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Auteurs principaux: Ghavasieh, Arsham, Vila-Minana, Meritxell, Khurd, Akanksha, Beggs, John, Ortiz, Gerardo, Fortunato, Santo
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2509.22649
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author Ghavasieh, Arsham
Vila-Minana, Meritxell
Khurd, Akanksha
Beggs, John
Ortiz, Gerardo
Fortunato, Santo
author_facet Ghavasieh, Arsham
Vila-Minana, Meritxell
Khurd, Akanksha
Beggs, John
Ortiz, Gerardo
Fortunato, Santo
contents Deep neural networks and brains both learn and share superficial similarities: processing nodes are likened to neurons and adjustable weights are likened to modifiable synapses. But can a unified theoretical framework be found to underlie them both? Here we show that the equations used to describe neuronal avalanches in living brains can also be applied to cascades of activity in deep neural networks. These equations are derived from non-equilibrium statistical physics and show that deep neural networks learn best when poised between absorbing and active phases. Because these networks are strongly driven by inputs, however, they do not operate at a true critical point but within a quasi-critical regime -- one that still approximately satisfies crackling noise scaling relations. By training networks with different initializations, we show that maximal susceptibility is a more reliable predictor of learning than proximity to the critical point itself. This provides a blueprint for engineering improved network performance. Finally, using finite-size scaling we identify distinct universality classes, including Barkhausen noise and directed percolation. This theoretical framework demonstrates that universal features are shared by both biological and artificial neural networks.
format Preprint
id arxiv_https___arxiv_org_abs_2509_22649
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Toward a Physics of Deep Learning and Brains
Ghavasieh, Arsham
Vila-Minana, Meritxell
Khurd, Akanksha
Beggs, John
Ortiz, Gerardo
Fortunato, Santo
Disordered Systems and Neural Networks
Statistical Mechanics
Artificial Intelligence
Adaptation and Self-Organizing Systems
Biological Physics
Deep neural networks and brains both learn and share superficial similarities: processing nodes are likened to neurons and adjustable weights are likened to modifiable synapses. But can a unified theoretical framework be found to underlie them both? Here we show that the equations used to describe neuronal avalanches in living brains can also be applied to cascades of activity in deep neural networks. These equations are derived from non-equilibrium statistical physics and show that deep neural networks learn best when poised between absorbing and active phases. Because these networks are strongly driven by inputs, however, they do not operate at a true critical point but within a quasi-critical regime -- one that still approximately satisfies crackling noise scaling relations. By training networks with different initializations, we show that maximal susceptibility is a more reliable predictor of learning than proximity to the critical point itself. This provides a blueprint for engineering improved network performance. Finally, using finite-size scaling we identify distinct universality classes, including Barkhausen noise and directed percolation. This theoretical framework demonstrates that universal features are shared by both biological and artificial neural networks.
title Toward a Physics of Deep Learning and Brains
topic Disordered Systems and Neural Networks
Statistical Mechanics
Artificial Intelligence
Adaptation and Self-Organizing Systems
Biological Physics
url https://arxiv.org/abs/2509.22649