Unit Outline
ENG441
Power System Dynamics and Stability
Semester 1, 2024
Waqas Hassan
School of Engineering
College of Sciences and Engineering
CRICOS Provider Code: 00586B
Unit Coordinator
Waqas Hassan
Email: waqas.hassan@utas.edu.au
What is the Unit About?
Unit Description
 
The aim of this unit is to provide students expertise in the analysis of power system dynamics and stability for practical applications. The unit covers an introduction to the concept of power system stability, representation of synchronous machines and AC transmission modelling in stability studies, static and dynamic load models, steam and hydro turbines and governing systems, HVDC systems and their representation in stability studies, small-signal stability concept, eigenvalues and eigenvectors, small-signal stability of a single machine and multimachine systems, transient stability concept, simulation of power system dynamic response, direct method of transient stability analysis, voltage stability and voltage collapse, wide-area monitoring, and impact of wind and solar integration on power system dynamics.
Intended Learning Outcomes
As per the Assessment and Results Policy 1.3, your results will reflect your achievement against specified learning outcomes.
On completion of this unit, you will be able to:
1.
Determine small-signal stability of power systems using eigenvalues and eigenvectors
2.
Evaluate power system dynamic response using appropriate commercial software
3.
Determine transient stability of a power system using the equal area criterion
4.
Investigate voltage stability and conditions for voltage collapse
5.
Analyse the impact of renewable energy integration by simulating power system dynamics
Requisites
REQUISITE TYPE
REQUISITES
Pre-requisite
ENG333 Power Systems 1
Alterations as a result of student feedback
 
 
 
Teaching arrangements
ATTENDANCE MODE
TEACHING TYPE
LEARNING ACTIVITY
CONTACT HOURS
FREQUENCY
Attendance / engagement expectations
If your unit is offered On campus, it is expected that you will attend all on-campus and onsite learning activities. This is to support your own learning and the development of a learning community within the unit. If you are unable to attend regularly, please discuss the situation with your course coordinator and/or our UConnect support team.

If your unit is offered Online, it is expected you will engage in all those activities as indicated in the Unit Outline, including any self-directed learning.

If you miss a learning activity for a legitimate reason (e.g., illness, carer responsibilities) teaching staff will attempt to provide alternative activities (e.g., make up readings) where it is possible.
 
 
 
 
How will I be Assessed?
 
For more detailed assessment information please see MyLO.
Assessment schedule
ASSESSMENT TASK #
ASSESSMENT TASK NAME
DATE DUE
WEIGHT
LINKS TO INTENDED LEARNING OUTCOMES
Assessment Task 1:
Project
Week 13
40 %
LO1, LO2, LO3, LO4, LO5
Assessment Task 2:
Exam
Exam Period
40 %
LO1, LO3, LO4
Assessment Task 3:
Labs
Refer to Assessment Description
20 %
LO2, LO4, LO5
 
Assessment details
    
Assessment Task 1: Project
Task Description:
Investigate the impacts of different factors and conditions on power system stability.

Students will utilise Matlab simulation tools and commercial software applications in conducting this project. Students will present their findings in pairs (20% of grade) during week 13, and write an individual report (80% of grade) due in week 13.

Task Length:
20 pages maximum (figures are not included) report, 15 minute presentation
Due Date:
Week 13
Weight:
40 %
 
CRITERION #
CRITERION
MEASURES INTENDED
LEARNING OUTCOME(S)
1
Calculate eigenvalues and eigenvectors for a given power system condition
LO1
2
Determine whether a system is stable or not using eigenvalues and eigenvectors
LO1
3
Run simulations and assess the power system stability under a given set of power system conditions
LO2
4
Determine voltage stability criteria for a power system and explain when voltage collapse may occur and how to prevent such a condition in power systems
LO4
5
Simulate and assess a given power system with renewable energy penetration
LO5
6
Explain how the equal area criterion is used in transient stability analysis of a large power system
LO3
 
Assessment Task 2: Exam
Task Description:
A three hour final exam covering all topics included in the lecture and tutorial sessions.

Task Length:
3 hours
Due Date:
Exam Period
 
Weight:
40 %
 
CRITERION #
CRITERION
MEASURES INTENDED
LEARNING OUTCOME(S)
1
Calculate eigenvalues and eigenvectors for a given power system condition
LO1
2
Determine whether a system is stable or not using eigenvalues and eigenvectors
LO1
3
Explain the equal area criterion on a simple example
LO3
4
Explain how the equal area criterion is used in transient stability analysis of a large power system
LO3
5
Determine voltage stability criteria for a power system
LO4
6
Explain when voltage collapse may occur and how to prevent such a condition in power systems
LO4
 
Assessment Task 3: Labs
Task Description:
Simulation lab assignment (x6).

Labs will be delivered from weeks 6 to 12. Students will submit reports within 1 week after the lab.

Task Length:
3 hour lab and 5 page report
Due Date:
Refer to Assessment Description
Weight:
20 %
 
CRITERION #
CRITERION
MEASURES INTENDED
LEARNING OUTCOME(S)
1
Input data for a given power system
LO2
2
Run simulations and assess the power system stability under a given set of power system conditions
LO2
3
Determine voltage stability criteria for a power system and explain when voltage collapse may occur and how to prevent such a condition in power systems
LO4
4
Simulate and assess a given power system with renewable energy penetration
LO5
 
 
 
How your final result is determined
To pass this unit, you need to demonstrate your attainment of each of the Intended Learning Outcomes, achieve a final unit grade of 50% or greater, and pass any hurdle tasks.
 
Submission of assignments
Where practicable, assignments should be submitted to an assignment submission folder in MYLO. You must submit assignments by the due date or receive a penalty (unless an extension of time has been approved by the Unit Coordinator). Students submitting any assignment in hard copy, or because of a practicum finalisation, must attach a student cover sheet and signed declaration for the submission to be accepted for marking.
 
Requests for extensions
If you are unable to submit an assessment task by the due date, you should apply for an extension.
 
A request for an extension should first be discussed with your Unit Coordinator or teaching support team where possible. A request for an extension must be submitted by the assessment due date, except where you can provide evidence it was not possible to do so. Typically, an application for an extension will be supported by documentary evidence: however, where it is not possible for you to provide evidence please contact your Unit Coordinator.
 
The Unit Coordinator must notify you of the outcome of an extension request within 3 working days of receiving the request.
Late penalties
Assignments submitted after the deadline will receive a late penalty of 5% of the original available mark for each calendar day (or part day) that the assignment is late. Late submissions will not be accepted more than 10 calendar days after the due date, or after assignments have been returned to other students on a scheduled date, whichever occurs first. Further information on Late Penalties can be found on the Assessments and Results Procedure.
 
Review of results and appeals
You are entitled to ask for a review of the marking and grading of your assessment task if there is an irregularity in the marking standards or an error in the process for determining the outcome of an assessment. Details on how to request a review of a mark for an assignment are outlined in the Review and Appeal of Academic Decisions Procedure.