Showing total 481 results

1. Adaptive fuzzy output-Feedback control of switched large-Scale systems with fast time-Varying delay.

Author

Wu, Dawei, Sun, Yonghui, and Yan, Xiaohui

Subjects

*ADAPTIVE fuzzy control, *TIME-varying systems, *NONLINEAR systems, *PSYCHOLOGICAL feedback, *PARTICIPATORY design, *CLOSED loop systems

Abstract

• For the fast-varying delay, an improved analytical method based on Lyapunov-Krasovskii (LK) functionals is given by introducing and proving a new lemma, which is not only independent of the upper bound of time-varying delay, but also independent of the derivative of the time-varying delay. Hence, the developed analytical method greatly expands the application range of the LK functional. • For unknown nonconstant control coefficients, an output feedback control strategy based on the compensated system is proposed. As an intermediate link, the adaptive fuzzy system is introduced into the controller indirectly by the compensation system, so as to avoid the algebraic-loop problem. Hence, the cooperative design of the compensation system, the state observer and the controller is one of the innovations in this paper. • Considering the problems of state immeasurability and time-varying delay comprehensively, an adaptive fuzzy output-feedback control law is proposed based on an improved average dwell time, which relaxes the constraints between the LK functional of each subsystem in switched large-scale interconnected nonlinear systems. In this paper, an adaptive fuzzy decentralized output-feedback control is developed for the uncertain switched large-scale interconnected nonlinear system, which contains fast time-varying delays and unknown nonconstant control coefficients. By introducing and proving a new lemma, an improved analysis method is given based on the Lyapunov-Krasovskii (LK) functional, and it gets rid of the dependence of LK functional design on the bound of the derivative of the delay. Immeasurable states are estimated by co-designing the decentralized state observer and the innovative compensation system, which eliminates a widely adopted but strict assumption that the unknown control coefficient must be constant. By comprehensively designing the state observer, the compensation system and LK functionals, a novel adaptive fuzzy decentralized output-feedback control law is proposed, and stability of the closed-loop system is guaranteed theoretically based on an improved average dwell time. Finally, the effectiveness is further verified by complete simulation experiments. [ABSTRACT FROM AUTHOR]

Published

2023

2. Adaptive fuzzy fixed-time tracking control for high-order nonlinear delayed systems with mismatched disturbances.

Author

Yu, Xin, Zhao, Wei, Xia, Jianwei, Chen, Xiangyong, and Shen, Hao

Subjects

*ADAPTIVE fuzzy control, *NONLINEAR systems, *BACKSTEPPING control method, *CLOSED loop systems, *FUZZY logic, *NONLINEAR functions

Abstract

The fixed-time tracking control issue is investigated for a class of high-order nonlinear delayed systems subject to mismatched disturbances in this paper. Wherein, the fuzzy logic system is applied in dealing with the nonlinear functions and the power integrator technique is appropriately introduced to address the high-order terms in the considered system. Different from the conventional methods of using the Lyapunov-Krasovskii functional approach to cope with the delayed terms in the previous work, the adaptive backstepping method is utilized in this paper. The main purpose of the addressed control problem is to design a suitable adaptive fuzzy fixed-time controller such that the closed-loop system is stable and guaranteed to be bounded in a fixed-time interval. Subsequently, the specific control law is deduced through the inductive method, and the upper bound on the settling time for the fixed-time control is given. Finally, the simulation examples are given to illustrate the feasibility and effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

3. Neural learning fixed-time adaptive tracking control of complex stochastic constraint nonlinear systems.

Author

Xu, Bo, Li, Yuan-Xin, and Tong, Shaocheng

Subjects

*NONLINEAR systems, *ITERATIVE learning control, *STOCHASTIC systems, *ADAPTIVE control systems, *SMOOTHNESS of functions, *CLOSED loop systems, *LYAPUNOV functions

Abstract

This paper investigates the adaptive fixed-time tracking control problem for a class of stochastic nonlinear systems with constrained states and input saturation. By utilizing a barrier Lyapunov function (BLF), the issue caused by constrained states is settled. Simultaneously, a smooth function is constructed to approximate input saturation and the unknown nonlinear function is approximated by neural networks (NNs). In view of the fixed-time tracking control problem of stochastic nonlinear systems, a fixed-time stability lemma for stochastic nonlinear systems has been established and proved. Under the designed controller, the closed-loop system is semi-globally fixed-time stable in probability (SGFSP), and all the states are constrained within a compact set. Moreover, the controlled system in this paper achieves equilibrium within a fixed-time internal. Lastly, the presented method is verified by a simulation example. [ABSTRACT FROM AUTHOR]

Published

2023

4. Quantized iterative learning control for nonlinear multi-agent systems with limited information communication and input saturation.

Author

Zhang, Ting and Li, Junmin

Subjects

*ITERATIVE learning control, *MULTIAGENT systems, *NONLINEAR systems, *NONSMOOTH optimization, *TELECOMMUNICATION systems, *INFORMATION storage & retrieval systems

Abstract

This paper considers a quantized consensus problem for nonlinear multi-agent systems (MAS) using iterative learning control (ILC). For actual digital communication networks, agents can only transmit state information with limited bandwidth. Therefore, a Sigma-Delta (Σ Δ) quantizer with a finite number of quantized bits is used to satisfy the communication network requirements. In addition, the introduction of network issues like input saturation and time delay make the problem more practically relevant. Due to the discontinuity caused by quantization, Filippov's non-smooth analysis theory is required to analyze the convergence performance of the MAS. The desired asymptotic consensus can be achieved with limited quantized information and possibly even a single bit between each pair of adjacent agents. Finally, numerical simulations are presented to illustrate the effectiveness of our theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2024

5. A new fixed-time terminal sliding mode control for second-order nonlinear systems.

Author

Zou, Quan and Chang, Shuaichuan

Subjects

*SLIDING mode control, *NONLINEAR systems

Abstract

In this paper, the fixed-time control for a class of second-order nonlinear systems with matched disturbance is addressed by using terminal sliding mode control technique. To improve the control performance of traditional fixed-time control method, a new fixed-time stability theorem is constructed by introducing a simple linear term, and theoretical analysis shows that the proposed control method provides faster convergence speed and more accurate estimate of the upper bound of settling time. Moreover, the practical fixed-time stability is also discussed in details. Based on the proposed fixed-time stability theorem, a fixed-time terminal sliding mode controller for a class of second-order nonlinear system is designed to obtain a bounded settling time independently of the initial conditions of the system. Simulations are carried out to verify the feasibility of the proposed control method. [ABSTRACT FROM AUTHOR]

Published

2024

6. Leader-following consensus control for nonlinear multiagent systems with unknown time-varying measurement sensitivity and infinite communication delays.

Author

Zhang, Liuliu, Liu, Songsong, and Hua, Changchun

Subjects

*MULTIAGENT systems, *NONLINEAR systems, *TIME-varying systems, *CLOSED loop systems, *NONLINEAR equations, *MEASUREMENT, *PSYCHOLOGICAL feedback

Abstract

This paper investigates the consensus problem for nonlinear multiagent systems (MASs) with unknown time-varying measurement sensitivity and infinite communication delays. Unlike existing works, the output measurement sensitivity is described as time-varying, and an infinite communication delay is considered between the agents. Under this condition, a novel output feedback control algorithm is developed. First, based on the hierarchical technique and Lyapunov-based time-domain method, the high-gain compensator and observer are constructed to tolerate the effect of infinite communication delays and accurately estimate the state of the leader. Subsequently, a new distributed k-filter and output feedback controller are proposed, which not only further relax the traditional Lipschitz conditional conservatism but also greatly simplify the design process. It is proved that the closed-loop system is globally stable and all agents can achieve consensus. Finally, the effectiveness of the proposed method is verified through the simulation of the single-link manipulators. [ABSTRACT FROM AUTHOR]

Published

2024

7. Discrete control of nonlinear stochastic systems driven by Lévy process.

Author

Yin, Liping, Han, Yawei, Song, Gongfei, Miao, Guoying, and Li, Tao

Subjects

*STOCHASTIC systems, *LEVY processes, *NONLINEAR systems, *SLIDING mode control, *DISCRETE-time systems, *EXPONENTIAL stability, *STOCHASTIC differential equations, *BROWNIAN motion

