English

Back to the Continuous Attractor

Neurons and Cognition 2025-03-25 v3 Neural and Evolutionary Computing Adaptation and Self-Organizing Systems

Abstract

Continuous attractors offer a unique class of solutions for storing continuous-valued variables in recurrent system states for indefinitely long time intervals. Unfortunately, continuous attractors suffer from severe structural instability in general--they are destroyed by most infinitesimal changes of the dynamical law that defines them. This fragility limits their utility especially in biological systems as their recurrent dynamics are subject to constant perturbations. We observe that the bifurcations from continuous attractors in theoretical neuroscience models display various structurally stable forms. Although their asymptotic behaviors to maintain memory are categorically distinct, their finite-time behaviors are similar. We build on the persistent manifold theory to explain the commonalities between bifurcations from and approximations of continuous attractors. Fast-slow decomposition analysis uncovers the persistent manifold that survives the seemingly destructive bifurcation. Moreover, recurrent neural networks trained on analog memory tasks display approximate continuous attractors with predicted slow manifold structures. Therefore, continuous attractors are functionally robust and remain useful as a universal analogy for understanding analog memory.

Keywords

Cite

@article{arxiv.2408.00109,
  title  = {Back to the Continuous Attractor},
  author = {Ábel Ságodi and Guillermo Martín-Sánchez and Piotr Sokół and Il Memming Park},
  journal= {arXiv preprint arXiv:2408.00109},
  year   = {2025}
}
R2 v1 2026-06-28T17:59:47.918Z