A hierarchical approach for the selection of optical ground stations maximizing the data transfer from low-earth observation satellites

2017 IEEE International Conference on Communications (ICC) Pub Date : 2017-05-21 DOI:10.1109/ICC.2017.7996550

Mikael Capelle, Marie-José Huguet, Nicolas Jozefowiez, X. Olive

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引用次数: 4

Abstract

For space industries, free-space optical communications are becoming a mature technology, but the impact of their use to download observations from spatial imagery systems has still to be evaluated. Unlike current radio-frequency technology, freespace optical communications are strongly impacted by weather conditions, and most notably by clouds. In order to cope with the later, it is necessary to achieve ground station diversity, i.e. having a network of optical ground stations able to receive data from satellites. In this paper, we aim to find a subset of a given number of ground stations maximizing the amount of data that can be downloaded from a low-earth orbiting satellite to the Earth during its missions. We present a Mixed Integer Linear Program model and a hierarchical method based on an exhaustive enumeration of the sets of stations and on a dynamic programming algorithm to solve it. The efficiency of this method is evaluated on several instances based on real ground station networks and on cloud cover throughout the last twenty years.

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利用近地观测卫星数据传输最大化的光学地面站分层选择方法

对于空间工业来说，自由空间光通信正在成为一项成熟的技术，但是它们用于从空间成像系统下载观测结果的影响仍有待评估。与当前的射频技术不同，自由空间光通信受到天气条件的强烈影响，尤其是云层。为了应对后者，有必要实现地面站分集，即拥有一个能够接收卫星数据的光学地面站网络。在本文中，我们的目标是找到给定数量的地面站的一个子集，使其在执行任务期间可以从低地球轨道卫星下载到地球的数据量最大化。本文提出了一个混合整数线性规划模型和一种基于站集穷举和动态规划算法的分层求解方法。在近二十年来基于实际地面站网络和云量的若干实例中，对该方法的有效性进行了评价。

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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2017 IEEE International Conference on Communications (ICC)

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