Evolution of tracking error over time.

Evolution of tracking error over time.

<div><p>Floating offshore platforms (FOPs) face the challenge of anchor chain failures due to their unique operating environments. This directly impacts the platform’s safety and stability. Traditional control methods are often ineffective in addressing anchor chain failures. Therefore,...

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Bibliografiske detaljer
Hovedforfatter: Chengliang Chao (22676651) (author)
Andre forfattere: Yang Liu (4829) (author), Zongkai Wang (20488603) (author)
Udgivet: 2025
Fag:
Biophysics
Biotechnology
Biological Sciences not elsewhere classified
Mathematical Sciences not elsewhere classified
unique operating environments
strategic parameter scheduling
platform &# 8217
multiple performance metrics
extreme performance optimization
traditional control methods
rigorous stability analysis
real fop system
fault handling capabilities
edf dual finite
triggered dynamic mechanism
time convergence paradigm
control system
time convergence
fop systems
driven mechanism
control design
tolerant strategy
time learning
study proposes
study introduces
study designs
results demonstrate
preset finite
often ineffective
offline phase
nonlinear error
mixed uncertainties
directly impacts
based generator
asymptotic stability
achieve finite
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Summary:<div><p>Floating offshore platforms (FOPs) face the challenge of anchor chain failures due to their unique operating environments. This directly impacts the platform’s safety and stability. Traditional control methods are often ineffective in addressing anchor chain failures. Therefore, this study proposes a novel event-triggered, self-tuning integrated PID control strategy based on finite-time learning to improve the stability and fault handling capabilities of FOP systems. This study introduces a preset finite-time convergence function based on a time-based generator (TBG) in the control design, combined with a nonlinear error-driven mechanism to achieve finite-time convergence. By integrating a composite variable construction method with neural network approximation techniques, a state mapping mechanism adaptable to mixed uncertainties is established. Furthermore, this study designs a control system that integrates an event-triggered dynamic mechanism with a finite-time convergence paradigm. Through strategic parameter scheduling, this control strategy achieves coordinated optimal configuration and extreme performance optimization under multiple performance metrics in an offline phase. A rigorous stability analysis of the designed control strategy using Lyapunov stability theory demonstrates its effectiveness in terms of asymptotic stability and finite-time convergence. Simulations are conducted on a real FOP system. Results demonstrate that the control strategy effectively addresses anchor chain failures and internal and external uncertain dynamics.</p></div>

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