%X Autonomous underwater vehicles (AUVs) are becoming increasingly widespread in today's industrialised world, with research shifting towards cooperative control between multiple vehicles. Cooperative control between AUVs poses a number of challenges such as collision-avoidance, path-planning and group formation. This paper presents a novel 3D technique for the purposes of inspecting underwater structures using autonomous vehicles. Vehicles are navigated using a combination of traditional artificial potential fields (APFs) and rotational potential fields (RPFs) which are employed using 2D sub-planes in a concertina effect to provide full boundary coverage and inspection of submerged architectures. Vehicles are freed from the usual angular constraints associated with group strategies whilst moving in a fluid formation, reducing computational load. Simulation results show the effectiveness of the technique on two different-sized structures, providing varying customised levels of inspection and successful collision-free journeys throughout with minimal path length. © 2017, National Institute of Science Communication and Information Resources (NISCAIR). All rights reserved.
%K autonomous underwater vehicle; collision avoidance; computer simulation; marine technology; numerical model; potential field; three-dimensional modeling; underwater environment
%N 12
%D 2017
%L scholars8087
%J Indian Journal of Geo-Marine Sciences
%O cited By 0
%I National Institute of Science Communication and Policy Research
%V 46
%A D. McIntyre
%A W. Naeem
%A S.S.A. Ali
%T Concertina effect-based underwater structure inspection by autonomous vehicles in three dimensions
%P 2588-2600