Stigmergy as a mechanism to produce collective vortex behaviours: a study case in shoveler duck

Ant mill, caterpillar circle, bat donut, bacteria vortex, duck swirl and fish torus are different names for rotating circular formations of animals, where individuals turn around a common centre. Even if the ubiquity of this behavioural phenomenon might have suggested common causes or fundamental un...

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Bibliographic Details
Main Authors: Delcourt, Johann, bode, W. Nikolaï
Format: Conference Object
Language:English
Published: 2014
Subjects:
stigmergy
shoveler
shoveller
anas clypeata
vortex
dynamic behaviour
density effect
depletation effect
interaction behaviour-environment
milling behaviour
filter-feeding
dabbling duck
feeding behaviour
swirl
swirling
collective behaviour
group dynamic
group behaviour
modelisation
nutrient field
resource landscape
food depletion
IBM
individual based-model
self-organization
self-organisation
tortuosity
trajectory
motion behaviour
Life sciences
Zoology
Sciences du vivant
Zoologie
Anas clypeata
Shoveler
Online Access:https://orbi.uliege.be/handle/2268/174855
https://orbi.uliege.be/bitstream/2268/174855/1/Delcourt%20%26%20Bode%20Benelux%20Congress%20of%20Zoology%20abstract%20book%20p.141.jpg
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Summary:Ant mill, caterpillar circle, bat donut, bacteria vortex, duck swirl and fish torus are different names for rotating circular formations of animals, where individuals turn around a common centre. Even if the ubiquity of this behavioural phenomenon might have suggested common causes or fundamental underlying principles across contexts, a variety of proximate mechanisms can give rise to vortex behaviours. Here, we investigate if stigmergic process (mechanism of self-organisation wit hout direct communication or interaction between individuals) is able to produce different collective behaviours, notably collective vortices. We present an individual-based simulation model for the movement of populations in a resource landscape that allows us to vary the strength of the interactions mentioned above. The key assumption and novelty of our model is that individuals can cause the release of additional nutrients, as well as consuming them. Our model produces clear predictions. For example, we expect more tortuous individual movement paths and higher levels of aggregation in populations occupying homogeneous environments where individual movement makes more nutrients available. We also show how observed movement dynamics could change when local nutrient sources are depleted or when the population density increases. Our predictions are testable and qualitatively reproduce the different feeding behaviours observed in filter-feeding ducks (Anas clypeata), for example. We suggest that considering two-way interactions between feeding individuals and resource landscapes could help to explain fine-scale movement dynamics.

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