Long-Period Building Response to Earthquakes in the San Francisco Bay Area

Olsen, Anna H.; Aagaard, Brad T.; Heaton, Thomas H.

doi:10.1785/0120060408

Cited by 19 publications

(7 citation statements)

References 24 publications

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“…The spectral acceleration level at which structural response becomes unbounded is the collapse capacity of the building. Finally, the emergence of rupture-to-rafters simulations [24] has led to extensive investigations on the performance of tall steel moment frame buildings under large simulated earthquakes in Los Angeles, San Francisco, and Seattle (e.g., [21,30,43,29]). …”

Section: Introductionmentioning

confidence: 99%

Sensitivity of the Earthquake Response of Tall Steel Moment Frame Buildings to Ground Motion Features

Krishnan¹,

Muto²

2013

Journal of Earthquake Engineering

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The seismic response of two tall steel moment frame buildings and their variants is explored through parametric nonlinear analysis using idealized sawtooth-like ground velocity waveforms, with a characteristic period (T ), amplitude (peak ground velocity, P GV ), and duration (number of cycles, N ).Collapse-level response is induced only by long-period, moderate to large P GV ground excitation.This agrees well with a simple energy balance analysis. The collapse initiation regime expands to lower ground motion periods and amplitudes with increasing number of ground motion cycles.

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Section: Introductionmentioning

confidence: 99%

Sensitivity of the Earthquake Response of Tall Steel Moment Frame Buildings to Ground Motion Features

Krishnan¹,

Muto²

2013

Journal of Earthquake Engineering

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“…For example, Ariga et al (2006) studied the resonant behavior of base-isolated high-rise buildings in terms of longterm ground motion, and Olsen et al (2008) also investigated long-term building responses. Deb (2004), Dicleli and Buddaram (2007), Casciati and Hamdaoui (2008), Di Egidio and Contento (2010) also have made progress in the study of isolated building systems.…”

Section: Introductionmentioning

confidence: 99%

Effects of Isolation Period Difference and Beam-Column Stiffness Ratio on the Dynamic Response of Reinforced Concrete Buildings

Chun¹,

Hur

2015

International Journal of Concrete Structures and Materials

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This study analyzed the isolation effect for a 15-story reinforced concrete (RC) building with regard to changes in the beam-column stiffness ratio and the difference in the vibration period between the superstructure and an isolation layer in order to provide basic data that are needed to devise a framework for the design of isolated RC buildings. First, this analytical study proposes to design RC building frames by securing an isolation period that is at least 2.5 times longer than the natural vibration period of a superstructure and configuring a target isolation period that is 3.0 s or longer. To verify the proposed plan, shaking table tests were conducted on a scaled-down model of 15-story RC building installed with laminated rubber bearings. The experimental results indicate that the tested isolated structure, which complied with the proposed conditions, exhibited an almost constant response distribution, verifying that the behavior of the structure improved in terms of usability. The RC building's response to inter-story drift (which causes structural damage) was reduced by about one-third that of a non-isolated structure, thereby confirming that the safety of such a superstructure can be achieved through the building's improved seismic performance.

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“…Base isolator with hardening behaviour under increasing loading has been developed for medium-rise buildings and sites with moderate earthquake risk (Pocanschi, Phocas 2007). Resonant behaviour of base-isolated high-rise buildings under long-period ground motions was dealt with by Ariga et al (2006) and for long period building responses by Olsen et al (2008). Wilkinson and Hiley (2006) presented a non-linear response history model for the seismic analysis of high-rise framed buildings.…”

Section: Introductionmentioning

confidence: 99%

Efficient Design in Building Construction With Rubber Bearing in Medium Risk Seismicity: Case Study and Assessment

Islam

Ahmad

Jumaat

et al. 2014

Journal of Civil Engineering and Management

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Earthquakes pose tremendous threats to life, property and a country's economy, not least due to their capability of destroying buildings and causing enormous structural damage. The hazard from ground excitations should be properly assessed to mitigate their action on building structures. This study is concerned with medium risk seismic regions. Specifically, the heavily populated capital city Dhaka in Bangladesh has been considered. Recent earthquakes that occurred inside and very close to the city have manifested the city's earthquake sources and vulnerability. Micro-seismicity data supports the existence of at least four earthquake source points in and around Dhaka. The effects of the earthquakes on buildings are studied for this region. Rubber base isolation is selected as an innovative option to lessen seismic loads on buildings. Case studies have been carried out for fixed and isolated based multi-storey buildings. Lead rubber bearing and high damping rubber bearing have been designed and incorporated in building bases. Structural response behaviours have been evaluated through static and dynamic analyses. For the probable severe earthquake, rubber bearing isolation can be a suitable alternative as it mitigates seismic effects, reduces structural responses and provides structural and economic benefits.

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Long-Period Building Response to Earthquakes in the San Francisco Bay Area

Cited by 19 publications

References 24 publications

Sensitivity of the Earthquake Response of Tall Steel Moment Frame Buildings to Ground Motion Features

Sensitivity of the Earthquake Response of Tall Steel Moment Frame Buildings to Ground Motion Features

Effects of Isolation Period Difference and Beam-Column Stiffness Ratio on the Dynamic Response of Reinforced Concrete Buildings

Efficient Design in Building Construction With Rubber Bearing in Medium Risk Seismicity: Case Study and Assessment

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