Book description
The definitive guide toadvanced control system design
Advanced Modern Control System Theory and Design offers the most comprehensive treatment of advanced control systems available today. Superbly organized and easy to use, this book is designed for an advanced course and is a companion volume to the introductory text, Modern Control System Theory and Design, Second Edition (or any other introductory book on control systems). In addition, it can serve as an excellent text for practicing control system engineers who need to learn more advanced control systems techniques in order to perform their tasks.
Advanced Modern Control Systems Theory and Design briefly reviews introductory control system analysis concepts and then presents the methods for designing linear control sys-tems using single-degree and two-degrees-of-freedom compensation techniques. The very important subjects of modern control system design using state-space, pole placement, Ackermann's formula, estimation, robust control, and H8 techniques are then presented. The following crucial subjects are then covered in the presentation:
* Digital Control System Analysis and Design-extends the continuous concepts presented to discrete systems
* Nonlinear Control System Design-extends the linear concepts presented tononlinear systems
* Introduction to Optimal Control Theory and Its Applications-presents such key topics as dynamic programming and the maximum principle, as well as applications to the space attitude control problem and the lunar soft-landing problem
* Control System Design Examples: Complete Case Studies-presents the complete case studies of five control system design examples that illustrate practical design projects
Other notable features of this volume are:
* Free MATLAB software containing problem solutions which can be retrieved from the Mathworks, Inc. anonymous FTP server at ftp://ftp.mathworks.com/pub/books/advshinners
* MATLAB programs and a tutorial on the use of MATLAB incorporated directly into the text
* An extensive set of worked-out, illustrative solutions added in dedicated sections at the end of chapters
* End-of-chapter problems-one-third with answers to facilitate self-study
* A solutions manual containing solutions to the remaining two-thirds of the problems available from the Wiley editorial department.
Table of contents
- Cover Page
- Title Page
- Copyright
- Dedication
- Contents
- PREFACE
-
1: INTRODUCTION
- 1.1. INTRODUCTION
- 1.2. GOAL OF ADVANCED MODERN CONTROL SYSTEM THEORY AND DESIGN
- 1.3. CONTROL SYSTEM PERFORMANCE OBJECTIVES
- 1.4. THE PROCEDURE FOR DESIGNING A CONTROL SYSTEM
- 1.5. OUTUNE OF ADVANCED MODERN CONTROL SYSTEM THEORY AND DESIGN
- 1.6. ADVANCED MODERN CONTROL SYSTEM THEORY ANDDESIGN TOOLBOX
- 1.7. ILLUSTRATIVE PROBLEMS AND SOLUTIONS [ 1 ]
- PROBLEMS
- REFERENCES
-
2: LINEAR CONTROL-SYSTEM COMPENSATION AND DESIGN
- 2.1. INTRODUCTION
- 2.2. CASCADE-COMPENSATION TECHNIQUES
- 2.3. MINOR-LOOP FEEDBACK-COMPENSATION TECHNIQUES
- 2.4. PROPORTIONAL-PLUS-INTEGRAL-PLUS DERIVATIVE (PID) COMPENSATORS
- 2.5. EXAMPLE FOR THEDESIGN OF A SECOND-ORDER CONTROL SYSTEM
