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arXiv 提交日期: 2026-07-05
📄 Abstract - Broken Ergodicity and the Violation of the Fluctuation-Dissipation Theorem Lead to Generalization Beyond Overfitting in Machine Learning

The remarkable ability of modern neural networks to generalize improves with increasing network capacity, even when the number of model parameters or effective degrees of freedom exceeds the number of training data points. This phenomenon is all the more surprising given that generalization error diverges when the number of model parameters approaches a critical value from below. Here we use dynamical mean field theory to show that this so-called "double descent" behavior is the outcome of a phase transition in the stochastic field theory describing the training process. We calculate the critical exponents and scaling function of the double descent phase transition, and show that it is marked by a breakdown of the fluctuation-dissipation theorem associated with broken ergodicity. The corresponding response function has the same functional form as the simple London model of the superconducting transition, with the rigidity of the wave function corresponding to the neural network's ability to generalize accurately.

顶级标签: theory machine learning model evaluation
详细标签: double descent generalization phase transition mean field theory fluctuation-dissipation theorem 或 搜索:

打破遍历性与涨落-耗散定理的违反导致机器学习超越过拟合的泛化能力 / Broken Ergodicity and the Violation of the Fluctuation-Dissipation Theorem Lead to Generalization Beyond Overfitting in Machine Learning


1️⃣ 一句话总结

这篇论文利用动力学平均场理论揭示了神经网络在参数数量超过训练数据点时仍能良好泛化的“双下降”现象,实际上是一种由训练过程随机场理论中的相变引起的,该相变破坏了涨落-耗散定理和遍历性,其响应函数与超导转变中的伦敦模型形式相同,从而解释了神经网络为何能超越过拟合而实现准确泛化。

源自 arXiv: 2607.04135