Расширенный поиск
МОДЕЛИРОВАНИЕ СИЛЬНЫХ ДВИЖЕНИЙ ГРУНТА ПРИ ОЦЕНКАХ СЕЙСМИЧЕСКИХ ПОТЕРЬ ДЛЯ ГОРОДСКИХ ТЕРРИТОРИЙ В РЕГИОНАХ С НЕДОСТАТОЧНЫМ КОЛИЧЕСТВОМ ЗАПИСЕЙ СИЛЬНЫХ ДВИЖЕНИЙ: ВЫБОР МОДЕЛЕЙ КОРРЕЛЯЦИИ
1 Геофизический институт
2 Технологический институт, Германия
2 Технологический институт, Германия
Журнал: Вопросы инженерной сейсмологии
Том: 40
Номер: 3
Год: 2013
Страницы: 5-22
Ключевые слова: оценки сейсмических потерь, случайные отклонения, корреляция сильных движений грунта, единичное землетрясение
Аннотация: МОДЕЛИРОВАНИЕ СИЛЬНЫХ ДВИЖЕНИЙ ГРУНТА ПРИ ОЦЕНКАХ СЕЙСМИЧЕСКИХ ПОТЕРЬ ДЛЯ ГОРОДСКИХ ТЕРРИТОРИЙ В РЕГИОНАХ С НЕДОСТАТОЧНЫМ КОЛИЧЕСТВОМ ЗАПИСЕЙ СИЛЬНЫХ ДВИЖЕНИЙ: ВЫБОР МОДЕЛЕЙ КОРРЕЛЯЦИИ
Список литературы: Афанасьева В. Онтология научной неопределенности. 2008. Режим доступа: http://vera-afanasyeva.ru/?p=269
Соколов В.Ю. О моделировании пространственного распределения сильных движений грунта при оценках сейсмической опасности и риска // Вопросы инженерной сейсмологии. 2012. Т. 39, № 2. С. 5-22.
Соколов В.Ю., Венцель Ф. Корреляция сильных движений грунта и ее влияние на оценки сейсмической опасности для протяженных объектов // Вопросы инженерной сейсмологии. 2011. Т. 38, № 4. С. 5-15.
Чернов Ю.К. Сильные движения грунта и количественная оценка сейсмической опасности территорий. Ташкент: Фан, 1989. 295 с.
Abrahamczyk L., Langhammer T., Schwarz J. Earthquake regions in Germany - a statistical evaluation// Bautechnik. 2005. V. 82(8). P. 500-507. doi: 10.1002/bate.200590166
Amstein S., Lang D.H., Schwarz J. Shaking effects of historical earthquakes and novel applications in the scientific field of earthquake engineering // Bautechnik. 2005. V. 82(9). P. 641-655. doi: 10.1002/bate.200590194 (in German).
Anderson J., Hough S. A model for the shape of the Fourier amplitude spectrum of acceleration at high frequencies // Bull. Seism. Soc. Amer. 1984. V. 74(5). P. 1969-1993.
Bal I.E., Bommer J.J., Stafford P.J., Crowley H., Pinho R. The influence of geographical resolution of urban exposure data in an earthquake loss model for Istanbul // Earthq. Spectra. 2010. V. 26(3). P. 619-634. doi: 10.1193/1.3459127.
Brune J.N. Tectonic stress and the spectra of seismic shear waves from earthquakes // J. Geoph. Res. 1970. V. 75. P. 4997-5009.
Brune J.N. Correction // J. Geoph. Res. 1971. V. 76. P. 5002.
Brüstle W., Stange S. Geologische Untergrundklassen zum Entwurf von Normspektren für DIN 4149 (neu) // Landesamt für Geologie, Rohstoffe und Bergbau Baden-Württemberg Freiberg i. Br. Juli. 1999.
Chernov Y., Sokolov V. Correlation of seismic intensity with Fourier acceleration spectra // Phys. and Chem. of the Earth. Pt. A. Solid Earth and Geodesy. 1999. V. 24(6). P. 522-528.
