The Western Australian optical ground station

38th International Communications Satellite Systems Conference (ICSSC 2021) Pub Date : 2022-01-25 DOI:10.1049/icp.2022.0552

S. Walsh, A. Frost, W. Anderson, Toby Digney, B. Dix-Matthews, D. Gozzard, Charles T. Gravestock, L. Howard, S. Karpathakis, A. McCann, S. Schediwy

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引用次数: 2

Abstract

Free-space communications at optical wavelengths offers the potential for orders-of-magnitude improvement in data rates over conventional radio wavelengths, and this will be needed to meet the demand of future space-to-ground applications. Supporting this new paradigm necessitates a global network of optical ground stations. This paper describes the architecture and commissioning of the Western Australian Optical Ground Station, to be installed on the roof of the physics building at the University of Western Australia. This ground station will incorporate amplitude- and phase-stabilisation technology, previously demonstrated over horizontal free-space links, into the ground station's optical telescope. Trialling this advanced amplitude- and phase-stabilisation technology, the ground station will overcome turbulence-induced noise to establish stable, coherent free-space links between ground-to-air and ground-to-space. These links will enable significant advances in high-speed and quantum-secured communications; positioning, navigation, and timing; and fundamental physics.

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西澳大利亚光学地面站

光学波长的自由空间通信提供了比传统无线电波长数据速率提高数量级的潜力，这将是满足未来空间对地面应用需求所必需的。支持这种新模式需要一个全球光学地面站网络。本文介绍了西澳大利亚光学地面站的结构和调试，该地面站将安装在西澳大利亚大学物理大楼的屋顶上。该地面站将把振幅和相位稳定技术整合到地面站的光学望远镜中，该技术之前在水平自由空间链路上进行了演示。通过试验这种先进的振幅和相位稳定技术，地面站将克服湍流引起的噪声，在地对空和地对空之间建立稳定、连贯的自由空间连接。这些链路将使高速和量子安全通信取得重大进展;定位、导航和定时;还有基础物理。

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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38th International Communications Satellite Systems Conference (ICSSC 2021)

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