A Lightweight Forward-Looking Sonar Sensing Framework for Embedded Target Detection in Resource-Constrained Underwater Systems
Sensors
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- Date Published
- 15 May 2026
- Priority Score
- 1
- Australian
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- Created
- 15 May 2026, 12:00 pm
Description
Sensors, an international, peer-reviewed Open Access journal.
Summary
This research details advancements in lightweight computer vision frameworks designed for autonomous underwater vehicles (AUVs) utilizing Forward-Looking Sonar (FLS). By integrating FPN-Mix architectures and knowledge distillation, the authors demonstrate significant improvements in target detection efficiency on resource-constrained embedded platforms like the NVIDIA Jetson Orin NX. While primarily focused on maritime robotics and aquaculture, the optimization of autonomous sensing in austere environments has dual-use implications for the reliability and deployment of autonomous systems in strategic domains. The paper contributes to the technical understanding of maintaining model performance under hardware constraints, a key challenge in ensuring the safety and predictability of frontier autonomous robotics.
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25 pages, 88822 KB
Open AccessArticle
A Lightweight Forward-Looking Sonar Sensing Framework for Embedded Target Detection in Resource-Constrained Underwater Systems
by
Hong Peng, Chaolin Yang, Chen He, Wei Ye and Renyou Yang
Sensors 2026, 26(10), 3133; https://doi.org/10.3390/s26103133 (registering DOI) - 15 May 2026
Abstract
Forward-looking sonar (FLS) is an important sensing modality for autonomous underwater vehicles and other marine robotic systems operating in turbid, low-visibility, and acoustically cluttered environments. Reliable target detection in FLS imagery remains challenging because target echoes are often weak, compact targets can be
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Forward-looking sonar (FLS) is an important sensing modality for autonomous underwater vehicles and other marine robotic systems operating in turbid, low-visibility, and acoustically cluttered environments. Reliable target detection in FLS imagery remains challenging because target echoes are often weak, compact targets can be obscured by background clutter, and embedded processors impose strict limits on model size, latency, and computation. To address these issues, this study presents a lightweight FLS sensing framework for embedded target detection in resource-constrained underwater systems. The framework combines a compact detection architecture, difficulty-aware supervision, and teacher–student knowledge transfer. Specifically, FPN-Mix is developed as a lightweight backbone with a Conv-Mix module to improve contextual aggregation under limited computational budgets. A target-aware dynamic weighting loss is introduced to increase the supervision weight of difficult acoustic samples associated with weak echoes, ambiguous boundaries, and clutter interference. A multi-level knowledge distillation strategy is then adopted to transfer feature-level and prediction-level knowledge from an enhanced teacher model to the compact student detector. Experiments on the public UATD benchmark and the independently collected Zhanjiang Bay No.1 field dataset show that the proposed method achieves a favorable balance between detection accuracy and efficiency and remains competitive in a real marine aquaculture environment. The proposed model contains only 2.83 M parameters and requires 6.68 GFLOPs. After ONNX export and TensorRT FP16 acceleration, the model reaches 72.23 frames per second (FPS) on an NVIDIA Jetson Orin NX platform, supporting its practical use in embedded FLS sensing systems.
Full article
(This article belongs to the Section Radar Sensors)
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