units
faculty-ug-eng
Faculty of Engineering
This unit entry is for students who completed this unit in 2012 only. For students planning to study the unit, please refer to the unit indexes in the the current edition of the Handbook. If you have any queries contact the managing faculty for your course or area of study.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Josie Carberry (Clayton); Dr Tan Boon Thong (Sunway) |
An introduction to momentum transfer. Topics include fluid statics; differential and integral balances of mass, momentum and energy; flow measurement; pipe flow and frictional losses; dimensional analysis; pumps; compressible flow.
Assignments: 30%
Examinations (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 1 hour of practice classes, 2 hours laboratory classes and 6 hours of private study per week
CHE2100
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Akshat Tanksale (Clayton); Dr Md Easir Arafat Khan (Sunway) |
This unit will introduce students to the fundamentals of material and energy balances through a systematic treatment of: single and multiple unit operations, reactive and non-reactive processes, recycle and by-pass, extent of reactions, equations of state, vapour-liquid phase equilibrium, solid-liquid phase equilibrium, internal energy and enthalpy changes for process fluids undergoing specified changes in temperature, pressure, phase, reactions and chemical compositions and computer aided simulation of process flow diagrams. The HYSYS process simulation software will be used to aid in the solution of more complex systems.
At the conclusion of the unit, students should be able to:
Laboratory/Assignments/Test: 40%
Examination (3 hours): 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours of lectures, 2 hours of practice sessions and 6 hours of private study per week plus 2 hours of computer labs each fortnight and one 4-hour lab during semester.
CHE2113, CHE2140
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Meng Wai Woo/Dr Shahnaz Mansouri (Clayton), Dr Ta Yeong Wu (Sunway) |
Introduce fundamentals and applications of heat and mass transfer. Develop an understanding of the mechanisms and mathematical representation of conduction, convection and radiation heat transfer and convective mass transfer. Gain an appreciation for the analogies between heat and mass transfer using dimensional analysis. Understand and apply concepts of local and overall heat and mass transfer coefficients including boiling heat transfer to simple problems. Gain an understanding of molecular diffusion in gases, solids, and liquids and develop methods to use these concepts in problem solving. Perform experiments to illustrate the concepts of heat and mass transfer.
1a. Understand the basic mechanisms of conduction, convection and radiation and the mathematical representations of the corresponding rates of heat transfer
1b. Understand the basic mechanisms of diffusive and convective mass transfer within a phase and the mathematical representation of the corresponding rate of mass transfer.
2. Develop an understanding of the dependence of heat and mass transfer rates on fluid and system properties and geometry
3. Understand the analogy between heat and mass transfer
4. Develop skills in solving engineering problems involving heat and mass transfer such as heat transfer between fluids in contact, radiation to/from surfaces, mass transfer between phases in contact.
5. Understand the application of dimensional analysis to the development of correlations for heat and mass transfer
6. Learn to derive and apply expressions for heat and mass transfer coefficients
7. Understand the basic mechanism of molecular diffusion and its mathematical representation.
8. Develop skills in the experimental measurement of heat and mass transfer processes and the interpretation of experimental data in the context of the theory of heat and mass transfer
9. Obtain practice in writing a technical report.
Laboratory: 10%, Assignments and Tests: 20%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice sessions and 6 hours private study per week, plus 2x2 hours laboratory classes during the semester.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | M Wai (Clayton); Ms Veena Doshi (Sunway) |
Introduce fundamentals and applications of classical thermodynamics. Understand the concepts of heat, work, energy, and entropy, the First and Second Laws of Thermodynamics and their application. Introduction to the Carnot cycle and the concept of irreversibility. Understand the use of property diagrams in solving heat engine and heat pump cycles. Understand the operation and analysis of the Brayton, Otto, Diesel and Rankine cycles. Introduction to the analysis of refrigeration and heat pump cycles. Perform experiments to illustrate the concepts of Thermodynamics. Simple combustion processes. Renewable energy and its use in heating and electricity generation and environmental benefits.
Assignments/Tests/Laboratory: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours practice sessions and/or laboratories and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Dr Wei Shen (Clayton); Dr Edward Ooi Chien Wei (Sunway) |
Application of biology, colloid, polymer and surface science to biotechnology, nanotechnology, and sustainable engineering. Colloid stability/coagulation, polymer physics, polymers in colloidal systems and interfacial science. Elements of interfacial engineering and nanomaterials including micelle bilayers, liquid crystals, vesicles, bicontinuous structures. Cell biology and DNA including the introduction of the cell, the parts of the cell, cellular composition and the different types of cells used in biotechnology. The cell as a factory. DNA and the central theme of DNA processes and applications. Examples of bio-nano engineering in food science.
Develop the ability to apply the basic concepts of biology, colloid, surface and polymer science to applications in biotechnology, nanotechnology and sustainable processes. Develop teamwork and communications skills. Develop the skills to undertake a literature search and prepare a literature review.
Mid-semester test: 10%
Individual and team projects: 40%
Examination (2 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours practice sessions/laboratory sessions and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Dr Wenlong Cheng (Clayton); Dr Ta Yeong Wu (Sunway) |
This unit covers thermodynamics from a chemical engineering viewpoint. Content will cover basic concepts and the use of: thermodynamic functions such as free energy, enthalpy, and entropy; estimation of properties of pure compounds and mixtures; description of solution thermodynamics and its applications, equilibrium phase diagrams and chemical reaction equilibria.
On successful completion of this course students should be able to:
Tests/Laboratory: 40% and Examination (3 hours): 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures and 2 hours tutorials per week, plus one 4 hour laboratory during the semester. Approximately 7 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Karen Hapgood (Clayton); Ms Poovarasi Balan (Sunway) |
This unit provides a thorough introduction to process control and simulation. The unit begins with understanding disturbances, why disturbances need to be controlled and possible responses of various systems to a disturbance. The selection of which variables to control, which variables to manipulate and approaches to interactions are covered, together with the most important types of control loops and computer control systems. Topics include common control scenarios - feed back, feed forward, and cascade systems; ratio control; tuning of PID controllers; single loop and multiple loop systems; interactions and decoupling; process simulation and advanced process control.
After completion of this unit, the student should be able to:
Assignments/tests/laboratory: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours of practice sessions/laboratories and 7 hours of private study per week
ENG2091 and ENG2092 or (MTH2010 and MTH2032)
CHE3107, CHE4110
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Dr David Kearns/ M Wai (Clayton); Ms Poh Phaik Eong (Sunway) |
This unit will explore cleaner production and sustainability concepts, the principles of process design and development and associated flow sheets, systematic approaches to waste minimisation in process and utility systems, the methodology of life cycle assessment and application of life cycle assessment to processes and products. These themes will be developed in lectures and supported by student project work related to selected industrial processes.
Understand the principles of cleaner production and sustainability and apply these principles in the design and evaluation of processes and products
Be able to design and evaluate processes with emphasis on resource and energy efficiency and waste minimisation
Be able to develop and draw a detailed process flow sheet
Be able to represent the life cycle of a product using a block diagram, and identify the main environmental impacts of the life cycle.
Understand the principles of life cycle assessment and apply the methodology to processes and products.
Understand the benefits and burdens of materials recycling.
Projects: 40%
Examination (3 hours): 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours project work and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Sankar Bhattacharya (Clayton); Dr Chai Siang Piao (Sunway) |
This unit aims to develop a fundamental understanding of chemical reaction kinetics and reactor design, including:
The student is expected to:
Assignments/Tests: 20%
Laboratory: 10%
Examination: 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours of lectures, 2 hours of tutorials and 6 hours of private study per week, plus two 4-hour laboratory experiments and associated reporting during the semester.
CHE3101, CHE4102
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Dr Akshat Tanksale (Clayton); S P Chai (Sunway) |
A comprehensive treatment of the fundamentals of separation processes of interest to the chemical industry is covered. The fundamental principles of mass transfer are introduced and extended to include principles of interfacial mass transfer and simultaneous heat and mass transfer. General mass and energy balances are derived for equilibrium staged processes. The applications of these principles are made to the unit operations of distillation (binary and multi-component), liquid-liquid extraction, gas-liquid absorption and stripping, adsorption and ion-exchange, and membrane separation processes.
Assignments/tests: 25%
Laboratory: 15%
Examination: 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice sessions and 6 hours of private study per week, plus one 4-hour lab during the semester
CHE3102
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Lian Zhang (Clayton); Dr Poh Phaik Eong/ Ms Poovarasi Balan (Sunway) |
This unit will develop four important inter-related themes associated with the detailed design of chemical equipment and processes. These themes are process safety, mechanical integrity, equipment selection, and process operability (including piping and instrumentation). These themes will be developed using a mixture of lectures and project-orientated learning activities, which will involve computer simulation and at least one plant visit.
Be able to design processes which eliminate or reduce the risks to personnel and the environment and layout a processing plant to facilitate its operation and safety.
Be able to calculate the stress distribution for plane stress and be able to calculate the principal stresses for the following loading conditions: internal pressure, bending, and torsion. Calculate the combined loading on a pressure vessel and complete the mechanical design according to AS1210.
Be able to select materials for particular applications from an understanding of their mechanical properties and corrosion resistance.
Be able to calculate the main parameters required to specify rotary equipment such as pumps, compressors, expanders and mixers and be able to design fully a heat exchanger. Furthermore, be able to select the appropriate form of this equipment.
Be able to draw a P & I diagram for a continuous process including details of the piping system and instrumentation, including simple control strategies.
Understand the role of the chemical engineer in the detailed design of a project and his/her relationship to other engineers and professions who might also be involved.
Tests: 10%
Projects: 30%
Examination (3 hours): 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours practice sessions and 6 hours of private study per week
CHE3109
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Dr Ravi Jagadeeshan (Clayton); M L Chew (Sunway) |
Fundamental principles of transport phenomena, Newton's law of viscosity, Fourier's law of heat conduction and Fick's law of diffusion. Transfer coefficients (viscosity, thermal conductivity and diffusivity). Newtonian and Non-Newtonian fluids, conservation laws (mass, momentum and energy) and steady state shell mass, momentum and energy balances. Numerical solution of partial differential equations, classification of equations (finite differences and finite elements) and incorporation of boundary conditions into numerical solutions. Utilise computer packages to solve complex, realistic chemical engineering problems in fluid flow and transport phenomena.
Develop understanding of the fundamental principles of transport phenomena (mass and heat transfer, multivariable fluid flow, boundary conditions, numerical solutions) and applications to practical chemical engineering problems. Utilise software package (MATLAB and COMSOL Multiphysics) to solve more complex problems commonly encountered in practice.
Individual Tests and Assignments: 50%
Examination: 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours of practice sessions/laboratories and 7 hours of private study per week.
CHE2161, ENG1060 and ENG2091 (or MTH2032)
N/A
CHE4163
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Mr Lizhong He (Clayton); Professor Tey Beng Ti/Assoc Professor Chan Eng Seng (Sunway) |
This unit explores how scalable, commercially viable process-unit operations are harnessed by the biotechnology industry for the production of valuable biomolecules (eg recombinant proteins, peptides, vaccines, enzymes, and nucleic acids). The design, operation and economic issues surrounding large-scale biomolecular process equipment including bioreactors, filtration systems, chromatographic columns, sterilisation and aseptic operation, auxiliary equipment and the associated control systems will be considered. The wider biotechnology environment will be considered especially with regards to GxP, national and international regulatory bodies, biosafety and commercialisation.
At the completion of the unit students will: have an understanding of biological systems and molecules and how these are harnessed in biotechnology; have an understanding of how scalable, commercially viable process-unit operations are employed in bioprocessing for the production of biotechnology products; understand the design, operation and economic issues surrounding large-scale biomolecular process equipment including fermenters/bioreactors, filtration systems, chromatography, aseptic operation, auxiliary equipment and the control systems; be able to read, understand, critically evaluate and develop process flow diagrams; have an understanding of the wider influences on the biotechnology industry: regulatory compliance, ethics and societal expectations; have had direct exposure to the industry through talks from industry representatives and site visits.
Assignments: 50%
Examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours tutorials/practice sessions and 7 hours of private study per week
CHE2165 (or BCH2011 or BMS1011 or BIO1011) and CHM1011 (or CHM1022 or CHM2735 or VPS1021 or VPS1022)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Wenlong Cheng |
This unit introduces the foundation concepts of nanotechnology and nanofabrication, the basic physics of the solid state, the unique properties of nanomaterials; characterisation techniques of materials. This unit also covers polymer synthesis and characterisation, polymer nanocrystals, functional polymers such as conductive polymers and block copolymers, supramolecular structures, and amphiphilic systems and their applications in nanofabrication.
On completion of this unit, students should understand the concepts of nanotechnology, and the important role of nanomaterials in the fabrication of nanodevices; appreciate the impact of emerging nanotechnology in society; be able to describe unique properties of nanomaterials based on the understanding of the basic physics of the solid state; have a thorough knowledge of structural characterisation techniques of materials; have an ability to carry out simple characterisations of nanostructures and materials; be able to describe the fabrication and application of typical functional polymer structures; understand the principles of self assembly of amphiphilic molecules in nanofabrication; have an ability to conduct literature review on a particular topic and complete tasks as part of a team; improve oral and written communication skills.
Projects/Tests/Laboratory: 50%
Examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice sessions, 2 hours laboratories and 6 hours of private study per week
CHM2735 or equivalent
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Warren Batchelor (Clayton); Dr Babak Salamati (Sunway) |
Application of the concepts of chemical engineering with the principles of sustainability to the major manufacturing process technologies. Sustainable engineering consists of simultaneously optimising the environmental, social and economical impacts of a process. Process technologies include the pharmaceutical, energy, petro-chemistry, minerals, food and pulp and paper industries. After an overview of the process technologies, elements of reaction engineering, chemistry, mass and heat transfer are applied using the sustainability principles. For each of the three case studies, a conceptual map of the process industry is presented in preparation for plant visits and the design project.
Develop an understanding of the principles of sustainability and an ability to apply them to the major manufacturing process industries in order to optimise the environmental, social and economical impacts of a process. Develop the ability to analyse an industrial process against sustainability criteria and to identify the critical unit operation or process that maximises sustainability. Improve teamwork and communication skills.
Projects/Presentations: 60%
Examination (2 hours): 40%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours practice sessions/laboratories and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Associate Professor David Brennan & S Sinclair (Clayton); Dr Babak Salamatinia (Sunway) |
An introduction to the role of engineers in the context of their employment in industry and their interaction with the wider community. Students will obtain an understanding of triple bottom line reporting as a driver for management, involving financial, environmental and the social impact of business. Financial management will include project management, project risk, market analysis, project costing and finance and financial indicators. Environmental management will look at the approval process for new projects and on-going environmental improvement strategies. Social management will look at company organisation, the role of unions, occupational health and safety law and safety management.
Continuous assessment: 60%
Final examination (2 hours): 40%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice class and 7 hours of private study per week
CHE4113, CHE4164
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Wenlong Cheng/Dr Ravi Jagadeeshan (Clayton); Dr Edward Ooi Chien Wei(Sunway) |
This unit provides a thorough introduction to particle technology. The unit begins with understanding particle characterisation, the fluid mechanics of single and multi-particle systems and particulate fluidization. The physics underlying powder flow will be covered to enable introductory hopper design. Common powder processing operations will be studied, selected from powder mixing/segregation, sedimentation, dewatering and size enlargement.
After completing this unit, the student will be able to understand particle characterisation techniques and how the motion and fluid mechanics of a single particle and multi-particle assemblies are affected by particle properties. The student will be able to select a suitable particle characterisation method; manipulate particle size distribution data; model particle flow in fluids and fluidized beds; and be able to use particle properties to design a suitable powder hopper to ensure powder flow. Finally, the student will understand the underlying principles of several powder processing operations, be able to design the key parameters for that unit operation and develop an appreciation for the complexities of powder handling and processing.
Assignments/tests/laboratory: 30%
Final examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours of lectures, 2 hours of practice sessions, an average of 1 hour of laboratories per week and 7 hours of private study per week
CHE3104
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr Warren Batchelor / Associate Professor Karen Hapgood |
This unit offers students the opportunity to work in-depth on a significant project, gain first-hand experience of professional practice in industry, applying skills and knowledge gained to date to a real life situation and study new topics in an industrial context. Projects are set up by the industrial partner and academic supervisor, and include tackling open-ended industrial problems, project management, process safety and process economics. A limited number of places are offered each year, and students are selected by the department on the basis of academic merit and leadership potential approximately 6 months in advanced.
Develop an understanding of professional industrial practice and an understanding of the application of chemical engineering science in an industrial setting. Analyse an open ended industrial problem and develop a practical approach. Critically analyse data and develop a new theory or conclusion. Develop interpersonal, oral presentation and technical report writing skills, Develop an understanding of the principles of management, process economics, process safety and the ability to apply these skills in an industrial setting.
Assignments/Presentations: 50%
Final report: 50%
36 hours industrial training placement work and 12 hours of private study per week
CHE3161 and CHE3162 and CHE3163 and CHE3164 and CHE3165 and CHE3166 and (CHE3167 or CHE4163)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Andrew Hoadley (Clayton); Mr Nagasundara Ramanan (Sunway) |
Students work in teams on the design and evaluation of a process plant for a specified duty. This is a capstone design unit drawing together the skills and knowledge previously developed in the areas of detailed design of chemical equipment and processes, process safety, mechanical integrity, equipment selection, process operability (including piping and instrumentation), environmental impact and economic evaluation.
To develop the ability to apply fundamental principles of chemical engineering to an industrial design problem and to prepare a report in a form required of a professional chemical engineer. To develop the skills to tackle a chemical engineering project of complexity matching a real industrial problem, to critically assess a problem and analyse relevant published literature, to develop process and plant designs as specified, to evaluate design work according to specified technical, economic, environmental and safety criteria, to work in a team over an extended period on a complex problem, to communicate concisely complex technical information, both orally and in writing, to manage a project of significant duration to an agreed timetable and to foster in students a sense of responsibility for the design work they have performed.
Presentations/Interviews 20%
Report: 80%
Two practice classes of 3 hours each week and 18 hours of private study.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Adel Fickak |
Quantitative and analytical skills required for biochemical and bioprocess engineering will be covered. The relationships between chemical engineering principles and approaches and biology will be explored. Knowledge about the operational considerations for suspended cultures, immobilized cultures, bioreactors, scaling, process selection, and operation of bioprocess unit operations will be discussed and worked on through calculations.
Assignments/Tests/Laboratory: 30%
Examination: 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours of practice sessions/tutor mediated group work/laboratory work and 7 hours of private study per week
CHE2165 (or BCH2011 or BMS1011 or BIO1011) and CHM1011 (or CHM1022 or CHM2735 or VPS1021 or VPS1022)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Raman Singh |
Understanding of synthetic methods, properties and applications of nanomaterials, including zero-dimensional nanoparticles, one-dimensional nanostructures (nanotubes, nanorods, nanowires and nanofibres), two-dimensional thin films, nanoporous materials and nanofabrication techniques such as lithography and self-assembly. Emphasis on advanced nanomaterials and the importance of nanostructured materials used in various chemical engineering applications. Examples of bionanotechnology-inspired nanostructures using biological building blocks in self-assembling processes.
On completion of this unit, students are expected to gain knowledge and understanding on:
Projects/tests/laboratory 45% and Closed book examination (3 Hours): 55%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 1 hour of practice sessions, 3 hours of laboratories and 6 hours of private study per week
None
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Andrew Hoadley (Clayton); Dr Irene Chew Mei Leng (Sunway) |
This unit will explore heat integration, water integration and recycling of process streams to achieve improved resource efficiencies and waste reduction, the identification and minimisation of waste in reactors and separation processes, natural cycles, pollution mechanisms and effects, strategies for improved industrial ecology and the role of regulatory and economic drivers in cleaner production. These themes will be developed in lectures and be supported by student project work related to selected industrial processes.
Understand and apply heat integration, water integration and process stream recycling in chemical engineering processes to achieve increased raw materials and energy efficiencies and waste reduction
Understand the technologies for treatment and disposal of gaseous, liquid and solid wastes
Understand the mechanisms and effects of natural cycles for water and carbon
Understand the mechanisms and effects of various forms of pollution
Explore the benefits of improved industrial ecology through integrated manufacture and improved industrial planning.
Assignments: 40%
Examination (3 hours): 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
Five hours of contact time per week including 3 hours of lectures and 2 hours of project work. 7 hours of private study devoted to preparation of assignments and independent study.
CHE4112, CHE4152
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Professor Raman Singh (Clayton); E S Chan (Sunway) |
Development and conduct of a specific research or other open-ended project, which may involve literature search, experimental design, equipment design, equipment commissioning, experimentation, troubleshooting, problem solving, data gathering, analysis and interpretation of data, oral and written reporting.
To develop skills to tackle a research or other open-ended project which may involve several of the following elements: literature search, experimental design, equipment design, equipment commissioning, experimentation, troubleshooting and problem solving, data gathering, analysis and interpretation of data, oral and written reporting.
Practical: 100%
6 hours lectures (first 3 weeks of semester) and 20 hours laboratory time and private study devoted to research and report writing per week
A minimum of 120 credit points including CHE2161, CHE2162, CHE2163 and CHE2164
CHE4118, CHE4164
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | A Hoadley |
Specific projects will range widely and be designed to address extensive industry-type problems. The specific problems will vary from year to year. Examples of the type of design projects that might be considered include: design of a refinery heat recovery network rising commercial software; isopropyl alcohol production via direct hydration of propylene; separation of the isopropyl alcohol-water azeotropic by distillation; uprating the capacity of an ammonia liquor plant; heat-exchanger network synthesis using mathematical programming approaches; design of an operable heat exchanger network; design of a site utility and fuel system.
Project 100%
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Walid Daoud (Clayton); Dr Barbie Panther (Gippsland) |
In this unit students will explore aspects of organic, inorganic and physical chemistry. The structures, properties and common reactions of classes of organic compounds will be investigated along with the structures and reactivities of coordination complexes. Aspects of physical chemistry including thermodynamics, kinetics and solution equilibria and electrochemistry will be studied in some detail. The interrelationship of these topics will be explored ultimately leading to the ability to predict reaction directionality in different reactions.
On completion of this unit students should be better able to: display insight into the bonding and structure of a variety of simple inorganic and organic molecules; classify the wide range of organic molecules into various groups, apply systematic naming procedures for a wide range of hydrocarbon species, state chemical properties and reaction for alkanes, alkenes and alkynes and demonstrate understanding of various aspects of isomerism and stereochemistry for such materials; describe the structure and properties of aldehydes, ketones, carboxylic acids and their derivatives, organic nitrogen compounds and aromatic compounds; understand the principal reactions of these compounds and be able to predict products of their reactions; show an appreciation of coordination compounds in terms of aspects of their formation, reactivities and stabilities and also their structures and bonding; explain the first and second laws of thermodynamics and describe and calculate energy changes that occur during reactions including enthalpy and entropy and free energy changes and use this information to predict reaction directionality and spontaneity; demonstrate an understanding of reaction kinetics at both the macroscopic and molecular level; discuss the concepts of dynamic solution equilibria and apply the principles of equilibrium to a number of situations which are important to chemical analysis and biological science; explain fundamental concepts of electrochemistry and their uses in voltaic and electrolytic processes; demonstrate skills and confidence in the laboratory with chemical techniques and measurements in the above areas; display a level of writing skills for laboratory practical reports which is appropriate to first year tertiary chemistry.
Two 2-hour examinations: 60%
Ten computer tests: 20%
Laboratory reports 20%
Dr Walid Daoud (Clayton); Dr Barbie Panther (Gippsland)
Three 1-hour lectures, three hours of laboratory/practice classes activity and six hours of individual study per week
VCE Chemistry units 3/4 or equivalent
CHM1022, CHM1639, CHM1742, ENG1702
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr David Turner |
This unit introduces the foundation concepts of modern organic chemistry through a systematic treatment of: covalent bonding and the shapes of molecules, chirality and stereoisomerism; the nature, nomenclature and reactions of alkanes and cycloalkanes, alkenes and alkynes, haloalkanes, alcohols and ethers, benzene and its derivatives, amines, aldehydes and ketones, carboxylic acids. The nature, properties and synthesis of polymers reinforce the fundamental aspects of this topic. The unit also introduces the important topic of kinetics covering rates of chemical reactions and the kinetics of complex and enzymatic reactions in both homogeneous and heterogeneous systems.
On completion of this unit, students should be able to:
Laboratory exercises: 20%
Examination (3 hours): 70%
Hurdle requirement: Laboratory course must be competed at Pass level
Web based continuous assessment: 10%
3 hours lecture/tutorials per week, 24 hours laboratory classes per semester and 8 hours of private study per week
VCE Chemistry 3/4, or ENG1070
CHM1011, CHM2733, CHM2734
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr Lizi Sironic |
The unit provides the basis for assessing the stress state of most engineering components, artefacts and structures - beams, deep beams, shear walls, and foundations under loads. The unit is also a primer for understanding how the critical strength of a structure or component can be assessed using modern day theoretical, experimental and numerical methods of stress analysis. After completing this unit, students should be able to determine the stress, strain and displacement in a beam and plate subjected to load using either an experimental, theoretical or numerical method. The unit includes linear algebra and numerical methods relevant to civil engineering.
After completion of this unit the student should have the following knowledge and skills:
Tests: 20%
Two projects: 20%
Examination (3 hours): 60%
3 hours lectures, 2 hours practice classes and 7 hours of private study per week
CIV2208
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Ha Bui/Dr Edoardo Daly |
This unit covers basic spreadsheet computing skills and includes particular training in: mathematical tools such as matrix operations (eg solving simultaneous equations), curve fitting and trendlines, and numerical search techniques; user defined functions; user interface elements such as dialog boxes (using elements such as labels, text boxes, drop-down list boxes, spinners, etc) and VBA programming to automate spreadsheet functions. It also covers the following topics in water engineering: estimation of design rainfall; runoff processes; streamflow data and analysis; flood frequency analysis; reservoir operation and a major assignment on hydrology using spreadsheets.
This unit aims to strengthen the computing skills of undergraduates in civil engineering and related courses, and provide experience with numerical modelling and general computer-based problem solving. Many of the required skills are developed in the context of solving problems in hydrology, geomechanics, and structural engineering. There is some emphasis on theoretical aspects of hydrology.
Three projects: 45%
Examination (3 hours): 55%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours computer laboratories/practice classes and 7hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Associate Professor Bill Wong |
This unit introduces the design of steel and timber framed structures in accordance with the design codes. It enables the students to understand the process for the design of steel and timber structures and the background knowledge which leads to the development of the current steel and timber design codes. Students will understand the behaviour of steel and timber structural components under realistic design conditions and relate the knowledge of design to practical design problems in a project-based learning environment.
