Probabilistic description of extreme oscillations and reliability analysis in rolling motion under stochastic excitation

Large-amplitude rolling motions, also regarded as extreme oscillations, are a great threat to marine navigation, which may lead to capsizing in ship motion. Therefore, it is important to quantify extreme oscillations, assess reliability of ship systems, and establish a suitable indicator to characte...

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Bibliographic Details
Published inScience China. Technological sciences Vol. 66; no. 9; pp. 2586 - 2596
Main Authors Zhao, Dan, Li, YongGe, Xu, Yong, Liu, Qi, Kurths, Jürgen
Format Journal Article
LanguageEnglish
Published Beijing Science China Press 01.09.2023
Springer Nature B.V
Subjects
Capsizing
Damage
Damping ratio
Degrees of freedom
Engineering
Harmonic excitation
Marine environment
Noise intensity
Nonlinear systems
Oscillations
Probability density functions
Probability theory
Random noise
Reliability analysis
Rolling motion
Ship motion
Statistical analysis
Surface navigation
System reliability
rolling motion
extreme oscillations
probabilistic decomposition-synthesis method
colored noise
reliability
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Summary:Large-amplitude rolling motions, also regarded as extreme oscillations, are a great threat to marine navigation, which may lead to capsizing in ship motion. Therefore, it is important to quantify extreme oscillations, assess reliability of ship systems, and establish a suitable indicator to characterize extreme oscillations in ship systems. In this work, extreme events are investigated in a ship model considering a complex ocean environment, described by a single-degree-of-freedom nonlinear system with stochastic harmonic excitation and colored Gaussian noise. The stationary probability density function (PDF) of the system is derived through a probabilistic decomposition-synthesis method. Based on this, we infer the classical damage rate of the system. Furthermore, a new indicator, independent of the PDF, is proposed to quantify the damage related only to the fourth-order moment of the system and the threshold for extreme events. It is more universal and easier to determine as compared with the classical damage rate. A large damping ratio, a large noise intensity, or a short correlation time can reduce the damage rate and the value of the indicator. These findings provide new insights and theoretical guidance to avoid extreme oscillations and assess the reliability of practical ship movements.
ISSN:1674-7321
1869-1900
DOI:10.1007/s11431-022-2388-4