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Visual Social Information Use in Collective Foraging

Collective dynamics emerge from individual-level decisions, yet we still poorly understand the link between individual-level decision-making processes and collective outcomes in realistic physical environments.Using collective foraging to study the key trade-off between personal and social information use, we present a mechanistic, spatially-explicit agent-based model that combines individual-level evidence accumulation of personal and (visual) social cues with particle-based movement.Under idealized conditions without physical constraints, our mechanistic framework reproduces findings from established probabilistic models, but explains how individual-level decision processes generate collective outcomes in a bottom-up way.Groups performed best in clustered environments if agents quickly accumulated social information and approached successful others; individualistic search was most beneficial in uniform environments.Incorporating different real-world physical and perceptual constraints profoundly shaped collective performance, occasionally buffering maladaptive herding and generating self-organized exploration.Our study uncovers the mechanisms linking individual cognition to collective outcomes in human and animal foraging and paves the way for decentralized robotic applications.

DOI (series): 10.5446/s_1546
4
2023
73
11 minutes 9 seconds
4 results
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03:26
30Mezey, David et al.
Collective dynamics emerge from individual-level decisions, yet we still poorly understand the link between such individual-level decision making processes and collective outcomes in realistic physical environments. Using collective foraging to study the key trade-off between personal and social information use, we present a mechanistic, spatially-explicit agent-based model that combines individual-level evidence accumulation of personal and (visual) social cues with particle-based movement. Under idealized conditions without physical constraints, our mechanistic framework reproduces findings from established probabilistic models, but explains how individual-level decision processes generate collective outcomes in a bottom-up way. Groups performed best in clustered environments if agents quickly accumulated social information and approached successful others; individualistic search was most beneficial in uniform environments. Incorporating different real-world physical and perceptual constraints greatly improved collective performance by buffering maladaptive herding and generating self-organized exploration. Our study uncovers the mechanisms linking individual cognition to collective outcomes in human and animal foraging and paves the way for decentralized robotic applications.
2023Mezey, David
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02:21
18Mezey, David et al.
Collective dynamics emerge from individual-level decisions, yet we still poorly understand the link between individual-level decision-making processes and collective outcomes in realistic physical environments. Using collective foraging to study the key trade-off between personal and social information use, we present a mechanistic, spatially-explicit agent-based model that combines individual-level evidence accumulation of personal and (visual) social cues with particle-based movement. Under idealized conditions without physical constraints, our mechanistic framework reproduces findings from established probabilistic models, but explains how individual-level decision processes generate collective outcomes in a bottom-up way. Groups performed best in clustered environments if agents quickly accumulated social information and approached successful others; individualistic search was most beneficial in uniform environments. Incorporating different real-world physical and perceptual constraints profoundly shaped collective performance, occasionally buffering maladaptive herding and generating self-organized exploration. Our study uncovers the mechanisms linking individual cognition to collective outcomes in human and animal foraging and paves the way for decentralized robotic applications.
2023Mezey, David
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02:27
13Mezey, David et al.
Collective dynamics emerge from individual-level decisions, yet we still poorly understand the link between individual-level decision-making processes and collective outcomes in realistic physical environments. Using collective foraging to study the key trade-off between personal and social information use, we present a mechanistic, spatially-explicit agent-based model that combines individual-level evidence accumulation of personal and (visual) social cues with particle-based movement. Under idealized conditions without physical constraints, our mechanistic framework reproduces findings from established probabilistic models, but explains how individual-level decision processes generate collective outcomes in a bottom-up way. Groups performed best in clustered environments if agents quickly accumulated social information and approached successful others; individualistic search was most beneficial in uniform environments. Incorporating different real-world physical and perceptual constraints profoundly shaped collective performance, occasionally buffering maladaptive herding and generating self-organized exploration. Our study uncovers the mechanisms linking individual cognition to collective outcomes in human and animal foraging and paves the way for decentralized robotic applications.
2023Mezey, David
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02:53
12Mezey, David et al.
Collective dynamics emerge from individual-level decisions, yet we still poorly understand the link between individual-level decision-making processes and collective outcomes in realistic physical environments. Using collective foraging to study the key trade-off between personal and social information use, we present a mechanistic, spatially-explicit agent-based model that combines individual-level evidence accumulation of personal and (visual) social cues with particle-based movement. Under idealized conditions without physical constraints, our mechanistic framework reproduces findings from established probabilistic models, but explains how individual-level decision processes generate collective outcomes in a bottom-up way. Groups performed best in clustered environments if agents quickly accumulated social information and approached successful others; individualistic search was most beneficial in uniform environments. Incorporating different real-world physical and perceptual constraints profoundly shaped collective performance, occasionally buffering maladaptive herding and generating self-organized exploration. Our study uncovers the mechanisms linking individual cognition to collective outcomes in human and animal foraging and paves the way for decentralized robotic applications.
2023Mezey, David