樊华,电子科技大学教授,博士生导师。主讲本科生专业基础课“电路分析与电子线路”“模拟电路基础”“电子电路基础”,主讲研究生专业基础课“模拟集成电路分析与设计”,近五年总计授课852学时,每年评教结果为五星(优秀),所授课程均为解决我国“缺芯”之痛、打通人才培养“最后一公里”的集成电路重要理论基础课程。主持8项教育部教改项目,4项校级教改项目,在IEEE Transactions on Education、《实验技术与管理》等期刊发表教学研究论文25篇。获第一届全国博士后创新创业大赛全国总决赛金奖(总分第一,2021年)、广东省“众创杯”创业创新大赛之科技海归领航赛特等奖(2022年)、四川省青年教师教学竞赛一等奖(2020年)、电子科技大学科技特别奖。入选四川省妇联女性科技典型,被评为全国创新创业优秀博士后。
电子电路基础/电子信息前沿技术丛书
- 书籍语言:简体中文
- 下载次数:1125
- 书籍类型:Epub+Txt+pdf+mobi
- 创建日期:2025-05-03 07:10:03
- 发布日期:2025-09-06
- 连载状态:全集
- 书籍作者:樊华
- ISBN:9787302680994
- 运行环境:pc/安卓/iPhone/iPad/Kindle/平板
- 下载地址
内容简介
为了实现课程知识体系内在的贯通和平滑过渡,电子科技大学将电子信息类专业的主干课“模拟电路基础”和“电路分析”整合成“电子电路基础”课程,本书是该课程英文课堂的配套教材。第一部分主要讲述电路的模型及基本的电路定律,“电路分析”实际上是对电路的模型进行分析,学习基尔霍夫等基本的电路定律才能对电路模型进行正确的数学求解。叠加定理是线性电路的一个重要定理,也是后续基本放大电路交直流分析的重要理论依据,同时配合戴维南定理和诺顿定理,大大简化电路分析的难度。第二部分进入模拟电路的学习,基本放大电路的时域分析和频域分析是“模拟电路基础”的核心,也是后续研究生课程“模拟集成电路分析与设计”的重要铺垫,对于有志于从事集成电路芯片设计的学生而言,基本放大电路这部分知识是重中之重,同时需要配合仿真工具强化理解。第三部分主要讲解应用集成运算放大器的范例,通过集成运算放大器和反馈可以实现对数、指数运算电路和乘法、除法运算电路,低通、高通、带通和带阻滤波电路,学生可以自行选择商用集成运放芯片搭建运算或者滤波电路,以加强实践能力。
本书可作为电子信息类、自动化类、电气类等相关专业的英文课堂配套教材,也可供相关领域的工程技术人员参考。
本书可作为电子信息类、自动化类、电气类等相关专业的英文课堂配套教材,也可供相关领域的工程技术人员参考。
作者简介
下载地址
目录
Chapter 1 Introduction
1.1 History
1.2 Overview
1.3 Simulation Tool
Chapter 2 Circuit Model
2.1 Lumped Circuit
2.2 Resistor and Its Circuit Mode
2.2.1 Resistor
2.2.2 Circuit Model of Resistor
2.2.3 Potentiometer and Circuit Mode
2.2.4 Switch and Its Circuit Mode
2.2.5 Generalization of Resistor Definition
2.3 Power Source and Its Circuit Model
2.3.1 Power Source
2.3.2 Circuit Model of Power Source
2.4 Inductor and Its Circuit Mode
2.4.1 Inductor
2.4.2 Circuit Model of an Inductor
2.4.3 Generalization of the Definition of Inductor
2.5 Capacitor and Its Circuit Mode
2.5.1 Capacitor
2.5.2 Capacitor Circuit Mode
2.5.3 Generalization of Capacitor Definition
2.6 Diode and Its Circuit Model
2.6.1 Diode
2.6.2 Main Parameters of Diodes
2.6.3 The Circuit Model of Diodes
2.6.4 Zener Diode
2.6.5 The Circuit Model of the Zener Diode
2.7 Field-Effect Transistor (FET) and Its Circuit Mode
2.7.1 Field-Effect Transistor (FET)
2.7.2 The Main Parameters of Enhanced Field-Effect Transistors
2.7.3 Field-Effect Transistor Circuit Mode
2.8 Bipolar Junction Transistor (BJT) and Its Circuit Model
2.8.1 Bipolar Junction Transistor (BJT)
2.8.2 Main Parameters of Transistor
2.8.3 Circuit Model of Transistor
2.9 Kirchhoff's Law
2.9.1 Kirchhoff's Current Law
2.9.2 Generalization of KCL
2.9.3 Kirchhoff's Voltage Law
2.9.4 Generalization of KVL
2.10 Simulation Experiment
2.10.1 Experimental Requirements and Purposes
2.10.2 Diode Voltage-Current Characteristic Circuit Problems
Chapter 3 Circuit Analysis Methods
3.1 Two Types of Constraints and Circuit Equations
3.1.1 Two Types of Constraints
3.1.2 Circuit Equations
3.2 The Three-Element Method for First-Order Circuits
3.2.1 First-Order RC Circuit
3.2.2 Properties of Exponent
3.3 Superposition Theorem and Its Application
3.3.1 Superposition Theorem
3.3.2 Application of Superposition Theorem
