Your search keyword '"Dou, Chunxia"' showing total 10 results

1. Voltage Distributed Cooperative Control Considering Communication Security in Photovoltaic Power System.

Author

Zhang, Zhanqiang, Dou, Chunxia, Zhang, Bo, and Yue, Wenbin

Subjects

*PHOTOVOLTAIC power systems, *ELECTRIC potential, *PHOTOVOLTAIC power generation, *VOLTAGE control

Abstract

A voltage regulation scheme considering communication security is proposed for photovoltaic (PV) power system. The scheme is a two-level regulation to, respectively, reduce overall voltage deviation (VDE) and voltages difference (VDI). First, the evaluation indexes of VDE and VDI are built. Then, primary regulation through a powers compensation scheme is used. Considering communication topology change and delay under upper bound, secondary regulation through consensus protocol is developed. In addition, communication packet-loss and large delay are solved by predictive compensation. Finally, effectiveness of the proposed method is verified by simulation in MATLAB. [ABSTRACT FROM AUTHOR]

Published

2019

2. Fusion State Estimation for Power Systems Under DoS Attacks: A Switched System Approach.

Author

Chen, Ji, Dou, Chunxia, Xiao, Li, and Wang, Zhuo

Subjects

*RADIAL distribution function, *DENIAL of service attacks, *PHASOR measurement, *COVARIANCE matrices, *CYBERTERRORISM

Abstract

This paper proposes a switched system method (SSM) for the fusion state estimation (SE) under denial-of-service (DoS) attacks in power systems. One of the subsystems in the SSM employs the widely used dynamic model with unit state transition matrix and zero control input. The performance of this model is favorable when the system operates in normal conditions but tends to suffer while the system state dramatically changes. Moreover, its accuracy and convergence is sensitive to the value of the process noise covariance matrix. The other subsystem, with some opposite characteristics, utilizes a pseudo-dynamic model derived from the linearization of the power flow equation. A switching rule based on the innovations is established to make a tradeoff between the two subsystems with regard to estimation accuracy, converge speed, and computing time. Apart from the difference in the reporting rate of various measurements, cyber attacks, such as DoS attacks may result in the absence of measurements in the snapshot of SE at the finest time scale. To deal with this problem, the linear extrapolation and multistep prediction techniques are involved. Simulation studies are conducted on the IEEE-14 bus test system and a 33 bus distribution system under various scenarios, and the performance of the proposed method is discussed. [ABSTRACT FROM AUTHOR]

Published

2019

3. Consensus of Multiagent Systems With Time-Varying Input Delay and Relative State Saturation Constraints.

Author

Chu, Hongjun, Yue, Dong, Dou, Chunxia, and Chu, Lanling

Subjects

*MULTIAGENT systems, *TIME-varying systems, *CONSTRAINTS (Physics), *DISTRIBUTED algorithms

Abstract

Relative states between neighbors are ubiquitous in large-scale systems, and the relative state saturations need to be considered when designing controllers based on this relative state information. This article investigates the consensus control of the delayed multiagent systems under the relative state saturations. By means of an incidence matrix, the consensus under the relative state saturations is transformed into the stability of edge dynamics operating on constrained sets. To enable the edge states to stay within the constrained sets, a novel nonlinear protocol is designed by embedding an elaborate saturation function. Sufficient conditions are identified, under which not only consensus is achieved but also relative state saturations do not occur. Moreover, this analytical result can address the consensus problem while preserving connectivity, within the limited communication range framework. Simulations illustrate the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2021

4. Consensus of Multiagent Systems With Time-Varying Input Delay via Truncated Predictor Feedback.

Author

Chu, Hongjun, Yue, Dong, Dou, Chunxia, Xie, Xiangpeng, and Chu, Lanling

Subjects

*MULTIAGENT systems, *TIME-varying systems, *PSYCHOLOGICAL feedback, *PARAMETRIC equations, *COMPUTER simulation

