Decentralized Dynamic Event-Triggered Output-Feedback Control of Stochastic Non-Triangular Interconnected Systems With Unknown Time-Varying Sensor Sensitivity
成果类型:
Article
署名作者:
Sun, Libei; Song, Yongduan; Lv, Maolong
署名单位:
Chongqing University; Air Force Engineering University
刊物名称:
IEEE TRANSACTIONS ON AUTOMATIC CONTROL
ISSN/ISSBN:
0018-9286
DOI:
10.1109/TAC.2024.3508547
发表日期:
2025
页码:
2786-2793
关键词:
Event detection
sensitivity
uncertainty
Stochastic processes
Interconnected systems
asymptotic stability
vectors
Time-varying systems
Backstepping
Couplings
Dynamic event-triggered control
Global asymptotic stability
non-triangular structural uncertainties
sensor sensitivity
stochastic interconnected systems
摘要:
This study addresses the intricate challenge of decentralized output-feedback control for stochastic non-triangular nonlinear interconnected systems with unknown time-varying sensor sensitivity in a dynamic event-triggered context. The presence of stochastic disturbances, non-triangular structural uncertainties, and evolving sensor sensitivity distinguishes this problem of global asymptotic stability from conventional event-triggered control scenarios. Existing event-triggered control approaches with static event conditions encounter difficulties in simultaneously ensuring zero tracking/stabilization error and preventing the occurrence of Zeno behavior. In this work, we develop a novel solution to address this complex issue. First, we establish a linear relationship between the state vector of each interconnected subsystem and two error vectors through a unique coordinate transformation. This transformation effectively handles the complexities introduced by non-triangular structural uncertainties. Second, we introduce a decentralized dynamic event-triggered output-feedback control strategy, which involves a state observer and a decentralized output-feedback controller. Unlike conventional event-triggered control methods with static event conditions, this strategy formulates a modified clock-based dynamic triggering mechanism by introducing an auxiliary variable that evolves based on predicted plant state values, while utilizing a clock variable to guarantee the existence of a positive lower bound on inter-execution times. Rigorous Lyapunov analysis confirms the global asymptotic stability in probability of the closed-loop system, with the states and the output of each local subsystem converging to the equilibrium at the origin in probability. In addition, the existence of a minimal dwell-time between triggering instants is guaranteed. Finally, we substantiate the advantages and efficiency of the proposed algorithm through comprehensive numerical simulations.
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