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Autori principali: Aaronson, Scott, Lee, Lin Lin, Li, Jiawei
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2603.07388
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author Aaronson, Scott
Lee, Lin Lin
Li, Jiawei
author_facet Aaronson, Scott
Lee, Lin Lin
Li, Jiawei
contents Explaining out-of-distribution generalization has been a central problem in epistemology since Goodman's "grue" puzzle in 1946. Today it's a central problem in machine learning, including AI alignment. Here we propose a principled account of OOD generalization with three main ingredients. First, the world is always presented to experience not as an amorphous mass, but via distinguished features (for example, visual and auditory channels). Second, Occam's Razor favors hypotheses that are "sparse," meaning that they depend on as few features as possible. Third, sparse hypotheses will generalize from a training to a test distribution, provided the two distributions sufficiently overlap on their restrictions to the features that are either actually relevant or hypothesized to be. The two distributions could diverge arbitrarily on other features. We prove a simple theorem that formalizes the above intuitions, generalizing the classic sample complexity bound of Blumer et al. to an OOD context. We then generalize sparse classifiers to subspace juntas, where the ground truth classifier depends solely on a low-dimensional linear subspace of the features.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07388
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Sparsity and Out-of-Distribution Generalization
Aaronson, Scott
Lee, Lin Lin
Li, Jiawei
Machine Learning
Artificial Intelligence
Explaining out-of-distribution generalization has been a central problem in epistemology since Goodman's "grue" puzzle in 1946. Today it's a central problem in machine learning, including AI alignment. Here we propose a principled account of OOD generalization with three main ingredients. First, the world is always presented to experience not as an amorphous mass, but via distinguished features (for example, visual and auditory channels). Second, Occam's Razor favors hypotheses that are "sparse," meaning that they depend on as few features as possible. Third, sparse hypotheses will generalize from a training to a test distribution, provided the two distributions sufficiently overlap on their restrictions to the features that are either actually relevant or hypothesized to be. The two distributions could diverge arbitrarily on other features. We prove a simple theorem that formalizes the above intuitions, generalizing the classic sample complexity bound of Blumer et al. to an OOD context. We then generalize sparse classifiers to subspace juntas, where the ground truth classifier depends solely on a low-dimensional linear subspace of the features.
title Sparsity and Out-of-Distribution Generalization
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2603.07388