This occurs in many indoor settings, emergency lighting and road traffic lighting conditions. Approximately 45% of all Australian road traffic fatalities occur under dim lighting conditions. My data will be unique, as it will provide accurate parameters to better design mesopic lighting environments to maximize visual function and performance. This work will help to optimise road traffic lighting for the early recognition of obstacles and dangerous situations. The research program will make important scientific contributions to understanding human visual function and performance at dim light levels.Read moreRead less
The rules governing combined rod and cone photoreceptor signalling in visual pathways. The research program investigates vision at dim (mesopic) light levels where rod and cone photoreceptors simultaneously transmit visual information. The interaction between rod and cone signals is not trivial because their different amplitudes, timings and delays significantly change the perceptual qualities of our visual experience. The research addresses fundamental questions about how the retina and brain i ....The rules governing combined rod and cone photoreceptor signalling in visual pathways. The research program investigates vision at dim (mesopic) light levels where rod and cone photoreceptors simultaneously transmit visual information. The interaction between rod and cone signals is not trivial because their different amplitudes, timings and delays significantly change the perceptual qualities of our visual experience. The research addresses fundamental questions about how the retina and brain integrate disparate signals from the rods and cones to produce a homogenous visual percept. New psychophysical and electroretinographic paradigms will independently control the retinal photoreceptors to resolve the long standing problem of how noise modifies signalling and information flow between the retina and visual cortex.Read moreRead less
Melanopsin function in humans. This project aims to understand melanopsin signalling in humans. A newly discovered retinal ganglion cell class expresses the melanopsin photopigment. Melanopsin signalling controls neural functions for light dependent image formation and non-image forming processes. Many of these are unknown in humans. This project will use a 5-primary photostimulator to define how melanopsin controls these processes in humans. The outcomes are expected to advance understanding of ....Melanopsin function in humans. This project aims to understand melanopsin signalling in humans. A newly discovered retinal ganglion cell class expresses the melanopsin photopigment. Melanopsin signalling controls neural functions for light dependent image formation and non-image forming processes. Many of these are unknown in humans. This project will use a 5-primary photostimulator to define how melanopsin controls these processes in humans. The outcomes are expected to advance understanding of human vision. This could provide avenues for using light to increase active participation in society and improve health and well-being, and strategies to assess human vision and the body’s internal clock.Read moreRead less
Determinants and consequences of conscious visual awareness. Usually salient images can disappear from awareness without corresponding stimulus changes. This project is based on an innovative account linking such disappearances to a functional adaptation which facilitates vision in cluttered environments. Project completion will expand Australia's knowledge base, forge links between junior and senior Australian based investigators and provide excellent training opportunities. Publication of rese ....Determinants and consequences of conscious visual awareness. Usually salient images can disappear from awareness without corresponding stimulus changes. This project is based on an innovative account linking such disappearances to a functional adaptation which facilitates vision in cluttered environments. Project completion will expand Australia's knowledge base, forge links between junior and senior Australian based investigators and provide excellent training opportunities. Publication of research in top-ranking international journals will further promote Australian science abroad. Ultimately, this research will have implications for the design and implementation of artificial visual systems, which must overcome many of the same dilemmas faced by the human visual system in cluttered environments.Read moreRead less
Human Time Perception. Most human tasks require timing on a scale of tens to hundreds of milliseconds. We must judge time to produce and comprehend speech, to move about and interact with our dynamic environment, to determine causality and decode information from sensory receptors. However, the neural bases of time perception are largely unknown. This project will explore temporal phenomena to determine how and where durations, temporal order and coincidence are encoded in the human brain. Proje ....Human Time Perception. Most human tasks require timing on a scale of tens to hundreds of milliseconds. We must judge time to produce and comprehend speech, to move about and interact with our dynamic environment, to determine causality and decode information from sensory receptors. However, the neural bases of time perception are largely unknown. This project will explore temporal phenomena to determine how and where durations, temporal order and coincidence are encoded in the human brain. Project results will provide new insight into the mechanisms of time perception, with implications for disorders associated with impaired time perception, such as autism, dyslexia and schizophrenia.Read moreRead less
Multimodal testing for a fast subcortical route for salient visual stimuli. This project aims to uncover links between underlying brain circuitry, uncertainty and consciousness, and perceptions of fear. The project will use a multi-modal combination of brain imaging and neural recording techniques to generate new knowledge about the brain’s processing of biologically relevant information. The expected outcomes will enhance our knowledge of how the brain rapidly and non-consciously prepares the ....Multimodal testing for a fast subcortical route for salient visual stimuli. This project aims to uncover links between underlying brain circuitry, uncertainty and consciousness, and perceptions of fear. The project will use a multi-modal combination of brain imaging and neural recording techniques to generate new knowledge about the brain’s processing of biologically relevant information. The expected outcomes will enhance our knowledge of how the brain rapidly and non-consciously prepares the body for potential escape behaviours and of the brain pathways engaged in fear perception. The outcomes have the potential to inform strategies for overcoming anxiety and its effects on daily life, social interactions and workplace productivity.Read moreRead less
Why does time seem to drag and fly? This project aims to investigate varying perceptions about the passage of time. It is unclear if these variations reflect functional adaptations that allow fast information processing in the face of disaster or if such sensations are inferred after the events in question. Nor is it clear if such experiences are similar across individuals. The project aims to answer these questions, with long-term potential to inform artificial intelligence systems that rely on ....Why does time seem to drag and fly? This project aims to investigate varying perceptions about the passage of time. It is unclear if these variations reflect functional adaptations that allow fast information processing in the face of disaster or if such sensations are inferred after the events in question. Nor is it clear if such experiences are similar across individuals. The project aims to answer these questions, with long-term potential to inform artificial intelligence systems that rely on temporal sensitivity. The project also has potential to provide insights into conditions associated with impaired time perception-place roles.Read moreRead less