Abstract

In this paper, the stabilization is studied for a complex dynamic model which involves nonlinearities, uncertainty, and Lévy noises. This paper also discusses the controller discretization and presents a new algorithm to obtain the upper bound for the sample interval through which the exponential stability of the discrete system can still be guaranteed. Firstly, an integral sliding surface is designed to obtain the sliding mode dynamics for the considered stochastic Lévy process. By using Lyapunov theory, generalized Itô formula and some inequality techniques, the exponential stability is proved in the sense of mean square for sliding mode dynamics. The reachability of the sliding mode surface is also ensured by designing a sliding mode control law. Secondly, the continuous-time controller is discretized from the point of control cost, and the squared difference is analyzed for the states before and after the discretization. Different from those classical stochastic differential equations driven by Brownian motions, the noise is supposed to be Lévy type and the squared difference is analyzed in different cases. Furthermore, we obtain the largest sampling interval through which the discretized controller can still stabilize the Lévy process driven stochastic system. Finally, a simulation for a drill bit system is given to demonstrate the results under the algorithms. [ABSTRACT FROM AUTHOR]

Published

2023

8. Prescribed-time containment control of high-order nonlinear multi-agent systems based on distributed observer.

Author

Zhao, Guanglei, Liu, Quanzhong, and Hua, Changchun

Subjects

*MULTIAGENT systems, *NONLINEAR systems, *ACCESS to information

Abstract

This paper investigates the prescribed-time containment control problem for multi-agent systems with high-order nonlinear dynamics under a directed communication topology. Firstly, in view of the fact that only some follower agents can directly access the state information of multiple leader agents, a prescribed-time distributed observer is put forward to estimate the convex hull spanned by these leaders. Then, with the help of the distributed observer, a novel containment control method is developed for each follower based on a time-varying scaling function, so that all followers can converge to the convex hull spanned by the states of multiple leaders within a prescribed time. The comparison with the finite-time and fixed-time control methods differs in that the convergence time of the method proposed in this paper is independent of the initial conditions and control parameters and can be arbitrarily preassigned according to actual needs. Finally, an example is given to demonstrate the usefulness of the prescribed-time containment control method. [ABSTRACT FROM AUTHOR]

Published

2023

9. Fault diagnosis for a class of nonlinear uncertain systems using deterministic learning approach.

Author

Zeng, Yu, Chen, Tianrui, and Wang, Cong

Subjects

*FAULT diagnosis, *NONLINEAR systems, *UNCERTAIN systems, *ADAPTIVE control systems, *SYSTEM identification, *DISEASE complications

Abstract

In this paper, we propose a fault diagnosis (FD) approach for a class of nonlinear uncertain systems based on the deterministic learning approach (DLA). Specifically, an adaptive learning observer is constructed, in which the adaptive neural networks (NNs) are constructed to approximate the unknown system dynamics under normal and fault modes. Based on the strictly positive real (SPR) condition, the convergence of the state estimation can be guaranteed. When the system is undergoing a periodic or periodic-like (recurrent) motion, the states of the observer will also become recurrent. Thus through DLA, the partial persistent excitation (PE) condition of the associated subvectors of NNs is satisfied. By utilizing the partial (PE) condition, the uniformly completely observable (UCO) property of the identification system is analyzed and the exponential convergence condition of the identification system is derived. Under this condition, the unknown dynamics under normal and fault modes can be accurately identified along the system trajectory. And by utilizing the knowledge obtained in the identification phase, the fault can be detected in the diagnosis phase. The main attraction of this paper lies in the analytical result, which shows that the exponential convergence condition of the learning observer not only depends on the observer gain matrix, but also depends on the PE level of the regressor subvector of NN. Simulation results are included to illustrate the effectiveness of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2023

10. Adaptive optimal backstepping control for strict-feedback nonlinear systems with time-varying partial output constraints.

Author

Qin, Yan, Cao, Liang, Ren, Hongru, Liang, Hongjing, and Pan, Yingnan

Subjects

*ADAPTIVE control systems, *BACKSTEPPING control method, *TIME-varying systems, *NONLINEAR systems, *MACHINE learning, *REINFORCEMENT learning, *PSYCHOLOGICAL feedback

Abstract

This paper investigates the optimal backstepping control strategy for strict-feedback nonlinear systems subject to input saturation and time-varying partial output constraints. Compared with the existing results on output constraints, the time-varying partial output constraint is a more general constraint that can start and end at any time during the system operation, or remain unconstrained, which can be called as output constraints occurring in a limited time interval (OCOLT). A special barrier function is embedded into the optimal performance index function to satisfy the OCOLT condition under the optimal control framework, and a shift function is introduced to address the function discontinuity caused by the OCOLT problem. Then, an auxiliary system and a disturbance observer are respectively constructed to handle the influence of the input saturation and compounded disturbances. Meanwhile, the simplified reinforcement learning algorithm, employing the identifier-critic-actor architecture, is developed to achieve the optimal control objective within the framework of the backstepping technology. Moreover, the proposed optimal control method ensures the semi-globally uniformly ultimately bounded of all signals within the closed-loop system. Finally, two simulation examples are given to further prove the effectiveness of the presented optimal control approach. [ABSTRACT FROM AUTHOR]

Published

2024

11. Robust model predictive control for continuous nonlinear systems with the quasi-infinite adaptive horizon algorithm.

Author

Zhang, Chuanxin, Wang, Shengbo, Cao, Yuting, Zhu, Song, Guo, Zhenyuan, and Wen, Shiping

Subjects

*NONLINEAR systems, *PREDICTION models, *ALGORITHMS, *TRACKING algorithms, *DISCRETE systems, *COMPUTATIONAL complexity, *HORIZON, *ARTIFICIAL satellite tracking

Abstract

The control input derived from model predictive control (MPC) scheme depends on the receding horizon whose length needs to be determined. Design length is also a trade-off between computational complexity and optimization metrics. To this end, a framework for adaptive selection of the horizon length has been developed for discrete systems in previous works. In this paper, this framework is extended to continuous nonlinear systems. A new algorithm is presented to solve the problem of how to adaptively select the horizon length. Then, according to the traditional method and the robust MPC scheme based on tubes, the recursive feasibility and robustness of the algorithm (the adaptive horizon nonlinear model predictive control, called AH-NMPC) for quasi-infinite time domain adaptive horizontal continuous-time nonlinear systems are proved. Finally, the NMPC controller is used to perform path-tracking experiments on an autonomous vehicle to verify the good effects of the algorithm (AH-NMPC). [ABSTRACT FROM AUTHOR]

Published

2024

12. A dynamic-event approach to adaptive asymptotic tracking control of [formula omitted]-normal nonlinear systems under full state constraints.

