English

Simulating stochastic population dynamics: The Linear Noise Approximation can capture non-linear phenomena

Quantitative Methods 2026-05-13 v5 Probability Chemical Physics Molecular Networks

Abstract

Population dynamics in fields such as molecular biology, epidemiology, and ecology exhibit highly stochastic and non-linear behaviour. In gene regulatory systems in particular, oscillations and multi-stability are especially common. Despite this, none of the currently available stochastic models for population dynamics are both accurate and computationally efficient for long-term predictions. A prominent model in this field, the Linear Noise Approximation (LNA), is computationally efficient for tasks such as simulation, sensitivity analysis, and parameter estimation; however, it is only accurate for linear systems and short-time predictions. Other models may achieve greater accuracy across a broader range of systems, but they sacrifice computational efficiency and analytical tractability. This paper demonstrates that, with specific modifications, the LNA can accurately capture non-linear dynamics in population processes. We introduce a new framework based on centre manifold theory, a classical concept from non-linear dynamical systems. This approach enables the identification of simple, system-specific modifications to the LNA, tailored to classes of qualitatively similar non-linear dynamical systems. With these modifications, the LNA can achieve accurate long-term simulations without compromising computational efficiency. We apply our methodology to classes of oscillatory and bi-stable systems, and present multiple examples from molecular population dynamics that demonstrate accurate long-term simulations alongside significant improvements in computational efficiency.

Keywords

Cite

@article{arxiv.2504.15166,
  title  = {Simulating stochastic population dynamics: The Linear Noise Approximation can capture non-linear phenomena},
  author = {Frederick Truman-Williams and Giorgos Minas},
  journal= {arXiv preprint arXiv:2504.15166},
  year   = {2026}
}

Comments

63 pages, 21 figures

R2 v1 2026-06-28T23:05:54.569Z