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May 04, 2024
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EE 547 - Power System Analysis I3 lecture hours 0 lab hours 3 credits Course Description This course provides the graduate student with an introduction to the classical methods and modern techniques in power system analysis with the aid of a personal computer. Topics covered include the concepts of complex power, balanced three-phase circuits, transmission line parameters, transmission line performance and compensation, system modeling and per-unit analysis, circuit theory as applied to power systems and load flow analysis. (prereq: EE 3401 and approval of course instructor) Course Learning Outcomes Upon successful completion of this course, the student will be able to:
- Describe the elements that make up a power system.
- Understand the basic concepts of real and reactive power, direction of power flow, conservation of complex power and power factor correction.
- Understand the per-phase representation of the three-phase systems and computations.
- Calculate the inductance and capacitance of a transposed transmission line.
- Use line models to obtain the transmission line performance.
- Determine the series and shunt capacitors and shunt reactors required for line compensation.
- Understand the basic models of transformers and synchronous generators for the steady-state analysis.
- Develop a program for formation of the bus admittance matrix.
- Understand the computer techniques and algorithms used to obtain the transmission line parameters, line performance, compensation and solution of the load flow problems.
Prerequisites by Topic
- Linear circuit analysis
- Three-phase circuits
- Basic knowledge of electrical machines and transformers
- Computer programming
Course Topics
- Power in AC circuits, complex power. (1 class)
- Review of three-phase systems. (2 classes)
- Simple models of transformers and generators for steady-state analysis. (3 classes)
- The per-unit systems and impedance diagram. (2 classes)
- Transmission line parameters. Electromagnetic and electrostatic induction. (5 classes)
- Transmission line models, performance and compensation. (5 classes)
- Network solution and the bus admittance matrix. (2 classes)
- Iterative solution of nonlinear algebraic equations. (1 class)
- Load flow problem and solution by the Gauss-Seidel iterative method. (3 classes)
- Load flow solution by the Newton-Raphson method. (2 classes)
- Tap changing transformers, real and reactive power control. (2 classes)
Coordinator Richard Kelnhofer
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