消磁站水下磁传感器定位方法研究

doi:10.19595/j.cnki.1000-6753.tces.222079

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摘要采用消磁站海底平面磁传感器阵列进行测量是获取舰艇磁场的主要途径,水下磁传感器位置误差是影响舰艇磁场测量的主要因素。针对该问题,将磁场与深度测量数据相融合,提出一种基于磁场梯度优化的消磁站水下磁传感器定位方法。将通电螺线管线圈等效成磁偶极子,通过磁传感器位置偏差区域x和y方向的平均磁场梯度优化确定线圈的两组磁源移动位置,结合深度测量数据分别建立方程组构造目标函数,并采用动态学习策略多群体粒子群算法进行优化求解,从而实现消磁站水下磁传感器的高精度定位。在系统分析和评估深度传感器精度和环境磁噪声等影响规律的基础上,开展位置校正数值模拟和物理缩比模型实验。实验结果表明：该方法可有效解决消磁站水下磁传感器的定位问题,定位误差小于0.1m,满足舰艇磁场测量要求。

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关键词 ：磁场梯度, 定位, 水下磁传感器, 深度传感器

Abstract：At present, the main way to measure ship's magnetic field is by the magnetic sensor array installed on the submarine plane of the fixed deperming station. The installation of underwater magnetic sensor is particularly difficult due to the complex and changeable submarine environment. There is a certain position deviation bet-ween the installation position of the underwater magnetic sensor and the preset position in actual engineering, which is the main factor affecting the magnetic field measurement of the ship. In addition, with the continuous development of magnetic mines and airborne magnetic prospecting, the requirements for the magnetic protection capability of ships are becoming increasingly strict. To solve this problem, combining magnetic field and depth measurement data,a localization method for underwater magnetic sensors based on optimization of magnetic field gradient has been proposed.
Firstly, the pier is meshed with a suitable grid spacing l. Secondly, the energized solenoid coil is equivalent to a magnetic dipole. When the magnetic dipole is located at each grid node, the average magnetic field gradients in the x-axis and y-axis directions of the region 60×60×60cm centered on the sensor is calculated respectively, Simultaneously, the coil coordinates are recorded. Then the average gradients of magnetic field in the three directions are sorted from large to small respectively. Thirdly, the magnetic source is moved on the grid nodes corresponding to the first k average magnetic field gradients in the x-axis and y-axis directions respectively, and underwater magnetic sensors measure the magnetic field of the magnetic source. Fourthly, the magnetic source data measured in the x-axis and y-axis directions and the depth data are respectively used to construct the objective function. A novel multi-swarm particle swarm optimization with dynamic learning strategy is used to obtain x-axis and y-axis components of the position deviation. In the locating model, the moving positions of the magnetic source are determined by optimization of the average magnetic field gradients in the x-axis and y-axis directions, which greatly improves the localization accuracy of the magnetic sensors in the x-axis and y-axis directions. In addition, the depth of the magnetic sensor is measured by the depth sensor, which avoids the imprecise solution of z-axis components.
In this paper, the effectiveness of this method is proved by numerical simulation experiments and physical scale model experiments under the size of typical degaussing stations, and the following main conclusions are drawn as follows: (1) The relationship between the position correction error and the number of moving positions k of magnetic source is studied quantitatively. The research shows that when the number of moving positions k of magnetic source reaches 12 times under the grid spacing of 2m, the position correction error no longer decreases with the increase of k, and basically reaches the saturation state. (2) Through numerical simulation experiments, the influence of environmental magnetic noises, accuracy of the depth sensor and other factors on the localization of underwater magnetic sensor is systematically analyzed, and the environmental noise brings the greatest influence. The numerical localization experiment of underwater magnetic sensor in different position deviation states was carried out. After correction, the mean value of the average error of sensors was 0.023 m, the mean value of the maximum error was 0.056 m, and the mean value of the variance was 2.26×10-4 m², that met the requirement for magnetic field measurement of ships in degaussing station. (3) The physical scale model experiment of the fixed deperming station is designed. The experimental results show that the average error of the sensor is 5 mm, and its amplification is 0.043 m according to the scale (1:8.5), which is basically consistent with the results of the numerical simulation experiment, and verifies the effectiveness and accuracy of the proposed method.

Key words： magnetic field gradients localization underwater magnetic sensor depth sensor

收稿日期: 2022-11-03

PACS:

P229

基金资助:国家自然科学基金资助项目(51377165)

通讯作者: 周国华男,1983年生,副教授,硕士生导师,研究方向为电磁场数值计算,电磁环境与防护技术,舰艇磁场模型等。E-mail：dandanqibing@126.com

作者简介: 王玉芬男,1997年生,硕士研究生,研究方向电磁环境与防护技术,电磁定位技术。E-mail：18370469195@qq.com

引用本文:

王玉芬, 周国华, 吴轲娜, 李林锋. 消磁站水下磁传感器定位方法研究[J]. 电工技术学报, 0, (): 119-119. Wang Yufen, Zhou Guohua, Wu Kena, Li Linfeng. Research on Localization Method for Underwater Magnetic Sensors in the Fixed Deperming Station. Transactions of China Electrotechnical Society, 0, (): 119-119.

