How do bees orchestrate smooth landings? The results should pave the way for the development of novel, biologically inspired strategies for the control of landing in unmanned aerial vehicles. Endowing aircraft with the capability of autonomous flight and landing has been a major challenge in engineering technology. There is now considerable interest, nationally and world wide, in the development of small, intelligent, autonomous airborne vehicles for application in a number of areas of defense, ....How do bees orchestrate smooth landings? The results should pave the way for the development of novel, biologically inspired strategies for the control of landing in unmanned aerial vehicles. Endowing aircraft with the capability of autonomous flight and landing has been a major challenge in engineering technology. There is now considerable interest, nationally and world wide, in the development of small, intelligent, autonomous airborne vehicles for application in a number of areas of defense, surveillance and space exploration. The proposed research will help Australia maintain a leading edge in uncovering important biological principles of flight control that can be translated into useful technological applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100949
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Did colour vision evolve in the dark? This project aims to investigate the ability of fishes to perceive colour in dim-light conditions by studying representatives from two delicate and endangered ecosystems, coral reefs (nocturnal fish) and the deep-sea. Through a multidisciplinary approach to understanding colour vision and animal behaviour, this study expects to fill a knowledge gap in visual neuroscience and ecology while adding to the understanding of how marine creatures see and interact. ....Did colour vision evolve in the dark? This project aims to investigate the ability of fishes to perceive colour in dim-light conditions by studying representatives from two delicate and endangered ecosystems, coral reefs (nocturnal fish) and the deep-sea. Through a multidisciplinary approach to understanding colour vision and animal behaviour, this study expects to fill a knowledge gap in visual neuroscience and ecology while adding to the understanding of how marine creatures see and interact. This should provide benefits in conservation and management strategies and may also inspire the development of new sensor technologies.Read moreRead less
Unravelling reef fish vision through gene-editing and behavioural ecology. This project aims to enhance understanding of visual neuroscience, genetic control of vision and environmental ecology on The Great Barrier Reef (GBR). Using the anemonefish as a model, together with new genetic, photographic and behavioural approaches, the project aims to reveal novel aspects of colour vision on the reef. Outcomes beyond multiple scientific disciplines include enhanced international collaboration and bui ....Unravelling reef fish vision through gene-editing and behavioural ecology. This project aims to enhance understanding of visual neuroscience, genetic control of vision and environmental ecology on The Great Barrier Reef (GBR). Using the anemonefish as a model, together with new genetic, photographic and behavioural approaches, the project aims to reveal novel aspects of colour vision on the reef. Outcomes beyond multiple scientific disciplines include enhanced international collaboration and building capacity for improved reef guardianship. The benefits are scientific discovery in multiple areas, providing greater community understanding of complex science and a desire to preserve the GBR for future generations.Read moreRead less
Colour vision and photoreceptors in reef fish: a model system to discover the function of double cones. Humans are visual animals and as lucky Australians we love to look at The Great Barrier Reef. This project, while rooted in the complexities of visual neurobiology, uses a recently discovered set of 4 different reef fish from the GBR to teach us more about fundamental principles in vision. These fish, diverse as damselfish and snappers, will help solve a mystery centuries old. Double cones are ....Colour vision and photoreceptors in reef fish: a model system to discover the function of double cones. Humans are visual animals and as lucky Australians we love to look at The Great Barrier Reef. This project, while rooted in the complexities of visual neurobiology, uses a recently discovered set of 4 different reef fish from the GBR to teach us more about fundamental principles in vision. These fish, diverse as damselfish and snappers, will help solve a mystery centuries old. Double cones are the commonest daytime photoreceptor in the eyes of almost all vertebrates (humans without them are exceptions) and yet nobody knows what they do. Reef fish have them, so let's ask them what they see!Read moreRead less
Novel control strategies for mosquitoes threatening Australia. Increased global transport and human mobility have led to the spread and establishment of potential disease vectors and pathogens of public health importance in many parts of the world from which these were absent or had been eradicated. Aversion of this risk can be more effective when applying area-wide rather than focal (e.g. insecticide) control efforts. We will further the development of genetic and biological control tactics. We ....Novel control strategies for mosquitoes threatening Australia. Increased global transport and human mobility have led to the spread and establishment of potential disease vectors and pathogens of public health importance in many parts of the world from which these were absent or had been eradicated. Aversion of this risk can be more effective when applying area-wide rather than focal (e.g. insecticide) control efforts. We will further the development of genetic and biological control tactics. We aim to reduce the risks posed by two important dengue-vectoring mosquitoes: the yellow fever and the Asian tiger mosquito. This will lead to environmentally friendly and sustainable mosquito control and protect the Australian population and its regional neighbours against the threats of mosquito-borne disease.Read moreRead less
Aquatic eye design: sharks and rays as models of underwater colour and luminance vision. Sharks are usually assumed to be colour blind. We have discovered that they may in fact see colour very well and that the eyes of different species are adapted to their particular lifestyles. Our research will help to raise the profile of sharks and portray them as animals with advanced sensory systems and complex visual behaviours rather than just dangerous killing machines. Studying the vision of sharks m ....Aquatic eye design: sharks and rays as models of underwater colour and luminance vision. Sharks are usually assumed to be colour blind. We have discovered that they may in fact see colour very well and that the eyes of different species are adapted to their particular lifestyles. Our research will help to raise the profile of sharks and portray them as animals with advanced sensory systems and complex visual behaviours rather than just dangerous killing machines. Studying the vision of sharks may also help to reduce the number (currently >50,000) that are killed each year as bycatch by Australian long-line fisheries and make a valuable contribution to one of Australia's National Research Priorities (an Environmentally Sustainable Australia) for managing and conserving our biodiversity.Read moreRead less