spContent=Circuits are important in electrical engineering because they process electrical signals. This course is designed to help you develop the knowledge and application skills needed to solve three types of circuit problems: analysis, design and evaluation.
Circuits are important in electrical engineering because they process electrical signals. This course is designed to help you develop the knowledge and application skills needed to solve three types of circuit problems: analysis, design and evaluation.
—— 课程团队
课程概述
Circuits Analysis and Electronics Illustrated is a first course in an undergraduate electronic information engineering in UESTC.
The topics covered include: resistive elements and networks, independent and dependent sources, diodes and MOS transistors, development of circuit models, and understanding the uses and limitations of various models, amplifiers, energy storage elements, dynamics of first- and second-order networks, design in the time and frequency domains, and analog circuits and applications.
It helps students to obtain the basic theory of electronic circuit and develop their engineering intuition.
授课目标
After successfully studying Circuits Analysis and Electronics Illustrated, students will be able to:
1. Understand the basic electrical engineering principles and abstractions on which the design of electronic systems is based. These include lumped circuit models, nonlinear circuits, and operational amplifiers.
2. Use these engineering abstractions to analyze and design simple electronic circuits such as active filter, amplifier, waveform generation circuit, etc.
3. Formulate and solve differential equations describing the time behavior of circuits containing energy storage elements. Use intuition to describe the approximate time and frequency behavior of circuits containing energy storage elements.
课程大纲
The Circuit Abstraction and Basic Concepts
课时目标:This chapter discusses the concept of abstraction and introduces the lumped circuit abstraction. It then introduces several ideal, lumped elements including resistors, voltage sources, and current sources. This chapter also introduces KVL and KCL. It then uses KVL and KCL to analyze simple resistive networks.
1.1 The Lumped Circuit Abstraction
1.2 Electrical Quantities and SI Units and Associated Variables Convention
1.3 Kirchhoff’s Laws
1.4 Ideal Voltage Sources and Current Sources
1.5 Ideal Wires and Resistors
1.6 Basic Method:2b
1.7 The Branch Method
Resistive Circuits
课时目标:This chapter discusses how to reduce and equivalent single port network and how to transform wye ↔ delta resistance networks. This chapter also introduces the dependent sources. It then analyze electric circuits containing dependent sources.
2.1 Series and Parallel Resistor Combinations
2.2 Network Reduction
2.3 Wye ↔ Delta Transformations
2.4 Dependent Sources and the Control Concept
Circuit Analysis Techniques
课时目标:This chapter presents more sophisticated methods for network analysis. This chapter also introduces general methods of analyzing circuits and the theorems that describe linear circuits.
3.1 Mesh-Current Analysis
3.2 Node-Voltage Analysis
3.3 Superposition
3.4 Thévenin’s Theorem and Norton’s Theorem
3.5 Ideal Wires and Resistors
3.6 Maximum Power Transfer Theorem
Analysis of Nonlinear Circuits
课时目标:This chapter introduces the nonlinear resistors such as diode and the analysis techniques of simple nonlinear circuits.
4.1 Introduction to Nonlinear Elements
4.2 Analytical Solutions
4.3 Graphical Analysis
4.4 Piecewise Linear Analysis
4.5 Incremental Analysis
The MOSFET Amplifier
课时目标:This chapter discusses the concept of amplification. It presents the SCS (switch-current-source) model of the MOSFET and builds a MOSFET amplifier.
5.1 Signal Amplification
5.2 Actual MOSFET Characteristics
5.3 The Switch-Current Source (SCS) MOSFET Model
5.4 The MOSFET Amplifier
5.5 Large-Signal Analysis of the MOSFET Amplifier
5.6 Operating Point Selection
The Small-Signal Model
课时目标:This chapter continues with small signal amplifiers. It also discusses how to determine the parameters of amplifier.
6.1 Small-Signal Circuit Representation
6.2 Small-Signal Circuit for the MOSFET Amplifier
6.3 Selecting an Operating Point
6.4 Input and Output Resistance, Current and Power Gain
Energy Storage Elements
课时目标:This chapter introduces storage elements, namely, capacitors and inductors, and discusses why the modeling of capacitances and inductances is necessary in high-speed design.
7.1 Capacitors
7.2 Inductors
First-Order Transients in Linear Electrical
课时目标:This chapter discusses first order transients in networks. This chapter also introduces several major applications of first-order networks.
8.1 Analysis of RC Circuits
8.2 Analysis of RL Circuits
8.3 Intuitive Analysis
Transients in Second-Order Circuits
课时目标:This chapter analyzes second order transients in networks.
9.1 Undriven, Series RLC Circuit
Sinusoidal Steady State: Impedance and Frequency Response
课时目标:This chapter discusses sinusoidal steady state analysis as an alternative to the time-domain transient analysis. The chapter also introduces the concepts of impedance and frequency response. This chapter presents the design of filters as a major motivating application.
10.1 Introduction
10.2 Phasors
10.3 Impedance
10.4 Frequency Response: Magnitude and Phase versus Frequency
10.5 Filters
10.6 AC Power
Sinusoidal Steady State: Resonance
课时目标:This chapter analyzes resonant circuits from a frequency point of view.
11.1 Series RLC
11.2 The Bode Plot for Resonant Functions
The Operational Amplifier Abstraction
课时目标:This introduces the operational amplifier as a key example of the application of abstraction in analog design.
12.1 Device Properties of the Operational Amplifier
12.2 The Non-Inverting Op Amp
12.3 The Inverting Op Amp
12.4 Adder
12.5 Subtracter
12.6 Op Amp Integrator
12.7 Op Amp Differentiator
12.8 The RC Active Filter
12.9 Op Amp in Saturation
Diodes
课时目标:This chapter discusses diodes and simple diode circuits.
13.1 Semiconductor Diode Characteristics
13.2 Analysis of Diode Circuits
13.3 Nonlinear Analysis with RL and RC
展开全部
预备知识
参考资料
Agarwal, Anant, and Jeffrey H. Lang. Foundations of Analog and Digital Electronic Circuits. San Mateo, CA: Morgan Kaufmann Publishers, Elsevier, July 2005. ISBN: 9781558607354.
常见问题
浙公网安备 33010802012594号
