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
Understanding and improving sustained attention under vigilance conditions. This project aims to address a major global challenge caused by technological advances: human operators have to monitor computer-control (e.g., in autonomous vehicles, rail and airtraffic control) but sustaining attention is very difficult under these conditions. Developing innovative behavioural and neural methods, this internationally collaborative project bridges basic and applied science to understand lapses of atten ....Understanding and improving sustained attention under vigilance conditions. This project aims to address a major global challenge caused by technological advances: human operators have to monitor computer-control (e.g., in autonomous vehicles, rail and airtraffic control) but sustaining attention is very difficult under these conditions. Developing innovative behavioural and neural methods, this internationally collaborative project bridges basic and applied science to understand lapses of attention under monitoring conditions. It creates a novel intervention, based on brain activity patterns, to improve performance. Outcomes will increase our neural understanding of attention and lay a foundation for a novel system to detect lapses of attention in high-risk environments, preventing errors before they occur.Read moreRead less