ELEC4300 - Sem 1 2008 - St Lucia - Internal

Authenticated View
Printed: 14 February 2008, 02:30PM
This printed course profile is valid at the date and time specified above. The course profile may be subject to change during the semester – the online version is the authoritative version.

1. General Course Information

1.1 Course Details

Course Code: ELEC4300 Course Title: Power Systems Analysis
Coordinating Unit: School of Information Technology and Electrical Engineering
Semester: Semester 1, 2008    Mode: Internal
Level: Undergraduate
Location: St Lucia
Number of Units: 2    Contact Hours Per Week: 3L1T1P
Pre-Requisites: ELEC3300 or ELEC7302
Incompatible: ELEC4300 or ELEC7303 or 3E432
Course Description: Overview of power system modelling, load flow analysis, symmetrical & unsymmetrical fault calculation, economic operation, power system stability, basic methods of power system reliability. Loss of load & energy indices.
Assumed Background:

Prerequisite: Elec3300

This course introduces introductory concepts of electrical energy conversion and utilisation.

1.2 Course Introduction

Modern power systems have grown larger with many interconnections between neighbouring systems. Proper planning, operation and control of such large systems require advanced computer based techniques. This course will provide a solid foundation in classical methods and modern techniques in power systems engineering for senior level electrical engineering students.  Course content includes the concepts of power system for various normal and abnormal conditions. The course will train students with modern computer-based techniques for solving a wide range of power system problems.

1.3 Course Staff

Course Coordinator:  Tapan Saha
Phone: 33653962     Email: saha@itee.uq.edu.au Homepage: http://www.itee.uq.edu.au/~saha
Campus: St Lucia Building: Axon Building (Map)   Room: 406
Consultation: Consultation time will be decided on the 1st week of lecture.


1.4 Timetable

Timetables are available on mySI-net.

Additional Timetable Information
Class
Day
Start
End
Building Name
Building
Room
Start/End Date (DD/MM/YYYY)
Not taught on these dates (DD/MM/YYYY)
L
Tue
1:00 PM
1:50 PM
General Purpose South
344
25/02/2008 - 31/05/2008
 
L
Wed
12:00 PM
1:50 PM
General Purpose South
344
25/02/2008 - 31/05/2008
 
T
Tue
4:00 PM
5:50 PM
General Purpose South
344
25/02/2008 - 31/05/2008
26/02/2008
 

Timetable as of 8th February 2008

Practical in this course will be a major assignment. Students will use their free time for this practical based assignment using the  Powerworld software .


2. Aims, Objectives & Graduate Attributes

2.1 Course Aims

The aim of this course is to expose students to the concepts of power system operation for various normal and abnormal conditions. The students are also exposed to modern commercial software for solving and designing a wide range of power systems problems.

2.2 Learning Objectives

After successfully completing this course you should be able to:

1  Understand the basic modelling of power system components
2  Know the methodologies to solve power system steady state operating conditions
3  Correctly solve load flow problems of large power systems with appropriate models of transmission line, transformer, generator and loads
4  Apply symmetrical and unsymmetrical fault algorithms
5  Understand why stability is important to normal operation of power systems
6  Apply basic stability techniques into power system analysis
7  Design a basic power system to fulfil certain specifications of generation, transmission and demand
8  Understanding power systems structure in a deregulated environment

2.3. Graduate Attributes

Successfully completing this course will contribute to the recognition of your attainment of the following UQ (Undergrad Pass) graduate attributes:

