Absolute stability of large-scale time-delay lurie indirect control systems with unbounded coefficients. (English) Zbl 1422.93147
Summary: We study the absolute stability of large-scale time-delay Lurie indirect control systems with unbounded coefficients. Based on Lyapunov-Krasovskii functional approach, we derive some novel absolute stability conditions for this class of Lurie systems with a single nonlinearity. These conditions are particularly suitable for large-scale time-delay Lurie systems with unbounded coefficients. At the same time, they are also effective for such systems with bounded or constant coefficients. Furthermore, we extend the results obtained to multiple nonlinearities. The effectiveness of the proposed methods is illustrated via two numerical examples.
MSC:
| 93D05 | Lyapunov and other classical stabilities (Lagrange, Poisson, \(L^p, l^p\), etc.) in control theory |
| 93A15 | Large-scale systems |
| 93C10 | Nonlinear systems in control theory |
| 93D20 | Asymptotic stability in control theory |
Keywords:
large-scale time-delay system; indirect control system; absolute stability; Lyapunov second methodReferences:
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