Modeling Ship Equations of Roll Motion Using Neural Networks
A neural network‐based approach is applied to fit ship rolling models to experimental data and the initial reporting of this methodology is presented in the work of Xing and McCue. Two multivariable nonlinear models are used to describe the nonlinear forced roll motion
of a ship at sea. One, a more traditional model, is based on ordinary differential equations, and the other is based on fractional differential equations (FDEs), which introduced a fractional derivative term to present added hydrodynamic inertia and traditional damping terms. The neural network
method is tested using experimental data. The statistical analysis of 20 cases results showed that the FDEs appeared to better approximate the physics of the system.
Document Type: Research Article
Publication date: 01 September 2010
- The Naval Engineers Journal is the peer-reviewed journal of the American Society of Naval Engineers (ASNE). ASNE is the leading professional engineering society for engineers, scientists and allied professionals who conceive, design, develop, test, construct, outfit, operate and maintain complex naval and maritime ships, submarines and aircraft and their associated systems and subsystems.
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