An integrated method of advanced optimisation and adaptive ensemble learning for ship fuel consumption prediction
An integrated method of advanced optimisation and adaptive ensemble learning for ship fuel consumption prediction
AbstractAccurate prediction and interpretable analysis of Ship Fuel Consumption (SFC) are critical for optimising maritime operations and supporting decarbonisation efforts in maritime transport, yet existing approaches face significant challenges including limited model generalisation, redundant features due to multi-source data integration, and a lack of transparency in model outputs. These limitations stem from fragmented modelling pipelines that fail to holistically address the challenges of data heterogeneity, feature relevance, parameter tuning, and model adaptability in complex maritime environments. To address these challenges, this study develops an integrated framework that comprises advanced optimisation techniques with adaptive ensemble learning, structured through a synergised pipeline of four technical components. Firstly, multi-source data fusion employs spatio-temporal alignment to integrate ship noon reports, Automatic Identification System data, ECMWF Reanalysis v5, and Global Ocean Physics Analysis and Forecast data, to construct a comprehensive feature space. Secondly, a SHAP-based Weighted Feature Selection algorithm leverages multi-model SHapley Additive exPlanations (SHAP) value assessment with recursive feature elimination to identify and eliminate redundant features, enhancing model generalisation and prediction efficiency. Thirdly, a Hierarchical Adaptive Parameter Space Exploration algorithm integrates global random search and local grid search for efficient hyperparameter optimisation. Finally, an Adaptive Cluster-based Multi-Ensemble model incorporates data clustering and model fusion to capture operational heterogeneity and adaptively assign optimal weights across different data clusters. Comparative experiments demonstrate that the proposed model significantly outperforms six mainstream machine learning models and three classical ensemble methods across multiple evaluation metrics. Moreover, SHAP-based interpretability analysis quantifies feature contributions and reveals specific effects of value changes, enhancing model transparency for decision support. This framework provides a robust technical solution for SFC prediction, offering reliable data-driven tools for energy efficiency management and sustainable maritime operations. The source code is publicly available at: https://github.com/AdvMarTech/ship_fuel_consum_predic.
Adaptive ensemble learning, Data fusion, Feature selection, Fuel consumption, Machine learning, Maritime transport
Cao, Wenjie
eda1ddbf-e811-42f8-9e37-d4307150bf51
Wang, Xinjian
f5b36426-10e7-4d48-8798-e34b972b3af0
Shu, Yaqing
78c0ef18-c191-4112-9a00-22d4b7f5c303
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Zhou, Jingen
ec6155ad-c243-4aa8-b410-bd30db1eaa51
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
1 July 2026
Cao, Wenjie
eda1ddbf-e811-42f8-9e37-d4307150bf51
Wang, Xinjian
f5b36426-10e7-4d48-8798-e34b972b3af0
Shu, Yaqing
78c0ef18-c191-4112-9a00-22d4b7f5c303
Li, Huanhuan
5e806b21-10a7-465c-9db3-32e466ae42f1
Zhou, Jingen
ec6155ad-c243-4aa8-b410-bd30db1eaa51
Yang, Zaili
82d4eebc-4532-4343-8555-35169e79bb6d
Cao, Wenjie, Wang, Xinjian, Shu, Yaqing, Li, Huanhuan, Zhou, Jingen and Yang, Zaili
(2026)
An integrated method of advanced optimisation and adaptive ensemble learning for ship fuel consumption prediction.
Transportation Research Part C: Emerging Technologies, 188, [105659].
(doi:10.1016/j.trc.2026.105659).
Abstract
AbstractAccurate prediction and interpretable analysis of Ship Fuel Consumption (SFC) are critical for optimising maritime operations and supporting decarbonisation efforts in maritime transport, yet existing approaches face significant challenges including limited model generalisation, redundant features due to multi-source data integration, and a lack of transparency in model outputs. These limitations stem from fragmented modelling pipelines that fail to holistically address the challenges of data heterogeneity, feature relevance, parameter tuning, and model adaptability in complex maritime environments. To address these challenges, this study develops an integrated framework that comprises advanced optimisation techniques with adaptive ensemble learning, structured through a synergised pipeline of four technical components. Firstly, multi-source data fusion employs spatio-temporal alignment to integrate ship noon reports, Automatic Identification System data, ECMWF Reanalysis v5, and Global Ocean Physics Analysis and Forecast data, to construct a comprehensive feature space. Secondly, a SHAP-based Weighted Feature Selection algorithm leverages multi-model SHapley Additive exPlanations (SHAP) value assessment with recursive feature elimination to identify and eliminate redundant features, enhancing model generalisation and prediction efficiency. Thirdly, a Hierarchical Adaptive Parameter Space Exploration algorithm integrates global random search and local grid search for efficient hyperparameter optimisation. Finally, an Adaptive Cluster-based Multi-Ensemble model incorporates data clustering and model fusion to capture operational heterogeneity and adaptively assign optimal weights across different data clusters. Comparative experiments demonstrate that the proposed model significantly outperforms six mainstream machine learning models and three classical ensemble methods across multiple evaluation metrics. Moreover, SHAP-based interpretability analysis quantifies feature contributions and reveals specific effects of value changes, enhancing model transparency for decision support. This framework provides a robust technical solution for SFC prediction, offering reliable data-driven tools for energy efficiency management and sustainable maritime operations. The source code is publicly available at: https://github.com/AdvMarTech/ship_fuel_consum_predic.
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Accepted/In Press date: 20 March 2026
e-pub ahead of print date: 2 April 2026
Published date: 1 July 2026
Additional Information:
Publisher Copyright:
© 2026 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY license. http://creativecommons.org/licenses/by/4.0/
Keywords:
Adaptive ensemble learning, Data fusion, Feature selection, Fuel consumption, Machine learning, Maritime transport
Identifiers
Local EPrints ID: 511429
URI: http://eprints.soton.ac.uk/id/eprint/511429
ISSN: 0968-090X
PURE UUID: 267476df-b69e-439a-9765-e2fcdfb19125
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Date deposited: 14 May 2026 16:37
Last modified: 16 May 2026 02:21
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Contributors
Author:
Wenjie Cao
Author:
Xinjian Wang
Author:
Yaqing Shu
Author:
Huanhuan Li
Author:
Jingen Zhou
Author:
Zaili Yang
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