Evolution of intelligence in small brains: how to navigate the messy natural outdoors smartly. This project unravels how small-brained desert ants navigate expertly using simple and coarse-grade visual cues, focusing on 1) how they use skylines, where the tops of terrestrial objects meet the sky, and 2) how they search efficiently for goals. The outcomes will be invaluable for designing robots that can navigate in the messy natural outdoors.
Information processing at its limits: from the dimmest habitats to the smallest sizes. Ensuring optimal information processing at the limits of size and ambient light is a challenge for technical systems, but has been elegantly solved by animals. The challenge of navigation is similar for animals of all sizes and in both day and night. This project aims to conduct a comparative analysis to identify the consequence of size and light on the information processing capacities for visual navigation. ....Information processing at its limits: from the dimmest habitats to the smallest sizes. Ensuring optimal information processing at the limits of size and ambient light is a challenge for technical systems, but has been elegantly solved by animals. The challenge of navigation is similar for animals of all sizes and in both day and night. This project aims to conduct a comparative analysis to identify the consequence of size and light on the information processing capacities for visual navigation. Outcomes of this project will reveal the behavioural and physiological adaptations needed and the costs associated with navigating in the dimmest of habitats and at the smallest of sizes. Identifying such optimal biological solutions for robust navigation will be relevant for image processing, computer vision and robotics.Read moreRead less
Bio-inspired camouflage to prevent shark attacks on surfers. Bio-inspired camouflage to prevent shark attacks on surfers. This project aims to develop a new shark deterrent technology to protect surfers and paddlers. Shark attacks are physically and emotionally devastating for the victims, and make the community disproportionately afraid. Surfers are at most risk of attack, but current surfboard-mounted deterrents are ineffective and not widely used. This project will build on the recent discove ....Bio-inspired camouflage to prevent shark attacks on surfers. Bio-inspired camouflage to prevent shark attacks on surfers. This project aims to develop a new shark deterrent technology to protect surfers and paddlers. Shark attacks are physically and emotionally devastating for the victims, and make the community disproportionately afraid. Surfers are at most risk of attack, but current surfboard-mounted deterrents are ineffective and not widely used. This project will build on the recent discovery that white sharks do not attack counter-illuminated (light emitting) seal-shaped decoys, and use new information about shark vision to understand why this ‘camouflage’ is so successful. This will also help to protect threatened shark species by reducing reliance on culling programs to keep people safe in the water.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101408
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Key mammalian survival strategies in a rapidly changing environment. The aim of this project is to quantify behavioural and physiological traits in mammals that are crucial for survival in a changing environment. It aspires to identify the most influential habitat and climatic factors that determine the relationship between individual foraging effort and energy-saving mechanisms. Understanding how individuals manage their daily energy needs – a crucial aspect of an animal’s life history – may pr ....Key mammalian survival strategies in a rapidly changing environment. The aim of this project is to quantify behavioural and physiological traits in mammals that are crucial for survival in a changing environment. It aspires to identify the most influential habitat and climatic factors that determine the relationship between individual foraging effort and energy-saving mechanisms. Understanding how individuals manage their daily energy needs – a crucial aspect of an animal’s life history – may provide significant understanding of how individuals survive to reproduce and ultimately sustain thriving populations. This novel scientific knowledge may enable managers of protected areas and threatened species in Australia and worldwide to develop informed policies to ensure positive interactions between natural and human systems and to sustain biodiversity.Read moreRead less
Navigating brains: the neurobiology of spatial cognition. Navigation is one of the most crucial and most challenging problems animals face. Behavioural analyses have shown that animals make use of a number of different mechanisms to navigate, but very little is known of how different forms of spatial information are processed and integrated by the brain. The project aims to tackle this by placing tethered ants in a virtual-reality simulation of their real environment allowing precise control of ....Navigating brains: the neurobiology of spatial cognition. Navigation is one of the most crucial and most challenging problems animals face. Behavioural analyses have shown that animals make use of a number of different mechanisms to navigate, but very little is known of how different forms of spatial information are processed and integrated by the brain. The project aims to tackle this by placing tethered ants in a virtual-reality simulation of their real environment allowing precise control of visual navigational cues, as well as the opportunity to study the brains of the tethered ants as they solve the real-world challenge of finding home. This may reveal how simple brains efficiently solve navigational tasks, which may inform both cognitive biology and bio-inspired computation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101513
