Abstract
Coordinated collective behaviors often emerge from simple rules governing the interactions of individuals in groups. We model mechanisms of coordination among ants during cooperative transport, a challenging task that requires a consensus on travel direction. Our goal is to determine whether groups following simple behavioral rules can reach a consensus using minimal information. Using deterministic and stochastic models, we investigate behavioral factors that affect coordination. We define and investigate three types of behavioral rules governing individual behavior that differ in the information available: individuals either 1) have no information, 2) can measure transport success, or 3) measure success while also knowing whether they are aligned with the majority. We find that groups break deadlocks only if individuals more readily give up when they are going against the majority, corresponding to rule type 3 –such groups are “informed.” These behavioral rules succeed through positive and negative feedbacks that are implemented in our model via a single mechanism: individuals only need to measure the relative group sizes to make effective decisions. We also find that groups reach consensus more quickly if they have either a shared bias, high sensitivity to group behavior, or finely tuned persistence. Each of these is a potential adaptation for efficient cooperative transport. This flexibility makes the behavioral rules in the informed case relatively robust to deficiencies in the individuals’ capabilities. While inspired by ants, our results are generalizable to other collective decisions with deadlocks, and demonstrate that groups of behaviorally simple individuals with no memory and extremely limited information can break symmetry and reach a consensus in a decision between two equal options.
Highlights
Across organizational scales, the patterns and complexity of many biological systems emerge from groups of individuals obeying relatively simple rules, often without a leader [1]
We do not suggest that all of the variation in cooperative transport behavior in ants is captured by these three sets of rules; rather, we explore these rules to see if such simple rules are sufficient to break deadlocks
The streamplots indicate the direction the system tends towards starting from any possible combination of the numbers of individuals in each behavioral state (NL and NR)
Summary
The patterns and complexity of many biological systems emerge from groups of individuals obeying relatively simple rules, often without a leader [1]. Interest in discovering rules for collective behavior has produced a rich literature, and there has been particular interest in group decision making [2,3,4,5]. This includes nest-site selection decisions in honeybees and Temnothorax ants [6,7,8,9], decisions by groups of neurons in brains [10], decisions in non-neuronal organisms [11], and more. Ant colonies are well suited to studies of collective behavior because workers can be observed and manipulated, and pheromone trail formation in ants is a classic study system for self-organized decision making (e.g. [1,12])
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