GRADUATE ATTRIBUTELEARNING OBJECTIVES
A. IN-DEPTH KNOWLEDGE OF THE FIELD OF STUDY
A1. A comprehensive and well-founded knowledge in the field of study.1, 2, 4, 5, 6, 7
A4. An understanding of how other disciplines relate to the field of study. 
A5. An international perspective on the field of study. 
B. EFFECTIVE COMMUNICATION
B1. The ability to collect, analyse and organise information and ideas and to convey those ideas clearly and fluently, in both written and spoken forms.7
B2. The ability to interact effectively with others in order to work towards a common outcome.6, 7, 8
B3. The ability to select and use the appropriate level, style and means of communication. 
B4. The ability to engage effectively and appropriately with information and communication technologies. 
C. INDEPENDENCE AND CREATIVITY
C1. The ability to work and learn independently.7
C3. The ability to generate ideas and adapt innovatively to changing environments.3
C4. The ability to identify problems, create solutions, innovate and improve current practices.7
D. CRITICAL JUDGEMENT
D1. The ability to define and analyse problems.3, 4, 6
D2. The ability to apply critical reasoning to issues through independent thought and informed judgement.7
D3. The ability to evaluate opinions, make decisions and to reflect critically on the justifications for decisions.3
E. ETHICAL AND SOCIAL UNDERSTANDING
E1. An understanding of social and civic responsibility.7
E2. An appreciation of the philosophical and social contexts of a discipline. 
E4. A knowledge and respect of ethics and ethical standards in relation to a major area of study.8
E5. A knowledge of other cultures and times and an appreciation of cultural diversity. 

Successfully completing this course will contribute to the recognition of your attainment of the following Engineers Australia graduate attributes:

GRADUATE ATTRIBUTELEARNING OBJECTIVES
1. Ability to apply knowledge of basic science and engineering fundamentals1, 2
2. Ability to communicate effectively, not only with engineers, but also with the community at large 
3. In-depth technical competence in at least one engineering discipline3, 5, 6, 7
4. Ability to undertake problem identification, formulation and solution6, 7
5. Ability to utilise a systems approach to design and operational performance 
6. Ability to function effectively as an individual and in multi-disciplinary and multi-cultural teams, with the capacity to be a team leader or manager as well as an effective team member 
7. Understanding of the social, cultural, global and environmental responsibilities of the professional engineer, and for the need for sustainable development8
8. Understanding of the principles of sustainable design and development7
9. Understanding of and commitment to professional and ethical responsibilities 
10. Expectation and capacity to undertake life-long learning 

3. Learning Resources

3.1 Required Resources

Any one from the list.

1. Hadi Saadat, Power System Analysis, International Edition, McGraw Hill, 2nd edition, 2002

2.J D Glover, M S Sharma, Power System analysis and design, Pacific Grove, CA : Wadsworth/Thomson Learning, c2002.
Edition 3rd ed.

 
 

3. Introduction to Electricity market

http://www.nemmco.com.au/nemgeneral/000-0187.pdf

 URL
 

3.2 Recommended Resources

Reference Books
1. Grainger and Stevenson, Power System Analysis, International Edition, McGraw Hill, 1994

2. B M Weedy and B J Cory, Electric Power Systems, Fourth Edition, John Wiley & Sons, 1998.

3. A. R. Bergen and V Vittal, Power Systems Analysis, Prentice-Hall, Second Edition 2000

4. M E El-Hawary, Electrical Power Systems, IEEE Press, 1995


 
 
Introduction to Australian electricity market URL
 

3.3 University Learning Resources

Access to required and recommended resources, plus past central exam papers, is available at the UQ Library website (http://library.uq.edu.au/search/r?SEARCH=ELEC4300).

The University offers a range of resources and services to support student learning. Details are available on the myServices website (https://student.my.uq.edu.au/).

3.4 School of Information Technology and Electrical Engineering Learning Resources

Students enrolled at St Lucia who wish to retain a hard copy of this profile can use the free print quota provided each semester to students enrolled in courses in the School of Information Technology & Electrical Engineering. For information on how to use this print quota, see the School Policy on Student Photocopying and Printing (St Lucia) (http://www.itee.uq.edu.au/about_ITEE/policies/copy-print.html). Students enrolled at the Ipswich campus will either be provided with a hard copy or given directions in class on how to obtain a free copy.

ITEE course websites can be found at http://www.itee.uq.edu.au/~COURSECODE. Many ITEE courses also have Usenet newsgroups, named uq.itee.COURSECODE. Instructions for accessing newsgroups are available at http://studenthelp.itee.uq.edu.au/faq/1stYearFAQ.html#accessnews.

