Wake-informed 3D path planning for autonomous underwater vehicles using A* and neural network approximations
Wake-informed 3D path planning for autonomous underwater vehicles using A* and neural network approximations
Autonomous Underwater Vehicles (AUVs) encounter significant energy, control and navigation challenges in complex underwater environments, particularly during close-proximity operations, such as launch and recovery (LAR), where fluid interactions and wake effects present additional navigational and energy challenges. Traditional path planning methods fail to incorporate these detailed wake structures, resulting in increased energy consumption, reduced control stability, and heightened safety risks. This paper presents a novel wake-informed, 3D path planning approach that fully integrates localized wake effects and global currents into the planning algorithm. Two variants of the A* algorithm – a current-informed planner and a wake-informed planner – are created to assess its validity and two separate neural network models are then trained, each designed to approximate one of the A*planner variants (current-informed and wake-informed respectively), enabling potential real time-application. Both the A* planners and NN models are evaluated using important metrics such as energy expenditure, path length, and encounters with high-velocity and turbulent regions. The results demonstrate a wake-informed A* planner consistently achieves the lowest energy expenditure and minimizes encounters with high-velocity regions, reducing energy consumption by up to 11.3%. The neural network models are observed to offer computational speedup of 6 orders of magnitude, but exhibit 4.51–19.79% higher energy expenditures and 9.81–24.38% less optimal paths. These findings underscore the importance of incorporating detailed wake structures into traditional path planning algorithms and the benefits of neural network approximations to enhance energy efficiency and operational safety for AUVs in complex 3D domains.
Path Planning, Hydrodynamics, Autonomous Underwater Vehicles, Optimization, Machine Learning
Cooper-Baldock, Zachary
47d91937-7989-4bfa-9e1a-903b1e7b3031
Turnock, Stephen R.
d6442f5c-d9af-4fdb-8406-7c79a92b26ce
Summut, Karl
579d7c43-7fc6-46dc-91e5-268f72034698
Cooper-Baldock, Zachary
47d91937-7989-4bfa-9e1a-903b1e7b3031
Turnock, Stephen R.
d6442f5c-d9af-4fdb-8406-7c79a92b26ce
Summut, Karl
579d7c43-7fc6-46dc-91e5-268f72034698
Cooper-Baldock, Zachary, Turnock, Stephen R. and Summut, Karl
(2025)
Wake-informed 3D path planning for autonomous underwater vehicles using A* and neural network approximations.
Ocean Engineering.
(In Press)
Abstract
Autonomous Underwater Vehicles (AUVs) encounter significant energy, control and navigation challenges in complex underwater environments, particularly during close-proximity operations, such as launch and recovery (LAR), where fluid interactions and wake effects present additional navigational and energy challenges. Traditional path planning methods fail to incorporate these detailed wake structures, resulting in increased energy consumption, reduced control stability, and heightened safety risks. This paper presents a novel wake-informed, 3D path planning approach that fully integrates localized wake effects and global currents into the planning algorithm. Two variants of the A* algorithm – a current-informed planner and a wake-informed planner – are created to assess its validity and two separate neural network models are then trained, each designed to approximate one of the A*planner variants (current-informed and wake-informed respectively), enabling potential real time-application. Both the A* planners and NN models are evaluated using important metrics such as energy expenditure, path length, and encounters with high-velocity and turbulent regions. The results demonstrate a wake-informed A* planner consistently achieves the lowest energy expenditure and minimizes encounters with high-velocity regions, reducing energy consumption by up to 11.3%. The neural network models are observed to offer computational speedup of 6 orders of magnitude, but exhibit 4.51–19.79% higher energy expenditures and 9.81–24.38% less optimal paths. These findings underscore the importance of incorporating detailed wake structures into traditional path planning algorithms and the benefits of neural network approximations to enhance energy efficiency and operational safety for AUVs in complex 3D domains.
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Accepted/In Press date: 22 April 2025
Keywords:
Path Planning, Hydrodynamics, Autonomous Underwater Vehicles, Optimization, Machine Learning
Identifiers
Local EPrints ID: 501867
URI: http://eprints.soton.ac.uk/id/eprint/501867
ISSN: 0029-8018
PURE UUID: 345a39ba-2502-4d0c-a813-56a0cdebd232
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Date deposited: 11 Jun 2025 16:49
Last modified: 12 Jun 2025 01:33
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Contributors
Author:
Zachary Cooper-Baldock
Author:
Karl Summut
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