Formation of human kinship structures depending on population size and cultural mutation rate

TL;DR

This paper models how kinship structures in traditional societies emerge from interactions influenced by population size and cultural mutation, using simulations inspired by statistical physics and evolution.

Contribution

It introduces a multilevel evolutionary model that explains the formation of kinship structures through cultural transmission, cooperation, and rivalry, revealing their dependence on key parameters.

Findings

Kinship structures depend on population size and mutation rate.

Emergent structures are stable attractors with characteristic cycle lengths.

Scaling relationships describe formation and collapse probabilities.

Abstract

How does social complexity depend on population size and cultural transmission? Kinship structures in traditional societies provide a fundamental illustration, where cultural rules between clans determine people's marriage possibilities. Here we propose a simple model of kinship interactions that considers kin and in-law cooperation and sexual rivalry. In this model, multiple societies compete. Societies consist of multiple families with different cultural traits and mating preferences. These values determine interactions and hence the growth rate of families and are transmitted to offspring with mutations. Through a multilevel evolutionary simulation, family traits and preferences are grouped into multiple clans with inter-clan mating preferences. It illustrates the emergence of kinship structures as the spontaneous formation of interdependent cultural associations. Emergent kinship structures are characterized by the cycle length of marriage exchange and the number of cycles in society. We numerically and analytically clarify their parameter dependence. The relative importance of cooperation versus rivalry determines whether attraction or repulsion exists between families. Different structures evolve as locally stable attractors. The probabilities of formation and collapse of complex structures depend on the number of families and the mutation rate, showing characteristic scaling relationships. It is now possible to explore macroscopic kinship structures based on microscopic interactions, together with their environmental dependence and the historical causality of their evolution. We propose the basic causal mechanism of the formation of typical human social structures by referring to ethnographic observations and concepts from statistical physics and multilevel evolution. Such interdisciplinary collaboration will unveil universal features in human societies.