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200 10$aAsian and Pacific Coasts 2003$b[electronic resource] $eproceedings of the 2nd International conference : Makuhari, Japan, 29 February - 4 March 2004 /$feditors, Yoshimi Goda, Wataru Kioka, Kazuo Nadaoka
210   $aRiver Edge, N.J. $cWorld Scientific$dc2004
215   $a1 online resource (305 p.)
300   $aDescription based upon print version of record.
311   $a981-238-558-4 
320   $aIncludes bibliographical references.
327   $aPreface; CONTENTS; Climate Change and Sea-Level Rise: Challenges to Coastal Science and Engineering N. Mirnura; A New Tsunami Numerical Simulation with Boussinesq-Type Equations Applied for the 1983 Nihonkai-Chubu Earthquake Tsunami H. Iwase and F. Imamura; Hydraulic Experiments and Numerical Model of Two-Layer for a Landslide-Induced Tsunami Y. Shigihara, D. Goto and F. Imamura; Study on the Evaluation of Tsunami Reducing by Coastal Control Forest for Actual Conditions K. Harada and F. Imamura; Study on the Accuracy of the Tsunami Numerical Model around Obstacles S.J. Hong and F. lmamura
327   $aFlood in Jakarta - Lessons Learnt from the 2002 Flood S. Diposaptono, W.A. Pratikto and A. ManoPrecise Nearshore Currents Model Using Sigma Coordinate System H. Nobuoka and N. Mimura; An Application of a Nesting Procedure to a Highly-Resolved Current Simulation in a Mangrove Area Y. Nihei, K. Sato, Y. Aoki, T. Nishimura and K. Nadaoka; Numerical Simulation of Wave Propagation in the Water Area of the Yangtze River Estuary H. Wang, Q. Zuo and J. Pan; Visualization of Tidal Oscillation in the Taiwan Strait W. J. Juang, M. C. Lin and C. C. Chiang
327   $aA Nonlinear Coupled Numerical Model for Astronomical Tides and Storm Surge Numerical Simulation of the Storm Surge in River Changjiang's Estuary Y. Tan and J. ZhangWave Propagation over Slowly Varying Depth with the Presence of Weak Currents M.C. Lin, C.M. Hsu and C.L. Ting; Regional Ocean Tide Simulator: Simulation of Barrier Effects B.H. Choi, J.H. Yuk and H.S. Lee; Field Observation of Waves near the Shoreline and Its Analysis K. Seki and M. Mizuguchi; Experimental Study on Bottom Shear Stress under Sawtooth Wave Suntoyo, H. Tanaka and H. Yamaji
327   $aA High-Resolution Numerical Scheme for Boussinesq Equations X. YuModified Boussinesq Model on Uneven Bottom B. Wang, H. Liu, L. Xue and Y. He; Some Considerations of Refinement of a Boussinesq Equation and Its Verification S. Onda, T. Hosoda and I. Kimura; A Quasi-3D Numerical Shallow Water Model Based on FVM S. Li and L. Lu; An Analytic Solution of the Mild-Slope Equation for Scattering by a Truncated Conical Shoal H. W. Liu. P.Z. Lin and N. Jothi Shankar; Transient Free-Surface Waves due to a Suddenly Stopping Body D.Q. Lu and A.T. Chwang
327   $aComparison and Characterization of Bottom Mounted Wave Directional System T. Nagai, N . Hashimoto, A. Lohrmann, M. Mitsui and S. KonashiLaboratory Experiments on the Effects of Mechanically Generated Waves on the Core Flow under Wind Waves S. Mizuno; Generation of Incident Random Waves in Numerical Extended Mild-Slope Equation Models Using a Source Function Method G. Kim, C. Lee and K.D. Suh; Simulation of Wave Overtopping on Partially Immersed Breakwater by SPH Model S. Shao, H. Gotoh and T. Memita
327   $aNumerical Model of Wave Breaking by Lagrangian Particle Method with Sub-Particle-Scale Turbulence Model H. Gotoh, M. Hayashi, T. Sakai and K. Oda
330   $aThis book presents the experience of coastal and port engineering development, as well as coastal environmental problems, in Asian and Pacific countries. It also provides information and promotes technological progress and activities, international technical transfer and cooperation, and opportunities for engineers and researchers to maintain and improve scientific and technical competence. The subject areas are not limited to the classical topics of coastal engineering but are extended to related fields, including environments, marine ecology, coastal oceanography, fishery, etc.
