Wave height quantification using land based seismic data with grammatical evolution

Donne, Sarah; Nicolau, Miguel; Bean, Christopher J.; O’Neill, Michael

doi:10.1109/cec.2014.6900563

Cited by 7 publications

(4 citation statements)

References 22 publications

(30 reference statements)

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“…Estimating the significant wave height using seismic land station, have been successfully used before using different methods (e.g. Bromirski et al 1999;Donne et al 2014).…”

Section: S E I S M I C Data a N A Ly S E Smentioning

confidence: 99%

Assessing swells in La Réunion Island from terrestrial seismic observations, oceanographic records and offshore wave models

Rindraharisaona

Cordier

Barruol

et al. 2020

Geophysical Journal International

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SUMMARY La Réunion Island in the southwest Indian Ocean is seasonally affected by austral swells among which some extreme events may have strong impacts on coastal infrastructures. The very limited number of sensors available on and around the island and in the whole SW Indian Ocean impedes any direct monitoring of the swell activity. In this study, we analyse direct observations of the ocean swell by combining terrestrial measurements of the microseismic noise with in situ oceanographic observations issued from two pressure gauges and an Acoustic Doppler Current Profiler (ADCP), together with swell numerical modelling. The reliability of the terrestrial seismic station to characterize the ocean activity in both the primary and secondary microseisms peaks (PM and SM, respectively), and also in the long period secondary microseismic peak (LPSM) for the case of La Réunion Island is presented and discussed here. By computing the hourly RMS of the PM and LP(SM) amplitudes, we establish a transfer function between the PM and (LP)SM amplitude and the maximum wave height, which appears to be valid for any PM and LPSM amplitudes >0.15 μm and >1.0 μm, respectively. The correlation coefficient between the PM amplitude and the wave height is >0.92. It suggests that the PM amplitude can be used as a robust proxy for the swell height and may help calibrating the wave heights from other independent observable. For some swell events, we observe LPSM that correlate well (>0.91) with the local wave height suggesting a generation by coastal swell reflection. From polarization and spectral analyses, directions and periods of swells are also well retrieved from seismic data. Finally, continuous measure of the SM amplitude shows that it can be used as precursor information for distant swells that may hit La Réunion Island a few days after their generation in the southern Indian Ocean.

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“…Estimating the significant wave height using seismic land station, have been successfully used before using different methods (e.g. Bromirski et al 1999;Donne et al 2014).…”

Section: S E I S M I C Data a N A Ly S E Smentioning

confidence: 99%

Assessing swells in La Réunion Island from terrestrial seismic observations, oceanographic records and offshore wave models

Rindraharisaona

Cordier

Barruol

et al. 2020

Geophysical Journal International

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“…Besides their influence on ambient noise tomography, noise sources have been extensively studied with the aims of understanding their excitation mechanism (e.g., Haubrich & McCamy, 1969;Hillers et al, 2012;Juretzek & Hadziioannou, 2016;Landès et al, 2010;Stehly et al, 2006;Traer et al, 2012) and of using them as proxy for present and past ocean wave states or Antarctic sea ice cover (e.g., Aster et al, 2010;Ebeling & Stein, 2011;Donne et al, 2014;Stutzmann et al, 2009).…”

Section: Motivation Ii: Finite-frequency Noise Source Inversion With 3-d Structurementioning

confidence: 99%

Ambient Seismic Source Inversion in a Heterogeneous Earth: Theory and Application to the Earth's Hum

et al. 2017

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The sources of ambient seismic noise are extensively studied both to better understand their influence on ambient noise tomography and related techniques, and to infer constraints on their excitation mechanisms. Here we develop a gradient‐based inversion method to infer the space‐dependent and time‐varying source power spectral density of the Earth's hum from cross correlations of continuous seismic data. The precomputation of wavefields using spectral elements allows us to account for both finite‐frequency sensitivity and for three‐dimensional Earth structure. Although similar methods have been proposed previously, they have not yet been applied to data to the best of our knowledge. We apply this method to image the seasonally varying sources of Earth's hum during North and South Hemisphere winter. The resulting models suggest that hum sources are localized, persistent features that occur at Pacific coasts or shelves and in the North Atlantic during North Hemisphere winter, as well as South Pacific coasts and several distinct locations in the Southern Ocean in South Hemisphere winter. The contribution of pelagic sources from the central North Pacific cannot be constrained. Besides improving the accuracy of noise source locations through the incorporation of finite‐frequency effects and 3‐D Earth structure, this method may be used in future cross‐correlation waveform inversion studies to provide initial source models and source model updates.

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“…Whereas previous studies linking changing wave climate with secondary microseisms have mainly used seismic noise amplitudes (Anthony et al, 2017;Aster et al, 2008;Donne et al, 2014;Essen et al, 1999;Grevemeyer et al, 2000;Stutzmann et al, 2009;Turner et al, 2020), we investigate temporal changes in the relative dominance of Rayleigh surface wave modes associated with secondary microseisms, recorded both in the ocean and on land. To do so, we focus on daily vertical component cross-correlations of ambient seismic noise which enable the extraction of Rayleigh waves (Shapiro & Campillo, 2004).…”

Section: Seasonal Variations In the Secondary Microseism Wavefieldmentioning

confidence: 99%

“…In contrast to primary microseisms (10-20 s) caused by the direct interaction of ocean waves with bathymetry, secondary microseisms (3-10 s) originate from pressure fluctuations at the seafloor as a result of non-linear interactions of opposing ocean wavefronts (Hasselmann, 1963;Longuet-Higgins, 1950). Due to their generation mechanisms, the energy of secondary microseisms is closely related to ocean wave amplitudes (Bromirski et al, 1999;Donne et al, 2014), globally and through the seasons (Stutzmann et al, 2009), and has therefore been linked to climate variability (Aster et al, 2008;Grevemeyer et al, 2000). In fact, atmospheric teleconnection patterns have been associated with temporal changes in microseisms intensity, including the NAO (Essen et al, 1999) and the El Niño Southern Oscillation (Aster et al, 2008), or more recently the Southern Annular Mode (SAM) or Antarctic oscillation in the southern hemisphere (Anthony et al, 2017;Turner et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

North Atlantic Oscillation (NAO) Climate Index Hidden in Ocean Generated Secondary Microseisms

Pape

Bean

2021

Geophysical Research Letters

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Ocean waves continuously generate seismic waves at the seafloor that are observed all over the world. In this study, we show how such vibrations recorded at the seafloor offshore West of Ireland are sensitive to long term weather and climate fluctuations in the Northeast Atlantic. Combining ocean wave and seismic simulation models with observations, we show that the North Atlantic Oscillation (NAO) climate index is hidden in the seismic records. LE PAPE AND BEAN

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Wave height quantification using land based seismic data with grammatical evolution

Cited by 7 publications

References 22 publications

Assessing swells in La Réunion Island from terrestrial seismic observations, oceanographic records and offshore wave models

Assessing swells in La Réunion Island from terrestrial seismic observations, oceanographic records and offshore wave models

Ambient Seismic Source Inversion in a Heterogeneous Earth: Theory and Application to the Earth's Hum

North Atlantic Oscillation (NAO) Climate Index Hidden in Ocean Generated Secondary Microseisms

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