Author

Li, Qidong, Hua, Changchun, Li, Kuo, and Li, Hao

Subjects

*NONLINEAR systems, *TRACKING algorithms, *SIGNALS & signaling

Abstract

In this paper, we study the problem of asymptotic tracking control for a class of interconnected p -normal nonlinear systems (p -NNS) with full-state constraints (FSCs). An event-triggered mechanism is constructed by introducing a new dynamic variable. It effectively reduces the update frequency of the controller compared to temporal-triggered. By building a new barrier function, the unknown functions of the system are converted into unknown scalars, which will be disposed of by the adaptive technique. To implement the FSCs control, we propose a low-complexity constrained control scheme while removing the condition that the initial value of the output is constrained. According to Barbalat's lemma, it is proved that the output signal can asymptotically track the predetermined signal, and the system states are kept within the constraint bound, with all signals bounded. Finally, two simulation examples illustrate the effectiveness of the scheme. [ABSTRACT FROM AUTHOR]

Published

2024

13. A unified methodology for the power efficiency analysis of physical systems.

Author

Tebaldi, Davide and Zanasi, Roberto

Subjects

*ELECTRIC motors, *ELECTRIC fields, *PLANETARY gearing, *LINEAR systems, *NONLINEAR systems, *HYDRAULIC drive

Abstract

In this paper, the problem of power efficiency evaluation for n -ports physical systems is investigated. The efficiency analysis that we perform highlights the necessary and sufficient conditions for the system to be passive, and outlines the guidelines for the efficiency maps computation. After addressing the problem from a formal point of view, the analysis is deepened for the case of two-ports linear and nonlinear physical systems, and for the cases of three and four-ports linear systems. The efficiency analysis and the computation of the efficiency maps are addressed as a function of the power variables characterizing all the energetic ports of the considered systems. Furthermore, the salient properties of the efficiency are highlighted and discussed. The theoretical analysis which is developed is then applied to some physical systems of interest for industries and engineers working in the electromechanical, hydraulic and automotive fields: a DC electric motor driving an hydraulic pump for the two-ports systems class, a single-stage planetary gear set for the three-ports systems class, and a Ravigneaux planetary gear set for the four-ports systems class. • Power efficiency modeling and efficiency maps computation for physical systems. • Interchangeable efficiency maps computed on the different systems energetic ports. • Highlighting of intrinsic properties and of a design parameter for two-ports systems. • Efficiency maps computation and intrinsic characteristics of planetary gear sets. [ABSTRACT FROM AUTHOR]

Published

2024

14. A robust state-dependent Riccati equation controller with parameter uncertainty and matched disturbance.

Author

Nekoo, Saeed Rafee and Ollero, Anibal

Subjects

*RICCATI equation, *SLIDING mode control, *DIFFERENTIAL equations, *NONLINEAR systems

Abstract

The state-dependent Riccati equation (SDRE) unveils a nonlinear optimal control approach; the method is sensitive to uncertainty and disturbance that provokes the necessity of precise modeling and omitting disturbance from the model and environment which is occasionally impossible. In this paper, a robust state-dependent Riccati equation is introduced using only the pure SDRE itself. Lyapunov's second method for stability analysis is used to extract two tuning rules for weighting matrices of the robust approach for handling both matched disturbance and parametric uncertainty. A fourth-order differential equation is simulated to show the effectiveness of the suggested method and the results were compared with conventional SDRE. The robust version could handle the matched disturbance with a steady-state shift from the equilibrium point where the conventional SDRE failed. Additionally, a comparison and detailed analysis have been performed between the proposed design and sliding mode control. • A robust SDRE design is proposed based on the defined bound of the uncertainty in the weighting matrices. • The stability of the controller is proved using the Lyapunov method to find the weighting matrices. • A fourth-order nonlinear system is simulated as an example of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

15. Decentralized robust adaptive backstepping control for a class of non-minimum phase nonlinear interconnected systems.

Author

Feng, Jiehua, Zhao, Dongya, Yan, Xing-Gang, and Spurgeon, Sarah K.

Subjects

*BACKSTEPPING control method, *NONLINEAR systems, *ADAPTIVE control systems, *CLOSED loop systems, *ROBUST control, *ACTUATORS

Abstract

In this paper, a class of interconnected systems is considered, where the nominal isolated subsystems are fully nonlinear and non-minimum phase. A decentralized Extended Kalman Filter-Extended High Gain Observer (EKF-EHGO) is designed to observe the system states. Then, a systematic backstepping design procedure is employed to develop a novel decentralized robust adaptive output feedback control, in which the adaptive law is designed to counter the effects of the interconnections and uncertainties. The proposed decentralized dynamic output feedback control scheme can guarantee that all the signals in the closed-loop system are uniformly ultimately bounded (UUB). Both interconnections and uncertainties are allowed to be unmatched and bounded by an unknown high-order polynomial, which is a more general form when compared with existing work. Two MATLAB simulation examples are used to demonstrate the effectiveness of the proposed method including a system comprising translational oscillator with rotating actuator (TORA) sub-systems. [ABSTRACT FROM AUTHOR]

Published

2023

16. Distributed fixed-time event-triggered containment control for nonlinear multiagent systems with actuator faults.

Author

Wang, Yuanqing, Shen, Runjie, Zhu, Fanglai, Zhang, Chunhui, and Zhao, Xudong

Subjects

*MULTIAGENT systems, *NONLINEAR systems, *ACTUATORS, *ENERGY consumption, *FAULT-tolerant computing, *ADAPTIVE control systems

Abstract

This paper is concerned with distributed fixed-time containment control for nonlinear multiagent systems with actuator faults via static and dynamic event-triggered strategies. A distributed fixed-time static event-triggered fault-tolerant controller is developed by employing the sign function, which eliminates the requirement for continuous control signal updates. To address the chattering phenomenon caused by the sign function, a distributed saturation controller is presented to enhance the control performance. To further reduce energy consumption and frequency of controller updates, a dynamic event-triggered strategy with an auxiliary parameter is proposed for each agent to dynamically regulate its threshold. The control scheme guarantees that the containment control objective is achieved within the settling time, and does not exhibit Zeno behavior. The effectiveness of the proposed control scheme is illustrated by simulation results. [ABSTRACT FROM AUTHOR]

Published

2023

17. Command-filter-based finite-time event-triggered adaptive output feedback control for nonlinear systems with state-function constraints.

Author

Gao, Lihong, Song, Zhibao, and Wang, Zhen

Subjects

*ADAPTIVE control systems, *ADAPTIVE fuzzy control, *FEEDBACK control systems, *BACKSTEPPING control method, *CLOSED loop systems, *NONLINEAR systems, *NONLINEAR functions

Abstract

This paper investigates the finite-time (FT) adaptive output feedback control for a class of nonlinear systems with asymmetric state-function constraints and unknown external disturbances. Incorporating the asymmetric barrier Lyapunov function (BLF) into the backstepping technique, a new control approach is proposed to ensure that all states do not cross the constraint boundary. With the help of the command filter, the explosion of complexity induced by repeated differentiations of virtual controllers is eliminated, and the corresponding compensation system is used to offset the filter error. Meanwhile, the fuzzy logic system (FLS) and fuzzy state observer are employed to approximate unknown nonlinear functions and estimate unmeasurable states respectively. For effectively conserve communication resources, a novel adaptive event-triggered controller is proposed such that all signals of the closed-loop system are bounded, the tracking error converges to a small neighborhood containing the origin in finite time. Finally, the feasibility of the fabricated control scheme is verified with two examples. [ABSTRACT FROM AUTHOR]

Published

2023

18. Reinforcement learning-based fixed-time resilient control of nonlinear cyber physical systems under false data injection attacks and mismatch disturbances.

Author

Mazare, Mahmood

Subjects

*CYBER physical systems, *SLIDING mode control, *COST functions, *REINFORCEMENT learning, *ADAPTIVE control systems, *NONLINEAR systems, *WIND turbines

Abstract

This paper presents a fixed-time adaptive resilient control framework based on reinforcement learning (RL), mismatch disturbance observer and nonsingular fast terminal sliding mode scheme for nonlinear cyber-physical systems (CPS) to enhance cyber-security under False Data Injection (FDI) attacks, as well as match and mismatch disturbances. The RL algorithm contains an actor-critic neural network (NN) in which the actor NN is employed to estimate the uncertainty while the critic NN is applied to evaluate the performance cost function. Next, to compensate the detrimental effects of attacks and mismatch disturbances, a new sliding mode-based adaptive disturbance observer is designed. To achieve high precision trajectory tracking within a fixed-time interval, a nonsingular fast terminal sliding mode scheme is designed. This scheme ensures fixed-time convergence of the tracking error and facilitates disturbance attenuation and attack mitigation which are the key features of the proposed fixed-time secure control strategy. Finally, the fixed-time stability analysis of is performed through Lyapunov theory. Results reveal the effectiveness of the proposed resilient control for wind turbine system as the nonlinear CPS. [ABSTRACT FROM AUTHOR]

Published

2023

19. Anti-disturbance control for HVs system subject to nonlinear actuator characteristics with extended state observer.

Author

Shen, Yaoxin, Zhou, Dengji, Wu, Yadong, and Huang, Dawen

Subjects

*SLIDING mode control, *RADIAL basis functions, *ACTUATORS, *NONLINEAR systems, *FAULT-tolerant computing, *CURRENT transformers (Instrument transformer)

Abstract

• It proposes a new fault tolerant control sheme in HVs. • The validity of effectiveness of the fault tolerant control is verified by multiple sets of experimental data. • Prove the fault extended state observer and whole FTC sheme converging in finite time. • Compensate the effect of external attitude disturbance, actuator faults and saturation on the system. This paper proposes a radial basis function neural network and the actuator fault extended state observer based fast non-terminal sliding mode fault-tolerant control scheme for hypersonic vehicles (HVs) system. The proposed scheme can cope with actuator faults, actuator saturation, parameter uncertainties, and external disturbances for HVs systems, without relying on redundancy as some passive FTC methods do. Moreover, an anti-windup compensator is designed to mitigate the input saturation effects. Furthermore, the finite-time stability of the attitude angle of the HVs system is proved by Lyapunov's theorem. Numerical simulations validate the effectiveness of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2023

20. Global event-triggered output-feedback stabilization for switched nonlinear systems with time-delay and measurement sensitivity.

