Qinwei Qiu scite author profile

Recently, Mao [19] initiates the study the mean-square exponential stabilization of continuous-time hybrid stochastic differential equations by feedback controls based on discrete-time state observations. Mao [19] also obtains an upper bound on the duration τ between two consecutive state observations. However, it is due to the general technique used there that the bound on τ is not very sharp. In this paper, we will be able to establish a better bound on τ making use of Lyapunov functionals. We will not only discuss the stabilization in the sense of exponential stability (as Mao [19] does) but also in other sense of H ∞ stability or asymptotic stability. We will not only consider the mean square stability but also the almost sure stability.

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Stabilization of stochastic differential equations with Markovian switching by feedback control based on discrete-time state observation with a time delay

Qiu

Liu

et al. 2016

Statistics & Probability Letters

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Feedback control based on discrete-time state observation for stochastic differential equations with Markovian switching was initialled by Mao (2013). In practice, various effects could cause some time delay in the control function. Therefore, the time delay is taken into account for the discrete-time state observation in this paper and the mean-square exponential stability of the controlled system IS investigated.This paper is devoted as a continuous research to Mao (2013).

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Stabilization of Hybrid Systems by Feedback Control Based on Discrete‐Time State and Mode Observations

Mao

et al. 2017

Asian Journal of Control

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Recently, a kind of feedback control based on discrete-time state observations was proposed to stabilize continuous-time hybrid stochastic systems in the mean-square sense. We find that the feedback control there still depends on the continuous-time observations of the mode. However, it usually costs to identify the current mode of the system in practice. So we can further improve the control to reduce the control cost by identifying the mode at discrete times when we make observations for the state. In this paper, we aim to design such a type of feedback control based on the discrete-time observations of both state and mode to stabilize the given hybrid stochastic differential equations (SDEs) in the sense of mean-square exponential stability. Moreover, a numerical example is given to illustrate our results.

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Asymptotic moment boundedness of the stochastic theta method and its application for stochastic differential equations

Qiu

Liu

2014

Adv Differ Equ

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Qinwei Qiu

Stabilization of Hybrid Systems by Feedback Control Based on Discrete-Time State Observations

Stabilization of stochastic differential equations with Markovian switching by feedback control based on discrete-time state observation with a time delay

Stabilization of Hybrid Systems by Feedback Control Based on Discrete‐Time State and Mode Observations

Asymptotic moment boundedness of the stochastic theta method and its application for stochastic differential equations

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