nerc.ac.uk

An innovative marine growth detection system for underwater gliders

Anderlini, Enrico; Alcaraz Real-Arce, Daniel; Morales, Tania; Barrera, Carlos; Hernandez-Brito, Jose J.; Phillips, Alexander B.; Thomas, Giles. 2021 An innovative marine growth detection system for underwater gliders. Journal of Oceanic Engineering. (Submitted)

Before downloading, please read NORA policies.
[img] Text
An Innovative Marine Growth Detection System for Underwater Gliders.pdf - Submitted Version
Restricted to NORA staff only

Download (4MB) | Request a copy

Abstract/Summary

Marine growth has been observed to cause a drop in the horizontal and vertical velocities of underwater gliders, thus making them unresponsive and needing immediate recovery. Currently, no strategies exist to correctly identify the onset of marine growth for gliders and only limited datasets of biofouled hulls exist. Here, a field test has been conducted to first investigate the impact of marine growth on the dynamics and power consumption of underwater gliders and then design an anomaly detection system for high levels of biofouling. A Slocum glider was deployed first for eight days with drag stimulators to imitate severe biofouling; then the vehicle was redeployed with no additions to the hull for a further 20 days. The mimicked biofouling caused a speed reduction due to a significant increase in drag. Additionally, the lower speed causes the steady-state flight stage to last longer and the rudder to become less responsive; hence, marine growth results in a shortening of deployment duration through an increase in power consumption. As actual biofouling due to p. pollicipes occurred during the second deployment, it is possible to develop and test a system that successfully detects and identifies high levels of marine growth on the glider, blending model- and data-based solutions using steady-state flight data. The system will greatly help pilots re-plan missions to safely recover the vehicle if significant biofouling is detected.

Item Type: Publication - Article
Date made live: 27 Apr 2021 10:00 +0 (UTC)
URI: https://nora.nerc.ac.uk/id/eprint/530043

Actions (login required)

View Item View Item

Document Downloads

Downloads for past 30 days

Downloads per month over past year

More statistics for this item...