Author

Zhao, Chenhao, Li, Lili, and Shen, Yanjun

Subjects

*NONLINEAR systems, *MATRIX inequalities, *ADAPTIVE control systems, *CLOSED loop systems, *HOPFIELD networks, *MEASUREMENT

Abstract

• A novel event-triggering mechanism and three dynamic gains are introduced to compensate uncertainty and execution error. • It overcomes difficulties from unknown polynomial growth rate, unknown large measurement sensitivity and time-delay. • It proves that all the signals are bounded, the states converge to zero asymptotically, and the Zeno behavior is excluded. In this paper, the problem of adaptive event-triggered output-feedback stabilization is addressed for a class of switched nonlinear systems with time-delay and output measurement sensitivity. With the assistance of the dynamic high gain technology and a novel event-triggered control mechanism, we overcome the design complexities arising from unknown polynomial growth rate with respect to the output, unknown large measurement sensitivity, unknown time-varying control coefficient and time-delay. Then, an effective constructive method is provided to design switched observers and a common event-triggered controller. Through introducing two key matrix inequalities and constructing a common Lyapunov-Krasovskii functional, sufficient conditions are given to get rid of Zeno behavior, and ensure that all the signals are bounded and the closed-loop system states converge to zero under arbitrary switchings. Two simulation studies are conducted for verifying the effectiveness of proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2023

21. Neural network-based output tracking control of high-order nonlinear systems with DoS attacks and perturbations.

Author

Jin, Xiaozheng, Yan, Bingheng, Chi, Jing, Wu, Xiaoming, and Deng, Chao

Subjects

*DENIAL of service attacks, *NONLINEAR systems, *BACKSTEPPING control method, *RADIAL basis functions, *ADAPTIVE filters, *HOPFIELD networks

Abstract

This paper focuses on the output feedback tracking control of a high-order nonlinear system with denial-of-service (DoS) attacks and exogenous disturbances. A radial basis function neural network (RBFNN)-based state observer is employed to estimate the system states. A new nonlinear filter with adaptive regulation is developed to eliminate the impacts of perturbed factors such as RBFNN approximation errors and disturbances. Constituting with filtering operation and backstepping control technique, a RBFNN-based security controller is constructed to suppress the influences of perturbations and DoS attacks based on the observation signals. The uniformly ultimately bounded output tracking result is established by using the security control signals via Lyapunov criterion in the cases of DoS attacks, nonlinearities, and disturbances. Comparative results are provided to validate the efficiency of the developed RBFNN-based observation and security control strategies of a nonlinear system. [ABSTRACT FROM AUTHOR]

Published

2023

22. Switching-based adaptive fault-tolerant control for uncertain nonlinear systems against actuator and sensor faults.

Author

Yang, Xinyu, Wang, Xingjian, Wang, Shaoping, and Puig, Vicenç

Subjects

*ADAPTIVE control systems, *FAULT-tolerant control systems, *NONLINEAR systems, *ACTUATORS, *UNCERTAIN systems, *BACK up systems, *DETECTORS

Abstract

In previous research on fault switching of redundant actuators using monitoring modules, the interference of sensor faults on monitoring results has not received enough attention. In this paper, a new fault-tolerant control (FTC) method combining adaptive compensation and active switching is proposed for a class of uncertain nonlinear systems with backup actuators against actuator and sensor faults. While using command filtered backstepping to reduce computational burden, a direct adaptive compensation scheme is designed to ensure that sensor faults within tolerable bounds do not trigger actuator switching. Based on this, a new lumped monitoring function (MF) containing prescribed performances and tolerable sensor fault bounds is designed to detect and isolate faulty actuators and ensure that the tracking error always satisfies prescribed transient and steady-state performances. Two simulation cases are used for illustrating the proposed method. It is proved that the proposed method can effectively reduce the interference of sensor faults on actuator fault detection and improve the accuracy of actuator switching. [ABSTRACT FROM AUTHOR]

Published

2023

23. Nonsmooth funnel function-based model-free adaptive sliding-mode control for discrete-time nonlinear systems.

Author

Cheng, Yun, Ren, Xuemei, and Zheng, Dongdong

Subjects

*NONLINEAR systems, *ADAPTIVE control systems, *DISCRETE-time systems, *SLIDING mode control, *COST functions, *DERACEMIZATION, *SYSTEM dynamics

Abstract

This paper proposes a nonsmooth funnel function (NFF)-based model-free adaptive sliding-mode control strategy for the discrete-time nonlinear systems with unknown dynamics and asymmetric constraints. The dynamic linearization model of the nonlinear systems with unknown dynamics is obtained online only using the input/output data, which is combining with the designed NFF-based discrete-time sliding-mode surface to guarantee asymmetric constraints of the tracking error. In the proposed NFF, the coordinate transformation for asymmetric constraints simplifies the controller design, and the nonsmooth parameter can improve the transient and steady-state performances of the tracking error. The control consumption is further reduced by a proposed time-varying weighting factor-based cost function in the controller design. Furthermore, parameter selections of performance boundaries and the sliding-mode surface are given, and the performance margin (the minimum distance from the tracking error to the preset boundaries) is proved theoretically. Simulation and experimental results verify the effectiveness of the proposed control strategy. [ABSTRACT FROM AUTHOR]

Published

2023

24. Adaptive control for a class of switched nonlinear systems with output constraints and quantized input signal.

Author

Lei, Ming and Chen, Weimin

Subjects

*ADAPTIVE control systems, *NONLINEAR systems, *TIME-varying systems, *HYPERBOLIC functions, *TANGENT function, *CLOSED loop systems

Abstract

The adaptive tracking problem for a class of strict-feedback switched nonlinear systems with output constraints, quantization input, distributed time-varying delays and external disturbances is studied in this paper. Firstly, we introduce the hyperbolic tangent function to handle the quantized signal in the design of the controller. For the nonlinear term and distributed time-varying delay of the system, the integral term is introduced into the candidate functional to compensate it. Secondly, based on Dynamic Surface Control (DSC) technique and Barrier Lyapunov function (BLF) method, an adaptive controller is designed to guarantee the stability of the controlled closed-loop system, and the system tracking error can converge to the origin without violating the constraints. Finally, simulation results verify the effectiveness of the proposed control strategy. [ABSTRACT FROM AUTHOR]

Published

2023

25. Event-triggered adaptive control for stochastic nonlinear systems with time-varying full state constraints and output dead-zone.