Three projects: 23%
Three tests: 26%
Exercise submissions: 11%
Final examination (3 hours): 40%
Three hours of lectures, two hours of practice classes and seven hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Associate Professor Frank Collins/Dr Ye Lu |
This unit introduces students to concrete technology, reinforced concrete and masonry design. Three major topics areas are basic concrete materials technology, reinforced concrete analysis and design, and masonry basics and design. The unit provides a balanced coverage of the practical construction aspects, analytical methods and design aspects.
At the completion of this unit students should have the following knowledge and skills:
Practical/project work, tests and laboratory work: 50%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Asadul Haque, Assoc Professor Jayantha Kodikara |
The unit covers all aspects of geoengineering at an elementary level, as well as basic engineering geology, formation and weathering processes, sedimentary, igneous and metamorphic rocks, the geotechnical spectrum: soil, rock, weathering, deposition cycle, basic soil and rock properties, engineering classification of soil and rock, soil structure, weight-volume relationship, and the two/three phase model. It also includes effective stress theory, stresses in a soil mass and shear strength. The unit includes elementary level application of geoengineering knowledge in the analysis and design of shallow and deep foundations, and pavements using CIRCLY software.
At the completion of this unit students should have the following knowledge and skills:
Practical/project work: 42%
Tests: 8%
Final examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
Three hour lecture, two hours of practice class and seven hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Professor Ana Deletic |
Fundamental physical properties of water are introduced together with water flow in pipes as part of a water supply system. The basic equations of continuity, momentum and energy conservation are introduced and friction and minor losses are considered in simple pipe systems. Operation and selection of pumps and hydrostatics and pressure transients are covered. Flow in open channels is introduced with application to waterways, aqueducts and pipes flowing partly full. Applications include design of spillways and culverts.
One assignment: 20%
Three laboratory reports: 30%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Yibing Wang |
The fundamental variables used to describe traffic flow are considered and the procedures used to analyse the capacity and level of service of both signalised and unsignalised intersections are explored. Students will be introduced to aaSIDRA intersection analysis software. Traffic surveys are also considered in detail. Public transport is also considered through an examination at the route level including determination of fleet size and factors affecting operational reliability. Intelligent transport systems are also examined. Consideration will be given to the role of communications, encompassing oral, written and drawing components, in the practice of transport and traffic engineers.
Four assignments: 50%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours of practice classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Each student will be required to select a project from those offered, or subject to the course director's approval, nominate their own project topic. The project outcomes are to be summarised in a major report and a brief oral presentation.
Written project proposal: 10%
Seminar presentation: 25%
Final report on project work (max 6000 words): 65%
12 hours per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Associate Professor Frank Collins |
Introduction to the nature of civil engineering construction projects. Construction technology including equipment performance, construction techniques, prefabrication, concrete, steel, timber, foundations, buildings, roads, formwork etc. Relevant OHS and site environmental management issues and requirements. Industry experience gained by working with a construction company.
Two projects: 65%
Industry experience report: 35%
2 hours lecture, 2 hours practicals, 8 hours private study per week.
(1 site visit and 27 hours industry placement)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Yibing Wang |
Systematic approach to engineering data collection, analysis and interpretation. Scope includes data, information and knowledge; data presentation; errors; randomness; exploratory data analysis; basic statistical procedures; systematic experimental design; stochastic and deterministic models; modelling in engineering systems.
Two group assignments: 15%
Four individual assignments: 40%
Final Examination: (3 hours) 45%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 3 hours practical and 7 hours private study per week.
CIV2207 and either ENG2091 or (MTH2032 + MTH2010)
CIV2207and ENG2091
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Professor William Young |
Need for project management; the project management context; fundamental project management processes and knowledge; tools and techniques for a structured application to project selection and planning including project brief/ideation/concept embodiment decision support tools, numeric profitability and scoring techniques, and EMV/decision tree risk quantification tools; analytical tool application to project scope, time, cost, risk, human resource, OHS and quality issues. Review of company financial management concepts.
To provide a framework and basic knowledge for understanding the processes of project management. The major themes covered in this unit are:
Project management: a perspective; project selection; project feasibility; risk assessment and scope definition; project time management; project risk management; project cost management; project cost budgeting and control; project quality management; human resource management and strategic management.
Students are expected to:
Acquire a basic knowledge of the principles and practice of project management; understand the different components of a project, their interaction and applications;
appreciate the role of a project manager as a member of a multi-disciplinary team and develop skills in the critical assessment of alternative solutions.
Progressive assessment: 40%
Final examination (3 hours): 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practice and site visit and 4 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Prof X-L Zhao, Dr B Bai |
Loads and load paths for multi-storey structures, including the action of core walls. Design of composite steel-concrete floor systems. Matrix structural analysis for the determination of forces and displacements in structures. Relationship between frame analysis software and the technique of matrix analysis. Emphasis on performance issues for buildings which are not related to strength and deflection.
Practice problems: 5%
Tests: 17%
Presentation and report: 23%
Final examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practice and 8 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Ye Lu |
Essential aspects of highway bridge design, assessment and rehabilitation. Criteria for selection of bridge types which are most prevalent. Examine structure as a whole, and implement the analysis and design of the bridge deck and the supporting members. Relevant strength and serviceability limit states applied to the design of the bridge, life cycle performance and risk assessment, material degradation, corrosion, fatigue and time-dependent deformations of reinforced and prestressed concrete elements of the bridge, structural rehabilitation and repair techniques.
Tests: 16%
Projects: 34%
Final examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practicals and 8 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Jayantha Kodikara |
Geological processes, folding and faulting, geological map interpretation, mineral types and influence on engineering properties, identification of soil and rock types, origins and behaviour, site investigation techniques, geological history, stereographic projection; kinematic analysis of slopes, engineering uses of rock and soil; the stress-strain-pore pressure response of soil and rock; failure criteria; stress paths; drained and undrained strengths, consolidation and creep settlements; earth pressures; and behaviour, analysis and design of slopes, embankments, retaining walls and tunnels.
Test: 10%
Design assignment: 40%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practicals and 6 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Professor Malek Bouazza and Dr Gavin Mudd |
Overview of concepts relating to groundwater resources and seepage, with emphasis on seepage containment in reservoirs, ponds, soil pollution and its avoidance, focusing on soil behaviour and its effect on seepage, groundwater percolation and migration of contaminant in the nearfield of waste containment facilities. Focus will also be on the function, design and construction of engineered soil barriers to prevent leakage from water reservoirs, ponds or to isolate different types of waste.
Tests: 20%
Design assignment: 40%
Examination (2 hours): 40%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practice class and 8 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr Christoph Rudiger |
Overview of the various water and wastewater systems in an urban environment, their functions and modes of operation and influence of climate variability on urban requirements in terms of management and discharge of stormwater and wastewater. Examination of water supply treatment, stormwater management system, sewerage system and the interface between these systems.
Assignments: 50%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practice and site visit and 8 hours private study per week.
CIV2207 and CIV2263; except for students enrolled in an Environmental Engineering (single or double) degrees who require CIV2263 only.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Nirajan Shiwakoti |
Introduce fundamentals and role of road engineering theory and practice. Examine a number of issues related to the planning, design and construction of roads, including: road planning, the road traffic environment, design and rehabilitation, geotechnical issues related to pavement performance, pavement drainage, road construction and road environmental safety.
Project design: 50%
Final examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practical and 8 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Each student will be required to select a project from a number of topics offered. The project outcomes are to be summarised in a major report and in a brief oral presentation.
Practical work: 100% (written project proposal, final report on practical work, seminar presentation)
12 hours per week
Completion of 120 credit points and level 3 units in chosen area
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Each student will be required to select a project from a number of topics offered. The project outcomes are to be summarised in a major report, a technical paper and in a brief oral presentation. Enrolment in this unit is by departmental approval only.
Practical work: 100% (written project proposal, preliminary and final reports on practical work, seminar presentation)
12 hours per week
CIV4210 and credit weighted average of at least 65%
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Frank Collins/Dr Ha Bui/Dr Majid Sarvi/Dr Wenhui Duan |
To carry out the design for a specified civil engineering development. The design project will vary from year to year but will include aspects of structural, water, geomechanics and transport design.
Written and oral project submission and interview: 100%
39 contact hours
(CIV3221 and CIV3222) or (CIV3247 and CIV3248) or CIV3264 or CIV3283
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr Wenhui Duan |
Coordinate transformation method, minimum potential energy, bifurcation loads, elastic buckling load, free vibration with damping, lumped mass modelling method, natural frequency and vibration mode, basis for FE method such as process of discretisation, element types and boundary conditions.
Three projects: 40%
Beam analysis problem and test: 10%
Final examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours computer laboratories, 2 hours practical and 6 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Amin Heidarpour/Dr W Young |
Advanced methods for the design of structures, considering both loading and strength aspects of design. Strength and serviceability design of continuous post-tensioned concrete members; analysis of shear and torsion in prestressed concrete members, design and detailing of anchorage zones. Introduction to the plastic design concept for engineering practice, with particular reference to steel structures design; methods of plastic analysis from simple beams to complex frames. Introduction to yield line theory for reinforced concrete slabs; yield line solutions based on work equations. Lower bound solutions for reinforced concrete slabs using Hillerborg strip method.
Three tests: 24%
Projects and assignments: 26%
Final examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 3 hours practicals and laboratory and 7 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Professor Malek Bouazza |
Geotechnical engineering concepts applied to solve or minimise geo-hazard problems specific to domestic and hazardous waste containment facilities (landfills), contaminated sites and tailings dams. The unit focuses on geotechnical aspects in the analysis, design and construction of waste containment facilities (landfills), ground improvement, redevelopment of old landfills, and contaminated site remediation.
Oral presentation: 20%+ Tests: 30%
Assignments: 50%
26 lectures, 26 hours of design class or practicals and 8 hours of site visits
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Asadul Haque/Professor J Walker |
Review of soil mechanics model; the geological context of a project; site investigation and laboratory testing techniques; conceptual design of foundations; elastic, consolidation and creep settlement of shallow footings; total and differential settlement; bearing capacity of shallow footings of layered soils; raft foundations; piling options; the relationship between construction techniques and pile performance; axial capacity of single piles in compression and tension; settlement of single piles; capacity and settlement of pile groups; piled rafts; lateral capacity of piles; rational methods for design of rock-socketed piles; static, dynamic, statnamic and integrity testing of piles.
Test: 25%
Assignments and interviews: 75%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practical and 8 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | D McCarthy |
This unit is designed to give a broad understanding of the integrated management of water resources within an urban context. This is a field of practice growing in importance in Australia and overseas, and will equip students well for careers in urban water management. The scope of the course will be multi-disciplinary, giving students an understanding of the range of perspectives required in integrated urban water management (IUWM) covering structural and non-structural techniques available. The social science and ecological perspectives will be emphasized to give an appreciation of the multi-disciplinary nature of IUWM. Software packages such as MUSIC and Aquacycle will be introduced.
Group project: 50%
Closed book examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor J Walker |
This unit considers the quality and quantity aspects of water resources management. Tools and techniques appropriate for design and analysis of water resource systems are introduced including rainfall/runoff modelling, yield analysis, characterisation of flow regimes, design of environmental flows and water reuse systems. The basic principles of water quality modelling will be addressed and developed. Water quality management issues to be addressed include the assessment of water quality in various watercourses, such as rivers and lakes, natural systems for water pollution control and pollutant transformations in aqueous environments.
Assignments: 50%
Examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practicals and 8 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor G Rose |
Examines the performance, impacts and costs of various urban passenger transport modes and the factors influencing the level, pattern and trends in urban travel demand and the issues relevant to selecting a mode for a particular urban passenger transport task. The role of the analytic methods used in transport planning is examined as are the factors to be considered in conducting transport surveys including sample design, questionnaire design and survey administration.
Three assignments: 45%
Class participation: 10%
Final examination (3 hours): 45%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practical and 8 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Prof W Young |
The traffic engineering profession, road hierarchy, design of road and street networks, traffic management, traffic and parking surveys, traffic impact analysis, treatment of hazardous road locations, parking, design, planning for pedestrians and cyclists, public transport, environmental and energy impacts of traffic systems, intelligent transport systems.
Class tests: 5%
Reports: 10%
Projects: 35%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lecture, 2 hours practice and site visit, 8 hours private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | E Viterbo (Clayton), Y C Kuang (Sunway) |
This unit will cover continuous-time and discrete-time signals, including sampling, aliasing, and the sampling theorem. Complex exponentials, and their representation as phasors, lead to periodic waveforms, Fourier series and the signal frequency spectrum. Modification of spectra will be described, using FIR filters, discrete-time systems, unit-sample response, discrete convolution, frequency response of FIR filters, z-transforms, IIR filters, linear time-invariant systems, convolution integrals, continuous-time Fourier transform, windowing, DFT, FFT, time-frequency spectrum analysis, spectrogram. Connecting frequency response and time response completes the unit.
To understand signals and how they are analysed and modified by systems. To understand the strengths and weakness of sampled and digitised representations of signals, including images, in both time and frequency domains. To experience the strength of mathematics in describing these processes.
Laboratory and assignment work: 30%
Examinations (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory/practice classes and 6 hours of private study per week
ECE2101
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Professor M Premaratne (Clayton); Dr Tn Win (Sunway) |
This is a study of electrostatic, magnetostatic and electromagnetic fields and their use to create devices and systems. This study includes a mathematical description of the fields, an examination of the basic laws governing the generation of fields, and a study of interactions with dielectric and magnetic materials. Maxwell's field equations are introduced. Applications of electromagnetic fields such as radio, televisions, transformers, electrical motors and generators are examined, as are electrostatic painting, magnetohydrodynamics and beam control in a synchrotron. Naturally generated fields such as the earth's magnetic field and the electric fields causing lightning are also discussed.
To understand the nature, representation, analysis and uses of electric and magnetic fields.
Laboratory and assignment work: 30%
Examinations (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory/practice classes and 6 hours of private study per week
ENG1060, ENG1090 (or equivalent)
ECE2201
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Jonathan Li (Clayton); Dr Low Sew Ming (Sunway) |
the unit will provide a grounding in circuit theory leading to solution of electrical networks with node and mesh analysis, equivalent sources, two port representations and simulation. AC analysis with phasors, real and reactive power, first and second order transient responses will be included. Frequency and time response will be developed with Laplace transform techniques.
Feedback control systems are introduced using differential equations, Laplace transform, time, frequency and state space representations. the concepts of poles and zeros, forward transfer functions, and PID control will be developed. Stability of feedback systems, root locus diagrams, Nyquist and Bode techniques, gain/phase margin concepts, and disturbance rejection will be covered.
On successful completion of the unit students will be able to:
Examination: (3 hrs), 70%. Laboratory and assignment work: 30%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory/practice classes, and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | J Armstrong (Clayton); M H Jaward (Sunway) |
This unit provides an introduction to the important aspects of modern telecommunication systems. Particular emphasis is given to digital communication systems including the internet. The concept of layered architectures will be introduced. Topics will include modulation techniques, source and error coding, multiplexing, peer to peer protocols, LAN protocols, packet switching, TCP/IP architecture and network security.
This unit aims to provide the student with an insight into the basic principles of modern data communication and telecommunication networks, and relate this information to their wider use in the engineering environment, including networking, information representation and transmission.
Laboratory and assignment work: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2401, TEC2141 and TRC4801
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | J M Redoute (Clayton), S M Low (Sunway) |
Students will be introduced to the fundamentals of linear electronic circuit analysis and design. At the completion of the unit students will develop skills in using state of the art prototyping and measurement tools for linear electronic circuit analysis and design. The topics covered in this course include, sinusoidal steady-state analysis using phasors and complex impedances, feedback concepts, solid-state electronics, solid-state diodes and diode circuits, field-effect transistors, bipolar junction transistors and single-transistor amplifiers.
An understanding of semiconductor devices and their uses as near linear amplifiers. More generally, an understanding of linear systems, and of how non-linear systems can be approximated by linear systems, and the advantages of doing so.
Laboratory and assignment work: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
TRC2500
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | T Drummond (Clayton), M Ooi (Sunway) |
This unit provides an introduction to computers and CPU organisation, assemblers and compilers, and algorithm design for engineering problems. It covers the language C and its implementation on a typical computer, including standard data types, arrays, control statements, functions, including ways of parameter passing, C library functions, pointers, strings, arrays of pointers, structures, linked lists and binary tree data structures, dynamic memory allocations, and calls to assembly language programs. Object-oriented programming is introduced. Software engineering is covered as the methodology of software development and lifecycle models. Operating system concepts are introduced. The unit also includes an introductiojtion to programmable logic controllers (PLCs).
To understand the basic concepts of computer programming, and to learn to program in the C language.
Laboratory and assignment work: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
CSE1301, TEC2041, TEC2042, TEC2171, TRC2400
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor L Kleeman (Clayton); Mr Nader Kamrani (Sunway) |
This unit introduces the student to modern logic design techniques, hardware used and common representations. Topics include two and multi-level combinational logic, decoders, multiplexers, arithmetic circuits, programmable and steering logic, flip-flops, registers, counters, RAM and ROM. Using this hardware the design component will include finite state machine design and applications to computer data path control. This will incorporate simple analogue and digital I/O interfacing. Programmable logic devices will be covered, and the use of a hardware description language for describing, synthesizing and testing digital logic. Laboratories cover logic design, implementation, and testing.
To understand the analysis and design of complex digital systems from building blocks, using modern digital design software.
Laboratory and assignment work: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2701, TEC2172, TRC2300
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | N Karmakar (Clayton); R Parthiban (Sunway) |
In this unit students will be introduced the principles of electromagnetism and wave propagation of wireless and guided waves based on the use of Maxwell's equations to analyse of more complicated structures such as radio frequency (RF) transmission lines, plane interfaces, optical waveguides and optical fibres, antenna and cylindrical metallic waveguides. Students will then apply these wave propagation principles to examine the practical issues of electromagnetic compatibility (EMC) including: interference and coupling mechanisms, RF circuit layout and grounding, interfaces, filtering and shielding and EMC measurement techniques.
To understand the principles of propagation electromagnetic waves in wireless and guided wave structures such as RF transmission lines, plane interfaces, optical waveguides and optical fibres, antenna and cylindrical metallic waveguides. To develop a working knowledge to apply the EM wave propagation phenomena to design basic and advanced antennae and optical waveguides and fibres. To develop a working knowledge of electromagnetic compatibility (EMC) including interference and coupling mechanisms, RF circuit layout and grounding, interfaces, filtering and shielding and EMC measurement techniques.
Continuous assessment: 30%
Examination: (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2021 (or ECE2201 or PHS2022) and ECE2041 (or ECE2401)
ECE3202
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
This unit introduces control systems and feedback and outlines their role in modern society. Initially tools for the modelling, analysis and design of continuous-time systems are briefly presented. Following this, the main focus is shifted to the analysis and design of modern discrete-time and hybrid sampled-data systems. For analysis, difference equations, z-transforms, transfer functions, frequency response, and state-space models are covered, as also is computer-based system identification. For design, pole-placement, and state feedback, state estimation, and linear quadratic optimal design are covered. Aspects of robust and non-linear control are also introduced.
An understanding of control theory. An appreciation of the diversity of control applications. An understanding of feedback and feed forward systems. An awareness of simplifying assumptions and their limitations. An understanding of digital controllers. The ability to model real systems in a variety of ways. The ability and confidence to effectively use feedback to improve the dynamic properties of a plant.
Examination: (3 hours): 70%
Continuous assessment: 30%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures and 3 hours laboratory and practice classes, and 6 hours of private study per week.
ECE3301
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Mr Mehmet Yuce/Dr Tadeusz Czaszejko (Clayton); Dr. Naing Win Oo (Sunway) |
The unit begins by considering electrical machines, looking at DC machines, induction motors, synchronous motors and other types of motors under fixed and variable speed operation. Then thyristor rectifiers and switched power converters are presented, looking at their use for electrical energy conversion in general and variable speed motor control in particular. Finally, single and three phase AC networks, power factor correction, and electrical power generation, transmission and distribution networks are explored. Particular focus is given here to three phase transformers, transmission line modelling, quality of electrical supply, electrical protection systems, and power system control.
To explore electrical power equipment, apparatus and systems. To understand the conversion of electrical energy into alternative forms for different load requirements. To understand electrical power generation, transmission and distribution systems.
Continuous assessment: 30%
Examination: (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2061 or TRC2500
ECE3502 and TRC3501
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Jean-Michel Redoute (Clayton); Dr Mark Ng (Sunway) |
The unit further explores the integration of multiple devices on a chip. MOS and BJT single ended as well as differential amplifier circuits, along with basic analogue circuit blocks like the current mirror, are introduced and developed using small signal models. Practical Operational Amplifiers are considered where properties deviate from ideal in terms of frequency response, CMMR, noise, stability and input/output impedance. The use of feedback in electronic circuits is studied, and ways to improve arising stability issues in operational amplifiers (eg using pole compensation) are discussed. Nyquist is presented and frequency domain analysis and design shall be explicitly explored via Bode plots. Concepts of State Space representation, transfer functions, canonical realisation, observability and controllability and discrete-time systems are presented.
Mid-semester test/laboratory/project and assignment work: 30%, Examination: (3 hrs) 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory/practice classes and 7 hours of private study per week
ECE2062
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | R Russell (Clayton); N Ramakrishnan (Sunway) |
This unit provides an introduction to computer architecture using a modern microprocessor as an example. Practical considerations involved in interconnecting logic element are explored, along with software and hardware techniques for interfacing computers to peripheral devices. An introduction to communication protocols used to connect local peripheral devices to a microprocessor, including RS232/RS422/RS485, CAN bus and i2C is provided. Real time systems including concurrency, inter-process communications and scheduling are introduced.
Laboratory and assignment work: 30%
Examinations (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
(ECE2071 or CSE1301 or FIT1002 or TEC2171 or TRC2400) and (ECE2072 or TEC2172 or TRC2300)
ECE3703, GSE2303, GSE3802, TEC3174, TRC3300
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Ahmet Sekercioglu (Clayton); Dr Narayanan Ramakrishnan (Sunway) |
This unit extends the level of complexity of electronic design by integrating and applying knowledge from a number of second year units. Students will use knowledge from linear and non-linear electronics, computer engineering and communications engineering, to tackle a group project, applying project management skills, and extending their experience of working in groups. The project will extend the design processes introduced in the earlier units to a larger, more complex, and less constrained situation. The project will be complemented by lectures in project management, including working with teams, project management tools and techniques, and written and verbal communication.
Integration and application of knowledge from different areas. Practical experience of the tools of circuit design of greater complexity. Experience in reading a wide range of component data and extracting the relevant information. Skills to work in teams. Skills to find optima in designs subject to constraints. Confidence to consider many possible solutions and choose on the data available. Experience of practical problems of more complex electronic constructions.
Project: 70%, Requirements Analysis Document: 10%, Design Specification Document: 10%, Presentation: 10%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2041 and ECE2061 and (ECE2062 or ECE2031) and ECE2071 and ECE2072 or FIT1002 for students studying double degrees with science
ECE3905, TEC3191, TRC3000
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | M Yuce (Clayton); N Win Oo (Sunway) |
This unit introduces systems engineering and reliability analysis. Key concepts and language are introduced through real world examples. Frameworks for analysing the life cycles of systems are introduced. Tools and techniques to aid decision-making are provided. Group projects and discussions reinforce the concepts through real-world examples. The concepts of component and system reliability are introduced and extended to reliability analysis of non-repairable and repairable systems, including time dependent reliability and availability, mean time to failure, mean repair time and lifetime distribution functions.
To understand the process of systems design. To learn principles of reliability evaluation of engineering systems and the use of mathematical tools in reliability analysis.
Continuous assessment: 40%
Examination: (3 hours): 60%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours laboratory and practice classes and 8 hours of private study per week
TEC3192
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Professor Kate Smith-Miles (Clayton), Mr Nader Kamrani (Sunway) |
This unit will introduce students to matrix decomposition methods including singular value decomposition with applications including data compression, image processing, noise filtering, and finding exact and approximate solutions of linear systems. Numerical methods for working efficiently with large matrices and handling ill-conditioned data will be discussed. Methods for unconstrained and constrained optimisation will be presented, with use of MATLAB. The second half of the unit will focus on stochastic processes inboth discrete and continuous time, with applications to time series modelling, and circuit analysis.
On completing this unit, students will have learned advanced mathematical techniques for working efficiently and reliably with both deterministic and stochastic systems, and their use in solving problems frequently arising in engineering applications such as solving linear systems, solving systems of differential equations, handling noise, modelling control systems, time series analysis, and studying stability in dynamical systems. Students will develop a rich set of techniques: eigenanalysis greatly simplifies the calculations for many numerical tasks; singular value decomposition and principal component analysis provide powerful tools for data compression and noise filtering; curve fitting methods for estimation, and optimization tools add to the toolkit of techniques students will learn to enable them to tackle a range of practical engineering problems. Students will also have learnt how to work with discrete and continuous random variables and some important distributions, random vectors and their covariance matrices, calculating best linear predictors, modeling using
random sequences and stochastic processes in continuous time, autocovariance functions, transfer functions, spectral density and linear filters, ARMA models and finding best linear predictors for stationary processes.
Continuous assessment: 30%
Examination: (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours laboratory and practice classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | TBA |
The practical application of DSP systems using industry standard platforms. The unit covers practical aspects including current industry standard integrated software development and debugger tools, assembler from C, code optimisation, memory management, cache, Architecture, Hardware pipelining, XDAIS (eXpressDSP Algorithm Standard), EDMA, HWI (hardware interrupts) , McBSP (multiple channel buffered serial port), channel sorting, DSP/BIOS (scalable real-time kernel), HPI (host port interface). Advanced topics include wavelets, adaptive filters, real time digital filters.
To understand signals as fractal and non fractal and how they can be faithfully recorded, analysed and modified by systems. To understand the strengths and weakness of sampled and digitised representations of signals, including images, in both time, frequency and time-frequency / time-scale domains. To experience the strength of mathematics in describing these processes. To understand and implement adaptive filter and real time filter systems. To implement adaptive filters on an industry standard DSP development system. To implement real-time filters on an industry standard DSP development system. To implement wavelets on an industry standard DSP development system. To develop a working knowledge of a real time current industry standard integrated software development system. To develop a working knowledge of a real time hardware development system. To develop a working knowledge of a real time hardware peripherals and their interfacing.
