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Auteurs principaux: Sakamoto, Keitaro, Sato, Issei
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2509.20829
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author Sakamoto, Keitaro
Sato, Issei
author_facet Sakamoto, Keitaro
Sato, Issei
contents The training dynamics of deep neural networks often defy expectations, even as these models form the foundation of modern machine learning. Two prominent examples are grokking, where test performance improves abruptly long after the training loss has plateaued, and the information bottleneck principle, where models progressively discard input information irrelevant to the prediction task as training proceeds. However, the mechanisms underlying these phenomena and their relations remain poorly understood. In this work, we present a unified explanation of such late-phase phenomena through the lens of neural collapse, which characterizes the geometry of learned representations. We show that the contraction of population within-class variance is a key factor underlying both grokking and information bottleneck, and relate this measure to the neural collapse measure defined on the training set. By analyzing the dynamics of neural collapse, we show that distinct time scales between fitting the training set and the progression of neural collapse account for the behavior of the late-phase phenomena. Finally, we validate our theoretical findings on multiple datasets and architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2509_20829
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Explaining Grokking and Information Bottleneck through Neural Collapse Emergence
Sakamoto, Keitaro
Sato, Issei
Machine Learning
The training dynamics of deep neural networks often defy expectations, even as these models form the foundation of modern machine learning. Two prominent examples are grokking, where test performance improves abruptly long after the training loss has plateaued, and the information bottleneck principle, where models progressively discard input information irrelevant to the prediction task as training proceeds. However, the mechanisms underlying these phenomena and their relations remain poorly understood. In this work, we present a unified explanation of such late-phase phenomena through the lens of neural collapse, which characterizes the geometry of learned representations. We show that the contraction of population within-class variance is a key factor underlying both grokking and information bottleneck, and relate this measure to the neural collapse measure defined on the training set. By analyzing the dynamics of neural collapse, we show that distinct time scales between fitting the training set and the progression of neural collapse account for the behavior of the late-phase phenomena. Finally, we validate our theoretical findings on multiple datasets and architectures.
title Explaining Grokking and Information Bottleneck through Neural Collapse Emergence
topic Machine Learning
url https://arxiv.org/abs/2509.20829