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Wikipedia

Autonomous underwater vehicle

December 02, 2023

"AUV" redirects here. For a type of road vehicle, see Asian utility vehicle.

An autonomous underwater vehicle (AUV) is a robot that travels underwater without requiring continuous input from an operator. AUVs constitute part of a larger group of undersea systems known as unmanned underwater vehicles, a classification that includes non-autonomous remotely operated underwater vehicles (ROVs) – controlled and powered from the surface by an operator/pilot via an umbilical or using remote control. In military applications an AUV is more often referred to as an unmanned undersea vehicle (UUV). Underwater gliders are a subclass of AUVs.

Picture taken of the Battlespace Preparation Autonomous Underwater Vehicle (BPAUV) by an employee of Bluefin Robotics Corporation during a US Navy exercise.
The Blackghost AUV is designed to undertake an underwater assault course autonomously with no outside control.
Pluto Plus AUV for underwater mine identification and destruction. From Norwegian minehunter KNM Hinnøy

History edit

The first AUV was developed at the Applied Physics Laboratory at the University of Washington as early as 1957 by Stan Murphy, Bob Francois and later on, Terry Ewart. The "Self-Propelled Underwater Research Vehicle", or SPURV, was used to study diffusion, acoustic transmission, and submarine wakes.

Other early AUVs were developed at the Massachusetts Institute of Technology in the 1970s. One of these is on display in the Hart Nautical Gallery in MIT. At the same time, AUVs were also developed in the Soviet Union[1] (although this was not commonly known until much later).

Applications edit

This type of underwater vehicles has recently become an attractive alternative for underwater search and exploration since they are cheaper than manned vehicles. Over the past years, there have been abundant attempts to develop underwater vehicles to meet the challenge of exploration and extraction programs in the oceans. Recently, researchers have focused on the development of AUVs for long-term data collection in oceanography and coastal management.[2]

Commercial edit

The oil and gas industry uses AUVs to make detailed maps of the seafloor before they start building subsea infrastructure; pipelines and sub sea completions can be installed in the most cost effective manner with minimum disruption to the environment. The AUV allows survey companies to conduct precise surveys of areas where traditional bathymetric surveys would be less effective or too costly. Also, post-lay pipe surveys are now possible, which includes pipeline inspection. The use of AUVs for pipeline inspection and inspection of underwater man-made structures is becoming more common.[citation needed] There also is development of AUVs for potential seabed mining and/or harvesting of polymetallic nodule rocks.[3]

Research edit

 
A University of South Florida researcher deploys Tavros02, a solar-powered "tweeting" AUV (SAUV)

Scientists use AUVs to study lakes, the ocean, and the ocean floor. A variety of sensors can be affixed to AUVs to measure the concentration of various elements or compounds, the absorption or reflection of light, and the presence of microscopic life. Examples include conductivity-temperature-depth sensors (CTDs), fluorometers, and pH sensors. Additionally, AUVs can be configured as tow-vehicles to deliver customized sensor packages to specific locations.

The Applied Physics Lab at the University of Washington has been creating iterations of its Seaglider AUV platform since the 1950s. Though the Seaglider was originally designed for oceanographic research, in recent years it has seen much interest from organizations such as the U.S. Navy or the oil and gas industry. The fact that these autonomous gliders are relatively inexpensive to manufacture and operate is indicative of most AUV platforms that will see success in myriad applications.[4][weasel words][vague][clarification needed]

An example of an AUV interacting directly with its environment is the Crown-Of-Thorns Starfish Robot (COTSBot) created by the Queensland University of Technology (QUT). The COTSBot finds and eradicates crown-of-thorns starfish (Acanthaster planci), a species that damages the Great Barrier Reef. It uses a neural network to identify the starfish and injects bile salts to kill it.[5]

Hobby edit

See also: Personal Submersibles Organization

Many roboticists construct AUVs as a hobby. Several competitions exist which allow these homemade AUVs to compete against each other while accomplishing objectives.[6][7][8] Like their commercial brethren, these AUVs can be fitted with cameras, lights, or sonar. As a consequence of limited resources and inexperience, hobbyist AUVs can rarely compete with commercial models on operational depth, durability, or sophistication. Finally, these hobby AUVs are usually not oceangoing, being operated most of the time in pools or lake beds. A simple AUV can be constructed from a microcontroller, PVC pressure housing, automatic door lock actuator, syringes, and a DPDT relay.[9] Some participants in competitions create designs that rely on open-source software.[10]

Illegal drug traffic edit

Submarines that travel autonomously to a destination by means of GPS navigation have been made by illegal drug traffickers.[11][12][13][14]

Air crash investigations edit

Autonomous underwater vehicles, for example AUV ABYSS, have been used to find wreckage of missing airplanes, e.g. Air France Flight 447,[15] and the Bluefin-21 AUV was used in the search for Malaysia Airlines Flight 370.[16]

