Vertical Displacement due to Ocean Tidal Loading Around Taiwan Based on GPS Observations

Abstract Presented paper is dedicated to problems of deformation of the Earth's crust as a response to the surface loading caused by continental waters. The aim of this study was to specify areas particularly vulnerable to studied deformation and to compare calculated and observed displacements. Information of the continental water volume was taken from the WaterGAP Global Hydrological Model. Calculated values of the deformations were verified with the results obtained with programs SPOTL and grat. Vertical deformations were almost 10 times higher than the deformation in the horizontal plane, for which reason later part of the paper focuses on the former. In order to check agreement of the calculated and observed deformation 23 stations of International GNSS Service (IGS) were selected and divided into three groups (inland, near the shoreline and islands). Before comparison outliers and discontinuities were removed from GNSS observations. Modelled and observed signals were centred. The analysed time series of the vertical displacements showed that only for the inland stations it is possible to effectively remove displacements caused by mass transfer in the hydrosphere. For stations located in the coastal regions or islands, it is necessary to consider additional movement effects resulting from indirect ocean tidal loading or atmosphere loading.

Download Full-text

Exploration of Terrestrial Water Storage Characterization via Assimilation of Ground-based GPS Observations of Vertical Displacement and GRACE TWS Retrievals

10.5194/gstm2020-2 ◽

2020 ◽

Author(s):

Gaohong Yin ◽

Barton Forman ◽

Jing Wang

Keyword(s):

Great Basin ◽

Land Surface ◽

Water Storage ◽

Vertical Displacement ◽

Estimation Accuracy ◽

Terrestrial Water Storage ◽

Drought Period ◽

Terrestrial Water ◽

Gps Observations

Accurate estimation of terrestrial water storage (TWS) is crucial in the characterization of the terrestrial hydrologic cycle. The launch of GRACE and GRACE Follow-On (GRACE-FO) missions provide an unprecedented opportunity to monitor the change in TWS across the globe. However, the spatial and temporal resolutions provided by GRACE/GRACE-FO are often too coarse for many hydrologic applications. Land surface models (LSMs) provide estimates of TWS at a finer spatio-temporal resolution, but most LSMs lack complete, all-encompassing physical representations of the hydrological system such as deep groundwater storage or anthropogenic influences (e.g., groundwater pumping and surface water regulation). In recent years, geodetic measurements from the ground-based Global Positioning System (GPS) network have been increasingly used in hydrologic studies based on the elastic response of the Earth&#8217;s surface to mass redistribution. This study explores the potential of improving our knowledge in TWS change via merging the information provided by ground-based GPS, GRACE, and the NASA Catchment Land Surface Model (Catchment), especially for the TWS change during an extended drought period. &#160; Ground-based GPS observations of vertical displacement and GRACE TWS retrievals were assimilated into the Catchment LSM, respectively, using an ensemble Kalman filter (EnKF) in order to improve the estimation accuracy of TWS change. The data assimilation (DA) framework effectively downscaled TWS into its constituent components (e.g., snow and soil moisture) as well as improved estimates of hydrologic fluxes (e.g., runoff). Estimated TWS change from the open loop (OL; without assimilation) and GPS DA (i.e., using GPS-based vertical displacement during assimilation) simulations were evaluated against GRACE TWS retrievals. Results show that GPS DA improved estimation accuracy of TWS change relative to the OL, especially during an extended drought period post-2011 in the western United States (e.g., the correlation coefficient ROL = 0.46 and RGPSDA = 0.82 in the Great Basin). The performance of GPS DA and GRACE DA in estimating TWS constituent components and hydrologic fluxes were evaluated against in situ measurements. Results show that GPS DA improves snow water equivalent (SWE) estimates with improved R values found over 76% of all pixels that are collocated with in situ stations in the Great Basin. The findings in this study indicate the potential use of GPS DA and GRACE DA for TWS characterization. Both GRACE and ground-based GPS provide complementary TWS change information, which helps correct for missing physics in the LSM. Additionally, this study provides motivation for a multi-variate assimilation approach to simultaneously merge both GRACE and ground-based GPS into an LSM to further improve modeled TWS and its constituent components.

