- 科学出版社
- 9787030471765
- 1-6
- 115448
- 46259603-2
- 平装
- 大大32开
- 2022-07
- 257
- 204
- 工学
- 控制科学与工程
- O231
- 自动化、电气
- 本科
内容简介
本书是“现代控制理论”双语教学教材,注重培养学生的国际视野和竞争能力。内容主要包括状态变量及状态空间表达式、线性空间变换、线性状态空间方程求解、系统稳定性、系统能控性、能观性以及状态反馈与状态观测。全书贯穿了MATLAB在线性系统中的应用方法。
目录
前言
Chapter 1 System Model
1.1 Introduction
1.2 Models of Systems
1.2.1 Differential Equation
1.2.2 Transfer Function
1.2.3 The State-space Model
1.3 Transition from One Mathematical Model to Another
1.3.1 From Differential Equation to Transfer Function for SISO Systems
1.3.2 From Transfer Function to Differential Equation for SISO Systems
1.3.3 From G(s) to g(t) and Vice Versa
1.3.4 From State Equations to Transfer Function Matrix
1.3.5 From Transfer Function Matrix to State Equations for SISO Systems
1.4 Summary
Appendix: Three Power Generation Models
Exercise
Chapter 2 Linear Transformation of State Vector
2.1 Linear Algebra
2.2 Transform to Diagonal Form and Jordan Form
Exercise
Chapter 3 Solution of State Space Model
3.1 Introduction
3.2 Solution of LTI State Equations
3.3 State Transfer Matrix
3.3.1 Properties
3.3.2 Calculating the state transition matrix
3.4 Discretization
3.5 Solution of Discrete-Time Equation
3.6 Summary
Exercise
Chapter 4 Stable Analysis
4.1 Introduction
4.2 Defimition
4.3 Stability Criteria
4.3.1 Lyapunov's Second Method
4.3.2 State Dynamics Stability Criteria for Continuous Linear Systems
4.3.3 State Dynamics Stability Criteria for Discrete Systems
4.4 Summary
Exercise
Chapter 5 Controllability and Observability
5.1 Introduction
5.2 Definition
5.2.1 Controllability
5.2.2 Observability
5.3 Criteria
5.3.1 Controllable Criteria
5.3.2 Controllable Examples
5.3.3 Observable Criteria
5.3.4 Observable Examples
5.4 Duality System
5.4.1 Definition
5.4.2 Properties of Duality Systems
5.5 Canonical Form
5.5.1 Controllability Canonical Form of Single-Input Systems
5.5.2 Observability Canonical Form of Single-Output Systems
5.5.3 Example
5.5.4 Observability and Controllability Canonical Form of Multi-input Multi-Output Systems
5.6 System Decomposition
5.6.1 Controllability Decomposition
5.6.2 Observability Decomposition
5.6.3 Controllability and Observability Decomposition
5.6.4 Minimum Realization
5.7 Summary
Exercise
Chapter 6 State Feedback and Observer
6.1 Introduction
6.2 Linear Feedback
6.2.1 State Feedback
6.2.2 Output Feedback
6.2.3 Feedback from output to x
6.3 Pole Assignment
6.3.1 Sufficient and Necessary Condition for Arbitrary Pole Assignment
6.3.2 Methods to Assign the Poles of a System
6.3.3 Examples
6.4 State Estimator
6.4.1 Introduction
6.4.2 State Estimator
6.5 State Feedback Based on State Estimator
6.6 Summary
Appendix: State Feedback and Observer for Main Steam-temperature Control in
Power Plant Steam-boiler Generation System
Exercises
参考文献
Chapter 1 System Model
1.1 Introduction
1.2 Models of Systems
1.2.1 Differential Equation
1.2.2 Transfer Function
1.2.3 The State-space Model
1.3 Transition from One Mathematical Model to Another
1.3.1 From Differential Equation to Transfer Function for SISO Systems
1.3.2 From Transfer Function to Differential Equation for SISO Systems
1.3.3 From G(s) to g(t) and Vice Versa
1.3.4 From State Equations to Transfer Function Matrix
1.3.5 From Transfer Function Matrix to State Equations for SISO Systems
1.4 Summary
Appendix: Three Power Generation Models
Exercise
Chapter 2 Linear Transformation of State Vector
2.1 Linear Algebra
2.2 Transform to Diagonal Form and Jordan Form
Exercise
Chapter 3 Solution of State Space Model
3.1 Introduction
3.2 Solution of LTI State Equations
3.3 State Transfer Matrix
3.3.1 Properties
3.3.2 Calculating the state transition matrix
3.4 Discretization
3.5 Solution of Discrete-Time Equation
3.6 Summary
Exercise
Chapter 4 Stable Analysis
4.1 Introduction
4.2 Defimition
4.3 Stability Criteria
4.3.1 Lyapunov's Second Method
4.3.2 State Dynamics Stability Criteria for Continuous Linear Systems
4.3.3 State Dynamics Stability Criteria for Discrete Systems
4.4 Summary
Exercise
Chapter 5 Controllability and Observability
5.1 Introduction
5.2 Definition
5.2.1 Controllability
5.2.2 Observability
5.3 Criteria
5.3.1 Controllable Criteria
5.3.2 Controllable Examples
5.3.3 Observable Criteria
5.3.4 Observable Examples
5.4 Duality System
5.4.1 Definition
5.4.2 Properties of Duality Systems
5.5 Canonical Form
5.5.1 Controllability Canonical Form of Single-Input Systems
5.5.2 Observability Canonical Form of Single-Output Systems
5.5.3 Example
5.5.4 Observability and Controllability Canonical Form of Multi-input Multi-Output Systems
5.6 System Decomposition
5.6.1 Controllability Decomposition
5.6.2 Observability Decomposition
5.6.3 Controllability and Observability Decomposition
5.6.4 Minimum Realization
5.7 Summary
Exercise
Chapter 6 State Feedback and Observer
6.1 Introduction
6.2 Linear Feedback
6.2.1 State Feedback
6.2.2 Output Feedback
6.2.3 Feedback from output to x
6.3 Pole Assignment
6.3.1 Sufficient and Necessary Condition for Arbitrary Pole Assignment
6.3.2 Methods to Assign the Poles of a System
6.3.3 Examples
6.4 State Estimator
6.4.1 Introduction
6.4.2 State Estimator
6.5 State Feedback Based on State Estimator
6.6 Summary
Appendix: State Feedback and Observer for Main Steam-temperature Control in
Power Plant Steam-boiler Generation System
Exercises
参考文献
