The Magnitude of Diurnal/Semidiurnal Atmospheric Tides (S1/S2) and Their Impacts on the Continuous GPS Coordinate Time Series

Li, Zhao; Chen, Wu; Jiang, Weiping; Deng, Liansheng; Yang, Ronghua

doi:10.3390/rs10071125

Cited by 3 publications

(4 citation statements)

References 36 publications

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“…However, in addition to ATML signals and other known geophysical effects, e.g., continental water storage and non-tidal ocean tidal loading induced displacements (van Dam et al, 1997(van Dam et al, , 2001(van Dam et al, , 2012Fritsche et al, 2012;Williams and Penna, 2011;Yuan et al, 2018), GNSS-related systematic errors also contribute to the observed non-linear variations in GNSS time series (Ray et al, 2008(Ray et al, , 2013. Previous results have shown that imperfect GNSS data processing models and strategies could result in spurious non-linear displacements of GNSS stations, which mask real crustal displacements, thus affecting the comparison between GNSS and predicted loading signals (Deng et al, 2017;Li et al, 2014Li et al, , 2018King and Watson, 2010;Penna and Stewart, 2003;Penna et al, 2007;.…”

Section: Gnss Position Time Seriesmentioning

confidence: 99%

Comparative analysis of different atmospheric surface pressure models and their impacts on daily ITRF2014 GNSS residual time series

Chen

Dam

et al. 2020

J Geod

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To remove atmospheric pressure loading (ATML) effect from GNSS coordinate time series, surface pressure (SP) models are required to predict the displacements. In this paper, we modeled the 3-D ATML surface displacements using the latest MERRA-2 SP grids, together with four other products (NCEP-R-1, NCEP-R-2, ERA-Interim and MERRA) for 596 globally distributed GNSS stations, and compared them with ITRF2014 residual time series. The five sets of ATML displacements are highly consistent with each other, particularly for those stations far away from coasts, of which the lowest correlations in the Up component for all the four models w.r.t. MERRA-2 become larger than 0.91.ERA-Interim-derived ATML displacement performs best in reducing scatter of the GNSS height for 90.3 % of the stations (89.3 % for NCEP-R-1, 89.1 % for NCEP-R-2, 86.4 % for MERRA, and 85.1 % for MERRA-2). We think that this may possibly due to the 4-D variational data assimilation method applied. Considering inland stations only, more than 96 % exhibit WRMS reduction in the Up direction for all five models, with an average improvement of 3~4 % compared with the original ITRF2014 residual time series before ATML correction. Most stations (>67 %) also exhibit horizontal WRMS reductions based on the five models, but of small magnitudes, with most improvements (>76 %) less than 5 %. In particular, most stations in South America, South Africa, Oceania and the Southern Oceans show larger WRMS reductions with MERRA-2, while all other four SP datasets lead to larger WRMS reduction for the Up component than MERRA-2 in Europe.Through comparison of the daily pressure variation from the five SP models, we conclude that the bigger model differences in the SP-induced surface displacements and their impacts on the ITRF2014 residuals for coastal/island stations are mainly due to the IB correction based on the different land-sea masks. A unique high spatial resolution land-sea mask should be applied in the future, so that model differences would come from only SP grids. Further research is also required to compare the ATML effect in ice-covered and high mountainous regions, for example, the Qinghai-Tibet Plateau in China, the Andes in South America, etc, where larger pressure differences between models tend to occur.

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Section: Gnss Position Time Seriesmentioning

confidence: 99%

Comparative analysis of different atmospheric surface pressure models and their impacts on daily ITRF2014 GNSS residual time series

Chen

Dam

et al. 2020

J Geod

Self Cite

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“…used threshold is the Akaike weight 1%. The results are shown in table 5. One can see that the ratio of the number of sites that can be applied to a model averaging algorithm is all over 50% per direction.…”

Section: Results Of the Analysis Of 110 Worldwide Igs Sitesmentioning

confidence: 96%

“…In recent years, an increasing number of newly built GNSS sites have been put into operation as well, these GNSS sites provide valuable basic data for scientific research. Currently, high-precision GNSS time series obtained through GNSS observations processing are widely used by researchers in scientific research in fields such as geophysics, geology, seismology, geodynamics and atmospheric and marine physics [1][2][3][4][5][6][7][8][9][10][11][12], as well as in infrastructure construction fields such as monitoring of dams, bridges, and tunnels [13,14].…”

Section: Introductionmentioning

confidence: 99%

Selection of noise models for GNSS coordinate time series based on model averaging algorithm

Huan,

Chang,

Huang

et al. 2024

Meas. Sci. Technol.

