Modern Control Engineering

Contents

-Preface




-Chapter 1 Introduction to Control Systems

-1–1 Introduction
-1–2 Examples of Control Systems
-1–3 Closed-Loop Control versus Open-Loop Control
-1–4 Outline of the Book


-Chapter 2 Mathematical Modeling of Control Systems

-2–1 Introduction
-2–2 Transfer Function and impulse Response Function
-2–3 Atomatic Control Systems
-2–4 Modeling in state space
-2–5 State-Space Representation of Scalar Differential Equation System
-2–6 Transformation of Mathematical models with MATLAB
-2–7 Linearization of Nonlinear Mathematical Models




-Example Problems and Solutions Problems


-Chapter 3 Mathematical Modeling of Mechanical Systems and Electrical Systems

-3–1 Introduction
-3–2 Mathematical Modeling of Mechanical Systems
-3–3 Mathematical Modeling of Electrical Systems




-Example Problems and Solutions Problems


-Chapter 4 Mathematical Modeling of Fluid Systems and Thermal Systems

-4–1 Introduction
-4–2 Liquid-Level Systems
-4–3 Pneumatic Systems
-4–4 Hydraulic Systems
-4–5 Thermal Systems




-Example Problems and Solutions Problems


-Chapter 5 Transient and Steady-State Response Analyses

-5–1 Introduction
-5–2 First-Order Systems
-5–3 Second-Order Systems
-5–4 Higher Order Systems
-5–5 Transient-Response Analysis with MATLAB
-5–6 Routh's Stability Criterion
-5–7 Effects of Integral and Derivative Control Actions on System Performance
-5–8 Steady-State Errors in Unity-Feedback Control Systems




-Example Problems and Solutions Problems


-Chapter 6 Control Systems Analysis and design by the Root-Locus Method

-6–1 Introduction
-6–2 Root-Locus Plots
-6–3 plotting Root Loci with MATLAB
-6–4 Root-Locus Plots of Positive Feedback Systems
-6–5 Root-Locus Approach to control Systems Design
-6–6 Lead Compensation
-6–7 Lag Compensation
-6–8 Lag-Lead Compensation




-Example Problems and Solutions Problems


-Chapter 7 Control Systems Analysis and Design by the Frequency Response Method

-7–1 Introduction
-7–2 Bode Digrams
-7–3 Polar Plots
-7–4 Log-Magnitude-versus-Phase plots
-7–5 Nyquist Stability Criterion
-7–6 Stability Analysis
-7–7 Relative Stability Analysis
-7–8 Closed-Loop Frequency Response of Unity-feedback Systems
-7–9 Experimental Determination of Transfer functions
-7–10 Control Systems design by Frequency Response Approach
-7–11 Lead Compensation
-7–12 Lag Compensation
-7–13 Lag-Lead Compensation




-Example Problems and Solutions Problems


-Chapter 8 PID Controllers and Modified PID Controllers

-8–1 Introduction
-8–2 Ziegler- Nichols Rules for tuning PID controllers
-8–3 Design of PID Controllers with Frequency Response Approach
-8–4 Design of PID Controllers with Computational Optimization Approach
-8–5 Modification of PID Control Schemes
-8–6 Two-Degrees-of-freedom PID Control Schemes
-8–7 Zero Placement Approach to Improve Response




-Example Problems and Solutions Problems


-Chapter 9 Control Systems Analysis in State Space

-9–1 Introduction
-9–2 State-space Representations of Transfer-Function Systems
-9–3 Transformation of System Models with MATLAB
-9–4 Solving the Time-Invariant State Equation
-9–5 Some Useful Results in vector-Matrix Analysis
-9–6 Controllability
-9–7 Observability




-Example Problems and Solutions Problems


-Chapter 10 Control Systems Design of in State Space

-10–1 Introduction
-10–2 Pole Placement
-10–3 Solving Pole-Placement Problems with MATLAB
-10–4 Design of Servo Systems
-10–5 State Observers
-10–6 Design of Regulator Systems with Observers
-10–7 Design of Control Systems with Observers
-10–8 Quadratic Optimal Regulator Systems
-10–9 Robust Control Solutions




-Example Problems and Solutions Problems




Appendix A Appendix B Appendix C References Index