DIN 4149. Bauten in Deutschen Erdbebengebieten-Lastannahmen bemessung und ausführung üblicher Hochbauten. Vorgesehen als Ersatz für DIN 4149-1:1981-04 und DIN 4149-1/A1:1992-12. Normenausschuss in Bauwesen (NADau) im DIN Deutsches Institut für Normung e.V. Berlin, 2005.
Du W., Wang W. Intra-event spatial correlations for cumulative absolute velocity, Arias intensity, and spectral accelerations based on regional site conditions // Bull. Seism. Soc. Amer. V. 103(2). P. 1117-1129. doi: 10.1785/0120120185.
Feskova T. Earthquake ground motion modeling for South-West Germany: Diploma Thesis. KIT, 2010.
Fiedler G. Die Erdbebentätigkeit in Südwestdeutschland in den Jahren 1800-1950: Doktorarbeit. Stuttgart, 1954.
Gisler M., Schwarz-Zanetti G., Fäh D., Masciadri M., Rippmann D. The 1356 Basel earthquake from a historical point of view: old wine in new wineskins? New data to gain new insight? // Proc. of the First Europ. conf. on earthquake engineering and seismology, Geneva, Switzerland, 3-8 September. Geneva, 2006. P. 24.
Goda K., Atkinson G. M. Probabilistic characterization of spatially correlated response spectra for earthquakes in Japan // Bull. Seism. Soc. Amer. 2009. V. 99(6). P. 3003-3020. doi: 10.1785/0120090007.
Goda K., Atkinson G.M. Intraevent spatial correlation of ground-motion parameters using SK-net data // Bull. Seism. Soc. Amer. 2010. V. 100(6). P. 3055-3067. doi: 10.1785/0120100031.
Grünthal G. The history of historical earthquake research in Germany // Ann. di Geof. 2004. V. 47(2/3). P. 631-643.
Grünthal G., Wahlström R. A MW based earthquake catalogue for Central, Northern and North-Western Europe using a hierarchy of magnitude conversions // J. of Seism. 2003. V. 7. P. 507-531.
Hintersberger E., Scherbaum F., Hainzl S. Update of likelihood-based ground-motion model selection for seismic hazard analysis in western central Europe // Bull. Earthq. Eng. 2007. V. 5(1). P. 1-16. doi: 10.1007/s10518-006-9018-x.
Johnson M.E. Multivariate statistical simulation / Wiley Series in Probability and Mathematical Statistics, Los Alamos National Laboratory. Los Alamos: NM, 1987. 240 p.
Keintzel E. About the way to the new German Seismic Code DIN 4149: 2005-04 // Bautechnik 2005. V. 82 (8). P. 475-485. doi: 10.1002/bate.200590164.
Lee R., Kiremidjian A.S. Uncertainty and correlation for loss assessment of spatially distributed systems // Earthq. Spectra. 2007. V. 23. P. 753-770. doi:10.1193/1.2791001.
Leydecker G. Erdbebenkatalog für die Bundesrepublik Deutschland mit Randgebieten für die Jahre 800 bis 1994 (für Schadensbeben bis 1998): Datenfile // Bund. für Geowissenschaften und Rohstoffe. Hannover, 1999.
Leydecker G., Aichele H. The seismogeographical regionalisation of Germany: the prime example for third-level regionalization // Geol. J. 1998. V. E55. P. 85-98.
Park J., Bazzurro P., Baker J.W. Modeling spatial correlation of ground motion intensity measures for regional seismic hazard and portfolio loss estimations // Applications of statistics and probability in civil engineering / Eds. J. Kanda, T. Takada, H. Furuta. London: Taylor and Francis Group, 2007. P. 1-8.
Prochazkova D., Schneider G., Schmedes E., Drimmel J., Fiegweil E., Lukeschitz G., Vogt J., Courtot P., Godefroy P., Grünthal G., Mayer-Rosa D., Berger R. Macroseismic field of the earthquake of September 3, 1978, in the Swabian Jura // J. of Geoph. 1979. V. 46. P. 343-347.
Schwarz J., Langhammer T., Kaufmann C. Assessment of damage and loss potentials due to earthquake (1) reconstruction of the «Albstadt»-quake in the Swabian Albs in September 03, 1978 // Bautechnik. 2005. V. 82(8). P. 520-531 doi: 10.1002/bate.200590170.
