基于误差空间的航天器姿态反步容错控制

提出了一种基于误差空间的航天器姿态反步容错控制方法,以反作用飞轮作为航天器的执行器,在考虑反作用飞轮存在安装偏差及故障的情况下,仍可保证航天器姿态的稳定性。首先,基于Lyapunov稳定性原理,根据系统机械能变化构造了具有普遍性的Lyapunov方程。通过反步递推方法,得到了适用于航天器存在执行器偏差及故障情况的普遍性的容错控制方法;然后,通过误差空间拓扑所得的误差函数描述了势能误差。从几何层面上看,这是描述势能误差的最短路径选择,从而得到了基于误差空间的反步容错控制方法。因此,在对航天器进行姿态控制时,该方法可以迅速调整增益,使得系统姿态误差迅速收敛至零,从而有效减少系统响应时间;最终,通过对考虑执行器偏差及故障情况的航天器姿态控制系统使用不同的控制方法进行数值仿真,验证了该方法能够在执行器故障情况下依然保持系统姿态的稳定,且具备良好的响应速度。     

事件触发机制下的充液航天器姿态控制

针对液体大幅晃动、通信资源受限的充液航天器姿态控制系统，提出一种自适应滑模控制与事件触发机制相结合的控制策略。首先，针对固-液耦合的充液航天器姿态控制系统，选用滑模变结构控制来削弱液体大幅晃动的非线性影响，并设计自适应更新律在线估计不确定参数来提高系统的鲁棒性。然后，考虑星载计算机资源的限制，设计相对阈值的事件触发机制来决定控制输入信号的更新，从而减少控制器与执行器之间的信号更新对通信网络的占用。最后，仿真结果表明，在液体大幅晃动下，所提控制策略不但可以使航天器姿态控制系统最终收敛到任意小的界内，而且可以减少96%的控制信号传输，减轻航天器的通信负载。      

基于深度神经网络的航天器姿态控制系统故障诊断与容错控制研究

针对传统航天姿控系统故障诊断与容错控制诊断精度及控制分配效率较低的问题，提出了一种基于深度神经网络的航天器姿态控制系统故障诊断与容错控制方法。以控制力矩陀螺为执行机构的航天器发生执行机构故障工况时，所提出的方法可保证鲁棒的姿态控制。首先，利用三个异构深度神经网络实现传统容错控制器的故障诊断、姿态控制和力矩分配等功能，建立了全神经网络的智能自适应容错控制器架构。然后，对三个神经网络的网络层数、神经元数目和激活函数等参数进行优化调整，对比分析了神经网络参数对控制器性能的影响。最后，对所提出的新型控制器在控制力矩陀螺发生故障时的控制精度和鲁棒性进行了仿真验证。仿真结果表明，对于具有冗余控制力矩陀螺的航天器，提出的方法不仅能在单一陀螺故障下实现高精度的容错控制，也能在发生多陀螺故障时保证一定的姿态稳定控制。     

基于自适应多设计融合航天器近距离操作的执行器故障补偿技术研究

针对带有执行器故障的航天器近距离操作系统，提出了基于多设计融合的自适应故障补偿方法，实现在发生执行器卡死故障情况下，对目标航天器的位置和姿态的跟踪。提出的故障补偿方法无需故障检测，针对每种可能的故障模式设计控制器组成多控制器集合，并有效地将它们融合后构建最终反馈控制器。仿真结果表明了该故障补偿策略的有效性，能够保证追踪航天器系统的稳定性和期望的跟踪性能。     

基于直接自适应的挠性航天器姿态稳定控制

针对挠性航天器姿态稳定控制,基于退步控制方法与直接自适应控制方法提出了一种自适应控制策略。首先将挠性航天器模型分解为运动学子系统和动力学子系统,并设计具有理想控制性能的参考模型;然后在姿态小角度的假设下,对满足近似严格正实性的姿态运动学子系统设计了直接自适应中间控制律;最后运用退步控制方法对航天器动力学子系统设计了姿态控制器,并证明了闭环系统的稳定性。理论分析和数值仿真结果表明该控制器对挠性航天器的姿态稳定控制是有效的。     

使用SGCMGs航天器滑模姿态容错控制

基于滑模控制与自适应理论,对使用单框架控制力矩陀螺群(SGCMGs)的刚性航天器的被动姿态容错控制问题进行了研究。首先建立了含有陀螺框架转速故障的系统数学模型。然后将框架转速直接作为控制量并应用滑模控制理论设计了容错控制器,同时控制器中还设计了自适应律对故障信息和干扰进行估计。由此,可在故障和干扰的先验信息未知的情况下,实现对航天器无故障和有故障情况下的姿态稳定控制,且具有较强的鲁棒性。最后,对2种构型单框架控制力矩陀螺群的不同故障模式进行数学仿真,验证了该控制方法的有效性和可行性。     

多航天器分布式事件触发分组姿态协同控制

在分布式事件触发机制的基础上对多航天器分组姿态协同控制问题进行了研究。系统内包含若干个分组，并且航天器间的信息交互被抽象为无向拓扑。以修正罗德里格斯参数（MRP）描述航天器的姿态，构造了包含姿态和角速度的辅助变量，并设计了分布式的控制输入。在分布式事件触发机制下，对每个航天器设计了触发函数，并结合代数图论和Lyapunov稳定性理论证明了多航天器能够渐近达到分组姿态协同，同时证明了系统内不会发生Zeno现象。仿真结果验证了在分布式事件触发机制下提出的控制输入的有效性。      

充液航天器大角度机动自适应无源控制

研究了基于自适应无源控制的三轴稳定充液航天器大角度姿态机动问题.将液体晃动等效为黏性球摆模型，利用动量矩守恒定理推导出充液航天器耦合动力学方程.针对陀螺故障及无陀螺配置导致航天器姿态无角速度测量的情况，同时考虑存在外部未知干扰、转动惯量不确定性以及液体晃动位移不可测量的特性，设计自适应输出反馈无源控制，其中自适应更新律用于补偿外部未知干扰和估计液体晃动的位移变量.利用Lyapunov方法和LaSalle不变引理，证明该控制律不但可以保证闭环系统渐进稳定，而且可以保证二个期望平衡位置均达到稳定.仿真结果验证了本文控制方法的有效性.      

