A High-Performance and Lightweight Maritime Target Detection Algorithm

• Published in: Remote sensing (Basel, Switzerland) Vol. 17; no. 6; p. 1012
• Main Authors: Sun, Shidan, Xu, Zhiping, Cao, Xiaochun, Zheng, Jiachun, Yang, Jiawen, Jin, Ni
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.03.2025
• Subjects: Accuracy; Algorithms; Cameras; Convolution; convolutional neural network; deformable convolution; Detectors; Edge computing; Efficiency; Feature extraction; Fog; Formability; Localization; Low visibility; maritime target detection; Modules; multi-scale feature fusion; Neural networks; Occlusion; Performance evaluation; Semantics; Surveillance; Target detection
• ISSN: 2072-4292; 2072-4292
• DOI: 10.3390/rs17061012

Maritime surveillance video (MSV) target detection systems are important for maritime security and ocean economy. Hindered by many complex factors, the existing MSV target detection systems have low detection accuracy. These factors include target distance, potential occlusion from rain and fog, and limited computing power of edge devices. To overcome these factors, a high performance and lightweight maritime target detection algorithm (HPMTD) is proposed in this paper. HPMTD consists of three modules: feature extraction, shallow feature progressive fusion (SFPF), and multi-scale sensing head. In the feature extraction module, a global coordinate attention-optimized offset regression module is proposed for deformable convolution. Thus, the ability to handle low visibility and target occlusion issues is enhanced. In the SFPF module, the ghost dynamic convolution combined with low-cost adaptive spatial feature fusion is proposed. In this way, lightweight design can be realized, and multi-scale target-detecting capacity can be increased. Furthermore, multi-scale sensing head is incorporated to learn and fuse scale features more effectively, thus improving localization accuracy. To evaluate the performance of the proposed algorithm, the Singapore Maritime Dataset is adopted in our experiments. The experimental results show that the proposed algorithm can achieve a nearly 10 percent mean average precision value improvement with nearly half the model size, compared with counterparts. Furthermore, the proposed algorithm runs three times faster with only half of the computation resources, and maintains nearly same accuracy in the maritime surface with low visibility. These results demonstrate that the HPMTD achieves lightweight and high-precision detection of marine targets.