Military applications edit

 
MK 18 MOD 1 Swordfish UUV
 
Mk 18 Mod 2 Kingfish UUV
 
Kingfish UUV launch

The U.S. Navy Unmanned Undersea Vehicle (UUV) Master Plan[17] identified the following UUV's missions:

  • Intelligence, surveillance, and reconnaissance
  • Mine countermeasures
  • Anti-submarine warfare
  • Inspection/identification
  • Oceanography
  • Communication/navigation network nodes
  • Payload delivery
  • Information operations
  • Time-critical strikes

The Navy Master Plan divided all UUVs into four classes:[18]

  • Man-portable vehicle class: 25–100 lb displacement; 10–20 hours endurance; launched from small water craft manually (i.e., Mk 18 Mod 1 Swordfish UUV)
  • Lightweight vehicle class: up to 500 lb displacement, 20–40 hours endurance; launched from RHIB using launch-retriever system or by cranes from surface ships (i.e., Mk 18 Mod 2 Kingfish UUV)
  • Heavyweight vehicle class: up to 3,000 lb displacement, 40–80 hours endurance, launched from submarines
  • Large vehicle class: up to 10 long tons displacement; launched from surface ships and submarines

In 2019, the Navy ordered five Orca UUVs, its first acquisition of unmanned submarines with combat capability.[19]

Vehicle designs edit

Hundreds of different AUVs have been designed over the past 50 or so years,[20] but only a few companies sell vehicles in any significant numbers. There are around 10 companies that sell AUVs on the international market, including Kongsberg Maritime, HII (formerly Hydroid, and previously owned by Kongsberg Maritime)[21]), Bluefin Robotics, Teledyne Gavia (previously known as Hafmynd), International Submarine Engineering (ISE) Ltd, Atlas Elektronik, RTsys,[22] MSubs[23] and OceanScan.[24]

Vehicles range in size from man portable lightweight AUVs to large diameter vehicles of over 10 metres length. Large vehicles have advantages in terms of endurance and sensor payload capacity; smaller vehicles benefit significantly from lower logistics (for example: support vessel footprint; launch and recovery systems).

Some manufacturers have benefited from domestic government sponsorship including Bluefin and Kongsberg. The market is effectively split into three areas: scientific (including universities and research agencies), commercial offshore (offshore energy, marine minerals etc.) and defence related applications (mine countermeasures, battle space preparation). The majority of these roles utilize a similar design and operate in a cruise (torpedo-type) mode. They collect data while following a preplanned route at speeds between 1 and 4 knots.

Commercially available AUVs include various designs, such as the small REMUS 100 AUV originally developed by Woods Hole Oceanographic Institution in the US and now produced commercially by HII; the HUGIN Family of AUVs comprising HUGIN, HUGIN Edge, HUGIN Superior and HUGIN Endurance developed by Kongsberg Maritime and Norwegian Defence Research Establishment; the Bluefin Robotics 12-and-21-inch-diameter (300 and 530 mm) vehicles; the ISE Ltd. Explorer; Cellula Robotics' Solus LR; the RT Sys Comet and NemoSens AUVs; Teledyne's Gavia, Osprey and SeaRaptor; and the L3 Harris Ocean Server Iver range of AUVs.

Most AUVs fall into the survey class or cruising AUVs, in a cylindrical or torpedo shape with a powered propeller. This is seen as the best compromise between size, usable volume, hydrodynamic efficiency and ease of handling. There are some vehicles that make use of a modular design, enabling components to be changed easily by the operators. Some recent developments move away from the traditional cylindrical shape in favour of other arrangements such as Saab's Sabretooth hybrid R/AUV or the recently launched HUGIN Edge. These either optimise the shape according to the operational requirements (Sabretooth) or to benefit from low drag hydrodynamic performance (HUGIN Edge).

The market has matured since 2010 with greater emphasis on data than on vehicle characteristics. Operators are more technically aware and the utilisation of AUVs has increased commensurately. More operators use their systems autonomously, rather than supervising the vehicles using an acoustic link. Consequently, on-board processing and in-mission autonomy have become more important features for AUVs. Most AUVs have what is considered navigational or event-based autonomy. They will follow a geographic mission plan with distinct events to operate sensors, change course or return to the surface. Some AUVs have adaptive autonomy, for example the ability to adjust course to avoid obstacles along the planned route. The current state of the art is a vehicle that collects, processes and acts on the data it has acquired without operator input.

