A Bayesian Approach to Microtremor Array Methods for Estimating Shallow <i>S</i> Wave Velocity Structures: Identifying Structural Singularities

Cho, Ikuo; Iwata, T.

doi:10.1029/2018jb015831

Cited by 14 publications

(6 citation statements)

References 63 publications

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“…By the use of the sets of the two parameters (radius and NSR) given in Section 4, we can obtain a relation between the array radius and the NSR at the ULF as shown in Figure 10. The figure shows that NSRs generally decrease with the decrease of the array radii, supporting our experiences: we have had very small values of NSR (e.g.,

ε 〈 10^{- 3}

) when we use very small arrays with radii about 1 m (e.g., Cho, 2020; Cho & Iwata, 2019; Cho et al., 2018, 2013). In such cases, we can treat long wavelength ranges reaching several tens of an array radius or more by the SPAC method.…”

Section: Discussionsupporting

confidence: 82%

“…The readers can refer to Tada et al (2007) and Cho (2018) for the technical details, including practical problems, of the compensation of the incoherent noise. Also, note that the value of NSR,  , can be used to determine the ULW as demonstrated in our previous papers (Cho & Iwata, 2019;Cho et al, 2013).…”

Section: Formula For the Evaluation Of Nsr And Noise Compensationmentioning

confidence: 91%

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Limits and Benefits of the Spatial Autocorrelation Microtremor Array Method Due to the Incoherent Noise, With Special Reference to the Analysis of Long Wavelength Ranges

Cho

Iwata

2021

JGR Solid Earth

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Microtremor array surveys determine Rayleigh wave phase velocity to infer the subsurface velocity structures (e.g., Okada, 2003). The spatial autocorrelation (SPAC) method of Aki (1957) is a technique that has been most popularly used to determine phase velocities (Okada, 2003). In earthquake engineering, the demands of microtremor surveys have been increasing year by year, because of their cost-effectiveness, so the demands of the SPAC method have. The analyzable wavelength ranges of the SPAC method, as those of the other methods do, generally depend on array size. The motivation of this study is that, albeit the markedly increasing popularity, the upper limit of the analyzable wavelength ranges (upper limit wavelength, ULW) of the SPAC method has not been clearly identified yet. For example, Foti et al. (2017) state that, "there is no clear maximum wavelength criterion" for the SPAC method and that it is "not recommended to try and extract wavelengths greater than 2-3 times the maximum aperture of the passive array" (i.e., their recommendation is the ULWs from 4r to 6r, where r means array radius). In this study, we first describe what is the signal and noise in microtremor records in Section 2. This is a premise for detailed examinations, as well as a help to interpret the analysis results in the later sections. In Section 3, we present a theory for determining and evaluating a crucial factor for the ULW of the SPAC method. In Section 4, we validate our theory based on field data. Finally, inspired by the results of these sections, we discuss and examine the relation between noise-to-signal ratio (NSR) and the distance between seismic sensors for novel use of the SPAC method to evaluate the attenuation of soils (Section 5). Each of these three sections details the effects of the incoherent noise on the SPAC analysis in long wavelength ranges and collectively constitutes the main subject.

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ε 〈 10^{- 3}

Section: Discussionsupporting

confidence: 82%

Section: Formula For the Evaluation Of Nsr And Noise Compensationmentioning

confidence: 91%

Limits and Benefits of the Spatial Autocorrelation Microtremor Array Method Due to the Incoherent Noise, With Special Reference to the Analysis of Long Wavelength Ranges

Cho

Iwata

2021

JGR Solid Earth

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“…In addition, a miniature array was arranged without a center point. The center point of a miniature array is used to evaluate the SNR, based on which the analysis limits are evaluated and noise compensation is performed (e.g., Cho & Iwata, 2019). Therefore, the center point is not necessary if only the standard SPAC method is applied.…”

Section: Simplification Of Small Arraymentioning

confidence: 99%

“…This means that an inverted velocity structure model can be easily assumed from the corresponding dispersion curve, so we do not discuss the inversion results here. Readers interested in case‐specific techniques can refer to our previous studies (Cho, 2023; Cho & Iwata, 2019; Cho et al., 2021) and refer to Supporting Information for the individual analysis results presented in this study.…”

