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Perturbing low dimensional activity manifolds in spiking neuronal networks.

Authors :
Wärnberg, Emil
Kumar, Arvind
Source :
PLoS Computational Biology; 5/31/2019, Vol. 15 Issue 5, p1-23, 23p, 1 Color Photograph, 2 Diagrams, 3 Graphs
Publication Year :
2019

Abstract

Several recent studies have shown that neural activity in vivo tends to be constrained to a low-dimensional manifold. Such activity does not arise in simulated neural networks with homogeneous connectivity and it has been suggested that it is indicative of some other connectivity pattern in neuronal networks. In particular, this connectivity pattern appears to be constraining learning so that only neural activity patterns falling within the intrinsic manifold can be learned and elicited. Here, we use three different models of spiking neural networks (FORCE learning, the Neural Engineering Framework and Efficient Coding) to demonstrate how the intrinsic manifold can be made a direct consequence of the circuit connectivity. Using this relationship between the circuit connectivity and the intrinsic manifold, we show that learning patterns outside the intrinsic manifold corresponds to much larger changes in synaptic weights than learning patterns within the intrinsic manifold. Assuming larger changes to synaptic weights requires extensive learning, this observation provides an explanation of why learning is easier when it does not require the neural activity to leave its intrinsic manifold. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
1553734X
Volume :
15
Issue :
5
Database :
Complementary Index
Journal :
PLoS Computational Biology
Publication Type :
Academic Journal
Accession number :
136757484
Full Text :
https://doi.org/10.1371/journal.pcbi.1007074