ELECTRIC CIRCUITS THEORY
Course Description
This course covers a wide array of essential concepts in electrical engineering. Students explore topics such as mutual inductance, transformers, three-phase circuits (both balanced and unbalanced), graph theory, network equations, the Laplace transform, natural frequency, transfer functions, poles, zeros, two-port circuits, state equations, nodal and mesh analysis, cut-set and loop analysis, and modified nodal analysis. This comprehensive course equips students with the analytical tools needed to understand, design, and troubleshoot electrical systems, making it a crucial stepping stone for their engineering journey.
Syllabus:
- Mutual Inductance and Transformers
- Graph Theory, Network Equations, and Tellegen Theorem
- The Laplace Transform in Circuit Analysis
- Natural Frequency
- Transfer Function, Poles, and Zeros
- Two-Port Circuits
- Three-Phase Circuits (Balanced and Unbalanced)
- State Equations.
- Nodal and Mesh Analysis
- Cut-Set and Loop Analysis
- Modified Nodal Analysis
References:
- Basic Circuit Theory, Ch. A. Desor and E. S. Kuh, McGraw-Hill (1966).
- Fundamentals of Electric Circuits. C. K. Alexander and M. N. O. Sadiku, McGraw Hill (6th Ed., 2021).
- Introduction to Electric Circuits, R. C. Dorf and J. A. Svoboda, John Wiley (9th, 2013)
- Electric Circuits, J. W. Nilsson and S. Riedel, Pearson (12th Ed, 2022).
Grading:
- Midterm #1 (5 out of 20)
- Midterm #2 (6 out of 20)
- Final Exam (6 out of 20)
- Homeworks (3 out of 20)
- subject to changes