Section: Field Examplesmentioning

confidence: 99%

Shallow Microtremor Array Survey Using Miniature and Small Arrays: Strategy for Efficient and Feasible Dense Survey

Cho,

Nakazawa

2024

Earth and Space Science

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We investigated the applicability of miniature microtremor arrays with a radius of a few meters or less to shallow surveys (up to a few tens of meters). It is shown that the upper limit wavelength normalized by the seismometer separation distance s that is analyzable by a miniature array does not depend on the observation instrument as long as the instrument has a self‐noise level that is sufficiently lower than the microtremor intensities; however, it generally depends on the average S‐wave velocity of the ground. This means that a miniature array is useful at soft‐soil sites but not hard‐soil sites. A statistical study in central Japan showed that the penetration depth by a miniature array with s = 1 m ranges from 6 to 12 m; specifically, the depth exceeds 12 m in one quarter of the cases but remains below 6 m in one quarter of the cases. This large variation is due to the variation in the average S‐wave velocity. A miniature array should thus be used in combination with a larger array with an s value of several meters to 20 m. In urbanized areas with high industrial activity, where the microtremor wavefield is likely isotropic, these arrays can be replaced by a linear array. In environments with extremely low signal‐to‐noise ratios, a less efficient zero‐crossing method should be applied to the larger array. An appropriate observation strategy should be selected for a given geoenvironment. Field examples show that our strategy enables efficient and feasible dense surveys.

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“…Therefore, we constructed an initial model empirically [Ballard Jr, 1964]. The initial models (number of layers and Vs) is updated by an empirical Bayesian approach [Cho and Iwata, 2019] to better explain the phase velocity dispersion curve. It enables flexible modeling of shallowto-deep structure by automatically determining the number of layers based on the Bayes…”

Section: Analysis Of Large Array Datamentioning

confidence: 99%

Shallow Subsurface Structure in the Hualien Basin and Relevance to the Damage Pattern and Fault Rupture during the 2018 Hualien Earthquake

Yamada

Cho

Kuo

et al. 2020

Bulletin of the Seismological Society of America

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The 2018 Mw 6.4 Hualien earthquake generated a large peak-to-peak velocity of over 2 m/s, with a period of 3 s at the south end of the Milun fault, which resulted in the collapse of five buildings. To investigate the shallow subsurface soil structure and evaluate possible effects on the ground motion and building damage, we performed microtremor measurements in the Hualien basin. Based on the velocity structure jointly inverted from both Rayleigh-wave dispersion curves and microtremor horizontal-to-vertical spectral ratio data, we found that the shallow subsurface structure generally deepens from west to east. Close to the Milun fault, the structure becomes shallower, which is consistent with faulting during the 2018 earthquake and the long-term tectonic displacement. There is no significant variation for the site conditions in the north–south direction that can explain the large peak ground velocity in the south. As a result of the dense measurements in the heavily damaged area, where three high-rise buildings totally collapsed, these locations have the average S-wave velocity of the upper 30 m (AVS30) values and are relatively high compared to the more distant area from the Meilun River. This is somewhat unusual, because lower AVS30 values indicating softer ground conditions are expected close to the river. We did not find any characteristic subsurface soil structure that may contribute to the building collapses. The large 3 s pulse was probably generated by source effects, rather than subsurface soil amplification.

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A Bayesian Approach to Microtremor Array Methods for Estimating Shallow S Wave Velocity Structures: Identifying Structural Singularities

Cited by 14 publications

References 63 publications

Limits and Benefits of the Spatial Autocorrelation Microtremor Array Method Due to the Incoherent Noise, With Special Reference to the Analysis of Long Wavelength Ranges

Limits and Benefits of the Spatial Autocorrelation Microtremor Array Method Due to the Incoherent Noise, With Special Reference to the Analysis of Long Wavelength Ranges

Shallow Microtremor Array Survey Using Miniature and Small Arrays: Strategy for Efficient and Feasible Dense Survey

Shallow Subsurface Structure in the Hualien Basin and Relevance to the Damage Pattern and Fault Rupture during the 2018 Hualien Earthquake

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