作为旋转模型的神经网络:通过训练从玻璃到隐藏秩序

Richard Barney, Michael Winer, Victor Galitski
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引用次数: 0

摘要

我们探索了神经网络(NN)与统计机械自旋模型之间的一一对应关系,其中神经元映射为伊辛自旋,权重映射为自旋-自旋耦合。训练神经网络的过程产生了以训练时间为参数的自旋哈密顿族。我们研究了训练过程中的磁相和熔化转变温度。首先,我们通过分析证明了训练前的共同初始状态--具有独立随机权重的 NN--映射为经典谢林顿-柯克帕特里克自旋玻璃的分层版本,表现出复制对称性破缺。我们计算了自旋玻璃到准磁体的转变温度。此外,我们还利用 Thouless-Anderson-Palmer (TAP) 方程--一种分析随机系统能量极小值景观的理论技术--确定了在 MNIST 数据集上训练的两类 NN(一类是连续激活,另一类是二值化激活)上磁性相位的演变。这两种 NN 得到了相似的结果,显示了自旋玻璃的快速破坏和具有隐序的相的出现,其熔化转变温度 $T_c$ 在训练时间内呈幂律增长。我们还讨论了自旋系统键矩阵频谱在 "富学习 "与 "懒学习 "背景下的特性。我们认为,这种关于 NN 的统计力学观点为训练过程提供了一个有用的统一视角,训练过程可以看作是选择和加强与训练任务相关的对称性破坏状态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Neural Networks as Spin Models: From Glass to Hidden Order Through Training
We explore a one-to-one correspondence between a neural network (NN) and a statistical mechanical spin model where neurons are mapped to Ising spins and weights to spin-spin couplings. The process of training an NN produces a family of spin Hamiltonians parameterized by training time. We study the magnetic phases and the melting transition temperature as training progresses. First, we prove analytically that the common initial state before training--an NN with independent random weights--maps to a layered version of the classical Sherrington-Kirkpatrick spin glass exhibiting a replica symmetry breaking. The spin-glass-to-paramagnet transition temperature is calculated. Further, we use the Thouless-Anderson-Palmer (TAP) equations--a theoretical technique to analyze the landscape of energy minima of random systems--to determine the evolution of the magnetic phases on two types of NNs (one with continuous and one with binarized activations) trained on the MNIST dataset. The two NN types give rise to similar results, showing a quick destruction of the spin glass and the appearance of a phase with a hidden order, whose melting transition temperature $T_c$ grows as a power law in training time. We also discuss the properties of the spectrum of the spin system's bond matrix in the context of rich vs. lazy learning. We suggest that this statistical mechanical view of NNs provides a useful unifying perspective on the training process, which can be viewed as selecting and strengthening a symmetry-broken state associated with the training task.
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