Exponential Stabilization of an n-star Thermoelastic Network System Based on Time-Varying Gains Extended State Observer
Document Type
Article
Publication Date
8-2025
Publication Title
Control Theory and Technology
Abstract
This study investigates the stabilization challenge at the boundaries of a type II thermoelastic network with n-star configuration and terminal masses, which experiences non-uniform bounded external disturbances at its control boundary. This research employs an advanced active disturbance rejection control framework, incorporating an innovative observer with adaptive gain characteristics for precise disturbance estimation, coupled with a robust feedback control mechanism for disturbance compensation. The theoretical analysis establishes rigorous convergence proofs for the proposed time-dependent extended state observer. Furthermore, this investigation utilizes semigroup theory to validate the closed-loop system's well-posed. Through comprehensive Lyapunov-based analysis, this study confirms the system's capability to achieve exponential convergence of tracking errors while effectively mitigating disturbance effects. Extensive numerical experiments corroborate the theoretical findings, demonstrating the control scheme's practical efficacy.
Repository Citation
Zheng, Lingwei; Wang, Lei; and Gao, Zhiqiang, "Exponential Stabilization of an n-star Thermoelastic Network System Based on Time-Varying Gains Extended State Observer" (2025). Electrical and Computer Engineering Faculty Publications. 534.
https://engagedscholarship.csuohio.edu/enece_facpub/534
Original Citation
Zheng, L., Wang, L. & Gao, Z. Exponential stabilization of an n-star thermoelastic network system based on time-varying gains extended state observer. Control Theory Technol. 23, 529–542 (2025). https://doi.org/10.1007/s11768-025-00283-5
DOI
10.1007/s11768-025-00283-5
Volume
23
Issue
3
