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Neural network Hessian eigenvalues explained by approximate symmetries

Researchers have developed a new explanation for the numerous near-zero eigenvalues of the Hessian matrix in neural networks. They propose that these vanishing eigenvalues stem from approximate symmetries within the network's parameterization, which they term weakly lifted pseudo-Goldstone modes. In deep linear networks, these symmetries are exact, leading to flat directions and zero modes. The introduction of a rectifier nonlinearity, like ReLU, perturbs these symmetries, causing them to break weakly. The study demonstrates this mechanism in various network architectures, including a two-layer student-teacher model and a network trained on CIFAR-10, suggesting the findings extend beyond fully connected layers to convolutional networks. AI

IMPACT Provides a theoretical framework for understanding the loss landscape geometry in neural networks, potentially aiding in optimization and model design.

RANK_REASON The cluster contains an academic paper detailing a new theoretical finding in machine learning. [lever_c_demoted from research: ic=1 ai=1.0]

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Neural network Hessian eigenvalues explained by approximate symmetries

COVERAGE [1]

  1. arXiv cs.LG TIER_1 English(EN) · Marcel K\"uhn, Bernd Rosenow ·

    Explaining Near-Zero Hessian Eigenvalues Through Approximate Symmetries in Neural Networks

    arXiv:2607.07845v1 Announce Type: new Abstract: The Hessian of the training loss governs the local geometry of the loss landscape, yet despite existing explanations for its largest eigenvalues, the origin of the vast multitude of vanishingly small eigenvalues remains elusive. We …