反馈控制系统(第5版 英文版) 出版时间:2012年版 内容简介 《反馈控制系统(第5版)(英文版)》以较小的篇幅深入浅出地讲解了经典控制理论和现代控制理论的主要内容。主要包括反馈控制的基本概念、根据物理定律等建立控制对象模型、控制对象模型的状态空间表示、单输入单输出控制系统的响应特性和主要性能指标、线性时不变系统的稳定性分析、控制系统的根轨迹分析与设计、控制系统的频域分析与设计、控制系统的极点配置、状态观测器设计、能控性和能观性、采样控制系统的分析与设计、非线性系统分析的描述函数法和相平面法等。《反馈控制系统(第5版)(英文版)》可作为高等院校从事自动化、电气工程及其自动化、机械工程及其自动化的工程技术人员等相关专业高年级本科生、研究生教材,也可供从事自动控制的研究人员、工程科技人员参考。 目录 Preface CHAPTER 1 Introduction 1.1 The Control Problem 1.2 Examples of Control Systems 1.3 Short History of Control References CHAPTER 2 Models of Physical Systems 2.1 System Modeling 2.2 E1ectrical Circuits 2.3 Block Diagrams and Signal F1ow Graphs 2.4 Mason's Gain Formula 2.5 Mechanical Translational Systems 2.6 Mechanical Rotational Systems 2.7 Electromechanical Systems 2.8 Sensors 2.9 Temperature-Control System 2.10 Analogous Systems 2.11 Transformers and Gears 2.12 Robotic Control System 2.13 System Identification 2.14 Linearization 2.15 Summary References Problems CHAPTER 3 State-Variable Models 3.1 State-Variable Modeling 3.2 Simulation Diagrams 3.3 Solution of Stare Equations 3.4 Transfer Functions 3.5 Similarity Transformations 3.6 Digital Simulation 3.7 Controls Software 3.8 Analog Simulation 3.9 Summary References Problems CHAPTER 4 System Responses 4.1 Time Response of first-Order Systems 4.2 Time Response of Second-Order Systems 4.3 Time Response Specifications in Design 4.4 Frequency Response of Systems 4.5 Time and Frequency Scaling 4.6 Response of Higher-Order Systems 4.7 Redneed-Order Models 4.8 Summary References Problems CHAPTER 5 Control一System Characteristics 5.1 Closed-Loop Control System 5.2 Stability 5.3 Sensitivity 5.4 Disturbance Rejection 5.5 Steady-State Accuracy 5.6 Transient Response 5.7 Closed-Loop Frequency Response 5.8 Summary References Problems CHAPTER 6 Stability Analysis 6.1 Routh-Hurwitz Stability Criterion 6.2 Roots of the Characteristic Equation 6.3 Stability by Simulation 6.4 Summary Problems CHAPTER 7 Root-Locus Analysis and Design 7.1 Root-Locus Principles 7.2 Some Root-Locus Techniques 7.3 Additional Root-Locus Techniques 7.4 Additional Properties of the Root Locus 7.5 other Configurations 7.6 Root-Locus Design 7.7 Phase-Lead Design 7.8 Analytical Phase-Lead Design 7.9 Phase-Lag Design 7.10 PID Design 7.11 Analytical PID Design 7.12 Complementary Root Locus 7.13 Compensator Realization 7.14 Summary References Problems CHAPTER 8 Frequency-Response Analysis 8.1 Frequency Responses 8.2 Bode Diagrams 8.3 Additional Terms 8.4 Nyquist Criterion 8.5 Application of the Nyquist Criterion 8.6 Relative Stability and the Bode Diagram 8.7 Closed-Loop Frequency Response 8.8 Summary References Problems CHAPTER 9 Frequency-Response Design 9.1 Control-System Specifications 9.2 Compensation 9.3 Gain Compensation 9.4 Phase-Lag Compensation 9.5 Phase-Lead Compensation 9.6 Analytical Design 9.7 Lag-Lead Compensation 9.8 PID Controller Design 9.9 Analytical PID Controller Design 9.10 PID Controller Implementation 9.11 Frequency-Response Software 9.12 Summary References Problems CHAPTER 10 Modern Control Design 10.1 Pole-Placement Design 10.2 Ackermann's Formula 10.3 State Estimation 10.4 Closed-Loop System Characteristics 10.5 Reduced-order Estimators 10.6 Controllability and observability 10.7 Systems with Inputs 10.8 Summary References Problems CHAPTER 11 Discrete-Time Systems 11.1 Discrete-Time System 11.2 Transform Methods 11.3 Theorems of the z-Transform 11.4 Solution 0f Difference Equations 11.5 Inverse z-Transform 11.6 Simulation Diagrams and Flow Graphs 11.7 State Variables 11.8 Solution of State Equations 11.9 Summary References Problems CHAPTER 12 Sampled-Data Systems 12.1 Sampled Data 12.2 Ideal Sampler 12.3 Properties 0f the Starred Transform 12.4 Data Reconstruction 12.5 Pulse Transfer Function 12.6 Open-Loop Systems Containing Digital Filters 12.7 Closed-Loop Discrete-Time Systems 12.8 Transfer Functions for Closed-Loop Systems 12.9 State Variables for Sampled-Data Systems 12.10 Summary References Problems CHAPTER 13 Analysis and Design of Digital Control Systems 13.1 Two Examples 13.2 Discrete System Stability 13.3 Jury's Test 13.4 Mapping the s-Plane into the z-Plane 13.5 Root Locus 13.6 Nyquist Criterion 13.7 Bilinear Transformation 13.8 Routh-Hurwitz Criterion 13.9 Bode Diagram 13.10 Steady-State Accuracy 13.11 Design 0f Digital Control Systems 13.12 Phase-Lag Design 13.13 Phase-Lead Design 13.14 Digital PID Controllers 13.15 Root-Locus Design 13.16 Emulation Design Methods 13.17 Summary References Problems CHAPTER 14 Pole-Assignment Design and State Estimation for Discrete-Time Systems 14.1 Introduction 14.2 Pole Assignment 14.3 State Estimtion 14.4 Reduced-Order observers 14.5 Current Observers 14.6 Controllability and Observability 14.7 Systems with Inputs 14.8 Summary References Problems CHAPTER 15 Nonlinear System Analysis 15.1 Nonlinear System Definitions and Properties 15.2 Review of the Nyquist Criterion 15.3 Describing Function 15.4 Derivations of Describing Functions 15.5 Use of the Describing Function 15.6 Stability Of Limit Cycles 15.7 Design 15.8 Application to other Systems 15.9 Linearization 15.10 Equilibrium States and Lyapunov Stability 15.11 State Plane Analysis 15.12 Linear-System Response 15.13 Summary References Problems APPENDICES A Matrices B Laplace Transform C Laplace Transform and z-Transform Tables D MATLAB®Commands Used in This Text E Answers to Selected Problems Index
