A Nonlinear Fertility Catastrophe Model Based on Thom's Differential Equations of Morphogenesis

Rolando Gonzales Martinez, University Of Groningen

A novel fertility model based on Thom's nonlinear differential equations of morphogenesis is presented, utilizing a three-dimensional catastrophe surface to capture the interaction between latent non-catastrophic fertility factors and catastrophic shocks. The model incorporates key socioeconomic and environmental variables and is applicable at macro-, meso-, and micro-demographic levels, addressing global fertility declines, regional population disparities, and micro-level phenomena such as teenage pregnancies. This approach enables a comprehensive analysis of reproductive health at aggregate, sub-national, and age-group-specific levels. An agent-based model for teenage pregnancy is described to illustrate how latent factors–such as education, contraceptive use, and parental guidance–interact with catastrophic shocks like socioeconomic deprivation, violence, and substance abuse. The bifurcation set analysis shows how minor shifts in socioeconomic conditions can lead to significant changes in fertility rates, revealing critical points in fertility transitions. By integrating Thom's morphogenesis equations with traditional fertility theory, this paper proposes a groundbreaking approach to understanding fertility dynamics, offering valuable insights for the development of public health policies that address both stable fertility patterns and abrupt demographic shifts.

Keywords: Mathematical demography , Children, Adolescents, and Youth, Fertility, The Demography of Indigenous Populations

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