Fixed-time synchronization for quaternion-valued memristor-based neural networks with mixed delays. (English) Zbl 1525.93406
Summary: In this paper, the fixed-time synchronization (FXTSYN) of unilateral coefficients quaternion-valued memristor-based neural networks (UCQVMNNs) with mixed delays is investigated. A direct analytical approach is suggested to obtain FXTSYN of UCQVMNNs utilizing one-norm smoothness in place of decomposition. When dealing with drive-response system discontinuity issues, use the set-valued map and the differential inclusion theorem. To accomplish the control objective, innovative nonlinear controllers and the Lyapunov functions are designed. Furthermore, some criteria of FXTSYN for UCQVMNNs are given using inequality techniques and the novel FXTSYN theory. And the accurate settling time is obtained explicitly. Finally, in order to show that the obtained theoretical results are accurate, useful, and applicable, numerical simulations are presented at the conclusion.
MSC:
| 93D40 | Finite-time stability |
| 93B70 | Networked control |
| 11R52 | Quaternion and other division algebras: arithmetic, zeta functions |
| 93C43 | Delay control/observation systems |
Keywords:
fixed-time synchronization; nonlinear controllers; unilateral coefficients; quaternion-valued; memristor-based neural networksReferences:
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