Effect of Underwater Ambient Noise on Quadraphase Phase-shift Keying Acoustic Sensor Network Links in Extremely Low Frequency Band

International journal of engineering. Transactions A: basics Pub Date : 2017-06-22 DOI:10.5829/ije.2017.30.07a.07

N. Bahrami, N. H. Khamis, A. Yahya, A. Baharom

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引用次数: 1

Abstract

This study evaluates the impact of underwater ambient noise using seven real noise samples; Dolphin, Rain, Ferry, Sonar, Bubbles, Lightning, and Outboard Motor in three frequency ranges in extremely low frequency (ELF) band. The ELF band is the most significant bandwidth for underwater long-range communication. ELF band which is extended from 3 to 3000 Hz clearly, faces bandwidth limitation. Measuring the impact of noises that are imposed on this bandwidth, based on center frequency employment is highly regarded. This measurement optimizes detection process and assists the design of more reliable underwater communication systems and will improve network quality of service (QoS). In this investigation, Quadraphase Phase-shift Keying (QPSK) acoustic communication nodes are designed in MATLAB and real noise samples are added to network link. Three frequency bands are defined (0-1600), (400-2000) and (1600-3200) Hz, then the impact of noise samples on phase is measured. Next, ( ) ratio for every bandwidth (BW) is simulated. The result demonstrates 0 to 1600 Hz band is the nosiest part of the ELF band. This study discovered the Bubble noise sample from the environmental noise; Ferry from man-made noise and the Dolphin in mammal’s noise have the greatest impact on 0 to 1600 Hz bandwidth.

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水下环境噪声对极低频四相移相键控声传感器网络链路的影响

本文利用7个真实噪声样本对水下环境噪声的影响进行了评价;海豚、雨、渡轮、声纳、气泡、闪电和舷外马达在极低频(ELF)波段的三个频率范围内。极低频波段是水下远程通信最重要的带宽。ELF频段明显从3 Hz扩展到3000 Hz，面临带宽限制。基于中心频率的使用，测量施加在该带宽上的噪声的影响受到高度重视。这种测量优化了探测过程，有助于设计更可靠的水下通信系统，并将提高网络服务质量(QoS)。本研究在MATLAB中设计了四相移相键控(QPSK)声学通信节点，并在网络链路中加入了真实噪声样本。定义了3个频段(0-1600)、(400-2000)和(1600-3200)Hz，然后测量了噪声样本对相位的影响。然后，模拟每个带宽(BW)的()比率。结果表明，0 ~ 1600 Hz波段是极低频波段中噪声最大的部分。本研究从环境噪声中发现气泡噪声样本;来自渡轮的人为噪音和海豚类哺乳动物的噪音对0 ~ 1600赫兹带宽的影响最大。

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

International journal of engineering. Transactions A: basics

CiteScore

3.10

自引率

0.00%

发文量