Time-delay systems : concepts, design and stability analysis /

Time-delay occurs in many physical, industrial and engineering systems such as biological systems, chemical systems, metallurgical processing systems, nuclear reactors, hydraulic systems and electrical networks, to name a few. The reason for the occurrence could be attributed to inherent physical ph...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Mahmoud, Magdi S. (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hauppauge, New York : Nova Science Publishers, Inc., [2018]
Colección:Quality control engineering and manufacturing.
Temas:
Time delay systems.
Automatic control.
Systèmes à retard.
Commande automatique.
TECHNOLOGY & ENGINEERING > Engineering (General)
Automatic control
Time delay systems
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Intro; TIME-DELAY SYSTEMSCONCEPTS, DESIGN ANDSTABILITY ANALYSIS; TIME-DELAY SYSTEMSCONCEPTS, DESIGN ANDSTABILITY ANALYSIS; CONTENTS; PREFACE; Chapter 1TIME-DELAY SYSTEMS:A GUIDED OUTLOOK; Abstract; 1. Introduction; 2. Typical Applications; 2.1. Models for Linear Time-Invariant Systems; 3. Notion of Stability; 4. Fundamental Stability Theorems; 5. Stability Results for Linear Delay Systems; 5.1. Augmented Lyapunov Functional; 5.2. Triple-Integral Lyapunov Functional; 5.3. Bounding Techniques; 6. Model Transformations; 7. Delay-Dependent Stabilization; 7.1. A Class of Nonlinear Systems
  • 8. Neural Networks9. Networked Control Systems; 9.1. State-Feedback Stabilization; 9.2. Observer-Based Feedback Stabilization; 9.3. Lyapunov-Based Sampled-Data Stabilization; Conclusion and FutureWork; References; Chapter 2CONTROLLING NONLINEAR TIME DELAYSYSTEMS; Abstract; 1. Introduction; 2. Control of Nonlinear Time Delay Systems; 2.1. Robust Stabilization of Nonlinear Time Delay Systemswith High-Order Polynomial Nonlinear Uncertainties; 2.2. Robust Control for a Class of Triangular Structure NonlinearTime Delay Systems via Razumikhin Lemma
  • 2.3. AdaptiveTracking Controller Design of Nonlinear Time DelaySystems with Unknown Dead-Zone Input2.4. OutputFeedback Control for StochasticNonlinear Time DelaySystems Using Dynamic Gain Technique; 3. Application to Chemical Reactor Systems; Conclusion and Outlook; References; Chapter 3RECENT ADVANCES IN POSITIVETIME-DELAY SYSTEMS; Introduction; 2. Notations and Preliminaries; 3. Discrete-Time Positive Systems with UnboundedDelays; 4. Continuous-Time Positive Systems with UnboundedDelays; 5. Decay Rate Analysis of Cone-Invariant Systems withUnbounded Delays
  • 6. Explicit Characterizations for Several Typical Cases7. Illustrative Example; Conclusion; References; Chapter 4 POLE CONSTRAINTS CONTROLFOR DELAYED DESCRIPTOR TYPE-2 FUZZY SYSTEMS; Abstract; 1. Introduction; 2. Preliminary Analysis; 3. Main Results; 4. Illustrative Example; Conclusion; Acknowledgment; References; Chapter 5NETWORKED CONTROL SYSTEMS:A RECENT ACCOUNT; Abstract; 1. Introduction; 2. Modeling of NCS; 2.1. Delays in NCS; 2.2. Packet Dropouts; 2.3. Variable Sampling/Transmission Intervals; 3. Control Over Networks; 3.1. Input Delay System Approach; 3.2. Switched System Approach
  • 4. Cloud Control SystemConclusion; References; Chapter 6STABILIZATION OF TIME DELAY SYSTEMS; Abstract; 1. Development on the Stabilization of Time DelaySystems; 1.1. Smith Predictor; 1.2. Reduction; 1.3. Linear Matrix Inequality Approach; 1.3.1. Discretized Lyapunov-Krasovskii Functional Method; 1.3.2. Model Transformations and Bounding Techniques; 1.3.3. Free-Weighting Matrices Method; 1.3.4. Jensen's Inequality; 1.3.5. Wirtinger-Based Integral Inequality; 2. Preliminaries; 3. Main Results; 3.1. State Feedback Control; Problem state feedback control

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