Continuous assessment: 30%
Examination: (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2011 (or ECE3102)
ECE3073 (or ECE3703) and ECE3093 (or MAT3901)
ECE4404, ECE4805, ECE5012, ECE5404, ECE5805
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | tba |
This unit is a study of passive and active electronic components and devices and how they perform at radio and microwave frequencies. Physical RF circuits are to be designed, built and tested in the laboratory and as design projects. Extensive use is made of modern RF simulation and design software.
To educate the student about the unique nature of working at RF and microwave frequencies
To give the student the necessary analytical skills to analyse RF and microwave electronic components, circuits and systems
To teach the student to design RF and microwave circuits and systems
To give the student the skills to utilise sophisticated RF and microwave EDA software and to use RF and microwave test equipment to develop RF and microwave electronics
Continuous assessment: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
(ECE2021 or ECE2201) and (ECE2041 or ECE2401) and (ECE2061 or ECE2601)
ECE4204, ECE5203, ECE5204
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Mohamed Hisham Jaward (Sunway) |
This unit is a study of the fundamentals of radio transmitters and receivers, the wireless radio channel and radio/wireless networks. An investigation into the configuration of wireless units to create communications systems and networks leads on to an appreciation of the diversity of wireless applications for personal and public use.
To understand the basics of radio transmission and reception in different frequency bands and different physical environments
To understand the limitations on radio communications imposed by the radio channel
To learn the wide range of applications of radio/wireless technology
To understand mobile radio communications and its networking capabilities.
Continuous assessment: 30%
Examination: (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2021 (or ECE3202 or PHS2022) and ECE2041
ECE5024
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr Edwin Tan Chee Pin (Sunway) |
This unit aims to firstly develop an understanding of key features of methods for mathematically modelling various categories of dynamical systems in terms of sets of dynamic and algebraic equations, ranging from engineering to biomedical systems. Secondly, students are shown how to write algorithms for efficient numerical solution of these equations. Computer-aided control systems design using optimal and robust control methods is then covered. Thirdly, students are introduced to Lyapunov and function analytic techniques for nonlinear systems stability analysis, and to nonlinear control design methods including feedback linearisation, sliding mode and passivity-based control techniques.
Continuous assessment: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory and practice classes and 7 hours private study per week
ECE2031 and (ECE3062 or ECE3031)
ECE4302, ECE5032, ECE5302
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Kuang Ye Chow/Mr Edwin Y S Sim |
This unit will introduce students to modern instrumentation, measurement theory, control and systems testing. The unit will introduce virtual and modular software and hardware tools and data bus architectures. A brief overview of the relevant industrial standards and protocols as well as expected future development will be included, along with the issues of measurement uncertainties, calibration and statistical analysis of results. There will be an additional section within the unit that will equip students with basic knowledge of occupational health and safety issues related to instrumentation.
Upon successful completion of the unit, the students are expected:
Laboratory and assignment work: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
Lecture: 3 hours per week
Tutorial/Laboratory: 3 hours per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | E Viterbo |
This unit will cover aspects of physical layer communications which are relevant to modern communication systems. Digital modulation techniques, including quadrature modulation and orthogonal frequency division multiplexing (OFDM) will be covered. The effects of noise on bit error rates will be covered, along with techniques to reduce them, including matched filtering and equalisation. Information theory covers questions of capacity, diversity, and error correction coding. Finally the use of multiple input multiple output (MIMO) communication systems will be covered.
Knowledge of the fundamental limits of communication in noisy band limited channels. Knowledge of digital modulation techniques and the advantages and disadvantages of different techniques. Understanding of the properties of different communication channels and how channels can be modelled mathematically. Knowledge of the properties of modern error correcting codes. Understanding of how orthogonal frequency division multiplexing and multiple input multiple output (MIMO) multiple antenna systems can be used in modern communication systems and the advantages and limitations of their use. Understanding of the statistical nature of communications. Skills to design and simulate modern communication systems using industry standard simulation tools.
Continuous assessment: 30%
Examination: (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures and 3 hours laboratory and practice classes, and 6 hours of private study per week
ECE2041 or ECE2401
ECE5042
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor A Lowery |
Students will study the characteristics of key components that make up optical communications systems, including: lasers and advanced lightwave sources and direct modulation, optical modulators, optical fibres, optical amplifiers, filters and multiplexers, optical receivers and associated electronics. Secondly, students will use this knowledge to analyse and design optical communications systems. Examples will include local-area networks, metropolitan area networks, long-haul links and transcontinental networks.
Knowledge of characteristics of fibres, including dispersion and non-linearity, and of multiplexers, filters and Raman optical amplifiers. Ability to prepare a power budget for an optical communications link. Understanding of the dispersion limits and compensation techniques for optical links. Knowledge of wavelength division multiplexing in links and networks. Skills to design optical communications links for short, medium and long-haul applications, and select appropriate components during link design. Ability to simulate the interactions of components and understand performance measures. Ability to propose optical network architectures for access and metropolitan networks. Ability to specify the performance of networks from an operator's perspective. Experience in making basic measurements on optical components and systems.
Continuous assessment: 30%
Examination: (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2021 (or ECE3202 or PHS2022) and ECE2041 (or ECE3402)
ECE4405, ECE5043, ECE5405
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | A Sekercioglu (Clayton); M Hisham (Sunway) |
This unit aims to study the fundamentals of telecommunication network protocols by having the Internet's software architecture as its primary focus. Reliable communication over an unreliable network layer, connection establishment and teardown, congestion and flow control, and multiplexing issues are covered. The functions of routers and routing algorithms and protocols for finding paths and interconnecting large number of heterogeneous networks are studied. Local area networks and protocols for sharing a multi-access channel are studied. Finally, protocols for network security, techniques for providing confidentiality, authentication, non-repudiation and message integrity are also studied.
Laboratory and assignment work: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory/practice classes and 7 hours private study per week
ECE4411, ECE5044, ECE5411, TEC3742
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) |
Coordinator(s) | E Viterbo (Clayton); R Parthiban (Sunway) |
This unit addresses the fundamental concepts and analytical tools for modelling, predicting and improving the performance of telecommunication networks. It also introduces simulation methods. First, network performance modelling and estimation is studied. Second, congestion in telecommunication networks is covered, and effectiveness of various congestion control algorithms, especially. Third, a comparative analysis of routing algorithms is covered from the graph theory perspective. The focus then shifts to individual links and an introduction to information theory, and limits of channel capacity are discussed. Finally, methods for Quality of Service (QoS) guarantees are studied.
To understand the basics of random processes and their relationship to traffic modelling.
To learn about link models for circuit switching, for packet switching and queuing theory for delay analysis.
To understand methods for modelling networks as graphs, and their application to routing.
To understand the fundamental principles of centralised network design.
To learn about flow and congestion control algorithms and their comparative analysis.
To know the building blocks of an architecture for guaranteed quality of service provision in next generation networks.
To develop skills to choose and use simulation tools for predicting network performance.
Appreciation of the role of a network engineer.
Confidence in identifying and using the most suitable analytical or simulation tool for network planning.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2041 or ECE2401
ECE5045
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Naing Win Oo (Sunway) |
This unit aims to develop an understanding of the structure and operation of electrical power systems using different resources, and considering their environmental impacts. It covers current and future energy scenarios for the world and Australia. This requires an understanding of the basic concepts and modelling of electrical power systems, including techniques for power flow and fault analysis, control of voltage, frequency, harmonic distortion, and system stability. Methods are presented to identify and clear faults, maximise power system economy and estimate the capital cost as well as unit price of electricity ($/kWh) using various energy conversion technologies.
To understand energy conversion technologies, electric power system modelling, power flow analysis faults in power systems electrical grid power and frequency control power stability and quality of supply economy of electric power systems.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2061 or TRC2500
ECE3051 or (TRC3501 and TRC3600)
ECE4503, ECE4057, ECE4507, ECE5507, ECE5053, ECE5503
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | T Czaszejko |
The unit looks at the use of power electronic converters in applications such as variable speed motor drives and electrical grid energy control. It analyses voltage and current source inverters operating under open and closed loop regulation, develops advanced models of AC motors, and then integrates these concepts into variable speed drives for AC motors. A similar approach is used for DC motor drive systems, first using multipulse SCR converters and then hard switched converters for more advanced systems based on brushless DC and stepper servo motors. Finally, topologies such as cycloconverters, matrix converters and multilevel converters are presented, together with typical applications.
To understand
The way in which electrical motors can operate at variable speeds
The use of power electronic converters for variable speed motor control
How electrical energy can be controlled by power electronic converters for industrial processes and to improve power quality.
Laboratory and assignment work: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory/practice classes and 7 hours private study per week
(ECE2031 and ECE2061) or TRC2500
ECE3051 or (TRC3501 and TRC3600)
ECE4504, ECE5054, ECE5504
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Tadeusz Czasjeko/Mr Robin Lisner |
The unit presents a structured treatment of the design of switched mode power electronic converters. It begins by considering semiconductor devices and topologies of various types of converters that suit particular applications. Then, detailed design processes are developed, taking into account converter topology and semiconductor device selection, design of magnetic components, voltage-mode and current-mode closed loop control, use of simulation, physical design layout, and EMI/EMC considerations, in the context of particular applications. Finally, specific real-world systems such as electronic lighting ballast's, UPSs and high-frequency induction heating systems are presented as examples.
To understand the use of power electronic switching conversion techniques to control electrical power in a wide-range of applications.
To select appropriate converter topologies and structures for specific applications.
To be able to design and construct practical switched mode power electronic converters.
To be able to use simulation tools as part of the design process.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2061 or TRC2500
ECE4505, ECE5055, ECE5505
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | T Czaszejko |
The unit introduces concepts of high voltage phenomena in the context of design and testing of electrical power plant. The unit describes sources of over voltage in power systems. It then presents fundamentals of high voltage insulation design and condition monitoring methods. It describes insulation performance characteristics and diagnostic methods in plant such as generators, transformers and high voltage cables. The notions of insulation co-ordination and over voltage protection are also established. Additionally, the unit introduces static electricity phenomena, hazards they pose and technology applications they bring.
To learn and understand the principles of high voltage technology as applied in the design and testing of power system equipment as well as in other industrial applications.
Continuous assessment: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE4508, ECE5058, ECE5508
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | L Kleeman (Clayton); M Ooi (Sunway) |
The unit aims to develop a fundamental understanding of the performance, specification and fabrication of large scale digital circuits. Students will become experienced at the design, simulation, verification and debugging of complex large scale digital circuits using a Hardware Description Language (HDL) and current CAD tools with FPGA development boards. Two group design projects will be undertaken: one involving an HDL using FPGA devices and another involving custom VLSI CMOS design and simulation
Laboratory and assignment work: 40%
Examination (3 hours): 60%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory/practice classes and 7 hours private study per week
ECE2061 or TRC2500
ECE3073 or TRC3300
ECE4604, ECE5063, ECE5604
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Melanie Ooi (Sunway) |
Electronic testing in IC fabrication cycle; the importance and organisation of testing within technological process; test equipment used in industry to verify the correct operation of digital integrated circuits (generic architecture and operation of a test system, main modules of a tester and their operation, computer-aided test engineering tools, test system programming, device interface board design), digital test methodologies (DC parametric, AC, functional and IDDQ tests), semiconductor memory testing, introduction to analog and mixed-signal testing, design-for-testability and built-in self-test and their implication on test technology, test data collection and analysis.
Upon successful completion of the unit, the students are expected:
Laboratory reports: 10%
Laboratory test and mid-semester test: 20%
Examination (3 hour): 70%
3 hours lectures, 1 hour tutorials, 2 hours laboratories and 6 hours private study per week
ECE2062 or ECE3062
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Damien Browne |
This unit builds upon earlier studies in computer organisation and engineering. The unit will explore the structures, techniques and trade-offs implicit in the study of high performance computer architectures. The focus will be on exploring all aspects of exploitable concurrency in computer systems and the applications they support. This will include considerations of data path design, memory structures, resource allocation and scheduling, threading, branch prediction; alternative application specific computer architectures; implementation using re-configurable devices and high-level languages.
Examination: (3 hours) 70%
Continuous assessment: 30%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory and practice classes and 7 hours of private study per week
ECE3073 or ECE3703 or TRC3300
ECE4705, ECE5074
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | L Kleeman |
The unit enables students to understand, analyse, specify, design and test embedded systems in terms of the hardware architecture, distributed systems and the software development that deploys a real time kernel and the migration of software to hardware. The design, analysis and implementation of a real time kernel will be studied that includes scheduling policies, process creation and management, inter-process communication, efficient handling of I/O and distributed processor implementation issues. Students will be involved in a design project that involves the hardware and real time system design of an embedded system with hard deadlines using an FPGA development system.
To understand the development process for embedded systems from specification, simulation, implementation and testing. To gain an appreciation of the effectiveness and properties of a real time kernel in the software development process. To gain a knowledge and understanding of the properties of different scheduling policies and their implementation in a real time system. To understand the process of migration of a software definition to a hardware implementation as a means to accelerate an embedded system design. To understand the complexities and design approaches necessary in a distributed real time embedded system.
Continuous assessment: 40%
Examination: (3 hours) 60%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 3 hours laboratory and practice classes and 7 hours of private study per week
ECE3073 or TRC3300
ECE4705, ECE5075
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | T Drummond (Clayton) |
This unit aims to develop an understanding of methods for extracting useful information (eg 3-D structure; object size, motion, shape, location and identity, etc) from images. It will allow students to understand how to construct Computer vision systems for robotics, surveillance, medical imaging, and related application areas.
To understand camera models
To learn to apply geometry and photometry to image analysis.
To understand the basic principles of laser scanners.
To understand the elements of the human visual system and perception.
To learn to implement low level vision processes (linear filtering, edge detection, texture, multi view geometry, stereopsis, structure from motion, optic flow).
To learn to implement midlevel vision (segmentation and clustering, model fitting, tracking).
To learn to implement high-level vision (model-based vision, surfaces and outlines, graphs, range data, templates and classifiers, learning methods).
To complete programming exercises (C, MatLab for example).
Continuous assessment: 30%
Examination: (3 hours) 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 4 hours laboratory and practice classes and 6 hours of private study per week
ENG2092, ECE2071 or TRC2400 and ECE2011 or TRC3500 or FIT1002 for students studying double degrees with science
ECE4711, ECE4712, ECE5076, ECE5711, ECE5712
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | M Premaratne |
This unit will look at the applications of modern object oriented approaches to engineering computation. Numerical libraries based upon modern meta-programming techniques are introduced to show ways of constructing performance-critical software to solve engineering problems that are formulated as partial differential equations. Due to their widespread usage, special emphasis will be placed on constructing numerical solutions based on finite difference and finite element methods. Specifically, this unit will extensively use advanced C++ language features and numerical libraries such as Blitz++.
Familiarity with the use of software development tools
Knowledge of the features of C++ including OOP
Understanding of efficiency considerations in C++ including temporary generation, in-lining, virtual functions usage, floating point, bit-set calculations, reference, pointers and exception handling.
Competence in meta-programming.
Experience of Blitz++ as an example system to demonstrate scientific programming.
Use of comsol multiphysics as an example scripting platform for handling finite element programs.
Competence in finite difference and finite element methods.
The ability to design object oriented, maintainable numerical software for solving engineering problems.
An appreciation of computational methodologies and high performance computing techniques in electrical engineering.
Confidence in using state of the art numerical packages for solving engineering problems.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
(ENG2092 or MAT2901) and (ECE2011 or ECE3102) and (ECE2071 or ECE2702 or CSE1301 or TRC2400 or FIT1002)
ECE4709, ECE5077, ECE5709
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Wai Ho Li (Clayton); Dr Kuppan Chetty Ramanathan (Sunway) |
Intelligent Robotics concerns the melding of artificial perception, strategic reasoning and robotic action in potentially unstructured and time-varying environments to fulfill useful physical tasks, whether in industry or for security, healthcare, search and rescue or civil defense etc.This unit covers topics underpinning the above requirements, including sensors, sensor fusion, machine perception, environmental mapping/monitoring, path planning, localisation, mechanisms, artificial intelligence methodologies and application domains.
Students will gain an understanding of the physical structure, sensing/actuation and programming required to develop an intelligent robot. They will be able to specify the robotic mechanism, its sensors and actuators and then be capable of programming and integrating these components into a functioning robot system. By considering case studies they will be able to critically appraise robot systems developed by others.
Laboratory and assignment work: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 4 hours laboratory/practice classes and 6 hours private study per week
ECE2071 or TRC2400 or FIT1002 for students studying double degrees with science
ECE4711, ECE5078, ECE5711
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Jingxin Zhang |
This unit shows how engineering principles are used in the design and construction of biomedical instrumentation. This includes application of electrochemistry to biological membranes, application of cable theory to nerve axons, application of electronic design principles to the recording of biological electrical signals, application of quantitative optics to spectrometry and fluoroscopy. In addition, the operating principles of a wide range of medical and laboratory instruments will be explored, ranging from pH meters to gene sequencers, pressure transducers to anaesthetic machines.
To understand the generation of electrical signals in the body.
To apply engineering principles to recording and analysis of electrical signals in the body.
To apply basic chemistry to sensors
To understand the principles and operation of optical instrumentation.
To become familiar with a range of hospital equipment.
Laboratory and assignment work: 30%
Examination (3 hours): 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lecture, 3 hours laboratory/practice classes and 6 hours private study per week
ECE3801, ECE5081, ECE5801
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | tba |
This unit will apply the basic mechanics included in the engineering course to the physiological background of the biomedical engineers. This will include characterisation of the principle body tissues as engineering materials, such as bone, cartilage and ligaments as structural materials, joints as mechanisms, muscles as motors and brakes, the heart as a pump, and the nervous system as sensor network and controller. Gait, the prime example of the interaction of all these elements, will be studied in its own right, and as a diagnostic tool in palsied, diseased and prosthetic patients. The technologies of the gait lab and of ambulatory monitoring will also be covered.
To understand the building blocks of human musculo-skeletal biomechanics.
To study human motor control with a particular focus on lower limb control and locomotion.
To compare gait of normal and disabled humans
To understand the principles and operation of gait measurement in the laboratory and in the field.
To become familiar with the biomechanics of prosthetics.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE4804, ECE5084, ECE5804
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | L Zhang |
This unit will introduce a range of medical imaging technologies currently used in health care, covering aspects of technical design, medical image analysis, systems integration and emerging technologies. It introduces students to the wide range of imaging modalities with an emphasis on the design and technical development of each modality. Future needs on medical imaging in health care and emerging medical imaging technologies will be covered. Image analysis and visualisation in the context of image guided therapy, image guided surgery, and virtual reality based simulation will also be covered.
To provide an introduction to medical imaging equipment and systems. To study medical imaging systems, including computational methods, analysis, design and performance requirements. To be able to evaluate future medical imaging systems. To become familiar with medical imaging equipment safety and regulation.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE2011 (or ECE3102) and ECE2021 (or ECE3202 or PHS2022)
ECE4806, ECE5086, ECE5806
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | A Lowery |
This unit provides an introduction to the process of design and innovation with particular reference to medical technology. The design, development and manufacture of medical technology are covered, taking into consideration safety and effectiveness issues, regulatory and legal issues, the patient equipment interface and the hospital or medical environment in which the equipment is to be used. This will be achieved through case studies and development of a business plan.
To introduce the process of medical technology innovation in the context of Australian case studies.
To develop a conceptual design for a new medical technology considering a wide range of parameters including technical feasibility, patient/doctor acceptance, manufacturability, financial viability, and safety.
To gain experience in developing and presenting a plan for new technology innovation.
Continuous assessment: 50%
Examination: (3 hours) 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory and practice classes and 6 hours of private study per week
ECE4807, ECE5087, ECE5807
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Jonathan Li (Clayton); Dr Vineetha Kalavally (Sunway) |
Together with ECE4095 Project B, this unit is a challenging opportunity to pursue independently an individual project and is likely to require extended effort. The two units together normally include a preparatory literature survey and developmental work such as design, construction and programming. Students choose a project that interests them, and are assigned to a team of two supervising staff members.
To give students the experience of tackling a real problem and presenting their achievement.
To search for prior knowledge.
To learn to apply safety considerations to all actions.
To present results in writing and in person.
Panel assessment of the achievement of the student in the project, as evidenced by a presentation, a poster and a written report (100%)
12 hours per week working on the project
ECE3091 or completion of 132 credit points
ECE4911, ECE5094
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Jonathan Li (Clayton); Dr Vineetha Kalavally (Sunway) |
Together with ECE4094 Project A this unit is a challenging opportunity to pursue independently an individual project and is likely to require extended effort. The two units together normally include a preparatory literature survey and developmental work such as design, construction and programming. Students choose a project that interests them, and are assigned to a team of two supervising staff members.
To give students the experience of tackling a real problem and presenting their achievement.
To search for prior knowledge.
To learn to apply safety considerations to all actions.
To present results in writing and in person.
Panel assessment of the achievement of the student in the project, as evidenced by a presentation, a poster and a written report: 100%
12 hours per week working on the project
ECE4094 or ECE4911
ECE4912
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | R Rimington (Clayton); S G Ponnambalam (Sunway) |
This unit will cover topics relevant to engineers working in a business environment, particularly in management, focusing on recent case studies. Areas covered include management of individuals, teams and organisations, management philosophy and practical techniques. Financial management will be discussed, including company objectives, accounting fundamentals, and financial planning and control. Marketing will follow, including business planning, quality and quality control. Relevant legal issues will be covered, including intellectual property, contract and negligence. This will be drawn together in discussing the role of the professional engineer, ethical behaviour and decision making.
To understand the role of an engineer as a manager - skills, styles, technique.
To learn about and understand organisations - types, structures, operations.
To understand accounting fundamentals.
To understanding the basics of marketing principles.
To experience and learn techniques for strategic business planning.
To understand some of the legal issues relevant to engineers.
To identify and inculcate the elements of professional behaviour, in particular the Engineering Code of Ethics.
To identify and learn key skills required to effectively perform the role of a manager.
To learn to operate effectively in a dynamic business environment.
To learn to use financial information to enhance business decision making.
To develop and utilise effective strategic plans using advanced planning techniques.
To come to understand important legal aspects of contract, negligence and intellectual property with relevance to the engineering profession and in the context of the engineering code of ethics.
To gain an appreciation of the value of planning.
To identify with ethical business behaviour.
Continuous assessment: 30%
Examination: (3 hours) 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours laboratory and practice classes and 7 hours of private study per week
ECE4908, TEC3193 and TRC4002
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Overseas First semester 2012 (Off-campus Day) Overseas Second semester 2012 (Off-campus Day) |
This unit is used by the faculty to enrol students undertaking outbound exchange studies at a host institution. Students will not be able to enrol in this unit via WES. The faculty will manage the enrolment of students undertaking an outbound exchange program to ensure fees and credit are processed accurately.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | G P Codner |
Introduce concepts of sustainable development, the demands of population and economic growth, industrialisation and urbanisation, energy demand and usage, and human environmental disturbance. Two environmental case studies will be covered in detail, designed to illustrate by way of example many of the considerations that underpin many environmental issues/conflicts/ethics. These are climate change and sustainable cities. The multi-disciplinary nature of environmental problems is emphasized together with the need to understand and communicate with other professional and community groups.
Objectives:
Examination: 50%
Group project: 35%
Tutorial involvement 5%
Two individual assignments:10%
3 hours lectures, 2 hours tutorial classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor George Simon/Ms Lisa Sweet |
This unit will give the students an appreciation of materials, their place in the environment and ways of dealing with their presence in the waste stream. The students will gain a basic understanding of the structure and properties of the main classes of materials: metals, polymers and ceramics. Students will learn about the ways in which these different materials can be disposed of, ranging from incineration, recycling and degradation, and the technologies involved in these processes. The advantages of these methods, as opposed simply to landfill, will be discussed. Methods of sorting of different materials from the waste stream into their various components will also be covered.
On successful completion of this course students will:
Examination (3 hours): 50%
Two written assignments: 20%
Two tests (30 mins): 15%
Laboratory work: 15%
3 hours of lectures/problem solving classes per week, 3 x 3 hrs laboratory classes per semester and 7 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Sankar Bhattarcharya |
Energy resources, chain, and energy conversion processes; non-renewable (fossil, nuclear) and renewable (photovoltaic, wind, hydro-, biomass) sources of energy; environmental impact of electricity generation; energy storage technologies; direct and indirect energy conversion; overview of the world and Australian energy production and consumption; the future energy scenarios.
To understand: the principles of energy conversion technologies, the environmental problems associated with these technologies, alternative energy technologies the environmental benefits of these technologies, engineering and economical aspects of alternative energies.
Examination: (3 hours) 40%
Continuous assessment: 60%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures and 3 hours laboratory and practice classes, and 6 hours of private study per week
Must have passed 72 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Eugene Quah/Victoria Lamb/Dr Gavin Mudd |
This unit considers international agreements in the air environment and links them to sustainability. Sources of air pollution are considered, together with the effects on humans and the environment, current levels of air pollution as well as air quality standards. This leads to consideration of atmospheric stability conditions and an explanation of how air pollution moves in the atmosphere and related plume behaviour which is important for an understanding of point and a real dispersion modelling of pollutants. Air pollution control strategies, factors important in control equipment selection and design of overall control schemes are covered relating to both particulates and gases.
On completion of this unit it is anticipated that students will be able to:
Understand what international protocols exist, their content, and how they relate to sustainability issues
Identify major sources of air pollution and be able to explain their impact on human health, vegetation, structures, aesthetics etc
Understand and explain the various atmospheric stability conditions and how they relate to different plume behaviour and dispersion of particulate and gaseous discharges
Understand processes and technologies available to reduce or eliminate the adverse consequences of gaseous discharges.
Calculate the atmospheric dispersion of discharges from both point and areal sources of air pollution
Describe the factors important in control equipment selection.
Design overall control schemes demonstrating an understanding of the complete process
Design of Particulate control systems including cyclone separators, electrostatic precipitators, filters and wet scrubbers.
Design of gaseous control. Systems including Incineration and gas/solid adsorption for VOC control and gas scrubbers for removal of non-condensable components.
Assignments and field trip reports: 40%
Examination (3 hours): 60%
3 hours lectures, 2 hours practice and computer classes and 7 hours of private study per week
ENE3604
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | G M Mudd/A Hoadley (Clayton); N Ramanan (Sunway) |
This unit aims to develop an understanding of the role and basis for environmental impact assessment (EIA) and environmental management systems (EMS). The unit focuses on the processes involved in producing an EIA or EMS, with a particular emphasis on synthesizing technical, regulatory and community issues. The unit aims to encourage students to integrate their existing knowledge in environmental engineering, applying it to real projects. Through lectures, practice classes, individual assignments and group project work, students should develop skills and knowledge in preparing major EIA and EMS reports, their presentation and communication as well as their engineering context.