As of 2008, a new class of AUVs are being developed, which mimic designs found in nature. Although most are currently in their experimental stages, these biomimetic (or bionic) vehicles are able to achieve higher degrees of efficiency in propulsion and maneuverability by copying successful designs in nature. Two such vehicles are Festo's AquaJelly (AUV)[25] and the EvoLogics BOSS Manta Ray.[26]

Sensors edit

AUVs carry sensors to navigate autonomously and map features of the ocean. Typical sensors include compasses, depth sensors, sidescan and other sonars, magnetometers, thermistors and conductivity probes. Some AUVs are outfitted with biological sensors including fluorometers (also known as chlorophyll sensors), turbidity sensors, and sensors to measure pH, and amounts of dissolved oxygen.

A demonstration at Monterey Bay, in California, in September 2006, showed that a 21-inch (530 mm) diameter AUV can tow a 400 feet (120 m)-long hydrophone array while maintaining a 6-knot (11 km/h) cruising speed.[citation needed]

Navigation edit

Radio waves cannot penetrate water very far, so as soon as an AUV dives it loses its GPS signal. Therefore, a standard way for AUVs to navigate underwater is through dead reckoning. Navigation can however be improved by using an underwater acoustic positioning system. When operating within a net of sea floor deployed baseline transponders this is known as LBL navigation. When a surface reference such as a support ship is available, ultra-short baseline (USBL) or short-baseline (SBL) positioning is used to calculate where the sub-sea vehicle is relative to the known (GPS) position of the surface craft by means of acoustic range and bearing measurements. To improve estimation of its position, and reduce errors in dead reckoning (which grow over time), the AUV can also surface and take its own GPS fix. Between position fixes and for precise maneuvering, an Inertial Navigation System on board the AUV calculates through dead reckoning the AUV position, acceleration, and velocity. Estimates can be made using data from an Inertial Measurement Unit, and can be improved by adding a Doppler Velocity Log (DVL), which measures the rate of travel over the sea/lake floor. Typically, a pressure sensor measures the vertical position (vehicle depth), although depth and altitude can also be obtained from DVL measurements. These observations are filtered to determine a final navigation solution.

Propulsion edit

There are a couple of propulsion techniques for AUVs. Some of them use a brushed or brush-less electric motor, gearbox, Lip seal, and a propeller which may be surrounded by a nozzle or not. All of these parts embedded in the AUV construction are involved in propulsion. Other vehicles use a thruster unit to maintain the modularity. Depending on the need, the thruster may be equipped with a nozzle for propeller collision protection or to reduce noise submission, or it may be equipped with a direct drive thruster to keep the efficiency at the highest level and the noises at the lowest level.[27] Advanced AUV thrusters have a redundant shaft sealing system to guarantee a proper seal of the robot even if one of the seals fails during the mission.[citation needed]

Underwater gliders do not directly propel themselves. By changing their buoyancy and trim, they repeatedly sink and ascend; airfoil "wings" convert this up-and-down motion to forward motion. The change of buoyancy is typically done through the use of a pump that can take in or push out water. The vehicle's pitch can be controlled by moving the center of mass of the vehicle. For Slocum gliders this is done internally by moving the batteries, which are mounted on a screw.[28] Because of their low speed and low-power electronics, the energy required to cycle trim states is far less than for regular AUVs, and gliders can have endurances of months and transoceanic ranges.[citation needed]

Communications edit

Since radio waves do not propagate well under water, many AUV's incorporate acoustic modems to enable remote command and control. These modems typically utilize proprietary communications techniques and modulation schemes. In 2017 NATO ratified the ANEP-87 JANUS standard for subsea communications. This standard allows for 80 BPS communications links with flexible and extensible message formatting.[citation needed] Alternative communication techniques are being explored, including optical, inductive and RF based techniques, which may be combined in a multi-modal solutions.[29] Evaluations are also being conducted on novel communication techniques which are able to utilize the infrastructure as a communication path to provide alternative communication paths and opportunities from the vehicles.[30]

Power edit

Most AUVs in use today are powered by rechargeable batteries (lithium ion, lithium polymer, nickel metal hydride etc.), and are implemented with some form of battery management system. Some vehicles use primary batteries which provide perhaps twice the endurance—at a substantial extra cost per mission. Previously some systems used aluminum based semi-fuel cells, but these require substantial maintenance, require expensive refills and produce waste product that must be handled safely. An emerging trend is to combine different battery and power systems with supercapacitors.[citation needed]

