Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems

To determine the nonlinear autoregressive model with exogenous inputs (NARX) parameter values is not an easy task, even though NARX is reported to successfully identify nonlinear systems. Apart from the activation functions, number of layers, layer size, learning rate, and number of epochs, the numb...

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Main Authors: Nordin F.H., Nagi F.H., Zainul Abidin A.A.
Other Authors: 25930510500
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Published: 2023
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spelling my.uniten.dspace-300212023-12-29T15:44:02Z Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems Nordin F.H. Nagi F.H. Zainul Abidin A.A. 25930510500 56272534200 25824750400 Layer recurrent network Nonlinear autoregressive with exogenous inputs Nonlinear system identification Recurrent neural network Complex networks Identification (control systems) Network layers Polynomials Recurrent neural networks Activation functions Computational parameters Correlation coefficient Investigate and analyze Non-linear autoregressive with exogenous Nonlinear autoregressive model with exogenous input (NARX) Polynomial equation Recurrent networks Nonlinear systems To determine the nonlinear autoregressive model with exogenous inputs (NARX) parameter values is not an easy task, even though NARX is reported to successfully identify nonlinear systems. Apart from the activation functions, number of layers, layer size, learning rate, and number of epochs, the number of delays at the input and at the feedback loop need to also be determined. The layer recurrent network (LRN) is seen to have the potential to outperform NARX. However, not many papers have reported on using the LRN to identify nonlinear systems. Therefore, it is the aim of this paper to investigate and analyze the parametric evaluation of the LRN and NARX in identifying 3 different types of nonlinear systems. From the 3 nonlinear systems, the satellite's attitude state space is more complex compared to the sigmoid and polynomial equations. To ensure an unbiased comparison, a general guideline is used to select the parameter values in an organized manner. The LRN and NARX performance is analyzed based on the training and architecture parameters, mean squared errors, and correlation coefficient values. The results show that the LRN outperformed NARX in training quality, needs equal or fewer parameters that need to be determined through heuristic processes and equal or lower number of epochs, and produced a smaller training error compared to NARX, especially when identifying the satellite's attitude. This indicates that the LRN has the capability of identifying a more complex and nonlinear system compared to NARX. � T�bi?tak. Final 2023-12-29T07:44:02Z 2023-12-29T07:44:02Z 2013 Article 10.3906/elk-1107-12 2-s2.0-84880109328 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84880109328&doi=10.3906%2felk-1107-12&partnerID=40&md5=f72cc3b674699ced3cbb47f4c4057690 https://irepository.uniten.edu.my/handle/123456789/30021 21 4 1151 1165 All Open Access; Bronze Open Access Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Layer recurrent network
Nonlinear autoregressive with exogenous inputs
Nonlinear system identification
Recurrent neural network
Complex networks
Identification (control systems)
Network layers
Polynomials
Recurrent neural networks
Activation functions
Computational parameters
Correlation coefficient
Investigate and analyze
Non-linear autoregressive with exogenous
Nonlinear autoregressive model with exogenous input (NARX)
Polynomial equation
Recurrent networks
Nonlinear systems
spellingShingle Layer recurrent network
Nonlinear autoregressive with exogenous inputs
Nonlinear system identification
Recurrent neural network
Complex networks
Identification (control systems)
Network layers
Polynomials
Recurrent neural networks
Activation functions
Computational parameters
Correlation coefficient
Investigate and analyze
Non-linear autoregressive with exogenous
Nonlinear autoregressive model with exogenous input (NARX)
Polynomial equation
Recurrent networks
Nonlinear systems
Nordin F.H.
Nagi F.H.
Zainul Abidin A.A.
Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems
description To determine the nonlinear autoregressive model with exogenous inputs (NARX) parameter values is not an easy task, even though NARX is reported to successfully identify nonlinear systems. Apart from the activation functions, number of layers, layer size, learning rate, and number of epochs, the number of delays at the input and at the feedback loop need to also be determined. The layer recurrent network (LRN) is seen to have the potential to outperform NARX. However, not many papers have reported on using the LRN to identify nonlinear systems. Therefore, it is the aim of this paper to investigate and analyze the parametric evaluation of the LRN and NARX in identifying 3 different types of nonlinear systems. From the 3 nonlinear systems, the satellite's attitude state space is more complex compared to the sigmoid and polynomial equations. To ensure an unbiased comparison, a general guideline is used to select the parameter values in an organized manner. The LRN and NARX performance is analyzed based on the training and architecture parameters, mean squared errors, and correlation coefficient values. The results show that the LRN outperformed NARX in training quality, needs equal or fewer parameters that need to be determined through heuristic processes and equal or lower number of epochs, and produced a smaller training error compared to NARX, especially when identifying the satellite's attitude. This indicates that the LRN has the capability of identifying a more complex and nonlinear system compared to NARX. � T�bi?tak.
author2 25930510500
author_facet 25930510500
Nordin F.H.
Nagi F.H.
Zainul Abidin A.A.
format Article
author Nordin F.H.
Nagi F.H.
Zainul Abidin A.A.
author_sort Nordin F.H.
title Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems
title_short Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems
title_full Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems
title_fullStr Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems
title_full_unstemmed Comparison study of computational parameter values between LRN and NARX in identifying nonlinear systems
title_sort comparison study of computational parameter values between lrn and narx in identifying nonlinear systems
publishDate 2023
_version_ 1806428309753430016
score 13.222552