- 2.6. COMPENSATION AND DESIGN USING THE BODE-DIAGRAM METHOD
- 2.7. APPROXIMATE METHODS FOR PRELIMINARY COMPENSATION AND DESIGN USING THE BODE DIAGRAM
- 2.8. COMPENSATION AND DESIGN USING THE NICHOLS CHART
- 2.9. COMPENSATION AND DESIGN USING THE ROOT-LOCUS METHOD
- 2.10. TRADEOFFS OF USING VARIOUS CASCADE-COMPENSATION METHODS AND MINOR-LOOP FEEDBACK
- 2.11. ILLUSTRATIVE PROBLEMS AND SOLUTIONS
- PROBLEMS
- REFERENCES
-
3: MODERN CONTROL-SYSTEM DESIGN USING STATE-SPACE, POLE PLACEMENT, ACKERMANN'S FORMULA, ESTIMATION, ROBUST CONTROL, AND H ∞ TECHNIQUES
- 3.1. INTRODUCTION
- 3.2. POLE-PLACEMENT DESIGN USING LINEAR-STATE-VARIABLE FEEDBACK
- 3.3. CONTROLLER DESIGN USING POLE PLACEMENT AND LINEAR-STATE-VARIABLE FEEDBACK TECHNIQUES
- 3.4. CONTROLLABILITY
- 3.5. OBSERVABILITY
- 3.6. ACKERMANN'S FORMULA FOR DESIGN USING POLE PLACEMENT [ 5 – 7 ]
- 3.7. ESTIMATOR DESIGN IN CONJUNCTION WITH THE POLE PLACEMENT APPROACH USING UNEAR-STATE-VARIABLE FEEDBACK
- 3.8. COMBINED COMPENSA FOR DESIGN INCLUDING A CONTROLLER AND AN ESTIMATOR FOR A REGULATOR SYSTEM
- 3.9. EXTENSION OF COMBINED COMPENSATOR DESIGN INCLUDING A CONTROLLER AND AN ESTIMATOR FOR SYSTEMS CONTAINING A REFERENCE INPUT
- 3.10. ROBUST CONTROL SYSTEMS [ 10 – 14 ]
- 3.11. AN INTRODUCTION TO H ∞ CONTROL CONCEPTS [ 16 , 17 ]
- 3.12. FOUNDATIONS OF H ∞ CONTROL THEORY
- 3.13. LINEAR ALGEBRAIC ASPECTS OF CONTROL-SYSTEM DESIGN COMPUTATIONS [ 22 – 25 ]
- 3.14. ILLUSTRATIVE PROBLEMS AND SOLUTIONS
- PROBLEMS
- REFERENCES
-
4: DIGITAL CONTROL-SYSTEM ANALYSIS AND DESIGN
- 4.1. INTRODUCTION
- 4.2. CHARACTERISTICS OF SAMPLING
- 4.3. DATA EXTRAPOLATORS
- 4.4. z -TRANSFORM THEORY
- 4.5. z -TRANSFORM BLOCK-DIAGRAM ALGEBRA
- 4.6. CHARACTERISTIC RESPONSE OF A SAMPLER AND ZERO-ORDER HOLD COMBINATION
- 4.7. STABILITYANALYSIS USING THE NYQUIST DIAGRAM
- 4.8. STABILITY DETERMINATION USING MATHEMATICAL TESTS
- 4.9. STABILITY ANALYSIS AND DESIGN USING THE BODE DIAGRAM
- 4.10. STABIUTY ANALYSIS AND DESIGN USING THEROOT-LOCUS DIAGRAM
- 4.11. BODE AND ROOT-LOCUS DIAGRAMS FOR DISCRETE TIMESYSTEMS USING MATLAB [ 13 ]
- 4.12. RAGAZZINI'S METHOD
- 4.13. THE DIGITIZATION PROCESS AND THE DESIGN OF DIGITAL FILTERS [ 2 ]
- 4.14. SUMMARY
- 4.15. IUUSTRATIVE PROBLEMS AND SOLUTIONS
- PROBLEMS
- REFERENCES
-
5: NONLINEAR CONTROL-SYSTEM DESIGN
- 5.1. INTRODUCTION
- 5.2. NONLINEAR DIFFERENTIAL EQUATIONS
- 5.3. PROPERTIES OF LINEAR SYSTEMS THAT ARE NOT VALID FOR NONLINEAR SYSTEMS
- 5.4. UNIQUE CHARACTERISTICS OF NONLINEAR SYSTEMS
- 5.5. METHODS AVAILABLE FOR ANALYZING NONUNEAR SYSTEMS
- 5.6. UNEARIZING APPROXIMATIONS
- 5.7. DESCRIBING-FUNCTION CONCEPT
- 5.8. DERIVATION OF DESCRIBING FUNCTIONS FOR COMMON NONLINEARITIES
- 5.9. USE OF THE DESCRIBING FUNCTION TO PREDICT OSCILLATIONS
- 5.10. COMPENSATION AND DESIGN OF NONLINEAR CONTROL SYSTEMS USING DESCRIBING FUNCTIONS
- 5.11. DESCRIBING-FUNCTION ANALYSIS AND DESIGN USING MATLAB [ 29 ]
- 5.12. DIGITAL COMPUTER PROGRAMS FOR PERFORMING THE DESCRIBING-FUNCTION ANALYSIS
- 5.13. PIECEWISE-LINEAR APPROXIMATIONS
- 5.14. STATE-VARIABLE ANALYSIS: THE PHASE PLANE
- 5.15. CONSTRUCTION OF THE PHASE PORTRAIT
- 5.16. CHARACTERISTICS OF THE PHASE PORTRAIT
- 5.17. PHASE PLANE FOR SYSTEMS CONTAINING EXTERNAL FORCING FUNCTIONS
