正版 自动控制原理 李彦梅,臧大进,郭凯 电子工业出版社 97871214

第 1 章绪论 ·····································1
1.1 自动控制的基本概念·················1
1.1.1 自动控制的定义·····················1
1.1.2 控制理论的发展过程················1
1.1.3 自动控制系统的组成················2
1.1.4 自动控制系统的基本控制
方式···································4
1.2 自动控制系统的分类·················6
1.3 对自动控制系统的基本要求········7
1.4 控制系统实例···························8
1.4.1 电冰箱制冷控制系统················8
1.4.2 函数记录仪···························9
1.4.3 炉温控制系统·····················.10
本章小结·····································.11
习题···········································.11
第2 章控制系统的数学模型············.13
2.1 微分方程的建立·····················.13
2.2 传递函数······························.14
2.2.1 传递函数的基本概念·············.14
2.2.2 传递函数的性质··················.15
2.2.3 典型环节及其传递函数··········.16
2.3 结构图·································.17
2.3.1 结构图的组成和绘制·············.17
2.3.2 结构图的等效变换················.18
2.4 信号流图······························.23
2.4.1 信号流图的基本概念·············.23
2.4.2 信号流图的绘制··················.24
2.4.3 梅森增益公式及其应用··········.25
本章小结·····································.26
习题···········································.27
第3 章线性系统的时域分析············.29
3.1 典型输入信号·······················.29
3.2 自动控制系统的时域性能
指标····································.31
3.3 一阶系统的时域分析··············.32
3.3.1 一阶系统的数学模型·············.32
3.3.2 一阶系统的单位阶跃响应及
性能分析··························.32
3.3.3 一阶系统的单位斜坡响应及
性能分析··························.33
3.3.4 一阶系统的单位加速度响应及
性能分析··························.33
3.3.5 一阶系统的单位脉冲响应及
性能分析··························.34
3.4 二阶系统的时域分析··············.34
3.4.1 二阶系统的数学模型·············.34
3.4.2 二阶系统的单位阶跃响应·······.35
3.4.3 欠阻尼二阶系统的动态性能
分析·······························.37
3.4.4 二阶系统的单位斜坡响应·······.42
3.4.5 二阶系统性能的改善·············.44
3.5 高阶系统的时域分析··············.46
3.6 稳定性分析···························.48
3.6.1 系统稳定的充分必要条件·······.49
3.6.2 劳斯判据··························.50
3.6.3 相对稳定性·······················.53
3.7 稳态误差······························.54
3.7.1 误差的定义·······················.54
3.7.2 输入引起的稳态误差·············.55
3.7.3 静态误差系数·····················.56
3.7.4 扰动作用下的稳态误差··········.59
3.7.5 改善系统稳态精度的方法········.60
本章小结·····································.62
习题···········································.63
第4 章根轨迹法 ····························.67
4.1 根轨迹的基本概念··················.67
4.1.1 根轨迹·····························.67
4.1.2 根轨迹方程························.68
4.2 根轨迹图的绘制法则··············.70
4.3 参数根轨迹···························.80
4.4 利用根轨迹分析系统性能········.82
4.4.1 已知根轨迹增益确定闭环极点
和传递函数························.82
4.4.2 已知系统性能指标确定闭环
极点································.83
4.4.3 增加开环零点对系统性能的
影响································.84
4.4.4 增加开环极点对系统性能的
影响································.87
本章小结·····································.88
习题···········································.89
第5 章线性系统的频域分析············.92
5.1 频率特性的基本概念··············.92
5.1.1 频率特性的定义··················.92
5.1.2 频率特性的表示方法·············.93
5.2 典型环节及系统频率特性········.94
5.2.1 典型环节的频率特性·············.95
5.2.2 开环系统的频率特性·············103
5.3 频域特性法的稳定性分析········109
5.3.1 奈奎斯特稳定判据················109
5.3.2 稳定裕度··························114
5.3.3 开环对数幅频特性曲线与
系统性能之间的关系·············117
本章小结·····································126
习题···········································127
第6 章控制系统设计······················131
