Geodetic Monitoring of the Variable Surface Deformation in Latin America

Sánchez, Laura; Drewes, H

doi:10.1007/1345_2020_91

Cited by 17 publications

(10 citation statements)

References 38 publications

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“… Changes in the Latin American reference frame kinematics induced by strong earthquakes. They are inferred from the difference between the two latest multi‐year solutions SIR15P01 (Sánchez & Drewes, 2016) and SIR17P01 (Sánchez & Drewes, 2020). Blue stars represent earthquakes with Mw > 6.0 since January 1, 2010.…”

Section: Sirgas Reference Frame and Geodynamics In Latin Americamentioning

confidence: 99%

“…The disadvantage of the alignment to linearly parametrized reference coordinates is that neither seasonal variations, for example, caused by atmospheric, oceanic, and hydrological loading (Seitz & Krügel, 2009; F. Seitz et al., 2014; Glomsda, Bloßfeld, et al., 2021), nor anthropogenic changes such as subsidence due to groundwater withdrawal (e.g., Bevis et al., 2005), are fully modeled in the reference coordinates. Moreover, especially in the extrapolation period of a reference frame, episodic changes like seismic events (Sánchez & Drewes, 2016, 2020) are no longer represented in the reference coordinates. The accuracy of the geocentricity of the resulting coordinates thus decreases over time, meaning that the coordinates' information value for research of geodynamics or global change decreases substantially.…”

Section: Introductionmentioning

confidence: 99%

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Combination Strategy for the Geocentric Realization of Regional Epoch Reference Frames

et al. 2022

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For high‐resolution regional geodetic applications, the International Terrestrial Reference Frame (ITRF) is complemented by regional densifications. These are realized either as multi‐year solutions related to a tectonic plate (e.g., EUREF for Europe) or as epoch reference frames (ERFs) to capture nonlinear geophysical station motions caused by, for example, earthquakes or non‐tidal loading (e.g., SIRGAS for Latin America). These Global Navigation Satellite Systems (GNSS)‐only based regional reference frames have in common that their geodetic datum is aligned with the ITRF datum at a specific epoch. The consequence is that their origin represents the Earth's center of figure and does not coincide with the instantaneous center of mass. Here, we present studies on a direct geocentric realization of regional ERFs. We propose to realize the geodetic datum for each epoch by combining global GNSS, Satellite Laser Ranging, and Very Long Baseline Interferometry networks via measured local ties at co‐located sites. A uniformly distributed global GNSS network is used to realize the orientation via a no‐net‐rotation constraint with respect to the ITRF and is densified by the stations of the regional subnetwork. The developed combination and filtering strategy aims to guarantee a stable datum realization for each epoch‐wise solution. Validating our results against global reference frames and geophysical loading models relating to the Earth's centers of mass and figure, we show that the realized displacement time series are geocentric and reflect seasonal geophysical processes. As the approach does not need to rely on co‐location sites in the region of interest, it is conceptually transferable to other regions on the globe.

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Section: Sirgas Reference Frame and Geodynamics In Latin Americamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Combination Strategy for the Geocentric Realization of Regional Epoch Reference Frames

et al. 2022

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“…IMBT, NEIA, POLI, PRGU, PRMA, SCAQ, SCFL, SCLA, SPBO and SPPI stations). These are all part of the latest SIRGAS multi-year solution (i.e., SIR17P01), which is aligned to the IGS14 reference frame, epoch 2015.0 (Sánchez and Drewes 2020). The stabilization process of the individual solutions was performed by using generalized constraints.…”

Section: Gps Data Processingmentioning

confidence: 99%

“…First of all, and in order to evaluate the consistency of our velocities with reference to SIRGAS velocities, a direct comparison was performed between them and those obtained in the latest SIRGAS solution (i.e. SIR17P01) (Sánchez and Drewes 2020). Figure 6 and Tables 2, show the velocities and their absolute differences obtained for each of the 10 SIRGAS-CON stations used in the stabilization process and the UFPR station, which is also part of the SIR17P01 solution.…”

