Materials are an important part of the civil engineers' work. Indeed, civil engineers who are concerned with the design, construction, and maintenance of facilities need to understand the behaviour and performance of the materials used. And as it happens, mechanical properties- which are essential and basic for civil engineers- are highly dependent on the structure of materials at various scales. Therefore, it is important that a student in Civil Engineering possesses a fundamental knowledge in materials science. This unit of study aims to provide students with the tools necessary to select the adequate material for a particular application and to assess its mechanical behaviour while in use. This unit will focus mainly on materials for civil engineering and construction applications, i.e. metals, concrete and soils.

Unit will focus on Engineering Statics, covering topics such as resolution of forces and moments, free body diagrams, support reactions, equilibrium in rigid bodies, trusses frames and machines, method of sections, method of joints, centroids, distributed forces, vibrations and friction. There will be extensive use of both 2D and 3D examples and solution methods by either resolution in the principle axes or by using vectors. Its main aim is to prepare students for 2nd year civil units such as Structural Mechanics.

Construction: Fundamental understanding of construction materials and techniques underpins Civil design and complements a rigorous analysis covered in other units such as Structural Mechanics and Soil Mechanics. In this unit students will be introduced to the realities of on-site civil construction. For many students this comes as a completely foreign experience and the methods they need to use to succeed in this unit rely on the student building his or her own awareness of the construction world and how it operates. This will be guided by the lectures and on-line material, but will not be spoon-fed to the students.
This unit presents concepts introducing students to engineering construction including:
- design, control, management, measurement and construction methods for excavation, embankments and other earthworks, hauling and associated operations;
- conceptual and formative exposure to building construction methods and materials, including reinforced concrete, masonry, steel and timber;
- drilling and blasting.
Surveying: The unit also introduces Engineering Survey topics, where the aims are:
- give an overall view of the functions of surveying and it's service role in Civil construction;
- become acquainted with selected specific surveying techniques, such as: (a) to provide basic analogue methods of distance, angle and height measurement and, (b) to provide an understanding of three dimensional mapping using basic total station electronic field equipment with associated data capture ability, and;
- to give an insight into future trends in the use of GPS and GIS systems.
Students should develop basic competency in earthwork engineering and awareness of costing issues in formulating building proposals (through simplified examples). Economic optimisation is investigated, and how this impinges on decisions of construction, including proposing and analysing systems and methods, estimation of probable output, unit cost and productivity evaluation. Students should have a basic knowledge of vertical construction in reinforced concrete, masonry, steel and timber. Students should also develop proficiency in the design and implementation of mapping systems in Civil Engineering, using analogue and electronic field equipment and associated software packages.
The tutorial exercises give practise for students to implement what they have learned from lectures and their own research about the framework under which construction projects are formulated and analysed; construction engineering fundamentals; construction systems related to excavation, hauling and embankment construction, including selection and evaluation of plant and methods as well as the expected output and cost; introduction to construction operations management, introduction to engineering surveying, distance measurement, angle measurement, levelling, traversing, topographic surveys, electronic surveying equipment, future surveying technologies.
While prior exposure to an actual construction site would be beneficial, in any case the key for success in this unit is for the student to develop a hungry curiosity for the world of construction and the professionals and personalities which form the intricate patchwork of talent which sees complex projects through to successful completion.

This unit introduces students to the role of civil engineers and the historical development of the profession, and relates this to the Code of Ethics - Engineers Australia; impact of engineering on the human and natural environment; energy consumption, resourcing and renewal, dealing with variability in climate; definitions and practice of sustainability; environmental assessment tools and life-cycle analyses. As graduates, students may expect to find themselves in a position which touches upon a wide variety of Engineering fields (including legal, institutional, and environmental considerations). In both small and large firms they could be acting as agents and managers of technology-driven change which has social and environmental impact. Engineering decision-making and problem-solving are made more complex by technical, economic, environmental, social and ethical constraints. The goals of this unit are to introduce students to major problems of environmental deterioration and engage students in active reflection on the role of civil engineers in addressing these issues; to develop the students skills at quantifying the impact of engineering decisions within the broader economic, environmental and socio-cultural contexts; to develop communication skills through participation in group discussions, video production and written report writing. Lectures, group discussions, case problems and projects are all used in teaching and learning in this unit of study.