- 5.18. DESIGN OF NONLINEAR FEEDBACK CONTROL SYSTEMS USING THE STATE-VARIABLE PHASE-PLANE METHOD
- 5.19. DIGITAL COMPUTER PROGRAM FOR OBTAINING THE PHASE PLANE
- 5.20. LIAPUNOV'S STABIUTY CRITERIA
- 5.21. POPOV'S METHOD
- 5.22. GENERALIZED CIRCLE CRITERION
- 5.23. GUIDELINES FOR SELECTING THE “BEST” NONLINEAR CONTROL SYSTEM METHOD(S) PRESENTED FOR ANALYSIS AND DESIGN
- 5.24. ILLUSTRATIVE PROBLEMS AND SOLUTIONS
- PROBLEMS
- REFERENCES
-
6: INTRODUCTION TO OPTIMAL CONTROL THEORY AND ITS APPLICATIONS
- 6.1. INTRODUCTION
- 6.2. CHARACTERISTICS OF THE OPTIMAL CONTROL PROBLEM
- 6.3. CALCULUS OF VARIATIONS
- 6.4. DYNAMIC PROGRAMMING
- 6.5. PONTRYAGIN'S MAXIMUM PRINCIPLE
- 6.6. APPLICATION OF THE MAXIMUM PRINCIPLE TO THE SPACE ATTITUDE-CONTROL PROBLEM
- 6.7. APPLICATION OF THE MAXIMUM PRINCIPLE TO THE LUNAR SOFT-LANDING PROBLEM
- 6.8. ILLUSTRATIVE PROBLEMS AND SOLUTIONS
- PROBLEMS
- REFERENCES
-
7: CONTROL-SYSTEM DESIGN EXAMPLES: COMPLETE CASE STUDIES
- 7.1. INTRODUCTION
- 7.2. OUTLINE OF PROCEDURE FOR DESIGNING A CONTROL SYSTEM [ 1 , 2 ]
- 7.3. EXAMPLE 1: DESIGN FOR THE POSITIONING SYSTEM OF A TRACKING RADAR USING LINEAR AND NONLINEAR TECHNIQUES JOINTLY [ 1 ]
- 7.4. EXAMPLE 2: DESIGN OF AN ANGULAR CONTROL SYSTEM FOR A ROBOT'S JOINT
- 7.5. EXAMPLE 3: DESIGN OF THE CONTROLLER AND FULL-ORDER ESTIMATOR FOR A SPACE SATELLITE'S ATTITUDE-CONTROL SYSTEM WITH POLE PLACEMENT USING LINEAR-STATE-VARIABLE FEEDBACK
- 7.6. EXAMPLE 4: DESIGN OF A SAMPLED-DATA CONTROL SYSTEM FOR CONTROLLING THE TEMPERATURE OF A LIQUID IN A TANK
- 7.7. EXAMPLE 5: DESIGN OF A ROBUST CONTROL SYSTEM FOR CONTROLLING THE FLAPS OF A HYDROFOIL [ 6 – 10 ]
- PROBLEMS
- REFERENCES
-
APPENDIX A: TUTORIAL FOR THE EFFECTIVE USE OF MATLAB
- A.1. INTRODUCTION
- A.2. First Time Usage—Software For Engineering
- A.3. Rrst Time Usage—MATLAS Installation
- A.4. First Time Usage—Performance Tuning MATLAB
- A.5. First Time Usage—MATLAB Fundamental Concepts
- A.6. First Time Usage—Matrix Representations
- A.7. First Time Usage—MATLAB Fundamentals
- A.9. Summary of MATLAB and Advanced Modern Control System Theory and Design Toolbox Commands
- APPENDIX B: CHARACTERISTIC RESPONSES OF SECOND-ORDER CONTROL SYSTEMS
- APPENDIX C: STATIC ACCURACY
- ANSWERS TO SELECTED PROBLEMS
- INDEX
Product information
- Title: Advanced Modern Control System Theory and Design
- Author(s):
- Release date: September 1998
- Publisher(s): Wiley-Interscience
- ISBN: 9780471318576
You might also like
book
Computer-Aided Control Systems Design
This step-by-step guide emphasizes applying control fundamentals to practical industry systems such as the ALSTOM gasifier …
book
Electrical Engineer's Reference Book, 16th Edition
For ease of use, this edition has been divided into the following subject sections: general principles; …
book
Flight Dynamics and System Identification for Modern Feedback Control
Unmanned air vehicles are becoming increasingly popular alternatives for private applications which include, but are not …
book
Building Valve Amplifiers, 2nd Edition
Building Valve Amplifiers is a unique hands-on guide for anyone working with tube audio equipment--as an …