This unit is an essential starting point for engineers to learn the knowledge and skills of computer programming, using a procedural language.Crucial concepts include defining data types, control flow, iteration, and functions. Studentswill learn to translate a general engineering problem into a computer program. This unit trains students in the software development process, which includes programming, testing and debugging.

Calculus is a discipline of mathematics that finds profound applications in science, engineering, and economics. This unit investigates differential calculus and integral calculus of one variable and the diverse applications of this theory. Emphasis is given both to the theoretical and foundational aspects of the subject, as well as developing the valuable skill of applying the mathematical theory to solve practical problems. Topics covered in this unit of study include complex numbers, functions of a single variable, limits and continuity, differentiation, optimisation, Taylor polynomials, Taylor's Theorem, Taylor series, Riemann sums, and Riemann integrals.
Students are strongly recommended to complete MATH1021 of MATH1921 before commencing MATH1023 or MATH1923.

MATH1002 is designed to provide a thorough preparation for further study in mathematics and statistics. It is a core unit of study providing three of the twelve credit points required by the Faculty of Science as well as a Junior level requirement in the Faculty of Engineering.
This unit of study introduces vectors and vector algebra, linear algebra including solutions of linear systems, matrices, determinants, eigenvalues and eigenvectors.

Integrated Engineering 1 provides students with an understanding of the nature and diversity of engineering practice and begins the development of a set of intellectual tools for integrating their ongoing personal, academic, and professional development.
An open-ended design project is used to highlight foundational engineering and professional practice skills, and the application of these skills to real world projects and workplace practice. The project demonstrates the role that various professional and academic competencies play in the ability to manage contemporary professional engineering issues.
Through developing their knowledge of the engineering discipline, students enhance their capacity for lifelong learning through critical reflection and self-assessment, creating and monitoring career goals as well as building a sense of responsibility for their learning. Through case studies, design projects and challenges, students expand their communication skills, develop competency in team-based problem solving and creating innovative solutions, as well as apply critical thinking and inquiry. These activities also develop student's research skills and enable them to experience the engineering design process, manage projects, and appreciate the significance of ethics, safety and sustainability.
Dalyell students may enrol in ENGD1000 Building a Sustainable World in place of ENGG1111.

The BEHonours degree (and all associated combined degrees) requires all students to develop a deep understanding of the professional and social contexts in which their engineering knowledge can be applied, and how this context shapes the application of their knowledge. This involves a strong engagement with the practice of their profession and ensuring that they are responsive to the needs and context of industry and community. This engagement is met through the completion of the PEP - Professional Engagement Program - a degree-long integrated program of professional development activities that involves students in contextualising their learning, progressively taking greater responsibility for their own development, and building the foundations of a strong professional engineering career. Once students have completed the requirements of the first stage of the Professional Engagement Program they will pass PEP1.

This unit of study introduces students to the role of professional aerospace engineers, along with the development of fundamental engineering knowledge and skills for aerospace vehicle design, analysis performance and operation. Students will learn through experience, to develop professional skills in research, interpretation, communication, and presentation of information relating to aerospace engineering. Expected learning includes: introduction to lateral thinking concepts; glossary of aerospace vehicle components and terminology; an introduction to the multiple disciplines related to aerospace engineering, such as aerodynamics, aircraft and spacecraft performance, mechanics of flight, aerospace structures, materials and propulsion systems; how the various disciplines are integrated into the design and development of flight platform systems; the operating characteristics of modern flight vehicles, their uses and limitations; modern developments and future trends in aerospace; the limitations of the aerospace environment; teamwork; and resource management.
Significantly, professional enhancement is introduced through the development of basic hands-on workshop skills. These practical skills enable students to have a better appreciation of the tools that they are expected to apply their engineering knowledge to, during their aerospace engineering profession. Experiential learning is facilitated through developing skills with machine and hand tools; solid modelling; and microcontrollers in a supervised environment, to develop fundamentals of practical aerospace vehicle component design, manufacture, control, servicing, and repair.
Manufacturing Technology: An overview of a range of processes related to the design and manufacture of aerospace components is provided through hands-on experience. Manufacturing Technology practical work is undertaken in: (a) Hand tools, Machining, and Fibreglassing - an introduction to basic manufacturing processes used to fabricate aerospace engineering hardware. Safety requirements: All students are required to provide their own personal protective equipment (PPE) and comply with the workshop safety rules provided in class. Students who fail to do this will not be permitted to enter the workshops. In particular, approved industrial footwear must be worn, and long hair must be protected by a hair net. Safety glasses must be worn at all times. (b) Solid Modelling - the use of computer aided design (CAD) tools to model geometry and create engineering drawings of engineering components. (c) Microcontrollers - ubiquitous in modern engineered products - will be introduced through experiential learning with development kits.

