A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems
Nonlinear inequalities are widely used in science and engineering areas, attracting the attention of many researchers. In this article, a novel jump-gain integral recurrent (JGIR) neural network is proposed to solve noise-disturbed time-variant nonlinear inequality problems. To do so, an integral er...
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sg-ntu-dr.10356-1705782023-09-19T08:40:08Z A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems Zhang, Zhijun Song, Yating Zheng, Lunan Luo, Yamei School of Electrical and Electronic Engineering Continental-NTU Corporate Lab Engineering::Computer science and engineering Antidisturbance Global Convergence Nonlinear inequalities are widely used in science and engineering areas, attracting the attention of many researchers. In this article, a novel jump-gain integral recurrent (JGIR) neural network is proposed to solve noise-disturbed time-variant nonlinear inequality problems. To do so, an integral error function is first designed. Then, a neural dynamic method is adopted and the corresponding dynamic differential equation is obtained. Third, a jump gain is exploited and applied to the dynamic differential equation. Fourth, the derivatives of errors are substituted into the jump-gain dynamic differential equation, and the corresponding JGIR neural network is set up. Global convergence and robustness theorems are proposed and proved theoretically. Computer simulations verify that the proposed JGIR neural network can solve noise-disturbed time-variant nonlinear inequality problems effectively. Compared with some advanced methods, such as modified zeroing neural network (ZNN), noise-tolerant ZNN, and varying-parameter convergent-differential neural network, the proposed JGIR method has smaller computational errors, faster convergence speed, and no overshoot when disturbance exists. In addition, physical experiments on manipulator control have verified the effectiveness and superiority of the proposed JGIR neural network. This work was supported in part by the National Natural Science Foundation under Grant 61976096, in part by the National High-Level Talents Special Support Program (Youth Talent of Technological Innovation of Ten-Thousands Talents Program) under Grant C7220060,in part by the Guangdong Basic and Applied Basic Research Foundation under Grant 2020B1515120047, in part by the Guangdong Foundation forDistinguished Young Scholars under Grant 2017A030306009, in part by the Guangdong Special Support Program under Grant 2017TQ04X475, in part by the SCUT-Tianxiagu Joint Lab Funding under Grant x2zdD8212590, in part by the Pazhou Lab Young Scholar Program under Grant PZL2021KF0015,in part by the National Key Research and Development Program of China under Grant 2017YFB1002505, in part by the Guangdong Key Researchand Development Program under Grant 2018B030339001, and in part by the Guangdong Natural Science Foundation Research Team Program under Grant 1414060000024. 2023-09-19T08:40:07Z 2023-09-19T08:40:07Z 2023 Journal Article Zhang, Z., Song, Y., Zheng, L. & Luo, Y. (2023). A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems. IEEE Transactions On Neural Networks and Learning Systems. https://dx.doi.org/10.1109/TNNLS.2023.3241207 2162-237X https://hdl.handle.net/10356/170578 10.1109/TNNLS.2023.3241207 37022813 2-s2.0-85148417530 en IEEE Transactions on Neural Networks and Learning Systems © 2023 IEEE. All rights reserved. |
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Engineering::Computer science and engineering Antidisturbance Global Convergence Zhang, Zhijun Song, Yating Zheng, Lunan Luo, Yamei A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| description |
Nonlinear inequalities are widely used in science and engineering areas, attracting the attention of many researchers. In this article, a novel jump-gain integral recurrent (JGIR) neural network is proposed to solve noise-disturbed time-variant nonlinear inequality problems. To do so, an integral error function is first designed. Then, a neural dynamic method is adopted and the corresponding dynamic differential equation is obtained. Third, a jump gain is exploited and applied to the dynamic differential equation. Fourth, the derivatives of errors are substituted into the jump-gain dynamic differential equation, and the corresponding JGIR neural network is set up. Global convergence and robustness theorems are proposed and proved theoretically. Computer simulations verify that the proposed JGIR neural network can solve noise-disturbed time-variant nonlinear inequality problems effectively. Compared with some advanced methods, such as modified zeroing neural network (ZNN), noise-tolerant ZNN, and varying-parameter convergent-differential neural network, the proposed JGIR method has smaller computational errors, faster convergence speed, and no overshoot when disturbance exists. In addition, physical experiments on manipulator control have verified the effectiveness and superiority of the proposed JGIR neural network. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Zhang, Zhijun Song, Yating Zheng, Lunan Luo, Yamei |
| format |
Article |
| author |
Zhang, Zhijun Song, Yating Zheng, Lunan Luo, Yamei |
| author_sort |
Zhang, Zhijun |
| title |
A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| title_short |
A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| title_full |
A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| title_fullStr |
A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| title_full_unstemmed |
A jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| title_sort |
jump-gain integral recurrent neural network for solving noise-disturbed time-variant nonlinear inequality problems |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170578 |
| _version_ |
1779156581510807552 |