Description
Focuses on advanced AC circuit analysis, including phasors, resonance, power calculations, and three-phase systems. It also covers transient analysis, two-port networks, and frequency response for complex circuit design
Outline
| Basic and Support Material to be Covered |
Foundational concepts required for circuit analysis |
| Math Tools |
Mathematical tools and techniques |
| Periodic Wave |
Analysis of periodic waveforms |
| Basic AC Theory |
Alternating current theory and phasor concepts |
| Mesh, Nodal, and Thevenin Analysis |
Circuit analysis techniques including Thevenin’s theorem |
| Power Calculation |
Methods to compute power in AC and DC circuits |
| Complex and Maximum Power |
Complex power, apparent power, and maximum power transfer |
| Balanced Three-Phase Circuit |
Analysis of balanced three-phase systems |
| Line Current and Line Voltages |
Relationship between phase and line quantities |
| The Star-Delta Connection |
Transformation between star (Y) and delta (Δ) configurations |
| Mutual Inductance |
Inductive coupling between coils |
| Dot Convention |
Polarity marking for mutual inductance |
| Static Magnetic Field |
Magnetic field concepts in circuits |
| Ferromagnetic Materials |
Characteristics and behavior of ferromagnetic materials |
| Laplace Transform |
Introduction to Laplace transform for circuit analysis |
| Laplace Transform Application on Circuit Analysis |
Application of Laplace transform techniques |
| Two-Port Circuits |
Analysis of two-port network parameters |
| Revision |
Review and consolidation of covered topics |
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