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VolF11Šª
”NF 2002”N
•ÅF 621-626•Å
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ŒfÚŽGŽi‰pjF THE EARTHQUAKE ENGINEERING SYMPOSIUM PROCEEDINGS
’˜ŽÒi‰pjF Nobuoto Nojima, Masata Sugito, Mitsuo Yamane
ƒ^ƒCƒgƒ‹i‰pjF STOCHASTIC RESPONSE SPECTRA OF EARTHQUAKE MOTION PREDICTION MODEL BASED ON RANDOM VIBRATION THEORY
´˜^i‰pjF This study presents a probabilistic method to prescribe response spectra for the earthquake motion pre-diction model (EMPR) 1) based on the random vibration theory. The EMPR model generates ground motions for given fault parameters such as magnitude and hypocentral distance (model I) or more detailed parameters (model II). Because of the stochastic nature of sample ground motions, it is appropriate to evaluate the maximum structural response in a probabilistic manner. In this study, theoretical distribu-tions of acceleration response spectra have been derived in the form of RMS response multiplied by peak factors. Numerical examples suggest that the theoretical distributions agree with simulated ones.
ƒL[ƒ[ƒhi‰pjF response spectra, earthquake motion prediction model, evolutionary spectrum, random vibration theory, RMS response, peak factor
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