English

Optimization hardness constrains ecological transients

Biological Physics 2025-04-15 v2 Optimization and Control Chaotic Dynamics Populations and Evolution

Abstract

Living systems operate far from equilibrium, yet few general frameworks provide global bounds on biological transients. In high-dimensional biological networks like ecosystems, long transients arise from the separate timescales of interactions within versus among subcommunities. Here, we use tools from computational complexity theory to frame equilibration in complex ecosystems as the process of solving an analogue optimization problem. We show that functional redundancies among species in an ecosystem produce difficult, ill-conditioned problems, which physically manifest as transient chaos. We find that the recent success of dimensionality reduction methods in describing ecological dynamics arises due to preconditioning, in which fast relaxation decouples from slow solving timescales. In evolutionary simulations, we show that selection for steady-state species diversity produces ill-conditioning, an effect quantifiable using scaling relations originally derived for numerical analysis of complex optimization problems. Our results demonstrate the physical toll of computational constraints on biological dynamics.

Keywords

Cite

@article{arxiv.2403.19186,
  title  = {Optimization hardness constrains ecological transients},
  author = {William Gilpin},
  journal= {arXiv preprint arXiv:2403.19186},
  year   = {2025}
}

Comments

9 pages, 7 figures, plus Appendix. Accepted at PLOS Comp Biol

R2 v1 2026-06-28T15:36:42.482Z