3.5 Other Learning Resources & Information

Handouts

Any handouts including tutorial sheets will be available on the course homepage

(http://www.itee.uq.edu.au/~elec4300/index.html). It is the student’s responsibility to make these

documents available for their use.

4. Teaching & Learning Activities

4.1 Learning Activities

Date
Activity
Learning Objectives
25 Feb 08 00:00 - 3 Mar 08 00:00
 Review of Basic Concepts (Lecture):
Readings/Ref: Any one ; Reference
1
4 Mar 08
 Background knowledge (Tutorial):
Readings/Ref: Any one ; Reference
1
5 Mar 08 - 12 Mar 08
 Transmission lines (Lecture):
Readings/Ref: Any one ; Reference
1, 2
17 Mar 08 00:00 - 4 Apr 08 00:00
 Load flow calculations (Lecture):
Readings/Ref: Any one ; Reference
2, 3
18 Mar 08
 Transmission lines (Tutorial):
Readings/Ref: Any one ; Reference
1, 2
1 Apr 08
 Load flow calculations cast study (Tutorial):
Readings/Ref: Any one ; Reference
3
7 Apr 08 00:00 - 18 Apr 08 00:00
 Fault analysis (Lecture):
Readings/Ref: Any one ; Reference
4
15 Apr 08
 Balanced fault analysis (Tutorial):
Readings/Ref: Any one ; Reference
4
15 Apr 08
 Designing a power system with specific requirement (Design):
Readings/Ref: Any one ; Reference
7
21 Apr 08 00:00 - 2 May 08 00:00
 Unbalanced fault analysis (Lecture):
Readings/Ref: Any one ; Reference
4
29 Apr 08
 Unbalanced fault analysis (Tutorial):
Readings/Ref: Any one ; Reference
4
5 May 08 00:00 - 16 May 08 00:00
 Transient Stability analysis (Lecture):
Readings/Ref: Any one ; Reference
5, 6
13 May 08
 Problem solving in stability analysis (Tutorial):
Readings/Ref: Any one ; Reference
6
19 May 08 - 23 May 08
 Introduction to Electricity Market (Lecture):
8
26 May 08 00:00 - 30 May 08 00:00
 Voltage stability and blackout issues (Lecture):
5, 7, 8
27 May 08
 Review tutorial (Tutorial): Review tutorial
1, 2, 3, 4, 5

4.2 Other Teaching and Learning Activities Information

Primary methods of teaching will be lecture and tutorial. A special tutorial will be organised to provide specifications for the design problem. Students will then use their free time to use a commercial software in ITEE laboratories to validate the designed power system. Students are encouraged to attend all teaching and tutorial sessions. The lectures, tutorials and design problem have been specifically designed to aid student's learning of the course material. Failure to attend a session may result in student being disadvantaged. It is up to the student to find out what happened at any class session that a student miss.

5. Assessment

5.1 Assessment Summary

This is a summary of the assessment in the course. For detailed information on each assessment, see 5.5 Assessment Detail below.

Assessment Task
Due Date
Weighting
Learning Objectives
Tutorial Exercise
Tutorial submission
See the policy on description
10%
1, 2, 3, 4, 5, 6
In Class Quiz
Class Test
1 Apr 08 04:00 - 1 Apr 08 05:00
15%
1, 2
Design
Design of a power system
15 Apr 08 04:00 - 31 May 08 05:00
Tutorial
15%
3, 4, 5, 7
Exam - during Exam Period (School)
Final Examination
Examination Period
60%
3, 4, 5, 6, 8

5.2 Course Grading


Grade 1, Fail: Fails to demonstrate most or all of the basic requirements of the course:

Fails to satisfy most or all of the basic requirements of the course.



Grade 2, Fail: Demonstrates clear deficiencies in understanding and applying fundamental concepts; communicates information or ideas in ways that are frequently incomplete or confusing and give little attention to the conventions of the discipline:

Fails to satisfy some of the basic requirements of the course



Grade 3, Fail: Demonstrates superficial or partial or faulty understanding of the fundamental concepts of the field of study and limited ability to apply these concepts; presents undeveloped or inappropriate or unsupported arguments; communicates information or ideas with lack of clarity and inconsistent adherence to the conventions of the discipline:

Falls short of satisfying all the requirements for a Pass: As evidenced by failing to successfully complete basic assessment tasks and so receive a final percentage grade of between 45 and 49%.