See also edit

References edit

  1. ^ Autonomous Vehicles at the Institute of Marine Technology Problems May 27, 2009, at the Wayback Machine
  2. ^ Saghafi, Mohammad; Lavimi, Roham (2020-02-01). "Optimal design of nose and tail of an autonomous underwater vehicle hull to reduce drag force using numerical simulation". Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment. 234 (1): 76–88. doi:10.1177/1475090219863191. ISSN 1475-0902. S2CID 199578272.
  3. ^ "Impossible Metals demonstrates its super-careful seabed mining robot". New Atlas. 8 December 2022. Retrieved 17 January 2023.
  4. ^ "Seaglider: Autonomous Underwater Vehicle".
  5. ^ Dayoub, F.; Dunbabin, M.; Corke, P. (2015). Robotic detection and tracking of Crown-of-thorns starfish. IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). doi:10.1109/IROS.2015.7353629.
  6. ^ . Archived from the original on 13 June 2015. Retrieved 25 May 2015.
  7. ^ Designspark ChipKIT Challenge (this competition is now closed)
  8. ^ Autonomous Underwater Vehicle Competition
  9. ^ Osaka University NAOE Mini Underwater Glider (MUG) for Education March 13, 2011, at the Wayback Machine
  10. ^ . Debian-News. 2009-10-08. Archived from the original on 28 April 2015. Retrieved 25 May 2015.
  11. ^ Kijk magazine, 3/2012[full citation needed]
  12. ^ Sharkey, Noel; Goodman, Marc; Ros, Nick (2010). "The Coming Robot Crime Wave" (PDF). Computer. 43 (8): 116–115. doi:10.1109/MC.2010.242. ISSN 0018-9162. S2CID 29820095.
  13. ^ Wired for war: The robotics revolution and conflict in the twenty-first century by P.W.Singer, 2009
  14. ^ Lichtenwald, Terrance G.,Steinhour, Mara H., and Perri, Frank S. (2012). "A maritime threat assessment of sea based criminal organizations and terrorist operations," Homeland Security Affairs Volume 8, Article 13.
  15. ^ "Malaysia Airlines: World's only three Abyss submarines readied for plane search". Telegraph.co.uk. 23 March 2014.
  16. ^ "Bluefin robot joins search for missing Malaysian plane - The Boston Globe". BostonGlobe.com. Retrieved 2017-02-28.
  17. ^ Department of the Navy, The Navy Unmanned Undersea Vehicle (UUV) Master Plan, 9 Nov 2004.
  18. ^ (PDF). Archived from the original (PDF) on 2015-09-08. Retrieved 2015-11-18.
  19. ^ "The Navy is starting to put up real money for robot submarines". Los Angeles Times. 19 April 2019. Retrieved 20 October 2020.
  20. ^ "AUV System Timeline". Retrieved 25 May 2015.
  21. ^ "KONGSBERG acquires Hydroid LLC" Kongsberg - Hydroid, 2007
  22. ^ "RTsys". www.rtsys.fr/.
  23. ^ rvarcoe (2018-03-27). "Unmanned Systems | Submergence Group | MSubs". Retrieved 2023-05-25.
  24. ^ "LAUV – Light Autonomous Underwater Vehicle". www.oceanscan-mst.com. Retrieved 2017-02-28.
  25. ^ "AquaJelly" 2015-09-24 at the Wayback Machine Festo Corporate, 2008
  26. ^ . Archived from the original on 2018-03-24. Retrieved 2018-03-24.
  27. ^ "High Efficiency, Low Noise Underwater Thruster". lianinno.com. Retrieved 23 January 2023.
  28. ^ "Slocum Glider". www.whoi.edu. Retrieved 23 January 2023.
  29. ^ Beatrice Tomasi, Marie B. Holstad, Ingvar Henne, Bard Henriksen, Pierre-Jean Bouvet, et al.. MarTERA UNDINA project: a multi-modal communication and network-aided positioning system for marine robotics and benthic stations. 28th annual Underwater Technology Conference - UTC'22, Jun 2022, Bergen, Norway. ⟨hal-03779076⟩
  30. ^ Mulholland, J.J.; Smolyaninov, I.I. (2022-08-30). "Plasmonic - Surface Electromagnetic Wave Communication for subsea asset inspection". 2022 Sixth Underwater Communications and Networking Conference (UComms). Lerici, Italy: IEEE. pp. 1–5. doi:10.1109/UComms56954.2022.9905693. ISBN 978-1-6654-7461-0. S2CID 252705048.

Bibliography edit

External links edit

 
Wikimedia Commons has media related to Autonomous underwater vehicles.
  • First AUV to cross Atlantic Ocean Displayed at Smithsonian

