Randomly distributed unit sources to enhance optimization in tsunami waveform inversion

Mulia, Iyan E.; Asano, Toshiyuki

doi:10.5194/nhess-15-187-2015

Cited by 12 publications

(14 citation statements)

References 24 publications

(29 reference statements)

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“…Without using earthquake fault parameters, initial sea surface elevation in the source region can be estimated by inversion of tsunami waveforms [Satake et al, 2005;Saito et al, 2010;Hossen et al, 2015;Mulia and Asano, 2015]. A combination of genetic algorithm (GA) methods for tsunami source inversion Asano, 2015, 2016] is used in this study to determine the initial sea surface elevation in the source region of the 2012 Haida Gwaii earthquake.…”

Section: Genetic Algorithm To Estimate the Initial Sea Surface Elevationmentioning

confidence: 99%

“…Unlike most of other tsunami inversion techniques that fix the distribution of unit sources (Figure 2a), our GA uses the least squares method iteratively to find the optimal number and distribution of unit sources. In the second stage, the GA adjusts the locations of the selected unit sources from the first stage in order to further improve the waveform fit [Mulia and Asano, 2015]. This leads to a reduction of the unit sources because the GA removes any unit source that has similar information in terms of surface height from the adjacent source points (black dots in Figure 2b) [Mulia and Asano, 2016].…”

Section: Genetic Algorithm To Estimate the Initial Sea Surface Elevationmentioning

confidence: 99%

“…We quantify the waveform fit based on a combination of root-mean-square error (RMSE) and Pearson correlation coefficient (r) [Mulia and Asano, 2015] (see Supporting Information S1). We quantify the waveform fit based on a combination of root-mean-square error (RMSE) and Pearson correlation coefficient (r) [Mulia and Asano, 2015] (see Supporting Information S1).…”

Section: Cost Functionmentioning

confidence: 99%

“…For every new location of unit source, synthetic tsunami waveforms at the stations are computed by applying nearest neighbor-weighted interpolation of waveforms from four nearest initial unit sources [Mulia and Asano, 2015]. For every new location of unit source, synthetic tsunami waveforms at the stations are computed by applying nearest neighbor-weighted interpolation of waveforms from four nearest initial unit sources [Mulia and Asano, 2015].…”

Section: Synthetic Tsunami Waveformsmentioning

confidence: 99%

See 3 more Smart Citations

Estimate of tsunami source using optimized unit sources and including dispersion effects during tsunami propagation: The 2012 Haida Gwaii earthquake

Gusman

Mulia

Satake

et al. 2016

Geophysical Research Letters

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We apply a genetic algorithm to find the optimized unit sources using dispersive tsunami synthetics to estimate the tsunami source of the 2012 Haida Gwaii earthquake. The optimal number and distribution of unit sources gives the sea surface elevation similar to that from our previous slip distribution on a fault using tsunami data, but different from that using seismic data. The difference is possibly due to submarine mass failure in the source region. Dispersion effects during tsunami propagation reduce the maximum amplitudes by up to 20% of conventional linear longwave propagation model. Dispersion effects also increase tsunami travel time by approximately 1 min per 1300 km on average. The dispersion effects on amplitudes depend on the azimuth from the tsunami source reflecting the directivity of tsunami source, while the effects on travel times depend only on the distance from the source.

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Section: Genetic Algorithm To Estimate the Initial Sea Surface Elevationmentioning

confidence: 99%

Section: Genetic Algorithm To Estimate the Initial Sea Surface Elevationmentioning

confidence: 99%

Section: Cost Functionmentioning

confidence: 99%

Section: Synthetic Tsunami Waveformsmentioning

confidence: 99%

See 2 more Smart Citations

Estimate of tsunami source using optimized unit sources and including dispersion effects during tsunami propagation: The 2012 Haida Gwaii earthquake

