S. Hurst, Xinyu Xie, Shwan Ashrafi, Sumit Roy, P. Arabshahi
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引用次数: 3
摘要
水下通信是一些下一代工程和科学应用的必要推动者,如分布式海底监测、持续监视和远程高保真导航。水声信道(以长传播延迟和小相干带宽为特征)继续面临重大挑战,可靠的网络通信仍然是未来的目标。为此目的,若干伙伴大学之间的联合合作(Ocean-TUNE项目,由美国国家科学基金会资助)寻求建立一个水下网络试验台,进行实地测试,以便更好地了解水声通道特性。部署的一个关键特征是一个新的多载波(OFDM)调制解调器-据我们所知,这是此类测试平台的第一个-辅以软件驱动的协议栈实现,允许适应声学信道特性。在本文中,我们首先提供了我们的网络测试平台的架构概述,然后是来自华盛顿州Lake Union (Puget Sound)的初步测试的初步结果。我们以对未来计划的简要描述来结束本文。
Underwater communications is the necessary enabler for several next-generation engineering and scientific applications such as distributed undersea monitoring, persistent surveillance, and long-range high fidelity navigation. Underwater acoustic channels (characterized by long propagation delays and small coherence bandwidths) continue to present significant challenges and reliable networked communications remains a future goal. To this end, a joint collaboration between a number of partner universities (Ocean-TUNE project, funded by the U.S. National Science Foundation), seeks to implement an underwater networking testbed to conduct field tests for better understanding of the underwater acoustic channel characteristics. A key feature of the deployment is a new multicarrier (OFDM) modem - a first for such a testbed to the best of our knowledge - complemented with a software driven protocol stack implementation that allows adaptation to acoustic channel characteristics. In this paper, we first provide an architectural overview of our network testbed, followed by initial results from preliminary testing in Lake Union (Puget Sound), WA. We conclude the paper with a brief description of future plans.
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