From skylight input to behavioural output: A computational model of the insect polarised light compass

Many insects navigate by integrating the distances and directions travelled on an outward path, allowing direct return to the starting point. Fundamental to the reliability of this process is the use of a neural compass based on external celestial cues. Here we examine how such compass information c...

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Bibliographic Details
Published in:PLoS computational biology 2019-07, Vol.15 (7), p.e1007123-e1007123
Main Authors: Gkanias, Evripidis, Risse, Benjamin, Mangan, Michael, Webb, Barbara
Format: Article
Language:English
Subjects:
Animal navigation
Animals
Behavior, Animal - physiology
Biology and Life Sciences
Brain
Brain - physiology
Compasses
Computational Biology
Computational neuroscience
Computer applications
Computer science
Computer Simulation
Cues
Ecology and Environmental Sciences
Engineering and Technology
Homing Behavior - physiology
Informatics
Insecta - physiology
Insects
International conferences
Light
Mathematical models
Medicine and Health Sciences
Models, Biological
Models, Neurological
Neural circuitry
Neural networks
Neurons
Optic Lobe, Nonmammalian - physiology
Optics
Orientation - physiology
Photoreceptor Cells, Invertebrate - physiology
Physiological aspects
Physiology
Polarization
Robotics
Robots
Sensor arrays
Sensors
Social Sciences
Spatial Behavior - physiology
Sun
Sunlight
Supervision
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Summary:Many insects navigate by integrating the distances and directions travelled on an outward path, allowing direct return to the starting point. Fundamental to the reliability of this process is the use of a neural compass based on external celestial cues. Here we examine how such compass information could be reliably computed by the insect brain, given realistic constraints on the sky polarisation pattern and the insect eye sensor array. By processing the degree of polarisation in different directions for different parts of the sky, our model can directly estimate the solar azimuth and also infer the confidence of the estimate. We introduce a method to correct for tilting of the sensor array, as might be caused by travel over uneven terrain. We also show that the confidence can be used to approximate the change in sun position over time, allowing the compass to remain fixed with respect to 'true north' during long excursions. We demonstrate that the compass is robust to disturbances and can be effectively used as input to an existing neural model of insect path integration. We discuss the plausibility of our model to be mapped to known neural circuits, and to be implemented for robot navigation.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1007123