Author

Yue, Hongyun, Feng, Shaofang, and Li, Junmin

Subjects

*ADAPTIVE control systems, *TIME-varying systems, *NONLINEAR systems, *STOCHASTIC systems, *BACKSTEPPING control method, *CLOSED loop systems

Abstract

This paper studies the problem of event-triggered adaptive control for a class of strictly-feedback stochastic nonlinear systems. The output dead zone and time-varying full-state constraints are considered in the controller. Firstly, time-varying barrier Lyapunov functions (TVBLFs) are introduced to address problems of time-varying state constraints. Then, the Nussbaum-type function is used to compensate for the influence of the output dead zone. The problem of state constraint is well solved when the system's output signal is affected by the dead zone, which satisfies a wider application space. In addition, a new relative threshold of the event-triggered control (ETC) scheme is considered to save communication resources, and the Zeno behavior is excluded. This scheme makes the trigger interval more flexible and optimizes the performance of the controller. Moreover, the error compensation signals reduce the filtered errors and simplify the algorithm. Simultaneously, an adaptive tracking controller with the backstepping technique is designed so that all signals in the closed-loop system are bounded and the tracking error converges to a small residual set of the origin. Finally, two simulation examples are given to demonstrate the effectiveness of the control method. [ABSTRACT FROM AUTHOR]

Published

2023

26. Type-B Nussbaum function-based fault-tolerant control for a class of strict-feedback nonlinear systems.

Author

Hua, Changchun, Chen, Zihan, Sun, Zhonghua, and Luo, Xi

Subjects

*ADAPTIVE control systems, *FAULT-tolerant control systems, *NONLINEAR systems, *CLOSED loop systems, *LYAPUNOV functions, *ACTUATORS

Abstract

This paper studies the fault-tolerant control (FTC) problem of a class of strict-feedback nonlinear systems. First, we put forward a key theorem which shows that type-B Nussbaum functions can be extended to the cases containing multiple Nussbaum functions in the same Lyapunov inequality under certain conditions. Then, by using the techniques of Nussbaum functions and adaptive control, a new fault-tolerant control scheme is proposed. Compared with the previous work, this paper considers unknown time-varying control coefficients and unknown time-varying fault coefficients of actuators. It is proved that all the signals of the closed-loop system are globally bounded and the tracking error converges to zero asymptotically. Finally, simulations are provided to verify the effectiveness of the proposed control scheme. [ABSTRACT FROM AUTHOR]

Published

2023

27. Event-triggered finite-time fault detection for delayed networked systems with conic-type nonlinearity and deception attacks.

Author

Wu, Zhihui, Li, Bei, Chen, Weilu, and Hu, Jun

Subjects

*DECEPTION, *BINOMIAL distribution, *NONLINEAR systems, *NONLINEAR functions, *SYSTEM dynamics, *LINEAR matrix inequalities, *CONIC sections

Abstract

• The RODAs and DETM are both considered in FTFD problem of conic-type nonlinear systems. • A finite-time fault detection filter is proposed to handle conic-type nonlinearity and RODAs. • New sufficient criterion is given to achieve the finite-time stochastic stability with H ∞ requirements. The paper is concerned with the finite-time fault detection (FTFD) problem for a class of delayed networked systems subject to conic-type nonlinearity and randomly occurring deception attacks (RODAs) via dynamic event-triggered mechanism (DETM). The nonlinear function with the conic-type constraint is limited to a known hypersphere with uncertain center. Moreover, a variable governed by Bernoulli distribution is introduced to characterize the RODAs phenomenon. In order to reduce unnecessary communication transmissions, a DETM is considered in the design of finite-time fault detection filter (FTFDF) for the addressed networked systems with time-delays. This paper focuses on the design of an FTFDF via the DETM to ensure the finite-time stochastic stability of error dynamics system with satisfactory the prescribed H ∞ performance. Moreover, the desired FTFDF parameter matrices are obtained by solving linear matrix inequalities. In the end, a simulation example is employed to illustrate the validity of the proposed FTFD method. [ABSTRACT FROM AUTHOR]

Published

2023

28. Feedback higher-order iterative learning control for nonlinear systems with non-uniform iteration lengths and random initial state shifts.

Author

Wei, Yun-Shan, Chen, Ying-Yu, and Shang, Wenli

Subjects

*ITERATIVE learning control, *NONLINEAR systems, *DISCRETE-time systems

Abstract

For nonlinear discrete-time systems with non-uniform iteration lengths and random initial state shifts, this paper developed a feedback higher-order iterative learning control (ILC) approach. To compensate the absent information of last iteration caused by non-uniform iteration lengths, the tracking information in both iteration domain and time domain is included in ILC design with the help of higher-order control and feedback control, respectively, while the general ILC schemes just adopt the information in iteration domain. A sufficient condition based on the higher-order ILC gains is derived. It is guaranteed that as the iteration number goes to infinity, the asymptotic bound of tracking error is proportional to random initial state shifts in mathematical expectation sense. Specifically, as the expectation of initial state shifts is zero, the ILC tracking error can be controlled to zero along the iteration direction. Two examples with different initial conditions are provided to validate the proposed ILC approach. [ABSTRACT FROM AUTHOR]

Published

2023

29. A robust distributed observer design for Lipschitz nonlinear systems with time-varying switching topology.

Author

Arefanjazi, Hadis, Ataei, Mohammad, Ekramian, Mohsen, and Montazeri, Allahyar

Subjects

*NONLINEAR systems, *TIME-varying systems, *LINEAR matrix inequalities, *DISTRIBUTED algorithms, *TELECOMMUNICATION systems, *TOPOLOGY

Abstract

This paper deals with state estimation for a class of Lipschitz nonlinear systems under a time-varying disconnected communication network. A distributed observer consists of some local observers that are connected to each other through a communication network. We consider a situation where a communication network does not remain connected all the time, and the network may be caused by intermittent communication link failure. Moreover, each local observer has access to a local measurement, which may be insufficient to ensure the system's observability, but the collection of all measurements in the network ensures observability. In this condition, the purpose is to design a distributed observer where the estimated state vectors of all local observers converge to the state vector of the system asymptotically, while local observers exchange estimated state vectors through a communication network and use their local measurements. According to theoretical analysis, a nonlinear and a robust nonlinear distributed observer exist when in addition to the union of all communication topologies being strongly connected during a time interval, the component of each communication graph is also strongly connected during each subinterval. The existence conditions of the distributed observers are derived in terms of a set of linear matrix inequalities (LMIs). Finally, the effectiveness of the presented method is numerically verified using some simulation examples. [ABSTRACT FROM AUTHOR]

Published

2023

30. Attacks detection and security control for cyber-physical systems under false data injection attacks.

Author

Chen, Yuhang, Li, Tieshan, Long, Yue, and Bai, Weiwei

Subjects

*CYBER physical systems, *NONLINEAR systems, *NONLINEAR equations

Abstract

This paper is concerned with the attack detection and security control problem for discrete-time nonlinear cyber-physical systems (CPSs) under false data injection (FDI) attacks, which can bypass the traditional error detection mechanism. With the help of the T–S fuzzy models, a novel robust extended state observer with H ∞ performance is proposed to estimate this kind of attack. The attacks are included inside the observer as an internal state variable and the estimation of the FDI attack can be obtained from the outputs of the observer. By utilizing the observation of the FDI attack, a compensator is designed to negate the attack. Additionally, a controller is proposed to bring on the attack ineffective. Finally, simulation examples are given to illustrate the effectiveness of the developed schemes. [ABSTRACT FROM AUTHOR]

Published

2023

31. Adaptive-critic-based model reference control for unknown nonlinear systems with input constraints.

Author

Huang, Zixin, Wan, Xiao, Wang, Liheng, Wang, Lejun, and Fu, Hao

Subjects

*NONLINEAR systems, *CLOSED loop systems, *DISCRETE-time systems, *ADAPTIVE control systems, *APPROXIMATION error, *CLUSTER sampling

Abstract

In this paper, the optimal model reference adaptive control (MRAC) problem is studied for the unknown discrete-time nonlinear systems with input constraint under the premise of considering robustness to uncertainty. Through an input constraint auxiliary system, a new adaptive-critic-based MRAC algorithm is proposed to transform the above problem into the optimal regulation problem of the auxiliary error system with lumped uncertainty. In order to realize the chattering-free sliding model control for the auxiliary error system, an action-critic variable is introduced into the adaptive identification learning. In this case, the closed-loop control system is robust to the disturbance and the neural network approximation error. The uniformly ultimate bounded property is proved by the Lyapunov method, and the effectiveness of the algorithm is verified by a simulation example. [ABSTRACT FROM AUTHOR]

Published

2023

32. Observer design with exponential time-varying gain for Takagi–Sugeno fuzzy systems with continuous and aperiodic sampled outputs.

