Abstract
Through theoretical analysis, we show how a superorganism may react to stimulus variations according to psychophysical laws observed in humans and other animals. We investigate an empirically-motivated honeybee house-hunting model, which describes a value-sensitive decision process over potential nest-sites, at the level of the colony. In this study, we show how colony decision time increases with the number of available nests, in agreement with the Hick-Hyman law of psychophysics, and decreases with mean nest quality, in agreement with Piéron’s law. We also show that colony error rate depends on mean nest quality, and difference in quality, in agreement with Weber’s law. Psychophysical laws, particularly Weber’s law, have been found in diverse species, including unicellular organisms. Our theoretical results predict that superorganisms may also exhibit such behaviour, suggesting that these laws arise from fundamental mechanisms of information processing and decision-making. Finally, we propose a combined psychophysical law which unifies Hick-Hyman’s law and Piéron’s law, traditionally studied independently; this unified law makes predictions that can be empirically tested.
Highlights
Psychophysics, introduced in the nineteenth century by Fechner[1,2], studies the relationship between stimulus intensity and its perception in the human brain
For the first time, we show that superorganismal behaviour, such as honeybee nest-site selection, may obey the same psychophysical laws displayed by humans in sensory discriminatory tasks
A large number of organisms at diverse levels of biological complexity, from humans to unicellular moulds, obey the same psychophysical laws that characterise the relationship between stimuli and the organism’s response
Summary
We show how a superorganism may react to stimulus variations according to psychophysical laws observed in humans and other animals. In our study psychophysical laws are measured at the colony level and the organism’s response to varying stimulus strengths corresponds to the colony’s response to varying nest-site qualities. This nest-site selection process as been modelled[18,20] as:. When a scout bee visits a potential nest-site i, she estimates its quality vi and modulates her behaviour showing higher activity in support of better quality nest-sites[25] Owing on these observations, in a previous study[18] we proposed a value sensitive parameterisation: γi = k vi, αi = k vi−1, ρi = h vi, βij = h vi,.
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