2-1 控制系统的时域数学模型 2-2 控制系统的复数域数学模型 2-3 控制系统的结构图与信号流图

System compensation is the process of designing a controller that will produce an acceptable transient response while maintaining a desired steady-state accuracy .These two design objectives are conflicting in most systems ,since small errors imply high gains reduce system stability and may even drive the system unstable .Compensation may be thought of as the process of increasing the stability of a system without reducing its accuracy below minimum acceptable standards

1 Introduction 2 Deterministic Dynamic Programming and Viscosity Solutions 2.1 Introduction 2.2 Value Functions are Viscosity Solutions 2.3 Comparison and Uniqueness 3 Stochastic Control 3.1 Some Probability Theory 3.2 Controlled State Space Models 3.3 Filtering 3.4 Dynamic Programming - Case I : Complete State Information 3.5 Dynamic Programming - Case II : Partial State Information 3.6 Two Continuous Time Problems 4 Robust Control 4.1 Introduction and Background 4.2 The Standard Problem of H∞ Control 4.3 The Solution for Linear Systems 4.4 Risk-Sensitive Stochastic Control and Robustness 5 Optimal Feedback Control of Quantum Systems 5.1 Preliminaries 5.2 The Feedback Control Problem 5.3 Conditional Dynamics 5.4 Optimal Control 5.5 Appendix: Formulas for the Two-State System with Feedback Example 6 Optimal Risk-Sensitive Feedback Control of Quantum Systems 6.1 System Model

3.1 Introduction 3.2 Typical test signals for time response of control systems 3.3 First –Order Systems 3.4 Performance of a Second-Order System 3.5 Concept of Stability 3.6 The Relative Stability of Feedback Control Systems

Frequency response is the analysis of the response of systemswhen subjected to a sinusoidal change in input. When a linear system is subjected to a sinusoidal input, its ultimate response is also a sustained sinusoidal wave, with the same frequency. The figure below compares the output response of a system (solid line) with a sinusoidal input (dashed line) disturbing the system

一、 非线性系统的特征与定义 二、 非线性对系统性能的影响 三、 非线性系统的分析方法

频率响应法是以传递函数为基础的一种控制系统分析方法，与上 一章介绍的根轨迹法一样，它也是一种工程方法。 能根据系统的开环频率特性图形直观地分析系统的闭环响应；还 能判别某些环节或参数对系统性能的影响。 可以对基于机理模型的系统性能进行分析；还可以对来自于实验 数据的系统进行有效分析

7.1 问题的提出 7.2 系统校正的几种常见古典方法 7.3 系统校正的概念 7-4 超前校正及其参数的确定 7-5 滞后校正及其参数的确定 7-6 校正方法小结 7.7 PID模型及其控制规律分析 7.8几种改良的PID控制器

4.1 线性系统稳定性的基本概念 4.2 传递函数表示的系统稳定性判定 4.3线性系统稳态误差的计算 4.4 本章小结

6-1 频率特性的概念 6-2 典型环节频率特性的绘制 6-3 系统开环频率特性的绘制 6-4 奈奎斯特稳定判据 6-5 最小相位系统的Bode图的应用 6-6 闭环频率特性