Author

Bouchama, Hiba Fawzia, Defoort, Michael, Lauber, Jimmy, and Berdjag, Denis

Subjects

*FUZZY systems, *LINEAR matrix inequalities, *ADAPTIVE fuzzy control, *NONLINEAR systems, *CONTINUOUS time systems, *COMPUTER simulation

Abstract

In this paper, an observer with exponential time-varying gain is proposed for a class of nonlinear systems in Takagi–Sugeno form with both continuous-time and aperiodic sampled outputs. The proposed observer consists of two parts: one related to the continuous-time outputs and one related to the discrete outputs. Sufficient conditions involving a tuning parameter and the maximum allowed sampling time are derived in terms of quasi linear matrix inequality with respect to a scalar to ensure asymptotic convergence of the observer on the basis of Lyapunov–Krasovskii functional and H ∞ approach. Numerical simulations are provided to show the benefits of the proposed observer. Some comparisons with the high gain continuous-discrete observer and fuzzy observer with constant gain are provided to illustrate the interest of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2023

33. Event-triggered secure control of nonlinear multi-agent systems under sensor attacks.

Author

Hu, Xiaoyan, Li, Yuan-Xin, and Tong, Shaocheng

Subjects

*MULTIAGENT systems, *NONLINEAR systems, *BACKSTEPPING control method, *ADAPTIVE control systems, *LYAPUNOV stability, *DETECTORS

Abstract

In this paper, a security consistent tracking control scheme with event-triggered strategy and sensor attacks is developed for a class of nonlinear multi-agent systems. For the sensor attacks on the system, a security measurement preselector and a state observer are introduced to combat the impact of the attacks and achieve secure state estimation. In addition, command filtering technology is introduced to overcome the "complexity explosion" caused by the use of the backstepping approach. Subsequently, a new dynamic event-triggered strategy is proposed, in which the triggering conditions are no longer constants but can be adjusted in real time according to the adaptive variables, so that the designed event-triggered mechanism has stronger online update ability. The measurement states are only transmitted through the network based on event-triggered conditions. The proposed adaptive backstepping algorithm not only ensures the security of the system under sensor attacks but also saves network resources and ensures the consistent tracking performance of multi-agent systems. The boundedness of all closed-loop signals is proved by Lyapunov stability analysis. Simulation examples show the effectiveness of the control scheme. [ABSTRACT FROM AUTHOR]

Published

2023

34. Asynchronous robust fuzzy event-triggered control of nonlinear systems.

Author

Farbood, Mohsen, Echreshavi, Zeinab, Shasadeghi, Mokhtar, and Mobayen, Saleh

Subjects

*NONLINEAR systems, *SLIDING mode control, *FUZZY systems, *CLOSED loop systems, *ADAPTIVE fuzzy control

Abstract

This paper deals with the problem of event-triggered integral sliding mode control (ISMC) for the perturbed nonlinear based-Takagi-Sugeno (TS) fuzzy systems. To reduce the chattering introduced by the unmatched disturbances, a disturbance observer is designed to get the estimated unmatched disturbances. To further reduce the computational burden and communication resources, compared with previous studies, two types of sliding surfaces are established. The time-triggered-based sliding surface which is used to ensure the reachability of the system states and the event-triggered-based sliding surface that is presented to calculate the control law, directly which benefits from less updates and consequently, less chattering that enhance the system performance. Moreover, the suggested control scheme is proposed based on asynchronous trait, i.e. , the premise variables of the controller are in different time scale with the fuzzy systems which also leads to communication resource reduction. As a key issue in event-triggered control, it is ensured that the proposed controlled system is Zeno-free along the implementation. By the Lyapunov theory, the appropriate conditions for the ultimate boundedness stability (UBS) of the closed-loop system with a prescribed H ∞ performance are derived in new offline LMIs. In order to illustrate the effectiveness of the suggested event-triggered integral sliding mode control, the Rossler system and track-trailer system are simulated and the obtained results are evaluated with the existing methods. [ABSTRACT FROM AUTHOR]

Published

2023

35. Disturbance observer-based neural adaptive stochastic control for a class of kinetic kill vehicle subject to unmeasured states and full state constraints.

Author

Ning, Xin, Luo, Chengfeng, and Wang, Zheng

Subjects

*ADAPTIVE control systems, *KINETIC control, *RADIAL basis functions, *ARTIFICIAL satellite attitude control systems, *NONLINEAR systems, *STOCHASTIC processes

Abstract

This paper proposes a disturbance observer-based neural adaptive stochastic control approach for the attitude control system of a class of Kinetic Kill Vehicles (KKVs) with unmeasured states and full state constraints. First, a one-one mapping is applied to transform the attitude control system with state constraints into a nonlinear novel system without any constraint. As a result, the control objective is changed into the boundness of the novel system states. Furthermore, the disturbances existing in the system are effectively estimated and eliminated by the nonlinear disturbance observer as well as the radial basis function neural networks (RBFNNs). Moreover, due to the dynamic signal, the dynamic uncertainty induced by the unmeasured states with an unknown dynamic is compensated appropriately. Utilizing the stochastic Lyapunov process, the boundness of all the signals in the system can be proven and the state constraints are satisfied. Finally, two groups of simulations are conducted, which demonstrate the remarkable performance of the proposed algorithm under different working conditions and highlight the advantages compared with existing studies. [ABSTRACT FROM AUTHOR]

Published

2023

36. Distributed control of time-delay interconnected nonlinear systems.

Author

Pessim, Paulo S.P., Coutinho, Pedro Henrique Silva, Lacerda, Márcio J., and Palhares, Reinaldo Martínez

Subjects

*NONLINEAR systems, *ADMISSIBLE sets, *CLOSED loop systems, *TIME-varying systems, *ADAPTIVE fuzzy control, *ADAPTIVE control systems

Abstract

This paper addresses the distributed control of delayed interconnected nonlinear systems with time-varying delays in both the local subsystems' dynamics and the physical interconnections among the subsystems. The Takagi–Sugeno fuzzy model with nonlinear consequent parts (N-TS), which is capable to provide less complex representations than standard T–S fuzzy models, is considered to efficiently deal with this class of complex systems. Then, based on Lyapunov–Krasovskii stability arguments, a synthesis condition is proposed to design a distributed control law such that the origin of the closed-loop interconnected system is locally asymptotically stable together with a guaranteed set of admissible initial conditions for which the validity of the N-TS fuzzy model is ensured. Moreover, a quasi-convex optimization procedure is formulated to enlarge the set of admissible initial conditions. The effectiveness of the proposed synthesis condition is validated in two numerical examples, including an interconnected power network with seven generators. [ABSTRACT FROM AUTHOR]

Published

2023

37. Further results on the finite-time static output feedback control for nonlinear singular systems.

Author

Li, Meiqing and Shao, Yu

Subjects

*NONLINEAR systems, *SINGULAR value decomposition, *STABILITY criterion, *PSYCHOLOGICAL feedback

Abstract

This paper studies the finite-time static output feedback control for a class of nonlinear singular systems. Finite-time stability criterion for the closed singular systems is proposed by static output feedback technique. Based on the properties of structure of the singular system, static output feedback control gain is obtained by using singular value decomposition technique. Meanwhile, different from the existing results of normal systems, the presented scheme reduces the conservatism and complexity during the calculation process. Furthermore, static output feedback H ∞ controller is designed and finite time stability criterion is proposed for the nonlinear singular systems with external disturbance. Finally, the applicability and effectiveness of the proposed strategy are illustrated by a circuit system simulation. [ABSTRACT FROM AUTHOR]

Published

2023

38. Stabilization for a class of strict-feedback nonlinear systems via the PWM control law.

Author

Chang, Le, Shao, Xiaowei, and Zhang, Dexin

Subjects

*NONLINEAR systems, *STATE feedback (Feedback control systems), *STABILITY criterion, *NONLINEAR equations, *PSYCHOLOGICAL feedback

