Experimental Study on Performance Improvement of Underwater Acoustic Communication Using a Single Vector Sensor

IF 3.8 2区工程技术 Q1 ENGINEERING, CIVIL

IEEE Journal of Oceanic Engineering Pub Date : 2024-06-03 DOI:10.1109/JOE.2024.3374424

Kang-Hoon Choi;Jee Woong Choi;Sunhyo Kim;Peter H. Dahl;David R. Dall'Osto;Hee Chun Song

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引用次数: 0

Abstract

Underwater acoustic communication is heavily influenced by intersymbol interference caused by the delay spread of multipaths. In this article, communication sequences transmitted from a drifting source were received by a fixed acoustic vector receiver system consisting of an accelerometer-based vector sensor and a pressure sensor, which can measure the three-directional components of vector quantity and pressure at a point. The underwater acoustic communication experiment was conducted in water approximately 30 m deep off the south coast of Geoje Island, South Korea, in May 2017 during the Korea Reverberation Experiment. Acceleration signals received by the vector sensor were converted to pressure-equivalent particle velocities, which were then used as input for a four-channel communication system together with acoustic pressure. These four channels have multipaths with different amplitudes but the same delay times, providing directional diversity that differs from the spatial diversity provided by hydrophone arrays. To improve the communication performance obtained from directional diversity, the Multichannel Combined Bidirectional Block-based Time Reversal Technique was used, which combines bidirectional equalization with time-reversal diversity and block-based time reversal that was robust against time-varying channels. Communication performance was compared with the outcomes produced by several other time reversal techniques. The results show that the Multichannel Combined Bidirectional Block-based Time Reversal Technique using a vector sensor achieved superior performance under the environmental conditions considered in this article.

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利用单矢量传感器提高水下声学通信性能的实验研究

水下声学通信深受多径延迟传播造成的符号间干扰的影响。本文中，由加速度计矢量传感器和压力传感器组成的固定声学矢量接收器系统接收了从漂流源发射的通信序列，该系统可测量矢量的三个方向分量和某一点的压力。水下声学通信实验于 2017 年 5 月韩国混响实验期间在韩国巨济岛南岸约 30 米深的水域进行。矢量传感器接收到的加速度信号被转换为压力当量粒子速度，然后与声压一起用作四通道通信系统的输入。这四个信道具有振幅不同但延迟时间相同的多径，从而提供了不同于水听器阵列所提供的空间分集的方向分集。为了提高定向分集的通信性能，使用了多通道组合双向块基时间反转技术，该技术将双向均衡与时间反转分集和块基时间反转相结合，对时变信道具有鲁棒性。通信性能与其他几种时间反转技术的结果进行了比较。结果表明，在本文考虑的环境条件下，使用矢量传感器的多通道组合双向分块时间反转技术取得了优异的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Journal of Oceanic Engineering 工程技术-工程：大洋

CiteScore

9.60

自引率

12.20%

发文量

审稿时长

12 months

期刊介绍： The IEEE Journal of Oceanic Engineering (ISSN 0364-9059) is the online-only quarterly publication of the IEEE Oceanic Engineering Society (IEEE OES). The scope of the Journal is the field of interest of the IEEE OES, which encompasses all aspects of science, engineering, and technology that address research, development, and operations pertaining to all bodies of water. This includes the creation of new capabilities and technologies from concept design through prototypes, testing, and operational systems to sense, explore, understand, develop, use, and responsibly manage natural resources.