导弹增量式自适应容错控制系统设计

导弹在实际飞行中存在气动参数不确定、执行机构故障等问题,从而对导弹飞行控制系统稳定性与操控能力造成严重影响。为此,设计一种增量式自适应容错控制方法,在实现导弹安全控制的同时,兼顾姿态控制算法时效性与可靠性。建立面向控制的三通道耦合姿态动力学模型;考虑系统不确定性和执行机构故障,基于增量式动态逆方法设计导弹被动容错控制律;基于自适应滑模控制与增量式动态逆方法,设计增量式动态逆自适应容错控制律,并对系统残差进行分析比较;通过某典型全弹道姿态跟踪任务,验证舵面故障下的姿态跟踪特性。仿真结果表明:所提方法在故障未知的情况下,能够保证飞行控制系统的鲁棒性与容错能力,实现导弹的安全可靠控制。      

基于事件触发的航天器变周期控制方法研究

摘要： 随着未来航天技术的发展对航天器自主性工作的要求越来越高，星上嵌入式系统所需处理的数据量也急剧增大.而如何在通信与计算资源约束下保证航天器性能就成为一个关键问题.本文基于事件触发控制方法，提出一种在保证控制性能前提下能够大幅降低星上总线负载的航天器姿态控制方法.并从扰动系统理论出发，给出算法的设计流程和稳定性证明.通过仿真算例验证算法的有效性.     

Event-triggered adaptive fuzzy attitude takeover control of spacecraft

The problem of attitude takeover control of spacecraft by using cellular satellites with limited communication, actuator faults and input saturation is investigated. In order to lighten the communication burden of cellular satellites, an event-triggered control strategy is adopted. The filtered attitude information needs to be transmitted only when the defined measurement error reaches the event-triggered threshold in this strategy. Then, to deal with the unknown inertia matrix, actuator faults, external disturbances and the errors caused by event-triggered scheme, fuzzy logic systems is introduced to estimate the uncertainties directly. Combining fuzzy logic control strategy and the event-triggered method, the first event-triggered adaptive fuzzy control law is developed. Then, torque saturation of cellular satellites is further considered in the second control law, where the upper bound of the uncertainties is estimated by fuzzy logic systems. The resulting closed-loop systems under the two control laws are guaranteed to be bounded. Finally, the effectiveness of two proposed control laws is verified by the numerical simulations.     

Fault tolerant small satellite attitude control using adaptive non-singular terminal sliding mode

The Attitude Control System (ACS) plays a pivotal role in the whole performance of the spacecraft on the orbit; therefore, it is vitally important to design the control system with the performance of rapid response, high control precision and insensitive to external perturbations. In the first place, this paper proposes two adaptive nonlinear control algorithms based on the sliding mode control (SMC), which are designed for small satellite attitude control system. The nonlinear dynamics describing the attitude of small satellite is considered in a circle reference orbit, and the stability of the closed-loop system in the presence of external perturbations is investigated. Then, in order to account for accidental or degradation fault in satellite actuators, the fault-tolerant control schemes are presented. Hence, two adaptive fault-tolerant control laws (continuous sliding mode control and non-singular terminal sliding mode control) are developed by adopting the nonlinear analytical model to describe the system, which can guarantee global asymptotic convergence of the attitude control error with the existence of unknown external perturbations. The nonlinear hyperplane based Terminal sliding mode is introduced into the control law design; therefore, the system convergence performance improves and the control error is convergent in “finite time”. As a result, the study on the non-singular terminal sliding mode control is the emphasis and the continuous sliding mode control is used to compare with the non-singular terminal sliding mode control. Meanwhile, an adaptive fuzzy algorithm has been proposed to suppress the chattering phenomenon. Moreover, several numerical examples are presented to demonstrate the efficacy of the proposed controllers by correcting for the external perturbations. Simulation results confirm that the suggested methodologies yield high control precision in control. In addition, actuator degradation, actuator stuck and actuator failure for a period of time are simulated to demonstrate the fault recovery capability of the fault tolerant controllers. The numerical results clearly demonstrate the good performance of the adaptive non-singular terminal control in the event of actuator fault compare with the continuous sliding mode control.     

Robust fault-tolerant saturated control for spacecraft proximity operations with actuator saturation and faults

In this paper, the motion control problem of autonomous spacecraft rendezvous and docking with a tumbling target in the presence of unknown model parameters, external disturbances, actuator saturation and faults is investigated. Firstly, a nonlinear six degree-of-freedom dynamics model is established to describe the relative motion of the chaser spacecraft with respect to the tumbling target. Subsequently, a robust fault-tolerant saturated control strategy with no precise knowledge of model parameters and external disturbances is proposed by combining the sliding mode control technique with an adaptive methodology. Then, within the Lyapunov framework, it is proved that the designed robust fault-tolerant controller can guarantee the relative position and attitude errors converge into small regions containing the origin. Finally, numerical simulations are performed to demonstrate the effectiveness and robustness of the proposed control strategy.