Docking and Persistent Operations for a Resident Underwater Vehicle

TL;DR

This paper presents a resilient, autonomous underwater ROV system with docking capabilities at 90m depth, enabling persistent, cost-effective ocean monitoring through integrated acoustic and visual navigation.

Contribution

It introduces a novel resident ROV system with autonomous docking and inspection routines, demonstrating high success rates and real-world operational feasibility.

Findings

90% autonomous docking success rate

Completed inspection missions within four minutes

Validated integrated acoustic and visual navigation at depth

Abstract

Our understanding of the oceans remains limited by sparse and infrequent observations, primarily because current methods are constrained by the high cost and logistical effort of underwater monitoring, relying either on sporadic surveys across broad areas or on long-term measurements at fixed locations. To overcome these limitations, monitoring systems must enable persistent and autonomous operations without the need for continuous surface support. Despite recent advances, resident underwater vehicles remain uncommon due to persistent challenges in autonomy, robotic resilience, and mechanical robustness, particularly under long-term deployment in harsh and remote environments. This work addresses these problems by presenting the development, deployment, and operation of a resident infrastructure using a docking station with a mini-class Remotely Operated Vehicle (ROV) at 90 m depth. The ROV is equipped with enhanced onboard processing and perception, allowing it to autonomously navigate using USBL signals, dock via ArUco marker-based visual localisation fused through an Extended Kalman Filter, and carry out local inspection routines. The system demonstrated a 90 % autonomous docking success rate and completed full inspection missions within four minutes, validating the integration of acoustic and visual navigation in real-world conditions. These results show that reliable, untethered operations at depth are feasible, highlighting the potential of resident ROV systems for scalable, cost-effective underwater monitoring.