Abstract

This paper studies the PWM control problem of a class of nonlinear systems. During a modulation period, the PWM control signal maintains a pulse waveform with tunable width and fixed magnitude. The PWM control only possesses finite states, and has relatively limited control capability. This causes the degradation of system performance, and even the instability when implementing into a nonlinear system. We will introduce a novel method to design both the state feedback stabilizer and the output feedback stabilizer for strict-feedback nonlinear systems via the PWM control. The system performance is analyzed in a novel framework and the stability criteria is derived to ensure the system convergence. At last, two examples are considered to illustrate the effectiveness of our proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

39. Robust stabilization of uncertain nonlinear systems with infinite distributed input delays.

Author

Zhou, Qianghui, Liu, Lu, and Feng, Gang

Subjects

*UNCERTAIN systems, *NONLINEAR systems, *LINEAR matrix inequalities

Abstract

This paper studies the robust stabilization problem of a class of uncertain Lipschitz nonlinear systems with infinite distributed input delays. A novel robust predictor feedback controller is developed and the controller gain can be obtained via solving a linear matrix inequality. It is shown that the proposed robust predictor feedback controller can globally exponentially stabilize the concerned uncertain nonlinear system with infinite distributed input delays. The key to the proposed approach is the development of several new quadratic Lyapunov functionals. The obtained results are extended to the case of systems with both multiple constant input delays and infinite distributed input delays. It is noted that the obtained results include some existing results on systems with constant input delays or bounded distributed input delays as special cases. Finally, two examples of Chua's circuit and spacecraft rendezvous system are presented to illustrate the effectiveness of the proposed robust controllers. [ABSTRACT FROM AUTHOR]

Published

2023

40. State and output feedback's finite-time guaranteed cost [formula omitted] control for uncertain nonlinear stochastic systems with time-varying delays.

Author

Zhang, Guoping and Zhu, Quanxin

Subjects

*TIME-varying systems, *STOCHASTIC systems, *NONLINEAR systems, *COST functions, *COST control, *ADAPTIVE control systems, *PSYCHOLOGICAL feedback

Abstract

The problems of guaranteed cost control and H ∞ control are studied in this paper for nonlinear uncertain Itô's stochastic systems with time-varying delays in finite-time. It is assumed that the nonlinear function in the systems satisfies the quasi-one-sided Lipschitz nonlinear constraint condition, which is weaker and less conservative than the one-sided Lipschitz condition. Some novel sufficient conditions for the existence of guaranteed cost control strategies are derived by using the Gronwall's inequality, Dynkin's formula, and Lyapunov–Krasovskii functional. The state and output feedback's controllers based on event-triggered control guarantee that the closed-loop system is finite-time stochastically bounded and the given quadratic cost function has an upper bound. Finally, the effectiveness of the suggested method is illustrated by numerical simulation. [ABSTRACT FROM AUTHOR]

Published

2023

41. Prescribed performance control for nonlinear parameter-varying systems with an application to turbofan engine.

Author

Zhu, Pingfang, Yu, Lianchen, and Zeng, Jianping

Subjects

*TURBOFAN engines, *NONLINEAR systems, *ERROR functions, *MAP design, *SUM of squares, *DYNAMIC models

Abstract

In this paper, we investigated the problem of the prescribed performance control for the turbofan engine described by nonlinear parameter-varying (NPV) systems formulation. NPV systems for describing the turbofan engine are set up. Compared with the existing dynamic linear models and nonlinear models, the turbofan engine NPV model can show its dynamics time-varying features and nonlinearity. Meanwhile, based on the turbofan engine NPV system, a prescribed performance tracking controller is designed by error mapping function, and a class of state-and-parameter-dependent (SAPD) control synthesis conditions are formulated. These SAPD conditions can be effectively solved by sum-of-squares technique, and steady-state and transient performance of tracking error can be ensured. Finally, simulation results on the turbofan engine have been given to verify the feasibility and effectiveness of the prescribed performance tracking control scheme. [ABSTRACT FROM AUTHOR]

Published

2023

42. Neural network-based adaptive optimal containment control for non-affine nonlinear multi-agent systems within an identifier-actor-critic framework.

Author

Zhao, Yanwei, Niu, Ben, Zong, Guangdeng, Zhao, Xudong, and Alharbi, Khalid H.

Subjects

*NONLINEAR systems, *HAMILTON-Jacobi-Bellman equation, *FOURIER series, *DYNAMIC programming, *SYSTEM dynamics, *ADAPTIVE fuzzy control, *MULTIAGENT systems

Abstract

This paper addresses the adaptive optimal containment control issue for non-affine nonlinear multi-agent systems in the presence of periodic disturbances. To deal with the disturbed internal dynamics, a fourier series expansion-neural networks-based adaptive identifier is designed for each follower, such that the restrictions posed on the system dynamics are released. Then,an adaptive dynamic programming technique is adopted to acquire the optimized virtual and actual controllers under a simplified actor-critic architecture, where the critic aims to appraise control performance and the actor aims to perform control task. Note that the above updating laws are constructed by the negative gradient of a designed function, which is constructed on the basis of the partial derivative of Hamilton-Jacobi-Bellman equation. Finally, simulation results are provided to show the applicability and effectiveness of the containment control scheme. [ABSTRACT FROM AUTHOR]

Published

2023

43. On consensus control of nonlinear multiagent systems satisfying incremental quadratic constraints.

Author

Qian, Yuchen, Miao, Zhonghua, Zhou, Jin, and Zhu, Xiaojin

Subjects

*MULTIAGENT systems, *NONLINEAR systems, *COMPUTER simulation

Abstract

In this paper, we investigate the problem of leaderless consensus control for the multiagent systems whose nonlinear dynamics satisfying incremental quadratic constraints. A distributed dynamic consensus protocol, decided by communication among neighboring agents, is presented to render nonlinear agent consensus with appropriate coupling weights. Next, an observer-based distributed protocol is considered to ensure consensus of nonlinear system without knowing full state information. Further, extensions to consensus strategies with nonlinear dynamics for the leader-following fashion are also addressed. By comparison to the traditional nonlinear consensus control methodologies, the proposed approach generalizes the Lipschitz nonlinearity as well as the combined nonlinearity of one-sided Lipschitz condition and quadratic inner-boundness condition towards a more generalized type of nonlinearity, which shows us a less conservative result in the Lyapunov proof. Finally, the numerical simulations for six agents are illustrated to show the feasibility and performance of the proposed control protocol with or without the presence of the observer. [ABSTRACT FROM AUTHOR]

Published

2023

44. Observer-based mean square consensus of nonlinear networked systems under Markov switching communication topologies.

Author

Na, Rui, Pan, Ji-An, Zhou, Jialing, Lv, Yuezu, Qin, Tong, and Zheng, Dezhi

Subjects

*NONLINEAR systems, *SPANNING trees, *TOPOLOGY, *MARKOV processes, *LYAPUNOV functions, *ERGODIC theory, *DIRECTED graphs

Abstract

This paper aims to investigate the mean square consensus (MSC) problem of a class of nonlinear networked systems subject to directed and stochastic switching communication topologies, where the switching law is determined by an ergodic continuous-time Markov process. The cooperative consensus controller is designed by using an observer-based method. Firstly, for the case with Lur'e nonlinear dynamics, by developing a stochastic Lyapunov function, we show that the MSC under consideration can be realized if the union of the underlying network graphs has a directed spanning tree. It is worth noting that none of the network graphs is required to contain a directed spanning tree. Moreover, we study the MSC problem for networked systems with Lipschitz-type nonlinear dynamics. Finally, a numerical simulation is conducted on multiple Chua's circuit systems to illustrate the effectiveness of the proposed controllers. [ABSTRACT FROM AUTHOR]

Published

2023

45. Global adaptive fuzzy consensus control of nonlinear multi-agent systems via distributed event-triggered communication.

