On the Analysis of Wind-Induced Noise in Seismological Recordings: Approaches to Present Wind-Induced Noise as a Function of Wind Speed and Wind Direction

On the Analysis of Wind-Induced Noise in Seismological Recordings Approaches to Present Wind-Induced Noise as a Function of Wind Speed and Wind Direction

Atmospheric processes, ranging from microscale turbulence to severe storms on the synoptic scale, impact the continuous ground motion of the earth and have the potential to induce strong broad-band noise in seismological recordings. We designed a target-oriented experiment to quantify the influence...

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Bibliographic Details
Published in:Pure and applied geophysics Vol. 174; no. 3; pp. 1453 - 1470
Main Authors: Lott, Friederike F., Ritter, Joachim R. R., Al-Qaryouti, Mahmoud, Corsmeier, Ulrich
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-03-2017
Springer Nature B.V
Subjects:
Earth and Environmental Science
Earth Sciences
Geophysics/Geodesy
Ground motion
Noise
Noise levels
Recording
Seismology
Spectrum analysis
Stations
Topography
Wind
Wind direction
Wind effects
Wind speed
Greece, Kriti, Dead Sea Valley
dead sea
Seismology
wind speed
topography
noise
microseisms
spectral analysis
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Summary:Atmospheric processes, ranging from microscale turbulence to severe storms on the synoptic scale, impact the continuous ground motion of the earth and have the potential to induce strong broad-band noise in seismological recordings. We designed a target-oriented experiment to quantify the influence of wind on ground motion velocity in the Dead Sea valley. For the period from March 2014 to February 2015, a seismological array, consisting of 15 three-component short-period and broad-band stations, was operated near Madaba, Jordan, complemented by one meteorological tower providing synchronized, continuous three-component measurements of wind speed. Results reveal a pronounced, predominantly linear increase of the logarithmic power of ground motion velocity with rising mean horizontal wind speed at all recording stations. Measurements in rough, mountainous terrain further identify a strong dependency of wind-induced noise on surface characteristics, such as topography and, therefore, demonstrate the necessity to consider wind direction as well. To assess the noise level of seismological recordings with respect to a dynamically changing wind field, we develop a methodology to account for the dependency of power spectral density of ground motion velocity on wind speed and wind direction for long, statistically significant periods. We further introduce the quantitative measure of the ground motion susceptibility to estimate the vulnerability of seismological recordings to the presence of wind.
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ISSN:0033-4553
1420-9136
DOI:10.1007/s00024-017-1477-2