Deriving spatial wave data from a network of buoys and ships

Raphaël E.G. Mounet; Jiaxin Chen; Ulrik D. Nielsen; Astrid H. Brodtkorb; Ajit C. Pillai; Ian G.C. Ashton; Edward C.C. Steele

doi:10.1016/j.oceaneng.2023.114892

Deriving spatial wave data from a network of buoys and ships

Raphaël E.G. Mounet^*, Jiaxin Chen, Ulrik D. Nielsen, Astrid H. Brodtkorb, Ajit C. Pillai, Ian G.C. Ashton, Edward C.C. Steele

^*Corresponding author for this work

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Abstract

The real-time provision of high-quality estimates of the ocean wave parameters at appropriate spatial resolutions are essential for the sustainable operations of marine structures. Machine learning affords considerable opportunity for providing additional value from sensor networks, fusing metocean data collected by various platforms. Exploiting the ship-as-a-wave-buoy concept, this article proposes the integration of vessel-based observations into a wave-nowcasting framework. Surrogate models are trained using a high-fidelity physics-based nearshore wave model to learn the spatial correlations between grid points within a computational domain. The performance of these different models are evaluated in a case study to assess how well wave parameters estimated through the spectral analysis of ship motions can perform as inputs to the surrogate system, to replace or complement traditional wave buoy measurements. The benchmark study identifies the advantages and limitations inherent in the methodology incorporating ship-based wave estimates to improve the reliability and availability of regional sea state information.

Original language	English
Article number	114892
Journal	Ocean Engineering
Volume	281
Number of pages	19
ISSN	0029-8018
DOIs	https://doi.org/10.1016/j.oceaneng.2023.114892
Publication status	Published - 2023

Keywords

Sea state estimation
Spectral wave model
Ship motions
Wave-buoy analogy
Machine learning
Metocean conditions

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10.1016/j.oceaneng.2023.114892Licence: CC BY

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Sea state estimation based on measurements from multiple observation platforms
Mounet, R. E. G. (PhD Student), Nielsen, U. D. (Main Supervisor), H. Brodtkorb, A. (Supervisor), Dietz, J. (Examiner) & J. Sørensen, A. (Examiner)
01/10/2020 → 16/02/2024
Project: PhD

NetSSE
Mounet, R. E. G. (Creator) & Nielsen, U. D. (Supervisor), Technical University of Denmark, 27 Jul 2023
DOI: 10.11583/DTU.26379811, https://gitlab.gbar.dtu.dk/regmo/NetSSE and one more link, http://netsse.readthedocs.io (show fewer)
Dataset

Cite this

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title = "Deriving spatial wave data from a network of buoys and ships",

abstract = "The real-time provision of high-quality estimates of the ocean wave parameters at appropriate spatial resolutions are essential for the sustainable operations of marine structures. Machine learning affords considerable opportunity for providing additional value from sensor networks, fusing metocean data collected by various platforms. Exploiting the ship-as-a-wave-buoy concept, this article proposes the integration of vessel-based observations into a wave-nowcasting framework. Surrogate models are trained using a high-fidelity physics-based nearshore wave model to learn the spatial correlations between grid points within a computational domain. The performance of these different models are evaluated in a case study to assess how well wave parameters estimated through the spectral analysis of ship motions can perform as inputs to the surrogate system, to replace or complement traditional wave buoy measurements. The benchmark study identifies the advantages and limitations inherent in the methodology incorporating ship-based wave estimates to improve the reliability and availability of regional sea state information.",

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author = "Mounet, {Rapha{\"e}l E.G.} and Jiaxin Chen and Nielsen, {Ulrik D.} and Brodtkorb, {Astrid H.} and Pillai, {Ajit C.} and Ashton, {Ian G.C.} and Steele, {Edward C.C.}",

year = "2023",

doi = "10.1016/j.oceaneng.2023.114892",

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AU - Mounet, Raphaël E.G.

AU - Chen, Jiaxin

AU - Nielsen, Ulrik D.

AU - Brodtkorb, Astrid H.

AU - Pillai, Ajit C.

AU - Ashton, Ian G.C.

AU - Steele, Edward C.C.

PY - 2023

Y1 - 2023

N2 - The real-time provision of high-quality estimates of the ocean wave parameters at appropriate spatial resolutions are essential for the sustainable operations of marine structures. Machine learning affords considerable opportunity for providing additional value from sensor networks, fusing metocean data collected by various platforms. Exploiting the ship-as-a-wave-buoy concept, this article proposes the integration of vessel-based observations into a wave-nowcasting framework. Surrogate models are trained using a high-fidelity physics-based nearshore wave model to learn the spatial correlations between grid points within a computational domain. The performance of these different models are evaluated in a case study to assess how well wave parameters estimated through the spectral analysis of ship motions can perform as inputs to the surrogate system, to replace or complement traditional wave buoy measurements. The benchmark study identifies the advantages and limitations inherent in the methodology incorporating ship-based wave estimates to improve the reliability and availability of regional sea state information.

AB - The real-time provision of high-quality estimates of the ocean wave parameters at appropriate spatial resolutions are essential for the sustainable operations of marine structures. Machine learning affords considerable opportunity for providing additional value from sensor networks, fusing metocean data collected by various platforms. Exploiting the ship-as-a-wave-buoy concept, this article proposes the integration of vessel-based observations into a wave-nowcasting framework. Surrogate models are trained using a high-fidelity physics-based nearshore wave model to learn the spatial correlations between grid points within a computational domain. The performance of these different models are evaluated in a case study to assess how well wave parameters estimated through the spectral analysis of ship motions can perform as inputs to the surrogate system, to replace or complement traditional wave buoy measurements. The benchmark study identifies the advantages and limitations inherent in the methodology incorporating ship-based wave estimates to improve the reliability and availability of regional sea state information.

KW - Sea state estimation

KW - Spectral wave model

KW - Ship motions

KW - Wave-buoy analogy

KW - Machine learning

KW - Metocean conditions

U2 - 10.1016/j.oceaneng.2023.114892

DO - 10.1016/j.oceaneng.2023.114892

M3 - Journal article

SN - 0029-8018

VL - 281

JO - Ocean Engineering

JF - Ocean Engineering

M1 - 114892

ER -

Deriving spatial wave data from a network of buoys and ships

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Keywords

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Sea state estimation based on measurements from multiple observation platforms

Datasets

NetSSE

Cite this