利用单频PPP分析电离层总电子含量半年变化对台站位移的影响

IF 0.8 4区 地球科学 Q4 GEOSCIENCES, MULTIDISCIPLINARY Terrestrial, Atmospheric and Oceanic Sciences Pub Date : 2021-01-01 DOI:10.3319/tao.2021.08.31.01
T. Tseng, C. Shum, Y. Hsiao, C. Kuo, W. Yeh
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引用次数: 0

摘要

在这项工作中,全球定位系统(GPS)站的位移是使用所谓的精确点定位(PPP)技术和低成本的单频(SF)接收器推导出来的。在SF PPP中,如果卫星轨道和时钟建模良好,电离层延迟是最大的误差源。我们使用两种策略来最小化电离层延迟以进行内部比较:(1)使用全球电离层图(GIM)进行校正,(2)从SF观测值(SFO)估计电离层总电子含量(TEC)。从这两种策略得到的台站位移趋势一致地呈现出向西南方向系统移动的趋势。这里的趋势是指用于拟合位移数据的线性函数的斜率。这种系统运动主要是由电离层TEC的半年变化引起的,而不是季节性地球物理效应和高阶电离层效应引起的,两者只引起几毫米到几厘米的台站位移。我们对半年TEC变化与台站位移之间的相关系数进行了统计分析。U分量的相关系数最大大于0.8,其次是E和N分量。此外,在北纬23°N、东经121°E附近,半年TEC变化对台站位移的影响分别在北(N)、东(E)和高(U)上分别约为0.71、0.45和0.92 m。这表明应该在SF-PPP得到的台站位移时间序列中考虑半年TEC变化。文章历史:收到2021年2月17日修订2021年7月12日接受2021年8月31日
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Impact of semi-annual ionospheric total electron content variation on station displacements using single-frequency PPP
Global Positioning System (GPS) station displacements in this work are derived using the so-called precise point positioning (PPP) technique with low-cost singlefrequency (SF) receivers. In the SF PPP, the ionosphere delay is the largest error source if the satellite orbits and clocks are well modeled. We use two strategies to minimize the ionosphere delay for an internal comparison: (1) correction using the global ionosphere map (GIM), and (2) estimates of the ionospheric total electron content (TEC) from SF observables (SFO). The trends of the station displacements derived from these two strategies consistently present a systematic movement toward the southwest. Here the trend is referred to the slope of a linear function used to fit the displacement data. Such a systematic movement is mainly caused by the semi-annual variation of the ionospheric TEC rather than the seasonal geophysical effect and the high-order ionosphere effect, both of which only cause the station displacements ranging from a few mm to a few cm. We present a statistical analysis in terms of correlation coefficients between the semi-annual TEC variation and the station displacement. The maximum correlation coefficient is higher than 0.8 in the U component, followed by the E and N components. In addition, the impact of the semi-annual TEC variation on the station displacement is approximately 0.71, 0.45, and 0.92 m in the north (N), east (E), and height (U) for a region close to the latitude 23°N and longitude 121°E. This suggests that the semi-annual TEC variation should be considered in a time series of station displacements derived by the SF-PPP. Article history: Received 17 February 2021 Revised 12 July 2021 Accepted 31 August 2021
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来源期刊
CiteScore
2.00
自引率
0.00%
发文量
29
审稿时长
4.5 months
期刊介绍: The major publication of the Chinese Geoscience Union (located in Taipei) since 1990, the journal of Terrestrial, Atmospheric and Oceanic Sciences (TAO) publishes bi-monthly scientific research articles, notes, correspondences and reviews in all disciplines of the Earth sciences. It is the amalgamation of the following journals: Papers in Meteorological Research (published by the Meteorological Society of the ROC) since Vol. 12, No. 2 Bulletin of Geophysics (published by the Institute of Geophysics, National Central University) since No. 27 Acta Oceanographica Taiwanica (published by the Institute of Oceanography, National Taiwan University) since Vol. 42.
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