Download Full-text

On the Influence of Diurnal and Subdiurnal Signals in the Normal Vector on Large Ring Laser Gyroscope Observations

Pure and Applied Geophysics ◽

10.1007/s00024-020-02484-2 ◽

2020 ◽

Vol 177 (9) ◽

pp. 4217-4228

Author(s):

Monika Tercjak ◽

André Gebauer ◽

Marcin Rajner ◽

Aleksander Brzeziński ◽

Karl Ulrich Schreiber

Keyword(s):

Solid Earth ◽

Ring Laser ◽

Earth Tides ◽

Love Numbers ◽

Ring Laser Gyroscope ◽

Solid Earth Tides ◽

Ocean Tidal Loading ◽

Tidal Loading ◽

Laser Gyroscope ◽

The Impact

Abstract The ring laser gyroscope (RLG) technique has been investigated for over 20 years as a potential complement to space geodetic techniques in measuring Earth rotation. However, RLGs are also sensitive to changes in their terrestrial orientation. Therefore in this paper, we review how the high-frequency band (i.e. signals shorter than 0.5 cycle per day) of the known phenomena causing site deformation contribute to the RLG observable, the Sagnac frequency. We study the impact of solid Earth tides, ocean tidal loading and non-tidal loading phenomena (atmospheric pressure loading and continental hydrosphere loading). Also, we evaluate the differences between available models of the phenomena and the importance of the Love numbers used in modeling the impact of solid Earth tides. Finally, we compare modeled variations in the instrument orientation with the ones observed with a tiltmeter. Our results prove that at the present accuracy of the RLG technique, solid Earth tides and ocean tidal loading effects have significant effect on RLG measurements, and continental hydrosphere loading can be actually neglected. Regarding the atmospheric loading model, its application might introduce some undesired signals. We also show that discrepancies arising from the use of different models can be neglected, and there is almost no impact arising from the use of different Love numbers. Finally, we discuss differences between data reduced with tiltmeter observations and these reduced with modeled signal, and potential causes of this discrepancies.

Download Full-text

Comparison of simultaneous variations of the ionospheric total electron content and geomagnetic field associated with strong earthquakes

Natural Hazards and Earth System Science ◽

10.5194/nhess-1-53-2001 ◽

2001 ◽

Vol 1 (1/2) ◽

pp. 53-59 ◽

Cited By ~ 7

Author(s):

Sh. Naaman ◽

L. S. Alperovich ◽

Sh. Wdowinski ◽

M. Hayakawa ◽

E. Calais

Keyword(s):

Total Electron Content ◽

Vertical Displacement ◽

Temporal Variations ◽

Electron Content ◽

Geomagnetic Disturbances ◽

Total Electron ◽

Strong Earthquakes ◽

Ionospheric Total Electron Content ◽

Geomagnetic Observations ◽

Gps Observations

Abstract. In this paper, perturbations of the ionospheric Total Electron Content (TEC) are compared with geomagnetic oscillations. Comparison is made for a few selected periods, some during earthquakes in California and Japan and others at quiet periods in Israel and California. Anomalies in TEC were extracted using Global Positioning System (GPS) observations collected by GIL (GPS in Israel) and the California permanent GPS networks. Geomagnetic data were collected in some regions where geomagnetic observatories and the GPS network overlaps. Sensitivity of the GPS method and basic wave characteristics of the ionospheric TEC perturbations are discussed. We study temporal variations of ionospheric TEC structures with highest reasonable spatial resolution around 50 km. Our results show no detectable TEC disturbances caused by right-lateral strike-slip earthquakes with minor vertical displacement. However, geomagnetic observations obtained at two observatories located in the epicenter zone of a strong dip-slip earthquake (Kyuchu, M = 6.2, 26 March 1997) revealed geomagnetic disturbances occurred 6–7 h before the earthquake.

Download Full-text

Semi-diurnal and diurnal variation of errors in GPS precipitable water vapor at Tsukuba, Japan caused by site displacement due to ocean tidal loading

Earth Planets and Space ◽

10.1186/bf03352264 ◽

2000 ◽

Vol 52 (10) ◽

pp. 685-690 ◽

Cited By ~ 10

Author(s):

Yoshinori Shoji ◽

◽

Hajime Nakamura ◽

Kazumasa Aonashi ◽

Akinori Ichiki ◽

...