The role of engineering in sustainable development; role of environmental impact assessment and environmental management systems in society; knowledge of relevant environmental legislation, policies, industry codes of practice and Australian or international standards; government, industry and community perspectives on engineering projects; key concepts of life cycle analysis, environmental auditing, waste prevention, cleaner production, community consultation, economic analysis, in engineering projects; types of environmental impact assessment and environmental management system methodologies; major report writing, team work and oral presentation skills; research skills; skills in synthesising environmental information.
Assignments: 65%
Examination (3 hours): 35%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week
Must have passed 72 credit points
CIV3201, ENE3602, ENE3603
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | G P Codner |
Students will work in groups (with CIV4212 students) to carry out a design for a specified development which will include policy, economic, environmental, social and technical aspects. The design will vary from year to year. The design problem will be that used in CIV4212, however, greater attention will need to be paid to sustainability issues than would be expected for the civil engineering students.
Written and oral design submission and interview of individual students: 100%
39 contact hours
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | G P Codner, G Mudd |
Each student will be required to select a project from a number of topics offered, or develop their own topic if a suitable supervisor is available. The project outcomes are to be summarised in a major report and in a brief oral presentation.
Practical work (written project proposal, final report on practical work, seminar presentation): 100%
12 hours per week
Completion of 120 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | tba |
This unit will allow a student to complete a major research project in the field of environmental engineering (continued from ENE4603).
Practical work (written proposal, preliminary and final project reports, oral presentation): 100%
12 hours per week
ENE4603, must have passed 120 points and have a weighted average of 65% or above. Enrolment is by approval of the Course Director only.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | G Mudd |
This unit aims to synthesize the various components of the Environmental Engineering degree, enabling development of a comprehensive approach to identifying, assessing and planning management approaches to the array of environmental risks associated with engineering. A critical aspect of this unit will be class discussions, where participation in broad ranging debate will be actively encouraged for all students. Communication skills are critical for environmental issues in engineering, as there are commonly differences of opinion with regards to environmental risks as well as their respective solutions. This unit seeks to unify environmental risk assessment in an engineering context.
Re-enforce the role of engineering in sustainable development; understanding of the role of environmental risk assessment in society; knowledge of relevant environmental legislation, policies, industry codes of practice and Australian or international standards; understanding of government, industry and community perspectives on the perceived and actual environmental risks of engineering projects; understanding of key concepts of fault and decision tree analyses; understanding of risk communication; knowledge of relevant occupational health and safety risks; knowledge of environmental toxicology and basis for incorporating into risk assessments; improved critical thinking and analysis skills; application of knowledge of formal risk assessment systems to engineering projects; ability to develop a HAZOP study for a particular project or process; improved major report writing skills; improved oral presentation and verbal communication skills; research skills to find relevant engineering, environmental and other information; improved skills in synthesizing broad-ranging environmental information
Class participation: 10%
Projects: 50%
Final Exam (3 hours): 40%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week
Must have passed 120 points
ENE4601
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Prof Bradley Ladewig (Clayton); Dr Estee Yong Siek Ting (Sunway) |
A systematic approach to solving a wide variety of engineering problems involving the use of mass and energy balances. Simple models for the sizing of equipment involved in chemical reaction, heat transfer and fluid flow operations. Application of these principles to selected engineering processes such as power generation, beer brewing and refrigeration.
The student is expected to: Knowledge and Understanding
Inidividual test and group project works: 50%
Examination (2 hours): 50%
2 hours lectures, 4 hours problem solving sessions and 6 hours of private study per week
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1101
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Lizi Sironic (Clayton); Ms Lim Jen Nee Jones (Sunway) |
This unit aims to develop an understanding of the context and terminology related to engineering structures. It will allow students to translate real world forces into abstract form for engineering modelling. The unit aims to develop an understanding of the fundamentals of engineering statics and their application to trusses and beams through design. Knowledge of various construction materials is developed to allow material choice for truss and beam design. Design of beams continues the theme of engineering statics through introduction to shear forces, bending moments and stress, and deflection.
At the completion of this unit students will have the following knowledge and understanding:
Assessment Projects: 30%
Individual tests 30%
Closed book exam (3 hours): 40%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice classes and seven hours of private study per week.
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1201
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Mr Jonathan Li (Clayton); Dr Vineetha Kalavally (Sunway) |
Introduction to electrostatics: electric charge, forces and fields, electric potential, emf, application in capacitors, energy and information storage. dielectrics, polarisation, electrical breakdown. Magnetic fields, current and current loops in magnetic field. force on charges, engineering applications solenoid. Electromagnetic induction. inductance. Engineering applications: transformer. Electric Motor. Energy stored in magnetic field. Ohm's Law, Kirchhoffs Laws. Mesh and vodal analysis. Circuit theorems, superposition. DC and AC networks, AC power systems. Ideal op amp circuits, applications in instrumentation. Logic, Boolean algebra. Digital arithmetic, combinatorial logic circuit.
Upon successful completion of this unit, a student will be able to:
Laboratory/Tests 30%
Examination 70% (3 hours).
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours of lectures, 3 hours of laboratory/practice classes and 6 hours of private study per week
VCE Physics 3/4 or ENG1080 or PHS1080.
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1301, ENG1803
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Greg Sheard (Clayton); Dr Lau Ee Von (Sunway) |
Dimension, units and error estimates. Kinematics of particles and rigid bodies. Free body diagrams The concept of work, energy and power Forces and torques applied to rigid bodies undergoing translation or rotation The relevance of these to some common engineering mechanisms. Free and damped vibration and engineering applications. Kinematics of gears and geared systems including compound epicyclic gears. Friction, and the kinetics of belts and belt drives.
The student is expected to:
Knowledge and Understanding:
Mid-semester test: 10%
Laboratory/problem solving: 10%
Design, build and test project: 10%
Final examination (3 hours): 70%
3 hours lectures, 2 hours of problem solving/laboratory and build and test design projects and 7 hours private study per week
VCE Physics 3/4 or ENG1080 recommended.
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1401
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor J S Forsythe/Dr Don Rodrigo (Clayton); Dr Pooria Pasbakhsh (Sunway) |
Key concepts in the design, selection and application of materials. Attributes such as stiffness (modulus), strength, toughness, chemical stability, electrical, magnetic, and thermal properties will be explained in terms of atomic bonding, crystal defects, polycrystalline microstructure and material flaws. Case studies will include a broad range of materials such as carbon nano tubes, microchips, reinforced concrete, biomaterials, suspension bridge, and aerospace components, all used in a diverse range of engineering applications.
On successful completion of this unit students will:
Examination (2 hours): 50%
Laboratory work: 20%
Assignments: 10%
Tests: 20%
Three 1-hour lecture/practice classes, one 2-hour laboratory class and 7 hours private study per week
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1501, MSC1010
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Yi Hong (Clayton); Mr Khoo Boon How (Sunway) |
General rules for software development and design. Errors. Data types, variables, expressions, control statements M-files. Numerical techniques: Gauss elimination, solution of non-linear equations, optimisation, curve fitting, numerical calculus, ordinary differential equations.
Written examination (3 hours): 70%
Continuous assessment: 30%
2 hrs lectures, 3 hrs laboratory and 7 hrs private study per week
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1602
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Eugene Quah (Clayton); Mr Ir Dennis Ong (Sunway) |
Introduction to engineering, the role of engineers and the engineering decision-making process. The Unit covers the economic, environmental, social and ethical aspects of engineering. Particular aspects relate to the systems approach to engineering problems; sustainable development and the environment; lifecycle concepts, safety, management, quality, economic analysis; engineering ethics, report writing, oral presentations, drawing and teamwork.
It is anticipated that students who successfully complete ENG1061 are expected to:
Group Projects: 40%
Individual assignments/tests: 13%
Presentations: 12%
Closed book exam (2 hours): 35%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice classes and seven hours of private study per week
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1601
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Dr David Turner |
This unit introduces the concepts of conservation of matter and energy, atomic theory and the principles of chemical bonding. Chemical reaction types, and the use of equations to describe these reactions, and their quantitative behaviour in both liquid and gaseous phases are introduced. The theories of acid/base and redox behaviour, and chemical equilibria are introduced. Key aspects of organic chemistry (organic compounds, nomenclature, functional groups and common reactions) will covered. The practical course introduces common techniques used in the chemical laboratory, and includes exercises that illustrate the theory component as well as laboratory OHSE issues.
On completion of this unit, students should be able to:
Examination (3 hours): 60%
Laboratory exercises: 20% Hurdle requirement: Laboratory course must be competed at PASS level)
Web based continuous assessment: 20%
Three 1-hour lectures, three hours of laboratory/practice class activity and six hours of individual study per week
VCE Chemistry Units 3/4 (or equivalent), CHM1031, CHM1731, ENG1701
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Kei Saito |
Atomic theory of matter; chemical periodicity; ionic, covalent and metallic bonding; role of intermolecular forces in the behaviour of liquids and solids in relation the structure and properties of materials like liquid crystals, amorphous solids and polymers; Equilibria involving precipitation, acid-base, redox and electrochemical reactions and their role in acid rain and corrosion; Coordination chemistry and the nature and properties of the transition metals and their complexes. Practical exercises are illustrative of the theory component and provide experience in laboratory techniques and laboratory OHSE practices.
On completion of this unit, students should be able to:
Examination (3 hours): 70%
Laboratory exercises: 20% Hurdle requirement: Laboratory course must be competed at PASS level)
Web based continuous assessment: 10%
Three 1-hour lectures/practice classes, two hours of laboratory activity and six hours of individual study per week
VCE Chemistry Units 3/4 (or equivalent) or ENG1070
CHM1022, ENG1702
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Associate Professor Michael Morgan (Clayton); Associate Professor Lan Boon Leong (Sunway) |
This unit relates key principles of physics to engineering and technology, and shows how physics, including quantum and nano-science, creates useful new technologies. Energy, momentum and angular momentum: planetary orbits, rocket propulsion, precession, fly wheels. Oscillations and waves: resonance, transmission of energy; Doppler effect and speed measurement, polarization and stress models, diffraction and nano-structures, thin film interference and antireflecting film. Quantum Physics: Uncertainty Principle, wave functions, atomic force microscope; lasers, stimulated emission. The practical component develops measurement, analysis, and communication skills.
On successful completion of this unit students will be able to:
Test: 8%
Quizzes/Assignments:10%
Practical work: 22%
Exam (3 hours): 60%
Associate Professor Michael Morgan
3 hours lectures, 3 hours practical work and 6 hours private study per week.
Year 12 Physics or PHS1080 or ENG1801
ENG1802, PHS1011
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Associate Professor Michael Page |
Functions and coordinate geometry: types of functions, composite functions, inverse functions, modelling of periodic phenomena with trigonometric functions. Complex numbers. Differentiation and integration: concepts and techniques, applications to related rate of change and optimization problems, areas, volume, and centre of mass. Vectors in two- and three-dimensional space, application to motion and kinematics.
On completing this unit students will be able to demonstrate understanding of the characteristics of different types of functions and their graphs, composition of functions, and inverse functions; use trigonometric functions to model periodic behaviour; represent complex numbers in cartesian, polar and exponential forms, and on the complex plane; operate with complex numbers, including finding powers and complex roots of polynomials; demonstrate understanding of the concepts of limit, continuity, differentiable and integrable functions; use differentiation rules to find derivatives of implicit and explicit functions; apply differentiation techniques to related rates of change problems and optimization problems; use simple integration techniques to find definite and indefinite integrals, including integration by substitution and integration of rational functions; apply integration techniques to calculate areas, average values, volumes, centres of mass, moment, and work; perform operations with two- and three-dimensional vectors, interpret them geometrically, find vector resolutes, and apply them to motion of a particle; solve kinematics problems, and set up and solve problems involving Newton's laws of motion.
Assignments and test: 30%
Examination (3 hours): 70%.
Associate Professor Michael Page
3 hours lectures, one 2-hour practice class and 7 hours of private study per week
VCE Mathematical Methods 3/4
ENG1901, MTH1020, MAT1055
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Sem 1: Mr John McCloughan (Clayton); Associate Professor Lan Boon Leong (Sunway) |
Vector algebra and geometry: equations of lines and planes. Linear algebra: matrix operations, systems of linear equations, eigenvalues and eigenvectors. Calculus: logarithmic differentiation, improper integrals, integration by parts. Sequences and series: convergence, power series, Taylor polynomials. Ordinary differential equations: first order, second order with constant coefficients, boundary value problems, systems of ODEs. Multivariable calculus: partial derivatives, directional derivatives, chain rule, maxima and minima.
On completing this unit, students will be able to calculate cross products of vectors, and use vectors to represent lines and planes; perform matrix algebra; solve systems of linear equations and find eigenvalues and eigenvectors in simple cases; use hyperbolic functions; perform logarithmic differentiation; establish the convergence of improper integrals, and use further techniques of integration, including integration by parts; establish the convergence of numeric and power series, construct Taylor series and use Taylor polynomials to approximate functions; solve first order ordinary differential equations, including the techniques of exact integration, separable variables and integrating factor; and systems of ordinary differential equations; solve 2nd order linear differential equations with constant coefficients; set up differential equations with initial or boundary conditions to model simple engineering problems; calculate partial derivatives, use the grad vector to find directional derivatives, use chain rule, calculate small error using the total differential, and find maximum and minimum values of two-variable functions.
Assignments and test: 30%
Examination (3 hours): 70%
Sem 1: Mr John McCloughanSem 2: Mr Alan Couchman
3 hours lectures, 2 hours practice classes and 7 hours of private study per week
VCE Specialist Mathematics (or ENG1090 or equivalent)
ENG1902, MTH1030, MAT1085
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | J Carberry |
This unit provides an introduction to the fundamental concepts of biological engineering and its related disciplines. The importance of scale and complexity in biological structures, especially at the meso-, micro- and nano- scale is discussed. How biotechnology has evolved to solve biological problems is investigated. Case studies highlighting applications of biological engineering will be studied. The connection with other first year units will be explained by how biological processes are broken down into solvable problems using methods in mathematics, physics, chemistry and IT
After completion of this unit, the student should be able to:
Assignments: 30%
Problem solving tasks: 20%
Examination: 50%
5 contact hours and 7 hours of private study per week
VCE Mathematical methods 3/4 (or equivalent) recommended.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Zhigang Xiao |
Structural engineering analysis and design topics include trusses, beams, columns, calculation of reactions and deflections. Design of simple structures.
As a project based unit, this unit should develop the student's knowledge and understanding. Understanding of the way in which civil engineers investigate and solve problems, including the need to understand the environment in which the problem is embedded. Knowledge of basic design. Knowledge of basic structural form and how structures carry load; static equilibrium; limit state concepts; truss analysis and stability; shear force and bending moment diagrams; buckling and serviceability; equilibrium and compatibility. Skills. Ability to acquire knowledge in the pursuit of solving engineering problems, ability to make critical observations of engineering problems and to successfully apply the acquired knowledge. Specific skills related to the analysis and design of simple structural elements. Communication skills, in both oral and written forms. Computer skills and knowledge of one structural analysis software package. Attitudes. Appreciation of the relevance of engineering knowledge to engineering practice. Confidence in the ability to tackle new engineering problems, particularly in the structural design environment, through the development of the above skills, knowledge and understanding.
Examination (3 hours): 40%
Coursework: 60%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
24 lectures, 24 hours of practice classes and 3 hours site visits
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1201
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Susanga Costa |
Introduction to engineering; the systems approach to engineering problems and their solutions; sustainable development, ecology and the environment; lifecycle concepts, safety, management, quality and economic analysis; engineering ethics. Group work, written reports and oral presentations.
Knowledge/understanding
To provide students with a vision and understanding of the scope of engineering, including emphasis on its breadth and interactions and linkages with other disciplines
To introduce students to the role of the engineer in society, including environmental issues.
To introduce the concepts of engineering ethics.
Skills
To improve students' communications skills, building an appreciation of the need for and value of both verbal and written communications in engineering. Included in this are the concepts of quality and standards in all communications.
Attitudes
To increase students' motivation to study engineering and work towards an engineering career.
To develop an appreciation of the teamwork nature of engineering.
Class work and assignments: 70%
Examination: 30%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
24 lecture hours and 24 practice classes
VCE Mathematical methods 3/4 (or equivalent) recommended.
ENG1601
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
This is a dummy unit used to enrol students who have partially completed level one of the Bachelor of Engineering and have yet to be allocated to an engineering branch.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | Sem 1: Dr Alina Donea (Clayton); Dr Yew Mun Hung (Sunway) |
Multivariable calculus: double and triple integrals, parametric representation of lines and curves in three dimensional space, use of Cartesian, cylindrical and spherical coordinates, surface and volume integrals, the operations of the gradient, divergence and curl. Ordinary differential equations: solve systems of linear differential equations and the 2nd order Sturm-Liouville type problems. Partial differential equations: the technique of separation of variables and the application of this technique to the wave equation, the heat equation and Laplaces equation.
On completing this unit, students will be able to represent curves parametrically solve line integrals on these curves; solve double and triple integrals in Cartesian, cylindrical and spherical coordinates; represent surfaces parametrically and solve flux integrals across these surfaces; perform the operations of the gradient, divergence and curl, use these operations in the solution of surface and volume integrals through the Divergence theorem and Stokes theorem; solve systems of simple ordinary differential equations; establish the eigenvalues of these systems; identify and solve 2nd order linear Sturm Liouville differential equations; represent a periodic function with a Fourier series and identify even and odd series expansions; solve elementary partial differential equations through the method of separation of variables; apply this technique to the wave equation, the heat equation and Laplaces equation; classify 2nd order linear partial differential equations as elliptic, parabolic or hyperbolic.
Assignments and test: 30%
Examination (3 hours): 70%
Sem 1: Dr Alina DoneaSem 2: Dr Rosemary Mardling
3 hours of lectures, 2 hours practice classes and 7 hours of private study per week
MAT2731, MAT2901, MAT2902, MAT2911, MAT2912, MAT2921, MAT2922, MTH2010, MTH2032
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Greg Markowsky (Clayton); Mr Nader Kamrani (Sunway) |
Complex analysis: introduction to functions of complex variables and the manipulation, differentiation and integration of complex functions, line integrals in the complex plane. Integral transforms: introduction of Laplace transforms and their application to ordinary differential equations. Statistics: probability density function and distribution function of random variables, joint density function of multivariate random functions, expectation and confidence limits of random variables.
On completing this unit, students will be able to manipulate elementary functions of complex variables (eg multiplication, division, root finding); manipulate exponential and trigonometric functions of complex variables; calculate derivatives and integrals of elementary functions of complex variables; calculate line integrals on the complex plane, apply Cauchy's integral theorem; employ simple Laplace transforms to solve ordinary differential equations; appreciate the representation of random variables through the distribution and density functions; calculate the expected value of a random variable; find the joint distribution of a multivariate random function; develop inference and confidence limits of random variables; calculate linear regression and correlations.
Assignments and test: 30%
Examination (3 hours): 70%
3 hours lectures, 2 hours practice classes and 7 hours of private study per week
ENG1091 or MTH1030 and MTH1035 for students studying double degrees with science
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Zhigang Xiao |
This unit covers the concepts of load and resistance, load factors and capacity factors, the design criterion for strength of structures, representation of loads on structures, the elastic response to applied loads of two dimensional framed structures, continuous beams and trusses, the concept of load path and equilibrium applied to framed structures, distinctions between braced and unbraced frames and their identification, flexural strength of beam cross-sections based upon idealised elastic-plastic material behaviour, up to ultimate strength, applied to steel beams of compact cross-section, flexural strength of beams based upon section capacity.
Knowledge
The concepts of load and resistance, load factors and capacity factors, and the design criterion for strength of structures representation of loads on structures. The elastic response to applied loads of two dimensional framed structures, continuous beams and trusses.
The concept of load path and equilibrium applied to framed structures. Distinctions between braced and unbraced frames and their identification. Flexural strength of beams based upon section capacity, excluding lateral buckling. Flexural buckling and strength of pin ended columns, with application to symmetric compact section steel columns. Interaction of axial force and bending moment in the ultimate strength of steel beam columns.
Skills
Analyse statically determinate frames and pin-jointed trusses by method of sections (and joint equilibrium for trusses). Analyse braced and unbraced frames using software Spacegass or Microstran. Determine moment-curvature relationship up to collapse of steel beams of compact cross-section. Determine capacity envelope for interaction of axial force with bending moment in compact steel beams, with extensions to asymmetric cross-sections. Visualise bending moment and shear force diagrams, and load paths through structures. Set up structural layouts for rectangular framed buildings. Use simplified structural modelling for initial sizing of members. Determine the envelope of maximum load effects on structures.
Attitudes
Through an engineering project that is within the students' life experiences (ie design of a multi-storey carpark), students should see the relevance of the study of this unit to their future careers. They will develop confidence in the use of standard analysis methods and computer software. Students will further develop their group work and communication skills (particularly in report writing).
Examination (3 hours): 50%
Practical/project work: 50%
48 contact hours
CIV2222
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Zhigang Xiao |
Sustainable engineering design, concepts of strength and serviceability limit states, load and strength factors, basic framing concepts in buildings, estimation of loads, basic analysis of slabs, computer analysis of frames, specifications for durability and strength analysis of RC sections, design of slabs in flexure, design of beams in flexure, shear design of beams, bond, length of development and detailing of reinforcement, analysis of interaction of axial compression and bending, strength design of columns, basic concepts in concrete technology, preparation of concrete specifications; prescriptive and performance specifications, preparation of design drawings.
The student is expected to acquire a basic knowledge and understanding of the methods and processes of structural engineering and the design of concrete structures.
Examination (3 hours): 50%
Practical/project work: 50%
24 lectures and 26 practice classes
CIV2223
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Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Mohan Yellishetty |
Holistic view of water resources, systems concepts, Fluid properties, Fluid statics, Continuity, Energy concepts - pressure, elevation, velocity, Momentum concepts - jets, forces due to sudden velocity changes, Pipe flow and friction losses - friction equations, TEL, HGL, Bernoulli's equation, D-W equation, minor losses, Manning's equation, Sources of supply (regulated, unregulated, reliability), Data: types, sources, quality, Benefits/costs (at least at conceptual level), Pump characteristics, Pumped storage, balancing reservoir, Water quality, water treatment, water sensitive urban design.
The student is expected to acquire a basic knowledge and understanding of the methods and processes of hydraulic engineering.
Closed Book Examination (3 hours): 50%
Practical/Project/Assignment work (continuous assessment): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Jianfeng Xue |
All aspects of geoengineering are considered at an elementary level, as well as basic engineering geology, formation and weathering processes, sedimentary, igneous and metamorphic rocks, the geotechnical spectrum - soil, rock, weathering, deposition cycle, basic soil and rock properties, void ratio, water content etc, and the two phase model. All materials are assumed to be granular and frictional. The unit includes the analysis and design of slopes, shallow and deep foundations, retaining walls, and pavements. Effective stresses only are used. Visualisation is developed through the mapping and modelling exercise. A clear emphasis on sustainable design will be made.
The student is expected to acquire a basic knowledge and understanding of the methods and processes of geoengineering.
Examination (3 hours) 50%
Practical/project work: 50%.
24 lectures, 24 tutorial/workshop classes per semester
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Mohan Yellishetty |
This unit introduces students to fundamental hydrological and hydraulic theories in the practice of waterway engineering. The unit places particular emphasis on the fundamental basis for the estimation of catchment flow and open channel flow hydraulics. The unit will first introduce students to the hydrologic background for estimating floods in a number of situations. Instruction in open channel hydraulics will then permit the determination of the behaviour of the flood within a river channel and associated flood plains.
Understand the hydrologic processes involved in flood estimation; principles involved in open channel flow; hydraulic principles and methods involved in estimating flood levels; and the fundamentals of risk analysis in relation to catchment flows and determining water levels in channels. Acquire skills to estimate catchment flows and determine the behaviour of flow in open channels, rivers and associated flood plains.
Practical/Project/Assignment work (continuous assessment): 50%
Closed book exam (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week.
CIV2262
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Off-campus Day) Clayton Second semester 2012 (Off-campus Day) |
Coordinator(s) | G P Codner |
This unit comprises full time work place experience in an engineering based organisation for one semester. Students will gain skills in relation to obtaining the position, application of engineering theory in the real world, and a better appreciation of the engineering profession, and will be more motivated on returning to study and better prepared to enter the work force on graduation.
At the completion of the unit students are expected to have:
Students will be expected to maintain a weekly journal where they should reflect on the progress they are making in their professional and personal development. A work place experience interim report must be submitted to the student's academic supervisor at the end of the semester. The report will contain a number of Engineers Australia competencies, which must be commented against in relation to the student's personal development and experience. The report is expected to be no more than 750 words in length. A brief oral presentation at the end of a student's work place experience. This will normally be at the end of ENG3002. Only students completing one semester of the program will give an oral presentation at the end of ENG3001.
Full time employment
Must have passed 96 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Off-campus Day) Clayton Second semester 2012 (Off-campus Day) |
Coordinator(s) | G P Codner |
This unit comprises full time work place experience in an engineering based organisation for one semester. Students will gain skills in relation to application of engineering theory in the real world, and a better appreciation of the engineering profession, and will be more motivated on returning to study and better prepared to enter the work force on graduation.
At the completion of the unit students are expected to have:
Students will be expected to maintain a weekly journal where they should reflect on the progress they are making in their professional and personal development. A work place experience final report must be submitted to the student's academic supervisor at the end of the semester. The report will contain a number of Engineers Australia stage two competencies, which must be commented against in relation to the student's personal development and experience. The report is expected to be no more than 750 words in length.
A brief oral presentation at the end of a student's work place experience.
Full time employment
Must have passed 96 credit points including ENG3001
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | Robyne Bowering |
This unit may be taken as a later year engineering elective in any department subject to their approval. Each student is required to research, develop, manage and deliver (teach) a unit of work that matches the learning outcomes specified to them by their client (supervising teacher). Prior to their school placement, students must participate in a series of workshops on: understanding and catering for different learning styles, motivation, team work, goal setting, planning, management, leadership, effective communication and presentation skills, asking the right questions and reflection. While there is an emphasis on how the students can directly apply this knowledge in the short term (during their school placements), they are also required to consider how they will transfer this learning into their future engineering workplaces.