Sokolov V. Seismic intensity and Fourier acceleration spectra: revised relationship // Earthq. Spectra. 2002. V. 18. P. 161-187.
Sokolov V., Wald D.J. Instrumental intensity distribution for the Hector Mine, California, and the Chi-Chi, Taiwan, earthquakes: a comparison of two methods // Bull. Seism. Soc. Amer. 2002. V. 92(6). P. 2145-2162. doi:10.1785/0120010264.
Sokolov V., Wenzel F. First step toward realistic ground-motion prediction for SW-Germany // Proc. of Workshop «Seismicity patterns in the Euro-Mediterranean Region», November 17-19, 2008, Luxemburg. Luxemburg, 2008. P. 53-68.
Sokolov V., Wenzel F. Influence of spatial correlation of strong ground-motion on uncertainty in earthquake loss estimation // Earthq. Eng. and Struct. Dynamics 2011. V. 40(9). P. 993-1009. doi: 10.1002/eqe.1074.
Sokolov V., Wenzel F. Spatial correlation of ground-motion in estimating seismic hazards to civil infrastructure // Handbook on seismic risk analysis and management of civil infrastructure systems / Eds S. Tesfamariam, K. Goda. Cambridge, UK: Woodhead Publ. Ltd., 2013. P. 57-78.
Sokolov V., Wenzel F., Jean W.Y., Wen K.L. Uncertainty and spatial correlation of earthquake ground motion in Taiwan // Terrestial, Atmospheric and Oceanic Sci. (TAO). 2010. V. 21(6). P. 905-521. doi: 10.3319/TAO.2010.05.03.01(T).
Sokolov V., Wenzel F., Wen K.L., Jean W.Y. On the influence of site conditions and earthquake magnitude on ground-motion within-earthquake correlation: analysis of PGA data from TSMIP (Taiwan) network // Bull. Earthq. Eng. 2012. V. 10(5). P. 1401-1429. doi: 10.1007/s10518-012-9368-5.
Stromeyer D., Grünthal G. Attenuation relationship of macroseismic intensity in Central Europe // Bull. Seism. Soc. Amer. 2009. V. 99(2A). P. 554-565. doi:10.1785/0120080011.
-Tyagunov S., Grьnthal G., Wahlstrцm R., Stempniewski L., Zschau J. Seismic risk mapping for Germany // Natural Hazards and Earth System Sci. 2006. V. 6 (4). P. 573586. doi:10.5194/nhess-6-573-2006.
Wang M., Takada T. Macrospatial correlation model of seismic ground motions // Earthq. Spectra. 2005. V. 21(4). P. 1137-1156. doi: 10.1193/1.2083887.
Wesson R.L., Perkins D.M. Spatial correlation of probabilistic earthquake ground motion and loss // Bull. Seism. Soc. Amer. 2001. V. 91(6). P. 1498-1515. doi: 10.1785/0120000284.
Соколов В.Ю. О моделировании пространственного распределения сильных движений грунта при оценках сейсмической опасности и риска // Вопросы инженерной сейсмологии. 2012. Т. 39, № 2. С. 5-22.
Соколов В.Ю., Венцель Ф. Корреляция сильных движений грунта и ее влияние на оценки сейсмической опасности для протяженных объектов // Вопросы инженерной сейсмологии. 2011. Т. 38, № 4. С. 5-15.
Чернов Ю.К. Сильные движения грунта и количественная оценка сейсмической опасности территорий. Ташкент: Фан, 1989. 295 с.
Abrahamczyk L., Langhammer T., Schwarz J. Earthquake regions in Germany - a statistical evaluation// Bautechnik. 2005. V. 82(8). P. 500-507. doi: 10.1002/bate.200590166
Amstein S., Lang D.H., Schwarz J. Shaking effects of historical earthquakes and novel applications in the scientific field of earthquake engineering // Bautechnik. 2005. V. 82(9). P. 641-655. doi: 10.1002/bate.200590194 (in German).
