Wave-Telescope Analysis for Multipoint Observatories: Impact of Timing and Spatial Uncertainties

IF 2.6 2区地球科学 Q2 ASTRONOMY & ASTROPHYSICS

Journal of Geophysical Research: Space Physics Pub Date : 2024-12-10 DOI:10.1029/2024JA033428

K. G. Klein, T. Broeren, O. Roberts, L. Schulz

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Abstract

The wave telescope technique is used to reconstruct spatial power distributions of space plasmas from multipoint spacecraft missions. This study aims to quantify the impact of uncalibrated uncertainties in the time synchronization and the spatial position on the accuracy of the wave telescope method for observatories with more than four spacecraft, for example, HelioSwarm a nine-spacecraft NASA observatory currently in Phase B. We simulate synthetic data with systemic timing and spatial errors modeled using geometries drawn from HelioSwarm's Design Reference Mission, applying the wave telescope technique to estimate wavevectors for two characteristic ion-scale waves. By carefully selecting optimal polyhedral configurations from the overall geometry, and combining signals from multiple polyhedra, the impact of systematic uncertainties and spatial aliasing can be significantly reduced, leading to more accurate wavevector identification for future multipoint missions.

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多点观测站的波望远镜分析：时间和空间不确定性的影响

利用波望远镜技术重建空间等离子体的空间功率分布。本研究旨在量化时间同步和空间位置的未校准不确定性对4个以上航天器天文台的波望远镜方法精度的影响，例如，HelioSwarm是美国宇航局目前处于b阶段的9个航天器天文台。我们模拟了具有系统时间和空间误差的合成数据，使用HelioSwarm设计参考任务绘制的几何图形建模。应用波望远镜技术估计两种特征离子尺度波的波矢。通过从整体几何结构中精心选择最佳多面体构型，并将来自多个多面体的信号组合在一起，可以显著降低系统不确定性和空间混叠的影响，从而为未来的多点任务提供更准确的波矢量识别。

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来源期刊

Journal of Geophysical Research: Space Physics Earth and Planetary Sciences-Geophysics

CiteScore

5.30

自引率

35.70%

发文量

570