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7 results on '"Limberger, Fabian"'

1. When linear inversion fails: neural-network optimization for sparse-ray travel-time tomography of a volcanic edifice

Author

Komeazi, Abolfazl, Rümpker, Georg, Faber, Johannes, Limberger, Fabian, and Srivastava, Nishtha

Subjects
Physics - Geophysics
Abstract

In this study, we present an artificial neural network (ANN)-based approach for travel-time tomography of a volcanic edifice. We employ ray tracing to simulate the propagation of seismic waves through the heterogeneous medium of a volcanic edifice, and an inverse modeling algorithm that uses an ANN to estimate the velocity structure from the observed travel-time data. The performance of the approach is evaluated through a 2-dimensional numerical study that simulates i) an active source seismic experiment with few (explosive) sources placed on one side of the edifice and a dense line of receivers placed on the other side, and ii) earthquakes located inside the edifice and receivers placed on both sides of the edifice. The results are compared with those obtained from conventional damped linear inversion, demonstrating that the ANN-based approach outperforms the classical approach, particularly in situations with sparse ray coverage. Our study emphasizes the advantages of employing a relatively simple ANN architecture in conjunction with second-order optimizers to minimize the loss function. The ANN-based approach is computationally efficient and capable of providing high-resolution velocity images of anomalous structures within the edifice, making it a potentially valuable tool for the detection of low velocity anomalies related to magmatic intrusions or mush., Comment: 26 pages, 9 figures in the main text, 6 figures in supplementary material, 1 table in the main text, 1 table in supplementary material

Published
2023

5. Experimental and numerical analysis of seismic waves produced by wind farms

Author

Limberger, Fabian and Limberger, Fabian

Abstract

This thesis presents the experimental and numerical analysis of seismic waves that are produced by wind farms. With the aim to develop renewable energies rapidly, the number of wind turbines has been increased in recent years. Ground motions induced by their operation can be observed by seismometers several kilometers away. Hence, the seismic noise level can be significantly increased at the seismic station. Therefore, this study combines long-term experiments and numerical simulations to improve the understanding of the seismic wavefields emitted by complete wind farms and to advance the prediction of signal amplitudes. Firstly, wind-turbine induced signals that are measured at a small wind farm close to Würzburg (Germany) are correlated with the operational data of the turbines. The frequency-dependent decay of signal amplitudes with distance from the wind farm is modeled using an analytical method including the complex effects of interferences of the wavefields produced by the multiple wind turbines. Specific interference patterns significantly affect the wave propagation and therefore the signal amplitude in the far field of a wind farm. Since measurements inside the wind turbines show that the assumption of in-phase vibrating wind turbines is inappropriate, an approach to calculate representative seismic radiation patterns from multiple wind turbines, which allows the prediction of amplitudes in the far field of a complete wind farm, is proposed. In a second study, signals with a frequency of 1.15 Hz, produced by the Weilrod wind farm (north of Frankfurt, Germany) are observed at the seismological observatory TNS (Taunus), which is located at a distance of 11 km from the wind farm. The propagation of the wavefield emitted by the wind farm is numerically modeled in 3D, using the spectral element method. It is shown that topographic effects can cause local signal amplitude reductions, but also signal amplification along the travel path of the seismic wave. The co, Das Innere der Erde wird anhand von seismischen Wellen, die den Erdglobus nach einem Erdbeben durchlaufen, erforscht. Seismische Wellen sind elastische Wellen und transportieren Informationen des Untergrunds an die Erdoberfläche und ermöglichen damit Aussagen zum Aufbau, zur Struktur und Beschaffenheit der Erde auf lokaler und globaler Skala. Mit hochempfindlichen Seismometern lassen sich schon sehr kleine Bodenbewegungen und Deformationsprozesse an der Erdoberfläche nachweisen. Neben Erdbeben oder vulkanischen Prozessen werden Seismometer auch zur globalen Überwachung von Nuklearwaffentests oder zur Erfassung lokaler mikroseismischer Ereignisse, beispielsweise bei geothermischen Kraftwerken oder Aktivitäten in Steinbrüchen, eingesetzt. Aufgrund von wachsenden Bevölkerungszahlen, der Vergrößerung der Städte und der raschen Entwicklung von Verkehrssystemen, Industrie und Technologien zur Energieerzeugung, zeichnen Seismometer nicht nur natürliche Signale, wie z.B. von Erdbeben auf, sondern registrieren auch Schwingungen, die durch die genannten Infrastrukturen verursacht werden - das sogenannte anthropogene seismische Rauschen. Mit dem Ziel, erneuerbare Energien schnell auszubauen, um unabhängig von fossilen Brennstoffen zu werden, nahm die Anzahl der Windenergieanlagen in den letzten Jahrzehnten drastisch zu und wird in Zukunft noch weiter ansteigen. Diese Anlagen werden häufig in abgelegenen windhöffigen Gebieten errichtet, um die Auswirkungen auf die Umwelt zu minimieren und gleichzeitig die Windenergie optimal zu nutzen. Standorte mit ähnlichen Bedingungen werden auch von den Betreibern seismologischer Stationen bevorzugt, da hier das anthropogene seismische Rauschen vermindert auftritt. Windenergieanlagen werden durch den Wind und die darauffolgende Rotation des Rotors in Vibrationen versetzt, welche über das Fundament der Anlage in das Erdreich eingekoppelt werden. Auf diese Weise entstehen Bodenbewegungen, die sich in Form von seismischen Wellen ausbreiten. Vi

Published
2023

6. Seismic radiation from wind turbines: observations and analytical modeling of frequency-dependent amplitude decays

Author

Limberger, Fabian, Lindenfeld, Michael, Deckert, Hagen, and Rümpker, Georg

Subjects
ddc:550
Abstract

In this study, we determine spectral characteristics and amplitude decays of wind turbine induced seismic signals in the far field of a wind farm (WF) close to Uettingen, Germany. Average power spectral densities (PSDs) are calculated from 10 min time segments extracted from (up to) 6 months of continuous recordings at 19 seismic stations, positioned along an 8 km profile starting from the WF. We identify seven distinct PSD peaks in the frequency range between 1 and 8 Hz that can be observed to at least 4 km distance; lower-frequency peaks are detectable up to the end of the profile. At distances between 300 m and 4 km the PSD amplitude decay can be described by a power law with exponent b. The measured b values exhibit a linear frequency dependence and range from b=0.39 at 1.14 Hz to b=3.93 at 7.6 Hz. In a second step, the seismic radiation and amplitude decays are modeled using an analytical approach that approximates the surface wave field. Since we observe temporally varying phase differences between seismograms recorded directly at the base of the individual wind turbines (WTs), source signal phase information is included in the modeling approach. We show that phase differences between source signals have significant effects on the seismic radiation pattern and amplitude decays. Therefore, we develop a phase shift elimination method to handle the challenge of choosing representative source characteristics as an input for the modeling. To optimize the fitting of modeled and observed amplitude decay curves, we perform a grid search to constrain the two model parameters, i.e., the seismic shear wave velocity and quality factor. The comparison of modeled and observed amplitude decays for the seven prominent frequencies shows very good agreement and allows the constraint of shear velocities and quality factors for a two-layer model of the subsurface. The approach is generalized to predict amplitude decays and radiation patterns for WFs of arbitrary geometry.

Published
2021

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