Cellular computational networksaA scalable architecture for learning the dynamics of large networked systems

Cellular computational networksaA scalable architecture for learning the dynamics of large networked systems

Neural networks for implementing large networked systems such as smart electric power grids consist of multiple inputs and outputs. Many outputs lead to a greater number of parameters to be adapted. Each additional variable increases the dimensionality of the problem and hence learning becomes a cha...

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Bibliographic Details
Published in:Neural networks Vol. 50; pp. 120 - 123
Main Authors: Luitel, Bipul, Venayagamoorthy, Ganesh
Format: Journal Article
Language:English
Published: 01-02-2014
Online Access:Get full text
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Summary:Neural networks for implementing large networked systems such as smart electric power grids consist of multiple inputs and outputs. Many outputs lead to a greater number of parameters to be adapted. Each additional variable increases the dimensionality of the problem and hence learning becomes a challenge. Cellular computational networks (CCNs) are a class of sparsely connected dynamic recurrent networks (DRNs). By proper selection of a set of input elements for each output variable in a given application, a DRN can be modified into a CCN which significantly reduces the complexity of the neural network and allows use of simple training methods for independent learning in each cell thus making it scalable. This article demonstrates this concept of developing a CCN using dimensionality reduction in a DRN for scalability and better performance. The concept has been analytically explained and empirically verified through application.
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ISSN:0893-6080
DOI:10.1016/j.neunet.2013.11.001