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Assessment of permanent drift demands in steel moment-resisting steel buildings due to recorded near-fault forward directivity earthquake ground motions and velocity pulse models
Jorge Ruiz-García, José M. Ramos Cruz
Structures 27: 1260-1273; 
https://doi.org/10.1016/j.istruc.2020.07.035
This paper presents the main results of an investigation focused on evaluating the height-wise distribution and amplitude of permanent interstorey drift, RIDR, demands of four case-study steel moment-resisting frames subjected to near-fault earthquake ground motions having forward-directivity effects (NF-FD) with increasing seismic intensity. To provide a context, maximum (transient) interstorey drift, IDR, demands were also computed as part of this study. Examining the results from nonlinear time-history analyses revealed that the case-study building models exhibited a recentering behaviour under NF-FD earthquake records, which means that the amplitude of RIDR at specific stories decreases with respect to the amplitude reached at a lower ground motion intensity. Scatter plots of maximum RIDR and IDR demands, and vice versa, revealed that both response parameters follow a nonlinear trend, which it can be approximated by a power functional form. Additionally, the ability of two velocity pulse analytical models introduced in the literature to estimate RIDR demands was also examined in this investigation. It was observed that both velocity pulse models lead to a different amplitude of RIDR demands computed from recorded earthquake ground motions; however, those equivalent pulses are adequate for estimating IDR drift demands as noted in previous studies. presenta las bases para evaluar la resiliencia Assessment of permanent drift demands in steel moment-resisting steel buildings due to recorded near-fault forward directivity earthquake ground motions and velocity pulse models 
Observations of Rayleigh waves in Mexico City Valley during the 19 September 2017 Puebla–Morelos, Mexico earthquake
Pablo Heresi, Jorge Ruiz-García, Omar Payán-Serrano, Eduardo Miranda, 
Earthquake Spectra 2020, SAGE Publ.
DOI: 10.1177/8755293020942547
This article discusses the principal features of Rayleigh surface waves generated by basin-edge effects in Mexico City during the Mw7.1 19 September 2017 Puebla– Morelos, Mexico earthquake. Rayleigh waves were extracted from ground motions recorded at 12 stations in Mexico City. We used a recently proposed method for extracting surface waves, where the earthquake record is filtered based on the normalized inner product of the Stockwell transform of the three-component earthquake recordings. Results of this study reveal that basin-edge effects produced strong Rayleigh waves, particularly at certain stations, with frequencies that are mainly between 0.2 and 0.9 Hz, which is consistent with previous frequency ranges reported in the literature. Evidence of higher-mode Rayleigh waves was found at all stations located on soft soil sites, even at stations that are more than 1 km away from the basin edges. It was also observed that peak acceleration spectral ordinates of the retrograde component of the extracted Rayleigh waves at two stations exceeded the design spectral ordinates of the 1976 and 2004 editions of the Mexico City Seismic Provisions.
Examination of the vertical earthquake ground motion component during the September 19, 2017 (Mw=7.1) earthquake in Mexico City 
Jorge Ruiz-García
Soil Dynamics and Earthquake Engineering 2018, 110: 13-17
https://doi.org/10.1016/j.soildyn.2018.03.029
This technical note aims at investigating the earthquake ground motion and spectral features of the vertical component motions recorded at soft soil sites in Mexico City during the strong September 19, 2017 Puebla- Morelos (Mw =7.1) earthquake by means of examining ground motion (EQGM) features, vertical-to-horizontal (V/H) spectral ratios, and comparison with design spectra ordinates. EQGM features of vertical components recorded at 10 accelerographic stations revealed that they have shorter mean periods than their corresponding horizontal components, and long significant duration. In addition, V/H spectral ratios are larger than one in 6 stations for periods of vibrations between 0.22 s and 0.56s. Mean V/H ratios confirmed that the trend depends on the period of vibration and the vertical component could be more important for short-period structures than medium-to-long period structures. Since current Mexico City seismic regulations do not include recommendations to account for the vertical component, it is showed that the simple rule of reducing the horizontal acceleration design spectrum prescribed in the recently released 2017 Mexico City seismic regulations by 2/3 is enough to cover the mean+one-standard deviation vertical acceleration response spectrum.
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