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Papers/The Weight Gram Matrix Captures Sequential Feature Linearization in Deep Networks
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The Weight Gram Matrix Captures Sequential Feature Linearization in Deep Networks

May 7, 2026

arXiv
Abstract

Understanding how deep neural networks learn representations remains a central challenge in machine learning theory. In this work, we propose a feature-centric framework for analyzing neural network training by relating weight updates to feature evolution. We introduce a simple identity, the Feature Learning Equation, which identifies the weight Gram matrix as the key object capturing feature dynamics. This enables us to interpret gradient descent as implicitly inducing a hypothetical evolution of features, whose covariance structure - termed the Virtual Covariance - characterizes how representations evolve during training. Building on this perspective, we introduce Target Linearity, a measure quantifying the linear alignment between features and targets. By analyzing the training and layer-wise dynamics, we show that deep networks learn to sequentially transform representations toward target-linear structure. This linearization perspective provides a unified interpretation of several empirical phenomena, including Neural Collapse and linear interpolation in generative models.

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Authors
Taehun Cha, Daniel Beaglehole, Adityanarayanan Radhakrishnan, Donghun Lee
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arXiv:2605.06258