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Shaping Dynamics With Multiple Populations in Low-Rank Recurrent Networks

Beiran, M, Dubreuil, AM, Valente, A, Mastrogiuseppe, F, Ostojic, S

2021UCL Discovery (University College London)75 citations

Abstract

An emerging paradigm proposes that neural computations can be understood at the level of dynamic systems that govern low-dimensional trajectories of collective neural activity. How the connectivity structure of a network determines the emergent dynamical system, however, remains to be clarified. Here we consider a novel class of models, gaussian-mixture, low-rank recurrent networks in which the rank of the connectivity matrix and the number of statistically defined populations are independent hyperparameters. We show that the resulting collective dynamics form a dynamical system, where the rank sets the dimensionality and the population structure shapes the dynamics. In particular, the collective dynamics can be described in terms of a simplified effective circuit of interacting latent variables. While having a single global population strongly restricts the possible dynamics, we demonstrate that if the number of populations is large enough, a rank R network can approximate any R-dimensional dynamical system.

Topics & Concepts

Curse of dimensionalityRank (graph theory)Dynamical systems theoryStatistical physicsPopulationGaussianComputationDynamical system (definition)Computer scienceMathematicsArtificial intelligencePhysicsAlgorithmCombinatoricsSociologyQuantum mechanicsDemographyNeural dynamics and brain functionNeural Networks and Reservoir ComputingNeural Networks and Applications
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