December 02, 2023
autonomous, underwater, vehicle, redirects, here, type, road, vehicle, asian, utility, vehicle, autonomous, underwater, vehicle, robot, that, travels, underwater, without, requiring, continuous, input, from, operator, auvs, constitute, part, larger, group, und. AUV redirects here For a type of road vehicle see Asian utility vehicle An autonomous underwater vehicle AUV is a robot that travels underwater without requiring continuous input from an operator AUVs constitute part of a larger group of undersea systems known as unmanned underwater vehicles a classification that includes non autonomous remotely operated underwater vehicles ROVs controlled and powered from the surface by an operator pilot via an umbilical or using remote control In military applications an AUV is more often referred to as an unmanned undersea vehicle UUV Underwater gliders are a subclass of AUVs Picture taken of the Battlespace Preparation Autonomous Underwater Vehicle BPAUV by an employee of Bluefin Robotics Corporation during a US Navy exercise The Blackghost AUV is designed to undertake an underwater assault course autonomously with no outside control Pluto Plus AUV for underwater mine identification and destruction From Norwegian minehunter KNM Hinnoy Contents 1 History 2 Applications 2 1 Commercial 2 2 Research 2 3 Hobby 2 4 Illegal drug traffic 2 5 Air crash investigations 2 6 Military applications 3 Vehicle designs 3 1 Sensors 3 2 Navigation 3 3 Propulsion 3 4 Communications 3 5 Power 4 See also 5 References 5 1 Bibliography 6 External linksHistory editThe first AUV was developed at the Applied Physics Laboratory at the University of Washington as early as 1957 by Stan Murphy Bob Francois and later on Terry Ewart The Self Propelled Underwater Research Vehicle or SPURV was used to study diffusion acoustic transmission and submarine wakes Other early AUVs were developed at the Massachusetts Institute of Technology in the 1970s One of these is on display in the Hart Nautical Gallery in MIT At the same time AUVs were also developed in the Soviet Union 1 although this was not commonly known until much later Applications editThis type of underwater vehicles has recently become an attractive alternative for underwater search and exploration since they are cheaper than manned vehicles Over the past years there have been abundant attempts to develop underwater vehicles to meet the challenge of exploration and extraction programs in the oceans Recently researchers have focused on the development of AUVs for long term data collection in oceanography and coastal management 2 Commercial edit The oil and gas industry uses AUVs to make detailed maps of the seafloor before they start building subsea infrastructure pipelines and sub sea completions can be installed in the most cost effective manner with minimum disruption to the environment The AUV allows survey companies to conduct precise surveys of areas where traditional bathymetric surveys would be less effective or too costly Also post lay pipe surveys are now possible which includes pipeline inspection The use of AUVs for pipeline inspection and inspection of underwater man made structures is becoming more common citation needed There also is development of AUVs for potential seabed mining and or harvesting of polymetallic nodule rocks 3 Research edit nbsp A University of South Florida researcher deploys Tavros02 a solar powered tweeting AUV SAUV Scientists use AUVs to study lakes the ocean and the ocean floor A variety of sensors can be affixed to AUVs to measure the concentration of various elements or compounds the absorption or reflection of light and the presence of microscopic life Examples include conductivity temperature depth sensors CTDs fluorometers and pH sensors Additionally AUVs can be configured as tow vehicles to deliver customized sensor packages to specific locations The Applied Physics Lab at the University of Washington has been creating iterations of its Seaglider AUV platform since the 1950s Though the Seaglider was originally designed for oceanographic research in recent years it has seen much interest from organizations such as the U S Navy or the oil and gas industry The fact that these autonomous gliders are relatively inexpensive to manufacture and operate is indicative of most AUV platforms that will see success in myriad applications 4 weasel words vague clarification needed An example of an AUV interacting directly with its environment is the Crown Of Thorns Starfish Robot COTSBot created by the Queensland University of Technology QUT The COTSBot finds and eradicates crown of thorns starfish Acanthaster planci a species that damages the Great Barrier Reef It uses a neural network to identify the starfish and injects bile salts to kill it 5 Hobby edit See also Personal Submersibles Organization Many roboticists construct AUVs as a hobby Several competitions exist which allow these homemade AUVs to compete against each other while accomplishing objectives 6 7 8 Like their commercial brethren these AUVs can be fitted with cameras lights or sonar As a consequence of limited resources and inexperience hobbyist AUVs can rarely compete with commercial models on operational depth durability or sophistication Finally these hobby AUVs are usually not oceangoing being operated most of the time in pools or lake beds A simple AUV can be constructed from a microcontroller PVC pressure housing automatic door lock actuator syringes and a DPDT relay 9 Some participants in