Anti-Disturbance Control for Systems with Multiple Disturbances

Content: Chapter 1. Developments in CHADC for systems with multiple disturbances --
chapter 2. Disturbance attenuation and rejection for nonlinear systems via DOBC --
chapter 3. Composite DOBC and H8 control for continuous models --
chapter 4. Composite DOBC and TSM control for nonlinear systems with disturbances --
chapter 5. Saturating composite DOBC and H8 control for discrete time delay systems --
chapter 6. Composite DOBC plus H8 control for MJSs with multiple disturbances --
chapter 7. Robust consensus of multi-agent systems with time delays and disturbances --
chapter 8. Hierarchical anti-disturbance adaptive controller design --
chapter 9. Estimation and rejection of unknown sinusoidal disturbances using TSNLDO --
chapter 10. Anti-disturbance PD attitude control and stabilization of flexible spacecraft --
chapter 11. Robust multi-objective initial alignment for INS with multiple disturbances --
chapter 12. Nonlinear initial alignment for INS with multiple disturbances --
chapter 13. Robust fault diagnosis method based on disturbance observer --
chapter 14. Adaptive fault diagnosis based on disturbance observer --
chapter 15. Anti-disturbance FTC for systems with multiple disturbances.
Abstract: ''Developing the essential theory for architecting and tackling issues faced during complex realistic engineering problems, this volume focuses on enhanced anti-disturbance control and filtering theory and applications. The book specifically addresses the novel disturbance observer based control (DOBC) methodologies for uncertain and nonlinear systems in time domain. It also examines novel anti-disturbance control and filtering with the composite hierarchical architecture to enhance control and filtering for the complex control systems with multiple disturbances. The book provides application examples, including flight control, robotic system, altitude control, and initial alignment to show how to use the theoretical methods in engineering''--

''Preface Unknown disturbances originating from various sources exist in all practical controlled systems, where unmodeled dynamics and uncertainties can also be formulated as an equivalent disturbance. As such, disturbance attenuation and rejection for nonlinear systems is a challenging objective in the area of control. Analysis and synthesis for non-linear control systems with disturbances has been one of the most active research fields in the past few decades. There are several drawbacks to be overcome in future studies on non-linear antidisturbance control. First, in engineering applications, the disturbance may originate from various sources and can be described by a composite form rather than a single variable. In this case, the H8 control may be too conservative to provide highly accurate control performance. On the other hand, disturbance rejection approaches usually need precise models for both the controlled system and the disturbance system. This confines their applications since the disturbance is also described by a single output variable from a precise exo-system and robustness is difficult to guarantee. For example, although disturbance observer based control is a valid disturbance rejection strategy for non-linear systems with harmonic disturbances, the performance of the system will deteriorate if the disturbance model cannot be described precisely. In filtering problems, both external noises, measurement noises and structure vibrations, and also unmodeled, nonlinear and uncertain dynamics are usually merged into the disturbance variable.''