Orbit design for a future geodetic satellite and gravity field recovery

IF 3.9 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Journal of Geodesy Pub Date : 2024-08-19 DOI:10.1007/s00190-024-01884-9
Krzysztof Sośnica
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Abstract

Spherical geodetic satellites tracked by satellite laser ranging (SLR) stations provide indispensable scientific products that cannot be replaced by other sources. For studying the time-variable gravity field, two low-degree coefficients C20 and C30 derived from GRACE and GRACE Follow-On missions are replaced by the values derived from SLR tracking of geodetic satellites, such as LAGEOS-1/2, LARES-1/2, Starlette, Stella, and Ajisai. The subset of these satellites is used to derive the geocenter motion which is fundamental in the realization of the origin of the terrestrial reference frames. LAGEOS satellites provide the most accurate standard gravitational product GM of the Earth. In this study, we use the Kaula theorem of gravitational perturbations to find the best possible satellite height, inclination, and eccentricity for a future geodetic satellite to maximize orbit sensitivity in terms of the recovery of low-degree gravity field coefficients, geocenter, and GM. We also derive the common station-satellite visibility-coverability coefficient as a function of the inclination angle and satellite height. We found that the best inclination for a future geodetic satellite is 35°–45° or 135°–145° with a height of about 1500–1700 km to support future GRACE/MAGIC missions with C20 and C30. For a better geocenter recovery and derivation of the standard gravitational product, the preferable height is 2300–3500 km. Unfortunately, none of the existing geodetic satellites has the optimum height and inclination angle for deriving GM, geocenter, and C20 because there are no spherical geodetic satellites at the heights between 1500 (Ajisai and LARES-1) and 5800 km (LAGEOS-1/2, LARES-2).

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未来大地测量卫星的轨道设计和重力场恢复
卫星激光测距(SLR)站跟踪的球面大地测量卫星提供了其他来源无法替代的不可或缺的科学产品。为了研究时变重力场,用 LAGEOS-1/2、LARES-1/2、Starlette、Stella 和 Ajisai 等大地测量卫星激光测距跟踪得出的值取代了 GRACE 和 GRACE Follow-On 任务得出的两个低度系数 C20 和 C30。这些卫星的子集用于推导地心运动,而地心运动是实现地面参照基准原点的基础。LAGEOS 卫星提供了最精确的地球标准重力产品 GM。在这项研究中,我们利用引力扰动的考拉定理为未来的大地测量卫星找到了最佳的卫星高度、倾角和偏心率,以便在恢复低度重力场系数、地心和全球定位系统方面最大限度地提高轨道灵敏度。我们还推导出了作为倾角和卫星高度函数的普通台站-卫星能见度-可覆盖性系数。我们发现,未来大地测量卫星的最佳倾角为 35°-45° 或 135°-145°,高度约为 1500-1700 公里,以支持未来的 GRACE/MAGIC 任务与 C20 和 C30。为了更好地恢复地心和推导标准重力产品,最好的高度是 2300-3500 公里。遗憾的是,现有的大地测量卫星都不具备推导 GM、地心和 C20 的最佳高度和倾角,因为在 1500 公里(Ajisai 和 LARES-1)和 5800 公里(LAGEOS-1/2、LARES-2)之间的高度上没有球形大地测量卫星。
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来源期刊
Journal of Geodesy
Journal of Geodesy 地学-地球化学与地球物理
CiteScore
8.60
自引率
9.10%
发文量
85
审稿时长
9 months
期刊介绍: The Journal of Geodesy is an international journal concerned with the study of scientific problems of geodesy and related interdisciplinary sciences. Peer-reviewed papers are published on theoretical or modeling studies, and on results of experiments and interpretations. Besides original research papers, the journal includes commissioned review papers on topical subjects and special issues arising from chosen scientific symposia or workshops. The journal covers the whole range of geodetic science and reports on theoretical and applied studies in research areas such as: -Positioning -Reference frame -Geodetic networks -Modeling and quality control -Space geodesy -Remote sensing -Gravity fields -Geodynamics
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