Terrain-Aided Navigation With Coarse Maps—Toward an Arctic Crossing With an AUV
Terrain-Aided Navigation With Coarse Maps—Toward an Arctic Crossing With an AUV
The desire to conduct research in the Arctic on an ever-larger spatiotemporal scale has led to the development of long-range autonomous underwater vehicles (AUVs), such as the Autosub Long-Range 1500 (ALR1500). While these platforms open up a world of new applications, their actual use is limited in GPS-denied environments since self-contained navigation remains yet unavailable. In response, this study evaluates whether terrain-aided navigation (TAN) can enable multimonth deployments using basic navigation sensors and sparse bathymetric maps. To evaluate the potential, ALR1500 undertakes a hypothetical science-driven mission from Svalbard (Norway) to Point Barrow (Alaska, USA) under the sea ice (a mission over 3200 km). Therefore, a simulated environment is developed, which integrates a state-of-the-art model of water circulation, error models for heading estimation at high latitudes, and an Arctic bathymetric map. Recognizing that this map is constructed based on sparse depth measurements and interpolation techniques, a bathymetric uncertainty model is developed. The performance of the TAN algorithm is examined with respect to the type of the heading sensor utilized and a range of vertical map distortions, calculated using the developed bathymetric uncertainty model. Simulations show that unaided navigation experiences an error of hundreds of kilometers, whereas TAN provides acceptable accuracy given a moderate map distortion. By degrading the quality of the map further, it appears that the navigation filter may diverge when traversing large regions subject to interpolation. Therefore, a rapidly-exploring random tree star algorithm is used to design a new path such that the AUV traverses reliable and rich in topographic information areas.
1192-1212
Salavasidis, Georgios
d412a9ad-2659-4e19-9547-fcf0262b0066
Munafò, Andrea
cac7d755-d119-49a3-b99f-ca62778ee9bf
Harris, Catherine A.
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McPhail, Stephen D.
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Fenucci, Davide
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Pebody, Miles
061eafd0-c200-4701-b465-274140a4602b
Rogers, Eric
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Phillips, Alexander
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26 July 2021
Salavasidis, Georgios
d412a9ad-2659-4e19-9547-fcf0262b0066
Munafò, Andrea
cac7d755-d119-49a3-b99f-ca62778ee9bf
Harris, Catherine A.
0ca5433f-ba05-43f5-a0c0-0fcf6e6dedda
McPhail, Stephen D.
58ac4bcd-26a6-4845-8e81-6d6a8f18aed7
Fenucci, Davide
b92d863f-231d-4f00-876a-f575ce966f3e
Pebody, Miles
061eafd0-c200-4701-b465-274140a4602b
Rogers, Eric
611b1de0-c505-472e-a03f-c5294c63bb72
Phillips, Alexander
f565b1da-6881-4e2a-8729-c082b869028f
Salavasidis, Georgios, Munafò, Andrea, Harris, Catherine A., McPhail, Stephen D., Fenucci, Davide, Pebody, Miles, Rogers, Eric and Phillips, Alexander
(2021)
Terrain-Aided Navigation With Coarse Maps—Toward an Arctic Crossing With an AUV.
IEEE Journal of Oceanic Engineering, 46 (4), .
(doi:10.1109/JOE.2021.3085941).
Abstract
The desire to conduct research in the Arctic on an ever-larger spatiotemporal scale has led to the development of long-range autonomous underwater vehicles (AUVs), such as the Autosub Long-Range 1500 (ALR1500). While these platforms open up a world of new applications, their actual use is limited in GPS-denied environments since self-contained navigation remains yet unavailable. In response, this study evaluates whether terrain-aided navigation (TAN) can enable multimonth deployments using basic navigation sensors and sparse bathymetric maps. To evaluate the potential, ALR1500 undertakes a hypothetical science-driven mission from Svalbard (Norway) to Point Barrow (Alaska, USA) under the sea ice (a mission over 3200 km). Therefore, a simulated environment is developed, which integrates a state-of-the-art model of water circulation, error models for heading estimation at high latitudes, and an Arctic bathymetric map. Recognizing that this map is constructed based on sparse depth measurements and interpolation techniques, a bathymetric uncertainty model is developed. The performance of the TAN algorithm is examined with respect to the type of the heading sensor utilized and a range of vertical map distortions, calculated using the developed bathymetric uncertainty model. Simulations show that unaided navigation experiences an error of hundreds of kilometers, whereas TAN provides acceptable accuracy given a moderate map distortion. By degrading the quality of the map further, it appears that the navigation filter may diverge when traversing large regions subject to interpolation. Therefore, a rapidly-exploring random tree star algorithm is used to design a new path such that the AUV traverses reliable and rich in topographic information areas.
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joe
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Published date: 26 July 2021
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Local EPrints ID: 480480
URI: http://eprints.soton.ac.uk/id/eprint/480480
ISSN: 0364-9059
PURE UUID: bb56803f-da5c-4e2d-aeb6-885af0e1180f
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Date deposited: 03 Aug 2023 16:31
Last modified: 17 Mar 2024 03:00
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Author:
Georgios Salavasidis
Author:
Andrea Munafò
Author:
Catherine A. Harris
Author:
Stephen D. McPhail
Author:
Davide Fenucci
Author:
Miles Pebody
Author:
Eric Rogers
Author:
Alexander Phillips
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