A Laser Link From Lunar Surface Employing Line-of-Sight MIMO

Frontiers in Space Technologies Pub Date : 2021-10-25 DOI:10.3389/frspt.2021.750938

R. Schwarz, D. Giggenbach, Marcus T. Knopp, A. Knopp

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Abstract

Future exploration of our planetary system relies on the Moon as a base and stepping stone to other planets. A high-rate data connection to this celestial body is, therefore, imperative. Free-space optical (FSO) communications will enable continuous broadband connectivity to Earth. Currently pursued concepts incorporate data relay satellites orbiting the Moon, where each individual satellite terminal has to overcome the lunar distance facing restraints on telescope apertures and on beam pointing and tracking accuracies. We propose a concept of one dedicated link originating from a robotic telescope station installed on the lunar surface. We study the conceptual architecture of such an FSO ground node at the lunar surface with a spotlight on the link design at the physical layer. In particular, we increase the FSO channel capacity through multiple transmission- and receiving-apertures. Our findings encourage the application of the Line-of-Sight (LOS) multiple-input multiple-output (MIMO) technology to FSO communications at large link distances typically coming along with space missions, as thereby the maximum MIMO capacity can be achieved. Directing our study on the link geometry such connections seem technically feasible at relatively low system complexity with the receivers located at a single site and the transmitters only few meters apart.

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采用视距MIMO的月球表面激光链路

未来对行星系统的探索依赖于月球作为基地和通往其他行星的垫脚石。因此，与这个天体的高速数据连接是必要的。自由空间光学(FSO)通信将实现与地球的连续宽带连接。目前所追求的概念包括绕月球运行的数据中继卫星，其中每个单独的卫星终端都必须克服月球距离所面临的望远镜孔径和波束指向和跟踪精度的限制。我们提出了一个从安装在月球表面的机器人望远镜站出发的专用链路的概念。我们研究了这种月球表面的自由通信地面节点的概念架构，重点研究了物理层的链路设计。特别是，我们通过多个发射和接收孔径增加了FSO信道容量。我们的研究结果鼓励将视距(LOS)多输入多输出(MIMO)技术应用于大链路距离的FSO通信，通常伴随着太空任务，因此可以实现最大的MIMO容量。指导我们对链路几何形状的研究，这种连接在相对较低的系统复杂性下似乎在技术上是可行的，接收器位于单个站点，发射机相距仅几米。

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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Frontiers in Space Technologies

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