At the completion of this unit, students will:
Journal entry 1 - Recognising what employers of engineering graduates are looking for and personal goal setting (1000 words): 15%
Journal entry 2 - Understanding learning styles (1000 words): 15%
Performance review from client and elective co-ordinatror: 20%
Written report (4000 words): 30%
Negotiated task (equivalent of 2000 words): 20%
Weeks 1-3 of semester: 2 hour workshop
6 hours individual study per week
Remainder of semester: 2 hour workshop
10 hours individual study per week
Completion of 96 credit points of study.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Zhigang Xiao |
Need for project management; the project management context; fundamental project management processes and knowledge; tools and techniques for a structured application to project selection and planning including project brief/ideation/concept embodiment decision support tools, numeric profitability and scoring techniques, and EMV/decision tree risk quantification tools; analytical tool application to project scope, time, cost, risk, human resource and quality issues.
To understand the relationship between engineering skills and project management knowledge areas and the key concepts of scope, time, risk, human resources, quality and cost management; to acquire the ability to apply systematic selection and evaluation techniques to engineering projects; and to develop an appreciation of the economic, environmental and social consequences of engineering project decisions, in order to be able to be able confidently to approach the task of managing engineering projects in the real world.
Progressive assessment: 50%
Examination: 50%
24 lectures, 24 practice classes
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Susanga Costa |
Geological processes, geological time scale, folding and faulting geological map interpretation, mineral types and influence on engineering properties, identification of soil and rock types and behaviour, site investigation techniques, geological history, stereographic projection, kinematic analysis of slopes, engineering uses of rock and soil, the stress-strain pore pressure response of soil and rock, failure criteria, stress paths, drained and undrained strengths, consolidation and creep settlements, earth pressures; and over-consolidated and normally consolidated behaviour, analysis and design of slopes, embankments, retaining walls, foundations and tunnels.
To develop an understanding of the principles of basic geotechnical engineering and engineering geology and their application to the investigation, modelling, analysis and design of geoengineering structures.
Assignments: 50% and Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
24 lectures, 24 hours of design class or practicals, 8 hours of field trip per semester
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Susanga Costa |
Overview of concepts relating to groundwater resources and seepage, with emphasis on seepage containment in reservoirs, ponds, soil pollution and its avoidance, focusing on soil behaviour and its effect on seepage, groundwater percolation and migration of contaminant in the nearfield of waste containment facilities. Focus will also be on the function, design and construction of engineered soil barriers to prevent leakage from water reservoirs, ponds or to isolate different types of waste.
To develop an understanding of the principles of environmental geoengineering and groundwater and their application to the analysis and design of surface impoundments and leachate ponds and to the design and construction of engineering soil barriers for controlling seepage and for water and waste isolation.
Design assignment: 50%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
24 lectures, 24 practice/project classes and 6 hours of laboratory or site visits
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Mohan Yellishetty |
Overview of the various water and wastewater systems in an urban environment, functions and modes of operation of urban water and wastewater systems and influence of climate variability on urban requirements in terms of supply of potable water and disposal of wastewater. Examination of the water supply system, stormwater management system, sewerage system and the interface between these systems.
To understand elements of urban water and wastewater management systems - their functions, modes of operation, and design standards; To acquire necessary skills to undertake engineering investigation and design of each of these elements and to integrate them to form urban water and wastewater infrastructure to facilitate sustainable urban catchment development and water resource utilisation.
Closed Book Examination (3 hours): 50%
Assignment/Practical/Project work (continuous assessment): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Jianfeng Xue |
Road safety, traffic surveys, the hierarchy of roads (briefly), road network design, road capacity and level of service, traffic flow in residential streets, unsignalised intersection design, signalised intersection design for interface with arterial roads, pedestrian and bicycle facilities, planning and design for commercial vehicles, planning and design for public transport, local area traffic management, traffic impact analysis, land use planning process, environmental considerations and the application of advanced technology.
The student is expected to acquire a basic knowledge and understanding of the methods and processes of transport and traffic engineering.
Practical/project work: 50%
Examination (2 hours): 50%
48 contact hours
CIV2281
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | G Codner |
This unit comprises a special study in a field of engineering with a content negotiated and agreed between a student and the faculty. The unit is offered as a vehicle to enable an excellent student to undertake studies that would otherwise not fit within the scope of a standard fourth level. The content of the study will vary from student to student. Where necessary, a safety audit and/or risk assessment will be conducted prior to the commencement of work. The student will be expected to prepare a proposal for the study and an analysis of any special requirements to ensure that the scope and expected outcomes of the study are manageable and agreed between the student and the supervisor.
Expected outcomes:
As agreed between the student and the supervisor; may include an initial safety audit/risk assessment, progress reports and a final written report and oral presentation.
12 hours per week
Completion of 144 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | G Codner |
This unit, taken in addition to ENG4001, is an extension of a special study in a field of engineering with a content negotiated and agreed between a student and the faculty. The unit is offered as a vehicle to enable an excellent student to undertake studies that would otherwise not fit within the scope of a standard fourth level. Where necessary, a safety audit and/or risk assessment will be conducted prior to the commencement of work. The student will be expected to prepare a proposal for the study and an analysis of any special requirements to ensure that the scope and expected outcomes of the study are manageable and agreed between the student and the supervisor.
Expected outcomes:
As agreed between the student and the supervisor; may include an initial safety audit/risk assessment, progress reports and a final written report and oral presentation.
12 hours per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Associate Professor Yousef Ibrahim |
Students will undertake an investigation into civil and environmental engineering problems. The projects will be industry-related. However, university-based projects may be acceptable. The students are expected to use various kinds of study (eg laboratory work, field studies and literature survey) as required. Teamwork is highly encouraged in the project.
On completion of this unit, students should:
Project: 100%
Associate Professor Yousef Ibrahim
12 hours per week
Completion of 120 points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Dr Jianfeng Xue/Dr Zhigang Xiao |
To carry out the design for a specified civil engineering development. The design project will vary from year to year but will include aspects of structural, water, geomechanics and transport design.
The objective of this unit is to provide students with the experience of carrying out a significant civil and environmental engineering project under conditions roughly equivalent to those experienced by a new graduate in an engineering office. The project will be drawn from industry, and will be multi disciplinary involving application of materials learnt throughout the undergraduate program.
Examination: 30%
Assignments: 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
Associate Professor Yousef Ibrahim
2 hours lectures, 1 hour workshop/practice class and 8 hours of private study/group work per week. An additional 8 hours of field trip over the semester.
Completion of 120 credit points including: ENG2202 (or ENG2203), ENG3202, ENG3204, ENG3205, ENV3737
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Mohan Yellishetty |
Introduction to typical issues related to catchment/stream complexes; rural and urban land uses and their potential water quantity and quality impacts. Basic principles of water quantity modelling and use of industry standard computer models. Water quality management options including improved land management, water demand management, planning frameworks, and environmental and social aspects. Environmental and social aspects will be covered.
Assignments/Practical/Project work (continuous assessment): 50%
Closed Book Examination (3 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice classes and 8 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) |
Coordinator(s) | Dr Mohan Yellishetty |
Introduce fundamentals and role of road engineering theory and practice. Examine a number of issues related to the planning, design and construction of roads, including; road planning, the road traffic environment, design parameters, design form, road geometric design, pavement design and rehabilitation, geotechnical issues related to pavement performance, pavement drainage, road construction and road environmental safety.
To develop the knowledge, skills and attitudes associated with best practice road engineering.
Assignments: 50%
Examination: 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
2 hours lectures, 2 hours practice/computer classes and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | A Fouras |
Introduction to biomedical engineering from the perspective of engineering based technologies of sensing and imaging. Topics include: basis of light and radiation, principles of synchrotron operation, practical study at the Australian synchrotron, human physiology for engineers, principles of detection and sensing of signals, biomedically relevant properties and phenomena.
The unit begins with an intensive lecture series culminating in a mid-semester examination. During this time project teams are formed and project proposals are developed. Project work continues with groups and individuals combining projects, allocated resources, knowledge and skills to develop a biomedical imaging device. The unit culminates in a test of this biomedical device at the Australian synchrotron.
To instil:
Mid-semester Exam: 20%, Project: 80%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
Weeks 1-6: 4 hours lectures, 1 hour tutorials and 6 hours of private study
Weeks 7-12: 2 hours practical, 3 hours tutorials and 6 hours private study
Completion of 144 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland Second semester 2012 (Day) Gippsland Second semester 2012 (Off-campus) |
Coordinator(s) | Dr John Arkinstall |
This unit introduces the modelling of environmental systems, through conceptual models showing linkages of variables, and full mathematical models. Using discrete and continuous models of biological, chemical and physical processes, the ecology and physical behaviour of environmental systems is represented by models with analytic or numerical solutions. A range of mathematical methods including: analytic and approximate methods (through spreadsheets) for ordinary differential equations, Fourier series solutions for partial differential equations, matrix models and simple difference equations; elementary systems analysis; are used to explore models, and their use in depicting the behaviour of simple physical systems.
On completion of this unit, students will be able to produce a concise conceptual map of an environmental system, as an aid in formulating a mathematical model representing the system; be able to formulate conceptual and mathematical models in ecological, environmental and physical contexts; be able to examine a simple mathematical model of an environmental system, in order to describe its assumptions and to investigate and interpret its predictions; be familiar with several types of models such as: mass balance, input-output, multi-compartment, equilibrium, competition models; illustrated by specific models representing physical and ecological phenomena such as rainfall, evapotranspiration, energy cycles, population growth , chemical reactions, air and plume flow, spatial variability, oscillation, feedback etc; be able to manipulate and solve a variety of simple mathematical models of environmental systems; be able to use spreadsheets and other appropriate software to implement and investigate the solutions of several types of models; be able to apply the following techniques to environmental models: analytic solution of simple 1st and 2nd order ordinary differential equations; solving the one dimensional heat and wave equations, solving analytically linear difference equations in one variable, and linear matrix/vector evolution equations
Assignments: 40%
Examination (3 hours): 60%
3 hours of lectures, 2 hours of tutorials/PC laboratories and 7 hours of private study per week
MTH1085 or equivalent, ENV1711
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | H Blackburn |
This unit will introduce students to the world of flight. It will give them an historical perspective on the evolution of aerospace vehicles and their design. The underpinning discipline areas of aerospace engineering flight mechanics; aerodynamics and propulsion, will be presented in simplified form and then integrated through the processes of analysis and design. Subsonic and supersonic aircraft and their differences will be examined. Students will gain an appreciation of the key aspects of aircraft performance and design.
To understand the evolution of aerospace vehicles and be able to articulate how this has resulted in modern aircraft. To be able to differentiate between the engineering activities of design and analysis and understand their relationship in aerospace vehicle design. To be able to calculate the basic relevant physical properties in different aerospace environments. To gain a basic appreciation of fluid dynamics related to aircraft flight. To understand the physical bases of and be able to differentiate between the different forces acting on aerospace vehicles, calculate their magnitude and direction and the balance between them. To be able to perform basic calculations of the forces involved in different methods of propulsion, including propellers, jets and rockets. To be able to outline the differences between low- and high-speed flight and nominate the basis of how the forces in each are calculated. To understand the basic aspects of aircraft performance in steady and accelerated flight, takeoff and landing, and be able to numerically estimate anticipated aircraft performance. To gain an appreciation of trade-offs made in a variety of example aircraft designs and to understand the roles played by the key physical quantities of thrust, weight and wing area in aircraft design. To understand the basic aspects of aircraft longitudinal stability and control.
Test and assignments 30%, Examination (3 hours) 70%
3 hours lectures, 3 hours of problem solving classes/laboratory and 6 hours of private study per week
MAE1415
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Brian Falzon |
This unit will introduce the student to aircraft structural analysis. Concepts of load paths, equilibrium, forces/moments, stresses/strains, reaction forces and bending moments will be presented. Basic trusses and beam analysis will be used to analyse simple airframes. Students will trace the historical development of the airframe from truss-like structures to modern semi-monocoque construction and the importance of appropriate material selection. The concept of static structural equilibrium will be extended to consider 'dynamic equilibrium' through the introduction of mechanical vibrations. The last two weeks will introduce basic concepts of orbital mechanics/spaceflight followed by an introduction to rocket propulsion.
Field Trip (10%), Structures laboratory (10%), Exam (80%)
Recommended reading:
Anderson, J., 'Introduction to Flight', 6th Edition, 2008, Mc Graw Hill, Singapore. [Chapter 10]
Barnard, R. H., Philpott, D. R., 'Aircraft Flight', 4th Edition, 2010, Prentice Hall, Essex, UK. [Chapter 14]
Gordon, J.E., 'Structures - or why things don't fall down', 1978, Penguin Books, London, UK
Lecture notes.
5 contact hours per week, 7 non-contact hours per week.
None
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | J-F Nie |
This unit provides a broad foundation on engineering materials. It gives an introduction to the basic physical and mechanical properties of common materials (metals, composites and ceramics). It presents students with the basic knowledge of functional materials and devices. Material selection, materials performance and failure mechanisms will be discussed in application to selected components and modern devices in aerospace engineering and mechatronics.
On successful completion of this unit students will be able to:
Two written assignments: 20%
Laboratory work: 15%
Examination (3 hours): 65%
3 x 1 hour lecture, 1 hour of problem solving classes and 7 hours of private study per week. 3 x 3 hrs laboratory classes per semester.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | B G Falzon |
This unit provides students with the necessary skills and knowledge in solid mechanics to confidently analyse and design engineering components and structures with particular reference to the aerospace industry. Each part of the unit contrasts theory and practical application in order to impart a practical appreciation of the knowledge gained. The role of approximate methods of analysis and their interaction with practical situations is highlighted. Constant use is made of real life problems from the aerospace industry
The unit builds on aspects of applied forces and basic structural analysis that are contained in various units in level 1. It provides a focus for this prior learning with respect to the analysis of components and structures within an aerospace context.
Progress test:10%, Computer Laboratory work:10%
Final examination (3 hours): 80%
3 hours lectures
3 hours practice sessions or laboratories and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Meng Wai Woo |
This unit provides the discipline basis for applications in energy, power and heat transfer. It is the core unit in the discipline of thermal sciences, providing a basic level of knowledge and problem solving capability in thermodynamics and heat transfer. The thermal sciences disciplines are central to mechanical and aerospace engineering, being used in the design and analysis of energy conversion devices and systems. Inevitably, in those conversion processes involving heat, analysis and consequent design requires and understanding of the basic heat transfer mechanisms. Thus, the unit is core to understanding aircraft propulsion and computational heat and fluid flow at later year levels.
The unit builds on aspects of thermodynamics and heat transfer and provides a focus for this and an understanding of the relevant mechanisms to be used in understanding aircraft propulsion and computational heat and fluid flow in later year.
Three tests: 15%
Laboratory work:15%
Examination (3 hours): 70%
3 x 1 hour lectures,
3 hours of laboratory or problem solving classes and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Murray Rudman |
This unit introduces numerical analysis techniques for interpolation, root finding, integration, the solution of ordinary differential equations, and the analysis of data. The role computers play in the solution of modern aerospace engineering problems is emphasized through exposure to finite difference, finite volume and finite element techniques for partial differential equations, and the implementation of these techniques in commercial fluid dynamics and structural mechanics packages.
Laboratory and Assignments (30%)
Examination (70%)
Recommended reading:
Anderson, J.D., Jr., "Computational Fluid Dynamics: The Basics with Applications", McGraw-Hill, 1995.
Chapra, S. C., "Applied Numerical Methods with MATLAB for Engineers and Scientists", McGraw-Hill, 2005.
Chapra, S. C., Canale, R. P., "Numerical Methods for Engineers", McGraw-Hill, 2002.
Lindfield, G., Penny, J., "Numerical Methods Using MATLAB", 2nd Edition, Prentice Hall, 2000.
Press, W. H., Teukolsky, S. A., Vetterling, W. T., Flannery, B. P., "Numerical Recipes in [C / C++ / Pascal / Fortran 77 / Fortran 90]", Cambridge University Press. (C & Fortran versions available online at http://www.nr.com/nronline_switcher.html ).
Tannehill, J. C., Anderson, D. A., Pletcher, R. H., "Computational Fluid Mechanics and Heat Transfer, Second Edition", Taylor & Francis, 1997.
5 hours per week lecture and laboratory contact hours, 7 hours per week self-study and assignment work
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | G Sheard |
This unit develops the student's physical and analytical understanding of the bases for aerodynamic flows and translates that into the ability to formulate, analyse and solve aerodynamic problems. It covers an introduction to the concept of a fluid and the continuum hypothesis. Definition of aerodynamic variables and coefficients. Introduction and description of fluid flow kinematics, and the application of this knowledge to the design and use of pumps, fans and compressors. Introduction of conservation principles and their application to the development of the governing equations for incompressible inviscid aerodynamic flows based on the ideas of control mass and control volume. Development of Bernoulli's equation. Solution of the governing Laplace equation for fundamental potential flows and the application of the principle of superposition to derive the solution of complex aerodynamic flows. Development and application of thin airfoil theory for infinite wings, and lifting line theory for finite wings. Introduction to the panel method for the analyses of general three-dimensional incompressible inviscid flow over twisted and delta wings.
Continuous assessment comprising problem sets, assignments and laboratory reports: 30%, Examination: 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
36 lectures, 24 hours of problem solving classes and laboratory sessions.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | J Soria |
This unit develops further the students' physical understanding and analytical skills by including compressibility effects and the viscous nature of aerodynamic flows and translates that into the ability to formulate, analyse and solve very general aerodynamic problems. It covers control volume analysis of steady, one-dimensional, linear and nonlinear compressible flows. Nozzle flows. Steady, supersonic, two-dimensional linear and nonlinear flows. Linearized compressible subsonic and supersonic flow. Introduction to transonic and hypersonic flow. Control volume analysis of viscous incompressible flow, boundary layer flow and free shear flows like jets and wakes, including momentum integral analysis, similarity analysis and similarity solutions of these equations as they pertain to wall bounded and free shear flows. Application of this knowledge to simple design problems.
Continuous assessment comprising problem sets, assignments and laboratory reports: 30%, Examination: 70%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
36 lectures, 24 hours of problem solving classes and laboratory sessions.
None
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Hugh Blackburn |
On completion of this unit students will have an understanding of the key elements of aircraft performance analysis as used in aerospace vehicle design. The design of mechanical elements for aerospace applications, including the use of solid modelling software and introductory finite element analysis of structural strength will be covered. A student project involving the initial design stages of a flight vehicle will integrate these studies. Various characteristics of aircraft performance and their design implications will be examined including whole-aircraft drag polar, power plant characterisation, thrust required in level flight, maximum speed estimation, minimum speed and high-lift devices, rate of climb, gliding, range, endurance, accelerated flight, structural limitations on performance, design for longitudinal and lateral stability. Mission analysis and preliminary weight estimation based on a design concept will be examined together with the aerodynamic synthesis to satisfy performance requirements, power plant selection, overall vehicle layout and balance. Trade-offs as a necessary part of the design will be apparent to students on completion of this unit.
Project work: 50%, Examination (2 hours): 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
Six hours of contact time per week - 3 hours lectures and 3 hours practice sessions or laboratories per week. In addition it is expected student will spend a further 6 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | B Shirinzadeh |
This unit introduces the student to the fundamental aspects in flight dynamics. The requirements and associated equations for static equilibrium and trim are developed. Further, these equations are treated to describe longitudinal static stability and lateral static stability. Performance and flying handling will be introduced. The equations of motion of a rigid vehicle are developed, together with the solution of these and introduction to state space model. The role of small perturbations, aerodynamic force and moment derivatives, aerodynamic control inputs will be established, together with linearized equations. The description of aircraft attitude and Euler angles are presented. The basis and formulations for lateral and longitudinal dynamics and stability will be developed. Control of aircrafts will also be introduced.
Knowledge of the dynamic forces acting on a flight vehicle in different flight environments, and an awareness of the use of equations governing dynamics in the design and use of flight vehicles in industry.
An understanding of the aeronautical forces, through an understanding of finite wing theory, which contribute to the stability derivatives acting on an aircraft.
An awareness of the development and use of equations governing longitudinal, lateral and directional static stability of an airplane.
An understanding of rigid body dynamics and kinematics with focus on aircraft dynamics.
Knowledge and understanding of transitional and space vehicle dynamics.
The ability to design and develop flight vehicles through an understanding of the underlying forces imposed on the vehicle structure.
The ability to develop equations of motion necessary for the successful operation of flight vehicles in atmospheric, orbital and trans-planetary flight.
Appreciation of the role of flight vehicle dynamics in the design, testing and operation of flight vehicles.
Confidence in designing and operating flight vehicles
An appreciation of the fundamental principles underlying solid-body kinematics and dynamics for use in a general engineering workplace environment.
Assignments/tutorials: 30%
Examination (3 hours): 70%
Six hours of contact time per week (usually 3 hours lectures and 3 hours practice sessions or laboratories) and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | D Honnery |
This unit builds on concepts in MAE3401 and relates aircraft and rocket engines to the laws of thermodynamics, various fuel-air power cycles, their real behaviour plus fuel and combustion chemistry. Efficiency and performance of aircraft engines based on piston and gas turbine platforms is examined along with piston and turboprop engines and propeller design for subsonic speed. For jets and turbofan engines, nozzle design for transonic to supersonic speed is covered, as are supersonic engines. The unit concludes with an introduction to rocket motors and their design and performance for both atmospheric and space flight.
Introduce students to the design, operation and performance of engines used for aircraft and rockets: 1. Understand the thermodynamics of fuel-air power cycles used for aircraft propulsion systems and undertake calculations of their thermodynamic properties.
2. Recognise the differences in real versions of the power cycles relative to their fuel-air analogues.
3. Demonstrate knowledge of the fuels used in aircraft and rocket engines and be able to undertake simple combustion related calculations dealing with these fuels. 4. Understand and undertake calculations on the operation and performance of piston engines, turbprops, and ramjets.
5. Understand and calculate the effects of high speed flight on jets, turbofans and ramjets intakes.
6. Demonstrate knowledge of propeller design through the application of various blade theories
7. Understand and undertake calculations on propeller operation and performance.
8. Understand and undertake calculations on the operation and performance of propulsion systems used in rockets operating in the atmosphere and in space.
9. Fuelling requirements of propulsion systems.
10. Aircraft and space flight propulsion systems, their operation and performance. Propeller design, operation and performance based on simple aerodynamic principles.
Problem solving
Laboratory work: 30%
Examination: (3 hours) 70%
Five hours of contact hours - usually 3 hours lectures and 2 hours practice sessions or laboratories per week as well as 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Bernard Chen/Professor Chris Davies |
Light weight composite materials are used widely in aerospace structures. They include carbon fibre reinforced plastics, glass fibre reinforced plastics, carbon laminates, composite panels, carbon mats and woven fabrics. Honeycomb structures, metal matrix composites, thermal ceramics and advanced materials. Light alloys: aluminium, titanium and magnesium. Thermoset and thermoplastic systems. Manufacture, processing and fabrication of aerospace materials. Net shape forming and structure-property relationships. Joining of composites. Properties and selection of aerospace materials. Degradation, failure modes, delaminating, bond failure, environmental and thermal degradation, fatigue and wear.
Understand the properties of aerospace materials, in particular the material anisotropy and how they relate to directional properties.
Understand processes used to manufacture and fabricate different composite materials and light alloys and how their properties can be altered by varying composition and process conditions and fabrication techniques.
Understand the factors that influence the performance and degradation of aerospace materials.
Appreciate the wide range of aerospace materials with high strength-to-weight ratios and advanced materials with specialized properties.
Optimize the performance and life of aerospace structures or components.
Appreciate research and new developments of advanced aerospace materials.
Ability to correlate of properties of aerospace materials with the design of aerospace structures and components.
Identify failure modes in composite materials and assess the impact of environmental and thermal degradation.
A practical understanding of the relationship between properties and performance of aerospace materials and applications in various aerospace components or structures.
An awareness of the advantages and limitations of aerospace materials.
Problem solving 15%
Laboratory work 15%
Examination (3 hours): 70%
Six hours of contact time per week - usually 3 hours lectures and 3 hours practice sessions or laboratories as well as 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | T W Ng |
This unit aims to develop an understanding of the analytical methodologies used in strength and stiffness assessment of aircraft structures. The unit will develop an understanding of the translation of aerodynamic and ground loading on aircraft wings and fuselage to the overall airframe. An understanding of the concept of structural idealisation and constraint will be developed along with real-world limitations. The principles of stressed skin construction will be considered in detail. The unit aims to develop an understanding of the analysis and design of structural problems common in the aerospace industry. It will provide students with the tools necessary to analyse aircraft structures.
Understanding of the relevance of strength and stiffness aspects of aircraft structures and components, including stressed skin construction.
Appreciation of a range of modelling tools and analytical methodologies currently used in the aerospace industry.
Understanding of the interaction between, often conflicting, requirements in the design of airframes i.e. aerodynamics, avionics and propulsion.
Knowledge and skills to translate real-world forces into abstract form for engineering modeling of airframes.
Understand the concept of loads and load paths on the airframe and the structural requirements of airworthiness.
Knowledge of alternative analytical tools to solve similar airframe problems.
Apply and contrast a range of analytical tools currently used in the aerospace industry.
Calculate elastic stresses and deflections in aircraft structures and associated components.
Apply the concept of structural idealization and constraint.
Analyse torsion of wing boxes and other non-circular cross-sections.
Analyse stresses and deflections of flat plates.
Analyse bending, shear and torsion of open and closed thin-walled sections.
Appreciate the relationship between analytical methodologies and real-world aircraft design.
Confidence in evaluating new engineering problems in the aerospace industry and formulating original solutions.
Problem sets: 10%
Laboratory reports: 20%
Examination (3 hours): 70%
Six hours of contact time per week (usually 3 hours lectures and 3 hours practice sessions or laboratories) and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Chao Chen |
This unit covers control theory for aerospace systems with the use of state-space techniques. The state-space of dynamic systems and resulting equations are covered. Concepts of controllability, observability, detectability and the state-transition matrix follow. Classical control concepts including root-locus and frequency-response techniques are set in context of their importance in robust control. Compensators for aerospace systems with full and reduced-order linear observers, parametric optimization. Linear quadratic optimal controllers. The equations of motion for dynamic systems with controllers determined with computational analysis in Matlab.
An understanding of the role of linear algebra in engineering dynamics and controls.
An understanding of modern control theory and its use in aerospace systems.
The concepts of controllability, stabilizability, observability, and detectability and their use in controllers.
An appreciation for optimization techniques, particularly those applied to optimum controllers.
The knowledge of where to go to learn more beyond the content of the course on related and more advanced topics.
A well-rounded individual ability to conduct control system analysis and design via independent hand and computer calculations in Matlab.