competitions create designs that rely on open source software 10 Illegal drug traffic edit Submarines that travel autonomously to a destination by means of GPS navigation have been made by illegal drug traffickers 11 12 13 14 Air crash investigations edit Autonomous underwater vehicles for example AUV ABYSS have been used to find wreckage of missing airplanes e g Air France Flight 447 15 and the Bluefin 21 AUV was used in the search for Malaysia Airlines Flight 370 16 Military applications edit nbsp MK 18 MOD 1 Swordfish UUV nbsp Mk 18 Mod 2 Kingfish UUV nbsp Kingfish UUV launchThe U S Navy Unmanned Undersea Vehicle UUV Master Plan 17 identified the following UUV s missions Intelligence surveillance and reconnaissance Mine countermeasures Anti submarine warfare Inspection identification Oceanography Communication navigation network nodes Payload delivery Information operations Time critical strikesThe Navy Master Plan divided all UUVs into four classes 18 Man portable vehicle class 25 100 lb displacement 10 20 hours endurance launched from small water craft manually i e Mk 18 Mod 1 Swordfish UUV Lightweight vehicle class up to 500 lb displacement 20 40 hours endurance launched from RHIB using launch retriever system or by cranes from surface ships i e Mk 18 Mod 2 Kingfish UUV Heavyweight vehicle class up to 3 000 lb displacement 40 80 hours endurance launched from submarines Large vehicle class up to 10 long tons displacement launched from surface ships and submarinesIn 2019 the Navy ordered five Orca UUVs its first acquisition of unmanned submarines with combat capability 19 Vehicle designs editHundreds of different AUVs have been designed over the past 50 or so years 20 but only a few companies sell vehicles in any significant numbers There are around 10 companies that sell AUVs on the international market including Kongsberg Maritime HII formerly Hydroid and previously owned by Kongsberg Maritime 21 Bluefin Robotics Teledyne Gavia previously known as Hafmynd International Submarine Engineering ISE Ltd Atlas Elektronik RTsys 22 MSubs 23 and OceanScan 24 Vehicles range in size from man portable lightweight AUVs to large diameter vehicles of over 10 metres length Large vehicles have advantages in terms of endurance and sensor payload capacity smaller vehicles benefit significantly from lower logistics for example support vessel footprint launch and recovery systems Some manufacturers have benefited from domestic government sponsorship including Bluefin and Kongsberg The market is effectively split into three areas scientific including universities and research agencies commercial offshore offshore energy marine minerals etc and defence related applications mine countermeasures battle space preparation The majority of these roles utilize a similar design and operate in a cruise torpedo type mode They collect data while following a preplanned route at speeds between 1 and 4 knots Commercially available AUVs include various designs such as the small REMUS 100 AUV originally developed by Woods Hole Oceanographic Institution in the US and now produced commercially by HII the HUGIN Family of AUVs comprising HUGIN HUGIN Edge HUGIN Superior and HUGIN Endurance developed by Kongsberg Maritime and Norwegian Defence Research Establishment the Bluefin Robotics 12 and 21 inch diameter 300 and 530 mm vehicles the ISE Ltd Explorer Cellula Robotics Solus LR the RT Sys Comet and NemoSens AUVs Teledyne s Gavia Osprey and SeaRaptor and the L3 Harris Ocean Server Iver range of AUVs Most AUVs fall into the survey class or cruising AUVs in a cylindrical or torpedo shape with a powered propeller This is seen as the best compromise between size usable volume hydrodynamic efficiency and ease of handling There are some vehicles that make use of a modular design enabling components to be changed easily by the operators Some recent developments move away from the traditional cylindrical shape in favour of other arrangements such as Saab s Sabretooth hybrid R AUV or the recently launched HUGIN Edge These either optimise the shape according to the operational requirements Sabretooth or to benefit from low drag hydrodynamic performance HUGIN Edge The market has matured since 2010 with greater emphasis on data than on vehicle characteristics Operators are more technically aware and the utilisation of AUVs has increased commensurately More operators use their systems autonomously rather than supervising the vehicles using an acoustic link Consequently on board processing and in mission autonomy have become more important features for AUVs Most AUVs have what is considered navigational or event based autonomy They will follow a geographic mission plan with distinct events to operate sensors change course or return to the surface Some AUVs have adaptive autonomy for example the ability to adjust course to avoid obstacles along the planned route The current state of the art is a vehicle that collects processes and acts on the data it has acquired without operator input As of 2008 a new class of AUVs are being developed which mimic designs found in nature Although most are currently in their experimental stages these biomimetic or bionic vehicles are able to achieve higher degrees of efficiency in propulsion and maneuverability by copying successful designs in nature Two such vehicles are Festo s AquaJelly AUV 25 and the EvoLogics BOSS Manta Ray 26 Sensors edit AUVs carry sensors to navigate autonomously and map features of the ocean Typical sensors include compasses