工程电路分析英文版第八版课程设计

Engineering Circuit Analysis Eighth Edition Course Design Introduction
The purpose of this course design is to guide students in understanding circuit analysis principles using the Engineering Circuit Analysis Eighth Edition textbook by William H. Hayt, Jack E. Kemmerly, and Steven M. Durbin.
The course is assumed to be taught in an academic setting with students having a basic understanding of circuit
analysis concepts. The length of the course is 16 weeks with three hours of class per week and an additional hour for laboratory experiments.
Learning Outcomes
By the end of this course, students should be able to: •Apply circuit analysis principles to analyze DC and AC circuits
•Analyze the behavior of active circuits such as amplifiers and oscillators
•Understand LTI (linear time-invariant) systems and their response to different input signals
•Analyze circuits using Laplace transform and frequency domn techniques
•Use MATLAB to solve circuit analysis problems and simulate circuits
Course Content
Week 1-2: Introduction and DC Circuit Analysis
•Course introduction, syllabus review
•Voltage, current, resistance, power, Ohm’s law
•Kirchhoff’s laws, nodal and mesh analysis
•Circuit theorems: superposition, Thevenin’s and Norton’s theorems
•Applications: voltage and current dividers, Wheatstone bridge
Week 3-4: Capacitors and Inductors
•Capacitance, charge and energy stored in capacitors •Inductance, flux and energy stored in inductors
•Series and parallel combinations of capacitors and inductors
•Time domn analysis of RC and RL circuits
•Transient analysis of first-order circuits
Week 5-6: AC Circuit Analysis
•AC circuits, phasors and complex numbers
•Circuit analysis using phasors
•Reactance, impedance and admittance
•Applications: filters, resonance, transformers Week 7-8: LTI Systems and Frequency Domn Analysis •LTI systems: impulse response, step response, transfer function
•Fourier series and Fourier transform
•Frequency response: Bode plots, frequency domn analysis
•Filters: low-pass, high-pass, band-pass, band-stop Week 9-10: Amplifiers
•Basics of amplifiers, types of amplifiers
•Amplifier characteristics: gn, input and output resistances, bandwidth
•BJT amplifiers: biasing, small-signal models, analysis using hybrid-pi model
•FET amplifiers: biasing, small-signal models, analysis using T-model
•Applications: differential amplifiers, operational amplifiers
Week 11-12: Oscillators
•Basics of oscillators, feedback concept
•Conditions for oscillation, types of oscillators •Analysis of LC oscillator
•Analysis of crystal oscillator
•Frequency stability and feedback compensation Week 13-14: Laplace Transform
•Introduction to Laplace transform
•Laplace transform properties
•Circuit analysis using Laplace transform
•Inverse Laplace transform
•Applications: circuit analysis of second-order circuits.
Week 15-16: MATLAB
•Introduction to MATLAB
•Numeric computation using MATLAB
•Symbolic computation using MATLAB
•Circuit analysis using MATLAB
•Laboratory experiments.
Assessment
The course will be assessed through a combination of homework assignments, quizzes, laboratory experiments, and a final examination. The weightage for each component is as follows:
•Homework assignments: 20%
•Quizzes: 20%
•Laboratory experiments: 20%
•Final examination: 40%
Conclusion
This course design is intended to provide a comprehensive understanding of circuit analysis principles using the Engineering Circuit Analysis Eighth Edition textbook. It is expected to equip students with the skills to analyze and design circuits using both time domn and frequency domn techniques. The laboratory experiments and MATLAB assignments will help students to develop practical skills for circuit analysis.。