《电路原理》双语教学大纲(英文版).docx

《电路原理》双语教学大纲(英文版) Teaching Program Course Code: 101C0040 Course Name: Electric Circuits （Ⅰ） Weekly Hours: 4.0-0 Credits: 4.0 Teaching Goal and Basic Requirements: This course introduces the principles of circuits and their role in electrical engineering, then introduces and demonstrates the power of the fundamental circuit laws and analysis methods. This is followed by an introduction to the principle of operational amplifier properties and operational amplifier circuits. The properties and applications of reactive circuit elements are introduced along with first and second order circuits. The basics of AC circuit analysis follow, the course will show how the sinusoidal steady state problem can be solved using phasor analysis. Students are prepared to analyze circuit properties with these tools and methods for each circuit type using both manual methods and PSpice tools. Content of Courses & Hours Allocation: Autumn Quarter Week 1: Introduction; Chapter 1-- Basic concepts; Week 2: Chapter 2-- Basic laws; Chapter 3--Nodal analysis; Week 3: Chapter 3--Mesh analysis; Chapter 4--Linearity property, superposition, source transformation; Week 4: National Holiday; Week 5: Chapter 4--Thevenin’s theorem, Norton’s theorem, Maximum power transfer; Week 6: Chapter 5--Operational amplifiers; Quiz 1; Week 7: Chapter 6--Capacitors and inductors; Chapter 7--First-order circuits: Source-free circuit; Week 8: Chapter 7--Step response; Chapter 8--Second-order circuits; Week 9: Chapter 9--Sinusoids and phasors; Winter Quarter Week 1: Chapter 10--Sinusoidal steady-state analysis; Quiz 2; Week 2: Circuit analysis with Pspice; Lab exercise--Circuit analysis with Pspice; Week 3: Chapter 11--AC power analysis: Effective or RMS value, Power factor; Week 4: Chapter 12--Three-phase circuits; Power in a system; Week 5: Chapter 13--Magnetically coupled circuits: Mutual inductance; Linear transformers, Ideal autotransformers; Week 6: Chapter 14--Frequency response: Transfer function, Resonance; Quiz 3; Week 7: New Year Holiday; Chapter 14--Passive filters; Circuit applications; Week 8: Chapter 16--The Fourier series: Average and RMS value; Review; Week 9: Review; Teaching Plan: The course grade is calculated based on: Homework 10%, Quiz 30% (two top scores from 3 quiz, 15% each), PSpice Assignment 5%, Final Exam: 55% Homework will be given full credit if the work is completed and the solutions understandable. Recommended Textbooks and Other References: (books, editors, publishing company, publishing time) 1．Fundamentals of Electric Circuits，Charles K. Alexander, Matthew N.O. Sadiku，McGraw-Hill Companies Inc，2000.12 2．PSpice and MATLAB for Electric Circuit Analysis，Tong Mei，Machine Industry Press，2022.7 3．Principles of Electric Circuits，Fan Chengzhi，Sun Dun，Tong Mei，Machine Industry Press，2022.7 4．Electric Circuits (Four Edition)，Qiu Guanyuan，High Education Press，1999.6 5．Electric Circuits (Six Edition)，James W. Nilsson, Susan A. Riedel, Publishing House of Electronics Industry，2022.6 Teaching Program Course Code: 101C0050 Course Name: Electric Circuits （II） Weekly Hours: 4.0-0 Credits: 2.0 Teaching Goal and Basic Requirements: Transient response analysis, network functions, poles and zeros; solution of network equations using Laplace transforms, inverse transforms, convolution integral, two-port networks. Matrix formulation of circuit equations, nodal Analysis and mesh analysis. Introduction of distributed circuits, distributed circuits of finite length, traveling wave, lossless transmission line of finite length. Analysis of nonlinear circuits, linearized circuit models, small signal analysis. Circuit analysis with MATLAB. Content of Courses & Hours Allocation: Spring Quarter Week 1: Chapter 15--Definition of Laplace transform; Properties of the Laplace transform; The inverse Laplace transform; Application to circuits; Transfer function; Week 2: The convolution integral; Network function and step response; Week 3: State variables and state equations; Circuit analysis with MATLAB; Week 4: Chapter 18--Two-port networks; Supplement 1: Matrix equations for network--Nodal Analysis; Week 5: Supplement 1: Matrix equations for network--Mesh Analysis; Week 6: Supplement 2: Distributed Circuits--Introduction, distributed circuits of finite length; Week 7: Supplement 2: Traveling wave; Lossless transmission line of finite length; Circuit analysis with MATLAB; Midterm exam; Week 8: Supplement 3: Simple nonlinear circuits--Introduction, Nonlinear resistor circuits, Small signal analysis; Review; Week 9: Review; Teaching Plan: The course grade is calculated based on: Homework 10%, Quiz 5%, Midterm 15%, MATLAB 。