Keyword(s):

Water Vapor ◽

Diurnal Variation ◽

Precipitable Water ◽

Precipitable Water Vapor ◽

Ocean Tidal Loading ◽

Tidal Loading

Download Full-text

The Extraction of Ocean Tidal Loading from ASAR Differential Interferograms

Sensors ◽

10.3390/s20030632 ◽

2020 ◽

Vol 20 (3) ◽

pp. 632 ◽

Cited By ~ 1

Author(s):

Wei Peng ◽

Qijie Wang ◽

Yunmeng Cao

Keyword(s):

Synthetic Aperture Radar ◽

The United States ◽

Synthetic Aperture ◽

Tectonic Deformation ◽

Spatial Characteristics ◽

Tide Model ◽

Ocean Tidal Loading ◽

Tidal Loading ◽

Mean Square Errors ◽

Aperture Radar

The spatiotemporal crustal non-tectonic deformation caused by ocean tidal loading (OTL) can reach the centimeters scale in coastal land areas. The temporal variation of the site OTL displacements can be estimated by the global positioning system (GPS) technique, but its spatial variation needs to be further determined. In this paper, in order to analyze the spatial characteristics of the OTL displacements, we propose a multi-scale decomposition method based on signal spatial characteristics to derive the OTL displacements from differential interferometric synthetic aperture radar (D-InSAR) measurements. The method was tested using long-term advanced synthetic aperture radar (ASAR) data and GPS reference site data from the Los Angeles Basin in the United States, and we compared the results with the FES2014b tide model. The experimental results showed that the spatial function of the OTL displacements in an ASAR image can be represented as a higher-order polynomial function, and the spatial trends of the OTL displacements determined by the InSAR and the GPS techniques are basically consistent with the FES2014b tide model. The root-mean-square errors of the differences between the spatial OTL displacements of these two methods and the FES2014b tide model are less than 0.8 mm. The results indicate that the OTL displacement extracted from InSAR data can accurately reflect the spatial characteristics of the OTL effect, which will help to improve the spatial resolution and accuracy of the OTL displacement in coastal areas.

Download Full-text

Ocean tidal loading models assessment using 28 months of gravimetric tidal records in Dublin, Ireland

10.5194/egusphere-egu21-2422 ◽

2021 ◽

Author(s):

Przemysław Dykowski ◽

Kamila Karkowska ◽

Marcin Sękowski ◽

Paul Kane

Keyword(s):

International Association ◽

Sampling Rate ◽

Remote Access ◽

Absolute Gravity ◽

Joint Analysis ◽

Raspberry Pi ◽

Ocean Tide ◽

Loading Effect ◽

Ocean Tidal Loading ◽

Tidal Loading

In June of 2018 a project for the establishment of a modern permanent Absolute Gravity Network&#160; on the island of Ireland was initiated by the National Mapping Agency of Ireland, Ordnance Survey Ireland (OSi) with the cooperation of &#160;Institute of Geodesy and Cartography (IGiK), and Land and Property Services (LPS) in Northern Ireland. The project assumes conducting absolute gravity surveys of the network using &#160;the A10 absolute gravimeter on approximately 60 stations homogenously distributed on the island of Ireland.Data processing includes time variable corrections for body tides, barometric pressure, polar motion as well as ocean tidal loading. For Ireland the ocean tidal loading effect can reach peaks of between 400 nm/s2 on the west coast and 200 nm/s2 on the east coast. This effect is significant and up to now the authors are unaware of previous historical data or&#160; tidal gravity records being performed in Ireland. Hence it was considered as a valid component of the overall Absolute Gravity Project to evaluate the current situation with ocean tidal loading effect in Ireland using gravimetric tidal records in order to validate available ocean tidal loading models.In order to assure the most optimal use of ocean tidal model as well as minimize the errors of including ocean tidal correction in absolute gravity processing the LaCoste&Romberg model G spring gravimeter was installed at OSi headquarters in Phoenix Park, Dublin, Ireland. Over a continuous period of 28 months gravity record with more than 99% data completeness at near 2Hz sampling rate was conducted.The project data was acquired through using a self-programmed Raspberry Pi computer allowing for automatic download and remote access to the data.A set of CSR, DTU, EOT, FES, GOT, TPXO (ocean tide loading provider &#8211; Chalmers, http://holt.oso.chalmers.se/loading/) ocean tidal loading models were used in a joint analysis with the collected tidal record. Analysis included performing tidal adjustment of the gravity data in the ETERNA 3.40 (ET34-X-V73) as well as comparison of IAG (International Association of Geodesy) recommended model combinations with the collected data.Recommendations by the project team as to which of the ocean tidal models is most suitable to be used in Ireland for the purpose of absolute gravity measurements were made.

Download Full-text