English

A Diffusion-Based Approach for Simulating Forward-in-Time State-Dependent Speciation and Extinction Dynamics

Populations and Evolution 2024-06-26 v2 Probability

Abstract

We establish a general framework using a diffusion approximation to simulate forward-in-time state counts or frequencies for cladogenetic state-dependent speciation-extinction (ClaSSE) models. We apply the framework to various two- and three-region geographic-state speciation-extinction (GeoSSE) models. We show that the species range state dynamics simulated under tree-based and diffusion-based processes are comparable. We derive a method to infer rate parameters that are compatible with given observed stationary state frequencies and obtain an analytical result to compute stationary state frequencies for a given set of rate parameters. We also describe a procedure to find the time to reach the stationary frequencies of a ClaSSE model using our diffusion-based approach, which we demonstrate using a worked example for a two-region GeoSSE model. Finally, we discuss how the diffusion framework can be applied to formalize relationships between evolutionary patterns and processes under state-dependent diversification scenarios.

Keywords

Cite

@article{arxiv.2402.00246,
  title  = {A Diffusion-Based Approach for Simulating Forward-in-Time State-Dependent Speciation and Extinction Dynamics},
  author = {Albert C. Soewongsono and Michael J. Landis},
  journal= {arXiv preprint arXiv:2402.00246},
  year   = {2024}
}

Comments

Minor typo fixes, figure aesthetics improvements, and some new analyses. 47 pages, 12 figures, 2 tables

R2 v1 2026-06-28T14:33:56.356Z