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Main Authors: Walker, Thomas, Roddenberry, T. Mitchell, Humayun, Ahmed Imtiaz, Balestriero, Randall, Baraniuk, Richard
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.08464
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author Walker, Thomas
Roddenberry, T. Mitchell
Humayun, Ahmed Imtiaz
Balestriero, Randall
Baraniuk, Richard
author_facet Walker, Thomas
Roddenberry, T. Mitchell
Humayun, Ahmed Imtiaz
Balestriero, Randall
Baraniuk, Richard
contents The manifold hypothesis (MH) is often used to explain how machine learning can overcome the curse of dimensionality. However, the MH is only applicable in regimes where the training data provides a sufficiently dense sample of the underlying low-dimensional data manifold, or where such a low-dimensional manifold is conceivably present. We describe the regimes where the MH is not applicable as sparse. In this paper, we demonstrate that models succeed in the sparse regime by exploiting a highly structured local geometry, a property we formalize as normal alignment. We prove that normal-aligned classifiers -- whose input-output Jacobians are rank-one and align perfectly with the training data -- minimize the training objective under norm constraints and achieve maximal local robustness under a non-zero Jacobian constraint. For continuous piecewise-affine deep networks, normal alignment manifests geometrically as centroid alignment within the network's induced power diagram partition and results from the feature-learning regime. Motivated by these theoretical insights, we introduce GrokAlign, a regularization strategy that actively induces normal alignment. We demonstrate that GrokAlign significantly accelerates the training dynamics of deep networks relevant to the grokking phenomenon. Furthermore, we apply the principle of normal alignment to Recursive Feature Machines (RFMs) to introduce Recursive Feature Alignment Machines (RFAMs). We show that RFAMs exhibit greater adversarial robustness compared to RFMs when trained on tabular data.
format Preprint
id arxiv_https___arxiv_org_abs_2605_08464
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The Geometric Structure of Models Learning Sparse Data
Walker, Thomas
Roddenberry, T. Mitchell
Humayun, Ahmed Imtiaz
Balestriero, Randall
Baraniuk, Richard
Machine Learning
The manifold hypothesis (MH) is often used to explain how machine learning can overcome the curse of dimensionality. However, the MH is only applicable in regimes where the training data provides a sufficiently dense sample of the underlying low-dimensional data manifold, or where such a low-dimensional manifold is conceivably present. We describe the regimes where the MH is not applicable as sparse. In this paper, we demonstrate that models succeed in the sparse regime by exploiting a highly structured local geometry, a property we formalize as normal alignment. We prove that normal-aligned classifiers -- whose input-output Jacobians are rank-one and align perfectly with the training data -- minimize the training objective under norm constraints and achieve maximal local robustness under a non-zero Jacobian constraint. For continuous piecewise-affine deep networks, normal alignment manifests geometrically as centroid alignment within the network's induced power diagram partition and results from the feature-learning regime. Motivated by these theoretical insights, we introduce GrokAlign, a regularization strategy that actively induces normal alignment. We demonstrate that GrokAlign significantly accelerates the training dynamics of deep networks relevant to the grokking phenomenon. Furthermore, we apply the principle of normal alignment to Recursive Feature Machines (RFMs) to introduce Recursive Feature Alignment Machines (RFAMs). We show that RFAMs exhibit greater adversarial robustness compared to RFMs when trained on tabular data.
title The Geometric Structure of Models Learning Sparse Data
topic Machine Learning
url https://arxiv.org/abs/2605.08464