An individual ability to determine the behaviour of simple aerospace dynamic systems and develop strategies to control that behavior, qualitatively and quantitatively.
An individual ability to determine the state-transfer matrix, determine the SISO transfer function, design regulators and full/reduced-order/linear quadratic control observers.
An individual ability to optimize a dynamic system based on the mathematical model of the system and linear optimization theory.
Presenting student work in a cogent and concise manner.
Examination (3 hours): 70%
Practice classes 20%
Computer laboratory exercise: 10%
Six hours of contact time per week - usually 3 hours lectures and 3 hours practice sessions or laboratories as well as 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | R Jones |
This unit introduces students to the rules, regulations and legislation governing ownership, use and operation of aircraft in Australia. Topics include aircraft classification, the regulations governing airworthiness and aircraft certification. Aircraft safety is examined through analysis of relevant case-studies as a basis for understanding professional practice. Issues relevant to aerospace engineers in the context of ethical practice, design and manufacture, the environment, intellectual property, trade practices, health and safety awareness and technological developments will be covered. Writing exercises and oral presentations will prepare students for professional practice.
Identify and apply the Rules, Regulations and Legislation pertaining to Australian aircraft.
Develop a working knowledge of the status of the Rules, Regulations and Legislation pertaining to Australian aircraft.
Gain knowledge of Australian airworthiness regulations
Understand of the relationship between regulation and safety in Australian Civil Aviation
Develop an appreciation of the continued role of regulation and governance within the Australian industry and how this contributes to safe operation.
Understand the ethical responsibilities of professional engineers and society's expectations
Recognise the responsibilities of engineers in the design and manufacture of aircraft products
Develop an understanding of the laws relating to intellectual property and in particular patents and copyright as they apply to professional engineering practitioners
Attain an informed understanding of workplace safety and the importance of risk assessment.
Develop the skills required to communicate both orally and in writing to an industry standard.
Class project or exercise: 10%, Assignment one: 20%, Assignment two: 20%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours practice classes or laboratories and 7 hours of private study per week
Completion of 132 points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | S Jenvey |
This unit introduces avionics instruments used in vehicles ranging from light aircraft, air transport, manned and unmanned space vehicles. Their application, principles of operation, accuracy, advantages, limitations, ground systems and the flight vehicle requirements of avionics equipment. Navigation systems with an emphasis on typical forms of measurements involved, their use to pilots and industry are covered. Steering systems, self contained and radio direction finding systems and components, system interfacing, instrumentation and control are examined. Issues of interference, compatibility, redundancy and operational safety and a brief look at active navigation aids complete the unit.
Laboratory exercise: 10%
Assignments: 20%
Examination (3 hours): 70%
3 hours lectures, 2 hours practice sessions or laboratories per week and 7 hours of private study per week
Completion of 132 points of engineering units including MAE3408
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Rhys Jones/Mr John Baker |
This unit will explain why aircraft structures/components fail, how engineers can learn from such failure and design to prevent it. Both fundamental and applied aspects of failure of aircraft structural components will be covered. The unit will detail the damage tolerance design philosophy, and how it fits into airworthiness requirements as described in the relevant Standard (JSSG 2006). The unit focuses on how fracture mechanics principles and modern fatigue crack growth laws are used to meet JSSG2006. To illustrate the effect of cracking on service aircraft we will consider flaw growth in a range of aircraft undergoing both in-service flight loading and full scale fatigue tests.
Understand how fracture mechanics principles can be used to ensure the safety of aircraft structural components. Understand modern fatigue crack growth theories and how these can be used to ensure the continued airworthiness of aircraft structural components. Explain the way in which damage tolerant design fits into JSSG 2006. Solve problems associated with the residual strength of cracked aircraft structural members. Solve problems associated with crack growth in aircraft structural members. Design composite repairs to cracked aircraft structural member.
Class Test 10%
Mid Semester Examination 20%
Class Project: 20%
Examination (2 hours): 50%
3 hours lectures, 2 hours practical classes or laboratories and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | H Blackburn |
The unit covers a more advanced study of the aerodynamics of aircraft wings and aerofoil sections than introduced in previous units. Topics are covered in sufficient depth that students will understand the essential aerodynamic principles applied to aircraft wing design. The notable features of wing and airfoil aerodynamics are outlined, including transition and the analysis of viscous flows. Methods for the analysis and prediction of airfoil and finite wing aerodynamics are covered, together with an introduction to procedures for quantitative design.
Design projects: 30%
Final examination (3 hours): 70%
3 hours lectures, 2 hours practice sessions or laboratories and 7 hours of private study per week
Completion of 132 points of engineering units including MAE3401, MAE3402 and MAE3403
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | B Chen/L Yeo |
This unit provides the student the opportunity to investigate a social problem which has subsequently been resolved through an engineering solution. The student is required to clearly define the problem which is to be resolved; describe the scientific principles underlying the engineering solution; discuss incremental improvements to the engineering product and identify future improvements which may resolve current issues in the construction, use and/or disposal of the engineering solution.
Assignments: 100%
Full semester project based work
MAE4902
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Julio Soria |
This unit introduces differential and integral forms of governing equations in tensor notation, reviews inviscid and viscous aerodynamic flows and analyses the derivation of thin shear layer equations. Solution methods for boundary layer equations for the prediction of drag, lift and boundary layer separation on airfoil surfaces follows. Flow instability and transition from laminar to turbulent flow is examined and boundary layer stability analysis is introduced. Turbulence physics and turbulent shear flows and the analysis of turbulent shear flows are covered together with an introduction to statistical analysis in turbulence and aerodynamic flow control.
Project/Assignment: 30%
Examination (3 hours): 70%
3 hours lectures, 2 hours practice sessions or laboratories and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | D R Honnery |
This unit deals with the operation, performance and design of spark ignition and gas turbine aircraft engines. Initially the engines will be treated as thermodynamic systems. A more detailed investigation of engine individual components will follow. Component integration will be examined through investigations into operation, performance and design. Methods based on thermodynamic modeling to predict engine performance will be investigated, including for gas turbines design and off-design conditions. Students will be required to undertake a significant individual project dealing with aspects of each engine.
The unit has as its primary objective:
Project work: 40%
Examination (3 hours): 60%
3 hour lectures, 2 hours practice sessions or laboratories and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) Gippsland First semester 2012 (Off-campus Day) |
Coordinator(s) | Dr Andrew Percy |
Vector analysis with physical applications. Integration in three dimensions: along curves, over surfaces and throughout regions of space. Identities including Gauss's divergence theorem and Stokes' theorem. The continuity, momentum and energy equations for fluid flow, expressed in 3D vector form. Mass transport (diffusion and advection), diffusion across a liquid/gas interface and light availability (Lambert-Beer model). Random variables, their probability distributions and expected values as summary measures. The Poisson, normal, exponential distributions and distributions useful in the analysis of extremes. Markov chains with hydrologic applications. Point and interval estimation of model parameters. Simple linear regression and correlation.
On completion of this unit, a student is expected to have developed: an enhanced appreciation of the analytic approach to the solution of engineering science problems; mathematical manipulative skills appropriate to the analysis tools; and an appreciation of the benefits and limitations of mathematical analysis and of the need to interpret a mathematical solution in the context of the engineering problem. The student is also expected to have developed: statistical skills for the analysis of data, the use of basic analytical and simulation techniques for Markov processes and the ability to calculate confidence intervals for means.
Three assignments (10% each): 30%
Mid-semester test (1 hour):10%
Examination (3 hours): 60%
3 hours lectures, 2 hours tutorials/ PC laboratory classes and 7 hours of private study per week
MAT1085 or ENG1902 and ENG1603
GSE2703, MAT2901, MAT2911, MTH2010
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | Andrew Percy |
This unit introduces the modelling of environmental systems, through conceptual models showing linkages of variables, and full mathematical models. Using discrete and continuous models of biological, chemical and physical processes, the ecology and physical behaviour of environmental systems is represented by models with analytic or numerical solutions. A range of mathematical methods including: analytic and approximate methods (through spreadsheets) for ordinary differential equations, Fourier series solutions for partial differential equations, matrix models and simple difference equations; elementary systems analysis; are used to explore models, and their use in depicting the behaviour of simple physical systems.
On completion of this unit, students will be able to produce a concise conceptual map of an environmental system, as an aid in formulating a mathematical model representing the system; be able to formulate conceptual and mathematical models in ecological, environmental and physical contexts; be able to examine a simple mathematical model of an environmental system, in order to describe its assumptions and to investigate and interpret its predictions; be familiar with several types of models such as: mass balance, input-output, multi-compartment, equilibrium, competition models; illustrated by specific models representing physical and ecological phenomena such as rainfall, evapotranspiration, energy cycles, population growth , chemical reactions, oscillation, feedback etc; be able to manipulate and solve a variety of simple mathematical models of environmental systems; be able to use spreadsheets and other appropriate software to implement and investigate the solutions of several types of models; be able to apply the following techniques to environmental models: analytic solution of simple 1st and 2nd order ordinary differential equations; solving the one dimensional heat and wave equations, solving analytically linear difference equations in one variable, and linear matrix/vector evolution equations.
Assignments: 40%, Examination (3 hours): 60%
3 hours of lectures and 2 hours of tutorials/PC laboratories per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | R Ibrahim (Clayton); S Rahman (Sunway) |
This unit introduces second year mechanical engineering students to the concepts of time, space, coordinate systems, particles, rigid bodies, forces, work, energy and Newton's Laws of Motion. Students will be taught the fundamentals of kinematics and kinetics of rigid bodies and systems of particles and to carry out dynamic analysis to balance systems with rotating and reciprocating masses. Students will also be introduced to 3-dimensional dynamics of rigid bodies. The fundamentals of mechanical vibration, analysis and synthesis of planar mechanisms and experimental modeling will complete the unit.
On completion of this unit, students will be able to:
Problem solving tests: 10%
Mid semester test: 10%
Laboratory/build and test project: 10%
Examination (3 hours): 70%
3 hours lectures, 3 hours problem solving/laboratory classes and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | N/A (Clayton), A/Prof. Ong Kok Seng/Ms Lim Jen Nee Jones (Sunway) |
A systematic method of capturing design requirements, tools for ideation, estimation and decision-making. Primary and secondary manufacturing processes, assembly techniques. Engineering graphics for problem-solving, manufacturing communication and ideation. Report writing, teamwork in solving design problems involving the integration of mechanical elements in prototype conception, construction and testing.
The student is expected to develop basic engineering design skills that include techniques for defining problems from open-ended specifications, tools for creating design concepts and systematic procedures for choosing between design alternatives. The student will also become aware of a range of manufacturing technologies, be able to design artifacts to suit those processes, and be able to communicate the design intent by drawings produced to the Australian Standard AS1100.
Computer Labs, Tutorial work and Design Assignments: 60%
Examination (3 hours): 40%
2 hours lectures and 3 hours laboratory/tutorial classes and 7 hours of private study a week
MEC2403 ( does not apply to students enrolled in Aerospace programs)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | N/A (Clayton); Dr Pooria Pasbacksh/Dr Hung Yew Mun (Sunway) |
This unit introduces second year students to materials available for the fabrication of engineering components and structures. Students will be instructed on fundamentals of solid mechanics and the determination of mechanical properties of materials that are important for engineering design. A systematic approach to materials selection and methods by which the mechanical properties of these materials can be controlled during manufacturing will be covered. Issues relating to the use of dissimilar materials in aqueous environments will be introduced. Case studies will be presented to highlight the importance of selecting appropriate materials for engineering design.
Knowledge and Understanding
Knowledge and Understanding
Problem solving classes: 10%
Laboratory classes: 10%
Final examination: 80%
3 hours of lectures, 3 hours of problem solving/laboratory classes and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Josie Carberry (Clayton); Dr Tan Boon Thong (Sunway) |
This unit develops the students' physical understanding of the bases of fluid flow and translates that into the ability to formulate and solve problems. It covers the topics of basic concepts and fluid properties, hydrostatics, control volume analysis, the Bernoulli equation, pipe flow and pumps, non-Newtonian flow, dimensional analysis, boundary layers, fluid forces in flow - lift and drag, and vehicle aerodynamics.
To be able to formulate and analyse hydraulics problems in fluids and to be able to calculate the forces on bodies in a quiescent fluid, including the effects of buoyancy. To be able to calculate forces on bodies in fluids undergoing rigid body motion.Use control volumes to predict fluid behaviour with particular regard to the principles of continuity, momentum and energy, and the Bernoulli equation. Use dimensional analysis and modelling to plan experiments, to present results meaningfully and to predict prototype performance. Calculate lift and drag forces for bodies subjected to fluid motion. Compute flow rates and pressure drops in pipe networks under steady state conditions. Understand the typical operation and applications of Pumps, Fans, Compressors and Turbines, their capabilities and limitations, and operating parameters that significantly affect performance. To be able to select the appropriate pump or fan for a particular pipe network and flow. To classify non-Newtonian Fluids, use constitutive equations for these fluids to predict pressure drops in different flows Calculate the lift and drag on vehicles of different geometries travelling at a variety of speeds and to determine the consequent effect on fuel consumption. Carry out simple experiments relating to fluid properties and flow behaviour. To be able to solve problems by defining the problem using the discipline theory taught and applying mathematical and other methods taught throughout the curriculum.
Tests, tutorials and laboratory assignments: 30%
Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 Lecture hours, 3 hours of laboratory/problem solving classes and 6 hours of private study per week.
CHE2082, CHE2100
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Mr Navid Shahangian (Clayton); Dr Shek Md Atiqure Rahman (Sunway) |
This unit introduces concepts of heat, work, energy, temperature and pressure. The properties of pure substances, steam tables and phase diagrams and their use in thermodynamics problems, First and Second Laws of Thermodynamics and their use in steady and unsteady state problems, Carnot cycle, Gas power cycles, vapour and combined power cycles are introduced. Use of T-s diagrams for power cycle analysis, P-h diagrams in refrigeration cycle analysis and simple combustion processes are covered. Renewable energy such as solar, hydro, wind and biomass, and their use in heating and electricity generation and the environmental benefits of renewable energy conclude study in this unit.
Examination (3 hours): 70%
Laboratory: 15%
Assignments and Tests: 15%
3 hours lectures, 3 hours practical classes or laboratories and 6 hours of private study per week.
CHE2120
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Jing Fu(Clayton); Dr Aravinthan Arumugam (Sunway) |
In this integrative level 2 unit students are introduced to the design of machine elements covering bearings, shafts, welds, fasteners, gears etc. This leads to an examination of techniques for improving engineering designs based on economic and functional considerations. Geometric and economic tolerancing is further explored. The use of solid modelling software to simulate kinematic behaviour of mechanical devices and produce engineering drawings is introduced. The integration of design skills and related engineering studies is covered through a group exercise to design a mechanical/mechatronic device.
Students will be able to:
Practical work/Assignments: 70%
Examination (2 hours): 30%
3 hours lectures, 2 hours laboratory/practical classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Tuck Wah Ng (Clayton); Mr Edwin Sim Yih Shyang (Sunway) |
Introduction to the design, analysis, and practical manufacture of electromechanical systems, incorporating DC and AC electrical circuit theory, simple semiconductor and amplifying components, transformers, and sensors and actuators. Mathematics of electromechanical systems is provided, including Laplace transforms and complex algebra. Computational and assignment work (via practicals) to be integrated to give student complete understanding of specific examples using modern microelectronic components, sensors, and actuators.
Students are to gain the ability to model elementary electro-mechanical systems, incorporating mechanical and electrical energy exchange and interaction, with additional instruction on common applied mathematical methods used in electromechanical system analysis, including Laplace transforms and complex algebra. Tutorial work will provide the student a reinforced understanding of electromechanics.
Problem solving classwork: 20%
Examination (3 hours): 80%
3 hours lectures, 3 hours laboratory/problem solving classes and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | P Ranganathan/M Thompson (Clayton); Y M Hung (Sunway) |
This unit expands upon concepts introduced in MEC2404 Control volume analysis is extended to consider Newton's second law of motion and the first and second laws of thermodynamics. Differential analysis leads to the development of the Navier-Stokes equations, and solution techniques for potential and viscous flows are introduced. The relationship of boundary layers to lift and drag is explored, theory of both turbomachinery and open-channel flow is consolidated, and the thermodynamics of insentropic compressible flows is described. The acoustic wave equation is derived, its and applications to sound intensity, noise control and the dB(A) weighting system are considered.
To derive and solve the Navier-Stokes equations governing a fluid of boundary layers, and their contribution to lift and drag of Turbo-machinery equations of open channel flows and the hydraulic analogy of compressible flows, including isentropic flows of acoustics, including the wave equation, sound intensity and power, noise control, and dB(A) weightings Identify and derive calculable solutions to fluid mechanics problems from the Navier-Stokes equations Exploit knowledge of lift and drag characteristics of various geometries to improve the performance of objects in a flow Determine the free-surface wave speed and the effects of a hydraulic jump Calculate the fluid and thermodynamic properties across an isentropic shock Use the hydraulic analogy to develop compressible flow theories Determine the sound intensity and power of an acoustic source Calculate the absorption and attenuation of sound at a simple surface geometry An understanding of the need to, and benefits of, contributing as part of a team towards a common goal Appreciate the historical societal benefit of mechanical engineering applications of fluid mechanics.
Practice classes: 10%
Assignment projects: 20%
Examination (3 hours): 70%
6 hours of contact time per week (usually 3 hours lectures and 3 hours practice sessions) and 6 hours of private study per week
Must have passed (ENG2091 and MEC2404) OR have passed (MEC2430 or MEC2404) AND passed 2 units in (MAT2901, MAT2902, MTH2010, MTH2021, MTH2032)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | S Wordley (Clayton); B T Tan(Sunway) |
This unit builds on knowledge gained in second year design units and continues the use of group work and design projects as key learning methodologies to integrate theoretical knowledge and understanding. It includes use of an Australian or International standard and design software tools for 3D modelling, assembly, motion, and stress analysis topics. Topics on manufacturing processes will incorporate the discussion of a wide variety of processes in addition to those relating to composites and polymers. The unit will emphasize design methodology and design processes for manufacturing and assembly.
Knowledge and understanding of the steps to be undertaken in the solution of open-ended design problems.
Knowledge of methods used to demonstrate a design's viability.
Knowledge of drawings and 3D modelling in the design process.
Knowledge of a range of engineering software tools including stress analysis, vibration, mechanical system simulation, fluid dynamics and manufacturing software. Find solutions to complex engineering problems using design methodologies.
Appreciate timing and budgetary constraints Undertake tasks as part of a team.
Communicate effectively in written, oral and graphical forms.
Appreciate the role of design in engineering practice. Confidence in identifying engineering problems and formulating solutions.
Computer Labs/Tutorial work/Design Assignments: 70%
Examination (2 hours): 30%
5 hours contact time (usually 3 hours lectures and 2 hours practice sessions or laboratories) and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | W K Chiu (Clayton); B T Tan (Sunway) |
Students develop skills in analysing the response of a vibratory system to an external stimuli. Techniques for developing the equation of motion, defining the forcing function and analysing the vibratory response. Fundamental calculus for analysing mechanical vibrations and the generalised kinematics and kinetics of particles and rigid bodies using vector algebra. A systematic method of establishing a dynamic model with the associated forces and motion, a set of coordinate axis and the choice of derivation method for the governing equations for the model and solution techniques follows. Skills presenting results develop along with understanding the relevance of dynamics in engineering.
Use of kinematics and kinetics in engineering problem solving
Use of vector algebra in solving 3D engineering dynamics
The concepts of degrees of freedom and its use in defining a model and the solutions to the model
An appreciation for the role of vibrations in machines and structures in engineering
Of the various solution methods for single and multi-degree of freedom representation of dynamic systems
How vibration fits into engineering design
How vibrations can affect the safe operation of machinery
Perform basic engineering calculations in a systematic and logical manner in dynamics and mechanical vibrations
Apply the concepts of dynamics in the analysis of vibration problems
Make observations and measurements for the analysis of vibration problems.
Use of computer methods to solve modelling problems.
Project Work 10%
Tutorial work:15%
Examination (3 hours): 75%
3 hour lectures, 3 hours practice sessions or laboratories per week and 6 hours of private study per week
ENG2091 and MEC2401 or MTH2021 or MTH2032
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | M Majumder (Clayton); S Rahman (Sunway) |
This unit aims to develop a fundamental understanding of the processes by which heat and energy are inter-related and converted and by which heat is transferred. The unit will review major principles of energy conversion and the modes of heat transfer. The basic laws of thermodynamics and the governing equations for heat transfer and thermodynamics will be introduced and subsequently used to solve practical engineering problems involving thermodynamics and heat transfer. The unit will also cover fundamental design principles of power generation systems and heat exchangers.
Understand the fundamental modes by which heat is transferred
Identify the responsible mechanism or combinations of mechanisms involved in heat transfer problems
Understand how different forms of energy are interconverted and appreciate the difference in their efficiencies
Analyse conventional power generation systems using steam and gas turbines and internal combustion engines
Solve practical heat transfer and thermodynamic problems
Formulate and solve models based on the governing equations of heat transfer and the basic laws of thermodynamics
Appreciate the three fundamental modes of heat transfer
Appreciate the difference between heat transfer and energy conversion (thermodynamics)
Recognise that thermodynamics is not an abstract but rather an applied energy-related unit based on the fundamental laws of mass and energy conservation.
Assignments: 10%
Tests: 20%
Examination (3 hours): 70%
3 hour lectures and 3 hours practice sessions/laboratories (his may alternate with 2 hours lectures and 4 hours practice sessions/laboratories) and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | tba (Clayton); Dr Tan Boon Thong/Ms Lau Ee Von (Sunway) |
This unit aims to develop an understanding of the analytical methodologies used in strength and stiffness assessment of engineering structures and components. It allows students to translate real-world forces into abstract form for engineering modelling of a range of common problems found in industry and gain knowledge of the relationship between analysis and design. Students will be exposed to a wide range of analytical tools and modeling philosophies. To complement these analytical solution techniques, students will now taught the fundamentals of finite element analysis.
Understanding of the relevance of strength and stiffness aspects of engineering structures and components.
Appreciation of a range of modeling tools and analytical methodologies.
Understanding of the role of solid mechanics in engineering analysis and design.
Knowledge and skills to translate real-world forces into abstract form for engineering modeling.
Understand the concept of loads and load paths.
Knowledge of alternative analytical tools to solve similar problems.
Apply and contrast a range of analytical tools.
Calculate elastic and inelastic stresses and deflections in simple and compound beams.
Calculate stresses and displacements in pressure vessels.
Analyse torsion of non-circular cross-sections.
Analyse stresses and deflections of flat plates.
Analyse shear stresses in thin-walled sections.
Appreciate the relationship between solid mechanics and engineering design.
Confidence in evaluating new engineering problems and formulating original solutions.
Assignments: 10%, Laboratory reports: 20% and Examination (3 hours): 70%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours practice sessions/laboratories (this may alternate with 2 hours lectures and 4 hours practice sessions/laboratories) and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Zhe Liu (Clayton); Dr Hung Yew Mun (Sunway) |
This unit conveys the fundamentals of numerical analysis techniques for root-finding, interpolation, integration, the solution of ordinary differential equations and data analysis, and Matlab is employed to demonstrate their implementation. The role computers play in both the solution of engineering problems and the acquisition and analysis of data is explored through consideration of common partial differential equations in mechanics, and their solution via finite difference, finite volume, and finite element methods.
Understanding of the role of computers and numerical analysis in modern engineering practice
Appreciation of stability, efficiency and accuracy constraints on available methods for numerical approximation of engineering solutions
Understanding of numerical methods for interpolation, root-finding, integration, solution of ordinary and partial differential equations, and analysis of data.
Knowledge and skills to generate accurate solutions to engineering problems using numerical computing
Knowledge of the types of equations which arise in computational mechanics
Understanding of finite difference, finite volume and finite element methods, and their application to computational mechanics problems
Understanding of methods for data analysis, including sampling, Fourier transforms and filtering
Solve engineering problems numerically
Determine the appropriate technique to solve a problem through consideration of the accuracy, efficiency and stability of available methods
Acquire, analyse and interpret data
Complete tasks as part of a team
Improve oral and written communication skills
Appreciation of the role of computers in engineering industry
Confidence in identifying engineering problems and formulating original solutions.
Laboratory and Assignments: 30%
Examination (3 hours): 70%
3 hour lectures, 3 hours practice sessions or laboratories per week (this may alternate with 2 hours lectures and 4 hours practice sessions/laboratories) and 6 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Chao Chen (Clayton); Dr Wang Xin (Sunway) |
This unit covers the nature and behaviour of simple components, processes and subsystems relevant to engineering control. Mechanical, electrical, fluid pressure devices and complete elementary control systems are included. Orientation is to predicting, examining and assessing system performance via formation of mathematical models and solution of models. Laboratory experiments and hands-on instruction in the digital simulation package Matlab to solve models. A unified approach to mathematical modelling via the concepts of resistance, capacitance and inertia/inductance is emphasised. Students learn to perform system modelling, develop solution, assess a system response and analyse systems.
Understand the significance and relevance of systems and associated control in engineering.
Appreciation for mathematical formulations to develop accurate linear models through classical and state space modelling techniques describing systems with single-input single-output (SISO) and multi-input and multi-output (MIMO).
Gain knowledge of system's response through the use of analytical techniques, such as classical solution, Laplace transforms, state space, etc.
Understand the concept of stability and its importance for systems analysis and control.
Gain knowledge of dynamic performance of a system, including selection of system parameters to achieve the desired response, and further analysis through techniques such as frequency response.
Understand the effects of non-linearity in systems and limitations of the use of linear models.
Gain knowledge of experimental, as well as computer-based (such as Matlab) techniques.
Ability to develop mathematical models for devices and systems for the purpose of response and dynamic behaviour analysis.
Ability to obtain system's solution and response using classical method, Laplace transforms method, and state space method.
Ability to determine the stability of a system utilising S-plane and Routh-Hurwitz technique.
Ability to analyse dynamic performance of systems in the time and frequency domains using the Bode plot, root-locus, and Nyquist plot.
Ability to continue learning about systems modelling and control techniques beyond the content provided in this course.
An appreciation of the unified concept of resistance, capacitance and inertia/indusctance to perform physical modelling of mechanical, fluidic, hydraulic and pneumatic systems.
An appreciation for the need to represent, predict and analyse the system and its response and dynamic performance, and convey these through pictorial representations such as block diagrams, signal flow graphs, plots, etc
An appreciation of non-linear effects and the use of linear models as approximation.
