Research on Passive Positioning Algorithm for AUVs Based on Single Mobile Surface Beacon and Inverted USBL

IF 8.9 1区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS IEEE Internet of Things Journal Pub Date : 2025-02-18 DOI:10.1109/JIOT.2025.3542445

Guolin Wang;Shuibo Hu;Mengzhuo Liu;Zheng Peng;Jun-Hong Cui

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Abstract

Single beacon passive positioning is crucial for the covert and rapid navigation of autonomous underwater vehicles (AUVs). Traditional methods, which assume a fixed beacon position, known sound speed, and error-free AUV heading, limit the applicability and accuracy of passive positioning systems. In this article, we proposed an angle-based passive positioning algorithm, underwater moving bearing angle of arrival (U-MBAOA), to solve the above problems. First, we replace the bottom-anchored fixed beacon with a mobile surface beacon and develop a dynamic positioning model to accommodate its movement. Then, to enhance the positioning accuracy, we parameterized the sound speed and derived a weighted least squares method to estimate the sound speed. Finally, we constructed an error model for heading errors and positioning under a straight-line trajectory and combined this model with U-MBAOA, achieving the estimation of heading errors in passive positioning for the first time. Through simulation analysis and sea tests, we confirmed that our algorithms outperform the existing algorithms.

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基于单移动水面信标和反向USBL的水下机器人被动定位算法研究

单信标无源定位是自主水下航行器隐蔽、快速导航的关键。传统的定位方法假定信标位置固定、声速已知、AUV航向无误差，限制了无源定位系统的适用性和精度。针对上述问题，本文提出了一种基于角度的水下移动方位到达角（U-MBAOA）被动定位算法。首先，我们将底部锚定的固定信标替换为移动的水面信标，并开发动态定位模型以适应其移动。然后，为了提高定位精度，我们将声速参数化，并推导出加权最小二乘法来估计声速。最后，构建了直线轨迹下的航向误差与定位误差模型，并将该模型与U-MBAOA相结合，首次实现了被动定位航向误差的估计。通过仿真分析和海上试验，我们证实了我们的算法优于现有算法。

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来源期刊

IEEE Internet of Things Journal Computer Science-Information Systems

CiteScore

17.60

自引率

13.20%

发文量

1982

期刊介绍： The EEE Internet of Things (IoT) Journal publishes articles and review articles covering various aspects of IoT, including IoT system architecture, IoT enabling technologies, IoT communication and networking protocols such as network coding, and IoT services and applications. Topics encompass IoT's impacts on sensor technologies, big data management, and future internet design for applications like smart cities and smart homes. Fields of interest include IoT architecture such as things-centric, data-centric, service-oriented IoT architecture; IoT enabling technologies and systematic integration such as sensor technologies, big sensor data management, and future Internet design for IoT; IoT services, applications, and test-beds such as IoT service middleware, IoT application programming interface (API), IoT application design, and IoT trials/experiments; IoT standardization activities and technology development in different standard development organizations (SDO) such as IEEE, IETF, ITU, 3GPP, ETSI, etc.