참고문헌 (19)

1. Dutykh, D., Dias, F. and Kervella, Y. (2006). Linear theory of wave generation by a moving bottom. Comptes Rendus de l'Academie des Sciences Paris, Series I 343, 499-504. 

2. Dutykh, D. and Dias, F. (2007). Water waves generated by a moving bottom. Tsunami and Nonlinear Waves (ed. A. Kundu), Geo Sciences. New York, Springer, 63-94. 

3. Hammack, J.L. (1973). A note on tsunamis: their generation and propagation in an ocean of uniform depth. Journal of Fluid Mechanics, 60(4), 769-799. 

   상세보기

4. Imai, K., Satake, K. and Furumura, T. (2010). Amplification of tsunami heights by delayed rupture of great earthquakes along the Nankai trough. Earth, Planets and Space, 62(4), 427-432. 

   상세보기

5. Ishii, M., Shearer, P.M., Houston, H. and Vidale, J.E. (2005). Extent, duration and speed of the 2004 Sumatra-Andaman earthquake imaged by the Hi-Net array. Nature, 435(7044), 933. 

   상세보기

6. Jung, T.-H. and Son, S. (2018). Propagation of tsunamis generated by seabed motion with time-history and spatial distribution: an analytical approach. Journal of Korean Society of Coastal and Ocean Engineers, 30(6), 263-269 (in Korean). 

7. Jung, T.-H. and Son, S. (2020a). The effect of surface ruptures on the propagation of tsunamis: An analysis of 1993 Hokkaido earthquake. Journal of Korean Society of Hazard Mitigation, 20(1), 365-371 (in Korean). 

   상세보기

8. Jung, T.-H. and Son, S. (2020b). The effect of fault failure with time difference on the runup height of East coast of Korea. Journal of Korean Society of Coastal and Ocean Engineers, 32(4), 2239-229 (in Korean). 

9. Kajiura, K. (1963). The leading wave of a tsunami. Bulletin Earthquake Research Institute. Tokyo University, 41, 535-571. 

10. Kervella, Y., Dutykh, D. and Dias, F. (2007). Comparison between three-dimensional linear and nonlinear tsunami generation models. Theoretical and Computational Fluid Dynamics, 21, 245-269. 

    상세보기

11. Kowalik, Z., Knight, W., Tom, L. and Whitmore, P.M. (2005). Numerical modeling of the global tsunami: Indonesian tsunami of 26 December 2004. Science of Tsunami Hazards, 23(1), 40-56. 

12. Lee, J.-W., Park, E.H., Park, S.-C. and Woo, S.-B. (2015). Development of the global tsunami prediction system using the finite fault model and the cyclic boundary condition. Journal of Korean Society of Coastal and Ocean Engineers, 27(6), 391-405. 

    원문보기 상세보기

13. Ohmachi, T., Tsukiyama, H. and Matsumoto, H. (2001). Simulation of tsunami induced by dynamic displacement of seabed due to seismic faulting. Bulletin of the Seismological Society of America, 91(6), 1898-1909. 

    상세보기

14. Saito, T. and Furumura, T. (2009). Three-dimensional tsunami generation simulation due to sea-bottom deformation and its interpretation based on the linear theory. Geophysical Journal International, 178(2), 877-888. 

    상세보기

15. Suppasri, A., Imamura, F. and Koshimura, S. (2010). Effects of the rupture velocity of fault motion, ocean current and initial sea level on the transoceanic propagation of tsunami. Coastal Engineering Journal, 52(2), 107-132. 

    상세보기

16. Suzuki, W., Aoi, S., Sekiguchi, H. and Kunugi, T. (2011). Rupture process of the 2011 Tohoku-Oki mega-thrust earthquake (M9.0) inverted from strong-motion data. Geophysical Research Letters, 38(7), 1-6. 

17. Tivot, V.V. and Synolakis, C.E. (1998). Numerical modeling of tidal wave runup. Journal of Waterway, Port, Coastal, and Ocean Engineering, 124(4), 157-171. 

    상세보기

18. Wang, X. (2009). User manual for COMCOT version 1.7(first draft). Cornel University, 65. 

19. Wei, Y., Newman, A.V., Hayes, G.P., Titov, V.V. and Tang, L. (2014). Tsunami forecast by joint inversion of real-time tsunami waveforms and seismic or GPS data: application to the Tohoku 2011 tsunami. Pure and Applied Geophysics, 171(12), 3281-3305. 

    상세보기

저자의 다른 논문 :

정태화 (19) 손상영 (19)