Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Tovey, Samuel, Krippendorf, Sven, Spannowsky, Michael, Nikolaou, Konstantin, Holm, Christian
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2410.07451
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866914969206915072
author Tovey, Samuel
Krippendorf, Sven
Spannowsky, Michael
Nikolaou, Konstantin
Holm, Christian
author_facet Tovey, Samuel
Krippendorf, Sven
Spannowsky, Michael
Nikolaou, Konstantin
Holm, Christian
contents This work presents a novel means for understanding learning dynamics and scaling relations in neural networks. We show that certain measures on the spectrum of the empirical neural tangent kernel, specifically entropy and trace, yield insight into the representations learned by a neural network and how these can be improved through architecture scaling. These results are demonstrated first on test cases before being shown on more complex networks, including transformers, auto-encoders, graph neural networks, and reinforcement learning studies. In testing on a wide range of architectures, we highlight the universal nature of training dynamics and further discuss how it can be used to understand the mechanisms behind learning in neural networks. We identify two such dominant mechanisms present throughout machine learning training. The first, information compression, is seen through a reduction in the entropy of the NTK spectrum during training, and occurs predominantly in small neural networks. The second, coined structure formation, is seen through an increasing entropy and thus, the creation of structure in the neural network representations beyond the prior established by the network at initialization. Due to the ubiquity of the latter in deep neural network architectures and its flexibility in the creation of feature-rich representations, we argue that this form of evolution of the network's entropy be considered the onset of a deep learning regime.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07451
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Collective variables of neural networks: empirical time evolution and scaling laws
Tovey, Samuel
Krippendorf, Sven
Spannowsky, Michael
Nikolaou, Konstantin
Holm, Christian
Machine Learning
Computational Physics
This work presents a novel means for understanding learning dynamics and scaling relations in neural networks. We show that certain measures on the spectrum of the empirical neural tangent kernel, specifically entropy and trace, yield insight into the representations learned by a neural network and how these can be improved through architecture scaling. These results are demonstrated first on test cases before being shown on more complex networks, including transformers, auto-encoders, graph neural networks, and reinforcement learning studies. In testing on a wide range of architectures, we highlight the universal nature of training dynamics and further discuss how it can be used to understand the mechanisms behind learning in neural networks. We identify two such dominant mechanisms present throughout machine learning training. The first, information compression, is seen through a reduction in the entropy of the NTK spectrum during training, and occurs predominantly in small neural networks. The second, coined structure formation, is seen through an increasing entropy and thus, the creation of structure in the neural network representations beyond the prior established by the network at initialization. Due to the ubiquity of the latter in deep neural network architectures and its flexibility in the creation of feature-rich representations, we argue that this form of evolution of the network's entropy be considered the onset of a deep learning regime.
title Collective variables of neural networks: empirical time evolution and scaling laws
topic Machine Learning
Computational Physics
url https://arxiv.org/abs/2410.07451