New York, NY : , : Springer New York : , : Imprint : Birkhäuser, , 2014

0-8176-4893-3

1 online resource (369 p.)

Control Engineering, , 2373-7719

629.8

System theory

Control engineering

Robotics

Mechatronics

Vibration

Dynamical systems

Dynamics

Applied mathematics

Engineering mathematics

Engineering design

Systems Theory, Control

Control, Robotics, Mechatronics

Vibration, Dynamical Systems, Control

Mathematical and Computational Engineering

Engineering Design

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Preface -- Introduction: intuitive theory of sliding mode control -- Conventional Sliding Modes -- Conventional Sliding Mode Observers -- Second order sliding mode controllers and differentiators -- Analysis of sliding mode controllers in the frequency domain -- Higher order sliding mode controllers and differentiators -- Observation and Identification via HOSM-Observers -- Disturbance Observer Based Control: Aerospace Applications -- A Mathematical Preliminaries -- B Describing Functions -- C Linear Systems Theory -- D Lyapunov

Stability -- Bibliography.

The sliding mode control methodology has proven effective in dealing with complex dynamical systems affected by disturbances, uncertainties and unmodeled dynamics. Robust control technology based on this methodology has been applied to many real-world problems, especially in the areas of aerospace control, electric power systems, electromechanical systems, and robotics. Sliding Mode Control and Observation represents the first textbook that starts with classical sliding mode control techniques and progresses toward newly developed higher-order sliding mode control and observation algorithms and their applications. The present volume addresses a range of sliding mode control issues, including: *Conventional sliding mode controller and observer design *Second-order sliding mode controllers and differentiators *Frequency domain analysis of conventional and second-order sliding mode controllers *Higher-order sliding mode controllers and differentiators *Higher-order sliding mode observers *Sliding mode disturbance observer based control *Numerous applications, including reusable launch vehicle and satellite formation control, blood glucose regulation, and car steering control are used as case studies Sliding Mode Control and Observation is aimed at graduate students with a basic knowledge of classical control theory and some knowledge of state-space methods and nonlinear systems, while being of interest to a wider audience of graduate students in electrical/mechanical/aerospace engineering and applied mathematics, as well as researchers in electrical, computer, chemical, civil, mechanical, aeronautical, and industrial engineering, applied mathematicians, control engineers, and physicists. Sliding Mode Control and Observation provides the necessary tools for graduate students, researchers and engineers to robustly control complex and uncertain nonlinear dynamical systems. Exercises provided at the end of each chapter make this an ideal text for an advanced course taught in control theory.