The primary objective of this unit is to understand internal actions (forces and moments) in structures (deformable objects) under loads in three key areas: how structures resist external loads by internal actions; the distribution of internal actions within structures; and the deformations, stresses and strains associated with the internal actions. At the end of this unit, students should be able to understand the basic methods of load transfer in structures - tension, compression, bending, shear and torsion (internal actions); apply the equations of equilibrium to determine the distribution of internal actions in a simple structure by drawing BMDs, SFDs, AFDs, and TMDs; understand the significance and methods of calculation of the geometric properties of structural sections (I, Z, S, J, etc.); understand the effect of internal forces and deformations of bodies through the concept and calculation of strains and stresses; appreciate the behaviour of structures by analysing structures without numerical calculations; display a knowledge of basic material properties, combined stresses and failure criteria; and demonstrate their hands-on experience of the behaviour of structural members via experiments and the ability to prepare written reports on those experiments. Emphasis in the assessment scheme will be placed on understanding structural behaviour and solving problems, rather than remembering formulae or performing complex calculations. The course seeks to utilise and improve the generic skills of students, in areas such as problem solving, neat and logical setting out of solutions, report writing, and team work. The syllabus comprises introduction; equilibrium; internal actions: BMDs, SFDs, AFDs, and TMDs; elasticity, stress and strain, and basic material properties; axial forces: tension and compression; elastic bending of beams; shear force and shear stresses in beams; torsion; deflection of beams; pipes and pressure vessels; trusses; material properties, combined stresses and yield criteria; advanced bending; introduction to buckling and instability.

This course provides an elementary introduction to Geotechnical Engineering, and provides the basic mechanics necessary for the detailed study of Geotechnical Engineering. This course aims to provide an understanding of: the nature of soils as engineering materials; common soil classification schemes; the importance of water in the soil and the effects of water movement; methods of predicting soil settlements, the stress-strain-strength response of soils, and earth pressures.

The objective of this unit of study is to develop an understanding of basic fluid concepts for inviscid and incompressible fluids. Topics to be covered will include: basic fluid properties, hydrostatics, buoyancy, stability, pressure distribution in a fluid with rigid body motion, fluid dynamics, conservation of mass and momentum, dimensional analysis, open channel flow, and pipe flow.
This core unit of study together with CIVL3612 forms the basis for further studies in the applied areas of ocean, coastal and wind engineering and other elective fluid mechanics units which may be offered.

This unit of study aims to provide an introduction to transport systems and is assumed knowledge for fourth year units on traffic engineering, transport planning, and city logistics. Topics include: the role of accessibility as the reason for transport; the history of transport technologies in Australia and globally; the characteristics of the principle modes of transport; factors behind the demand for mobility; qualitative choice modeling; agent-based modeling; predicting travel demands; the mechanics of queueing and traffic flow; intelligent transport systems; the microscopic and macroscopic fundamental diagrams; highway capacity and level of service; the design of transport junctions.

This unit aims to introduce students to project valuations using present-value cash flow theory, taxation and probabilities, and the role of these valuations in the decision-making process. Students are taught techniques for making an analysis of issues involved in project appraisal by various methods and these are applied to businesses, non-profit organisations, and governments. At the end of this unit, students should be able to comprehend and relate to real-life examples the fundamental concepts in project appraisal (e. g. the meaning of time value for money, equivalence); calculate common financial indicators for a given project and explain the relevance of each to the appraisal of the project; rank projects by combining both financial and non-financial indicators (e. g. environmental and social); understand how risks and uncertainties affect evaluation outcomes and be able to deal with uncertainties and risks in analysis; apply techniques to account for the effects of inflation/deflation and exchange rates in analysis; understand the concept and mechanisms for depreciation and carry out pre-tax as well as post-tax analysis; understand the assumptions, pros and cons of each evaluation method and be able to explain why a particular method is appropriate/not appropriate for a given project. The syllabus covers the following concepts: time value of money, cost of capital, simple/compound interest, nominal/effective interest, cost/benefit analysis of projects; equivalence, net present worth (value), future worth (value), annual worth (value), internal rate of return, external rate of return, payback period; cost-benefit analysis, cost-utility analysis, identifying and quantifying non-financial benefits/externalities; Other influencing factors: price changes and exchange rates, depreciation, taxation; Capitalisation and valuation studies, replacement of assets, real option, project risk analysis, decision-tree analysis, WACC, MARR, equity capital, debt. This unit of study is a second-year core unit for students enrolled in Civil Engineering (any major), and is a possible elective in other schools of engineering.

