ENGG1000 is a unique course that aims to provide students with an understanding of the historical development of Engineering with relation to societal expectations of the period. Engineering as a field of study and profession has developed over millennia from simple (yet significant) advances in technology such as the lever and wheel, to modern day examples such as advanced computers, nanomaterials and space flight.
Interaction between human society and Engineers has helped develop and guide the advancement of engineering technology; with society posing problems for Engineers to solve and Engineers developing new technology that changed the course of human history, and helped shape the world we live in.
The general philosophy behind Engineering is that Engineers work to fulfil the needs of society (water, electricity, technological improvements etc.), and as such Engineers are expected to act ethically towards society. The role of Engineers in society will be analysed and discussed from a humanistic perspective, with relation to the current Engineers Australia code of ethics. Other relevant philosophical analyses of Engineering as a skill and profession will also be examined such as, aesthetics, creativity, the epistemology of Engineering and more.
This course will use online resources extensively and help develop research and communication skills of students, whilst providing an overview of the historical significance of Engineers in society, and what it means to be an Engineer.

This unit introduces students to specialisations in the Engineering discipline areas of Aeronautical, Biomedical Chemical, Civil, Mechanical and Mechatronic Engineering, and Project Engineering and Management. By providing first-year students with an experience of these various engineering streams, the unit aims to develop the students' professional identity as an engineer and thus provide a suitable basis on which students can choose their discipline for further study.
Introductory sessions in the School of Aerospace,
Mechanical and Mechatronic Engineering
-4 weeks-
An overview of the degree requirements in each stream. The roles of the engineer in each stream (employments, skills, etc). How each of the subjects taught relate to the skills/knowledge and applications required of the engineers. Basically make sure students fully understand what engineers are in the discipline areas and why the students do the subjects they do. In each stream, one engineering technical topic will be taught as a problem solving exercise, and this topic will be the focus of the laboratory.
School of Civil Engineering
-4 weeks-
Introductory lectures in Engineering Economics and Construction Planning, Foundation Engineering, Structural Engineering, Materials, Environmental Engineering. Each student will be involved in the erection and dismantling of an 8 metre high steel and timber tower in the Civil Engineering Courtyard. Preliminary lectures related to the tower will include safety issues, loading, statical analysis, foundation calculations, construction management, engineering drawings and detailing, geometric calculations, and survey measurements. Exercises related to these issues will be performed before assembly and disassembly of the tower.
School of Chemical and Biomolecular Engineering
-4 weeks-
This course will enable students to gain an appreciation of: the methods and materials of construction of items of process equipment; the role of this equipment in building an entire chemical processing plant: its operation and maintenance and safety requirements and procedures. Students will dismantle, disassemble and operate items of process equipment. They will present written answers to questions, supplemented by drawings of process flowsheets, diagrams of dismantled equipment, and discussions of heat and mass balances and of process parameters.

The unit will introduce students to fundamental principles of programming. The language used will be Matlab but the principles taught are readily portable to other languages like C and Java. The unit material will be presented in a manner which will help students to draw a connection between programming constructs and real engineering applications. The unit will use engineering inspired case-studies : especially from Civil, Chemical, Aerospace and Mechanical streams, to motivate new material. There will be a major project which uses programming to solve a real world engineering problem. The extensive Matlab library for visualization will also be introduced. Matlab will cover two-thirds of the unit. The remaining one-third will be devoted to the use of Excel in engineering scenarios. Furthermore, cross integration between Matlab and Excel will also be highlighted.

The unit aims to provide students with an understanding of and competence in solving statics and introductory dynamics problems in engineering. Tutorial sessions will help students to improve their group work and problem solving skills, and gain competency in extracting a simplified version of a problem from a complex situation. Emphasis is placed on the ability to work in 3D as well as 2D, including the 2D and 3D visualization of structures and structural components, and the vectorial 2D and 3D representations of spatial points, forces and moments. Introduction to kinematics and dynamics topics includes position, velocity and acceleration of a point; relative motion, force and acceleration, momentum, collisions and energy methods.

Professional Engineering 1 is an introductory Unit of Study within the Faculty of Engineering. The semester 1 course is aimed at students from the School of Aerospace, Mechanical and Mechatronic Engineering. It seeks to introduce newly admitted undergraduates to general principles of professional engineering practice, a range of contemporary professional engineering issues, plus outline skills related to academic study within an engineering environment. The subject is structured around a team based design and build project, in which students apply the professional engineering concepts they are learning to an engineering project. Professional engineering topics to be covered include: accessing information, teamwork, creativity, leadership, written and oral communication, project management, problem solving, ethics, liability, occupational health and safety and environmental issues.

ENGG1805 aims to introduce students to the fundamental principles that underlie the study of engineering and information technologies. It lays the foundation for later studies, and presents to the students challenges common to a multidisciplinary engineering environment. The subject also provides students with the opportunity to develop an understanding of engineering ethics and of working as a part of a team. Professional Engineering and IT (6CP) is composed from the following five parts: (a) Introduction to engineering: the engineer as problem solver, critical analysis of greatest engineering achievements and failure. (b) Introduction to common engineering software tools: word processors, Matlab, LABView. (c) Ethics and workplace health and safety. (d) Testing - concepts of destructive and not destructive tests will be given on samples. (e) "Meet the professionals" - A selection of guest speakers will address students on the most important aspects of the engineering profession. (f) Design Process - The process of design synthesis as an important part of engineering: students will be required to complete an engineering design (from conception, to implementation and testing) maintaining a proper lab-notebook.

Organisations today are heavily reliant on projects as part of their daily operations. A project is a temporary endeavour undertaken with limited resources to achieve organisational goals that are linked to broader organisational strategies and missions. Project management is therefore the process of planning, scheduling, resourcing, budgeting and monitoring the various phases of a project.
"Introduction to Project Management" is an introductory course that teaches students essential principles and concepts of project management, its application and related technologies. Students will learn about the project organisation, its structure, and role of the project manager, project sponsor and project committee. In addition, students will also learn how to identify business problems that require project-based solutions, how to select and evaluate projects, develop a business case, and manage the project at a basic level.
At completion of the course, students will have a high-level understanding of project management concepts, which equips them with basic technical and managerial skills required for project-based organisations.

The BE requires students to obtain industrial work experience of twelve weeks duration (60 working days) or its equivalent towards satisfying the requirements for award of the degree. Students are recommended to undertake their work experience in the break between Year 3 and 4, however any engineering work taken after Year 2 may be accepted for the requirements of this unit.
Students must be exposed to professional engineering practice to enable them to develop an engineering approach and ethos, and to gain an appreciation of engineering ethics. and to gain an appreciation of engineering ethics.
The student is required to inform the Faculty of any work arrangements by emailing the Undergraduate Administration Office of the Faculty of Engineering and Information Technologies prior to the commencement of work. Assessment in this unit is by the submission of a portfolio containing written reports on the involvement with industry. For details of the reporting requirements, go to the faculty`s Practical Experience web site.