3.4 Network Equivalence with the Application of Thevenin's Theorem and Norton's Theorem
3.4.1 Network Equivalence
3.4.2 Thevenin's Theorem and Norton's Theorem
3.4.3 Application of Thevenin's Theorem and Norton's Theorem
……
Chapter 4 Basic Amplifier Circuits
Chapter 5 Multi-Stage Amplifier Circuits and Operational Amplifiers
Chapter 6 Operational Amplifiers
Chapter 7 Negative Feedback Amplifier Circuit
Chapter 8 Operational Circuits and Filtering Circuits
Chapter 9 Waveform Generating Circuit and Signal Conversion Circuit
Chapter 10 AC/DC Power Sources
1.1 History
1.2 Overview
1.3 Simulation Tool
Chapter 2 Circuit Model
2.1 Lumped Circuit
2.2 Resistor and Its Circuit Mode
2.2.1 Resistor
2.2.2 Circuit Model of Resistor
2.2.3 Potentiometer and Circuit Mode
2.2.4 Switch and Its Circuit Mode
2.2.5 Generalization of Resistor Definition
2.3 Power Source and Its Circuit Model
2.3.1 Power Source
2.3.2 Circuit Model of Power Source
2.4 Inductor and Its Circuit Mode
2.4.1 Inductor
2.4.2 Circuit Model of an Inductor
2.4.3 Generalization of the Definition of Inductor
2.5 Capacitor and Its Circuit Mode
2.5.1 Capacitor
2.5.2 Capacitor Circuit Mode
2.5.3 Generalization of Capacitor Definition
2.6 Diode and Its Circuit Model
2.6.1 Diode
2.6.2 Main Parameters of Diodes
2.6.3 The Circuit Model of Diodes
2.6.4 Zener Diode
2.6.5 The Circuit Model of the Zener Diode
2.7 Field-Effect Transistor (FET) and Its Circuit Mode
2.7.1 Field-Effect Transistor (FET)
2.7.2 The Main Parameters of Enhanced Field-Effect Transistors
2.7.3 Field-Effect Transistor Circuit Mode
2.8 Bipolar Junction Transistor (BJT) and Its Circuit Model
2.8.1 Bipolar Junction Transistor (BJT)
2.8.2 Main Parameters of Transistor
2.8.3 Circuit Model of Transistor
2.9 Kirchhoff's Law
2.9.1 Kirchhoff's Current Law
2.9.2 Generalization of KCL
2.9.3 Kirchhoff's Voltage Law
2.9.4 Generalization of KVL
2.10 Simulation Experiment
2.10.1 Experimental Requirements and Purposes
2.10.2 Diode Voltage-Current Characteristic Circuit Problems
Chapter 3 Circuit Analysis Methods
3.1 Two Types of Constraints and Circuit Equations
3.1.1 Two Types of Constraints
3.1.2 Circuit Equations
3.2 The Three-Element Method for First-Order Circuits
3.2.1 First-Order RC Circuit
3.2.2 Properties of Exponent
3.3 Superposition Theorem and Its Application
3.3.1 Superposition Theorem
3.3.2 Application of Superposition Theorem
3.4 Network Equivalence with the Application of Thevenin's Theorem and Norton's Theorem
3.4.1 Network Equivalence
3.4.2 Thevenin's Theorem and Norton's Theorem
3.4.3 Application of Thevenin's Theorem and Norton's Theorem
……
Chapter 4 Basic Amplifier Circuits
Chapter 5 Multi-Stage Amplifier Circuits and Operational Amplifiers
Chapter 6 Operational Amplifiers
Chapter 7 Negative Feedback Amplifier Circuit
Chapter 8 Operational Circuits and Filtering Circuits
Chapter 9 Waveform Generating Circuit and Signal Conversion Circuit
Chapter 10 AC/DC Power Sources