A novel dataset and feature selection for data-driven conceptual design of offshore jacket substructures

Conceptual design is crucial for designing offshore jacket substructures because it sets the direction for the entire design process. Nevertheless, conventional simulation-based optimization methods for jacket conceptual design face challenges, such as high computational costs and restricted optimiz...

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Bibliographic Details
Published in:Ocean engineering 2024-07, Vol.303, p.117679, Article 117679
Main Authors: Qian, Han, Panagiotou, Emmanouil, Peng, Mengyan, Ntoutsi, Eirini, Kang, Chongjie, Marx, Steffen
Format: Article
Language:English
Subjects:
Conceptual design
Data-driven method
Dataset
Feature selection
Machine learning
Offshore jacket substructure
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Summary:Conceptual design is crucial for designing offshore jacket substructures because it sets the direction for the entire design process. Nevertheless, conventional simulation-based optimization methods for jacket conceptual design face challenges, such as high computational costs and restricted optimization objectives. This paper proposes a data-driven method for offshore jacket conceptual design using machine learning (ML). First, a novel dataset of completed and under-construction jackets worldwide was established as the cornerstone of ML. The dataset comprised “in-action” data capturing key structural parameters of jackets and information on design boundary conditions. Subsequently, different features were comprehensively selected to identify and visualize their correlations for an interpretable data-driven design, ensuring the effectiveness of the dataset for training the ML models. Finally, random forest and eXtreme gradient boosting models were trained on the data from the selected feature subsets and then employed to predict individual jacket structural parameters. The predictive performance of the models indicates that the dataset and feature selection can capture the fundamental and shared characteristics of well-designed jackets, thereby improving the accuracy and efficiency of the conceptual design process. This study suggests the potential of a data-driven conceptual design for offshore jacket substructures. [Display omitted] •Data-driven approach for conceptual design of offshore jacket substructures.•Novel dataset of offshore jacket substructures worldwide.•Suitable subsets of input features for predicting each jacket structural parameter.•Trained Random Forest, XGBoost models for predicting jacket structural parameters.
ISSN:0029-8018
1873-5258
DOI:10.1016/j.oceaneng.2024.117679