Mid-semester test (1 hour): 30%
Examination (3 hours): 70%
3 hour lectures, 3 hours practice sessions or laboratories (this may alternate with 2 hours lectures and 4 hours practice sessions/laboratories depending on the week) and 6 hours of private study per week
(ENG2091 and MEC2407 and MEC3453) or (MEC3453 and MTH2021 or MEC3453 and MTH2032)
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Shahin Khoddam/Professor W K Chiu/Dr B Chen (Clayton); Mr. Edwin YS Sim/Dr Hung Yew Mun (Sunway) |
Introduction to data acquisition across a range data types, analogue-digital sampling and signal conditioning. Data acquisition and processing functions using LabView. Current data measurement technologies and equipment, acquisition methodologies used in fluid dynamics, material properties, thermodynamics, control and dynamics. Data analysis methods including error analysis, validation, spectral analysis identification and interpretation of trends. Introduction to research practices, formation and testing of hypotheses as well as experiment design and project management. Communication skills and techniques, preparation of reports and oral presentations. Occupational health and safety.
Understanding of skills and techniques required for the acquisition of optimised meaningful experimental data
Knowledge of the important components of experimental design
Overview of current technologies available for experimentation
Knowledge of data acquisition methods
Knowledge of data analysis methods
Appreciation for the importance and application of occupational health and safety procedures
Manage and execute short and medium term projects
Form and evaluate hypotheses
Communicate results using written and oral formats
Acquire and optimise experimental data
Use data analysis techniques to explore and evaluate experimental data, including error analysis
Use LabView to acquire and analyse experimental data Apply occupational health and safety procedures.
Written reports and oral presentations (100%)
3 hour lectures, 3 hours practice sessions/laboratories (this may alternate with 2 hours lectures and 4 hours practice sessions) and 6 hours of private study per week
Must have passed 120 credit points from engineering or science
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Josie Carberry (Clayton); Dr Hung Yew Mun (Sunway) |
Students undertake a self-guided learning task in the form of a project.
Projects may be a single semester or (in conjunction with MEC4402) a full year in length [Enrolment by Departmental approval only]. Projects will consist of either a design, theoretical, or experimental investigation. The project may be undertaken either within the Department or externally with a company or research organization. In either case, an academic member of staff will act as the supervisor. While some projects may benefit from group based work it is expected that students will work individually on each project.
NB. Before work is started on the project a safety induction and risk assessment process will be completed.
On successful completion of the unit students will be able to:
Full semester project-based work.
1 hour lecture and 11 hours of private sudy per week.
Must have passed 36 credit points at level three in the engineering component of the course.
None
MAE4901
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Josie Carberry (Clayton); Dr Hung Yew Mun (Sunway) |
In this unit, together with MEC4401, students undertake a self-guided learning task in the form of a project. It is a full year project of either a major design, theoretical, or experimental investigation. The project may be undertaken either within the department or externally with a company or research organisation. In either case, an academic member of staff will act as the supervisor. While some projects may benefit from group based work it is expected that students will work individually on each project.
Full semester project-based work: 100%
Full semester project-based work
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr B Chen + Dr L Yeo |
This unit provides the student the opportunity to investigate a social problem which has subsequently been resolved through an engineering solution. The student is required to clearly define the problem which is to be resolved; describe the scientific principles underlying the engineering solution; discuss incremental improvements to the engineering product over time and identify future improvements which may resolve current issues in the construction, use and/or disposal of the engineering solution.
Assignments: 100%
Full semester project based work
120 credit points completed and subject to department approval.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | D Burton, B Chen and H Frost (Clayton); L K Ong (Sunway) |
This unit provides students with an understanding of the work environment of professional engineers addressing topics not covered in other parts of the degree program. It allows students to more effectively use their engineering skills within the context of a business environment, and assists them to add value to the community. Students will be encouraged to evaluate problems from a multi-faceted perspective and to articulate their views in writing as well as in discussion. The unit provides a balance between global macro issues likely to influence their future work environment, and more current, micro issues likely to confront graduates in establishing themselves as professional engineers.
Role and contribution of an engineer in society
Ethical responsibilities of engineers
Modern work practices and organising for high performance
Sources of wastes and process inefficiencies, the lean manufacturing methodology, customer focused pull design and manufacturing strategies
Factors affecting the performance of the Australian manufacturing sector including energy, water, environmental issues, sustainability, work skills Individual performance assessment
Transition from university Safety and OHS, risk assessment
Project management
Designing for innovation, and creative approaches towards problem solving
The role of standards and accreditation in work practices
Intellectual property, and in particular patents and copyright
Responsibilities of engineers in the design and manufacture of consumer products
Contract law
Product costs, in particular the effect of direct costs and the allocation of overheads on performance
Capital budgeting
Complete tasks as part of a team
Improve oral and written communication skills
The significance of non-engineering factors in the context of their role as an engineer
To be more aware of their role as an engineer in society
To value the practice of self-directed learning and lifelong learning
To appreciate that problem solving will often involve the use of incomplete data and data of varying reliability, a choice of method, and the possibility of more than one outcome depending on the weighting given to different factors.
Practice class activities: 10%, Two assignments: 40%
Examination (3 hours): 50%.
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
6 hours of contact time (usually 3 hours lectures and 3 hours practice sessions or laboratories) and 6 hours of private study per week
Must have passed 120 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Unsteady heat conduction, numerical solutions to multi-dimensional conduction problems. Derivation of general governing equations for fluid flow, heat transfer and mass transfer. Free and forced convection heat transfer in laminar and turbulent flow regimes. Fundamentals of mass transfer. Introduction to two-phase heat transfer.
Examination (3 hours, Open Book): 65%
Project work (Literature Research Paper): 20%
Assignments (15%)
5 hours of contact teaching time based on a mix of lectures and problem based learning classes in addition to 6 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway Second semester 2012 (Day) |
Coordinator(s) | tba (Clayton); Dr Ong Kok Seng (Sunway) |
Review of mass and energy conservation and transfer processes; psychrometry and moist air properties; factors influencing human comfort; calculation of building thermal loads; simulation packages for calculating building loads; air conditioning systems; fans, pumps, ducts, etc in air conditioning plant; control systems in air conditioning plant; vapour compression and absorption refrigeration; air conditioning and refrigeration in transportation; industrial fieldwork.
Examination (3 hours): 45%
Laboratory/field work: 35%
Projects: 20%
3 hours lectures, 2 hours laboratory or practice classes and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | H Chung (Clayton); C P Tan (Sunway) |
Instruction on the basics of automatic control design, including anaysis and design techniques (with MATLAB/SIMULINK). Assumes students have the ability to form and use classical and state-space models of linear systems, can calculate their responses in time and frequency domain, and have experience in using MATLAB. Control system design through root-locus, frequency response, direct pole-placement, and state estimation, with concepts of linear systems, controllability, and observability. Introductions to robust stability, PID control design, digital systems, and optimal control design methods will also be provided.
Assignments: 25%
Examination (3 hours): 75%
22 lectures, 22 practice class/laboratory hours
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Mr Tuncay Alan |
Introducing micro and nano- technology in the design of next-generation microelectromechanical systems, microfluidic devices and biomedical applications. Basic concepts and physics of small-scale systems are covered. Topics include: scaling effects, nanofabrication techniques, continuum mechanical theories, low Reynolds number flows, capillary effects and interfacial flows, flows in channels of arbitrary dimensions, convective-diffusive mass transport, electro hydrodynamics
including classical double layer theory, electrophoresis, electrosmosis, dielectric polarisation and dielectrophoresis. The course also focuses on device applications, specifically MEMS sensors and actuators and lab-on-chip devices, through hands-on laboratory sessions (held at Melbourne Centre for Nanofabrication).
To instill
Laboratory work: 15%
Design project 20%
Examination (3 hours): 65%
3 hours lectures, 3 hours practical classes and 6 hours of private study per week
Mechanical Engineering and Aerospace Engineering students: MEC3451, MEC3453 and MEC3455.
Mechatronics students: 120 points including TRC2200 and TRC3200
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | S Khoddam |
Finite element analysis is widely used in mechanical, automotive, rail, mining and aerospace engineering. Commercial codes are used to identify elements in a given problem, their limitations and ways to improve the accuracy and reliability of analysis. Lectures present relevant theory and cover formulation of both the common default elements and the preferred element types. Other topics include stress recovery, formation of stiffness matrices, aspect ratio limits and the role of reduced integration. Tutorials provide hands-on knowledge of finite element analysis on a simple structure. Students develop skills in some leading edge commercial CAD programs.
Class assignment: 10%
Project: 20%
Mid semester examination 20%
Examination (3 hours): 50%
22 lecture hours and 22 practice class hours
Must have passed 96 credit points including MEC3455 or MAE3407 or TRC2201.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Jing Fu |
Topics include maintenance planning and scheduling, organisation of maintenance resources, quantitative techniques in maintenance management. Queue theory; network planning and Monte Carlo simulation are introduced. Preventive and condition-based maintenance, failure analysis, reliability engineering, computerised maintenance management and appraising maintenance performance are examined and industry-based case studies are presented. The T* integral limitation and growth rules as well as variable amplitude loading and the alternating finite element method are covered. Damage tolerant design principles complete the unit.
Examination (2 hours): 60%
Assignments and laboratory work: 40%
33 lecture hours, 10 practice class hours and 12 laboratory hours
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Mr Tuncay Alan |
Instruction on advanced topics in dynamics, incorporating electromagnetics via D'Lambert's principle, Hamilton's equations and the virtual power (Jourdain/Kain) method. Focus on kinematics and dynamics of robotic structures and magnetoelectromechanical devices (motors, speakers, transducers, vibration sensors etc). Consideration of the inevitable and critical consequences of nonlinearities in dynamics response, including limit cycles and Poincare maps and flows. Reinforcement of concepts using computer analysis.
Students are expected to gain the ability to model the dynamics of systems incorporating mechanic, electrical, magnetic and other forma of energy storage and interaction, with consideration of the consequences of nonlinear behaviour. Computational work will provide the student with a reinforced understanding of advanced dynamics.
Examination (3 hours): 70%
Assignment, laboratory and tutorials: 30%
22 lecture hours, 18 practice class/laboratory hours
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | W K Chiu (Clayton); Edwin Sim (Sunway) |
Fundamentals of sound and sound propagation, wave equation, Helmholtz equation, absorption, impedance and intensity, silencers. Transmission from one medium to another, applications and optimisation. Transmission through walls, mass law, coincidence and resonance. Sound transmission in the atmosphere, inverse square law, excess attenuation. Radiation of sound, directivity. Sound in enclosed spaces. Noise sources, noise reduction techniques, noise legislation and regulation, acceptable noise levels, hearing conservation, measurement and analysis of noise, design for low noise.
Examination (2 hours): 70%
Assignments and tutorials: 25%
Laboratory: 5%
22 lecture hours plus 22 hours of practice classes and laboratory classes
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | W Yan |
Specific modulus and specific strength; 3D stress and 3D strain tensors; anisotropic elasticity; composite lamina and composite laminate; hygrothermal strain and hygrothermal stress analysis of composite structures; failure theories for a composite lamina; micromechanical analysis of a composite lamina; classical lamination
theory for composite laminate, failure analysis of composite laminates, design of composite laminates, finite element analysis of composite materials and structures.
Examination (2 hours): 70%
Assignments and tutorial work: 30%
22 lecture hours and 22 practical/practice class hours
120 credit points completed
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Professor Mark Thompson (Clayton); Dr Tan Boon Thong (Sunway) |
Computational Fluid Dynamics (CFD) is a well-established analysis, design and optimaisation approach for industrial fluid and heat transfer problems.Examples include turomachinery, vehicle aerodynamics and aeronautics. It is also a powerful research tool and is being increasingly used to answer fundamental questions in a wide range of fields, from astrophysics to nanomaterials. This Unit provides an introduction to this mathematically sophisticated discipline. This involves a review of the equations governing motion and energy of fluids, the mathematical properties of these equations and the relevance of such properties to obtaining numerical solutions. The basics of numerical discretization and solution methods will be discussed. The Unit will also introduce you to using commercial CFD packages in analysing complex industrial problems involving fluids.
Examination (3 hours): 50%
Tests: 20%
Assignments: 30%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
5 contact hours per week including lectures, tutorials and computer laboratory classes and 7 hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | C Chen |
Spatial descriptions and transformations. Manipulator forward and inverse kinematics. Differential relationships and Jacobian. Manipulator dynamics: Lagrangian and Newton Euler formulations. Design of mechanisms and end-effectors. Actuation, sensing and control. Computational geometry for design, manufacture, and path planning. Robotics in manufacturing and automation. Techniques for modelling, simulation and programming of robotic tasks. Advanced mathematical formulations. Introduction to advanced robotics. A self-directed learning component completes the unit.
Examination (3 hours): 70%
Project and laboratory work: 30%
36 lectures, 24 practice class/laboratory hours
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Qizhi Chen |
Bonding: atomic/molecular arrangement. Crystal systems: directions and planes, stereographic projection; metallic, ionic and ceramic crystals. Defects; vacancies and interstitials; dislocations; stacking faults, twin and grain boundaries. Thermodynamics: condensed systems; entropy, Gibbs free energy; ideal and non-ideal solutions; surface energy and microstructure. Phase equilibria and microstructures: Gibbs phase rule; free energy diagrams; phase diagrams; deviations from ideality, phase separation; ordering; eutectic, eutectoid, peritectic and peritectoid reactions; non-equilibrium microstructures, implications for physical properties.
On successful completion of this course students will:
Assignments: 18%
Mid semester test: 7%
Laboratory work: 25%
Written examination: 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lecture/tutorial, 7.5 hours of private study per week and 18 hours laboratory classes per semester
MSC2011, MTE2501
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Ilana Timokhina/Professor Kiyonori Suzuki |
Thermal conductivity, heat transfer film coefficients. Non-steady state conduction; lumped systems. Convection and radiation. Casting, forging, hot rolling, injection moulding. Interstitial and substitutional diffusion. Carburization, homogenization. Nucleation and growth: homogeneous and heterogeneous nucleation, solid/liquid interface, growth of solid in liquid, growth of solid in solid. Solidification: coring; cells and dendrites; eutectics; segregation in ingots. Kinetics of phase transformations: TTT and CCT diagrams Evolution of microstructure/nanostructure: thermomechanical processing of steels and Al/Mg alloys; hardenability, quenching and tempering of steels, alloying elements.
Laboratory work: 25%
Assignments: 25%
Examination (3 hours): 50%
3 hours lecture/tutorial classes, 7.5 hours of private study per week and 18 hours laboratory classes per semester
MTE2541or MSC2011
MSC2122, MTE2502, MTE2503, MTE2504, MTE3502
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | K Suzuki |
The unit focuses on the 'smart' functional roles of the materials in devices which depend on their electrical, optical and thermal properties. Examples of such devices are: active semiconducting devices and associated passive electrical components, 'smart' transducers, optical fibres, optical coatings, liquid crystal displays, optical storage devices, the ruby laser, the solar cell, ceramic insulators, the Peltier cooler. The functional materials will be studied at the microscopic (atomic and/or molecular) level in order to gain an understanding of the device operation. In addition, some discussion will focus on device fabrication.
On successful completion of this course students will be able to: understand the atomic and molecular structures of functional electrical materials, describe conduction processes in metals, alloys, semiconductors, polymers and ceramics, understand the temperature dependencies of these processes to the extent that they relate to the functioning of modern devices, understand the microscopic origins of polarization processes in electrical insulators, ionic, molecular, ferroelectric and piezoelectric materials, account for optical transmission and absorption processes in polarizable electrical materials, appreciate material compatibility requirements in the fabrication of devices from different classes of materials, conduct laboratory experiments designed to measure properties and to have an appreciation of the importance of experimental accuracy in measuring physical properties, appreciate the importance of a co-operative team effort in materials evaluation, prepare and present written reports on property measurement, appreciate the role of physical property assessment in materials research and/or manufacturing.
Written assignments: 15%
Laboratory work: 25%
Examination (3 hours): 60%
3 hours lectures/practice classes and 7.5 hours of private study per week and six 3 hour laboratory classes per semester
ENG1050, MSC1010 or by permission
MTE2507, MSC2022, MSC2111
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Bjorn Winther-Jensen/Dr Don Rodrigo |
Introduction to common ceramics: industrial ceramics: ceramic crystal structures, clay based industrial ceramics, alumina, mullite; their general compositions, microstructures, processing and properties; understanding the characteristics of these materials from phase diagrams. Introduction to polymers: Polymer coil; molecular weight and molecular weight distribution; chain and step-growth polymers; tacticity; random, block and graft copolymers; solution properties; thermal properties and Tg; thermoplastics and crosslinked polymers; polymer blends.
Examination: 50%
Assignments: 30%
Laboratory: 20%
36 lecture/practice classes and 3 laboratory experiments per semester
MTE2502
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | R Lapovok |
Normal and shear stresses in three dimensions. Mohrs circle for stress in two and three dimensions. Strain state analysis, normal, shear , principal and volumetric strains. Invariants of stress and strain. Linear elasticity. Visco-elasticity. Yielding criteria. Strain rate and temperature effects. Power-law deformation. Work hardening and hardening coefficient. True and engineering stress strain curves. Influence of the loading path on mechanical properties. Brittle failure. Yielding and yield point phenomena. Stress concentrations. Irwin analysis of stress around a crack. Fracture toughness. Griffith analysis. Phenomenological and classical theories of fracture.
Examination (3 hours): 60%
Assignments: 30%
Laboratory work: 10%
36 lecture/practice classes, 3 laboratory experiments
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Wayne Cook/Dr Nikhil Medhekar |
The unit shows how the properties of materials and their structure can be mathematically analysed. Students will apply mathematical techniques to solve problems in various materials engineering fields. Examples of mechanical and electrical properties of materials are examined by the application of matrix operations. Heat transfer and diffusion in materials processing are used as exemplars of partial differential equations and boundary value problems. The error function is introduced. Finite difference methods are explored in relation to heat transfer and diffusion problems, basic curve fitting is introduced as a way of modelling a material's response to deformation. The statistical treatment of experimental data is presented. The distribution of errors for discrete and continuous data are analysed via the Binomial, Poisson and Normal distributions. Statistical testing and fitting of data and various forms of least square fitting of data is introduced. The applicability of non-parametric statistics is applied to a range of non-ordinal data. Problems are analysed using Excel and Matlab.
To develop:
Assignments: 40%
Laboratory class: 10%
Examination (3 hours): 50%
Two 1 hour lectures, one 2 hour tutorial/problem solving class, and 7.5 hours of private study per week and two 3 hour laboratory classes per semester
ENG1091, ENG1060 and ENG1050 or MTE2541
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Qizhi Chen |
Classifications of biomaterials covering metallic, polymeric, ceramic and composite materials; typical structures and properties for biomedical applications. Definitions of biocompatibility and critical design criteria of biomedical devices. Introduction to basic human anatomy, human histology, cells and genes and responses of living tissues to implanted biomaterials including inflammatory responses and blood compatibility. Assessment of biocompatibility of biomaterials, sterilization procedures and an introduction to ethical and regularity issues with biomedical devices.
MTE2548 Biomaterials I will introduce students to biomaterials and also provide a foundation for further study in biomedical engineering. The following are the specific learning objectives of this unit: Upon successful completion of this course, the student will be able to:
2 practical class reports: 15%, 4 written assignments: 20%, mid-semester test: 5%
3-hour written examination: 60%
2 x1 hour lectures, 1 x 1 hour tutorial and 3 hours practical classes.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | G P Simon |
Corrosion of surfaces, chemical and electrochemical properties of interfaces, localized corrosion, protection of surfaces, techniques of protection, organic and inorganic surface treatments, bonding at surfaces, thermodynamics of surfaces and interfaces, adhesion and mechanical properties.
Examination (3 hours): 55%
Practical classes: 15%
Assignments: 30%
48 lecture/tutorials and 3 x 3 hour laboratory experiments per semester and seven hours of private study per week
MTE3510 or MSC3111
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | J F Nie |
This unit deals with structural and chemical changes (phase transformations) at the atomic scale and impacts of such changes on the performance of materials in structural applications. The major strengthening mechanisms involving interactions of dislocations with obstacles are discussed This unit examines the factors that are important in influencing the structural and chemical changes and the principles for microstructrual design. It demonstrates how to use the design principles to manipulate, in a controlled manner, the alloying additions and thermomechanical processing to tailor the properties and thus the performance of materials.
To develop:
Four laboratory classes: 20%
Three written assignments: 30%
Examination (3 hours): 50%
36 hours lectures/tutorials and 4 five-hour laboratory classes during the semester and 7 hours of private study per week
MTE2541 or MSC2011
MTE3502, MSC3121
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | R Lapovok |
This unit explores the relationships between the microstructure and deformation of materials. Metal forming will be linked to the factors that control formability, with yield criteria and constitutive behaviour being examined. Students will engage in finite element analysis of metal processing. Microstructural features governing fatigue, fracture and failure of structures will be explored and the extent to which we can predict failure outlined, including design against failure, critical crack size, low and high cycle fatigue. Microstructural toughening, effects of welds and thermal stability of materials will be addressed in terms of mitigation or minimization of structural defects.
On successful completion of this unit, students will be better able to:
Final examination (3 hours):60%
Assignments and case study report: 30%
Laboratory reports: 10%
Three 1 hour lectures/tutorials per week and seven hours of private study per week. 20 hours of laboratory classes during the semester
MTE3506, MTE4561
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | T Turney |
Students learn to understand the interrelationship of innovation and invention, the generation and exploitation of intellectual property. By following the life cycle of manufactured goods, they see environmental effects and follow obsolescence to waste and the recycling chain. Students learn to use aids to decision making, including the identification of likely critical processes. Entering the manufacturing environment, they receive overviews of quality management and quality control, and the relationship between design, manufacture and product life. They glimpse the major forces governing workplace relations and work place conditions in Australia.
On successful completion of this course students will be able to:
Six written assignments: 80%
Two oral presentations: 20%
24 one-hour lectures, 18 one-hour tutorials and 102 hours of private study throughout the semester
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Kiyonori Suzuki/Assoc Professor Udo Bach |
Electrical and optical properties of materials - dielectrics, ferroelectrics, superconductors and optical fibres; magnetic properties - microscopic origin of magnetism in specific classes of materials, domains, magnet fabrication and applications; nanodevices which rely on the preceding properties, experimental techniques.
To understand the science and technology governing the important properties and uses of the major electrical, optical and magnetic materials and the development of associated nanotechnological devices.
Examination (3 hours): 55%
Assignments: 12%
Laboratory work: 33%
Three one-hour lecture/tutorial classes per week and four x five hour laboratory classes during the semester and 7 hours of private study per week.
MTE2544 or MSC2022 or TRC3800 or MSC2111 of PHS2011
MSC3011, MSC3132, MTE3508
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Wayne Cook/Professor Yi-Bing Cheng |
The importance of ceramic properties on their manufacturing is highlighted. The mechanical and thermal properties of ceramics, the structure and production of amorphous ceramics and porous ceramics, the glass transition, optical and electrical properties of glass. The mechanical properties of polymers are very dependent on the timescale and temperature and so the structural basis of linear viscoelasticity and time/temperature superposition are discussed. The mechanical properties of elastomers, crosslinking and reinforcement, rubber elasticity and the tear and fatigue of elastomers. The Eyring theory and methods of toughening polymers are discussed.
On successful completion of this course students will be able to:
Four written assignments: 20%
Practical classes: 20%
Examination (3 hours): 60%
Three 1-hour lecture/tutorial classes and seven hours of private study per week. 4 x 5-hour practical classes throughout the semester
MTE2541 or MSC2011
MTE3504, MTE3507
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Nikhil Medhekar/Dr Laure Bourgeois |
Metals, ceramics and polymers may be characterised using a number of techniques, and some of these will be explored in this unit. The techniques can be broadly split into direct (imaging, chemical analysis) and indirect (scattering) techniques. The principles underlying techniques such as x-ray diffractometry, electron microscopy, photoelectron or mass spectroscopy and gel permeation chromatography are explained. Students will investigate the design of experiments, testing for relationships among variables and curve fitting. Models will be related to the characterization techniques studied by the application of appropriate models to real data.
Upon successful completion of this unit students will develop skills to be able to:
Examination (3 hours): 50%
Four written assignments: 20%
Laboratory work 30%
3 x 1-hour lecture/tutorial classes and seven hours of private study per week and 4 x 5-hour laboratory sessions throughout the semester
MSC3142
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Christopher Hutchinson/Assoc Professor Chris Davies |
An introduction to the computational/modelling approaches currently available in materials science and engineering is provided. The reasons for using modelling approaches are discussed and the different types of models available are outlined. For each of the length scales important in understanding material behaviour (nano-, micro-, meso- and macro-), the available modelling techniques are outlined and their principles, methods of implementation, advantages, disadvantages and perceived future developments are discussed. Examples of modelling approaches will be selected from all classes of materials. The general methodology used for constructing models is emphasised.
On successful completion of this units students will:
Test: 15%
Minor assignment: 15%
Major assignment: 40%
Examination (2 hours): 30%
Three 1 hour lecture/tutorial classes, one 2 hour practice class and seven hours of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Nikhil Medhekar |
Project in the materials field involving a literature survey, experimental or theoretical program, preparation and an oral defence of a technical poster.
On successful completion of this unit, the student will:
Poster: 10%, risk assessment: 10%, interview: 60% and overall performance: 20%
One hour of consultation with supervisor per week.
Completion of 120 points or permission
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Clayton Second semester 2012 (Day) |
Coordinator(s) | Dr Nikhil Medhekar |
Project in the materials field involving a literature survey, experimental or theoretical program, preparation and presentation of a technical paper.
On successful completion of this unit, the student will:
Public oral presentation: 20%, Report: 40% and overall performance: 40%
One hour of consultation with supervisor per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | W Cook |
This unit is expected to develop discernment of good and poor design and the close relationship between design, manufacture and material, with special emphasis upon practical materials selection. It engenders an appreciation of the role and responsibility of the engineer in management of risk - be it economic or personal (through design, manufacturing and use). The role of materials selection and the impact on function and environment is covered. In addition it looks at the role computers play in all facets of the current engineering environment, including the key areas of design, analysis, machining and robotics. It seeks to give students practical skills in these areas, in particular in the area of computer-aided drafting.
