Abstract
For practical problems with non-convex, large-scale and highly constrained characteristics, evolutionary optimisation algorithms are widely used. However, advanced data-driven methods have yet to be comprehensively applied in related fields. In this study, a surrogate model combined with the Non-dominated Sorting Genetic Algorithm II-Differential Evolution (NSGA-II-DE) is applied to reduce the low-frequency Discrete-Spectrum (DS) force of propeller noise. Reduction of this force has drawn a lot of attention as it is the primary signal used in the sonar-based detection and identification of ships. In the present study, a surrogate model is proposed based on a trained Back-Propagation (BP) fully connected neural network, which improves the optimisation efficiency. The neural network is designed by analysing the depth and width of the hidden layers. The results indicate that a four-layer neural network with 64, 128, 256 and 64 nodes in each layer, respectively, exhibits the highest prediction accuracy. The prediction errors for the first order of DST, second order of DST and the thrust coefficient are only 0.21%, 5.71% and 0.01%, respectively. Data-Driven Evolutionary Optimisation (DDEO) is applied to a standard high-skew propeller to reduce DST. DDEO and a Traditional Evolutionary Optimisation Method (TEOM) obtain the same optimisation results, while the time cost of DDEO is only 0.68% that of the TEOM. Thus, the proposed DDEO is applicable to complex engineering problems in various fields.
Highlights
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The optimisation presented in this study is aimed at reducing the Discrete-Spectrum Thrust (DST) of a propeller, which is the main source of radiated noise and structural vibration from a ship 2
A neural network was carefully designed by analysing the depth and width of the hidden layers
Summary
Marine propeller noise is one of the most prominent noise components that is detectable outside a ship. The source of a marine propeller noise is an unsteady force that comprises a low-frequency Discrete-Spectrum (DS) force, caused by blade rotation in the incoming non-uniform flow, a low-frequency Broadband-Spectrum (BS) force, caused by the interaction between the blade and turbulent fluctuations, and a moderate-to-highfrequency BS force, caused by vortex shedding from the blade’s trailing edge [1]. Low-frequency DS force, which is the primary signal used in the sonar-based detection and identification of ships [2,5], has been extensively licenses/by/4.0/).
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