1 控制系统的数学描述 1.1 微分方程 1.2 传递函数 1.3 状态空间描述 1.4 模型转换 2 控制系统的校正 2.1 单变量系统的两种主要校正方式 2.2 PI、PD、PID 校正 2.3 串联校正举例 3 MATLAB 在自动控制系统中的应用 3.1 概述 3.2 控制系统函数全集 3.3 应用实例 4 SIMULINK 简介 4.1 引导 4.2 SIMULINK 模型的构建 5 自动控制系统设计任务 5.1 任务一 5.2 任务二 5.3 任务三 5.4 任务四 6 附录 6.1 时域分析例题及程序 6.2 根轨迹分析例题及程序 6.3 频域分析例题及程序

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

3.6.1 稳态误差的定义 3.6.2 系统类型 3.6.3 扰动作用下的稳态误差

6.3.1 串联超前校正（基于频率响应法） 6.3.2 串联滞后校正(基于频率响应法) 6.3.3 串联滞后-超前校正

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

本章讨论另一命题，即如何根据系统预先给定的性能指标，去设计一个能满足性能要求的控制系统。基于一个控制系统可视为由控制器和被控对象两大部分组成，当被控对象确定后，对系统的设计实际上归结为对控制器的设计，这项工作称为对控制系统的校正

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

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

The OP07 is a precision operational amplifier with Ultra Low offset Voltage: 10uV for the OPO7A), input offset drift of 0. 2uv/C an Ultra Low Offset Voltage Drift0.2μ° put bias current of 0.7nA the wide inp o Ultra Stable vs. Time: 0.2u V/Month 110dB minimum(OP07A), plus high input Ultra L。wNo|e:035

一、现实生活中,我们经常需要获取物体运动的速度,比如:汽车是否超速?摩托车的速度表,控制系统中电机的转速等等。 二、实际测量中线位移的测量比较麻烦(测量装置尺寸很大),一般转换为角位移的测量。同样,线速度的测量一般转换为角速度的测量。这种转换很容易,比如使用一个从动轮即可。 三、思考:如何获得机器人当前运行的速度 Industry Training Center