Abstract

This article investigates the consensus tracking of exponentially unstable multiagent systems with time-varying input delay. The truncated predictor feedback approach is utilized for designing delay-dependent state and output feedback protocols. And the explicit conditions that can realize consensus tracking are established in terms of parametric Lyapunov equations and scalar inequalities. Besides, the protocol design algorithms under the maximum allowable delay and the maximum convergence rate are, respectively, provided. Compared with the existing results, the salient characteristic of the current results is to reveal the quantitative relationship among the time delay, unstable plant, network topologies, and the convergence rate. Specifically, for achieving the consensus tracking, the synchronization force from network connectivity needs to dominate the anti-synchronization force from unstable open-loop poles and input delays; the maximum allowable input delay is inversely proportional to the sum of the unstable open-loop poles; the convergence rate becomes smaller as the input delay bounds or/and the sum of the unstable poles in plant increase. Numerical simulations confirm the effectiveness of the proposed theoretical design. [ABSTRACT FROM AUTHOR]

Published

2021

5. Multiagent System-Based Integrated Design of Security Control and Economic Dispatch for Interconnected Microgrid Systems.

Author

Zhang, Zhijun, Yue, Dong, Dou, Chunxia, and Zhang, Huifeng

Subjects

*MICROGRIDS, *ECONOMIC security, *POWER resources, *PREDICTION models, *COMPUTATIONAL complexity, *MATHEMATICAL models

Abstract

Hybrid and intermittent characteristics of the distributed energy resources (DERs) bring great challenges to the security control and economic dispatch (ED) of the microgrids. To bypass these hurdles, this article proposes a multiagent system-based integrated design of security control and ED to guarantee the effective and economical operation of the interconnected microgrids. First, a hierarchical control scheme is constructed by two-level unit agents, in which the switching control and dynamic regulation are fully implemented with the corresponding hybrid behaviors based on the differential hybrid Petri-net (DHPN) model. Based on the DHPN model, a novel dynamic ED integrated with security control is proposed to overcome the issues that cannot be solved in conventional models. Furthermore, to reduce the computational complexity and unified the mathematical model of the DERs, the inverter-based power control strategy is converted to a predictive control model which can be decomposed into several subsystems. In the optimization process, all the subsystems are implemented in a fully distributed, communication free, and rolling optimization manner based on the distributed model predictive control (DMPC). The validity of the proposed design is demonstrated according to the simulation results in case studies. [ABSTRACT FROM AUTHOR]

Published

2021

6. Attack-Tolerant Switched Fault Detection Filter for Networked Stochastic Systems Under Resilient Event-Triggered Scheme.

Author

Chen, Xiaoli, Hu, Songlin, Yue, Dong, Xie, Xiangpeng, and Dou, Chunxia

Subjects

*STOCHASTIC systems, *DENIAL of service attacks, *LINEAR matrix inequalities, *KALMAN filtering, *DELAY-tolerant networks, *PULSE width modulation

Abstract

This article investigates the problem of event-triggered switched fault-detection filters for networked stochastic systems under Denial-of-Service (DoS) jamming attacks. The considered DoS attacks are imposed by a power-constrained pulse-width modulated (PWM) jammers. A new resilient event-triggered communication strategy is designed to save network resources while counteracting the periodic PWM DoS jamming attacks. A new event-based switched residual model for fault detection is established, which characterizes the effects of the event-triggering scheme and DoS attacks simultaneously. By employing a piecewise stochastic Lyapunov functional method, sufficient conditions for achieving the exponentially mean-square stability and the prescribed performance of the residual system under the DoS attacks are formulated in terms of linear matrix inequalities. Consequently, co-design of the desired fault-detection filter parameters and the triggering parameters is achieved if the previous presented conditions are feasible. At last, an F-18 aircraft model is provided to show the validity of the proposed theoretical results. [ABSTRACT FROM AUTHOR]

Published

2022

7. Resilient Distributed Coordination Control of Multiarea Power Systems Under Hybrid Attacks.

Author

Cheng, Zihao, Hu, Songlin, Yue, Dong, Dou, Chunxia, and Shen, Shigen

Subjects

*HYBRID power systems, *POWER system simulation, *LINEAR matrix inequalities, *DENIAL of service attacks, *STABILITY theory

