Emergence of the Semi-Empirical Technique of Strong Ground Motion Simulation: A Review
Authors
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Department of Geophysics, Banaras Hindu University, Varanasi - 221 005
Sandeep -
Department of Earth Sciences, Indian Institute of Technology, Roorkee
A. Joshi
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Department of Earth Sciences, Indian Institute of Technology, Roorkee
P. Kumari
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Department of Earth Sciences, Indian Institute of Technology, Roorkee
S. Lal
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Ministry of Earth Sciences, New Delhi - 110 003
Vandana
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Wadia Institute of Himalayan Geology, Dehradun - 248 001
Parveen Kumar
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Department of Earth Sciences, Indian Institute of Technology, Roorkee
Kamal
DOI:
https://doi.org/10.1007/s12594-017-0684-xAbstract
High frequency ground motion simulation techniques are powerful tools for designing earthquake resistant structures in seismically active regimes. Simulation techniques also provide the synthetic strong ground motion in the regions where actual records are not available (Kumar et al. 2015).These techniques require several parameters of earthquake and other seismic information proceeding to the simulation. Practically estimation of parameters is a tough task, particularly in a region with limited information. This demands a simulation technique based on the easily estimated parameters for a new site. The purposes of this paper are to briefly review existing simulation techniques and to discuss in detail the new, simple and effective semi-empirical technique (Midorikawa 1993) of strong motion simulation.
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Abrahamson, N.A., Litehiser, J.J. (1989) Attenuation of vertical peak acceleration. Bull. Seism. Soc. Amer., v.79, pp.549–580.
Boore, D.M. (1983) Stochastic simulation of high frequency ground motion based on seismological models of radiated Spectra. Bull. Seism. Soc. Amer., v.73, pp.1865–1894.
Boore, D.M. and Atkinson, C.M. (1987) Stochastic prediction of ground motion and spectral response parameters at hard rock sites in eastern North America. Bull. Seism. Soc. Amer., v.77, pp.440–467.
Boore DM (2003) Simulation of ground motion using the stochastic method. Pure Appld. Geophys., v.160, pp.635–676.
Boore DM, Campbell KW, Atkinson GM (2010) Determination of stress parameters for eight well-recorded earthquakes in Eastern North America. Bull. Seism. Soc. Amer., v.100, pp.1632–1645.
Campbell, K.W. (1997) Empirical near–source attenuation relationships for horizontal and vertical components of peak ground acceleration, peak ground velocity, and pseudo-absolute acceleration response spectra. Seism. Res. Lett., v.68(1), pp.154–179.
Cocco, M, and J. Boatwright (1993) The envelopes of acceleration time histories. Jour. Geophys. Res., v.83, pp.1095-1114.
Douglas, J., and Aochi, H. (2008) A survey of techniques for predicting earthquake ground motions for engineering purposes. Surv. Geophys., v.29, pp.187–220.
Fukuyama, E. and Irikura, K. (1986) Rupture process of the 1983 Japan sea (Akita-Oki) earthquake using a waveform inversion method. Bull. Seism. Soc. Amer., v.76, pp.1623–1640.
Hadley, D.M. and Helmberger, D.V. (1980) Simulation of ground motions. Bull. Seism. Soc. Amer., v.70, pp.617–630.
Hanks, T.C. and McGuire, R.K. (1981) The character of high frequency ground motion. Bull. Seism. Soc. Amer., v.71, pp.2071–2095.
Hartzell, S.H. (1978) Earthquake aftershocks as Green's functions. Geophys. Res. Lett., v.5, pp.1–4
Heaton, T.H., Hartzell, S.H. (1989) Estimation of strong ground motions from hypothetical earthquakes on the Cascadia subduction zone, Pacific Northwest. Pure Appld. Geophys., v.129, pp.131–201.
Housner, G.W., Jennings, P.C. (1964) Generation of artificial earthquakes. Proc. ASCE, v.90, pp.113–150.
Houston, H., Kanamori, H. (1984) The effect of asperities on short period seismic radiation with application on rupture process and strong motion. Bull. Seism. Soc. Amer., v.76, pp.19–42.
Hutchings, L. (1985) Modelling earthquakes with empirical Green's functions (abs). Earthquake Notes, v.56, p.14.
Irikura, K. and Muramatu, I. (1982) Synthesis of strong ground motions from large earthquakes using observed seismograms of small events. Proc. of the Third International Microzonation Conference, Seattle, pp.447–458.
Irikura, K. (1983) Semi empirical estimation of strong ground motion during large earthquakes. Bull. Dis. Prevent. Res. Inst., v.33pp.63–104.
Irikura, K. (1986) Prediction of strong acceleration motion using empirical Green's function. Proc. 7th Japan earthquake engineering symposium, pp.151–156.
Irikura, K. and Kamae, K. (1994) Estimation of strong ground motion in broad– frequency band based on a seismic source scaling model and an Empirical Green's function technique. Ann Geofis XXXVII, no.6, pp.1721–1743.
Irikura, K., Kagawa, T. and Sekiguchi, H. (1997) Revision of the empirical Green's function method by Irikura, 1986. Programme and Abstracts. Seismol. Soc. Japan, 2:B25
Joshi, A. and Patel, R.C. (1997) Modelling of active lineaments for predicting a possible earthquake scenario around Dehradun, Garhwal Himalaya, India. Tectonophysics, v.283, pp.289–310.
