Steady-State Performance and Stability Analysis of Electric Power Systems

The course provides detailed presentations of steady-state performance and stability analysis of electric power systems. The handled problems cover the effects of various controllers and conditions on the performance and stability of power systems. The course consists in 8 lectures and 5h 16m total length.

Course Description

The course contains comprehensive presentations on the steady-state performance and stability analysis of electric power systems. The addressed issues are to the impact of different controllers and conditions on the performance and stability of power systems. The addressed topics encompass steady-state performance, equilibrium, various stability analyses, and methods for improving power system stability.

This course meticulously evaluates the application of software tools for both theoretical validation and practical concerns.

The course consists in 8 lectures and 5h 16m total length.

The course goals encompass, but are not restricted to:

  1. Modeling, simulating, and analyzing electric power systems influenced by various steady-state and electromechanical transient events.
  2. Analyze the impact and provide mitigation strategies for issues associated with power systems under steady-state and transient settings.
  3. Execute, assess, and appraise steady-state and transient situations in electric power systems utilizing various excitation and speed control mechanisms.
  4. Evaluate and forecast the performance of simplified power systems employing various stability criteria.
  5. Comprehend diverse stability phenomena and employ appropriate methodologies for their analysis and the augmentation of stability levels.
  6. Utilize software applications like PSAT and ETAP to address power system stability issues.

Intended Learning Outcomes

Upon completion of the course, you will acquire knowledge in:

  • Analyze, assess, and forecast the behavior of electrical power systems under steady-state and transient situations.
  • Describe and analyze several methods for depicting power system components, including different types of controllers.
  • Forecast and assess appropriate criteria for the analysis of power systems under varying parameters, operational states, and beginning conditions.
  • Determine the modeling prerequisites for analyzing diverse steady-state and transient occurrences.
  • Elucidate and analyze several topics pertaining to power system stability.
  • Identify, analyze, and assess viable solutions to issues based on the physical and operational constraints of power system components.
  • Utilization of computer software for the resolution of diverse power system issues.

Who Is This Course For

  • Electric power & energy engineers
  • Electric power & energy students
  • Operation engineers

Requirements

  • Basic knowledge in electrical engineering

After purchasing the course, students can download the following materials:

  1. Introduction (PDF)
  2. Steady-state performance and equilibruim (PDF)
  3. SSSA - Part 1 Classical Model (PDF)
  4. SSSA - Part 2 Field_Dynamics (PDF)
  5. TS - Part 1 EAC & TD (PDF)
  6. TS - Part 2 TS Enhancement (PDF)
  7. Voltage Stability (PDF)
  8. Other Stability Studies - Frequency, Converter Driven and Resonance (PDF)
  9. The facts about transients in power systems you should properly understand (PDF)
  10. Analysis of transients and disturbances in electric power systems (PDF)
  11. Stability analysis of power network using 600kV, 800kV, and 1000kV HVDC (PDF)

About Instructor

Prof. Dr. Mohamed El-Shimy

Prof. Dr. Mohamed EL-Shimy is currently a professor of the electrical power systems with the department of Electrical Power and Machines, Faculty of Engineering, Ain Shams University. He is also an electromechanical specialist, a freelance trainer, technical advisor, and a member of many associations and professional networks. He is a technical reviewer with some major journals and conferences. His fields of interest include electric power system: analysis, stability, economics, optimization, distribution, renewable energy integration, and reliability.

3 Courses

Not Enrolled

Course Includes

  • 6 Lessons
  • 9 Topics
  • Course Certificate
  • Lifetime Access