Bachelor of Engineering (Electrical Power) Honours
Edith Cowan University
About
Electrical power engineering is a well-established engineering discipline encompassing electrical power generation, transmission and distribution, power electronics, electromechanical systems, and renewable energy.
Graduates of the course will be conversant in electrical and electronic engineering, as well as have specialist skills in design, development and management of advanced and sustainable electrical power generation and transmission systems.
The course focuses on the development of knowledge and skills relevant to professional engineering practice and, along with a sound theoretical base, includes strong elements of practical problem-solving, teamwork and project development.
As a result, as well as having multiple technical and transferable skill competencies, graduates will have strong analytical skills and the ability to lead complex projects.
Structure
Students are required to complete 30 Core units, 2 Elective units and a Practicum unit.
Year 1 - Semester 1
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS1154 * | Introduction to Engineering | 15 |
| ENS1115 | Materials and Manufacturing 1 | 15 |
| ENM1102 | Engineering Drawing and Computer Aided Design | 15 |
| MAT1250 | Mathematics 1 | 15 |
Year 1 - Semester 2
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS1101 | Engineering Mechanics | 15 |
| ENS1180 | Introduction to Energy and Resource Engineering | 15 |
| ENS1253 | Electrical Engineering 1B | 15 |
| MAT1251 | Mathematics 2 | 15 |
Year 2 - Semester 1
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENM2104 | Instrumentation and Measurement | 15 |
| ENS2456 | Digital Electronics | 15 |
| ENS3551 | Electrical Networks | 15 |
| ENS5170 | Engineering Systems | 15 |
Year 2 - Semester 2
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| CSP2151 | Programming Fundamentals | 15 |
| ENS2113 | Engineering Dynamics | 15 |
| ENS3553 | Signals and Systems | 15 |
| ENS2457 | Analog Electronics | 15 |
Year 3 - Semester 1
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS5360 | Power Electronics | 15 |
| ENS2159 * | Engineering Innovation and Ethics | 15 |
| ENS5253 | Control Systems | 15 |
| ENS3554 | Data Communications and Computer Networks | 15 |
Year 3 - Semester 2
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS2160 | Thermodynamics | 15 |
| ENS3206 | Power Systems 1 | 15 |
| ENS5230 | Electrical Machines and Transformers | 15 |
| ENS5240 | Industrial Control | 15 |
Note: Students who receive a WAM of 70 per cent or above at the end of their third year of study will be invited to complete a graded Honours degree by taking the two Honours Thesis units in place of the standard project units in their fourth year. Students below this cut-off, or who decline the offer to undertake the Honours Thesis, will graduate with an ungraded Honours degree.
Year 4 - Semester 1
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS5111 | Engineering Practicum | |
| ENS5361 | Power Systems 2 | 15 |
| ENS3555 | Communication Systems 1 | 15 |
| ENS4152 ^ | Project Development | 15 |
| Or | ||
| ENS5145 ^ | Engineering Honours Thesis 1 | 15 |
| Elective Unit | 15 |
Note: Students undertaking the graded Honours pathway should enrol into ENS5145 Engineering Honours Thesis 1 in place of ENS4152 Project Development.
Year 4 - Semester 2
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS5543 | Engineering Management | 15 |
| ENS5445 | Sustainability and Renewable Energy | 15 |
| ENS4253 ^ | Engineering Project | 15 |
| Or | ||
| ENS5146 ^ | Engineering Honours Thesis 2 | 15 |
| Elective Unit | 15 |
Note: Students undertaking the graded Honours pathway should enrol into ENS5146 Engineering Honours Thesis 2 in place of ENS4253 Engineering Project.
RECOMMENDED ELECTIVES
| Unit Code | Unit Title | Credit Points |
|---|---|---|
| ENS2257 | Microprocessor Systems | 15 |
| ENS2170 | Principles of Industrial Maintenance | 15 |
| ENM3218 | Fluid Mechanics | 15 |
| ENS3556 | Wireless Communication | 15 |
| ENS5204 | Real-Time Embedded Systems | 15 |
| ENS5447 | Propagation and Antennas | 15 |
| ENS5203 | Electronic Circuit Design | 15 |
| ENS5251 | Digital Signal Processing | 15 |
| ENS5444 | Telecommunication Networks | 15 |
| ENS5442 | Robotics 1 | 15 |
| ENS5542 | Communication Systems 2 | 15 |
| MAT3486 | Multivariate Calculus | 15 |
| ENS5562 | Renewable Energy Conversions 1 | 15 |
Note: Electives chosen from outside this list must be approved by the Course Coordinator.
^ Core Option * Students will be assessed to see if they have achieved the ECU minimum standard of English language proficiency in this unit. Students who don't meet the minimum standard will be provided with appropriate English language support and development.
Entry requirements
Admission requirement (Band 4)
All applicants must meet the academic admission requirements for this course. The indicative or guaranteed ATAR is as published (where applicable) or academic admission requirements may be satisfied through completion of one of the following:
- AQF Diploma or equivalent;
- Successfully completed 0.5 EFTSL of study at bachelor level or higher at an Australian higher education provider (or equivalent);
- Special Tertiary Admissions Test;
- University Preparation Course;
- Indigenous University Orientation Course; or
- Aboriginal University Readiness Assessment.
English Language requirement (Band 3)
English competency requirements may be satisfied through completion of one of the following:
- Year 12 English ATAR/English Literature ATAR grade C or better or equivalent;
- Special Tertiary Admissions Test;
- IELTS Academic Overall band minimum score of 6.0 (no individual band less than 6.0);
- Successfully completed 1.0 EFTSL of study at bachelor level or higher in the UK, Ireland, USA, NZ or Canada;
- University Preparation Course;
- Indigenous University Orientation Course;
- Aboriginal University Readiness Assessment;
- AQF Diploma, Advanced Diploma or Associate Degree;
- Successfully completed 0.375 EFTSL of study at bachelor level or higher at an Australian higher education provider (or equivalent); or
- Other tests, courses or programs as defined in the Admissions Policy.
Course Specific Admission Requirements
All applicants are required to have Mathematics: Methods ATAR, with equivalents considered, and Physics ATAR or Engineering Studies ATAR, with equivalents considered. It is desirable that all applicants have Mathematics: Specialist ATAR, with equivalents considered.
Portfolio pathway applications are not accepted for this course.
Learning outcomes
- Demonstrate advanced knowledge of the underpinning natural and physical sciences and in depth understanding of specialist bodies of knowledge within the electrical power engineering discipline.
- Think critically, and apply established engineering methods and research skills to complex electrical power engineering problem solving.
- Apply systematic engineering synthesis and design processes to conduct and manage electrical power engineering projects, with some intellectual independence.
- Demonstrate conceptual understanding of the mathematics, numerical analysis, statistics and computer and information sciences which underpin the electrical power engineering discipline and fluently apply engineering techniques, tools and resources.
- Demonstrate clear and coherent oral and written communication in professional and lay domains.
- Demonstrate a global outlook and knowledge of contextual factors impacting the engineering discipline, including respect for cultural diversity and indigenous cultural competence.
- Demonstrate effective team membership and team leadership to implement engineering projects according to relevant standards of ethical conduct, sustainable practice and professional accountability.
- Demonstrate responsibility for own learning, professional judgement and an understanding of the scope, principles, norms, accountabilities and bounds of contemporary engineering practice.
Institution
