English

Asymmetric Scaling Laws from Sparse Features

Machine Learning 2026-05-25 v1 Disordered Systems and Neural Networks Machine Learning Statistics Theory Statistics Theory

Abstract

We introduce a model for neural scaling laws under sparse activations. In the model, test loss is often dominated by rare coordinates that are never observed in the training input. This mechanism induces a novel bottleneck absent from dense models. We derive the asymptotic population loss in both the underparameterized and overparameterized regimes, and show that the loss exhibits a double-descent peak near the interpolation threshold -- where the number of parameters is just sufficient to fit the training data -- resulting in a loss curve governed by two distinct scaling exponents -- one for the overparameterized regime and one for the underparameterized regime -- with a gap determined by the degree of sparsity. Additionally, we derive a compute-optimal frontier that favors increasing dataset size over model capacity under fixed compute budgets. We also analyze gradient-descent dynamics and identify a scaling law for the probability that fixed-step gradient descent becomes unstable. We further show that the sparsity-induced effect persists under nonlinear activations.

Keywords

Cite

@article{arxiv.2605.23591,
  title  = {Asymmetric Scaling Laws from Sparse Features},
  author = {John Sous and Michael Winer},
  journal= {arXiv preprint arXiv:2605.23591},
  year   = {2026}
}