Grade 4, Pass: Demonstrates adequate understanding and application of the fundamental concepts of the field of study; develops routine arguments or decisions and provides acceptable justification; communicates information and ideas adequately in terms of the conventions of the discipline:

To successfully pass the course (GP 4), the student should have knowledge of the fundamental concepts of power systems. These include the basic principles of normal and abnormal operations of power systems and its components, their equivalent circuits and simple voltage-current and power calculations. The student should show the ability to apply the fundamental concepts to problem solving of transmission line, load flow calculation and fault calculation.



.



Grade 5, Credit: Demonstrates substantial understanding of fundamental concepts of the field of study and ability to apply these concepts in a variety of contexts; develops or adapts convincing arguments and provides coherent justification; communicates information and ideas clearly and fluently in terms of the conventions of the discipline:

To obtain a credit (GP 5), in addition to criteria for a GP of 4, the student should show the ability to understand the concepts of voltage stability and important issues related to deregulated electricity market.



Grade 6, Distinction: As for 5, with frequent evidence of originality in defining and analysing issues or problems and in creating solutions; uses a level, style and means of communication appropriate to the discipline and the audience:

To obtain a distinction (GP 6), in addition to criteria for a GP of 5, deeper understanding of the course has to be demonstrated. The student should show the ability to apply the fundamental concepts to problem solving in power system transient stability analysis.



Grade 7, High Distinction: As for 6, with consistent evidence of substantial originality and insight in identifying, generating and communicating competing arguments, perspectives or problem solving approaches; critically evaluates problems, their solutions and implications:

To obtain a high distinction (GP 7), in addition to criteria for a GP of 6, the student should demonstrate the ability of original thinking and/or cross migration of ideas from other areas of knowledge by solving advanced level application oriented problems.



Other Requirements & Comments :

Your final mark will be calculated from your marks on following assessment items:-

(a) tutorial submissions

(b) Design submission

(c) Class test

(d) Final Exam

  • You must pass (50% or above) the final exam and class test together (not individually) to pass (GP of  4 ) the subject. Your final grade is then computed from the final mark using the following table:

    Standard breakpoints of grading will be used for assigning the GP's.


    · GP 7 High Distinction Marks: >=85
    · GP 6 Distinction Marks: >=75 and < =84
    · GP 5 Credit Marks: >=65 and < =74
    · GP 4 Pass Marks: >=50 and < =64
    · GP 3 Fail mark >=45and < =49
    · GP 2 Fail mark: >=20 and < =44
    · GP 1 Serious fail mark: >=0 and < =19


5.3 Late Submission

Submission of the assignment and tutorial will be via the submission boxes on level one of the GPSouth building. Your assignment submission must be accompanied by a signed coversheet declaring that the submission is your original work.

Normally, no tutorial or assignment submission will be accepted after the end of this time. Only in special circumstances (with a medical certificate from a GP) will tutorial submissions be accepted later. You have to ask your lecturer for an extension. Late submissions will be only accepted by the lecturer directly.

5.5 Assessment Detail

Tutorial submission
Type: Tutorial Exercise
Learning Objectives Assessed: 1, 2, 3, 4, 5, 6
Due Date:
         See the policy on description
Weight: 10%
Task Description:

Tutorial submission Policy:
Tutorial sheets will be handed out in advance of the tutorial classes. At the beginning of each
tutorial session, directions will be given concerning submission of worked problems for marking.

Four tutorial will be marked  for this part of the assessment.
Students will be required to submit the tutorial problems designated as required for assessment by
10 am of the following Monday at the box located in GP South level 1. No tutorial submission will
be accepted after this time. Only in special circumstances (approved medical reasons) will tutorial
submissions be accepted within a very short period of time after this specified time.


Criteria & Marking:

Students are required to show their calculation procedure.

