04717nam 22005534a 450 991100476160332120200520144314.01-281-03282-497866110328210-08-051301-8(CKB)1000000000384701(EBL)316808(OCoLC)194019806(SSID)ssj0000072625(PQKBManifestationID)11997318(PQKBTitleCode)TC0000072625(PQKBWorkID)10102760(PQKB)10019887(MiAaPQ)EBC316808(EXLCZ)99100000000038470120020325d2002 uy 0engur|n|---|||||txtccrObservers in control systems a practical guide /George EllisSan Diego, CA Academic Pressc20021 online resource (275 p.)Description based upon print version of record.0-12-237472-X Includes bibliographical references and index.Front Cover; Observers in Control Systems: A Practical Guide; Copyright Page; Contents; Acknowledgements; Safety; Chapter 1. Control Systems and the Role of Observers; 1.1 Overview; 1.2 Preview of Observers; 1.3 Summary of the Book; Chapter 2. Control-System Background; 2.1 Control-System Structures; 2.2 Goals of Control Systems; 2.3 Visual ModelQ Simulation Environment; 2.4 Software Experiments: Introduction to Visual ModelQ; 2.5 Exercises; Chapter 3. Review of the Frequency Domain; 3.1 Overview of the s-Domain; 3.2 Overview of the z-Domain; 3.3 The Open-Loop Method3.4 A Zone-Based Tuning Procedure3.5 Exercises; Chapter 4. The Luenberger Observer: Correcting Sensor Problems; 4.1 What Is a Luenberger Observer?; 4.2 Experiments 4A-4C: Enhancing Stability with an Observer; 4.3 Predictor-Corrector Form of the Luenberger Observer; 4.4 Filer Form of the Luenberger Observer; 4.5 Designing a Luenberger Observer; 4.6 Introduction to Tuning an Observer Compensator; 4.7 Exercises; Chapter 5. The Luenberger Observer and Model Inaccuracy; 5.1 Model Inaccuracy; 5.2 Effects of Model Inaccuracy; 5.3 Experimental Evaluation; 5.4 ExercisesChapter 6. The Luenberger Observer and Disturbances6.1 Disturbances; 6.2 Disturbance Response; 6.3 Disturbance Decoupling; 6.4 Exercises; Chapter 7. Noise in the Luenberger Observer; 7.1 Noise in Control Systems; 7.2 Sensor Noise and the Luenberger Observer; 7.3 Noise Sensitivity when Using Disturbance Decoupling; 7.4 Reducing Noise Susceptibility in Observer-Based Systems; 7.5 Exercises; Chapter 8. Using the Luenberger Observer in Motion Control; 8.1 The Luenberger Observers in Motion Systems; 8.2 Observing Velocity to Reduce Phase Lag; 8.3 Using Observers to Improve Disturbance Response8.4 ExercisesReferences; Appendix A. Observer-Based Resolver Conversion in Industrial Servo Systems; Introduction; Resolvers and Traditional RDC; Converting the Signal; Observers; Applying the Observer to RDC; Advantages of Observer-Based Conversion; Conclusion; References; Appendix B. Cures for Mechanical Resonance in Industrial Servo Systems; Introduction; Two-Part Transfer Function; Low-Frequency Resonance; Velocity Control Law; Methods of Correction Applied to Low-Frequency Resonance; Conclusion; Acknowledgments; References; Appendix C. European Symbols for Block DiagramsPart I: Linear FunctionsPart II: Nonlinear Functions; Appendix D. Development of the Bilinear Transformation; Bilinear Transformation; Prewarping; Factoring Polynomials; Phase Advancing; Appendix E. Solutions of Exercises; Chapter 2; Chapter 3; Chapter 4; Chapter 5; Chapter 6; Chapter 7; Chapter 8; IndexObservers are digital algorithms that combine sensor outputs with knowledge of the system to provide results superior to traditional structures, which rely wholly on sensors. Observers have been used in selected industries for years, but most books explain them with complex mathematics. This book uses intuitive discussion, software experiments, and supporting analysis to explain the advantages and disadvantages of observers. If you are working in controls and want to improve your control systems, observers could be the technology you need and this book will give you a clear, thorough explanatiObservers (Control theory)Observers (Control theory)629.8Ellis George(George H.)348189MiAaPQMiAaPQMiAaPQBOOK9911004761603321Observers in control systems4388507UNINA