Direct acoustic communication between underwater and airborne nodes

The Journal of the Acoustical Society of America Pub Date : 2023-10-01 DOI:10.1121/10.0023622

Shaojian Yang, Yimu Yang, Xingbin Tu, Xuesong Lu, Wei Yan, Fengzhong Qu

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Abstract

Direct acoustic communication between underwater and airborne nodes has always been considered unfeasible due to the energy loss caused by the strong surface reflection of sound waves. However, contrary to popular belief, our study demonstrates that underwater transducers can effectively transmit detectable acoustic signals in the air. To investigate this phenomenon, we conducted an experiment involving the deployment of an underwater transducer at a depth of 1 m, while an unoccupied aerial vehicle equipped with a voice recorder was positioned at various altitudes ranging from 2 to 30 m and horizontal distances of 0–30 m. Sound pressure levels were measured at 20 different positions within the frequency range of 10–20kHz, and orthogonal frequency division multiplex acoustic communication signals were recorded at specific positions. Our findings reveal the successful establishment of a direct acoustic communication link between the water and air interface, achieving a data rate of 4.565 kbps. This study opens up new possibilities for practical applications in underwater-to-air communication systems.

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水下和机载节点之间的直接声学通信

由于声波强烈的表面反射会造成能量损失，水下和空中节点之间的直接声学通信一直被认为是不可行的。然而，与人们普遍认为的相反，我们的研究表明，水下传感器可以有效地在空气中传输可探测到的声学信号。为了研究这一现象，我们进行了一项实验，在 1 米深的水下部署了一个水下换能器，同时在 2 至 30 米的不同高度和 0 至 30 米的水平距离上放置了一个装有语音记录器的无人驾驶飞行器，在 10-20kHz 频率范围内的 20 个不同位置测量了声压级，并在特定位置记录了正交频分复用声学通信信号。我们的研究结果表明，在水和空气界面之间成功建立了直接声学通信链路，数据传输速率达到 4.565 kbps。这项研究为水下-空中通信系统的实际应用提供了新的可能性。

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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The Journal of the Acoustical Society of America

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