Sonar-equipped unmanned surface vehicle for search and rescue operations
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Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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Sammanfattning
Drowning remains a major public safety challenge and accounts for hundreds of
thousands of fatalities globally, with survival rates heavily dependent on rapid
response. Current underwater search and rescue (SAR) methods, including rescue
divers, remotely operated vehicles, and side-scan sonar systems, are often resource
intensive, slow to deploy, or otherwise operationally limited. This thesis investigates
whether a lightweight, rapidly deployable and sonar-equipped unmanned surface
vehicle (USV) can provide a faster and more efficient solution for underwater SAR
operations. Building upon the ongoing Seadragon initiative within the Division of
Vehicle Engineering and Autonomous Systems at Chalmers University of Technology,
a redesigned USV platform (Seadragon 2.0) was developed with improved structural
durability and sensing capability. The prototype integrates a Teledyne BlueViewM900
Mk2 multibeam imaging sonar and an NVIDIA Jetson Orin Nano edge-computer
within a compact catamaran-style hull architecture. To enable automatic underwater
target detection, a custom sonar dataset was collected using recordings of submerged
humans and simulated underwater debris. A two-stage transfer learning pipeline
based on the YOLO26n architecture was trained both on the custom dataset and a
larger public sonar dataset. While maintaining a real-time inference performance of
39.1 FPS on the embedded platform, the resulting model achieved a precision of 0.868,
recall of 0.812, and mAP of 0.859. In addition, the redesigned Seadragon prototype
achieved an estimated theoretical search coverage rate of 244.3 m2/s, exceeding
that of conventional rescue divers and comparable side-scan sonar vessel operations.
Although full-scale field validation was limited by project time constraints, the results
demonstrate the feasibility of the lightweight USV concept for enhancing underwater
SAR operations and, critically, reducing time to rescue.
Beskrivning
Ämne/nyckelord
unmanned surface vehicle (USV), search and rescue (SAR), imaging sonar, underwater target detection, machine learning, autonomous systems, acoustic imaging, human detection, edge computing
