Synopses & Reviews
Underwater vehicles present some difficult and very particular control system design problems. These are often the result of nonlinear dynamics and uncertain models, as well as the presence of sometimes unforeseeable environmental disturbances that are difficult to measure or estimate.
Autonomous Underwater Vehicles: Modeling, Control Design, and Simulation outlines a novel approach to help readers develop models to simulate feedback controllers for motion planning and design. The book combines useful information on both kinematic and dynamic nonlinear feedback control models, providing simulation results and other essential information, giving readers a truly unique and all-encompassing new perspective on design.
Includes MATLAB? Simulations to Illustrate Concepts and Enhance Understanding
Starting with an introductory overview, the book offers examples of underwater vehicle construction, exploring kinematic fundamentals, problem formulation, and controllability, among other key topics. Particularly valuable to researchers is the book's detailed coverage of mathematical analysis as it applies to controllability, motion planning, feedback, modeling, and other concepts involved in nonlinear control design. Throughout, the authors reinforce the implicit goal in underwater vehicle design?to stabilize and make the vehicle follow a trajectory precisely.
Fundamentally nonlinear in nature, the dynamics of AUVs present a difficult control system design problem which cannot be easily accommodated by traditional linear design methodologies. The results presented here can be extended to obtain advanced control strategies and design schemes not only for autonomous underwater vehicles but also for other similar problems in the area of nonlinear control.
Synopsis
Highlighting the unique and difficult design and control problems related to autonomous underwater vehicles (AUVs), this book explains the impact of nonlinear dynamics, uncertain models, and unforeseeable environmental interferences and disturbances on AUV control. It emphasizes the importance of vehicle adherence to a precise trajectory whether that trajectory is preprogrammed, derived by a knowledge-based system in response to the environment, or specified by a human supervisor. Contributions consider motion planning, nonlinear controllability, and nonlinear feedback controller design systems, and they emphasize high-level planning and reliance on dynamic control to guarantee stability and consistent performance.