Anderson J., Hough S. A model for the shape of the Fourier amplitude spectrum of acceleration at high frequencies // Bull. Seism. Soc. Amer. 1984. V. 74(5). P. 1969-1993.
Bal I.E., Bommer J.J., Stafford P.J., Crowley H., Pinho R. The influence of geographical resolution of urban exposure data in an earthquake loss model for Istanbul // Earthq. Spectra. 2010. V. 26(3). P. 619-634. doi: 10.1193/1.3459127.
Brune J.N. Tectonic stress and the spectra of seismic shear waves from earthquakes // J. Geoph. Res. 1970. V. 75. P. 4997-5009.
Brune J.N. Correction // J. Geoph. Res. 1971. V. 76. P. 5002.
Brüstle W., Stange S. Geologische Untergrundklassen zum Entwurf von Normspektren für DIN 4149 (neu) // Landesamt für Geologie, Rohstoffe und Bergbau Baden-Württemberg Freiberg i. Br. Juli. 1999.
Chernov Y., Sokolov V. Correlation of seismic intensity with Fourier acceleration spectra // Phys. and Chem. of the Earth. Pt. A. Solid Earth and Geodesy. 1999. V. 24(6). P. 522-528.
DIN 4149. Bauten in Deutschen Erdbebengebieten-Lastannahmen bemessung und ausführung üblicher Hochbauten. Vorgesehen als Ersatz für DIN 4149-1:1981-04 und DIN 4149-1/A1:1992-12. Normenausschuss in Bauwesen (NADau) im DIN Deutsches Institut für Normung e.V. Berlin, 2005.
Du W., Wang W. Intra-event spatial correlations for cumulative absolute velocity, Arias intensity, and spectral accelerations based on regional site conditions // Bull. Seism. Soc. Amer. V. 103(2). P. 1117-1129. doi: 10.1785/0120120185.
Feskova T. Earthquake ground motion modeling for South-West Germany: Diploma Thesis. KIT, 2010.
Fiedler G. Die Erdbebentätigkeit in Südwestdeutschland in den Jahren 1800-1950: Doktorarbeit. Stuttgart, 1954.
Gisler M., Schwarz-Zanetti G., Fäh D., Masciadri M., Rippmann D. The 1356 Basel earthquake from a historical point of view: old wine in new wineskins? New data to gain new insight? // Proc. of the First Europ. conf. on earthquake engineering and seismology, Geneva, Switzerland, 3-8 September. Geneva, 2006. P. 24.
Goda K., Atkinson G. M. Probabilistic characterization of spatially correlated response spectra for earthquakes in Japan // Bull. Seism. Soc. Amer. 2009. V. 99(6). P. 3003-3020. doi: 10.1785/0120090007.
Goda K., Atkinson G.M. Intraevent spatial correlation of ground-motion parameters using SK-net data // Bull. Seism. Soc. Amer. 2010. V. 100(6). P. 3055-3067. doi: 10.1785/0120100031.
Grünthal G. The history of historical earthquake research in Germany // Ann. di Geof. 2004. V. 47(2/3). P. 631-643.
Grünthal G., Wahlström R. A MW based earthquake catalogue for Central, Northern and North-Western Europe using a hierarchy of magnitude conversions // J. of Seism. 2003. V. 7. P. 507-531.
Hintersberger E., Scherbaum F., Hainzl S. Update of likelihood-based ground-motion model selection for seismic hazard analysis in western central Europe // Bull. Earthq. Eng. 2007. V. 5(1). P. 1-16. doi: 10.1007/s10518-006-9018-x.
Johnson M.E. Multivariate statistical simulation / Wiley Series in Probability and Mathematical Statistics, Los Alamos National Laboratory. Los Alamos: NM, 1987. 240 p.
Keintzel E. About the way to the new German Seismic Code DIN 4149: 2005-04 // Bautechnik 2005. V. 82 (8). P. 475-485. doi: 10.1002/bate.200590164.
Lee R., Kiremidjian A.S. Uncertainty and correlation for loss assessment of spatially distributed systems // Earthq. Spectra. 2007. V. 23. P. 753-770. doi:10.1193/1.2791001.
