Underwater Channel Characterization for Effective Communication Link

2020 3rd International Conference on Computing, Mathematics and Engineering Technologies (iCoMET) Pub Date : 2020-01-01 DOI:10.1109/iCoMET48670.2020.9074122

Hammad Shaikh, M. Nadeem, Muhammad Yasir Zaheen, A. Khan, Muhammad Rauf

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引用次数: 2

Abstract

Generating effective communication links in an offshore environment is a vital need for the oil and gas industry as well as the military domain. The highly conductive medium of the environment is yet the biggest hurdle to develop the channel. Focusing towards the challenges lies in underwater communication channel, this paper first presents an efficient transmitter and receiver design using the conduction current method. Subsequent to the design development, a comparative analysis is presented that can be used to model an optimum underwater communication channel through electromagnetic conduction. Effect of different channel characterization parameters is discussed such as conductivity, frequency and transmitter and receiver antenna separation. Through an efficient circuit design for transmitter and receiver, increasing frequencies increased the signal strength is proved. Further statistical analysis revealed that in the developed experimental setup, 100 kHz has a greater possibility in designing an efficient demodulation circuit design. The promising results have proved the possibilities in way forward for the technology.

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水下信道特性的有效通信链路

在海上环境中建立有效的通信链路是石油和天然气行业以及军事领域的重要需求。环境的高导电性介质仍然是开发该通道的最大障碍。针对水下通信信道面临的挑战，本文首先提出了一种基于传导电流法的高效发射接收机设计方案。在设计开发之后，通过对比分析，提出了一种可用于通过电磁传导建立最佳水下通信信道的模型。讨论了不同信道特性参数如电导率、频率、收发天线间距等的影响。通过对发射机和接收机进行有效的电路设计，证明了增加频率可以提高信号强度。进一步的统计分析表明，在开发的实验装置中，100 kHz具有更大的可能性设计出有效的解调电路设计。这些有希望的结果证明了这项技术未来的可能性。

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

2020 3rd International Conference on Computing, Mathematics and Engineering Technologies (iCoMET)

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