利用光谱组合方法和GNSS/调平数据验证面向空间的GOCE重力梯度网格

IF 4.9 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Martin Pitoňák, Michal Šprlák, Vegard Ophaug, Ove C. D. Omang, Pavel Novák
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引用次数: 0

摘要

在新千年之初,重力专用卫星任务的发射使全球地球重力场模型(GGMs)的精度得到了提高。其中一项任务是2009年发射的重力场和稳态海洋环流探测器(GOCE)。作为欧洲航天局的第一个地球探测任务,这颗卫星携带了一种新颖的仪器,一个3-D梯度仪,它可以测量重力势的二阶方向导数(重力梯度),具有统一的质量和近全球覆盖。主要任务目标是确定静态地球重力场,在100公里(赤道半波长)的空间分辨率下,以1-2厘米的大地水准面高度和1 mGal的重力异常精度确定静态地球重力场。三年多来的出色测量成果产生了三个级别的数据产品(0级、1b级和2级),发布了六次全球重力梯度网格,以及几个全球重力梯度网格。这些网格代表了沿GOCE轨道直接测量的重力梯度与由ggm表示的重力梯度之间的一个步骤,主要用于地球物理应用。在这篇文章中,我们使用位于中欧和北欧(捷克/斯洛伐克和挪威)的两个测试区域的高度异常来验证官方2级产品GRD_SPW_2。采用基于最小二乘谱权的数学模型,估计相应的谱权,对重力梯度网格进行验证。该模型将地球表面平均轨道高度的重力梯度延续到不规则的地球表面(而不是球体),并在一个计算步骤中将其转换为高度异常。利用闭环试验估计了模型的解析向下延拓误差。在将重力梯度估算的高度异常与全球导航卫星系统(GNSS)/水准测量的参考值进行比较之前,将重力梯度和参考数据进行校正,以消除潮汐系统转换等所有系统影响。此外,估计重力信号的高频部分,并从参考数据中减去,因为它在GOCE测量的重力梯度中被衰减了。在捷克/斯洛伐克地区,第6版和第2版梯度网格在高度异常方面的相对改进达到了48 \(\%\)。挪威的相对改善更为显著,达到了55 \(\%\)。官方二级产品GRD_SPW_2的第6版获得了绝对精度,在捷克/斯洛伐克的标准偏差为8.7 cm,在挪威的标准偏差为9.3 cm。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Validation of Space-Wise GOCE Gravitational Gradient Grids Using the Spectral Combination Method and GNSS/Levelling Data

Validation of Space-Wise GOCE Gravitational Gradient Grids Using the Spectral Combination Method and GNSS/Levelling Data

The launch of gravity-dedicated satellite missions at the beginning of the new millennium led to an accuracy improvement of global Earth gravity field models (GGMs). One of these missions was the Gravity field and steady-state Ocean Circulation Explorer (GOCE) launched in 2009. As the first European Space Agency’s Earth Explorer Mission, the satellite carried a novel instrument, a 3-D gradiometer, which allowed measurement of the second-order directional derivatives of the gravitational potential (gravitational gradients) with a uniform quality and a near-global coverage. The main mission goal was to determine the static Earth’s gravity field with the ambitious precision of 1-2 cm in terms of geoid heights and 1 mGal in terms of gravity anomalies for spatial resolution of 100 km (half wavelength at the equator). More than three years of the outstanding measurements resulted in three levels of data products (Level 0, Level 1b and Level 2), six releases of GGMs, and several global grids of gravitational gradients. The grids, which represent a step between gravitational gradients measured directly along the GOCE orbit and those represented by GGMs, found their usage mainly in geophysical applications. In this contribution, we validate the official Level 2 product GRD_SPW_2 using height anomalies over two test areas located in central and northern Europe (Czechia/Slovakia and Norway). A mathematical model based on the least-squares spectral weighting is employed with corresponding spectral weights estimated for validation of gravitational gradient grids. This model continues gravitational gradients from the mean orbital altitude of GOCE down to the irregular Earth’s surface (not to a sphere) and transforms them to height anomalies in one computational step. Analytical downward continuation errors of the model are estimated using a closed-loop test. Prior to the comparison of height anomalies estimated from gravitational gradients with their reference values derived from Global Navigation Satellite Systems (GNSS)/levelling over the two test areas, the gravitational gradients and reference data are corrected for all systematic effects such as the tide system conversion. Moreover, the high-frequency part of the gravitational signal is estimated and subtracted from reference data as it is attenuated in the gravitational gradients measured by GOCE. A relative improvement between the release 6 and release 2 gradient grids reaches 48\(\%\) in terms of height anomalies in Czechia/Slovakia. The relative improvement in Norway is even more significant and reaches 55\(\%\). The release 6 of the official Level 2 product GRD_SPW_2 gained the absolute accuracy with the standard deviation of 8.7 cm over Czechia/Slovakia and 9.3 cm over Norway.

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来源期刊
Surveys in Geophysics
Surveys in Geophysics 地学-地球化学与地球物理
CiteScore
10.00
自引率
10.90%
发文量
64
审稿时长
4.5 months
期刊介绍: Surveys in Geophysics publishes refereed review articles on the physical, chemical and biological processes occurring within the Earth, on its surface, in its atmosphere and in the near-Earth space environment, including relations with other bodies in the solar system. Observations, their interpretation, theory and modelling are covered in papers dealing with any of the Earth and space sciences.
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