Leydecker G. Erdbebenkatalog für die Bundesrepublik Deutschland mit Randgebieten für die Jahre 800 bis 1994 (für Schadensbeben bis 1998): Datenfile // Bund. für Geowissenschaften und Rohstoffe. Hannover, 1999.
Leydecker G., Aichele H. The seismogeographical regionalisation of Germany: the prime example for third-level regionalization // Geol. J. 1998. V. E55. P. 85-98.
Park J., Bazzurro P., Baker J.W. Modeling spatial correlation of ground motion intensity measures for regional seismic hazard and portfolio loss estimations // Applications of statistics and probability in civil engineering / Eds. J. Kanda, T. Takada, H. Furuta. London: Taylor and Francis Group, 2007. P. 1-8.
Prochazkova D., Schneider G., Schmedes E., Drimmel J., Fiegweil E., Lukeschitz G., Vogt J., Courtot P., Godefroy P., Grünthal G., Mayer-Rosa D., Berger R. Macroseismic field of the earthquake of September 3, 1978, in the Swabian Jura // J. of Geoph. 1979. V. 46. P. 343-347.
Schwarz J., Langhammer T., Kaufmann C. Assessment of damage and loss potentials due to earthquake (1) reconstruction of the «Albstadt»-quake in the Swabian Albs in September 03, 1978 // Bautechnik. 2005. V. 82(8). P. 520-531 doi: 10.1002/bate.200590170.
Sokolov V. Seismic intensity and Fourier acceleration spectra: revised relationship // Earthq. Spectra. 2002. V. 18. P. 161-187.
Sokolov V., Wald D.J. Instrumental intensity distribution for the Hector Mine, California, and the Chi-Chi, Taiwan, earthquakes: a comparison of two methods // Bull. Seism. Soc. Amer. 2002. V. 92(6). P. 2145-2162. doi:10.1785/0120010264.
Sokolov V., Wenzel F. First step toward realistic ground-motion prediction for SW-Germany // Proc. of Workshop «Seismicity patterns in the Euro-Mediterranean Region», November 17-19, 2008, Luxemburg. Luxemburg, 2008. P. 53-68.
Sokolov V., Wenzel F. Influence of spatial correlation of strong ground-motion on uncertainty in earthquake loss estimation // Earthq. Eng. and Struct. Dynamics 2011. V. 40(9).
Sokolov V., Wenzel F. Spatial correlation of ground-motion in estimating seismic hazards to civil infrastructure // Handbook on seismic risk analysis and management of civil infrastructure systems / Eds S. Tesfamariam, K. Goda. Cambridge, UK: Woodhead Publ. Ltd., 2013. P. 57-78.
Sokolov V., Wenzel F., Jean W.Y., Wen K.L. Uncertainty and spatial correlation of earthquake ground motion in Taiwan // Terrestial, Atmospheric and Oceanic Sci. (TAO). 2010. V. 21(6). P. 905-521. doi: 10.3319/TAO.2010.05.03.01(T).
Sokolov V., Wenzel F., Wen K.L., Jean W.Y. On the influence of site conditions and earthquake magnitude on ground-motion within-earthquake correlation: analysis of PGA data from TSMIP (Taiwan) network // Bull. Earthq. Eng. 2012. V. 10(5). P. 1401-1429. doi: 10.1007/s10518-012-9368-5.
Stromeyer D., Grünthal G. Attenuation relationship of macroseismic intensity in Central Europe // Bull. Seism. Soc. Amer. 2009. V. 99(2A). P. 554-565. doi:10.1785/0120080011.
-Tyagunov S., Grьnthal G., Wahlstrцm R., Stempniewski L., Zschau J. Seismic risk mapping for Germany // Natural Hazards and Earth System Sci. 2006. V. 6 (4). P. 573586.
Wang M., Takada T. Macrospatial correlation model of seismic ground motions // Earthq. Spectra. 2005. V. 21(4). P. 1137-1156. doi: 10.1193/1.2083887.
Wesson R.L., Perkins D.M. Spatial correlation of probabilistic earthquake ground motion and loss // Bull. Seism. Soc. Amer. 2001. V. 91(6). P. 1498-1515. doi: 10.1785/0120000284.
