Distributed acoustic sensing for active offshore shear wave profiling

Trafford, Andrew; Ellwood, Robert; Wacquier, Loris; Godfrey, Alastair; Minto, Chris; Coughlan, Mark; Donohue, Shane

doi:10.1038/s41598-022-13962-z

Cited by 10 publications

(3 citation statements)

References 41 publications

(39 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A promising method to monitor offshore power cables, which typically already feature inbuilt fiber optic strands, lies in use of Distributed Acoustic Sensing (DAS) measurements [6]. DAS is a recent fiber optic sensing technology, which uses Rayleigh scattering to track changes in the strain of a fiber at any location [7].…”

Section: Background and Problem Setupmentioning

confidence: 99%

Towards unsupervised fault detection for offshore wind turbine cable protection systems using contrastive learning

Duthé,

L’Homme,

Abdallah

et al. 2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

As offshore wind power expands globally, it is essential to ensure the reliable operation of components of such critical infrastructures. A less explored instance of such components, which are though essential in terms of operation, is found in subsea turbine cables and their protection systems, whose failure can incur prolonged shutdown periods and costly repairs. We propose a novel unsupervised machine learning approach exploiting use of Distributed Acoustic Sensing (DAS) data and contrastive learning for monitoring offshore wind turbine Cable Protection Systems (CPSs). A Transformer neural network adapted for time-series ingests the high-frequency, noisy DAS CPS time-series measurements, and is trained to learn a coherent representation of the data using a contrastive learning scheme that enforces temporal and positional consistency in the latent space. This latent representation can then be used to perform anomaly detection in an unsupervised manner, alleviating the need for costly labeled offshore anomaly data. We demonstrate that a coherent representation of the data is learnt by the model, which we then use to detect synthetic anomalies and an actual CPS stabilization event.

show abstract

Section: Background and Problem Setupmentioning

confidence: 99%

Towards unsupervised fault detection for offshore wind turbine cable protection systems using contrastive learning

Duthé,

L’Homme,

Abdallah

et al. 2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

show abstract

“…Distributed Acoustic Sensing (DAS) is an emerging technology which is commonly employed for the detection and analysis of seismic waves on the ocean bottom and for submarine structural characterization [38], [39]. It is enabled by fiber optic installed along underwater infrastructures, that continuously allows the monitoring in real time of underwater assets.…”

Section: Distributed Acoustic Sensingmentioning

confidence: 99%

Monitoring of Underwater Critical Infrastructures: the Nord Stream and Other Recent Case Studies

Soldi¹,

Gaglione²,

Raponi³

et al. 2023

Preprint

View full text Add to dashboard Cite

The explosions on September 26th, 2022, which damaged the gas pipelines of Nord Stream 1 and Nord Stream 2, have highlighted the need and urgency of improving the resilience of Underwater Critical Infrastructures (UCIs). Comprising gas pipelines and power and communication cables, these connect countries worldwide and are critical for the global economy and stability. An attack targeting multiple of such infrastructures simultaneously could potentially cause significant damage and greatly affect various aspects of daily life. Due to the increasing number and continuous deployment of UCIs, existing underwater surveillance solutions, such as Autonomous Underwater Vehicles (AUVs) or Remotely Operated Vehicles (ROVs), are not adequate enough to ensure thorough monitoring.We show that the combination of information from both underwater and above-water surveillance sensors enables achieving Seabed-to-Space Situational Awareness (S3A), mainly thanks to Artificial Intelligence (AI) and Information Fusion (IF) methodologies. These are designed to process immense volumes of information, fused from a variety of sources and generated from monitoring a very large number of assets on a daily basis. The learned knowledge can be used to anticipate future behaviors, identify threats, and determine critical situations concerning UCIs.To illustrate the capabilities and importance of S3A, we consider three events that occurred in the second half of 2022: the aforementioned Nord Stream explosions, the cutoff of the underwater communication cable SHEFA-2 connecting the Shetland Islands and the UK mainland, and the suspicious activity of a large vessel in the Adriatic Sea. Specifically, we provide analyses of the available data, from Automatic Identification System (AIS) and satellite data, integrated with possible contextual information, e.g., bathymetry, Patterns Of Life (POLs), weather conditions, and human intelligence (HUMINT).

show abstract

“…Depending on the method used we can sense acoustic signals, temperature and strain. Seismic analysis of acoustic signals can enable the mechanical properties of the subsurface to be detected [2] and potentially monitored over time. Strain measurements can used to detect small amounts of ground motion, that can be an indication that the area is becoming unstable and a larger movement is likely to occur.…”

Section: Introductionmentioning

confidence: 99%

Long term strain and temperature measurements on a railway using Brillouin OTDR

Crickmore,

Allousch,

Marx

et al. 2024

Optical Sensing and Detection VIII

View full text Add to dashboard Cite

A distributed temperature and strain sensing (DTSS) system based on Brillouin backscatter was used to measure changes during a 5 month period on an 9km length of fibre optic cable deployed next to a railway line, including on an embankment and a bridge. By measuring the amplitude and frequency of the Brillouin backscatter it was possible to determine both temperature and strain changes. Most of the strain changes occurred slowly over many weeks, however some rapid strain changes occurred on part of the embankment on one particular day. Temperature effects were dominated by the diurnal and seasonal variations of the air temperature. At a number of points along the cable there were small optical losses that varied with time, but the ability of the system to also carry out regular Rayleigh OTDR measurements meant that these losses could be accounted for, so they had minimal effect on the data.

show abstract

Distributed acoustic sensing for active offshore shear wave profiling

Cited by 10 publications

References 41 publications

Towards unsupervised fault detection for offshore wind turbine cable protection systems using contrastive learning

Towards unsupervised fault detection for offshore wind turbine cable protection systems using contrastive learning

Monitoring of Underwater Critical Infrastructures: the Nord Stream and Other Recent Case Studies

Long term strain and temperature measurements on a railway using Brillouin OTDR

Contact Info

Product

Resources

About