Students are required to show the formula used for each section of problems.

Students are required to explain any assumtions they take to solve problems.

Marks will be allocated based on correct procedures as well as for the final answer.

Marking scheme will be explained to students for individual tutorial.


Submission: Four tutorial will be marked for this part of the assessment.Students will be required to submit the tutorial problems designated as required for assessment by 10 am of the following Monday at the box located in GP South level 1. No tutorial submission will be accepted after this time. Only in special circumstances (approved medical reasons) will tutorial submissions be accepted within a very short period of time after this specified time.
Class Test
Type: In Class Quiz
Learning Objectives Assessed: 1, 2
Due Date:
         1 Apr 08 04:00 - 1 Apr 08 05:00
Weight: 15%
Perusal: 10 minutes
Duration: 60 minutes
Task Description: Class Test during tutorial session
Criteria & Marking: Students are required to show their calculation procedure.

Students are required to show the formula used for each section of problems.

Students are required to explain any assumtions they take to solve problems.

Marks will be allocated based on correct procedures as well as for the final answer.

After the exam, marking scheme will be explained to students for individual questions.

Design of a power system
Type: Design
Learning Objectives Assessed: 3, 4, 5, 7
Due Date:
         15 Apr 08 04:00 - 31 May 08 05:00    Tutorial
Weight: 15%
Task Description: Each student will be required to design a power system; and then perform computer simulations  on load flow and short circuit analysis using the Powerworld software and students will be required to submit a report. Details will be provided during the tutorial session
Criteria & Marking:

Students are required to show their data sources very clearly in the report.

Students are required to show justification for their selection of a particular power system. 

Students are required to explain any assumtions they take in designing the system.

Marks will be allocated based on correct procedures as well as for the explanations of results.

Marks will be given for each section of the design separately. There will be few marks for the completeness of the design.


Final Examination
Type: Exam - during Exam Period (School)
Learning Objectives Assessed: 3, 4, 5, 6, 8
Due Date:
         Examination Period
Weight: 60%
Perusal: 10 minutes
Duration: 120 minutes
Task Description:

Final exam will test loadflow, fault analysis, stability and electricity market structure.


Criteria & Marking: Students are required to show their calculation procedures.

Students are required to show the formula used for each section of problems.

Students are required to explain any assumtions they take to solve problems.

Marks will be allocated based on correct procedures as well as for the final answer.


6. Policies & Guidelines

 
This section contains the details of and links to the most relevant policies and course guidelines. For further details on University Policies please visit myAdvisor and the University Handbook of Policies and Procedures.

6.1 Assessment Related Policies and Guidelines

University Policies & Guidelines

An overview of the University’s assessment-related policies can be found on myAdvisor (http://www.uq.edu.au/myadvisor/index.html?page=2910).

Academic Integrity
It is the University's task to encourage ethical scholarship and to inform students and staff about the institutional standards of academic behaviour expected of them in learning, teaching and research. Students have a responsibility to maintain the highest standards of academic integrity in their work. Students must not cheat in examinations or other forms of assessment and must ensure they do not plagiarise.

Plagiarism
The University has adopted the following definition of plagiarism:

Plagiarism is the act of misrepresenting as one's own original work the ideas, interpretations, words or creative works of another. These include published and unpublished documents, designs, music, sounds, images, photographs, computer codes and ideas gained through working in a group. These ideas, interpretations, words or works may be found in print and/or electronic media.

Students are encouraged to read the UQ Academic Integrity and Plagiarism policy (http://www.uq.edu.au/hupp/index.html?page=25128) which makes a comprehensive statement about the University's approach to plagiarism, including the approved use of plagiarism detection software, the consequences of plagiarism and the principles associated with preventing plagiarism.

Feedback on Assessment
Feedback is essential to effective learning and students can expect to receive appropriate and timely feedback on all assessment. For a detailed explanation of the feedback you are entitled to, you should consult the policy on Student Access to Feedback on Assessment. (http://www.uq.edu.au/hupp/index.html?page=25114&pid=25075)

As a student you have a responsibility to incorporate feedback into your learning; make use of the assessment criteria that you are given; be aware of the rules, policies and other documents related to assessment; and provide teachers with feedback on their assessment practices.

