research-article

Computational capabilities of recurrent NARX neural networks

Authors:

H. T. Siegelmann,

B. G. Horne,

C. L. GilesAuthors Info & Claims

IEEE Transactions on Systems, Man, and Cybernetics, Part B: Cybernetics, Volume 27, Issue 2

Pages 208 - 215

https://doi.org/10.1109/3477.558801

Published: 01 April 1997 Publication History

Abstract

Recently, fully connected recurrent neural networks have been proven to be computationally rich-at least as powerful as Turing machines. This work focuses on another network which is popular in control applications and has been found to be very effective at learning a variety of problems. These networks are based upon Nonlinear AutoRegressive models with eXogenous Inputs (NARX models), and are therefore called NARX networks. As opposed to other recurrent networks, NARX networks have a limited feedback which comes only from the output neuron rather than from hidden states. They are formalized by y(t)=Ψ(u(t-n_u), ..., u(t-1), u(t), y(t-n_y), ..., y(t-1)) where u(t) and y(t) represent input and output of the network at time t, n_u and n_y are the input and output order, and the function Ψ is the mapping performed by a Multilayer Perceptron. We constructively prove that the NARX networks with a finite number of parameters are computationally as strong as fully connected recurrent networks and thus Turing machines. We conclude that in theory one can use the NARX models, rather than conventional recurrent networks without any computational loss even though their feedback is limited. Furthermore, these results raise the issue of what amount of feedback or recurrence is necessary for any network to be Turing equivalent and what restrictions on feedback limit computational power

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Computational capabilities of recurrent NARX neural networks

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cover image IEEE Transactions on Systems, Man, and Cybernetics, Part B: Cybernetics

IEEE Transactions on Systems, Man, and Cybernetics, Part B: Cybernetics Volume 27, Issue 2

April 1997

202 pages

ISSN:1083-4419

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IEEE Press

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Published: 01 April 1997

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Li KPríncipe J(2022)Functional Bayesian FilterIEEE Transactions on Signal Processing10.1109/TSP.2021.313227770(57-71)Online publication date: 1-Jan-2022
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