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Emulating homeoplasticity phenomena with organic electrochemical devices
Authors
,
P Gkoupidenis
DA Koutsouras
GG Malliaras
Publication date
4 April 2018
Publisher
Abstract
Copyright © Materials Research Society 2018 Biologic neural networks are immersed in common electrolyte environment, and homeoplasticity or global factors of this environment are forcing specific normalization functions that regulate the overall network behavior. In this work, a common electrolyte is used to gate a grid of organic electrochemical devices. The electrolyte functions as a global parameter that controls collectively the device grid. Statistical analysis of the grid and the subsequent definition of global metrics reveal that the grid behaves similarly to a single device. This global control modulates the gain of the device grid, a phenomenon analog to multiplicative scaling in biologic networks. This work demonstrates the potential use of electrolytes as homeostatic media in neuromorphic device architectures
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Last time updated on 15/07/2020