Effect of Ground Motion Modification Technique on Seismic Geotechnical Engineering Analyses

Zekkos, Dimitrios; Carlson, Clinton; Nisar, Ahmed; Ebert, Stephanie

doi:10.1193/1.4000077

Cited by 7 publications

(5 citation statements)

References 17 publications

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“…In some cases, large changes in ground motion characteristics have been observed, cautioning against the use of spectral matching in engineering practice (Naeim and Lew 1995). In other cases, the impact of spectral matching on ground motion characteristics has been found to vary from minimal to significant (Zekkos et al 2012, Gascot and Montejo 2014). Overall, the impact of spectral matching on a seed ground motion, as reported by Carlson et al (2014b), is known to be affected by (a) the relative shape and amplitude of the acceleration response spectrum of the seed ground motion to the target spectrum, (b) the seed ground motion itself and its characteristics, (c) the ground motion characteristic of interest (e.g., Arias intensity versus peak ground velocity), and (d) the technique (i.e., the mathematical manipulations) used for modification (e.g., TD versus FD).…”

Section: Brief Review Of Spectral Matching Procedures In Practicementioning

confidence: 99%

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Predictive Equations to Quantify the Impact of Spectral Matching on Ground Motion Characteristics

Carlson

Zekkos

Athanasopoulos-Zekkos

2016

Earthquake Spectra

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Spectral matching, the process of modifying a seed acceleration time history in intensity and frequency content until its acceleration response spectrum matches a target spectrum, is used extensively in practice. Predictive equations that quantify the impact of spectral matching on the peak ground velocity, peak ground displacement, Arias intensity, and cumulative absolute velocity of a scaled seed time history have been developed and validated on the basis of thousands of matched motions, three different earthquake scenarios, and numerous target spectra. It is found that spectral mismatch is the most critical factor affecting the changes in ground motion characteristics. The technique used for modification (e.g., time domain or frequency domain) is in many cases not critical. Based on the results, recommendations in order to minimize the impact of matching on the ground motion characteristics are provided.

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Section: Brief Review Of Spectral Matching Procedures In Practicementioning

confidence: 99%

“…Spectral matching is also used when three-component ground motions are needed for dynamic analyses or spectrum compatible ground motions are required by regulations. The numerous advantages of spectral matching compared to other approaches (such as scaling of motions or use of synthetic motions) have been outlined by Zekkos et al 2012.…”

Section: Introductionmentioning

confidence: 99%

Predictive Equations to Quantify the Impact of Spectral Matching on Ground Motion Characteristics

Carlson

Zekkos

Athanasopoulos-Zekkos

2016

Earthquake Spectra

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“…al., 2018). In some cases, major changes were noticed (Naeim and Lew, 1995), and in others the effect could vary from minor to significant (Zekkos et. al., 2012;Gascot and Montejo, 2016).…”

Section: Introductionmentioning

confidence: 99%

Spectral Matching of Three-Component Seismic Ground Accelerations for Nuclear Power Plants

Mangkoesoebroto

Zulkifli

Yasa

2021

Preprint

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The aim of the paper is to introduce a new procedure of three-component spectral matching of seismic ground acceleration records. The procedure is straightforward, yet it is general. In principle, the procedure involves varying of both the Fourier amplitude and the phase spectra so that the modified records’ spectra agree with a target. The matching can be performed against either a target Fourier or response spectra. In the former the solution is exact, while in the latter it becomes approximate. A target spectrum representative of three directions should be provided. In the example several three-component records were matched against two target spectra. Good convergence was achieved in velocity and displacement records so that no baseline correction was necessary. The couplings among the components were preserved.

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“…For earthquake scenarios where recorded ground motions are either not available or the spectra of the available motions do not resemble the target spectrum, ground motion modification becomes a useful alternative. Additional advantages of spectral matching over other approaches (such as scaling of motions or use of synthetic motions) have been discussed in Zekkos et al (2012).…”

Section: Introductionmentioning

confidence: 99%

“…Altering the frequency content of the seed motion during ground motion modification can significantly change its velocity and displacement time histories (Naeim and Lew 1995, Hancock et al 2006, Zekkos et al 2012). Therefore, the characteristics and time histories of the modified ground motion must be carefully examined after modification to decide if the modified motion is acceptable or has undergone an unacceptable amount of change relative to the seed ground motion.…”

Section: Introductionmentioning

confidence: 99%

A Metric to Screen Acceptable Velocity and Displacement Time Histories of Modified Ground Motions

Carlson

Zekkos

2017

Earthquake Spectra

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Ground motion modification is extensively used in practice to modify a seed acceleration time history in intensity and frequency content until its acceleration response spectrum matches a target spectrum. However, the decision to accept or reject a modified motion commonly relies on a subjective process where the time histories of the modified motion are visually compared to those of the seed motion. Various metrics were used to quantify the similarity between the modified time histories and their scaled counterparts for hundreds of modified ground motions from three different earthquake scenarios. Of the metrics considered, the inverse modified RMSE metric for time histories ( imRMSE t) was found most appropriate as it resulted in the least amount of dispersion in the goodness-of-fit values with respect to spectral mismatch. The imRMSE t was then found to be correlated to qualitative rankings assigned to the modified time histories through a visual assessment. The correlation between the quantitative imRMSE t values and qualitative rankings is used to establish threshold values to screen modified velocity and displacement time histories that are likely acceptable or likely unacceptable.

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Effect of Ground Motion Modification Technique on Seismic Geotechnical Engineering Analyses

Cited by 7 publications

References 17 publications

Predictive Equations to Quantify the Impact of Spectral Matching on Ground Motion Characteristics

Predictive Equations to Quantify the Impact of Spectral Matching on Ground Motion Characteristics

Spectral Matching of Three-Component Seismic Ground Accelerations for Nuclear Power Plants

A Metric to Screen Acceptable Velocity and Displacement Time Histories of Modified Ground Motions

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