36. Huang, T.T., Groves, N.C. and Belt, G., “Boundary-Layer Flow on An Axisymmetric Body with An Inflected Stern, ” David W.Taylor Naval Ship Research and Development Center, Report No. DTNSRDC-80/064, August 1980.

37. Ahn, S., “An Experimental Study of Flow Over a 6 to 1 Prolate Spheroid at Incidence, ” Ph.D. Dissertation, Aerospace and Ocean Engineering Department, Virginia Polytechnic Institute and State University, October 1992.

38. Devenport, W.J. and Simpson, R.L., “An Experimental Investigation of the Flow Past an Idealized Wing-Body Junction: Final Report,” Department of Aerospace and Ocean Engineering, Virginia Polytechnic Institute and State University, Report VPI-AOE-172, July 1990.

39. Taylor, L.K. and Whitfield, D.L., “Unsteady Three-Dimensional Incompressible Euler and Navier-Stokes Solver for Stationary and Dynamic Grids,” AIAA Paper No. 91–1650, June 1991.

40. Sheng. C., Taylor, L.K., and Whitfield, D.L., “An Efficient Multigrid Acceleration for Solving the 3-D Incompressible Navier-Stokes Equations in Generalized Curvilinear Coordinates,” AIAA Paper No. 94–2335, 25th AIAA Fluid Dynamics Conference, Colorado Springs, CO, June 1994.

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Front Matter (R1-R16)

Opening Remarks (1-4)

Progress Toward Understanding How Waves Break (5-28)

Radiation and Diffraction Waves of a Ship at Forward Speed (29-44)

Nonlinear Ship Motions and Wave-Induced Loads by a Rankine Method (45-63)

Nonlinear Water Wave Computations Using a Multipole Accelerated, Desingularized Method (64-74)

Computations of Wave Loads Using a B-Spline Panel Method (75-92)

Simulation of Strongly Nonlinear Wave Generation and Wave-Body Interactions Using a 3-D Model (93-109)

Analysis of Interactions Between Nonlinear Waves and Bodies by Domain Decomposition (110-119)

Fourier-Kochin Theory of Free-Surface Flows (120-135)

24-inch Water Tunnel Flow Field Measurements During Propeller Crashback (136-146)

Accuracy of Wave Pattern Analysis Methods in Towing Tanks (147-160)

Unsteady Three-Dimensional Cross-Flow Separation Measurements on a Prolate Spheroid Undergoing Time-Dependent Maneuvers (161-176)

Time-Domain Calculations of First-and Second-Order Forces on a Vessel Sailing in Waves (177-188)

Third-Order Volterra Modeling Ship Responses Based on Regular Wave Results (189-204)

Nonlinearly Interacting Responses of the Two Rotational Modes of Motion-Roll and Pitch Motions (205-219)

Nonlinear Shallow-Water Flow on Deck Coupled with Ship Motion (220-234)

Radar Backscatter of a V-like Ship Wake from a Sea Surface Covered by Surfactants (235-248)

Turbulent Free-Surface Flows: A Comparison Between Numerical Simulations and Experimental Measurements (249-265)

Conductivity Measurements in the Wake of Submerged Bodies in Density-Stratified Media (266-277)

Macro Wake Measurements for a Range of Ships (278-290)

Time-Marching CFD Simulation for Moving Boundary Problems (291-311)

Yaw Effects on Model-Scale Ship Flows (312-327)

A Multigrid Velocity-Pressure-Free Surface Elevation Fully Coupled Solver for Calculation of Turbulent Incompressible Flow around a Hull (328-345)

The Shoulder Wave and Separation Generated by a Surface-Piercing Strut (346-358)

Vorticity Fields due to Rolling Bodies in a Free Surface-Experiment and Theory (359-376)

Numerical Calculations of Ship Stern Flows at Full-Scale Reynolds Numbers (377-391)

Near-and Far-Field CFD for a Naval Combatant Including Thermal-Stratification and Two-Fluid Modeling (392-407)

Water Entry of Arbitrary Two-Dimensional Sections with and Without Flow Separation (408-423)

Coupled Hydrodynamic Impact and Elastic Response (424-437)