depth sensors sidescan and other sonars magnetometers thermistors and conductivity probes Some AUVs are outfitted with biological sensors including fluorometers also known as chlorophyll sensors turbidity sensors and sensors to measure pH and amounts of dissolved oxygen A demonstration at Monterey Bay in California in September 2006 showed that a 21 inch 530 mm diameter AUV can tow a 400 feet 120 m long hydrophone array while maintaining a 6 knot 11 km h cruising speed citation needed Navigation edit Radio waves cannot penetrate water very far so as soon as an AUV dives it loses its GPS signal Therefore a standard way for AUVs to navigate underwater is through dead reckoning Navigation can however be improved by using an underwater acoustic positioning system When operating within a net of sea floor deployed baseline transponders this is known as LBL navigation When a surface reference such as a support ship is available ultra short baseline USBL or short baseline SBL positioning is used to calculate where the sub sea vehicle is relative to the known GPS position of the surface craft by means of acoustic range and bearing measurements To improve estimation of its position and reduce errors in dead reckoning which grow over time the AUV can also surface and take its own GPS fix Between position fixes and for precise maneuvering an Inertial Navigation System on board the AUV calculates through dead reckoning the AUV position acceleration and velocity Estimates can be made using data from an Inertial Measurement Unit and can be improved by adding a Doppler Velocity Log DVL which measures the rate of travel over the sea lake floor Typically a pressure sensor measures the vertical position vehicle depth although depth and altitude can also be obtained from DVL measurements These observations are filtered to determine a final navigation solution Propulsion edit There are a couple of propulsion techniques for AUVs Some of them use a brushed or brush less electric motor gearbox Lip seal and a propeller which may be surrounded by a nozzle or not All of these parts embedded in the AUV construction are involved in propulsion Other vehicles use a thruster unit to maintain the modularity Depending on the need the thruster may be equipped with a nozzle for propeller collision protection or to reduce noise submission or it may be equipped with a direct drive thruster to keep the efficiency at the highest level and the noises at the lowest level 27 Advanced AUV thrusters have a redundant shaft sealing system to guarantee a proper seal of the robot even if one of the seals fails during the mission citation needed Underwater gliders do not directly propel themselves By changing their buoyancy and trim they repeatedly sink and ascend airfoil wings convert this up and down motion to forward motion The change of buoyancy is typically done through the use of a pump that can take in or push out water The vehicle s pitch can be controlled by moving the center of mass of the vehicle For Slocum gliders this is done internally by moving the batteries which are mounted on a screw 28 Because of their low speed and low power electronics the energy required to cycle trim states is far less than for regular AUVs and gliders can have endurances of months and transoceanic ranges citation needed Communications edit Since radio waves do not propagate well under water many AUV s incorporate acoustic modems to enable remote command and control These modems typically utilize proprietary communications techniques and modulation schemes In 2017 NATO ratified the ANEP 87 JANUS standard for subsea communications This standard allows for 80 BPS communications links with flexible and extensible message formatting citation needed Alternative communication techniques are being explored including optical inductive and RF based techniques which may be combined in a multi modal solutions 29 Evaluations are also being conducted on novel communication techniques which are able to utilize the infrastructure as a communication path to provide alternative communication paths and opportunities from the vehicles 30 Power edit Most AUVs in use today are powered by rechargeable batteries lithium ion lithium polymer nickel metal hydride etc and are implemented with some form of battery management system Some vehicles use primary batteries which provide perhaps twice the endurance at a substantial extra cost per mission Previously some systems used aluminum based semi fuel cells but these require substantial maintenance require expensive refills and produce waste product that must be handled safely An emerging trend is to combine different battery and power systems with supercapacitors citation needed See also editIntervention AUV Type of autonomous underwater vehicle capable of autonomous interventions Underwater glider Type of autonomous underwater vehicle Bionics Application of natural systems to technology Biomimetics Imitation of biological systems for the solving of human problems Monterey Bay Aquarium Research Institute American oceanographic research institute Office of Naval Research Office within the United States Department of the Navy National Oceanography Centre Southampton Centre for research teaching and technology development in Ocean and Earth sciencePages displaying short descriptions of redirect targets DeepC Autonomous underwater vehicle powered by a fuel cell National Institute for Undersea Science and Technology Research organisation within NOAA AUV 150 Unmanned