Joshi, A., Kumar, B., Sinvhal, A. and Sinvhal, H. (1999) Generation of synthetic accelerograms by modelling of rupture plane. Jour. Earthquake Tech., v.36, pp.43–60
Joshi, A. and Midorikawa, S. (2004) A simplified method for simulation of strong ground motion using rupture model of the earthquake source. Jour. Seismol., v.8, pp.467–484.
Joshi, A. and Mohan, K. (2008) Simulation of accelerograms from simplified deterministic approach for the 23rd October 2004 Niigata–ken Chuetsu earthquake. Jour. Seismol., v.12. pp.35–51.
Joshi, A., Kumari, P., Sharma, M.L., Ghosh, A.K., Agarwal, M.K., and Ravikiran, A. (2012a) A strong motion model of the 2004 great Sumatra earthquake: simulation using a modified semi empirical method. Jour. Earthquake and Tsunami, v.6, pp.1–29.
Joshi, A., Kumari, P., Singh, S. and Sharma, M.L. (2012b) Near–field and far–field simulation of accelerograms of Sikkim earthquake of September 18, 2011 using modified semi empirical approach. Natural Hazards, v.64, pp.1029–1054.
JOSHI, A. and SANDEEP, KAMAL (2014) Modelling of Strong Motion Generation Areas of the 2011 Tohoku, Japan earthquake using modified semi empirical technique. Natural Hazards, v.71, pp.587–609.
Kamae, K. and Irikura, K. (1992) Prediction of site specific strong ground motion using semi-empirical methods. Proc. 10th World Conference on Earthquake Engineering, pp.801–806.
Kamae, K. and Irikura, K. (1998) Source model of the 1995 Hyogo-ken Nanbuearthquake and simulation of near-source ground motion. Bull. Seism. Soc. Amer., v.88, pp.400–412.
Kameda, H. and Sugito, M. (1978) Prediction of strong earthquake motions by evolutionary process model. In: Proceedings of the sixth Japan earthquake engineering symposium. pp.41–48.
Kumar, D., Khattri, K.N., Teotia, S.S. and Rai, S.S. (1999) Modelling of accelerograms for two Himalayan earthquakes using a novel semi– empirical method and estimation of accelerogram for a hypothetical great earthquake in the Himalaya. Curr. Sci., v.76, pp.819–830.
Kumar, R., Sumathi, P. and Kumar, A. (2015) A time–frequency approach for generation of synthetic time-histories of earthquake signals Acta Geod. Geophys., v.51,pp.57.
Lai, S.P. (1982) Statistical characterization of strong ground motions u sing power spectral density function. Bull. Seism. Soc. Amer. v.72, pp.259– 274.
Midorikawa, S. and Kobayashi, H. (1978) On estimation of strong earthquake motions with regard to fault rupture. Proc. 2nd Internat. Conference on Microzonation, v.2, pp.825–836.
Midorikawa, S. (1993) Semi empirical estimation of peak ground acceleration from large earthquakes. Tectonophysics, v.218, pp.287–295
Mikumo, T., Irikura, K. and Imagawa, K. (1981) Near-field strong motion synthesis from foreshock and aftershock records and rupture process of the main shock fault (abs.). IASPEI 21st General Assembly, London
Munguia. L. and Brune, J.M. (1984) Simulations of strong ground motions for earthquakes in the Mexicali–Imperial Valley. Proc. of workshop on strong ground motion simulation and earthquake engineering applications, Pub.85–02. Earthquake Engineering Research Institute, Los Altos, California 21–1–21–19.
Sandeep, A., Joshi, Kamal, Parveen Kumar and Ashvini Kumar (2014a) Effect of frequency dependent radiation pattern in simulation of high frequency ground motion of Tohoku earthquake using modified semi empirical method. Natural Hazards, v.73, pp.1499-1521.
Sandeep, A., Joshi, Kamal, Parveen Kumar and Pushpa Kumari (2014b) Modeling of strong motion generation area of the Uttarkashi earthquake using modified semi-empirical approach. Natural Hazards, v.73, pp.2041-2066.
Sandeep, A., Joshi, Kamal, Parveen Kumar, Ashvini Kumar and Piu Dhibar (2015) Modeling of strong motion generation areas of the Niigata, Japan, earthquake of 2007 using modified semi empirical technique. Natural Hazards, v.77, pp.933-957.
Somerville, P.G., Sen, M.K. and Cohee, B.P. (1991) Simulation of strong ground motions recorded during the 1985 Michoacan, Mexico and Valparaiso Chile earthquakes. Bull. Seism. Soc. Amer., v.81, pp.1–27.
Yu G, KhattriKN, Anderson JG, Brune JN, Zeng Y (1995) Strong ground motion from the Uttarkashi, Himalaya, India, earthquake: Comparison of observations with synthetics using the composite source model. Bull. Seism. Soc. Amer., v.85, pp.31–50.
Yu G (1994) Some aspects of earthquake seismology: slip partitioning along major convergent plate boundaries; composite source model for estimation of strong motion; and nonlinear soil response modeling. Ph.D. thesis, University of Nevada.
Zeng, Y., Anderson, J.G. and Su, F. (1994) A composite source model for computing realistic synthetic strong ground motions. Geophys. Res. Lett., v.21, pp.725–728.
