High Speed Monohull and Hydrofoil Craft: Performance, Technology, and Applications provides comprehensive coverage of the basic hydrodynamics of high-speed monohulls and hydrofoil craft useful to students and engineers alike. The first half of the book introduces different hull shapes for semi-planing and planing craft with examples from their development through the last century. Succeeding chapters then describe the hydrodynamic theory behind their performance in calm water and a seaway. They also document the extensive series of model test programs naval architects use to create prediction models for resistance and powering. Electronic versions of a number of these are included for readers’ use. A final chapter on monohulls looks at hull geometric form that has been developed to provide the best possible combination of resistance in waves and motion response through a combination of a deep and sharp forefoot and a hard chine cross-section towards the stern for patrol vessels and offshore logistics craft. The book’s second half introduces the various geometries and planform configurations of hydrofoils under a fast craft hull. It reviews the development of these craft for inland waterways, such as major river systems, and the rougher environment of seaways, such as the Mediterranean and Atlantic oceans. It is followed by hydrofoil theory in an ideal fluid close to a free surface. Then the theory for a real fluid includes the vorticity and effect of planform, dihedral, and surface interaction. Hydrofoil craft design and analysis are covered next. Finally, there is a chapter on special configurations, such as craft having foils just at the bow and hydrofoil craft based on catamaran hulls. High Speed Monohull and Hydrofoil Craft: Performance, Technology, and Applications provides comprehensive coverage of the basic hydrodynamics of high-speed monohulls and hydrofoil craft useful to students and engineers alike. The first half of the book introduces different hull shapes for semi-planing and planing craft with examples from their development through the last century. Succeeding chapters then describe the hydrodynamic theory behind their performance in calm water and a seaway. They also document the extensive series of model test programs naval architects use to create prediction models for resistance and powering. Electronic versions of a number of these are included for readers’ use. A final chapter on monohulls looks at hull geometric form that has been developed to provide the best possible combination of resistance in waves and motion response through a combination of a deep and sharp forefoot and a hard chine cross-section towards the stern for patrol vessels and offshore logistics craft. The book’s second half introduces the various geometries and planform configurations of hydrofoils under a fast craft hull. It reviews the development of these craft for inland waterways, such as major river systems, and the rougher environment of seaways, such as the Mediterranean and Atlantic oceans. It is followed by hydrofoil theory in an ideal fluid close to a free surface. Then the theory for a real fluid includes the vorticity and effect of planform, dihedral, and surface interaction. Hydrofoil craft design and analysis are covered next. Finally, there is a chapter on special configurations, such as craft having foils just at the bow and hydrofoil craft based on catamaran hulls. ⦁ Presents practical design and calculation methods based on vessels that have been built and put into service; ⦁ Contains comprehensive references for each chapter, as well as a general technical resource appendix; ⦁ Provides several simple electronic analytical models for engineers and students to build upon. Professor Liang Yun has more than 40 years’ experience at the Marine Design & Research Institute of China, Shanghai (MARIC). He graduated from the Shipbuilding Engineering Faculty of Da-Lian Polytechnic University in 1953 and completed a postgraduate diploma at the Military Engineering Academy of China in 1955. He has been involved in ACV development in China since the first prototypes were constructed in Harbin in the 1950s. He was involved in the design and prototype construction of WIG craft in the 1990s and the development of high-speed catamarans and air cavity vessels through the millennium. He was director of the HPMV division, MARIC, from 1983 to 1987 and Deputy Chief Naval Architect of MARIC from 1980 to 1997. He has been a Guest Professor supporting HPMV postgraduate students at Harbin Engineering University and Wu Han Water Transportation University in the early 1990s. Prof. Yun has been Chairman of HPMV Design subcommittee of the China Society of Naval Architecture and Marine Engineering, CSNAME, over the last 20 years and vice chairman of the organizing committee of the annual International HPMV Conference, Shanghai, China, since 1996. He continued to play an active role in promoting and developing HPMV