6.1 概述····································131
6.2 PID 控制器··························.131
6.2.1 PID 控制器概述·················.131
6.2.2 比例控制器······················.131
6.2.3 比例微分控制器·················.132
6.2.4 积分控制器······················.133
6.2.5 比例积分控制器·················.133
6.2.6 比例积分微分控制器············.134
6.3 基于频域法的控制系统
设计···································.135
6.3.1 相位超前补偿····················.135
6.3.2 相位滞后补偿····················.137
6.3.3 相位滞后?超前补偿·············.138
6.3.4 串联补偿网络的期望幅频
特性设计方法····················.139
6.3.5 反馈补偿·························.146
本章小结····································.148
习题··········································.148
第7 章非线性系统分析·················.150
7.1 非线性系统概述···················.150
7.1.1 为什么研究非线性系统·········.150
7.1.2 非线性系统的特性··············.150
7.1.3 非线性系统的特点··············.153
7.1.4 非线性系统的分析方法·········.154
7.2 相平面法·····························.155
7.2.1 相平面的基本概念··············.155
7.2.2 相轨迹的绘制····················.156
7.2.3 奇点······························.158
7.2.4 非线性系统的相平面分析······.160
7.3 描述函数法··························.162
7.3.1 描述函数的基本概念············.162
7.3.2 典型非线性环节的描述函数····.166
7.3.3 非线性系统的描述函数法
分析······························.170
本章小结····································.176
习题··········································.177
第8 章线性离散系统 ····················.179
8.1 计算机控制系统概述·············.179
8.1.1 计算机控制系统简图·············179
8.1.2 计算机控制系统的组成··········180
8.1.3 计算机控制系统的特点··········180
8.1.4 信号的采样与恢复················181
8.2 计算机控制系统分析··············181
8.2.1 离散系统的稳定性分析··········181
8.2.2 线性采样系统稳定的充要
条件································183
8.2.3 离散系统的过渡响应分析········184
本章小结·····································186
习题···········································186
第9 章线性系统的状态空间分析······187
9.1 概述····································187
9.2 基本概念······························187
9.2.1 系统································187
9.2.2 系统状态空间描述················188
9.2.3 动态系统状态空间表达式的
一般形式··························190
9.3 线性多变量系统的运动
分析····································191
9.3.1 线性系统状态方程的解··········192
9.3.2 状态转移矩阵的性质·············192
9.4 Lyapunov 稳定性分析··············194
9.4.1 概述································194
9.4.2 Lyapunov 意义下的稳定性
问题······························.194
9.5 Lyapunov 稳定性理论············.195
9.5.1 Lyapunov 第一法················.195
9.5.2 Lyapunov 第二法················.196
本章小结····································.198
习题··········································.198
第10 章自动控制系统综合案例······.200
10.1 水位控制系统建模···············.200
10.1.1 单容水箱························.200
10.1.2 双容水箱和三容水箱··········.201
10.2 系统性能分析·····················.202
10.2.1 时域分析法的水位控制
系统分析························.202
10.2.2 根轨迹分析法和频域分析法的
水位控制系统分析·············.205
10.3 系统的校正和综合设计········.206
10.3.1 超前校正························.206
10.3.2 PID 控制器·····················.207
本章小结····································.208
附录A 拉普拉斯变换与反变换·········.209
附录B 常用函数的拉普拉斯
变换表······························.214
参考文献 ·······································.215

李彦梅，安庆师范大学机电系教工机械自动化党支部支部书记，教授，硕士生导师，主要从事智能控制与流量检测方面研究，公开发表学术论文20余篇，出版教材3部，主持（参与）省级以上教科研项目4项。

本书结合具体的控制系统介绍了自动控制的基本理论及工程应用。主要内容包括绪论、控制系统的数学模型、线性系统的时域分析、根轨迹法、线性系统的频域分析、控制系统设计、非线性系统分析、线性离散系统、线性系统的状态空间分析，以及自动控制系统综合案例。本书融入了课程思政内容，从实际应用出发，突出物理概念，减少数学公式推导；强化工程应用中常用知识点的介绍，采用不同方法对一个工程实例进行分析和设计，阐明自动控制原理的应用。