Your search keyword '"Hu, Zhipei"' showing total 4 results

1. Control of Discrete-Time Stochastic Systems With Packet Loss by Event-Triggered Approach.

Author

Hu, Zhipei, Shi, Peng, Zhang, Jin, and Deng, Feiqi

Subjects

*STOCHASTIC systems, *DISCRETE-time systems, *BINOMIAL distribution, *EXPONENTIAL stability, *MATHEMATICAL analysis

Abstract

Event-triggered schemes are characterized in less communication traffic while maintaining the resulting controlled plant’s desired stability and performance criteria. In the presence of packet dropouts, this paper is concerned with the modeling and control problems for a class of discrete-time stochastic systems with event-triggered schemes. Two different mathematical analysis methods are proposed to model the packet loss when an event-triggered scheme is subject to packet loss. First, a stochastic distributed sequence satisfying the Bernoulli process is utilized to model the triggered packets transmitted in the communication networks. Considering the difference between time-triggered and event-triggered schemes, an equivalent model with a random sequence not satisfying a Bernoulli distribution process is also analyzed, which is not the same as some existing results in the literature. Then, the mean-square exponential stability of resulting augmented system is guaranteed and the prescribed ${H}_{\infty }$ performance level is achieved by solving resulting discrete ${P}$ -problem. Two examples with simulations are provided to validate the analytical results and demonstrate the effectiveness of the proposed co-design techniques. [ABSTRACT FROM AUTHOR]

Published

2021

2. A New Approach to Characterize Successive Packet Losses in Stochastic Networked Systems.

Author

Hu, Zhipei, Deng, Feiqi, Shi, Peng, and Lim, Cheng-Chew

Subjects

*STOCHASTIC systems, *CLOSED loop systems, *STOCHASTIC processes, *DISCRETE-time systems, *PROBABILITY theory, *ASYMPTOTIC distribution, *GLOBAL asymptotic stability

Abstract

In this paper, we discuss the modeling and stabilization problems for a class of discrete-time stochastic networked systems (DSNSs) subject to successive packet losses. The system under consideration is transformed into a stochastic one with bounded stochastic delay. Considering that the stochastic delay is characterized by nonuniform distribution, a new equivalent model is then constructed that enables the DSNS’s controller design to benefit from knowing the probability characteristic of packet losses. Specially, to verify this feature, the probabilities of the delay can be explicitly obtained by utilizing the formula of total probability, which is critical to model transformation and analyze practical problems that exist in DSNSs. Based on the proposed model, sufficient conditions are established under which the globally mean-square asymptotic stability of resulting stochastic delay closed-loop system is guaranteed, and a delay-distribution-dependent design procedure is then proposed. A numerical example with simulation is provided to validate the analytical results and demonstrate the effectiveness of the design procedure. [ABSTRACT FROM AUTHOR]

Published

2021

3. Robust exponential stability of uncertain stochastic systems with probabilistic time‐varying delays.

Author

Hu, Zhipei, Deng, Feiqi, Shi, Peng, Luo, Shixian, and Xing, Mali

Subjects

*ROBUST control, *STOCHASTIC systems, *STOCHASTIC analysis, *STOCHASTIC processes, *PROGRAMMABLE controllers

Abstract

Summary: This paper is concerned with the problem of delay‐distribution–dependent robust exponential stability for uncertain stochastic systems with probabilistic time‐varying delays. Firstly, inspired by a class of networked systems with quantization and packet losses, we study the stabilization problem for a class of network‐based uncertain stochastic systems with probabilistic time‐varying delays. Secondly, an equivalent model of the resulting closed‐loop network‐based uncertain stochastic system is constructed. Different from the previous works, the proposed equivalent system model enables the controller design of the network‐based uncertain stochastic systems to enjoy the advantage of probability distribution characteristic of packet losses. Thirdly, by applying the Lyapunov‐Krasovskii functional approach and the stochastic stability theory, delay‐distribution–dependent robust exponential mean‐square stability criteria are derived, and the sufficient conditions for the design of the delay‐distribution–dependent controller are then proposed to guarantee the stability of the resulting system. Finally, a case study is given to show the effectiveness of the results derived. Moreover, the allowable upper bound of consecutive packet losses will be larger in the case that the probability distribution characteristic of packet losses is taken into consideration. [ABSTRACT FROM AUTHOR]

Published

2018

4. Modeling and Control of It? Stochastic Networked Control Systems With Random Packet Dropouts Subject to Time-Varying Sampling.

Author

Hu, Zhipei, Deng, Feiqi, Xing, Mali, and Li, Junhui

Subjects

*STOCHASTIC systems, *STOCHASTIC processes, *TIME-varying systems, *CONTINUOUS time systems, *LINEAR systems

Abstract

In this note, we discuss the modeling and control of a class of Itô stochastic networked control systems (NCSs) with packet dropouts that are subject to time-varying sampling. The system under consideration is first modeled as a continuous-time system with input delay that is subject to double randomness via the input-delay approach. Then, by assuming the packet drop rate and recurring to the celebrated formula of total probability, an equivalent model which takes full advantage of probability distribution characteristics of both packet dropouts and sampling periods is established. In particular, the probability distribution values of the stochastic delay taking values in two given intervals can be explicitly obtained, which is of crucial importance to model and analyze the actual problem in NCSs. Based on that, robustly exponentially mean-square stability of the system with an $H_\infty$ performance is guaranteed, an $H_\infty$ controller design procedure is then proposed. Finally, a numerical simulation example is exploited to show the effectiveness and applicability of the results derived and some less conservative results are obtained. [ABSTRACT FROM AUTHOR]

Published

2017