Modern Control Engineering
International Edition
4th Edition
Published on 30. November 2001
Book
Paperback/Softback
970 pages
978-0-13-043245-2 (ISBN)
Description
For senior/graduate-level first courses in Control Theory in departments of Mechanical, Electrical, Aerospace, and Chemical Engineering.
This comprehensive treatment of the analysis and design of continuous-time control systems provides a gradual development of control theory-and shows how to solve all computational problems with MATLAB. It avoids highly mathematical arguments, and features an abundance of examples and worked problems throughout the text.
This comprehensive treatment of the analysis and design of continuous-time control systems provides a gradual development of control theory-and shows how to solve all computational problems with MATLAB. It avoids highly mathematical arguments, and features an abundance of examples and worked problems throughout the text.
More details
Edition
4th edition
Language
English
Place of publication
United States
Publishing group
Pearson Education (US)
Target group
Professional and scholarly
Dimensions
Height: 234 mm
Width: 203 mm
Thickness: 34 mm
Weight
1542 gr
ISBN-13
978-0-13-043245-2 (9780130432452)
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Classification
Other editions
New editions
Book
10/2009
5th Edition
Pearson
€71.79
Article exhausted; check for reprint
Previous edition
Katsuhiko Ogata
Modern Control Engineering
Book
09/1996
3rd Edition
Prentice Hall
€47.03
Article exhausted; check for reprint
Content
(NOTE: Each chapter begins with Introduction and concludes with Example Problems and Solutions and Problems.)
1. Introduction to Control Systems.
Examples of Control Systems. Closed-Loop Control versus Open-Loop Control. Outline of the Book.
2. The Laplace Transform.
Review of Complex Variables and Complex Functions. Laplace Transformation. Laplace Transform Theorems. Inverse Laplace Transformation. Partial-Fraction Expansion with MATLAB. Solving Linear, Time-Invariant, Differential Equations.
3. Mathematical Modeling of Dynamic Systems.
Transfer Function and Impulse-Response Function. Automatic Control Systems. Modeling in State Space. State-Space Representation of Dynamic Systems. Transformation of Mathematical Models with MATLAB. Mechanical Systems. Electrical and Electronic Systems. Signal Flow Graphs. Linearization of Nonlinear Mathematical Models.
4. Mathematical Modeling of Fluid Systems and Thermal Systems.
Liquid-Level Systems. Pneumatic Systems. Hydraulic Systems. Thermal Systems.
5. Transient and Steady-State Response Analyses.
First-Order Systems. Second-Order Systems. Higher-Order Systems. Transient-Response Analysis with MATLAB. An Example Problem Solved with MATLAB. Routh's Stability Criterion. Effects of Integral and Derivative Control Actions on System Performance. Steady-State Errors in Unity-Feedback Control Systems.
6. Root-Locus Analysis.
Root-Locus Plots. Summary of General Rules for Constructing Root Loci. Root-Locus Plots with MATLAB. Positive-Feedback Systems. Conditionally Stable Systems. Root Loci for Systems with Transport Lag.
7. Control Systems Design by the Root-Locus Method.
Preliminary Design Considerations. Lead Compensation. Lag Compensation. Lag-Lead Compensation. Parallel Compensation.
8. Frequency-Response Analysis.
Bode Diagrams. Plotting Bode Diagrams with MATLAB. Polar Plots. Drawing Nyquist Plots with MATLAB. Log-Magnitude-versus-Phase Plots. Nyquist Stability Criterion. Stability Analysis. Relative Stability. Closed-Loop Frequency Response of Unity-Feedback Systems. Experimental Determination of Transfer Functions.
9. Control Systems Design by Frequency Response.
Lead Compensation. Lag Compensation. Lag-Lead Compensation. Concluding Comments.
10. PID Controls and Two-Degrees-of-Freedom Control Systems.
Tuning Rules for PID Controllers. Computational Approach to Obtain Optimal Sets of Parameter Values. Modifications of PID Control Schemes. Two-Degrees-of-Freedom Control. Zero-Placement Approach to Improve Response Characteristics.
11. Analysis of Control Systems in State Space.
State-Space Representations of Transfer-Function Systems. Transformation of System Models with MATLAB. Solving the Time-Invariant State Equation. Some Useful Results in Vector-Matrix Analysis. Controllability. Observability.
12. Design of Control Systems in State Space.
Pole Placement. Solving Pole-Placement Problems with MATLAB. Design of Servo Systems. State Observers. Design of Regulator Systems with Observers. Design of Control Systems with Observers. Quadratic Optimal Regulator Systems.
References.
Index.
1. Introduction to Control Systems.
Examples of Control Systems. Closed-Loop Control versus Open-Loop Control. Outline of the Book.
2. The Laplace Transform.
Review of Complex Variables and Complex Functions. Laplace Transformation. Laplace Transform Theorems. Inverse Laplace Transformation. Partial-Fraction Expansion with MATLAB. Solving Linear, Time-Invariant, Differential Equations.
3. Mathematical Modeling of Dynamic Systems.
Transfer Function and Impulse-Response Function. Automatic Control Systems. Modeling in State Space. State-Space Representation of Dynamic Systems. Transformation of Mathematical Models with MATLAB. Mechanical Systems. Electrical and Electronic Systems. Signal Flow Graphs. Linearization of Nonlinear Mathematical Models.
4. Mathematical Modeling of Fluid Systems and Thermal Systems.
Liquid-Level Systems. Pneumatic Systems. Hydraulic Systems. Thermal Systems.
5. Transient and Steady-State Response Analyses.
First-Order Systems. Second-Order Systems. Higher-Order Systems. Transient-Response Analysis with MATLAB. An Example Problem Solved with MATLAB. Routh's Stability Criterion. Effects of Integral and Derivative Control Actions on System Performance. Steady-State Errors in Unity-Feedback Control Systems.
6. Root-Locus Analysis.
Root-Locus Plots. Summary of General Rules for Constructing Root Loci. Root-Locus Plots with MATLAB. Positive-Feedback Systems. Conditionally Stable Systems. Root Loci for Systems with Transport Lag.
7. Control Systems Design by the Root-Locus Method.
Preliminary Design Considerations. Lead Compensation. Lag Compensation. Lag-Lead Compensation. Parallel Compensation.
8. Frequency-Response Analysis.
Bode Diagrams. Plotting Bode Diagrams with MATLAB. Polar Plots. Drawing Nyquist Plots with MATLAB. Log-Magnitude-versus-Phase Plots. Nyquist Stability Criterion. Stability Analysis. Relative Stability. Closed-Loop Frequency Response of Unity-Feedback Systems. Experimental Determination of Transfer Functions.
9. Control Systems Design by Frequency Response.
Lead Compensation. Lag Compensation. Lag-Lead Compensation. Concluding Comments.
10. PID Controls and Two-Degrees-of-Freedom Control Systems.
Tuning Rules for PID Controllers. Computational Approach to Obtain Optimal Sets of Parameter Values. Modifications of PID Control Schemes. Two-Degrees-of-Freedom Control. Zero-Placement Approach to Improve Response Characteristics.
11. Analysis of Control Systems in State Space.
State-Space Representations of Transfer-Function Systems. Transformation of System Models with MATLAB. Solving the Time-Invariant State Equation. Some Useful Results in Vector-Matrix Analysis. Controllability. Observability.
12. Design of Control Systems in State Space.
Pole Placement. Solving Pole-Placement Problems with MATLAB. Design of Servo Systems. State Observers. Design of Regulator Systems with Observers. Design of Control Systems with Observers. Quadratic Optimal Regulator Systems.
References.
Index.