A Practical Prediction of Wave-Induced Structural Responses in Ships with Large Amplitude Motion (438-452)

Evaluation of Eddy Viscosity and Second-Moment Turbulence Closures for Steady Flows Around Ships (453-469)

On the Modeling of the Flow Past a Free-Surface-Piercing Flat Plate (470-477)

Self-Propelled Maneuvering Underwater Vehicles (478-489)

Spray Formation at the Free Surface of Turbulent Bow Sheets (490-505)

Numerical Simulation of Three-Dimensional Breaking Waves About Ships (506-519)

Generation Mechanisms and Sources of Vorticity Within a Spilling Breaking Wave (520-533)

The Flow Field in Steady Breaking Waves (534-549)

Freak Waves-A Three-Dimensional Wave Simulation (550-560)

Bluff Body Hydrodynamics (561-579)

Large-Eddy Simulation of the Vortical Motion Resulting from Flow over Bluff Bodies (580-591)

The Wake of a Bluff Body Moving Through Waves (592-604)

Low-Dimensional Modeling of Flow-Induced Vibrations via Proper Orthogonal Decomposition (605-621)

Measurements of Hydrodynamic Damping of Bluff Bodies with Application to the Prediction of Viscous Damping of TLP Hulls (622-634)

Hydrodynamics in Advanced Sailing Design (635-660)

Divergent Bow Waves (661-679)

A Method for the Optimization of Ship Hulls from a Resistance Point of View (680-696)

Hydrodynamic Optimization of Fast-Displacement Catamarans (697-714)

On Ships at Supercritical Speeds (715-726)

The Influence of a Bottom Mud Layer on the Steady-State Hydrodynamics of Marine Vehicles (727-742)

A Hybrid Approach to Capture Free-Surface and Viscous Effects for a Ship in a Channel (743-755)

Shock Waves in Cloud Cavitation (756-771)

Asymptotic Solution of the Flow Problem and Estimate of Delay of Cavitation Inception for a Hydrofoil with a Jet Flap (772-782)

Examination of the Flow Near the Leading Edge and Closure of Stable Attached Cavitation (783-793)

Numerical Investigation on the Turbulent and Vortical Flows Beneath the Free Surface Around Struts (794-811)

Steep and Breaking Faraday Waves (812-826)

The Forces Exerted by Internal Waves on a Restrained Body Submerged in a Stratified Fluid (827-838)

Influence of the Cavitation Nuclei on the Cavitation Bucket when Predicting the Full-Scale Behavior of a Marine Propeller (839-850)

Inception, Development, and Noise of a Tip Vortex Cavitation (851-864)

Velocity and Turbulence in the Near-Field Region of Tip Vortices from Elliptical Wings: Its Impact on Cavitation (865-881)

Calculations of Pressure Fluctuations on the Ship Hull Induced by Intermittently Cavitating Propellers (882-897)

Hydroacoustic Considerations in Marine Propulsor Design (898-912)

Prediction of Unsteady Performance of Marine Propellers with Cavitation Using Surface-Panel Method (913-929)

A Comparitive Study of Conventional and Tip-Fin Propeller Performance (930-945)

A New Way of Stimulating Whale Tail Propulsion (946-958)

Effects of Tip-Clearance Flows (959-972)

Experiments in the Swirling Wake of a Self-Propelled Axisymmetric Body (973-985)

Hydrodynamic Forces on a Surface-Piercing Plate in Steady Maneuvering Motion (986-996)

Advances in Panel Methods (997-1006)

Effect of Ship Motion on DD-963 Ship Airwake Simulated by Multizone Navier-Stokes Solution (1007-1017)

Large-Eddy Simulation of Decaying Free-Surface Turbulence with Dynamic Mixed Subgrid-Scale Models (1018-1032)

Fully Nonlinear Hydrodynamic Calculations for Ship Design on Parallel Computing Platforms (1033-1047)

Validation of Incompressible Flow Computation of Forces and Moments on Axisymmetric Bodies Undergoing Constant Radius Turning (1048-1060)

The Validation of CFD Predictions of Nominal Wake for the SUBOFF Fully Appended Geometry (1061-1076)

Appendix-List of Participants (1077-1084)