English

Evolving Afferent Architectures: Biologically-inspired Models for Damage-Avoidance Learning

Machine Learning 2026-02-05 v1

Abstract

We introduce Afferent Learning, a framework that produces Computational Afferent Traces (CATs) as adaptive, internal risk signals for damage-avoidance learning. Inspired by biological systems, the framework uses a two-level architecture: evolutionary optimization (outer loop) discovers afferent sensing architectures that enable effective policy learning, while reinforcement learning (inner loop) trains damage-avoidance policies using these signals. This formalizes afferent sensing as providing an inductive bias for efficient learning: architectures are selected based on their ability to enable effective learning (rather than directly minimizing damage). We provide theoretical convergence guarantees under smoothness and bounded-noise assumptions. We illustrate the general approach in the challenging context of biomechanical digital twins operating over long time horizons (multiple decades of the life-course). Here, we find that CAT-based evolved architectures achieve significantly higher efficiency and better age-robustness than hand-designed baselines, enabling policies that exhibit age-dependent behavioral adaptation (23% reduction in high-risk actions). Ablation studies validate CAT signals, evolution, and predictive discrepancy as essential. We release code and data for reproducibility.

Keywords

Cite

@article{arxiv.2602.04807,
  title  = {Evolving Afferent Architectures: Biologically-inspired Models for Damage-Avoidance Learning},
  author = {Wolfgang Maass and Sabine Janzen and Prajvi Saxena and Sach Mukherjee},
  journal= {arXiv preprint arXiv:2602.04807},
  year   = {2026}
}

Comments

16 pages, 6 figures

R2 v1 2026-07-01T09:36:24.052Z