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[1] 王锴松, 周国华, 刘月林, 王玉芬, 刘胜道. 地磁模拟法测量舰船感应磁场的数值模拟[J]. 兵工学报, 2022, 43(3): 617-625.
Wang Kaisong, Zhou Guohua, Liu Yuelin,, et al.Numerical simulation of measuring ship's induced magnetic field by geomagnetic field simulation method[J]. Acta Armamentarii, 2022, 43(3): 617-625.
[2] 曹恒佩, 艾萌萌, 王延波. 永磁辅助同步磁阻电机研究现状及发展趋势[J]. 电工技术学报, 2022, 37(18): 4575-4592.
Cao Hengpei, Ai Mengmeng and Wang Yanbo. Research Status and Development Trend of Permanent Magnet Assisted Synchronous Reluctance Motor[J]. Transactions of China Electrotechnical Society, 2022, 37(18): 4575-4592.
[3] 刘琪,孙兆龙,姜润翔,等. 一种舰船下方磁场的信号重构及换算方法[J]. 电工技术学报, 2012, 37(15):3723-3732.
Liu Qi, Sun Zhaolong, Jiang Runxiang, et al.A Signal Reconstruction and Conversion Method of Magnetic Field under Ship[J]. Transactions of China Electrotechnical Society, 2012, 37(15):3723-3732.
[4] Maurice Hott, Andrej Harlakin and Peter A. Hoeher. Hybrid communication and localization underwater network nodes based on magnetic induction and visible light for AUV support[C]//2020 International Conference on Information and Communication Technology Convergence (ICTC). Jeju, Korea (South): IEEE,2020:66-68.
Maurice Hott, Andrej Harlakin and Peter A. Hoeher.
[5] Jonas Callmer, Martin Skoglund,Fredrik Gustafsson.Silent localization of underwater sensors using magnetometers[J]. Eurasip Journal on Advances in Signal Processing, 2010, 2010(1):709318.
[6] 张朝阳, 肖昌汉. 海底布放磁传感器的磁定位方法的模拟实验研究[J]. 上海交通大学学报(自然版), 2011, 45(06): 826-830.
Zhang Chaoyang, Xiao Changhan.Simulation experiment research for magnetic localization method for magnetometer sensor at seabed. J. Shanghai Jiaotong Univ. (Sci.), 2011, 45(006):826-830.
[7] 杨明明, 刘大明, 连丽婷, 等. 用海面磁偶极子源定位海底矢量磁传感器[J]. 探测与控制学报, 2011, 33(5): 41-45.
Yang Mingming, Liu Daming, Lisn Liting, et al.Underwater vector-magnetometer located by using magnetic dipole sources in the offing[J]. Journal of Detection & Control, 2011, 33(5): 41-45.
[8] 孙晔,肖昌汉,周国华. 磁主动式海底磁传感器定位方法及其解析公式[J]. 海洋测绘, 2012, 32(4): 25-32.
Sun Ye, Xiao Changhan, Zhou Guohua, An active method and its analytical formulas of magnetic sensor positioning using the magnetic source[J]. Hydrographic Surveying & Charting, 2012, 32(4): 25-32.
[9] 周国华,张树,赵文春等. 低速运动条件下的磁传感器定位方法[J]. 船电技术, 2016, 36(9):1-5.
Zhou Guohua, Zhang Shu, Zhao Wenchun, et al.Magnetic sensor positioning method under low speed movement condition[J]. Marine Electric & Electronic Engineering, 2016,36(9):1-5.
[10] Zhou Yu, Xiao Changhan, Zhou Guo.Multi-objectivization-based localization of underwater sensors using magnetometers[J]. IEEE Sensors Journal,2014, 14(4):1099-1106.
[11] 王泽忠, 金玉生, 卢斌先. 工程电磁场[M]. 北京: 清华大学出版社, 2011.
[12] 张朝阳, 虞伟乔. 基于磁偶极子等效的潜艇空间磁场分布[J]. 舰船科学技术, 2013, 35(1):31-34.
Zhang Chaoyang, Yu Weiqiao.Research on spatial magnetic field distributing of submarine based on magnetic dipole equivalent[J]. Ship science and Technology, 2013, 35(1):31-34.
[13] 刘芙妍, 颜冰. 磁偶极子阵列模型的适用性研究与优化分析[J]. 物理学报, 2022, 71(12): 124101.
Liu Fuyan, Yan Bing.Applicability and optimization analysis of magnetic dipole array model[J]. Acta Phys. Sin., 2022, 71(12): 124101.
[14] 李岩松,刘启智,刘军,唐晓骏. 基于磁偶极子模型的材料缺陷漏磁检测正演问题的单元积分计算方法[J]. 电工技术学报, 2017,32(21) :176-185.
Li Yansong, Liu Qizhi, Liu Jun, Tang Xiaojun.The Unit Integral Calculation Method of Defective Material’s Forward Question of Magnetic Flux Leakage Detection Based on the Magnetic Dipole Model[J]. Transactions of China Electrotechnical Society, 2017, 32(21):176-185.
[15] 丁璨, 李江, 袁召, 等. NSGA-II和BP神经网络的杯状纵磁触头结构优化设计[J]. 电工技术学报, 2022, 37(23): 6074-6082.
Ding Can, Li Jiang, Yuan Zhao, et al.Structural Optimization Design of Cup-Shaped Longitudinal Magnetic Contact Based on NSGA-II and BP Neural Network[J]. Transactions of China Electrotechnical Society, 2022, 37(23): 6074-6082.
[16] 李婕, 杨淑英, 谢震, 等. 基于有效信息迭代快速粒子群优化算法的永磁同步电机参数在线辨识[J]. 电工技术学报, 2022, 37(18):4605-4613.
Li Jie, Yang Shu Ying, Xie Zhen, et al.Online Parameter Identification of Permanent Magnet Synchronous Motor Based on Fast Particle Swarm Optimization Algorithm with Effective Information Iterated[J]. Transactions of China Electrotechnical Society, 2022, 37(18):4605-4613.
[17] Ye Wenxing, Feng Weiying, Fan Suohai.A novel multi-swarm particle swarm optimization with dynamic learning strategy[J]. Applied Soft Computing, 2017, 61:832-843