基于光学的水下小目标探测技术综述

陈青艳; 吴国俊; 吴亚风; 苗宇宏

doi:10.11993/j.issn.2096-3920.2026-0049

基于光学的水下小目标探测技术综述

doi: 10.11993/j.issn.2096-3920.2026-0049

中国科学院西安光学精密机械研究所海洋光学技术研究室, 陕西西安, 710077

基金项目: 中国科学院重国防科技创新专项重点部署项目资助(KGFZD-145-25-15); 崂山国家实验室自理科技创新项目资助(LSKJ202502201).

详细信息

作者简介:
陈青艳(1995-), 女, 博士, 助理研究员, 主要研究方向为水下图像处理及三维点云识别

通讯作者:
吴亚风(1990-), 男, 硕士, 高级工程师, 主要研究方向为水下光学探测.

中图分类号: TJ630; U754.4
计量
- 文章访问数: 18
- HTML全文浏览量: 9
- PDF下载量: 0
- 被引次数: 0
出版历程
- 收稿日期: 2026-03-06
- 修回日期: 2026-04-15
- 录用日期: 2026-04-20
- 网络出版日期: 2026-05-26

Review of Optical-based Detection Technology for Underwater Small Targets

Shaanxi Key Laboratory of Ocean Optics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an 710119, China

摘要

摘要: 水下小目标(如微型水下航行器、水下探测器装置)的精准探测与识别是海洋资源开发、水下安防预警及水下工程检测等领域的重要内容。受水体衰减、光学散射、声波多径效应及复杂背景噪声等因素的综合制约, 传统探测技术在作用距离、空间分辨率与实时响应性等方面存在显著局限。随着海洋开发向精细化、智能化方向迈进, 以及水下无人装备对抗的战略价值持续凸显, 水下小目标光学探测技术已成为当前海洋信息技术领域的研究热点。文中系统梳理水下小目标光学探测技术的研究背景与战略意义, 重点从基于图像和基于激光雷达(LiDAR)两大技术路径展开全面综述: 在基于图像的技术体系中, 聚焦图像增强与目标检测两大核心环节, 深入剖析各类技术的原理机制、改进策略及性能表现; 在基于LiDAR的技术体系中, 针对面扫描成像、点扫描成像及线扫描成像等探测模式, 系统阐述其技术特性与典型应用场景。文中进一步剖析现有技术面临的瓶颈问题, 并结合海洋技术发展趋势展望未来研究方向, 为水下小目标光学探测技术的工程化落地提供理论支撑。
- 水下小目标 /
- 光学探测 /
- 图像增强 /
- 激光雷达
Abstract: Accurate detection and recognition of underwater small targets (e.g., micro underwater vehicles, underwater detection device etc.) constitute a critical component in the fields of marine resource exploitation, underwater security early warning, and underwater engineering inspection. Constrained by the combined effects of water body attenuation, optical scattering, acoustic multipath effect, and complex background noise, traditional detection technologies exhibit notable limitations in terms of effective detection range, spatial resolution, and real-time responsiveness. With the advancement of marine development toward refinement and intelligence, coupled with the increasingly prominent strategic value of underwater unmanned equipment countermeasures, optical detection technology for underwater small targets has emerged as a research hotspot in the domain of marine information technology. This paper systematically sorts out the research background and strategic significance of optical detection technology for underwater small targets, and presents a comprehensive review focusing on two major technical approaches: image-based and LiDAR-based methods. For the image-based technical system, the study centers on two core modules—image enhancement and target detection—and conducts an in-depth analysis of the principle mechanism, improvement strategies, and performance characteristics of various technologies. For the LiDAR-based technical system, aiming at detection modes including area-scan imaging, point-scan imaging, and line-scan imaging, the paper systematically elaborates on their technical features and typical application scenarios. Furthermore, this paper analyzes the bottleneck problems faced by existing technologies, and prospects future research directions in combination with the development trend of marine technology, so as to provide theoretical support and practical reference for the engineering implementation of optical detection technology for underwater small targets.
- underwater small targets /
- optical detection /
- image enhancement /
- LiDAR

HTML全文

图 1 WaterGAN生成深度图

Figure 1. Depth map generated by WaterGAN

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图 2 UWCNN算法效果

Figure 2. Performance of the UWCNN

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图 3 典型面扫描LiDAR系统

Figure 3. Typical area-scanning LiDAR system

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图 4 水下激光距离选通成像系统

Figure 4. Underwater laser range-gated imaging system

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图 5 典型点扫描LiDAR

Figure 5. Typical point-scanning LiDAR system

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图 6 典型线扫描LiDAR

Figure 6. Typical line-scanning LiDAR system

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图 7 水下线扫描LiDAR样机及海试结果

Figure 7. Prototype of an underwater line-scanning LiDAR and sea trial results

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图 8 自扫描测量设备及示意图

Figure 8. Self-scanning measurement device and schematic diagram

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表 1 不同方法在测试集的定量评估

Table 1. Quantitative Evaluation on the UIEB Dataset

评价指标	RED	UDCP	ODM	UIBLA	UWCNN
MSE	2107.3	5131	3208.6	3012.6	3887.7
PSNR	14.935	11.029	16.085	15.079	18.79
SSIM	0.5965	0.5019	0.5040	0.6957	0.7558

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表 2 典型面扫描LiDAR系统

Table 2. Typical area-scanning LiDAR system

科研单位	分辨率	视场角	帧频
加拿大国防研究所^[55]	8 cm@12 m	10 mrad	30 fps@488×380
美国海军研究所	10 cm@15 m	100×5 mrad	2 kfps@20×1
瑞典国防研究所^[56]	4 mm@3 m	37.5°	0.2 fps@752×582
德国圣路易斯研究所^[57]	cm级@6.5 m	17°×13°	21 fps@680×512
英国赫瑞-瓦特	0.18 mm@3 m	1.89×0.4 mrad	10 fps

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表 3 典型点扫描LiDAR系统

Table 3. Typical point-scanning LiDAR system

科研单位	分辨率	视场角	帧频
英国赫瑞瓦特	1 mm	1.6°	0.05 fps@256×256
日本三菱电机株式会社	20 mm	120°×30°	0.2 fps@1080×214
加拿大Kraken Robotics	2 mm	65°×50°	0.1 fps
美国3D at depth	0.5 mm	30°	0.019 fps@1450×1450
广西测绘激光雷达智能装备中试基地(GQ-23)	约20 cm	—	3 min/万m²

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表 4 典型线扫描LiDAR系统

Table 4. Typical line-scanning LiDAR system

科研单位	分辨率	视场角	帧频
西班牙赫罗纳	3 mm@3 m	35°×35°	70 fps
加拿大Voyis公司	4.1 mm@10 m	50°	90 fps
葡萄牙波尔图大学^[60]	0.8 mm@1 m	45°×35°	10 fps
西安光机所	—	40°	29 fps
中国海洋大学	0.4 mm@0.4 m	40°	10 fps

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