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Local EGOP for Continuous Index Learning

Machine Learning 2026-02-10 v4 Machine Learning

Abstract

We introduce the setting of continuous index learning, in which a function of many variables varies only along a small number of directions at each point. For efficient estimation, it is beneficial for a learning algorithm to adapt, near each point xx, to the subspace that captures the local variability of the function ff. We pose this task as kernel adaptation along a manifold with noise, and introduce Local EGOP learning, a recursive algorithm that utilizes the Expected Gradient Outer Product (EGOP) quadratic form as both a metric and inverse-covariance of our target distribution. We prove that Local EGOP learning adapts to the regularity of the function of interest, showing that under a supervised noisy manifold hypothesis, intrinsic dimensional learning rates are achieved for arbitrarily high-dimensional noise. Empirically, we compare our algorithm to the feature learning capabilities of deep learning. Additionally, we demonstrate improved regression quality compared to two-layer neural networks in the continuous single-index setting.

Keywords

Cite

@article{arxiv.2601.07061,
  title  = {Local EGOP for Continuous Index Learning},
  author = {Alex Kokot and Anand Hemmady and Vydhourie Thiyageswaran and Marina Meila},
  journal= {arXiv preprint arXiv:2601.07061},
  year   = {2026}
}
R2 v1 2026-07-01T08:59:49.528Z