Practical exponential stability of impulsive stochastic functional differential systems with distributed-delay dependent impulses. (English) Zbl 1533.93637
Summary: This paper develops new practical stability criteria for impulsive stochastic functional differential systems with distributed-delay dependent impulses by using the Lyapunov-Razumikhin approach and some inequality techniques. In the given systems, the state variables on the impulses are concerned with a history time period, which is very appropriate for modelling some practical problems. Moreover, different from the existing practical stabilization results for the systems with unstable continuous stochastic dynamics and stabilizing impulsive effects, we take the systems with stable continuous stochastic dynamics and destabilizing impulsive effects into account. It shows that under the impulsive perturbations, the practical exponential stability of the stochastic functional differential systems can remain unchanged when the destabilizing distributed-delay dependent impulses satisfy some conditions on the frequency and amplitude of the impulses. In other words, it reveals that how to control the impulsive perturbations such that the corresponding stochastic functional differential systems still maintain practically exponentially stable. Finally, an example with its numerical simulation is offered to demonstrate the efficiency of the theoretical findings.
MSC:
| 93D23 | Exponential stability |
| 93C27 | Impulsive control/observation systems |
| 93E15 | Stochastic stability in control theory |
| 93C23 | Control/observation systems governed by functional-differential equations |
| 34K50 | Stochastic functional-differential equations |
| 34K45 | Functional-differential equations with impulses |
Keywords:
impulsive stochastic functional differential systems; distributed-delay dependent impulses; practical exponential stability; Lyapunov-Razumikhin approachReferences:
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