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Hauptverfasser: Landry, Nicholas W., Hyde, Beckett R., Perez, Jake C., Shaheen, Sean E., Restrepo, Juan G.
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2408.09223
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author Landry, Nicholas W.
Hyde, Beckett R.
Perez, Jake C.
Shaheen, Sean E.
Restrepo, Juan G.
author_facet Landry, Nicholas W.
Hyde, Beckett R.
Perez, Jake C.
Shaheen, Sean E.
Restrepo, Juan G.
contents Efficient and accurate prediction of physical systems is important even when the rules of those systems cannot be easily learned. Reservoir computing, a type of recurrent neural network with fixed nonlinear units, is one such prediction method and is valued for its ease of training. Organic electrochemical transistors (OECTs) are physical devices with nonlinear transient properties that can be used as the nonlinear units of a reservoir computer. We present a theoretical framework for simulating reservoir computers using OECTs as the non-linear units as a test bed for designing physical reservoir computers. We present a proof of concept demonstrating that such an implementation can accurately predict the Lorenz attractor with comparable performance to standard reservoir computer implementations. We explore the effect of operating parameters and find that the prediction performance strongly depends on the pinch-off voltage of the OECTs.
format Preprint
id arxiv_https___arxiv_org_abs_2408_09223
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A theoretical framework for reservoir computing on networks of organic electrochemical transistors
Landry, Nicholas W.
Hyde, Beckett R.
Perez, Jake C.
Shaheen, Sean E.
Restrepo, Juan G.
Neural and Evolutionary Computing
Efficient and accurate prediction of physical systems is important even when the rules of those systems cannot be easily learned. Reservoir computing, a type of recurrent neural network with fixed nonlinear units, is one such prediction method and is valued for its ease of training. Organic electrochemical transistors (OECTs) are physical devices with nonlinear transient properties that can be used as the nonlinear units of a reservoir computer. We present a theoretical framework for simulating reservoir computers using OECTs as the non-linear units as a test bed for designing physical reservoir computers. We present a proof of concept demonstrating that such an implementation can accurately predict the Lorenz attractor with comparable performance to standard reservoir computer implementations. We explore the effect of operating parameters and find that the prediction performance strongly depends on the pinch-off voltage of the OECTs.
title A theoretical framework for reservoir computing on networks of organic electrochemical transistors
topic Neural and Evolutionary Computing
url https://arxiv.org/abs/2408.09223