控制系統技術概論

本書的作者有長達10年的控制工程技術工作經歷，加之非常明確的編著目的——培養學生掌握閉環控制系統構建、控制器設計、系統現場調試等方面的技術與方法，使本書具有理論聯繫實際、工程背景強的基本特色和鮮明特點。 1.總體結構獨特，突出工程實踐； 全書正文由五部分組成，思路開闊，內容由淺入深，層次分明，系統性強。第一部分“引論”共四章，占全書除附錄外的23.3%篇幅，這在其他同類書籍中較為少見，有利於初學者對自動控制的概念、閉環系統的基本組成與常用部件、系統類型、控制的目的與評價標準等有一個全面、清晰的認識。 2.內容融合多門課程，結合技術標準； 本書以閉環控制系統的分析、設計為主線，涉及的被控對象包括電系統、氣動系統、液壓系統、熱力系統、機械系統等，將自動控制理論、自動檢測技術、自動檢測技術、電機氣動基礎、電力電子技術、過程控...(展開全部) 本書的作者有長達10年的控制工程技術工作經歷，加之非常明確的編著目的——培養學生掌握閉環控制系統構建、控制器設計、系統現場調試等方面的技術與方法，使本書具有理論聯繫實際、工程背景強的基本特色和鮮明特點。 1.總體結構獨特，突出工程實踐； 全書正文由五部分組成，思路開闊，內容由淺入深，層次分明，系統性強。第一部分“引論”共四章，占全書除附錄外的23.3%篇幅，這在其他同類書籍中較為少見，有利於初學者對自動控制的概念、閉環系統的基本組成與常用部件、系統類型、控制的目的與評價標準等有一個全面、清晰的認識。 2.內容融合多門課程，結合技術標準； 本書以閉環控制系統的分析、設計為主線，涉及的被控對象包括電系統、氣動系統、液壓系統、熱力系統、機械系統等，將自動控制理論、自動檢測技術、自動檢測技術、電機氣動基礎、電力電子技術、過程控制系統、運動控制系統、電氣控制與PLC等多門課程融合在一起，形成一個有機的整體。 3.論述深度把握合理，採用啟發性方式敘述； 書中每章前都列出該章學習目的和需要重點掌握的內容，便於讀者目標明確地學習，並自我衡量是否達到本章學習要求。全書的16章中有14章都引論。引論的內容起到如下幾個作用：①概括全章的內容；②承上啟下，提出問題，以便在此後的各節中逐一解決；③闡明重要要領。 4.插圖強調聯繫實際，習題側重工程訓練。 全書的插圖經過精心設計，直觀、清晰，有助於概念的理解。書中有相當數量的工程圖，如氣動控制閥的機械結構圖、工業傳送帶控制系統電氣控制原理圖等等，體現了與工程緊密聯繫的特點。一插圖配有較大篇幅的文明說明，一方面方便了讀者，另一一方面使正文的文字簡練。