underwater vehicle in development in by Central Mechanical Engineering Research Institute REMUS AUV Autonomous underwater vehicle seriesPages displaying short descriptions of redirect targets MAYA AUV Autonomous underwater vehicle from National Institute of Oceanography India Torpedo Self propelled underwater weapon Theseus AUV Large autonomous underwater vehicle for laying fibre optic cable Eelume Autonomous underwater vehicle being developed by Eelume ASReferences edit Autonomous Vehicles at the Institute of Marine Technology Problems Archived May 27 2009 at the Wayback Machine Saghafi Mohammad Lavimi Roham 2020 02 01 Optimal design of nose and tail of an autonomous underwater vehicle hull to reduce drag force using numerical simulation Proceedings of the Institution of Mechanical Engineers Part M Journal of Engineering for the Maritime Environment 234 1 76 88 doi 10 1177 1475090219863191 ISSN 1475 0902 S2CID 199578272 Impossible Metals demonstrates its super careful seabed mining robot New Atlas 8 December 2022 Retrieved 17 January 2023 Seaglider Autonomous Underwater Vehicle Dayoub F Dunbabin M Corke P 2015 Robotic detection and tracking of Crown of thorns starfish IEEE RSJ International Conference on Intelligent Robots and Systems IROS doi 10 1109 IROS 2015 7353629 RoboSub Archived from the original on 13 June 2015 Retrieved 25 May 2015 Designspark ChipKIT Challenge this competition is now closed Autonomous Underwater Vehicle Competition Osaka University NAOE Mini Underwater Glider MUG for Education Archived March 13 2011 at the Wayback Machine Robotic Submarine Running Debian Wins International Competition Debian News 2009 10 08 Archived from the original on 28 April 2015 Retrieved 25 May 2015 Kijk magazine 3 2012 full citation needed Sharkey Noel Goodman Marc Ros Nick 2010 The Coming Robot Crime Wave PDF Computer 43 8 116 115 doi 10 1109 MC 2010 242 ISSN 0018 9162 S2CID 29820095 Wired for war The robotics revolution and conflict in the twenty first century by P W Singer 2009 Lichtenwald Terrance G Steinhour Mara H and Perri Frank S 2012 A maritime threat assessment of sea based criminal organizations and terrorist operations Homeland Security Affairs Volume 8 Article 13 Malaysia Airlines World s only three Abyss submarines readied for plane search Telegraph co uk 23 March 2014 Bluefin robot joins search for missing Malaysian plane The Boston Globe BostonGlobe com Retrieved 2017 02 28 Department of the Navy The Navy Unmanned Undersea Vehicle UUV Master Plan 9 Nov 2004 Johns Hopkins APL Technical Digest Volume 32 Number 5 2014 PDF Archived from the original PDF on 2015 09 08 Retrieved 2015 11 18 The Navy is starting to put up real money for robot submarines Los Angeles Times 19 April 2019 Retrieved 20 October 2020 AUV System Timeline Retrieved 25 May 2015 KONGSBERG acquires Hydroid LLC Kongsberg Hydroid 2007 RTsys www rtsys fr rvarcoe 2018 03 27 Unmanned Systems Submergence Group MSubs Retrieved 2023 05 25 LAUV Light Autonomous Underwater Vehicle www oceanscan mst com Retrieved 2017 02 28 AquaJelly Archived 2015 09 24 at the Wayback Machine Festo Corporate 2008 Products R amp D Projects BOSS Manta Ray AUV Overview EvoLogics GMBH Archived from the original on 2018 03 24 Retrieved 2018 03 24 High Efficiency Low Noise Underwater Thruster lianinno com Retrieved 23 January 2023 Slocum Glider www whoi edu Retrieved 23 January 2023 Beatrice Tomasi Marie B Holstad Ingvar Henne Bard Henriksen Pierre Jean Bouvet et al MarTERA UNDINA project a multi modal communication and network aided positioning system for marine robotics and benthic stations 28th annual Underwater Technology Conference UTC 22 Jun 2022 Bergen Norway hal 03779076 Mulholland J J Smolyaninov I I 2022 08 30 Plasmonic Surface Electromagnetic Wave Communication for subsea asset inspection 2022 Sixth Underwater Communications and Networking Conference UComms Lerici Italy IEEE pp 1 5 doi 10 1109 UComms56954 2022 9905693 ISBN 978 1 6654 7461 0 S2CID 252705048 Bibliography edit Technology and Applications of Autonomous Underwater Vehicles Gwyn Griffiths ISBN 978 0 415 30154 1 Review of Autonomous Underwater Vehicle AUV Developments doi 10 5962 bhl title 39207 OCLC 227209412 Masterclass in AUV Technology for Polar Science ISBN 978 0 906940 48 8 The Operation of Autonomous Underwater Vehicles2 ISBN 978 0 906940 40 2 1996 Symposium on Autonomous Underwater Vehicle Technology ISBN 978 0 7803 3185 3 Development of an Autonomous Underwater Vehicle ISBN 978 3 639 09644 6 Optimal Control System for A Semi Autonomous Underwater Vehicle ISBN 978 3 639 24545 5 Autonomous Underwater Vehicles ISBN 978 1 4398 1831 2 Recommended Code of Practice for the Operation of Autonomous Marine Vehicles ISBN 978 0 906940 51 8 Autonomer Mobiler Roboter ISBN 978 1 158 80510 5 Remotely operated underwater vehicle ISBN 978 613 0 30144 6 Underwater Robots ISBN 978 3 540 31752 4 The World AUV Market Report 2010 2019 ISBN 978 1 905183 48 7 Autonomous Underwater Vehicles Design and practice ISBN 978 1 78561 703 4External links edit nbsp Wikimedia Commons has media related to Autonomous underwater vehicles First AUV to cross Atlantic Ocean Displayed at Smithsonian Presentation of the AUV Abyss IFM GEOMAR Kiel The Application of Autonomous Underwater Vehicle AUV Technology in the Oil Industry Vision and Experiences Retrieved from https en wikipedia org w index php title Autonomous underwater vehicle amp oldid 1166524619, wikipedia, wiki, book, books, library,

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