There are certain steps you can take if you feel your result does not reflect your performance. Please refer to the myAdvisor web site. (http://www.uq.edu.au/myadvisor/index.html?page=2953&pid=2910)

Feedback in this Course

Students are encouraged to provide their feedback to the lecturer through email or through making an appointment. TEVAL forms will be also provided to students for getting their formal feedback.

Lecturer and tutor will also provide timely feedback on all progressive assessment; broad feedback on end-of-semester examinations (usually including access to examination scripts and question papers).

School of Information Technology and Electrical Engineering Assessment Guidelines

Misconduct

Further to the statement on academic integrity and plagiarism above, students are required to read and understand the ITEE policy on Student Misconduct (http://www.itee.uq.edu.au/about_ITEE/policies/student-misconduct.html).

Late Arrival or Non-attendance at Examinations

The policy and procedure for late arrival or non-attendance at centrally controlled examinations is set out in the University's Examinations policy (HUPP 3.30.5), sections 8 and 10.2.

The way in which late arrival at a School-controlled examination is dealt with will be at the discretion of the course coordinator, who may be guided by the policy for centrally controlled exams.

In the case that a student requests a special exam for a School-controlled exam, the request will be considered and, if allowed, the timing shall be determined by the course coordinator, in consultation with the School's Chief Examiner where necessary, and in accordance with HUPP 3.30.5. Unless otherwise indicated in the Course Profile, applications must be made in writing to the Head of School no later than one week after the exam. Late applications will not be accepted.
 
Examination Feedback
 
In addition to the advice above, students wishing to view examination answer scripts and/or question papers should consult with the School office (Room 217, General Purpose South Building [78], St Lucia; Room 218, Building 1, Ipswich) regarding arrangements. The ITEE policy on exam script viewing is available at http://study.itee.uq.edu.au/current_students/exam_script_viewing.html.

Supplementary Assessment

If you fail this course you may be eligible for supplementary assessment - see the general award rules and/or your program rules for details. You should note that even though you may be eligible for supplementary assessment under these rules, in some circumstances there may be no practical assessment that can be offered to allow you to meet the minimum passing requirements. These circumstances may include failure based on:
  • group or team based assessment;
  • attendance or class participation requirements;
  • laboratory-based assessment, where laboratories can't practically be made available after classes have finished;
  • project or thesis-based assessment, where a significant period of time would be required to undertake supplementary assessment;
  • progressive assessment, where subsequent assessment items build on earlier assessment items; or
  • multiple assessment items, where it is impractical to offer multiple supplementary assessment items.
If the course coordinator determines that there is no practical supplementary assessment that can be offered to allow you to improve your grade, then you will not be offered supplementary assessment and your grade will remain unchanged.

6.2 Other Policies and Guidelines

University Policies and Guidelines

Placement Courses
Students on a placement course – also known as a work placement, internship, industry study, industry experience, clinical practice, clinical placement, practical work, practicum, fieldwork, teaching practice – should refer to the University policy, Placement Courses (http://www.uq.edu.au/hupp/index.html?page=25120&pid=25075) for detailed information.
 
Working with Children
Students whose studies include a professional/work placement, internship, clinical practice, teaching practice or other similar activity which involves them in regular contact with children should refer to the University policy, Working with Children Check - "blue card" (http://www.uq.edu.au/hupp/index.html?page=25004&pid=24963) to find out how to apply for a ‘blue card’.
 
Students with a Disability
Any student with a disability who may require alternative academic arrangements, including assessment, in the course/program is encouraged to seek advice at the commencement of the semester from a Disability Adviser at Student Support Services. Refer to the University policy, Students with a Disability (Disability Action Plan) (http://www.uq.edu.au/hupp/index.html?page=25122&pid=25075) and to the policy on Special Arrangements for Examinations for Students with a Disability (http://www.uq.edu.au/hupp/index.html?page=25111&pid=25075

Where an adjustment is made to an accredited program, it is the responsibility of the relevant Faculty to liaise with professional and registration bodies regarding the acceptability of the change/s.  