Biomedical Engineering 1A introduces students to the exciting interdisciplinary field of Biomedical Engineering through lectures from experts in the key thematic areas of Biomedical Engineering, and practical hands-on training that every Biomedical Engineer needs to know. Areas you will cover include: (i) Medical Imaging; (ii) Biomaterials and Tissue Engineering; (iii) Nanomaterials and Nanotechnology; (iv) Medical Devices and Sensors; (v) Biomechanics and Computational Biomedical Engineering; (vi) Biomanufacturing; and (vii) Bionics and Neuromodulation.
You will also complete two major assignments. Assignment 1 is the BMET1960 CANNES (creatively argued no-nonsense ethics scenarios) Film Festival, in which you will develop a persuasive position on a biomedical ethical scenario with your peers and present it creatively in a video. In Assignment 2 you will explore one of the areas of Biomedical Engineering that interests you and present a hypothetical "game-changing" technical report for the field.
The quizzes, assignments and exam make up 60% of the total assessment. The remaining 40% comprises practical work (the Manufacturing Technology Workshop) involving a range of hardware and software skills vital to your future work as an engineer.
We hope this introductory unit stirs your passion and interest in the exciting field of Biomedical Engineering!

This unit will introduce students to the profession of chemical engineering. It will give students an appreciation of the variety of the chemical and process industries, their history, the economic importance and the scale of their operations both in Australia and globally.
The unit will make use of virtual process plants and industrial leaders as guest speakers.

The objective of this unit of study is to introduce students to the field of civil engineering and its areas of specialisation: structural engineering, environmental engineering, geotechnical engineering, construction management, transportation engineering, and humanitarian engineering. The unit will cover basic physics concepts relevant to civil engineering. The unit will equip students with knowledge of foundational civil engineering tools and techniques such as the identification and calculation of loads on structures, structural systems, and load paths in structures. The unit covers design and construction issues related to the use of standard materials such as steel, concrete, and timber. The unit includes several design tasks and a design project with an emphasis on issues associated with the impact of civil infrastructure on the natural environment, the economy, and social and humanitarian outcomes. The topics will provide a sound foundation for the further study of civil infrastructure design, analysis, construction, and maintenance.

This unit of study aims to expose the students with fundamental (basic) concepts of different specializations within electrical engineering and give them hands on experience to develop the required engineering skills. The unit is based on extensive laboratory work covering Measuring skills using basic electrical instruments, Soldering skills to make electronic circuits and test them, Computer programming skills including real time programming and simulation programming, Use of internet technology, Wireless technology, Renewable energy technology.

