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Auteurs principaux: Yajima, Yoshiyuki, Mishima, Sakiko, Tonami, Noriyuki, Hino, Tomoyuki, Aibe, Shugo, Saikawa, Junichiro, Mizuguchi, Koji
Format: Preprint
Publié: 2026
Sujets:
Accès en ligne:https://arxiv.org/abs/2604.24882
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author Yajima, Yoshiyuki
Mishima, Sakiko
Tonami, Noriyuki
Hino, Tomoyuki
Aibe, Shugo
Saikawa, Junichiro
Mizuguchi, Koji
author_facet Yajima, Yoshiyuki
Mishima, Sakiko
Tonami, Noriyuki
Hino, Tomoyuki
Aibe, Shugo
Saikawa, Junichiro
Mizuguchi, Koji
contents Monitoring sea states across the offshore wind farm areas is essential to keep their structures safe, efficiently operate the systems, and assess the environmental effects of wind turbines. Conventional sea state sensors like buoys limit their observable coverage; therefore, installing many sensors across the wide area is necessary to obtain sufficient sea state information. However, such a situation is not practical in terms of cost. Instead, the study proposes utilising optical fibres, which is embedded in existing power cables for telecommunications on the seabed, as sea state monitoring sensors with distributed acoustic sensing (DAS). DAS is a vibration-sensing technology along optical fibres based on the Rayleigh backscattering of the injected laser. It measures the dynamic strain of the optical fibre in real time at each spatial bin, which is called a "channel" along the fibre. In power cables on the seabed, time-varying water pressure due to waves is expected to exert dynamic strain. This hypothesis motivates us to validate whether the application of DAS for power cables can estimate sea state, such as wave period, height, and the direction of arrival. Hence, the authors carried out a wave tank experiment with a programmable wave generator. An actual power cable is installed under the same condition as the bottom-mounted offshore wind turbines. The experimental results show that (i) the wave period can be accurately estimated from the frequency-domain analysis. (ii) The strong linearity between DAS vibration power and the wave height is found. (iii) The direction of arrival of waves can be estimated with the error of 1.5$^\circ$ when there are at least two laying angles of the cable in parallel with the estimation of wavelength. These outcomes promote the feasibility of utilising the existing power cables across offshore wind farms as sea state monitoring sensors.
format Preprint
id arxiv_https___arxiv_org_abs_2604_24882
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Wave Tank Experiment for Sea State Monitoring with Distributed Acoustic Sensing
Yajima, Yoshiyuki
Mishima, Sakiko
Tonami, Noriyuki
Hino, Tomoyuki
Aibe, Shugo
Saikawa, Junichiro
Mizuguchi, Koji
Signal Processing
Optics
Physics and Society
Monitoring sea states across the offshore wind farm areas is essential to keep their structures safe, efficiently operate the systems, and assess the environmental effects of wind turbines. Conventional sea state sensors like buoys limit their observable coverage; therefore, installing many sensors across the wide area is necessary to obtain sufficient sea state information. However, such a situation is not practical in terms of cost. Instead, the study proposes utilising optical fibres, which is embedded in existing power cables for telecommunications on the seabed, as sea state monitoring sensors with distributed acoustic sensing (DAS). DAS is a vibration-sensing technology along optical fibres based on the Rayleigh backscattering of the injected laser. It measures the dynamic strain of the optical fibre in real time at each spatial bin, which is called a "channel" along the fibre. In power cables on the seabed, time-varying water pressure due to waves is expected to exert dynamic strain. This hypothesis motivates us to validate whether the application of DAS for power cables can estimate sea state, such as wave period, height, and the direction of arrival. Hence, the authors carried out a wave tank experiment with a programmable wave generator. An actual power cable is installed under the same condition as the bottom-mounted offshore wind turbines. The experimental results show that (i) the wave period can be accurately estimated from the frequency-domain analysis. (ii) The strong linearity between DAS vibration power and the wave height is found. (iii) The direction of arrival of waves can be estimated with the error of 1.5$^\circ$ when there are at least two laying angles of the cable in parallel with the estimation of wavelength. These outcomes promote the feasibility of utilising the existing power cables across offshore wind farms as sea state monitoring sensors.
title Wave Tank Experiment for Sea State Monitoring with Distributed Acoustic Sensing
topic Signal Processing
Optics
Physics and Society
url https://arxiv.org/abs/2604.24882