Unraveling linguistic patterns in dog behaviour
Arunita Banerjee, Nandan Das, Rajib Dey, Shouvik Majumder, Piuli Shit,, Ayan Banerjee, Nirmalya Ghosh, Anindita Bhadra

TL;DR
This study reveals that free-ranging dogs exhibit scale-invariant power-law patterns in their behaviour frequencies, with multifractal properties suggesting a language-like syntax in their behavioral repertoire.
Contribution
It is the first comprehensive analysis showing that animal behaviour follows power-law and multifractal patterns, indicating a possible language-like structure in non-human species.
Findings
Dog behaviour frequencies follow power-law distributions.
Behavioural data exhibits multifractal self-similarity.
Patterns suggest a syntax similar to human languages.
Abstract
Apparently random events in nature often reveal hidden patterns when analysed using diverse and robust statistical tools. Power-law distributions, for example, project diverse natural phenomenon, ranging from earthquakes1 to heartbeat dynamics2 onto a common platform of statistical self-similarity. A large range of human languages are known to follow a specific regime of power-law distributions, the Zipf-Mandelbrot law, in addition to showing properties like the Pareto principle and Shannon entropy3,4. Animal behaviour in specific contexts have been shown to follow power-law distributions5,6. However, the entire behavioural repertoire of a species has never been analysed for the existence of underlying patterns. Here we show that the frequency-rank data of randomly sighted behaviours at the population level of free-ranging dogs follow a scale-invariant power-law behaviour. While the…
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Taxonomy
TopicsComplex Systems and Time Series Analysis · Evolutionary Game Theory and Cooperation · Fractal and DNA sequence analysis
