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Dimension of Activity in Random Neural Networks

David G. Clark, L. F. Abbott, Ashok Litwin-Kumar

2023Physical Review Letters42 citationsDOI

Abstract

Neural networks are high-dimensional nonlinear dynamical systems that process information through the coordinated activity of many connected units. Understanding how biological and machine-learning networks function and learn requires knowledge of the structure of this coordinated activity, information contained, for example, in cross covariances between units. Self-consistent dynamical mean field theory (DMFT) has elucidated several features of random neural networks---in particular, that they can generate chaotic activity---however, a calculation of cross covariances using this approach has not been provided. Here, we calculate cross covariances self-consistently via a two-site cavity DMFT. We use this theory to probe spatiotemporal features of activity coordination in a classic random-network model with independent and identically distributed (i.i.d.) couplings, showing an extensive but fractionally low effective dimension of activity and a long population-level timescale. Our formulas apply to a wide range of single-unit dynamics and generalize to non-i.i.d. couplings. As an example of the latter, we analyze the case of partially symmetric couplings.

Topics & Concepts

Artificial neural networkStatistical physicsDimension (graph theory)Independent and identically distributed random variablesChaoticNonlinear systemRange (aeronautics)Computer scienceFunction (biology)PhysicsRandom variableArtificial intelligenceMathematicsQuantum mechanicsPure mathematicsStatisticsComposite materialEvolutionary biologyMaterials scienceBiologyNeural dynamics and brain functionNeural Networks and Reservoir ComputingNeural Networks and Applications
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