Course
code | EE748 |
credit_hours | 3 |
title | Power System Analysis |
arbic title | |
prequisites | None |
credit hours | 3 |
Description/Outcomes | System modeling and load flow analysis. Optimum operation and control. Data acquisition, transmission and processing (SCADA system). Frequency, voltage and VAR control. Optimum control. Introduction to power system reliability. Unbalanced system analysis. Transient stability analysis. Harmonics measuring, elimination with passive and active filters. |
arabic Description/Outcomes | |
objectives | The student should be able to: Build confidence and understanding of those concepts of power system analysis that are likely to be encountered in the study and practice of electric power engineering. Develop network models based on the admittance and impedance representations. Studying applications commonly encountered in electric power system engineers practice. |
arabic objectives | |
ref. books | O.L. Elgerd, "Electric Energy System Theory", McGraw-Hill, N.Y., 1982. P.M. Anderson and A.A. Fouad, "Power System Control and Stability", IEEE Computer Society Publisher, 1994. L. L. Grisby, "Power System Stability and Control", CRC PR., 2007. |
arabic ref. books | |
textbook | |
arabic textbook | |
objective set | |
content set | |
Course Content
content serial |
Description |
1 |
Power system modeling.
|
2 |
Load flow analysis.
|
3 |
Optimum power system operation.
|
4 |
Control of power system.
|
5 |
SCADA System.
|
6 |
Power system frequency control.
|
7 |
Power system frequency control(2).
|
8 |
Power system voltage control.
|
9 |
Power system voltage control(2).
|
10 |
Power system VAR control.
|
11 |
Introduction to power system reliability.
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12 |
Analysis of unbalance power systems.
|
13 |
Transient stability Study.
|
14 |
Harmonics Analysis.
|
15 |
Study of passive and active filters.
|
16 |
Final Exam.
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