Your search keyword '"Jing, Yuanwei"' showing total 3 results

1. Finite-time congestion tracking control for TCP/AWM network systems employing event-triggered mechanism.

Author

Jing, Yuanwei, Xie, Haixiu, Chen, Jiqing, and Dimirovski, Georgi M.

Subjects

*ADAPTIVE control systems, *FUZZY logic, *FUZZY systems, *LYAPUNOV functions, *SYSTEM dynamics

Abstract

This paper addresses the tracking control problem of TCP/AWM network systems in presence of nonresponsive data flows of category user datagram protocol (UDP) flows. Firstly, a modified network system model is established by a certain suitable variable transformation, and then a fuzzy logic system (FLS) emulator is used to approximate the nonlinear terms in the network dynamics representation system. Secondly, inspired by the idea of the prescribed performance control (PPC), a novel finite-time performance function (NFTPF) is proposed. In turn, an adaptive finite-time congestion control strategy is designed by compatible usage as appropriate of a barrier Lyapunov function (BLF), the backstepping control synthesis, and an event-triggered mechanism. The proposed control strategy can not only make the tracking error to satisfy the pre-assigned transient and steady-state performance, but also ensure that all the closed-loop signals remain semi-globally uniformly ultimately bounded (SGUUB). In addition, the designed congestion control strategy eliminates potential occurrence of Zeno behavior. A set of simulation results are presented to clarify the feasibility and effectiveness of proposed methodological approach and the designed congestion controller. [ABSTRACT FROM AUTHOR]

Published

2022

2. Adaptive synchronization of complex dynamic networks with switching parameters subject to state constraints in power system.

Author

Cui, Enchang, Jing, Yuanwei, Gao, Xiaoting, and Yang, Dongsheng

Subjects

*SWITCHING systems (Telecommunication), *SYNCHRONIZATION, *STATE power, *LYAPUNOV functions, *ADAPTIVE natural resource management, *PHASOR measurement

Abstract

This paper deals with the synchronization control of power complex networks with switching parameters. In the meantime, the node state constraints are considered during the synchronization process. Admittedly, synchronization problem encountered in power complex networks is becoming progressively important due to the increasing connection and disconnection operations resulting from sustainable energy and controllable load. Hereon, the network model considering switching parameters of each node is established to describe the topology variation of power systems that may be confronted in practical terms. Then, by utilizing the adaptive backstepping technique with a barrier Lyapunov function (BLF), a novel synchronization controller is constructed recursively which accomplishes the nodes full states tracking within the predefined transient behavior. Owing to the characteristic of BLF, the designed controller as well as its adaptive law could guarantee both the constrained state of each node restricted by a prescribed range and the synchronization performance. Meanwhile, the bounded output of the system could track the desired trajectory. Finally, scenario simulations are performed to demonstrate the effectiveness and superiority of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2021

3. A novel finite-time prescribed performance control scheme for spacecraft attitude tracking.

Author

Gao, Shihong, Liu, Xiaoping, Jing, Yuanwei, and Dimirovski, Georgi M.

Subjects

*ARTIFICIAL satellite attitude control systems, *SPACE vehicles, *ERROR functions, *ATTITUDE (Psychology), *LYAPUNOV functions, *ACTUATORS

Abstract

This paper studies the issue of finite-time prescribed performance control for spacecraft attitude tracking with inertia perturbations, external disturbances, actuator saturations and faults. To the best of the authors' knowledge, limited results have been reported in the relevant literature, and how to achieve the prescribed performance attitude tracking within a preset time interval is still an open problem. A novel finite-time prescribed performance function (FTPPF) whose settling time can be arbitrarily preset is first proposed. With the FTPPF predefining the envelope of tracking-error trajectories, the original spacecraft model is transformed into a new error system. Based on the barrier Lyapunov function of converted errors, the attitude controller is derived via backstepping design. During the process, the fuzzy approximation is used to handle inertia perturbations and external disturbances, while the Nussbaum gain technique is adopted to compensate for the efficiency loss caused by actuator saturations and faults. Finally, a finite-time fault-tolerant control scheme that guarantees both transient and steady-state performances (e.g., the maximum overshoot, steady-state error, and settling time) is developed. To verify the effectiveness of the solution, numerical experiments involving comparisons with related achievements are performed. [ABSTRACT FROM AUTHOR]

Published

2021