606   $aCoasts$zAsia$vCongresses
606   $aGeology, Structural$zPacific Ocean$vCongresses
606   $aOceanography$zPacific Ocean$vCongresses
608   $aElectronic books.
615  0$aCoasts
615  0$aGeology, Structural
615  0$aOceanography
676   $a333.917095
676   $a551.46/14
712 12$aInternational Conference on Asian and Pacific Coasts
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200 10$aMaterials and acoustics handbook /$fedited by Michel Bruneau, Catherine Potel
210   $aLondon, UK $cISTE ; Hoboken, NJ : J. Wiley$dc2009
215   $a1 online resource (943 p.)
225 1 $aISTE ;$vv.76
300   $aDescription based upon print version of record.
311 08$a9781848210745 
311 08$a1848210744 
320   $aIncludes bibliographical references and index.
327   $aMaterials and Acoustics Handbook; Table of Contents; Foreword; Preface; Part 1. Homogenous and Homogenous Stratified Media: Linear Model of Propagation; Chapter 1. Equations of Propagation; 1.1. Introduction; 1.1.1. Fluid medium; 1.1.2. Elastic solid; 1.2. Solutions of the propagative equation: monochromatic waves, plane waves; 1.2.1. Fluid medium or isotropic solid; 1.2.2. Anisotropic solid; 1.3. Bibliography; Chapter 2. Interaction of a Plane Wave and a Plane Interface; 2.1. Introduction; 2.1.1. Boundary conditions in acoustics
327   $a2.1.2. Plane interface separating two fluid or isotropic solid media2.1.3. Interface separating two anisotropic solid media; 2.2. Bibliography; Chapter 3. Propagation of Plane Waves in Multilayered Media; 3.1. Introduction; 3.1.1. Propagation on a single material layer; 3.1.2. Propagation in a multilayered medium; 3.1.3. Propagation in a periodic multilayered medium; 3.2. Bibliography; Chapter 4. Propagation in Continuously Stratified Media; 4.1. Introduction; 4.2. Wave equation for 1D inhomogenous media; 4.2.1. Second-order differential system
327   $a4.2.2. First-order ordinary differential system for the case of 1Dinhomogenity4.3. Solution to the wave equation in 1D inhomogenous media; 4.3.1. The matricant; 4.3.2. Evaluation of the matricant by the Peano series; 4.4. Remarks on the numerical implementation; 4.4.1. The Peano series as a power series in dispersion parameters; 4.4.2. Examples; 4.5. Bibliography; Chapter 5. Modal Waves in Plane Structures; 5.1. Introduction; 5.1.1. General properties of modal waves in plane structures; 5.1.2. Usual modal waves; 5.1.3. Dispersion effects for modal waves
327   $a5.1.4. Generalized modal waves - pseudo modal waves5.1.5. A generic example; 5.2. Appendix: non-null elements of determinant D; 5.3. Bibliography; Part 2. Porous and Stratified Porous Media Linear Models of Propagation; Introduction to Part 2; Chapter 6. The Equivalent Fluid Model; 6.1. Introduction; 6.2. Geometry definitions; 6.2.1. Ideal fluid; 6.2.2. Thermoviscous fluids; 6.3. Bibliography; Chapter 7. Biot's Midel; 7.1. Introduction; 7.1.1. Perfect fluid and elastic solid; 7.1.2. Thermoviscous fluid and visco-elastic structure; 7.2. Bibliography
327   $aChapter 8. Propagation Equations in the Time Domain8.1. Introduction; 8.1.1. Materials: frequency and temporal approach; 8.1.2. Fractional derivative and behavior of materials; 8.1.3. Fractional derivative and viscoelasticity; 8.1.4. Fractional derivative and model of the equivalent fluid; 8.2. Inertial regime (high frequency approximation); 8.2.1. A semi-infinite medium; 8.2.2. Cases of a finite medium; 8.2.3. Reflection and transmission operators; 8.3. Viscous regime (low frequency approximation); 8.3.1. Resolution for the semi-infinite medium; 8.3.2. Solution in a finite medium
327   $a8.3.3. Reflection and transmission operators
330   $aWritten by a group of acoustics and vibration specialists, this book studies the acoustic and vibrating phenomena that occur in diverse materials used for all kinds of purposes. The first part studies the fundamental aspects of propagation: analytical, numerical and experimental. The second part outlines industrial and medical applications. Covering a wide range of topics that associate materials science with acoustics, this will be of invaluable use to researchers, engineers, or practitioners in this field, as well as students in acoustics, physics, and mechanics.
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