Gusman

Mulia

Satake

et al. 2016

Geophysical Research Letters

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“…Liu and Wang, 2008;Saito and Furumura, 2009;Saito et al, 2011;Tsushima et al, 2014;Mulia and Asano, 2015), pyramidal (Zaibo et al, 2003), conical or circular with positive elevation in the centre and negative at the edge (Choi et al, 2005;Zaitsev and Pelinovsky , 2011), rectangular prisms (Miranda et al, 2014) or cosine-tapered (Hossen et al, 2015) ES. The approach has been proposed in retrospective for rapid near-field forecasting of the Tohoku 2011 tsunami with tFISH/RAPiD (Tsushima et al, 2014), for PTHA (Selva et al, 2016) and for source inversion (Liu and Wang, 2008;Saito et al, 2011;Mulia and Asano, 2015;Hossen et al, 2015). However, such an approach has never been fully validated by a systematic assessment of the uncertainties that it introduces in the tsunami modelling or forecasting.…”

Section: Introductionmentioning

confidence: 99%

Fast evaluation of tsunami scenarios: uncertainty assessment for a Mediterranean Sea database

Molinari

Tonini

Lorito

et al. 2016

Nat. Hazards Earth Syst. Sci.

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Abstract. We present a database of pre-calculated tsunami waveforms for the entire Mediterranean Sea, obtained by numerical propagation of uniformly spaced Gaussian-shaped elementary sources for the sea level elevation. Based on any initial sea surface displacement, the database allows the fast calculation of full waveforms at the 50 m isobath offshore of coastal sites of interest by linear superposition. A computationally inexpensive procedure is set to estimate the coefficients for the linear superposition based on the potential energy of the initial elevation field. The elementary sources size and spacing is fine enough to satisfactorily reproduce the effects of M > = 6.0 earthquakes. Tsunami propagation is modelled by using the Tsunami-HySEA code, a GPU finite volume solver for the non-linear shallow water equations. Like other existing methods based on the initial sea level elevation, the database is independent on the faulting geometry and mechanism, which makes it applicable in any tectonic environment. We model a large set of synthetic tsunami test scenarios, selected to explore the uncertainty introduced when approximating tsunami waveforms and their maxima by fast and simplified linear combination. This is the first time to our knowledge that the uncertainty associated to such a procedure is systematically analysed and that relatively small earthquakes are considered, which may be relevant in the near-field of the source in a complex tectonic setting. We find that non-linearity of tsunami evolution affects the reconstruction of the waveforms and of their maxima by introducing an almost unbiased (centred at zero) error distribution of relatively modest extent. The uncertainty introduced by our approximation can be in principle propagated to forecast results. The resulting product then is suitable for different applications such as probabilistic tsunami hazard analysis, tsunami source inversions and tsunami warning systems.

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Initial tsunami source estimation by inversion with an intelligent selection of model parameters and time delays

Mulia

Asano

2016

JGR Oceans

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We propose a method for accurately estimating the initial tsunami source. Our technique is independent of the earthquake parameters, because we only use recorded tsunami waveforms and an auxiliary basis function, instead of a fault model. We first use the measured waveforms to roughly identify the source area using backward propagated travel times, and then infer the initial sea surface deformation through inversion analysis. A computational intelligence approach based on a genetic algorithm combined with a pattern search was used to select appropriate least squares model parameters and time delays. The proposed method significantly reduced the number of parameters and suppressed the negative effect of regularization schemes that decreased the plausibility of the model. Furthermore, the stochastic approach for deriving the time delays is a more flexible strategy for simulating actual phenomena that occur in nature. The selected parameters and time delays increased the accuracy, and the model's ability to reveal the underlying physics associated with the tsunami‐generating processes. In this paper, we applied the method to the 2011 Tohoku‐Oki tsunami event and examined its effectiveness by comparing the results to those using the conventional method.

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Randomly distributed unit sources to enhance optimization in tsunami waveform inversion

Cited by 12 publications

References 24 publications

Estimate of tsunami source using optimized unit sources and including dispersion effects during tsunami propagation: The 2012 Haida Gwaii earthquake

Estimate of tsunami source using optimized unit sources and including dispersion effects during tsunami propagation: The 2012 Haida Gwaii earthquake

Fast evaluation of tsunami scenarios: uncertainty assessment for a Mediterranean Sea database

Initial tsunami source estimation by inversion with an intelligent selection of model parameters and time delays

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