Autonomous underwater vehicles (AUVs) and investigations of the ice-ocean interface in Antarctic and Arctic waters

JA Dowdeswell, J Evans, R Mugford, G Griffiths, Steve McPhail, N W Millard, P Stevenson, Mark Brandon, C Banks, K J Heywood, M R Price, P A Dodd, A Jenkins, K W Nicholls, D Hayes, E P Abrahamsen, P A Tyler, Brian Bett, D Jones, Peter WadhamsJeremy Wilkinson, K Stansfield, S Ackley

Research output: Contribution to journalArticle

45 Citations (Scopus)

Abstract

Limitations of access have long restricted exploration and investigation of the cavities beneath ice shelves to a small number of drillholes. Studies of sea-ice underwater morphology are limited largely to scientific utilization of submarines. Remotely operated vehicles, tethered to a mother ship by umbilical cable, have been deployed to investigate tidewater-glacier and ice-shelf margins, but their range is often restricted. The development of free-flying autonomous underwater vehicles (AUVs) with ranges of tens to hundreds of kilometres enables extensive missions to take place beneath sea ice and floating ice shelves. Autosub2 is a 3600 kg, 6.7 m long AUV, with a 1600 m operating depth and range of 400 km, based on the earlier Autosub1 which had a 500 rn depth limit. A single direct-drive d.c. motor and five-bladed propeller produce speeds of 1-2 m s(-1). Rear-mounted rudder and stern-plane control yaw, pitch and depth. The vehicle has three sections. The front and rear sections are free-flooding, built around aluminium extrusion space-frames covered with glass-fibre reinforced plastic panels. The central section has a set of carbon-fibre reinforced plastic pressure vessels. Four tubes contain batteries powering the vehicle. The other three house vehicle-control systems and sensors. The rear section houses subsystems for navigation, control actuation and propulsion and scientific sensors (e.g. digital camera, upward-looking 300 kHz acoustic Doppler current profiler, 200 kHz multibeam receiver). The front section contains forward-looking collision sensor, emergency abort, the homing systems, Argos satellite data and location transmitters and flashing lights for relocation as well as science sensors (e.g. twin conductivity-temperature-depth instruments, multibeam transmitter, sub-bottom profiler, AquaLab water sampler). Payload restrictions mean that a subset of scientific instruments is actually in place on any given dive. The scientific instruments carried on Autosub are described and examples of observational data collected from each sensor in Arctic or Antarctic waters are given (e.g. of roughness at the underside of floating ice shelves and sea ice).
Original languageEnglish
Pages (from-to)661-672
Number of pages12
JournalJ GLACIOL
Volume54
Issue number187
Publication statusPublished - 2008

Keywords

  • UNDERSIDE
  • Geosciences, Multidisciplinary
  • SOUTH
  • Geography, Physical
  • STREAMS
  • SHEET
  • GLACIER
  • SEA-ICE
  • ZONE
  • GREENLAND
  • SHELF

Fingerprint Dive into the research topics of 'Autonomous underwater vehicles (AUVs) and investigations of the ice-ocean interface in Antarctic and Arctic waters'. Together they form a unique fingerprint.

  • Cite this

    Dowdeswell, JA., Evans, J., Mugford, R., Griffiths, G., McPhail, S., Millard, N. W., Stevenson, P., Brandon, M., Banks, C., Heywood, K. J., Price, M. R., Dodd, P. A., Jenkins, A., Nicholls, K. W., Hayes, D., Abrahamsen, E. P., Tyler, P. A., Bett, B., Jones, D., ... Ackley, S. (2008). Autonomous underwater vehicles (AUVs) and investigations of the ice-ocean interface in Antarctic and Arctic waters. J GLACIOL, 54(187), 661-672.