Concomitant Observer-Based Multi-Level Fault-Tolerant Control for Near-Space Vehicles with New Type Dissimilar Redundant Actuation System

Symmetry Pub Date : 2024-09-17 DOI:10.3390/sym16091221
Meiling Wang, Jun Wang, Jian Huang
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Abstract

This paper presents a concomitant observer-based multi-level fault-tolerant control (FTC) for near-space vehicles (NSVs) with a new type dissimilar redundant actuation system (NT-DRAS). When NSV flight control system faults occur in NT-DRAS and attitude-corresponding sensors, the NSV hybrid output states, including the concomitant observer usable states and the real system states, are applied to solve the FTC gain by using the linear quadratic regulator (LQR) technique. Furthermore, since NT-DRAS is used in NSVs, a multi-level (actuation system level and flight control level) FTC strategy integrating NT-DRAS channel switching and flight control LQR is proposed for complex and worsening fault cases. The most important finding is that though the proposed strategy is applicable for worsening fault cases in NSVs, systematic and accurate criteria for the process being performed are necessary and can improve the FTC efficiency with minimal FTC resources. Additionally, such criteria can improve the NSV’s responsiveness to comprehensive faults, provided that the real-time performance of the fault detection and diagnosis (FDD) scheme can be further optimized. The concomitant observer convergence and the multi-level FTC strategy have been verified by numerical simulations based on the Matlab/Simulink platform.
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基于观测器的近空间飞行器多级容错协同控制与新型异构冗余执行系统
本文提出了一种基于伴随观测器的多级容错控制(FTC),适用于带有新型异样冗余执行系统(NT-DRAS)的近空间飞行器(NSV)。当NSV飞行控制系统的NT-DRAS和姿态对应传感器发生故障时,NSV混合输出状态,包括伴随的观测器可用状态和真实系统状态,通过线性二次调节器(LQR)技术用于求解FTC增益。此外,由于在 NSV 中使用了 NT-DRAS,因此针对复杂和恶化的故障情况,提出了一种集成 NT-DRAS 信道切换和飞行控制 LQR 的多级(执行系统级和飞行控制级)FTC 策略。最重要的发现是,尽管所提出的策略适用于 NSV 中的恶化故障情况,但必须对正在执行的过程制定系统而准确的标准,这样才能以最少的 FTC 资源提高 FTC 效率。此外,只要能进一步优化故障检测和诊断(FDD)方案的实时性能,这些标准还能提高 NSV 对综合故障的响应能力。基于 Matlab/Simulink 平台的数值仿真验证了相应的观测器收敛性和多级 FTC 策略。
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