利用离子电流波通过海水进行兆赫频率和中距离(0-30米)的信号传输

IF 0.4 Q4 Engineering

UNDERWATER TECHNOLOGY Pub Date : 2019-11-27 DOI:10.3723/ut.36.053

J. Lucas

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引用次数: 0

摘要

电磁(EM)信号只能通过海水传输短距离(1兆赫)。因此，离子电流波(ICW)作为一种新的信号传播技术被开发出来。这项技术利用海水中产生的传导电流，这是热电离释放H+和OH -离子的结果。在浸入海水中的两个金属电极之间施加一个小电压(<1.5 V pk)，以避免输入电能电离。对ICW过程的详细理论分析表明，离子电流可以在兆赫频率下传输10米的距离，每十年的信号损失很低。对于100米的长距离传播，理论预测每10年的信号损失为-20 dB。在利物浦码头的海水中，在2米深的海水中垂直放置平行的0.5 m × 0.3 m电极，在2米至28米的距离上进行了传播实验。研究了1 MHz - 8 MHz范围内的信号频率。在每个实验中，接收到的传播信号功率约为-67 dBm(远高于-140 dBm的船坞电噪声)，并且在整个传播范围内仅显示出很小的功率损失。ICW系统将能够在适合舰船和潜艇通信的深海条件下测量更长的传播距离。其性能可与声纳系统相媲美。

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Signal transmission through seawater for MHz frequencies and medium distances (0–30 m) using ionic current waves

Electromagnetic (EM) signals can only be transmitted through seawater for short distances (<1 m) for frequencies (>1 MHz). Therefore a new technique, the ionic current wave (ICW), has been developed for signal propagation at MHz frequency. This technique uses the conduction current produced in seawater as a result of thermal ionisation releasing H+ and OH– ions. A small voltage (<1.5 V pk) is applied between two metal electrodes submerged in the seawater to avoid ionisation by the input electrical energy. A detailed theoretical analysis of the ICW process has shown that ionic currents can be transmitted at MHz frequency over distances of 10 m with low signal loss per decade. For longer propagation distances of 100 m the theory predicts a signal loss of –20 dB per decade. Propagation experiments have been carried out in Liverpool dock seawater for distances of 2 m–28 m between parallel 0.5 m × 0.3 m electrodes placed vertically in the seawater at a depth of 2 m. Signal frequencies within the range of 1 MHz–8 MHz have been investigated. In each experiment the received propa gated signal power was approximately –67 dBm (well above the dock electrical noise of –140 dBm) and only showed a small power loss over the full range of propagation. The ICW system will be able to measure longer propagation distances in deep seawater conditions suitable for ship and submarine communications. Its performance is comparable to that of sonar systems.

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来源期刊

UNDERWATER TECHNOLOGY ENGINEERING, OCEAN-

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