Time-ordered networks reveal limitations to information flow in ant colonies

An important function of many complex networks is to inhibit or promote the transmission of disease, resources, or information between individuals. However, little is known about how the temporal dynamics of individual-level interactions affect these networks and constrain their function. Ant coloni...

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Bibliographic Details
Published in:PloS one 2011-05, Vol.6 (5), p.e20298-e20298
Main Authors: Blonder, Benjamin, Dornhaus, Anna
Format: Article
Language:English
Subjects:
Animals
Ants
Ants - physiology
Bees
Biology
Colonies
Communication
Communications networks
Comparative analysis
Decision making
Disease transmission
Ecology
Evolutionary biology
Food chains
Functions (mathematics)
Group size
Hypotheses
Infectious diseases
Information flow
Information management
Leptothorax unifasciatus
Mathematical models
Mathematics
Mobility
Models, Theoretical
Networks
Plant reproduction
Social and Behavioral Sciences
Social networks
Temnothorax rugatulus
Time and Motion Studies
Upper bounds
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Summary:An important function of many complex networks is to inhibit or promote the transmission of disease, resources, or information between individuals. However, little is known about how the temporal dynamics of individual-level interactions affect these networks and constrain their function. Ant colonies are a model comparative system for understanding general principles linking individual-level interactions to network-level functions because interactions among individuals enable integration of multiple sources of information to collectively make decisions, and allocate tasks and resources. Here we show how the temporal and spatial dynamics of such individual interactions provide upper bounds to rates of colony-level information flow in the ant Temnothorax rugatulus. We develop a general framework for analyzing dynamic networks and a mathematical model that predicts how information flow scales with individual mobility and group size. Using thousands of time-stamped interactions between uniquely marked ants in four colonies of a range of sizes, we demonstrate that observed maximum rates of information flow are always slower than predicted, and are constrained by regulation of individual mobility and contact rate. By accounting for the ordering and timing of interactions, we can resolve important difficulties with network sampling frequency and duration, enabling a broader understanding of interaction network functioning across systems and scales.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0020298