Abstract
This paper investigates the dynamic positioning control of turret-moored vessels with uncertainties, unknown disturbances and velocities. Firstly, a bio-inspired state observer is proposed based on the bio-inspired neural dynamics model to estimate unknown velocities without vessel dynamics model. Meanwhile, an online constructive fuzzy approximator is designed to approximate uncertainties and unknown disturbances. To ensure fuzzy rules adequate and parsimonious, an online constructive scheme is proposed to adjust the fuzzy system structure without any prior knowledge. Based on the designed state observer and fuzzy approximator, a reliability-based robust output-feedback controller is proposed to make the reliability and heading converge to desired values. A reliability-based matrix is applied into the adaptive fuzzy parameter update law to simplify the stability analysis of closed-loop control system. The convergence of reliability can ensure full utilization of mooring system to maintain the vessel within allowable region. Finally, simulations and comparisons show the performance of proposed methods. • The bio-inspired state observer can make the velocity estimation errors converge to zero without the dynamics of vessels. • An online constructive scheme is proposed based on the distances between the current input and existing fuzzy set only. • The online constructive scheme can ensure the fuzzy rules adequate and parsimonious without any prior knowledge. • A reliability-based matrix is designed to build the relationship between the mooring line tension and vessel motion. • The reliability-based matrix is used in the adaptive fuzzy parameter update law to simplify system stability analysis.
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More From: International Journal of Naval Architecture and Ocean Engineering
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