2025-07-19 東京大学
森林火災(上)と、ディープニューラルネットワークにおける人工ニューロンの活動(下)の類似性。
<関連情報>
- https://www.s.u-tokyo.ac.jp/ja/press/10865/
- https://journals.aps.org/prresearch/abstract/10.1103/jp61-6sp2
人工深層ニューラルネットワークにおける吸収相転移の普遍的スケーリング則 Universal scaling laws of absorbing phase transitions in artificial deep neural networks
Keiichi Tamai, Tsuyoshi Okubo, Truong Vinh Truong Duy, Naotake Natori, and Synge Todo
Physical Review Research Published: 18 July, 2025
DOI: https://doi.org/10.1103/jp61-6sp2
Abstract
We demonstrate that conventional artificial deep neural networks operating near the phase boundary of the signal propagation dynamics—also known as the edge of chaos—exhibit universal scaling laws of absorbing phase transitions in nonequilibrium statistical mechanics. We exploit the fully deterministic nature of the propagation dynamics to elucidate an analogy between a signal collapse in the neural networks and an absorbing state (a state that the system can enter but cannot escape from). Our numerical results indicate that the multilayer perceptrons and the convolutional neural networks belong to the mean-field and the directed percolation universality classes, respectively. Also, the finite-size scaling is successfully applied, suggesting a potential connection to the depth-width trade-off in deep learning. Furthermore, our analysis of the training dynamics under the gradient descent reveals that hyperparameter tuning to the phase boundary is necessary but insufficient for achieving optimal generalization in deep networks. Remarkably, nonuniversal metric factors associated with the scaling laws are shown to play a significant role in concretizing the above observations. These findings highlight the usefulness of the notion of criticality for analyzing the behavior of artificial deep neural networks and offer new insights toward a unified understanding of the essential relationship between criticality and intelligence.
