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<div>Introduction.-&nbsp;Fundamentals of Hydordynamics and Statistics&nbsp;Wave Theories.-&nbsp;Kinematics and Dynamics of rigid bodies.-&nbsp;Strip Methods.-&nbsp;Boundary Element Methods.-&nbsp;Field Methods.-&nbsp;Computational Procedures.-&nbsp;Applications.</div><div><br></div>

<p><b>Bettar Ould el Moctar</b> studied Naval Architecture and Ocean Engineering at the University of Hamburg/Germany. He graduated in 1997 and has since then worked as a research assistant in different departments of the University of Technology Hamburg, where he has specialized in computational fluid dynamics. He completed his doctorate at the University of Technology Hamburg with a dissertation entitled "Numerical Computation of Forces Acting on Maneuvering Ships." In 2000 he joined the Hamburg Ship Model Basin (HSVA) and worked as a research engineer. He was head of department of fluid dynamics at Germanischer Lloyd/Germany from 2002 to 2008 and global head of research at DNV GL advisory services/Germany/Norway from 2013 to 2016. Since 2008 he has been working at the University Duisburg-Essen as a full professor for ship technology and Ocean Engineering and member of the Board of Directors of the shallow water model basin DST/Germany. He is editor and co-editor for several international journals and has been member of different international committees. His publications cover various aspects of hydrodynamics and Fluid-Structure-Interaction. The focus of his research is the development of numerical and experimental methods for seakeeping, hydroelasticity, cavitation, slamming and sloshing, maneuvering and propulsion in waves.</p><p><br></p><p><b>Thomas E. Schellin</b> has been lecturing at the Institute of Ship Technology, Ocean Engineering and Transport Systems (ISMT) of the University of Duisburg-Essen since the beginning of 2016. Currently, he also works on a freelance relationship for DNV GL, acting as a Marine Warranty Surveyor. In 2004, after his formal retirement from Germanischer Lloyd (now DNV GL), he spent a semester teaching Ship Dynamics at Virginia Tech University and, from 2007 to 2014, he taught also at the Technical University of Berlin. His work at Germanischer Lloyd (GL) comprised the development of hydrodynamic analysis methods for ships and offshore structures, coordination of nationally and internationally sponsored research projects, and formulation of class rules for fast ships, offshore structures, and offshore service vessels. He was GL's representative in the IACS AHG on Mooring and Anchoring, served on the 2001 and 2003 ISSC Committee I.2 Loads, and was the official discusser of the 2009 ISSC I.2 Loads Committee Report. He has published widely and is a Life Fellow of ASME and SNAME. Born in Germany, in 1964 he obtained his M.S. in Naval Architecture from the Massachusetts Institute of Technology and, in 1971, his Ph.D. in Mechanical Engineering from Rice University, Houston, Texas.</p><p><br></p><p><b>Heinrich Söding</b> was born in Dresden (Germany) in 1936. Grown up in Münster and Hamburg, he began studying Physics in Hamburg, then Naval Architecture in Hannover and Hamburg, receiving a Ph.D. in 1967 from the Hamburg University. He then joined Germanischer Lloyd from 1967 to 1970, mainly developing and applying load predictions of large containerships. From 1970 to 1979 he was Professor for computer-aided ship design at the Technical University Hannover, and from 1980 Professor for ship theory at the Hamburg University until his retirement in 2001. He lead about 50 scholars to their Ph.D. degree in the fields of ship design, seakeeping and maneuvering. Besides his university obligations, he performed numerous investigations for industry and courts of justice on the fields of lines fairing, hydrostatics, damage stability, resistance, seakeeping and maneuvering of ships and airplane ditching. His computer programs for these topics are used widely. He published about 90 papers in English and numerous others in German language. For nearly two decades he was (first) editor and (later) publisher of the journal Ship Technology Research.</p><p></p>

<div>The book describes currently applied and newly developed advanced numerical methods for wave-induced ship motions and loads.&nbsp; Besides well-established computational methods based on strip theory, panel methods and finite volume methods for unsteady Reynolds-averaged Navier-Stokes equations (URANS), recent advances like a fully nonlinear Rankine panel method, URANS calculations including elastic hull deformations, and an improved method to predict added resistance in waves are explained in detail. Furthermore, statistical methods to assess extreme motions and loads are described both for linear and nonlinear responses in a stationary seaway as well as during long-term ship operations. Results of motions and loads, computed using the various methods, are compared with each other and with results of model experiments.</div><div><br></div><div>Introductory chapters on fluid dynamics, motions of rigid and elastic ship hulls, numerical methods to compute fluid flows associated withwind waves, and the development and simulation of seaways complement the volume. The book will be of interest to post-graduate students, PhD candidates, as well as engineers in the field of naval architecture, ocean, and marine engineering.</div>

Provides instructions on how to make appropriate approximations when solving problems Details which methods are best used for particular applications Equips readers to handle complex calculations