English

Range, not Independence, Drives Modularity in Biologically Inspired Representations

Neurons and Cognition 2025-08-05 v4 Artificial Intelligence Machine Learning Neural and Evolutionary Computing

Abstract

Why do biological and artificial neurons sometimes modularise, each encoding a single meaningful variable, and sometimes entangle their representation of many variables? In this work, we develop a theory of when biologically inspired networks -- those that are nonnegative and energy efficient -- modularise their representation of source variables (sources). We derive necessary and sufficient conditions on a sample of sources that determine whether the neurons in an optimal biologically-inspired linear autoencoder modularise. Our theory applies to any dataset, extending far beyond the case of statistical independence studied in previous work. Rather we show that sources modularise if their support is ``sufficiently spread''. From this theory, we extract and validate predictions in a variety of empirical studies on how data distribution affects modularisation in nonlinear feedforward and recurrent neural networks trained on supervised and unsupervised tasks. Furthermore, we apply these ideas to neuroscience data, showing that range independence can be used to understand the mixing or modularising of spatial and reward information in entorhinal recordings in seemingly conflicting experiments. Further, we use these results to suggest alternate origins of mixed-selectivity, beyond the predominant theory of flexible nonlinear classification. In sum, our theory prescribes precise conditions on when neural activities modularise, providing tools for inducing and elucidating modular representations in brains and machines.

Keywords

Cite

@article{arxiv.2410.06232,
  title  = {Range, not Independence, Drives Modularity in Biologically Inspired Representations},
  author = {Will Dorrell and Kyle Hsu and Luke Hollingsworth and Jin Hwa Lee and Jiajun Wu and Chelsea Finn and Peter E Latham and Tim EJ Behrens and James CR Whittington},
  journal= {arXiv preprint arXiv:2410.06232},
  year   = {2025}
}

Comments

37 pages, 12 figures. WD and KH contributed equally; LH and JHL contributed equally

R2 v1 2026-06-28T19:13:19.655Z