Occupational Health and Safety
Undergraduate Students (http://www.uq.edu.au/hupp/index.html?page=25055&pid=25015) and Postgraduate Students (http://www.uq.edu.au/hupp/index.html?page=25057&pid=25015) should be familiar with the University policies on occupational health and safety in the laboratory.

Other School of Information Technology and Electrical Engineering Guidelines

Ethical Clearance
If your course involves assignment or project work involving human subjects or human-related materials, you must investigate the need for ethical clearance and obtain it when required. Information on ethical clearance can be found at http://www.uq.edu.au/research/orps/index.html?page=5064&pid=5256.

Learning Summary

 

Below is a table showing the relationship between the learning objectives for this course and the broader graduate attributes developed, the learning activities used to develop each objective and the assessment task used to assess each objective.

Learning Objectives

After successfully completing this course you should be able to:

1  Understand the basic modelling of power system components
2  Know the methodologies to solve power system steady state operating conditions
3  Correctly solve load flow problems of large power systems with appropriate models of transmission line, transformer, generator and loads
4  Apply symmetrical and unsymmetrical fault algorithms
5  Understand why stability is important to normal operation of power systems
6  Apply basic stability techniques into power system analysis
7  Design a basic power system to fulfil certain specifications of generation, transmission and demand
8  Understanding power systems structure in a deregulated environment


Assessment & Learning Activities

  Learning Objectives
  1 2 3 4 5 6 7 8
Learning Activities
Review of Basic Concepts (Lecture)
selected
              
Background knowledge (Tutorial)
selected
              
Transmission lines (Lecture)
selected
selected
            
Load flow calculations (Lecture)  
selected
selected
          
Transmission lines (Tutorial)
selected
selected
            
Load flow calculations cast study (Tutorial)    
selected
          
Fault analysis (Lecture)      
selected
        
Balanced fault analysis (Tutorial)      
selected
        
Designing a power system with specific requirement (Design)            
selected
  
Unbalanced fault analysis (Lecture)      
selected
        
Unbalanced fault analysis (Tutorial)      
selected
        
Transient Stability analysis (Lecture)        
selected
selected
    
Problem solving in stability analysis (Tutorial)          
selected
    
Introduction to Electricity Market (Lecture)              
selected
Voltage stability and blackout issues (Lecture)        
selected
  
selected
selected
Review tutorial (Tutorial)
selected
selected
selected
selected
selected
      
Assessment Tasks
Tutorial submission
selected
selected
selected
selected
selected
selected
    
Class Test
selected
selected
            
Design of a power system    
selected
selected
selected
  
selected
  
Final Examination    
selected
selected
selected
selected
  
selected

Graduate Attributes

Successfully completing this course will contribute to the recognition of your attainment of the following UQ (Undergrad Pass) graduate attributes:

  Learning Objectives
  1 2 3 4 5 6 7 8
Graduate Attributes
A IN-DEPTH KNOWLEDGE OF THE FIELD OF STUDY
A1. A comprehensive and well-founded knowledge in the field of study.
selected
selected
  
selected
selected
selected
selected
  
A4. An understanding of how other disciplines relate to the field of study.                
A5. An international perspective on the field of study.                
B EFFECTIVE COMMUNICATION
B1. The ability to collect, analyse and organise information and ideas and to convey those ideas clearly and fluently, in both written and spoken forms.            
selected
  
B2. The ability to interact effectively with others in order to work towards a common outcome.          
selected
selected
selected
B3. The ability to select and use the appropriate level, style and means of communication.                
B4. The ability to engage effectively and appropriately with information and communication technologies.                
C INDEPENDENCE AND CREATIVITY
C1. The ability to work and learn independently.            
selected
  
C3. The ability to generate ideas and adapt innovatively to changing environments.    
selected
          
C4. The ability to identify problems, create solutions, innovate and improve current practices.            
selected
  
D CRITICAL JUDGEMENT
D1. The ability to define and analyse problems.