Manoeuvring modelling of a containership in shallow water based on optimal truncated nonlinear kernel-based least square support vector machine and quantum-inspired evolutionary algorithm

Xu H.; Guedes Soares C.

Key information

Authors:

Xu H. (Haitong Xu); Guedes Soares C. (Carlos Guedes Soares)

Published in

01/01/2020

Abstract

Nonlinear implicit models are proposed for manoeuvring simulation of a container model in shallow water. A series of Planar Motion Mechanism tests of the DTC ship model carried out in a towing tank with shallow water is used for training the nonlinear implicit manoeuvring model. A novel method, nonlinear kernel-based Least Square Support Vector Machine (LS-SVM), is proposed to approximate the nonlinear manoeuvring model. It is a robust method for regression modelling with a low computational cost by reducing the dimensionality of the kernel matrix. The radial basis function kernel is employed in the SVMs to guarantee the performance of the approximation. The quantum-inspired evolutionary algorithm (QEA) is used to search the optimal value of the predefined parameters of the nonlinear kernel-based LS-SVM. The optimal truncated LS-SVM is used to train the nonlinear regression models for ship manoeuvring, and the generalization performance of the obtained nonlinear manoeuvring models is further tested against the validation set. The R2 goodness-of-fit criterion is used to demonstrate the accuracy of the obtained models.

Publication details

Authors in the community:

Haitong Xu
ist400381
IST > CENTEC
Centro de Engenharia e Tecnologia Naval e Oceânica
IST > DEM
Departamento de Engenharia Mecânica
In: orcid
ID: 132514175
In: scopus
ID: 2-s2.0-85074979700
Carlos Guedes Soares
ist11869
IST > CENTEC
Centro de Engenharia e Tecnologia Naval e Oceânica
In: cienciavitae
ID: 949235

Publication version

VoR - Version of Record

Title of the publication container

Ocean Engineering

First page or article number

106676

Last page

106676

Volume

195

ISSN

0029-8018

DOI

10.1016/j.oceaneng.2019.106676

Fields of Science and Technology (FOS)

mechanical-engineering - Mechanical engineering

Publication language (ISO code)

eng - English

Alternative identifier (URI)

http://dx.doi.org/10.1016/j.oceaneng.2019.106676

Rights type:

Only metadata available

European Commission

Identifier for the funding entity: UID/Multi/00134/2013 - LISBOA-01-0145-FEDER-007629