Modeling the Horizontal Velocity Field of the Earth’s Crust in a Regular Grid from GNSS Measurements

Modeling the Horizontal Velocity Field of the Earth’s Crust in a Regular Grid from GNSS Measurements

There are numerous methods for modeling velocity fields of the Earth’s crust. However, only a few of them are capable of modeling data beyond the contour of the geodetic network (extrapolating). Spatial modeling based on a neural network approach allows for the adequate modeling of the field of rece...

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Bibliographic Details
Main Authors: Manevich Aleksandr, Losev Ilya, Avdonina Alina, Shevchuk Roman, Kaftan Vladimir, Tatrinov Victor
Format: Article
Language:English
Published: Russian Academy of Sciences, The Geophysical Center 2023-12-01
Series:Russian Journal of Earth Sciences
Subjects:
velocity fields
resent crustal movements
spatial modeling
regular grid
extrapolation
interpolation
artificial neural networks
Online Access:http://doi.org/10.2205/2023ES000885
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Summary:There are numerous methods for modeling velocity fields of the Earth’s crust. However, only a few of them are capable of modeling data beyond the contour of the geodetic network (extrapolating). Spatial modeling based on a neural network approach allows for the adequate modeling of the field of recent crustal movements and deformations of the Earth’s crust beyond the geodetic network contour. The study extensively examines the hyperparameter settings and justifies the applicability of the neural network model for predicting crustal movement fields using the Ossetian geodynamic polygon as an example. The presented results, when compared to classical modeling methods, demonstrate that the neural network approach confidently yields results no worse than classical methods. The results of modeling for the Ossetian polygon can be used for geodynamic zoning, identification zones of extension and compression, computing the tectonic component of stresses, and identifying areas of high-gradient displacements.
ISSN:1681-1208

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