The objectives of this unit are to provide a basic understanding of the behaviour of reinforced concrete members and structures; to provide a basic understanding of standard methods of analysis and design of reinforced concrete structures (including an understanding of capabilities and limitations); and to provide basic design training in a simulated professional engineering environment. At the end of this unit students will gain proficiency in basic methods of reinforced concrete analysis and design.
The syllabus covers the behaviour of reinforced concrete members and structures, including: material properties, 'elastic' analysis (stresses/deformations/time-dependence), ultimate strength of beams (flexure), ultimate strength of columns (short and slender), behaviour or reinforced concrete slabs, the reinforced concrete truss analogy (shear and detailing implications), design criteria (for durability, fire- resistance, serviceability and strength), design calculation procedures, reinforcement detailing and structural drawings.

This unit of study is concerned with the behaviour and design of steel structures. Statics provided the fundamentals of equilibrium upon which most structural engineering is based. Structural Concepts and Structural Analysis provided information on the loads (actions) on a structure and how structures resist these actions with a resulting distribution of internal actions (bending moments, shear forces, axial forces; BMDs, SFDs and AFDs). Structural Mechanics considered how these internal actions resulted in stresses and strains in members. Materials considered the microscopic and molecular structure of metals to determine its inherent mechanical properties such as yield stress. This unit of study will then combine the knowledge of stresses, material properties of steel, structural analysis, and loading, and consider new concepts and modes of failure, such as local and flexural torsional buckling, combined actions and second-order effects to understand the behaviour of steel members and frames, and how this behaviour is accounted for in the design standard AS 4100.
Both the units of study "Steel Structures 1" and "Concrete Structures 1" can be considered the culmination of the various elements of structural engineering begun in "Engineering Mechanics" in first year, and is further developed in "Civil Engineering Design" in final year. More advanced topics, such as plate behaviour, advanced buckling and connection design, are considered in the final year elective subject "Steel Structures 2".
It is recognised that not all students intend to become consulting structural engineers. The unit of study is designed so that students who make an effort to understand the concepts are most capable of passing. Students who are planning a career in the consulting structural engineering profession should be aiming at achieving a Distinction grade or higher.

This unit of study aims to provide an understanding of the conservation of mass and momentum in differential forms for viscous fluid flows. It provides the foundation for advanced study of turbulence, flow around immersed bodies, open channel flow, pipe flow and pump design.

The twin foci of this unit are: to enable students to participate as design engineers by developing an understanding of the design principles and techniques involved in the planning of a range of construction activities; and to assist students in preparing themselves for the role of a site engineer in a construction project wherein they will become familiar with the planning and execution of those activities, albeit with supervision and guidance from experienced professionals. Construction topics include hard rock tunnelling and general rock excavation; soft ground tunnelling; underground construction; micro tunnelling; cut and cover tunnelling; earth retaining systems; piling; formwork and falsework; dewatering; pavement design and construction - rigid and flexible; stormwater drainage design and construction; marine construction; civil construction in environmentally sensitive areas; contract administration for construction engineers; general engineering in remote localities (project based); construction methods in bridge engineering; QA documentation on a typical project; insurance in the construction industry, OHandS issues in the construction industry; timber engineering; post-tensioned/prestressed concrete construction.

