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Table of Contents
- Contents
- Preface by the Editors-in-Chief
- Preface by Trevor Blakeley
- Preface by Guo Da-cheng
- Preface by Huang Ping-tao
- Preface by Zhang Guangqin
- Preface by Zhou Zhen-bo
- Chapter 1: High-Speed Monohull Craft
- 1.1 On the Development of High-Speed Monohull Craft
- 1.2 The Concise Hull-Form Parameters to Estimate a Planing Boat’s Resistance (2003)
- 1.3 Development of High-Speed Planing Hull Forms with Consideration of Resistance and Sea-Keeping Performance (2013)
- 1.4 Simulation of Transverse Motion and Dynamic Stability for High- Speed Planing Craft (2001)
- 1.5 Series-Test Research on the Linear Form of Double-Step Planing Boats (2014)
- 1.6 Study on Line Optimization of M-Form Hulls (2014)
- 1.7 The Hull Characteristics and Numerical Simulation without Grids of M-Form Hulls (2013)
- 1.8 A Probe into the Turning Heel of Deep-V Vessels (2000)
- 1.9 Novel Design and Hydrodynamic Optimization of a High-Speed Hull Form (2005)
- 1.10 Model Experimental Investigation on Resistance of Axe Bow Ships (2011)
- 1.11 An Axe Bow Ship of Excellent Sea-Keeping (2012)
- 1.12 Hydrodynamic Analysis of the Performance of Stern Flaps in a Semi-displacement Hull (2003)
- 1.13 Intruder
- 1.14 Estimation of Effect and Size on Ship Interceptors (2014)
- 1.15 Research on Model Tests for a 1,000t Hybrid Monohull with Stern Flap (2013)
- 1.16 Investigation of a Built-Up Appendage Applied to a High-Speed Round Bilge and a Deep-V Hull for Motion Performance Improvement (2014)
- 1.17 Sea-Keeping Research on an Axe Bow Ship with an Appendage (2014)
- Chapter 2: Multihull Ships
- 2.1 Introduction
- 2.2. Calculations of the Resistance, Sea-Keeping Characteristics, and Optimization of High-Speed Trimarans (2006)
- 2.3 On Resistance and Initial Transverse Stability of a High-Speed Transport Trimaran (2012)
- 2.4 An Investigation into the Wave Resistance of High-Speed Trimarans (2003)
- 2.5 Calculation and Analysis of High-Speed Trimaran Maneuvering Motion Based on Potential Flow Theory (2013)
- 2.6 Numerical Analysis of Resistance Characteristics of and Flow Fields around Multihull Ships Based on Overset Grid Techniques (2011)
- 2.7 Research on Asymmetric Outrigger Hull Form Design and Resistance of Trimarans (2014)
- 2.8 Model Testing of Trimaran Resistances and the Semi-planing FPOT (Forward Placed Outrigger Trimaran) Concept
- 2.9 On the Hydrodynamic Characteristics of Trimarans and their Application (2012)
- 2.10 The Practical Design of a 102m Trimaran Ferry for the Taiwan Strait (2010)
- 2.11 High-Speed Multihull Craft for Medium-Distance Marine Transportation (2005)
- 2.12 The Evolution of Advanced SLICE® Technology Adapted to Satisfy the HSC Code and Commercial Requirements (2007)
- Chapter 3: Hydrofoil Craft
- 3.1 Hydrofoil Craft
- 3.2 Single Hydrofoil and Double Hydrofoil Craft
- 3.2.1 Two Kinds of High-Speed Passenger Ship with Bow Hydrofoil (2005)
- 3.2.2 Research on Developing a Fully Submerged, Automatically Controlled, and Waterjet-Driven Hydrofoil Craft, Model PS30 (2000)
- 3.3 Multihull Hydrofoil Craft
- 3.3.1. Development of Modern Hydrofoil-Assisted Multihulls
- 3.3.2. A Brief Introduction to a High-Speed Passenger Craft— Hydrofoil Assisted Catamaran Superfoil 40 (2005)
- 3.3.3 Design and Motion Prediction of a Hybrid Hydrofoil-Assisted Catamaran (2015)
- 3.3.4 Research on a New Type of Tri-hydrofoil Craft (2015)
- 3.4 The Research and Design of Hydrofoil Craft
- 3.4.1. Design of 2D Anti-Cavitation Hydrofoil by SectionReshaping (2012)
- 3.5 Application of Hydrofoil Craft
- 3.5.1. Design of Qinzhou II Fully-TransparentTri-Hydrofoil Sightseeing Tourist Boat (2015)
- Chapter 4: Air Lubrication Craft (ALC) and Air Cavity Craft (ACC)
- 4.1 Introduction to Air Lubrication Craft (ALC) and Air Cavity Craft (ACC)
- 4.2 The Contribution of Russian Inventors to the Development of Artificial Cavity Ships (2002)
- 4.3 Development and Performance of Air Cavity Craft (2004)
- 4.4 Air-Supported-Vessel (ASV) Technology with Improved Capabilities for a Wide Range of Fast Vessels Including Fast Offshore Crew boats and Support Crafts (2015)
- 4.5 Design and Exploitation of a New Air Bubble Navigation-Guide Ship (ACC) (2011)
- 4.6 Air Film (layer) Energy-Saving Technology and Application Tests on Ships (2013)
- 4.7 Mechanism Study of Use of an Artificial Bubble for the Drag Reduction of a High-Speed Boat (ACC) (2010)
- 4.8 An Experimental Investigation to Reduce Drag with the Aid of Air Injection on the Bottom of Planing Hull Craft (2000)
- 4.9 A Test Study on the Resistance Reduction of an Air Bubble Ship (2010)
- 4.10 Numerical Evaluation of the Resistance Reduction Effect for Three-Dimensional High-Speed Air Cavity Craft (2013)
- Chapter 5: Wing in Ground Effect Craft (WIG)
- 5.1 Introduction to Performance, Technology, and Application of Wing in Ground Effect Craft (WIG)
- 5.2 A WIG Craft as a Taiwan Straits Passenger Liner (2010)
- 5.3 Development, Operation, and Experience on the Practical WIG Craft Tianyi-1 (2003)
- 5.4 Design Features of WIG Craft EL-7 Ivolga and Test Results (2006)
- 5.5 Development of Air Cushion Technology—From Static Air Cushion (SAC) to Dynamic Air Cushion Wing in Ground Effect Technology (DACWIG) (2003)
- 5.6 A New Concept in Wing In Surface Effect Ships (2003)
- 5.7 Study on Stability of WIG Craft during Take-off and Landing (2006)
- 5.8 Study on Optimization of Automatic Control Parameters for WIG Craft (Ekranoplan) (2006)
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