控制理论(社会学)
容错
饱和(图论)
跟踪(教育)
计算机科学
控制(管理)
主题(文档)
控制工程
断层(地质)
工程类
实时计算
人工智能
分布式计算
数学
地质学
心理学
教育学
组合数学
地震学
图书馆学
标识
DOI:10.1177/01423312251321562
摘要
In practical engineering applications, timely fault detection and estimation are often critical, while time-consuming fault detection processes can lead to system instability or significant performance degradation. To address this issue, a practical predefined-time convergence mechanism has been developed. This mechanism starts with an introduction to fault detection, followed by the design of a predefined-time fault estimation approach. Subsequently, a practical predefined-time fault-tolerant controller, along with a theoretical proof of the proposed control algorithm, is provided. A new scheme for singularity avoidance is introduced, ensuring that tracking errors do not approach infinity near the origin. The effectiveness of this approach is verified through its application to unmanned surface vessels for trajectory tracking, where it outperforms traditional fixed-time and predefined-time controllers. Its key characteristics include simple operation, remarkable effectiveness, and intuitive display. Ultimately, this research enhances the transient stability and robustness of unmanned ships control under non-ideal conditions and environments.
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