Geostationary Satellite Station Keeping Robustness to Loss of Ground Control

IF 0.6 Q4 ASTRONOMY & ASTROPHYSICS

Journal of Astronomy and Space Sciences Pub Date : 2021-03-01 DOI:10.5140/JASS.2021.38.1.65

Hyung-Je Woo, Björn Buckwalter

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Abstract

For the vast majority of geostationary satellites currently in orbit, station keeping activities including orbit determination and maneuver planning and execution are ground-directed and dependent on the availability of ground-based satellite control personnel and facilities. However, a requirement linked to satellite autonomy and survivability in cases of interrupted ground support is often one of the stipulated provisions on the satellite platform design. It is especially important for a geostationary military-purposed satellite to remain within its designated orbital window, in order to provide reliable uninterrupted telecommunications services, in the absence of ground-based resources due to warfare or other disasters. In this paper we investigate factors affecting the robustness of a geostationary satellite’s orbit in terms of the maximum duration the satellite’s station keeping window can be maintained without ground intervention. By comparing simulations of orbit evolution, given different initial conditions and operations strategies, a variation of parameters study has been performed and we have analyzed which factors the duration is most sensitive to. This also provides valuable insights into which factors may be worth controlling by a military or civilian geostationary satellite operator. Our simulations show that the most beneficial factor for maximizing the time a satellite will remain in the station keeping window is the operational practice of pre-emptively loading East-West station keeping maneuvers for automatic execution on board the satellite should ground control capability be lost. The second most beneficial factor is using short station keeping maneuver cycle durations.

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地球同步卫星站对失去地面控制的鲁棒性

对于目前在轨的绝大多数地球静止卫星来说，包括轨道确定和机动规划和执行在内的站保持活动是由地面指导的，并取决于地面卫星控制人员和设施的可用性。然而，在地面支援中断的情况下，与卫星自主性和生存能力有关的要求往往是卫星平台设计中规定的条款之一。特别重要的是，地球同步军用卫星必须保持在其指定的轨道窗口内，以便在由于战争或其他灾害而缺乏地面资源的情况下提供可靠、不间断的电信服务。本文研究了影响地球静止卫星轨道鲁棒性的因素，即在没有地面干预的情况下卫星保持站窗的最大持续时间。通过对比轨道演化仿真，在给定不同初始条件和运行策略的情况下，进行了参数变化研究，分析了持续时间对哪些因素最敏感。这也为哪些因素值得由军事或民用地球静止卫星运营商控制提供了宝贵的见解。仿真结果表明，在失去地面控制能力的情况下，在卫星上预先加载东西站保持机动以自动执行，是使卫星在站保持窗口中停留时间最大化的最有利因素。第二个最有利的因素是使用短的站保持机动周期持续时间。

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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来源期刊

Journal of Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-

CiteScore

1.30

自引率

20.00%

发文量

审稿时长

12 weeks

期刊介绍： JASS aims for the promotion of global awareness and understanding of space science and related applications. Unlike other journals that focus either on space science or on space technologies, it intends to bridge the two communities of space science and technologies, by providing opportunities to exchange ideas and viewpoints in a single journal. Topics suitable for publication in JASS include researches in the following fields: space astronomy, solar physics, magnetospheric and ionospheric physics, cosmic ray, space weather, and planetary sciences; space instrumentation, satellite dynamics, geodesy, spacecraft control, and spacecraft navigation. However, the topics covered by JASS are not restricted to those mentioned above as the journal also encourages submission of research results in all other branches related to space science and technologies. Even though JASS was established on the heritage and achievements of the Korean space science community, it is now open to the worldwide community, while maintaining a high standard as a leading international journal. Hence, it solicits papers from the international community with a vision of global collaboration in the fields of space science and technologies.