The objective of this unit is to give students an appreciation of the role of the designer in the development of Civil Engineering projects. At the end of this unit, students will have developed an understanding of the design philosophy. They will gain this through their involvement in a number of exercises which cover the design sequence from concept to documentation.
The syllabus comprises: design sequence beginning with a 'brief' and including definition, value and criteria selection; generation of proposals; analysis of proposals; selection of design; development of details of a particular design selected; feasibility studies and examination of existing works; study of design projects by stages, including details of some aspects.
This unit is under the direction of an engineer in professional practice in cooperation with other professional practitioners and members of the academic staff. Lectures and exercises on the interaction between civil engineering and architectural design and practice are included in the unit.

Course objectives: To introduce basic geology and the principles of site investigation to civil engineering students. Expected outcomes: Students should develop an appreciation of geologic processes and their influence civil engineering works, acquire knowledge of the most important rocks and minerals and be able to identify them, and interpret geological maps with an emphasis on making construction decisions. Syllabus summary: Geological concepts relevant to civil engineering and the building environment. Introduction to minerals; igneous, sedimentary and metamorphic rocks, their occurrence, formation and significance. General introduction to physical geology and geomorphology, structural geology, plate tectonics, hydrogeology, rock core logging site investigation techniques for construction. Associated laboratory work on minerals, rocks and mapping.

This unit starts with an investigation of linearity: linear functions, general principles relating to the solution sets of homogeneous and inhomogeneous linear equations (including differential equations), linear independence and the dimension of a linear space. The study of eigenvalues and eigenvectors, begun in junior level linear algebra, is extended and developed. The unit then moves on to topics from vector calculus, including vector-valued functions (parametrised curves and surfaces; vector fields; div, grad and curl; gradient fields and potential functions), line integrals (arc length; work; path-independent integrals and conservative fields; flux across a curve), iterated integrals (double and triple integrals; polar, cylindrical and spherical coordinates; areas, volumes and mass; Green's Theorem), flux integrals (flow through a surface; flux integrals through a surface defined by a function of two variables, though cylinders, spheres and parametrised surfaces), Gauss' Divergence Theorem and Stokes' Theorem.

The objectives of this unit are to provide an understanding of the principles of structural analysis by introducing the strain-displacement, stress-strain and equilibrium relationships for beam members; applying the relationships to the matrix displacement analysis of frame structures; and using computer software to conduct the linear-elastic and buckling analyses of frame structures. At the end of this unit, students will be able to deduce appropriate structural models for frame structures; and use computer methods and simple hand methods to obtain internal forces and displacements as well as buckling loads for frame structures. The syllabus comprises theoretical background (strain-displacement, stress-strain and equilibrium relationships), structural analysis software, matrix displacement method, beam theory, introduction to nonlinear analysis, buckling analysis.

CIVL4860 is a core final year unit for BE/BDesArch students aimed at enhancing students' skills in bridging between the architectural and engineering disciplines. The Unit will have a particular focus on developing strategies for how best to resolve the frequently conflicting interests and preferred concept solutions for addressing architectural and structural requirements for a building with given functions. Students will work in groups on developing final building designs from scratch from project briefs. Architectural and structural designs will be detailed in group presentations and reports.

The objectives of this unit are to provide an understanding of the principles of structural analysis by introducing the strain-displacement, stress-strain and equilibrium relationships for beam members; applying the relationships to the matrix displacement analysis of frame structures; and using computer software to conduct the linear-elastic and buckling analyses of frame structures. At the end of this unit, students will be able to deduce appropriate structural models for frame structures; and use computer methods and simple hand methods to obtain internal forces and displacements as well as buckling loads for frame structures. The syllabus comprises theoretical background (strain-displacement, stress-strain and equilibrium relationships), structural analysis software, matrix displacement method, beam theory, introduction to nonlinear analysis, buckling analysis.

