Low-Computational-Complexity Zeroing Neural Network Model for Solving Systems of Dynamic Nonlinear Equations

Kangze Zheng, Shuai Li, Yunong Zhang*

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

3 Citations (Scopus)

Abstract

Nonlinear equation systems are ubiquitous in a variety of fields, and how to tackle them has drawn much attention, especially dynamic ones. As a particular class of recurrent neural network, the zeroing neural network (ZNN) takes time-derivative information into consideration, and thus, is a competent approach to dealing with dynamic problems. Hitherto, two kinds of ZNN models have been developed for solving systems of dynamic nonlinear equations. One of them is explicit, involving the computation of a pseudoinverse matrix, and the other is of implicit dynamics essentially. To address these two issues at once, a low-computational-complexity ZNN (LCCZNN) model is proposed. It does not need to compute any pseudoinverse matrix, and is in the form of explicit dynamics. In addition, a novel activation function is presented to endow the LCCZNN model with finite-time convergence and certain robustness, which is proved rigorously by Lyapunov theory. Numerical experiments are conducted to validate the results of theoretical analyses, including the competence and robustness of the LCCZNN model. Finally, a pseudoinverse-free controller derived from the LCCZNN model is designed for a UR5 manipulator to online accomplish a trajectory-following task.

Original languageEnglish
Pages (from-to)4368-4379
Number of pages12
JournalIEEE Transactions on Automatic Control
Volume69
Issue number7
DOIs
Publication statusPublished - 1 Jul 2024
MoE publication typeA1 Journal article-refereed

Keywords

  • Activation function (AF)
  • dynamic nonlinear equation systems (DNESs)
  • low computational complexity (LCC)
  • trajectory following
  • zeroing neural network (ZNN)

Fingerprint

Dive into the research topics of 'Low-Computational-Complexity Zeroing Neural Network Model for Solving Systems of Dynamic Nonlinear Equations'. Together they form a unique fingerprint.

Cite this