Your search keyword '"An, Qingxian"' showing total 4 results

1. Spacecraft Attitude Stabilization Control with Fault-Tolerant Capability via a Mixed Learning Algorithm.

Author

Wang, Jihe, Jia, Qingxian, and Yu, Dan

Subjects

MACHINE learning, FAULT-tolerant control systems, SPACE vehicles, ARTIFICIAL satellite attitude control systems, ADAPTIVE control systems, PARTICLE swarm optimization

Abstract

The issue of active attitude fault-tolerant stabilization control for spacecrafts subject to actuator faults, inertia uncertainty, and external disturbances is investigated in this paper. To robustly and accurately reconstruct actuator faults, a novel mixed learning observer (MLO) is explored by combining the iterative learning algorithm and the repetitive learning algorithm. Moreover, to guarantee robust spacecraft attitude fault-tolerant stabilization, by synthesizing the mixed learning algorithm with the sliding mode controller, a novel mixed learning sliding-mode controller (MLSMC) is designed based on the separation principle, in which the mixed learning algorithm is used to update composite disturbances online, including fault errors, inertia uncertainty, and external disturbances. Finally, a numerical example is provided to demonstrate the effectiveness and superiority of our proposed spacecraft attitude fault-tolerant stabilization control approach. [ABSTRACT FROM AUTHOR]

Published

2023

2. Spacecraft attitude fault-tolerant stabilization against loss of actuator Effectiveness: A novel iterative learning sliding mode approach.

Author

Jia, Qingxian, Ma, Rui, Zhang, Chengxi, and Varatharajoo, Renuganth

Subjects

*FAULT-tolerant computing, *MACHINE learning, *ITERATIVE learning control, *ARTIFICIAL satellite attitude control systems, *ACTUATORS, *SLIDING mode control, *SPACE vehicles

Abstract

This paper investigates the attitude fault-tolerant stabilization problem for a spacecraft subjected to its actuator effectiveness loss, inertia uncertainties and space disturbances. A novel Iterative Learning Sliding Mode Observer (ILSMO) is proposed to reconstruct the actuator effectiveness factors robustly and accurately by combining the P-type iterative learning algorithm with the sliding mode approach. Based on the reconstructed fault signals, an Iterative Learning Sliding Mode Controller (ILSMC) is designed to guarantee the closed-loop spacecraft attitude fault-tolerant stabilization by compensating for its lumped disturbance. The ILSMO and ILSMC stabilities are guaranteed using the Lyapunov direct approach, respectively. Finally, the numerical simulation results show that the proposed ILSMO-ILSMC-based spacecraft attitude fault-tolerant stabilization method is effective and superior. [ABSTRACT FROM AUTHOR]

Published

2023

3. Disturbance observer-based performance guaranteed fault-tolerant control for multi-spacecraft formation reconfiguration with collision avoidance.

Author

Jia, Qingxian, Gui, Yule, Wu, Yunhua, and Zhang, Chengxi

Subjects

*FAULT-tolerant control systems, *SLIDING mode control, *FORMATION flying, *ARTIFICIAL satellite attitude control systems

Abstract

In this study, the issue of the performance guaranteed fault-tolerant control for formation reconfiguration with collision avoidance in the multi-spacecraft system subjects to space perturbations and thruster faults is investigated. A new nonlinear iterative learning disturbance observer is constructed to accurately reconstruct the synthesized disturbance no matter it is time-varying or not. Then, an exponential artificial potential function with a simple structure and low computation requirement is designed to avoid collision between spacecrafts. A nonsingular terminal sliding mode fault-tolerant control method is explored to accomplish fault-tolerant formation reconfiguration with collision avoidance ability and prescribed robust performance. Finally, numerical simulations and comparisons are performed to validate the effectiveness and superiority of the proposed approaches. [ABSTRACT FROM AUTHOR]

Published

2023

4. Fault-tolerant attitude coordination control for multiple flexible spacecraft using vector measurements.

Author

Zheng, Zhong, Chen, Ti, Zhou, Feng, Jia, Qingxian, and Li, Peng

Subjects

*ARTIFICIAL satellite attitude control systems, *SPACE vehicles, *FAULT-tolerant control systems, *ERRORS-in-variables models, *ANGULAR velocity, *ROBUST control

Abstract

This paper addresses the control problems of distributed attitude coordination for multiple flexible spacecraft based on the feedback of inertial vector measurements. It is assumed that the angular velocity information is not available, and the modal variable cannot be measured. The orientation error model with vector measurements is introduced. And then the distributed attitude synchronization control scheme is presented without actuator faults or disturbances. It is guaranteed that the desired equilibrium is locally asymptotically stable and the undesired equilibrium is unstable. Meanwhile, the domain of attraction is given by inequality constraints. In the case that there exist actuator faults and external disturbances, a robust fault-tolerant control strategy is developed to realize attitude synchronization. The hyperbolic tangent function in place of sign function is adopted to eliminate external disturbances. Meanwhile, the adaptive laws are proposed to estimate actuator faults. The salient feature of these control approaches is that no modal variable observers are utilized and the control schemes are robust to the inertia uncertainty of spacecraft. Finally, numerical simulations are implemented to manifest the validity of the presented control schemes. [ABSTRACT FROM AUTHOR]

Published

2023