This title appears in the Scientific Report : 2022 
Gell-Mann–Low Criticality in Neural Networks
Tiberi, Lorenzo (Corresponding author)
Stapmanns, Jonas / Kühn, Tobias / Luu, Thomas / Dahmen, David / Helias, Moritz
Computational and Systems Neuroscience; INM-6
Theorie der starken Wechselwirkung; IKP-3
Theorie der Starken Wechselwirkung; IAS-4
Theoretical Neuroscience; IAS-6
Jara-Institut Brain structure-function relationships; INM-10
Physical review letters, 128 (2022) 16, S. 168301
College Park, Md. APS 2022
10.1103/PhysRevLett.128.168301
Journal Article
Transparent Deep Learning with Renormalized Flows
Human Brain Project Specific Grant Agreement 3
Neuroscientific Foundations
OpenAccess
Please use the identifier: http://dx.doi.org/10.1103/PhysRevLett.128.168301 in citations.
Please use the identifier: http://hdl.handle.net/2128/32544 in citations.


Criticality is deeply related to optimal computational capacity. The lack of a renormalized theory of critical brain dynamics, however, so far limits insights into this form of biological information processing to mean-field results. These methods neglect a key feature of critical systems: the interaction between degrees of freedom across all length scales, required for complex nonlinear computation. We present a renormalized theory of a prototypical neural field theory, the stochastic Wilson-Cowan equation. We compute the flow of couplings, which parametrize interactions on increasing length scales. Despite similarities with the Kardar-Parisi-Zhang model, the theory is of a Gell-Mann–Low type, the archetypal form of a renormalizable quantum field theory. Here, nonlinear couplings vanish, flowing towards the Gaussian fixed point, but logarithmically slowly, thus remaining effective on most scales. We show this critical structure of interactions to implement a desirable trade-off between linearity, optimal for information storage, and nonlinearity, required for computation.