Development and testing of an unmanned surface towing system for autonomous transport of multiple heterogeneous underwater vehicles for seafloor survey
Development and testing of an unmanned surface towing system for autonomous transport of multiple heterogeneous underwater vehicles for seafloor survey
Simultaneous operation of multiple autonomous underwater vehicles (AUVs) can increase seafloor mapping efficiency. However, AUVs typically rely on support vessels with an operations crew for transport to sites of interest and supervision during their dives. This is costly and limits the scalability of AUV-based seafloor mapping. This paper describes a robotic system that can transport AUVs from shore and deploy them in a survey area located offshore, without the need for a crewed support vessel. We clarify the functional requirements for ship-free AUV operations and propose a concept that allows a single autonomous surface vehicle (ASV) to transport, release, and monitor multiple large and heterogeneous AUVs. The proposed system uses towing modules that can be connected in parallel and can accommodate a variety of pre-existing ASVs and AUVs. A full-scale system was developed and tested during sea trials in the Mediterranean Sea off Greece, to verify basic functionality and gather data on the impact of towing multiple AUVs on ASV endurance and range. Results of these trials and lessons learned are discussed.
Autonomous surface vehicle (ASV), Autonomous underwater vehicle (AUV), Robotic launching system, Seafloor survey, Ship-free operation
61-71
Ohki, Takeshi
6d824584-3963-48c0-8521-ce3dfc51af18
Kakami, Hitoshi
281b26c1-9b8c-4cc0-98b6-fe302f388473
Nishida, Yuya
3128a94d-c57f-4933-8433-d2c57e3bd1ca
Nakatani, Takeshi
dc8f7f62-f81e-487b-8a6d-e1a2fb83a810
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
2020
Ohki, Takeshi
6d824584-3963-48c0-8521-ce3dfc51af18
Kakami, Hitoshi
281b26c1-9b8c-4cc0-98b6-fe302f388473
Nishida, Yuya
3128a94d-c57f-4933-8433-d2c57e3bd1ca
Nakatani, Takeshi
dc8f7f62-f81e-487b-8a6d-e1a2fb83a810
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
Ohki, Takeshi, Kakami, Hitoshi, Nishida, Yuya, Nakatani, Takeshi and Thornton, Blair
(2020)
Development and testing of an unmanned surface towing system for autonomous transport of multiple heterogeneous underwater vehicles for seafloor survey.
Marine Technology Society Journal, 54 (5), .
(doi:10.4031/MTSJ.54.5.10).
Abstract
Simultaneous operation of multiple autonomous underwater vehicles (AUVs) can increase seafloor mapping efficiency. However, AUVs typically rely on support vessels with an operations crew for transport to sites of interest and supervision during their dives. This is costly and limits the scalability of AUV-based seafloor mapping. This paper describes a robotic system that can transport AUVs from shore and deploy them in a survey area located offshore, without the need for a crewed support vessel. We clarify the functional requirements for ship-free AUV operations and propose a concept that allows a single autonomous surface vehicle (ASV) to transport, release, and monitor multiple large and heterogeneous AUVs. The proposed system uses towing modules that can be connected in parallel and can accommodate a variety of pre-existing ASVs and AUVs. A full-scale system was developed and tested during sea trials in the Mediterranean Sea off Greece, to verify basic functionality and gather data on the impact of towing multiple AUVs on ASV endurance and range. Results of these trials and lessons learned are discussed.
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Accepted/In Press date: 3 September 2020
Published date: 2020
Keywords:
Autonomous surface vehicle (ASV), Autonomous underwater vehicle (AUV), Robotic launching system, Seafloor survey, Ship-free operation
Identifiers
Local EPrints ID: 444386
URI: http://eprints.soton.ac.uk/id/eprint/444386
ISSN: 0025-3324
PURE UUID: 7925f956-a887-492b-a72b-e1595a41ffb4
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Date deposited: 16 Oct 2020 16:30
Last modified: 17 Mar 2024 12:41
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Contributors
Author:
Takeshi Ohki
Author:
Hitoshi Kakami
Author:
Yuya Nishida
Author:
Takeshi Nakatani
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