Preface VII

PART0NE INTRODUCTIOI

CHAPTER I Basic Concepts and Terminology

1.1 Introduction

1.2 Block Diagrams and Transfer Functions

1.3 Open-Loop Control

1.4 Closed-Loop Control: Feedback

1.5 Control System Drawings

1.6 Nonlinearities

1.7 Benefits of Automatic Control

1.8 Load Changes

1.9 Damping and Instability

1.11 Criteria of Good Control

1.12 Block Diagram Simplification

CHAPTER 2 Types of Control

2.1 Introduction

2.2 Analog and Digital Control

2.3 Regulator and Follow-Up Systems

2.4 Process Control

2.5 Servomechanisms

2.6 Sequential Control

2.7 Numerical Control

2.8 Robotics

Contents

2.9 The Evolution of Control Systems

2.10 Examples of Control Systems

CHAPTER 3 The Common Elements of System Components

3.1 Introduction

3.2 Electrical Elements

3.3 Liquid Flow Elements

3.4 Gas Flow Elements

3.5 Thermal Elements

3.6 Mechanical Elements

CHAPTER 4 Laplace Transforms and Transfer Functions

4.1 Introduction

4.2 Input/Output Relationships

4.3 Laplace Transforms

4.4 Inverse Laplace Transforms

4.5 Transfer Functions

4.6 Initial and Final Value Theorems

4.7 Frequency Response: Bode Plots

PARTTW0 MEASUREMENT

CHAPTER 5 Measuring Instrument Characteristics

5.1 Introduction

5.2 Statistics

5.3 Operating Characteristics

5.4 Static Characteristics

5.5 Dynamic Characteristics

5.6 Selection Criteria

CHAPTER 6 Signal Conditioning

6.1 Introduction

6.2 The Operational Amplifier

6,3 Op-Amp Circuits

6.4 Analog Signal Conditioning

6.5 Digital Signaling Conditioning

CHAPTER 7 Position, Motion, and Force Sensors

7.1 Introduction

7.2 Position and Displacement Measurement

Contents

7.3 Velocity Measurement

7.4 Acceleration Measurement

7.5 Force Measurement

CHAPTER 8 Process Variable Sensors

8.1 Temperature Measurement

8.2 Flow Rate Measurement

8.3 Pressure Measurement

8.4 Liquid Level Measurement

PARTTHREE MANIPULATK

CHAPTER 9 Switches, Actuators, Valves, and Heaters

9.1 Mechanical Switching Components

9.2 Solid-State Components

9.3 Hydraulic and Pneumatic Valves and Actuators

9.4 Control Valves

9.5 Electric Heating Elements

CHAPTER I0 Electric Motors

10.1 Introduction

10.2 AC Motors

10.3 DC Motors

10.4 Stepping Motors

10.5 AC Adjustable-Speed Drives

10.6 DC Motor Amplifiers and Drives

PARTFOUR CONTR

CHAPTER 11 Control of Discrete Processes

11.1 Introduction

11.2 Time-Driven Sequential Processes

11.3 Event-Driven Sequential Processes

11.4 Time/Event-Driven Sequential Processes

CHAPTER 12 Programmable Logic Controllers

12.1 Introduction

12.2 PLC Hardwarev

Contents

12.3 PLC Programming and Operation

12.4 PLC Programming Functions

CHAPTER 13 Control of Continuous Processes

13.1 Introduction

13.2 Modes of Control

13.3 Electronic Analog Controllers

13.4 Digital Controllers

13.5 Advanced Control

13.6 Fuzzy Logic Controllers

PARTFIVE ANALYSIS AND DESIGN

CHAPTER 14 Process Characteristics

14.1 Introduction

14.2 The Integral or Ramp Process

14.3 The First-Order Lag Process

14.4 The Second-Order Lag Process

14.5 The Dead-Time Process

14.6 The First-Order Lag Plus Dead-Time Process

CHAPTER 15 Methods of Analysis

15.1 Introduction

15.2 Overall Bode Diagram of Several Components

15.3 Open-Loop Bode Diagrams

15.4 Closed-Loop Bode Diagrams

15.5 Error Ratio and Deviation Ratio

15.6 Computer-Aided Bode Plots

15.7 Stability

15.8 Gain and Phase Margin

15.9 Nyquist Stability Criterion

15.10 Root Locus

CHAPTER 16 Controller Design

16.1 Introduction

16.2 The Ultimate Cycle Method

16.3 The Process Reaction Method

16.4 Self-Tuning Adaptive Controllers

16.5 Computer-Aided PID Controller Design

16.6 Example Design of a Three-Loop Control System

16.7 Control System Compensation

Contents

APPENDIX A Properties at Materials

Properties of Solids

Melting Point and Latent Heat of Fusion

Properties of Liquids

Properties of Gases

Standard Atmospheric Conditions

APPENDIX B Units and Conversion

Systems of Units

Conversion Factors

APPENDIX C Binary Codes

Powers of 2

Octal and Binary Equivalents

Decimal, Hexadecimal, and Binary Equivalents

One's and Two's Complements

The Gray Code

Binary Codes for Decimal Digits

Seven-Bit ASCII Code

APPENDIX D Instrumentation Symbols and Identification

Purpose

Scope

Definition

Outline of the Identification System

APPENDIX E Complex Numbers

Introduction

Rectangular and Polar Forms of Complex Numbers

Conversion of Complex Numbers

Graphical Representation of Complex Numbers

Addition and Subtraction of Complex Numbers

Multiplication and Division of Complex Numbers

Integer Power of a Complex Number

Roots of a Complex Number

APPENDIX F Communications

Communication Interfaces

Local Area Networks

Communication Protocols