| 1 | Introduction to power system analysis: steady-state sinusoidal conditions, phasor diagrams, concepts of active, reactive, and apparent power, components of power systems, and balanced three-phase systems. | [1]- [4] |
| 2 | Components of a power system: generators, transformers, and loads. | [1]- [4] |
| 3 | Single-line and impedance diagrams of power systems and the application of the per-unit (pu) method. | [1]- [4] |
| 4 | Simplified representation of power systems, creation of single-line diagrams, and derivation of impedance diagrams. | [1]- [4] |
| 5 | Definition of the per-unit system, its advantages, basic calculations, and application examples. | [1]- [4] |
| 6 | Bus admittance and impedance matrix models. | [1]- [4] |
| 7 | Use of the admittance matrix in system analysis, Ybus formation methods, and the Kron reduction method. | [1]- [4] |
| 8 | Purpose and basic concepts of load flow analysis, and preparation of system data. | [1]- [4] |
| 9 | Load flow analysis using the Gauss and Gauss-Seidel methods. | [1]- [4] |
| 10 | Load flow analysis using the Gauss and Gauss-Seidel methods. | [1]- [4] |
| 11 | Load flow analysis using the Newton-Raphson method. | [1]- [4] |
| 12 | Formation of the bus impedance matrix, example calculations, and preparation for short-circuit analysis. | [1]- [4] |
| 13 | Symmetrical and asymmetrical faults. | [1]- [4] |
| 14 | Symmetrical and asymmetrical faults. | [1]- [4] |