Evaluating the impact of commercial radio occultation data using the observation system simulation experiment tool for ionospheric electron density specification

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Frontiers in Astronomy and Space Sciences Pub Date : 2024-06-12 DOI:10.3389/fspas.2024.1387941
Joseph Hughes, Ian Collett, Geoff Crowley, A. Reynolds, I. Azeem
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Abstract

Decision makers must often choose how many sensors to deploy, of what types, and in what locations to meet a given operational or scientific outcome. An observation system simulation experiment (OSSE) is a numerical experiment that can provide critical decision support to these complex and expensive choices. An OSSE uses a “truth model” or “nature run” to simulate what an observation system would measure and then passes these measurements to an assimilation model. Then, the output of the assimilation model is compared to that of the truth model to assess improvement and the impact of the observation system. Orion Space Solutions has developed the OSSE tool (OSSET) to perform OSSEs for ionospheric electron density specification quickly and accurately. In this study, we use OSSET to predict the impact of adding commercial radio occultation total electron content (TEC) data to an assimilation model. We compare the OSSE’s predictions to the real performance at a group of validation ionosondes and find good agreement. We also demonstrate the global assessments that are possible with the OSSET using the improvement in critical frequency specification as an example. From this, we find that commercial radio occultation data can improve the critical frequency specification by nearly 20% at high latitudes, which are not covered by COSMIC-2. The commercial satellites are in sun-synchronous orbits with constant local times, and this improvement is concentrated at these local times.
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利用观测系统模拟实验工具评估商业无线电掩星数据对电离层电子密度规格的影响
决策者往往必须选择部署多少传感器、什么类型的传感器以及部署在什么位置,以满足特定的业务或科学成果。观测系统模拟实验(OSSE)是一种数值实验,可以为这些复杂而昂贵的选择提供重要的决策支持。观测系统模拟实验使用 "真实模式 "或 "自然运行 "来模拟观测系统的测量结果,然后将这些测量结果传递给同化模式。然后,将同化模型的输出与真实模型的输出进行比较,以评估观测系统的改进和影响。Orion Space Solutions 开发了 OSSE 工具(OSSET),用于快速准确地执行电离层电子密度规格的 OSSE。在本研究中,我们使用 OSSET 预测在同化模型中添加商业射电掩星总电子含量(TEC)数据的影响。我们将 OSSE 的预测结果与一组验证电离层探测仪的实际性能进行了比较,发现两者的一致性很好。我们还以临界频率规格的改进为例,展示了使用 OSSET 可以进行的全球评估。由此,我们发现商业无线电掩星数据可以将 COSMIC-2 未覆盖的高纬度地区的临界频率规格提高近 20%。商业卫星处于太阳同步轨道,当地时间恒定,这种改进主要集中在这些当地时间。
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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