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Ant-inspired rules for self-assembly in swarm robotics and complex systems. This project aims to investigate how ants use self-assembly to build bridges and chains, joining their bodies using simple rules at the individual-level to build complex structures at the group-level. The long-standing conceptual gap between these two organisational levels will be addressed using innovative animal behaviour experiments, computer modelling and embodied testing of theory in a robot swarm. The expected outc ....Ant-inspired rules for self-assembly in swarm robotics and complex systems. This project aims to investigate how ants use self-assembly to build bridges and chains, joining their bodies using simple rules at the individual-level to build complex structures at the group-level. The long-standing conceptual gap between these two organisational levels will be addressed using innovative animal behaviour experiments, computer modelling and embodied testing of theory in a robot swarm. The expected outcomes of the project include new models for understanding self-assembly in complex systems and new control algorithms for robot swarms. The project should provide significant benefits such as programming to allow robot swarms to autonomously self-assemble useful structures that enhance their operational capabilities.Read moreRead less
Social insects as model systems in complexity science. Many optimisation algorithms are based on the behaviour of social insects. These algorithms function well under static conditions, when there is only one optimal solution. This project will determine how individual insect behaviour affects collective behaviour. Outcomes will allow the development of better algorithms.
The physiological mechanisms underlying animal group dynamics. The project aims to provide novel insights into how individual differences in muscle biomechanics and metabolism constrain group assemblages, and the extent to which these constraints can cause fission and fusion of populations in changing environments. This research is significant because most ecological and evolutionary processes and their management occur at the level of groups. The project expects to yield a theoretical model cal ....The physiological mechanisms underlying animal group dynamics. The project aims to provide novel insights into how individual differences in muscle biomechanics and metabolism constrain group assemblages, and the extent to which these constraints can cause fission and fusion of populations in changing environments. This research is significant because most ecological and evolutionary processes and their management occur at the level of groups. The project expects to yield a theoretical model calibrated against empirical data to predict group dynamics of natural populations in changing environments, and of human crowds as diseases and lifestyle change physiological capacities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101281
Funder
Australian Research Council
Funding Amount
$384,589.00
Summary
Mechanisms influencing the evolutionary trajectories of extended phenotypes. Although we know how the environment and predator-prey interactions shape traits, we have a poor grasp of the evolution of extended phenotypes. The webs of spiders have switched repeatedly between two- and three-dimensional forms over time, so are excellent models for assessing extended phenotype evolution. This project will use innovative experiments to assess whether the prey capture performance of webs or their visib ....Mechanisms influencing the evolutionary trajectories of extended phenotypes. Although we know how the environment and predator-prey interactions shape traits, we have a poor grasp of the evolution of extended phenotypes. The webs of spiders have switched repeatedly between two- and three-dimensional forms over time, so are excellent models for assessing extended phenotype evolution. This project will use innovative experiments to assess whether the prey capture performance of webs or their visibility to insects drove the repeated This project will provide insights into the interactive roles of the environment and prey in shaping extended phenotype diversification. Read moreRead less
Movement, migration and social networks in wild shark populations. Sharks are vital components of marine ecosystems and contribute significantly to ecotourism and fisheries. Due to their slow rate of growth and reproduction, sharks are susceptible to over exploitation. A lack of knowledge regarding their behaviour and movement patterns is a key impediment to effective management. This project aims to examine social interactions and migration patterns of Port Jackson sharks using a unique combina ....Movement, migration and social networks in wild shark populations. Sharks are vital components of marine ecosystems and contribute significantly to ecotourism and fisheries. Due to their slow rate of growth and reproduction, sharks are susceptible to over exploitation. A lack of knowledge regarding their behaviour and movement patterns is a key impediment to effective management. This project aims to examine social interactions and migration patterns of Port Jackson sharks using a unique combination of genetic techniques, novel acoustic tag technology, behavioural manipulations and modern social network analysis. Once verified, the approach developed can be applied to other marine predators of particular management concern. The data generated will directly inform fisheries and conservation management policy.Read moreRead less