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Integral Event-Triggered Attack-Resilient Control of Aircraft-on-Ground Synergistic Turning System With Uncertain Tire Cornering Stiffness | |
Chenglong Du; Fanbiao Li; Yang Shi; Chunhua Yang; Weihua Gui | |
发表期刊 | IEEE/CAA Journal of Automatica Sinica |
ISSN | 2329-9266 |
2023 | |
卷号 | 10期号:5页码:1276-1287 |
摘要 | This article proposes an integral-based event-triggered attack-resilient control method for the aircraft-on-ground (AoG) synergistic turning system with uncertain tire cornering stiffness under stochastic deception attacks. First, a novel AoG synergistic turning model is established with synergistic reverse steering of the front and main wheels to decrease the steering angle of the AoG fuselage, thus reducing the steady-state error when it follows a path with some large curvature. Considering that the tire cornering stiffness of the front and main wheels vary during steering, a dynamical observer is designed to adaptively identify them and estimate the system state at the same time. Then, an integral-based event-triggered mechanism (I-ETM) is synthesized to reduce the transmission frequency at the observer-to-controller end, where stochastic deception attacks may occur at any time with a stochastic probability. Moreover, an attack-resilient controller is designed to guarantee that the closed-loop system is robust $ {\cal{L}}_2$-stable under stochastic attacks and external disturbances. A co-design method is provided to get feasible solutions for the observer, controller, and I-ETM simultaneously. An optimization program is further presented to make a tradeoff between the robustness of the control scheme and the saving of communication resources. Finally, the low- and high-probability stochastic deception attacks are considered in the simulations. The results have illustrated that the AoG synergistic turning system with the proposed control method follows a path with some large curvature well under stochastic deception attacks. Furthermore, compared with the static event-triggered mechanisms, the proposed I-ETM has demonstrated its superiority in saving communication resources. |
关键词 | Adaptive observer aircraft-on-ground (AoG) synergistic turning attack-resilient controller integral-based event-triggered mechanism $ \makescalebox{0.8}{{\cal{L}}_2}$-stability |
DOI | 10.1109/JAS.2023.123480 |
引用统计 | |
文献类型 | 期刊论文 |
条目标识符 | http://ir.ia.ac.cn/handle/173211/51561 |
专题 | 学术期刊_IEEE/CAA Journal of Automatica Sinica |
推荐引用方式 GB/T 7714 | Chenglong Du,Fanbiao Li,Yang Shi,et al. Integral Event-Triggered Attack-Resilient Control of Aircraft-on-Ground Synergistic Turning System With Uncertain Tire Cornering Stiffness[J]. IEEE/CAA Journal of Automatica Sinica,2023,10(5):1276-1287. |
APA | Chenglong Du,Fanbiao Li,Yang Shi,Chunhua Yang,&Weihua Gui.(2023).Integral Event-Triggered Attack-Resilient Control of Aircraft-on-Ground Synergistic Turning System With Uncertain Tire Cornering Stiffness.IEEE/CAA Journal of Automatica Sinica,10(5),1276-1287. |
MLA | Chenglong Du,et al."Integral Event-Triggered Attack-Resilient Control of Aircraft-on-Ground Synergistic Turning System With Uncertain Tire Cornering Stiffness".IEEE/CAA Journal of Automatica Sinica 10.5(2023):1276-1287. |
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