Abstract

Resilient distributed coordination control is studied on multiarea power systems with low inertia under hybrid attacks, including denial-of-service (DoS) attack and deception attack. The communication among various areas under the DoS attack is deteriorated to switching residual topologies whose time characteristic is modeled by model-dependent average dwell time (MDADT). Deception attack with malicious strategy targeting at negative feedback control is modeled by a sign function. To obtain resilience performance of the power system under low inertia and hybrid attacks, resilient distributed scheme combining load-frequency control (LFC) with virtual inertia control (VIC) is proposed. Then, resilient frequency control problem of the studied power system is converted to $H_{\infty }$ control of the switched nonlinear system. By employing the Lyapunov stability theory and switched system method, the resilient conditions are given by the lower bound of the average dwell time of each residual topology and the upper bound of deception attacks. Furthermore, a linear matrix inequality (LMI) technique is used to design the distributed resilient control gains of the LFC-VIC scheme. Finally, a simulation of four-area power systems is carried out to verify the validness of our theory. [ABSTRACT FROM AUTHOR]

Published

2022

8. Bandwidth Allocation-Based Switched Dynamic Triggering Control Against DoS Attacks.

Author

Hu, Songlin, Cheng, Zihao, Yue, Dong, Dou, Chunxia, and Xue, Yusheng

Subjects

*DENIAL of service attacks, *BANDWIDTH allocation, *BANDWIDTHS, *EXPONENTIAL stability, *REDUNDANCY in engineering, *STABILITY criterion, *DYNAMICAL systems

Abstract

This note is concerned with bandwidth allocation-based switched dynamic triggering control under DoS attacks and time delay. To prevent DoS attacks from causing open-loop unstable operation of the system with single-channel transmission, we present a primary-redundancy (PR) communication structure on the basis of limited bandwidth allocation; the correlation of communication delay bound between PR channels is introduced. To save the limited bandwidth, we propose a dynamic the event-triggered mechanism (DETM). Then, a switched delay system model is established to describe system dynamic driven by primary channel control, redundancy channel control, and unstable operation under DoS attacks. Further, by using the convex combination method, a switching law for PR channel is designed with the aim of keeping the concealment of the redundancy channel. With the switching law, a criterion of exponential stability is obtained by using piecewise Lyapunov–Krasovskii functional method. A co-design method is proposed to obtain feedback control gains, DETM parameters and switching law parameters. Finally, two simulation examples are illustrated to verify the validness of our proposed method. [ABSTRACT FROM AUTHOR]

Published

2021

9. Consensus of Lipschitz Nonlinear Multiagent Systems With Input Delay via Observer-Based Truncated Prediction Feedback.

Author

Chu, Hongjun, Gao, Lixin, Yue, Dong, and Dou, Chunxia

Subjects

*MULTIAGENT systems, *FORECASTING, *LINEAR matrix inequalities, *NONLINEAR systems, *PSYCHOLOGICAL feedback, *TREATMENT delay (Medicine)

Abstract

This paper investigates leaderless consensus and leader-following consensus of multiagent systems with Lipschitz nonlinearity and input delay. For such systems, the observer-based truncated prediction feedback protocols are designed via dropping the distributed term and remaining the exponential term of the solution of the system equation over the delay period. Using Lyapunov–Krasovskii functional approach, two sufficient criteria are, respectively, established for achieving leaderless and leader-following consensus. The observer and controller gains are then obtained by means of an iterative linear matrix inequality procedure. A numerical simulation verifies the effectiveness of the proposed control design approach. [ABSTRACT FROM AUTHOR]

Published

2020

10. Observer-Based Consensus of Nonlinear Multiagent Systems With Relative State Estimate Constraints.

Author

Chu, Hongjun, Chen, Jianliang, Yue, Dong, and Dou, Chunxia

Subjects

*MULTIAGENT systems, *SYSTEMS theory, *SWITCHING theory, *HYPERCUBES, *NONLINEAR systems, *VEHICLE routing problem

Abstract

Within the framework of multiagent systems, relative information can be directly acquired by vehicle-mounted sensors and the relative information constraints inevitably occur due to limited sensing capabilities. This paper investigates observer-based consensus of nonlinear multiagent systems subject to relative state estimate constraints. Each agent’s state is constructed via a state observer, and the relative state estimate is assumed to be confined into a hypercube. In virtue of the edge Laplacian, the consensus problem of nonlinear multiagent systems under this constraint is converted into the stabilization problem of edge dynamics operating on the constrained set. Observer-based intermittent protocol and adaptive protocol are, respectively, designed for achieving consensus. A convergence analysis is provided with the help of state saturation theory, switched system theory and adaptive theory. Finally, the results on consensus with relate state estimate constraints are applied into the consensus problem while preserving the connectedness, and are validated by a simulation example. [ABSTRACT FROM AUTHOR]

Published

2020