Learning Time-Scales in Two-Layers Neural Networks

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Raphaël Berthier, Andrea Montanari, Kangjie Zhou
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Abstract

Gradient-based learning in multi-layer neural networks displays a number of striking features. In particular, the decrease rate of empirical risk is non-monotone even after averaging over large batches. Long plateaus in which one observes barely any progress alternate with intervals of rapid decrease. These successive phases of learning often take place on very different time scales. Finally, models learnt in an early phase are typically ‘simpler’ or ‘easier to learn’ although in a way that is difficult to formalize. Although theoretical explanations of these phenomena have been put forward, each of them captures at best certain specific regimes. In this paper, we study the gradient flow dynamics of a wide two-layer neural network in high-dimension, when data are distributed according to a single-index model (i.e., the target function depends on a one-dimensional projection of the covariates). Based on a mixture of new rigorous results, non-rigorous mathematical derivations, and numerical simulations, we propose a scenario for the learning dynamics in this setting. In particular, the proposed evolution exhibits separation of timescales and intermittency. These behaviors arise naturally because the population gradient flow can be recast as a singularly perturbed dynamical system.

Abstract Image

两层神经网络的学习时标
多层神经网络中基于梯度的学习显示出许多显著特点。特别是,经验风险的下降率即使在对大量批次进行平均后也是非单调的。在漫长的高原期与快速下降期交替出现,在高原期几乎看不到任何进展。这些连续的学习阶段往往发生在非常不同的时间尺度上。最后,在早期阶段学习的模型通常 "更简单 "或 "更容易学习",尽管这种学习方式很难正规化。尽管对这些现象已经提出了理论解释,但每种解释最多只能捕捉到某些特定的机制。在本文中,我们研究了当数据按照单指数模型分布时(即目标函数取决于协变量的一维投影),宽双层神经网络在高维条件下的梯度流动态。基于新的严格结果、非严格数学推导和数值模拟,我们提出了在这种情况下的学习动力学方案。特别是,所提出的进化表现出时标分离和间歇性。由于种群梯度流可以重塑为奇异扰动动态系统,这些行为自然而然地产生了。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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