Author

Mao, Bing, Wu, Xiaoqun, and Lei, Ling

Subjects

*ADAPTIVE fuzzy control, *MULTIAGENT systems, *NONLINEAR systems, *MATRIX inequalities, *MATRIX functions

Abstract

This paper investigates globally bounded consensus of leader-following multi-agent systems with unknown nonlinear dynamics and external disturbance via adaptive event-triggered fuzzy control. Different from existing works where filtering and backstepping techniques are applied to design controllers and event-triggered conditions, a matrix inequality is established to obtain the feedback gain matrix and event-triggered functions. To save communication resources, a new distributed event-triggered controller with fully discontinuous communication among following agents is designed. Meanwhile, a strictly positive minimum of inter-event time is provided to exclude Zeno behavior. Furthermore, to achieve globally bounded leader-following consensus, an adaptive fuzzy approximator and a parameter estimator are designed to approximate the unknown nonlinear dynamics and parameters, respectively. Finally, the effectiveness of the proposed method is validated via a simulation example. [ABSTRACT FROM AUTHOR]

Published

2023

46. Model-Free distributed optimal consensus control of nonlinear multi-agent systems: A graphical game approach.

Author

An, Ningbo, Zhao, Xiaochuan, Wang, Qishao, and Wang, Qingyun

Subjects

*MULTIAGENT systems, *NONLINEAR systems, *NONLINEAR equations, *DYNAMIC programming, *DIFFERENTIAL games, *COMPUTER simulation

Abstract

In this paper, the optimal consensus control problem of nonlinear multi-agent systems(MASs) with completely unknown dynamics is considered. The problem is formulated in a differential graphical game approach which can be solved by Hamilton-Jacobi (HJ) equations. The main difficulty in solving the HJ equations lies in the nonlinear coupling between equations. Based on the Adaptive Dynamic Programming (ADP) technique, an VI-PI mixed HDP algorithm is proposed to solve the HJ equations distributedly. With the PI step, a suitable iterative initial value can be obtained according to the initial policies. Then, VI steps are run to get the optimal solution with exponential convergence rate. Neural networks (NNs) are applied to approximate the value functions, which makes the data-driven end-to-end learning possible. A numerical simulation is conducted to show the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2023

47. Stabilization of highly nonlinear hybrid systems driven by Lévy noise and delay feedback control based on discrete-time state observations.

Author

Moualkia, Seyfeddine and Xu, Yong

Subjects

*HYBRID systems, *NONLINEAR systems, *STOCHASTIC differential equations, *EXPONENTIAL stability, *NOISE, *LYAPUNOV functions, *PSYCHOLOGICAL feedback

Abstract

• Our paper shows how to stabilize an unstable nonlinear delay hybrid SDEs with Lévy noise. • We design a feedback control in both drift and diffusion parts based on discrete-time observations. • We prove the existence and boundedness of the unique global solution under a new set of suitable conditions. • We discuss several kinds of stability for the controlled system using Lyapunov functions. • Our findings improve and generalize some works done in the stabilization theory. There are many hybrid stochastic differential equations (SDEs) in the real-world that don't satisfy the linear growth condition (namely, SDEs are highly nonlinear), but they have highly nonlinear characteristics. Based on some existing results, the main difficulties here are to deal with those equations if they are driven by Lévy noise and delay terms, then to investigate their stability in this case. The present paper aims to show how to stabilize a given unstable nonlinear hybrid SDEs with Lévy noise by designing delay feedback controls in the both drift and diffusion parts of the given SDEs. The controllers are based on discrete-time state observations which are more realistic and make the cost less in practice. By using the Lyapunov functional method under a set of appropriate assumptions, stability results of the controlled hybrid SDEs are discussed in the sense of p th moment asymptotic stability and exponential stability. As an application, an illustrative example is provided to show the feasibility of our theorem. The results obtained in this paper can be considered as an extension of some conclusions in the stabilization theory. [ABSTRACT FROM AUTHOR]

Published

2023

48. Unknown input observer based distributed fault detection for nonlinear multi-agent systems with probabilistic time delay.

Author

Zhao, Siyang, Yu, Jinyong, Wang, Zongxing, and Gao, Dezhi

Subjects

*TIME delay systems, *MULTIAGENT systems, *NONLINEAR systems, *LINEAR matrix inequalities, *BINOMIAL distribution

Abstract

This paper focuses on the fault detection (FD) problem for nonlinear continuous-time multi-agent systems (MASs) with external disturbances and random time-varying delay. The communication topology is assumed to be undirected and connected. Firstly, a stochastic variable satisfying the Bernoulli distribution is utilized to describe the random time-varying delay and transfer the random time-varying delay to a deterministic time-varying delay. To avoid the constraints of the rank conditions for unknown input observer (UIO), the external disturbances and faults from other agents are treated as the unknown inputs which are partitioned into the decoupled part and the non-decoupled part. Sufficient conditions composed of linear matrix inequalities (LMIs) are derived to ensure the stochastic stability of the augmented system with a desired H ∞ performance index and extra freedom of design. By utilizing the properties of UIOs properly, the method proposed in this paper can detect multiple faulty nodes simultaneously. Finally, a numerical example demonstrates the effectiveness and feasibility of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2023

49. A novel [formula omitted] adaptive-hybrid control with guaranteed stability for a class of uncertain nonlinear systems: A case study on SA330 Puma.

Author

Ahmadian, Hossein, Lotfi, Mohammad, Menhaj, Mohammad Bagher, Talebi, Heydar Ali, and Sharifi, Iman

Subjects

*HELICOPTERS, *UNCERTAIN systems, *NONLINEAR systems, *ADAPTIVE control systems, *DEGREES of freedom, *DYNAMICAL systems, *ARMED Forces

Abstract

The helicopter is a highly unstable nonlinear non-minimum phase multiple-input multiple-output (MIMO) system with strong coupling between degrees of freedom. Therefore, its modeling will cause many problems such as control complexity. In addition, hover and forward flight modes are one of the most widely used helicopter flight modes used in many operations. To achieve and stay in these situations, you need very precise settings and timely manual control of the bird. This paper seeks to provide an L 1 adaptive-hybrid control method to solve helicopter control problems in the Koppler system. In this regard, three channels in the coupler system are considered for the design of this controller. The proposed controller also proves the stability of the system during switching between channels. The helicopter that is modeled in this research and its data is used to implement and simulate the Coupler system control is the SA330 Puma helicopter, which is a medium-sized twin-engine support helicopter, in the category of 6 tons, built by Eurocopter France (ECF), and is in service several domestic operators and the armed forces, including the British Air Force. This device is a completely unstable dynamic system. In addition to the inherent instability of this bird, by adding an external load hanging to this system, the challenge of controlling this system is doubled hence, it is necessary to maintain its stability by using a suitable control system. In the meantime, the modeling of the hanging load should be done in three dimensions and two planes, and like most of the work done, only the movement of the plane should not be considered. For this purpose, an L 1 adaptive-hybrid control method is proposed and fully developed in the paper, then it is properly designed for the Coupler system, which contains three channels: Pitch, Roll, and Collective, taking into account the load hanging on the helicopter. Finally, by simulating the results, it can be seen that the main goals, even in the presence of various disturbances, have the desired, efficient, and very good performance. [ABSTRACT FROM AUTHOR]

Published

2022

50. [formula omitted]-stability-based [formula omitted] state estimation of discrete-time nonlinear systems with time-varying delays.

Author

Zhang, Huan, Zhang, Xian, and Yu, Tianqiu

Subjects

*NONLINEAR systems, *DISCRETE-time systems, *TIME-varying systems, *NONLINEAR estimation, *NONLINEAR equations

Abstract

In this paper, the l 2 − l ∞ state estimation problem of discrete-time nonlinear systems (DTNSs) with time-varying delay is studied. The main objective of this paper is to design a state estimator that guarantees not only the global h -stability of the error system in the absence of interference, but also that the output peak value of the error system remains within a certain range under the zero initial conditions. A direct analysis method based on the system solutions is presented, which gives a sufficient condition to decide whether the designed state estimator satisfies the expectation. The method does not follow the construct of any Lyapunov–Krasovskii functional (LKF), thus greatly reducing the workload and complexity of calculation. Finally, three simulation examples are presented to illustrate the applicability of the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2024