Objectives:
a) To develop an understanding of the role of Mechanical Engineers and the core concepts within the discipline.
b) To understand the content of the degree structure and how the subjects are applied.
c) To develop an understanding of a range of machining and manufacturing processes required to make mechanical components.
Introductory Mechanical Engineering (60%): The subject introduces the core mechanical engineering concepts of design and mechanisms, intelligent systems, applied materials and fluid machinery. An overview is provided of the range of roles and the skills and knowledge required of a Mechanical Engineer. Emphasis is placed on the relationship between the subjects in the degree program and how they are applied by practicing engineers.
Manufacturing Technology (40%): An overview of a range of processes related to the design and manufacture of aerospace components is provided through hands-on experience. Manufacturing Technology practical work is undertaken in: (a) Hand tools, Machining, and Welding - an introduction to basic manufacturing processes used to fabricate mechanical engineering hardware. Safety requirements: All students are required to provide their own personal protective equipment (PPE) and comply with the workshop safety rules provided in class. Students who fail to do this will not be permitted to enter the workshops. In particular, approved industrial footwear must be worn, and long hair must be protected by a hair net. Safety glasses must be worn at all times. (b) Solid Modelling - the use of computer aided design (CAD) tools to model geometry and create engineering drawings of engineering components. (c) Microcontrollers - ubiquitous in modern engineered products - will be introduced through experiential learning with development kits.

This unit of study aims to introduce students to the fundamental principles that underlie the study of mechatronic engineering. It lays the foundation for later studies, including advanced mechatronic engineering, computing, control and system design courses. The subject also provides students with the opportunity to develop an understanding of a range of machining and manufacturing processes required to make mechanical components.
Introduction to Mechatronic Engineering (60%): (a) Introduction to mechatronics and to the structure of the BE in Mechatronic Engineering. (b) Systems Modelling and Control - Fundamental concepts which underlie the modelling and control of dynamic systems. (c) Design Process - The process of design synthesis as an important part of engineering. (d) Actuators - Components that exert effort to accomplish a given task. (e) Sensors - Components that take measurements of the environment. (f) Computers - Hardware and software components that, when combined, allow a system to be controlled. (g) Advanced Topics - Case studies relating to the application of mechatronic engineering principles.
Manufacturing Technology (40%): An overview of a range of processes related to the design and manufacture of aerospace components is provided through hands-on experience. Manufacturing Technology practical work is undertaken in: (a) Hand tools, Machining, and Soldering - an introduction to basic manufacturing processes used to fabricate mechatronic engineering hardware. Safety requirements: All students are required to provide their own personal protective equipment (PPE) and comply with the workshop safety rules provided in class. Students who fail to do this will not be permitted to enter the workshops. In particular, approved industrial footwear must be worn, and long hair must be protected by a hair net. Safety glasses must be worn at all times. (b) Solid Modelling - the use of computer aided design (CAD) tools to model geometry and create engineering drawings of engineering components. (c) Microcontrollers - ubiquitous in modern engineered products - will be introduced through experiential learning with development kits.

This is a shell unit to enable Flexible First Year students to complete their Semester 2 enrolment.

This is a shell unit to enable Flexible First Year students to complete their Semester 2 enrolment.

This is a shell unit to enable Flexible First Year students to complete their Semester 2 enrolment.

Calculus is a discipline of mathematics that finds profound applications in science, engineering, and economics. This unit investigates multivariable differential calculus and modelling. Emphasis is given both to the theoretical and foundational aspects of the subject, as well as developing the valuable skill of applying the mathematical theory to solve practical problems. Topics covered in this unit of study include mathematical modelling, first order differential equations, second order differential equations, systems of linear equations, visualisation in 2 and 3 dimensions, partial derivatives, directional derivatives, the gradient vector, and optimisation for functions of more than one variable.
Students are strongly recommended to complete MATH1021 of MATH1921 before commencing MATH1023 or MATH1923.

In a data-rich world, global citizens need to problem solve with data and evidence based decision-making is essential in every field of research and work. This unit equips you with the foundational statistical thinking to become a critical consumer of data. You will learn to think analytically about data and to evaluate the validity and accuracy of any conclusions drawn. Focusing on statistical literacy, the unit covers foundational statistical concepts, including the design of experiments, exploratory data analysis, sampling and tests of significance.