Objectives
To develop:
Design project (60%)
Materials selection assignment (30%)
Computer-based test (10%)
Three 1 hour lecture/practice classes and 9 hours of private study per week
MTE3544 or by permission
MTE4521, MTE4522
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | W D Cook |
This unit deals with the structure, processing and properties of polymers and shows how these aspects determine their use in particular applications. The rheology of polymers are discussed and the factors controlling viscosity are described and related to polymer processing. The thermodynamics of polymer blends and the resulting morphology is related to the mechanical properties. The wide range of polymer additives is reviewed. For composite materials, the types of matrices and fibres/fillers are described as well as composite fabrication and the effect of reinforcement on properties. Designing with polymers and materials selection for properties and applications is studied in detail.
On successful completion of this course students will have:
Four written assignments: 20%
PBLE work: 20%
Examination (3 hours): 60%
3 hours lectures/tutorials and 7.5 hours of private study per week and 3 hours of problem based learning classes every two weeks
MTE4560
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Professor Yi-Bing Cheng/Dr Don Rodrigo |
The first part of this unit will focus on processing of cast and wrought metals. In particular, foundry technology and design of castings, welding and design of weldments and approaches to obtaining high quality 'clean' steel will be addressed. Selection of an appropriate thermomechanical processing schedule in order to achieve the required microstructure and properties of steels will be discussed. The second part of the unit will introduce ceramic processing technologies including green body shaping, solid state sintering, liquid phase sintering, hot-pressing and sol-gel processing. Microstructures of ceramics and their effects on the materials properties will be presented.
To develop:
Two written assignments: 20%
Laboratory classes: 20%
Examination (3 hours): 60%
3 hours lectures/tutorials, 7.5 hours of private study per week and 15 hours laboratory classes per semester
MTE4561, MTE4562, MTE4536
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Christopher Hutchinson/Assoc Professor Chris Davies |
An introduction to the computational/modelling approaches currently available in materials science and engineering is provided. The reasons for using modelling approaches are discussed and the different types of models available are outlined. For each of the length scales important in understanding material behaviour (nano-, micro-, meso- and macro-), the available modelling techniques are outlined and their principles, methods of implementation, advantages, disadvantages and perceived future developments are discussed. Examples of modelling approaches will be selected from all classes of materials. The general methodology used for constructing models is emphasised.
On successful completion of this course students will:
Minor Assignment: 15%
Test: 15%
Major Assignment: 40%
Examination (2 hours): 30%
3 hours lecture/tutorial classes, 2 hours practice class and 7 hours of private study per week
MTE3547 or MSC3142
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | Y-B Cheng |
The first part of this unit will focus on structural ceramics including zirconium oxides, silicon nitride, sialons, silicon carbide and ceramic particulate and fibre reinforced composites, their processing and applications. The crystal structures of the different materials and their properties will be correlated. Examples include cutting tools, wear parts and advanced refractories. The second part of the unit will introduce functional ceramics, predominantly those used in electrical or electronic applications, their microstructure and nanostructure. Examples include thermistors, varistors, capacitors, multi-layer substrates, piezoelectric and electrooptic transducers, and gas sensors.
To develop:
Laboratory work: 15%
Two written assignments: 20%
Examination (3 hours): 65%
3 hours lectures/tutorials, 8 hours of private study per week and 9 hours laboratory classes per semester
MTE4562
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | G Simon |
This unit provides an introduction to the political, social and environment background to materials recycling and looks at motivations for recycling. Major technologies relating to the recycling of metals, plastics, glass, paper and ceramic materials are discussed: involving looking at the choice between materials reclamation, energy recovery and landfill. It considers the economics of materials production, as well as 'cradle-to-grave' analyses of materials including products and by-products of the nuclear fuel cycle. In particular it looks at life-cycle analysis techniques. Market failure in the economics of the environment and the role of externalities and their remedies are covered.
The student will develop an understanding of the economic, social, political and technical aspects of materials recycling, an appreciation of the role of recycling in the broader environmental context, the capacity to undertake life-cycle analysis of products or services, and technical knowledge in the main areas of recycling including polymers, ceramics, metals and paper.
Two written assignments: 25%
Oral presentation: 5%
Tests: 10%
Examination (3 hours): 60%
3 hours lectures/tutorials and 9 hours private study per week
ENE4506
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | C Hutchinson |
Engineering alloys play a vital role in modern society. In almost all structural applications the principle loads are carried by engineering alloys. The reasons underlying this choice are discussed and the general methodology used to choose a material for use in a new application is presented. The link between processing, microstructure and properties is emphasized. A selection of engineering alloys, including steels (carbon, alloy, stainless, dual phase, TRIP/TWIP), cast irons, aluminium, magnesium, titanium, nickel and cobalt-based superalloys and zirconium alloys, is discussed. The state-of-the-art approaches to the design and development of new alloys for the 21st century are outlined.
To develop:
Alloy selection exercise: 25%
Alloy systems project: 25%
Examination (3 hours): 50%
3 hours lectures/tutorials and 9 hours of private study per week
MTE3542 or MSC3121
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | N Birbilis |
Introduction to the typical manifestations and types of corrosion usually found in the field in areas including marine, chemical/manufacture, transport and offshore industries. Emphasis will be placed on identification and recognition of the types of corrosion likely to occur and then taking this further towards developing strategies to mitigate the corrosion. The mechanisms of corrosion in some environments will also be studied, including stress corrosion cracking and microbiologically induced corrosion, corrosion in reinforced concrete based structures. Corrosion mitigation mechanisms will be discussed, including, materials selection, cathodic protection, coatings and inhibitors.
To gain a detailed understanding of corrosion mechanisms and methods of corrosion prevention and protection.
Examination (3 hours): 50%
One written assignment: 20%
Group project: 30%
Three hours lectures/tutorials and 7.5 hrs of private study per week and 15 hours laboratory classes/projects per semester
MTE3541 or MSC3111 or by permission
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor John Forsythe/Dr Qizhi Chen |
Biocompatibility is explored and is related to the foreign body response. The importance of the interfacial properties of biomaterials is covered and includes factors affecting cellular response and protein adsorption. Polymers and ceramics used in medicine are reviewed with examples including the total hip joint replacement (TFJR), heart valves, catheters and vascular grafts and hydrogels used in ophthalomology. Drug delivery devices are reviewed and include degradation mechanisms and kinetics. Biomaterials with biological recognition and smart biomaterials will be studied. Biosensors and examples in bionanotechnology will be investigated. Tissue engineering and scaffold manufacture is covered and the use of stem cells for regenerative medicine reviewed.
Have a basic understanding of the processes involved in the foreign body response and biocompatibility
Appreciate some factors that affect protein adsorption
Understand the different classes of polymeric biomaterials used in the body.
Be familiar with some of the degradation processes of polymers
Describe some methods of drug delivery
Describe the action and use of smart materials
Be familiar with ceramic materials used in body and some aspects of thermal spraying
Understand some techniques used in tissue engineering including some methods of scaffold manufacture
Understand some techniques commonly used to characterise biomaterial surfaces.
Be able to review a journal article and provide a detailed assessment.
Have an ability to communicate within a team, and submit a group assignment.
Examination (2 hours): 50%
Mid-semester test (1 hour): 20%
Individual assignment: 10%
Group assignment: 10%
Laboratory work:10%
2 hours lectures, 1 hour tutorials, 8 hours of private study per week per week and 6 hours laboratory classes per semester
Must have passed 96 credit points
MTE4539, MTE5596
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Dan Li/Assoc Professor Udo Bach/Professor George Simon/Dr Qiaoliang Bao |
This unit aims to develop an understanding of synthetic methods, properties and applications of nanomaterials and nanofabrication techniques. The nanomaterials include zero-dimensional nanoparticles, one-dimensional nanostructures (nanotubes, nanorods, nanowires and nanofibres) and two-dimensional thin films and nanocomposites. Principles of nanofabrication such as lithography and self-assembly will be introduced. The unit will stress the design of properties and devices based on biomimicry. It will highlight the importance of nanostructured materials in a range of areas such as sensors and energy-related applications.
On completion of this unit, students will:
Projects: 20%, Individual tests: 20%, Lab experiments: 10%
Closed book examination (3 hours): 50%
2 hours lectures, 2 hours of practice sessions, 1 hour of laboratories and 7 hours of private study devoted to preparation of assignments and independent study per week.
MTE2541 or MSC2011
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | J Etheridge |
This unit will reveal how electron microscopy can be used to determine the
structure and chemistry of a material from the micron to the atomic scale. It
will cover methods for the determination of atomic structure, chemical
composition and bonding, 3D structures, surface morphology and
topography, orientation-relationships and electronic and magnetic structures.
These methods will be illustrated with applications, for example, to
nanomaterials, alloys, ceramics, catalysts, polymers and electronic
materials. The course will cover the theory, methodology and application of
both scanning and transmission electron microscopy and will incorporate
practical sessions in front of electron microscopes.
On completion of this unit, students will:
Two laboratory reports: 20% each
Closed book examination (3 hours): 60 %
2 hours lectures, 1 hour of tutorial classes, 6 hours of private study per week and 26 hours of laboratories per semester (in 3 sessions).
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) |
Coordinator(s) | B Winther-Jensen |
Materials used in energy production, storage and conversion will be described in detail. These include: light harvesting materials; solar power conversion efficiency; interaction of light with matter; inorganic semiconductor cells, organic (and hybrid) solar cells, dyesensitized solar cells; electrocatalytic materials and applications in fuel-cells, dye-sensitized solar cells and water-splitting; photo-(electro)-catalysis and modern battery systems, Li-ion cells and Li metal cells, metal-air batteries, flow batteries, advanced electrolytes; principles in capacitors, carbon materials, nanotubes graphine, mesoporous materials; hydrogen storage materials and electrochemical methods.
Upon successful completion of this unit, students will:
Two 3-hour practical classes: 15%, two written assignments: 15%, One 1-hour mid-semester test: 10% and 3-hour written examination: 60%.
3 lectures/tutorials per week, a total of 2 three hour laboratory sessions each requiring three hours report preparation (1hr per week), 8 hrs of private study per week.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Gippsland First semester 2012 (Day) |
Coordinator(s) | Mr Phillip Higgins |
PHS1711 assumes a mathematical background of VCE maths methods 3 and 4 or equivalent. It is designed for students that have an interest in physical computations and the practical applications of physical principles. Topics covered in this unit include: description of linear motion, statics and equilibrium, simple machines dynamics and kinematics of motion in two dimensions, work, energy and energy conversion, momentum, rotational motion, properties of materials with applications, basic concepts of waves and their role in the transport of energy and information, acoustics, introduction to fluid statics and dynamics, principles of electricity, electrical measurement and monitoring.
On completion of this unit students should be able to: apply linear kinematic relationships, involving scalars and vectors to analyse typical situations encountered in engineering applications; apply the linear and rotational requirements for equilibrium to examine static mechanical structures and the operation of simple machines; apply the concepts of stress and strain to a material under load; use the principles of rotational dynamics to determine and predict the behaviour of fixed-axis rotating systems, including flywheels and turbines; apply Archimedes' and Pascal's principles and Bernoulli's theorem to analyse streamline fluid flow; apply the principles of harmonic motion to vibrating systems and predict the features of damped and forced oscillations; analyse and predict the behaviour of waves in various media, including adsorption of acoustic waves, scattering by reflection, refraction and diffraction; analyse simple DC circuits involving series and parallel resistors and describe the properties and circuit influences of capacitors and inductors; recognise the role of measurement, sensors and monitoring systems and the limitations inherent in instruments and their usage.
Written examinations 70%
Laboratory projects and reports 30%
39 hours lectures/tutorials plus 36 hours of laboratory work for the semester, and 6 hours per week of private study.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | R Russell |
Design of machine elements: bearings, shafts, welds, fasteners, gears etc. Techniques for improving mechatronic designs based on economic and functional consideration. Geometric tolerancing. The use of solid modelling in the simulation of kinematic behaviour of mechatronic devices and in the production of engineering drawings. Integration of studies in the group-design of a mechatronic device.
This unit provides a focus in level 2 of the mechatronics program where studies from the first semester are integrated into whole mechatronic design tasks involving a combination of individual and group work. Additional mechanical elements are included in this unit so that moderately complex mechatronic devices can be designed and evaluated theoretically by using conventional mathematical techniques, and geometrically and kinematically by constructing virtual devices in solid modeling software.
Tutorial work: 10%
Assignments: 60%
Examination (2 hours): 30%
3 hours lectures, 2 hours laboratory/tutorial and 7 hours of private study per week
TRC2100 or MEC2402
MEC2450, MEC2406
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Prabhakar Ranganathan (Clayton); Dr Darwin Gouwanda (Sunway) |
This unit provides the discipline basis for applications in energy, power and motive force where fluids are involved. It also provides a basic level of knowledge and problem solving capability in heat transfer. These disciplines are central to mechanical engineering and, as a consequence, are essential knowledge for mechatronic engineers whose designs usually have mechanical elements. Also, they provide the basis for the use of hydraulic and pneumatic power as motive forces, which also form an important part of the unit content.
To understand the concepts of thermo-fluid properties, systems and control volumes. To be able to analyse thermodynamic processes and simple cycles. To be able to calculate hydrodynamic forces on in static fluids or those in rigid body motion. To be able calculate fluid flow in pipes, including pumps, valves and other fittings. To be able to analyse and design the elements of fluid and pneumatic control systems.
Assignments: 30%
Tests: 20%
Examination: 50%
Students are required to achieve at least 45% in the total continuous assessment component (assignments, tests, mid-semester exams, laboratory reports) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 2 hours of problem solving classes or laboratories and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | Z Liu (Clayton); D Gouwanda (Sunway) |
Kinematics: position, velocity and acceleration; relative motion analysis and applications for particles and rigid bodies; Dynamics: translational and rotational motion of free and constrained forces, their origin and significance; equation of motion, principle of impulse and momentum, principles of work and energy; Analysis of planar motion. Fundamentals of mechanical vibrations. Strength of materials: stress and strain in 2D and 3D space; Hookes law; Shear force and bending moments, moments of area, deflection of beams; Equilibrium and compatibility equations; Stress and strain transformation; Mohr circle; Simple failure criteria; Elastic instability --- buckling.
On completion of this units students should be able to:
Test/Class work: 30%
Examination (3 hours): 70%
3 hours lectures, 3 hours of practice/laboratory classes and 6 hours of private study per week
Must have passed 42 credit points
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Mrs Ros Rimington/H Chung (Clayton); Dr Madhavan Shanmugavel (Sunway) |
Students will learn the planning and communication skills required to undertake a group project. An introduction will be given to the evolution of mechatronic technologies, design tools and methodologies, concurrent engineering design support tools, mechatronic design process and requirement interpretation. The acquisition of these skills will be motivated and tested by applying them in a group project to design and build a mechatronic system. The mechatronic system will be based on a microcontroller together with appropriate mechanical structure, sensors and actuators.
The aim of this unit is to provide a focus in the second semester of level 3 of the mechatronics program where studies from the earlier stages of the course are integrated into whole design tasks involving group work. Additional project management elements including planning, management and documentation are included in this unit. The application of project management techniques to the level 3 project will provide additional context and motivation for this material.
Examination (2 hours): 30%
Tutorial work: 10%
Assignments: 60%.
Associate Professor Bijan Shirinzadeh
Lectures: 2 hours per week
Laboratory classes: 3 hours per week
Tutorial: 1 hour per week
Private study: 6 hours per week
(TRC2000 or MEC2406) and (TRC3300 or ECE3073)
ECE3905
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | tba (Clayton); Dr Madhavan Shanmugavel (Sunway) |
Instruction on the basics of dynamics of mechatronic systems, incorporating electromagnetics into advanced dynamics analysis via D'Lambert's principle, Hamiton's equations and the virtual power (Jourdain/Kane) method. Focus on applications of dynamics in mechatronics, with kinematics and dynamics of robotic structures, magnetoelectromechanical transducers (motors, speakers, vibration sensors, and so on). Consideration of the inevitable and critical consequences of nonlinearities in dynamic response, including limit cycles and Poincar maps and flows. Reinforcement of concepts using laboratory experiments and computer analysis on simple mechatronic systems.
Students are to gain the ability to model the dynamics of systems incorporating mechanical, electrical, magnetic, and other forms of energy storage and interaction, with consideration of the consequences of nonlinear behavior. Experimental and computational work will provide the student with a reinforced understanding of mechatronic dynamics.
Examination (3 hours): 70%
Laboratory work: 20%
Written assignments:10%.
Associate Professor Bijan Shirinzadeh
3 hours lectures, 3 hours laboratory/tutorial classes and six hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) |
Coordinator(s) | J Li (Clayton); K Chetty (Sunway) |
The unit provides an introduction to transducer principles and the background to classify them in terms of performance and characteristics. A range of commonly available sensors are considered. Electronic components and data acquisition/digital signal processing software used in sensor systems are examined. Advanced sensory systems and associated programming techniques are introduced using robotic systems as an example domain.
The student is expected to acquire an understanding of transducer principles and to be able to evaluate sensors in terms of their performance and characteristics. They should be able to develop a complete sensory system including specifying the electronic components required and programming data acquisition and signal processing functions. Students should gather an appreciation of advanced sensory techniques used in robotics and be familiar with their implementation and programming requirements.
Examination (3 hours): 70%
Laboratory work: 20%
Written assignments: 10%
Students are required to achieve at least 45% in the total continuous assessment component (Laboratory reports, mid-semester exams) and at least 45% in the final examination component and an overall mark of 50% to achieve a pass grade in the unit. Students failing to achieve this requirement will be given a maximum of 45% in the unit.
3 hours lectures, 3 hours laboratory/practice classes and six hours of private study per week.
TRC2500, ECE2061
TRC3300
ECE4306, GSE3801
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Chao Chen (Clayton); Dr Edwin Tan (Sunway) |
Instruction on automatic control of electromechanical systems, including analysis, experimental, and computational techniques (with Matlab/Simulink). Control system design through state-space for application to mechatronics, with particular focus on compensators, controllability and observability.
Students are expected to gain the ability to model and control mechatronics systems through analysis, computational, and experimental methods; master the fundamentals of modern and digital control theories in order to apply them to the design of control systems, and understand the significance and difficulty associated with nonlinear phenomena in control system design.
Written assignments:10%
Laboratory work: 20%
Examination (3 hours): 70%
3 hours lectures, 3 hours laboratory/tutorial and six hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Assoc Professor Raafat Ibrahim (Clayton); Professor S G Ponnambalam (Sunway) |
Manufacturing Operations, Models and Metrics. Automation and NC/CNC. Material Transport and storage systems. Manufacturing Systems: Single cell, Assembly line, Cellular Manufacturing and Flexible Manufacturing systems. Manufacturing Support Systems: CAD/CAM/CIM, Process planning, Production planning including material requirement planning, manufacturing resource planning, shop floor control, inventory control.
Manufacturing excellence: push/pull systems, pull control systems, JIT, TQM, simulation of manufacturing systems.
Students are to gain an understanding of the manufacturing systems taxonomy, manufacturing systems, CNC Programming, Cellular and Flexible Manufacturing Systems, Material Transport and storage systems, manufacturing support systems such as process planning, production planning and control. Students also learn modern manufacturing systems such as, pull systems (KANBAN and CONWIP), and Just-In-Time systems and to evaluate manufacturing systems using simulation.
Laboratory work and assignments: 30%
Examination (3 hours): 70%
3 hours lectures, 2 hours laboratory classes, 1 hour tutorial classes and 6 hours of private study a week
TRC2100, MEC2402
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Josie Carberry (Clayton); Dr Kuppan Chetty Ramanathan (Sunway) |
The aim of this capstone unit is to provide an opportunity for students to undertake a substantial individual or small group project. In order complete the project studies from earlier stages of the course will be integrated into a complete design/build/test task, a computer modelling or simulation task or a combination of both. It is envisaged that the project may involve design of mechanical components, sensing, actuation and computing elements, a simulated model or similar. Before work is started on the project a safety induction and/or risk assessment process will be completed. The student will also complete a research proposal or requirements analysis to ensure that the scope and expected outcomes of the project are agreed between student and supervisor. A progress report and a progress presentation at the end of the semester will give a detailed account of progress and a research plan for the next semester.
Students will gain the experience of designing, building and testing a mechatronic hardware or simulated system. In doing this they will strengthen their ability to perform self-directed study. The interaction and tradeoffs between different elements of a mechatronic system will become clearer. Students will learn to plan their work and make effective use of their time. Overall the project will help to integrate knowledge gained in units completed earlier in the mechatronics course program.
Full semester project based work: Panel assessment of the achievement of the student in the project, as evidenced by a presentation and written report (100%).
Associate Professor Bijan Shirinzadeh
12 hours week of engagement in project activities.
132 credit points completed including TRC3000.
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway First semester 2012 (Day) Clayton Second semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | Dr Josie Carberry (Clayton); Dr Kuppan Chetty Ramanathan (Sunway) |
The aim of this capstone unit is to provide an opportunity for students to undertake a substantial individual or small group project with a strong mechatronics content. In order complete the project studies from earlier stages of the course will be integrated into a complete design/build/test task. It is envisaged that the project will involve design of mechanical components, sensing, actuation and computing elements.
Students will gain the experience of designing, building and testing a mechatronic hardware or simulated system. In doing this they will strengthen their ability to perform self-directed study. The interaction and tradeoffs between different elements of a mechatronic system will become clearer. Students will learn to plan their work and make effective use of their time. Overall the project will help to integrate knowledge gained in units completed earlier in the mechatronics program.
Full semester project-based work: 100% including a written report submitted towards the end of semester and other criteria as decided by the department offering the thesis project. The assessed mark will be combined with the mark for TRC4000 to arrive at an overall mark for the two units.
Associate Professor Bijan Shirinzadeh
12 hours week of engagement in project activities.
TRC4000 in the previous semester
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton Second semester 2012 (Day) |
Coordinator(s) | Mrs Ros Rimington |
This unit provides an introduction to aspects of management relevant to the needs of the professional mechatronics engineer. Students will be introduced to a range of topics including the role of a manager, organizations, financial management, marketing and planning, legal issues and professional ethics.
The aim of this unit is to provide a broad introduction to aspects of management relevant to a professional mechatronics engineer. Theoretical concepts will be introduced followed by practical applications and skill development. Students will develop an understanding of the nature of the business environment and learn basic skills in several key areas of management.
Assignments: 30%
Examination (3 hours): 70%
3 hours week lectures and 2 hours week tutorials and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | A Senanayake (M'sia) |
Studies from earlier stages of the course are integrated in such a way that students will gain knowledge and skills in the development of movement analysis system. Fundamental devices of bio-electronic devices and phases involved in product development are covered. Bioinstrumentation for measurements of key parameters involved in the use of bio-interfacing devices is addressed based on virtual technologies. Basic elements required for bio-interfacing devices in movement analysis, sensors and vision are considered. In order to downolad acquired data/signals from sensors and vision, specific Data Acquisition (DAQ) methods will be analysed and tested. Students will be taught synchronisation of signals and data as the critical issue. Based on synchronized data signals, movement model reconstruction will be essential in order to understand the motion. Finally, motion regeneration will be created based on the movement data measured and preprocessed.
After completion of this unit, students should be able to:
Assignments: 30%
Tutorial work: 10%
Examination (3 hours): 60%
Lectures: 2 hours per week
Laboratory: 3 hours per week
Practice class: 1 hour per week
TRC2400 or ECE2071 or MEC2407 and 96 credit points and all first level units completed
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Clayton First semester 2012 (Day) Sunway Second semester 2012 (Day) |
Coordinator(s) | tba (Clayton); Dr S Parasuraman (Sunway) |
The unit will cover fundamentals of robotics and robotic automation. The contents include: Spatial descriptions and transformations, manipulator forward and inverse kinematics, differential relationships and the Jacobian. Manipulator dynamics. Problem specification and solution preparation. Manipulator and end-effector configuration and design. Manipulator position control, involving sensing and actuation. Robotics in manufacturing and automation. Task Planning and techniques for modelling, simulation and programming of robotic tasks. Computational geometry for design and manufacture. Introduction to autonomous systems.
Students are expected to gain the ability to appreciate, design and analyse robotic mechanisms. This will involve consideration of manipulator kinematics and dynamics. They will gain familiarity with techniques for modeling, simulation and programming of robotic tasks. The students will become familiar with applications of autonomous robotic systems including advanced forms of robot sensing.
Examination (3 hours): 70%
Laboratory work and written assignments: 30%
2.5 hours lectures, 2.5 hours laboratories/tutorials and 7 hours of private study per week
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Not offered in 2012 |
Coordinator(s) | K Chetty (Sunway) |
This unit will introduce students to hardware/software systems and codesign philosophy for Systems-on-a-Chip (SoC). Material on behavioural design, architecture selection, partitioning, scheduling, and communication will be covered. Design methodologies and tools including Hardware Description Languages (HDLs) and methods for system testing and verification will be introduced. The concept of intellectual property, reuse and verification will be presented. Examples and case studies from mechatronics related industries in Malaysia will be examined and SoC prototype product development will be investigated in hands-on laboratory exercises.
Students are expected to gain knowledge of real-time embedded systems for real world applications. They will learn about software/hardware integration and I/O programming. State-of-the-art SoC platforms and emerging embedded system development tools will be introduced. Integration of hardware modules to construct embedded systems, and the programming models and characteristics of various input/out interfaces will be emphasised. Students will develop an understanding of how assembly language, high-level languages and Hardware Description Languages (HDLs) can be chosen to meet computation, resource, software development requirements.
Tutorial work: 10%
Assignments: 30%
Examination (3 hours): 60%
Associate Professor Bijan Shirinzadeh
2 hours week lectures, 3 hours week laboratory/tutorials and 7 hours week of private study
TRC3300
Refer to the specific census and withdrawal dates for the semester(s) in which this unit is offered, or view unit timetables.
Level | Undergraduate |
Faculty | Faculty of Engineering |
Offered | Sunway First semester 2012 (Day) |
Coordinator(s) | S Parasuraman (Sunway) |
This unit provides a systematic approach of solving a variety of engineering problems using artificial intelligence techniques including fuzzy logic, artificial neural networks and genetic algorithms. The theory and applications of these soft computing techniques will be considered. Students will learn AI methods of problem solving. The AI language LISP will be introduced. The Matlab fuzzy logic, neural network and genetic algorithm toolboxes will be used to solve engineering problems.
The aim of this unit is to introduce the principles of artificial intelligence and soft computing techniques and shows how these techniques can be applied to solve a wide variety of engineering problems. Students will develop an understanding of and confidence in applying such artificial intelligence techniques as neural networks, fuzzy logic systems and genetic algorithms.
Mid semester test: 10%
Practice assessment(lab): 20%
Examination (3 hours): 70%
Associate Professor Bijan Shirinzadeh
2 hours of lectures, 3 hours of practice classes and 7 hours week of private study by the student
TRC3300
ECE4708, ECE5708, GSE4703