Section: Velocities Sites Estimation and Local Movement Analysismentioning

confidence: 99%

“…The ability of Global Navigation Satellite Systems (GNSS) to estimate high accuracy 3D positions has contributed greatly to the development of new monitoring techniques aimed at understanding how different tectonic and geological processes affect the Earth surface and fundamentally, to explain how these mechanisms impact the society and the environment (Bock and Melgar 2016). One of the main applications that currently make use of GNSS is the study and monitoring of geophysical phenomena (e.g., tectonic motion, fault zones, landslides, subduction processes, and volcanoes) (Luna et al 2017, Duman and Sanli 2019, Sánchez and Drewes 2020. In this scenario, GNSS observations play an important role, since they provide estimates of crustal deformation with respect to a global terrestrial reference frame, while also provide constraints of the nature of the forces acting on the Earth surface (Lambeck 1988).…”

Section: Introductionmentioning

confidence: 99%

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Analysis of local surface displacement using repeated GPS measurements: a case study of the Guabirotuba area, Curitiba, Brazil

et al. 2022

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In recent years, the ability of GNSS systems to estimate high accuracy 3D positions has greatly contributed to the development of new monitoring techniques aimed at understanding the mechanisms by which the different Earth processes are generated. This paper presents the result of 9 GPS campaigns, between 2014 and 2019 for a group of 29 stations, held in the Guabirotuba urban area, Curitiba, Brazil, intending to estimate local crustal movements. The average magnitude and direction of horizontal velocities obtained for each site, allow demonstrating deformation of the southern zone of the area as a result of a local landslide process. The magnitude of the vectors varies between 1 and 16 mm/a horizontally. All sites had an absolute vertical movement, probably correlated with a local geological pattern or a physical site's motion driven by environmental mass redistribution. The uncertainties in positions and velocities for a long-term survey (over 5 years), showed good consistency at most sites when compared with the coordinates and velocities precision of the latest SIRGAS solution. The typical precision for the station positions at the reference epoch was ±2 mm horizontally and ±5 mm vertically, and ±0.60 mm/a horizontally and ±1.37 mm/a vertically for the constant velocities.

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Status of the SIRGAS Reference Frame: Recent Developments and New Challenges

Alves Costa,

Sánchez,

Piñón

et al. 2023

International Association of Geodesy Symposia

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In accordance with recent developments of the International Association of Geodesy (IAG) and the policies promoted by the Subcommittee on Geodesy of the United Nations Committee of Experts on Global Geospatial Information Management (UN-GGIM), a main goal of the Geodetic Reference System for the Americas (SIRGAS) is the procurement of an integrated regional reference frame. This frame should support the precise determination of geocentric coordinates and also provide a unified physical reference frame for gravimetry, physical heights, and a geoid. The geometric reference frame is determined by a network of about 500 continuously operating GNSS stations, which are routinely processed by ten analysis centers. The GNSS solutions from the analysis centers are used to generate weekly station positions aligned to the International Terrestrial Reference Frame (ITRF) and multi-year (cumulative) reference frame solutions. This processing is also the basis for the generation of precise tropospheric zenith path delays with an hourly sampling rate over the Americas. The reference frame for the determination of physical heights is a regional densification of the International Height Reference Frame (IHRF). Current efforts focus on the estimation and evaluation of potential values obtained from high resolution gravity field modelling, an activity tightly coupled with geoid determination. The gravity reference frame aims to be a regional densification of the International Terrestrial Gravity Reference Frame (ITGRF). Thus, SIRGAS activities are focused on evaluating the quality of existing absolute gravity stations and to identify regional gaps where additional absolute gravity stations are needed. Another main goal of SIRGAS is to promote the use of its geodetic reference frame at the national level and to support capacity building activities in the region. This paper summarizes key milestones in the establishment and maintenance of the SIRGAS reference frame and discusses current efforts and future challenges.

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Geodetic Monitoring of the Variable Surface Deformation in Latin America

Cited by 17 publications

References 38 publications

Combination Strategy for the Geocentric Realization of Regional Epoch Reference Frames

Combination Strategy for the Geocentric Realization of Regional Epoch Reference Frames

Analysis of local surface displacement using repeated GPS measurements: a case study of the Guabirotuba area, Curitiba, Brazil

Status of the SIRGAS Reference Frame: Recent Developments and New Challenges

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