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In the field of Global Navigation Satellite System (GNSS) time series noise analysis, appropriately modeling the noise components plays an important role in determining the velocity of GNSS sites and quantifying the uncertainty associated with the velocity estimation. Over the years, researchers have focused on only one optimal noise model, while other noise models that show similar performance to the optimal model have been ignored. We investigated whether these ignored noise models that can be made use of describing the noise in the GNSS time series after applying model averaging algorithm. The experimental data were derived from 28 International GNSS Service (IGS) sites in the California region of the United States and 110 IGS sites worldwide. The results showed that for the GNSS time series of 28 IGS sites in the California, 79%, 68%, and 75% of the site components can be applied the model averaging algorithm in the East/North/Up directions, respectively. Based on it, the East direction showed the best performance, with 50% of the site components obtaining more conservative velocity uncertainty after applying the model averaging algorithm compared to the optimal noise model. For GNSS time series of 110 IGS stations worldwide, the model averaging algorithm demonstrates excellent performance in all the East/North/Up directions. In the East/North/Up directions, 86%, 94%, and 57% of the site components can apply the model averaging algorithm. Building upon this, 77%, 65%, and 62% of the sites achieve more conservative velocity uncertainty in the East/North/Up directions compared to the optimal noise model. To fully validate the feasibility of model averaging algorithm, we also tested GNSS time series of varying lengths and different thresholds of the model averaging algorithm. To summarize, the model averaging algorithm performs exceptionally well in the noise analysis of GNSS time series. It helps prevent overly optimistic estimation results.

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“…The differences interpreted as being related to the representation of atmospheric tides may induce regional biases up to 3 ppm on the mole fraction of methane with respect to dry air averaged over the atmospheric column (see Figure 5). Indeed, time interpolation creates systematic errors for insufficiently sampled periodic components such as atmospheric tides, as it is well documented in other contexts [24].…”

Section: Time Interpolation and Tide Wavesmentioning

confidence: 89%

Impact of Meteorological Uncertainties in the Methane Retrieval Ground Segment of the MERLIN Lidar Mission

et al. 2022

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MERLIN (MEthane Remote sensing LIdar missioN) is a Franco-German space mission designed to provide weighted columns of atmospheric methane through an inversion of the lidar signal using a priori information on the atmospheric state. Uncertainties about the meteorological parameters of the observed scene used in the ground segment contribute to the error budget on the retrieved methane column. With the LIDSIM (LIDar SIMulator) data simulator and the PROLID (PROcessor LIDar) inversion processor developed for MERLIN, we perform an impact experiment using ECMWF (European Centre for Medium Weather Range Forecast) ensemble forecast data. In addition, we estimate the standard deviation of the error in the methane column due to the meteorological uncertainties to be about 0.6 ppb. In addition, we innovate by discussing the impact of interpolations both in time and space, focusing on vertical extrapolations under the topography by using state-of-the-art methods to determine from the scatter between these methods the range in which the actual profile should be. We conclude that, in areas where the topography variations exceed 10 m over 10 km, an additional random error of 0.1 ppb is due to our lack of knowledge of the adjustment of atmospheric profiles to terrain. Finally, we point out that further work needs to be performed on temporal interpolation. Indeed, the 3 h time interpolation of atmospheric tides can create regional biases of up to 2 ppm (which is a major problem for models trying to identify methane sinks and sources).

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The Magnitude of Diurnal/Semidiurnal Atmospheric Tides (S1/S2) and Their Impacts on the Continuous GPS Coordinate Time Series

Cited by 3 publications

References 36 publications

Comparative analysis of different atmospheric surface pressure models and their impacts on daily ITRF2014 GNSS residual time series

Comparative analysis of different atmospheric surface pressure models and their impacts on daily ITRF2014 GNSS residual time series

Selection of noise models for GNSS coordinate time series based on model averaging algorithm

Impact of Meteorological Uncertainties in the Methane Retrieval Ground Segment of the MERLIN Lidar Mission

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