Humanitarian Engineering is the application of engineering to meet the needs of communities globally; while maintaining a focus on sustainability and appropriateness. This unit will give an introduction to engineers from all disciplines about the unique skills and knowledge needed to tackle challenges in; developing countries, during all stages of disasters and indigenous communities. Achieving global sustainability is a consistent theme through-out the subject. The unit will develop skills in intra-disciplinary teamwork and cross-cultural competence. The subject is taught through a series of lectures based on real case studies and engaging guest seminars. Seminars presenters are all people who are currently working in the field of humanitarian engineering with representatives from industry, government, multi-lateral organisations and non-government organisations. This unit of study is the first lecture based subject in the Humanitarian Engineering major. The unit aligns as a 3rd year elective and is a prerequisite for 4th year subject in the Humanitarian Engineering major CIVL5320 Engineering for Sustainable Development.

The objectives of this unit are to provide an understanding of the factors influencing soil strength, and to give practice in the application of this understanding by exploring the stability of slopes, retaining walls and foundations. At the end of this unit students will be able to: determine the strength parameters appropriate to a range of stability problems, and understand the difference between total and effective stress approaches; evaluate strength parameters from laboratory data; critically analyse foundation stability and slope stability problems; use spreadsheets to perform parametric studies and produce design charts for simple geotechnical design problems; and communicate the results of experiments and analyses using written methods appropriate for professional geotechnical engineers. The syllabus comprises; methods of analysis for gravity and sheet pile retaining walls; reinforced soil; slope stability, including modes of failure, analysis and computer methods; bearing capacity of shallow foundations under general loading, and axial and lateral capacities of deep pile foundations; the mechanical behaviour of sands and clays; and Critical State models.

Students will gain insight into the framework that underpins integrated engineering principles applied for the design of structures and buildings. The Unit of Study is articulated in the following three components. In the initial part of this Unit of Study, students will be exposed to selected case studies that highlight the engineering design requirements, including serviceability and limit state design criteria, that buildings of different structural typologies and construction materials need to satisfy. Case studies considered are representative of current trends in the construction sector. In the second part of the Unit of Study, students will be introduced to typical engineering design methodologies and how these vary depending on the level of sophistication required in the analysis and design, and on the expected design and construction phases of a project. Particular attention will be devoted to concrete, steel and modular construction. Optimisation techniques will be introduced and applied in the third part of the Unit of Study to simple geometries to explore the effects of different design parameters and to identify suitable integrated engineering designs among available solutions.

The overall objective of this unit of study is to give a general introduction to water resources, how these are linked the hydrological processes, and how engineering plays a role in the management of water resources. The aim of this unit is to provide a detailed understanding of: the hydrologic cycle of water as a whole and its specific components including: geophysical flows of water throughout the environment, dynamics of precipitation formations, transformations into runoff, reservoir and lake dynamics, stream flow discharge, surface runoff assessment, calculation of peak flows, the hydrograph theory, ground water flows, aquifers dynamics, concept of water quality and water treatment methods and units. The topics mentioned above will be covered in both qualitative and quantitative aspects. Use will be made of essential concepts of energy, mass and momentum conservation. An intermediate level of integral and differential calculus is required as well as knowledge and use of calculation software such as Excel and Matlab.

This unit of study offers students an introduction to civil engineering data analysis using examples of real-world transport operations applications. Students will develop skills to convert data into information for decision making including data ingestion, data structures, summarisation, visualisation, error analysis, and basic modelling. The data science skills will be taught using Python notebooks.

In parallel with data science skills, this unit of study will introduce public transport system operations and planning. Lecture and reading content will provide a foundation of history, terminology and methods to assess the performance of public transport systems and make data-driven planning decisions. The datasets will be drawn from urban public transport applications, and explore real-world challenges in transport informatics.

The general aim of this unit of study is to offer the student the opportunity to develop an understanding of the scope, time and cost management in project environments. Students will engage with some of the key concepts and various activities which underpin project scope, time and cost management. At the end of this unit, students will be able to: develop Work Breakdown Structure (WBS), develop network diagrams, and undertake Critical Path Analysis (CPA) and Earned Value Analysis (EVA) using the given project information; explain in depth why scope, time and cost management are important to project management; analyse a project situation that involves scope, time and cost management issues; and explain how the components of scope, time and cost management interrelate in project environments. The syllabus comprises the project planning cycle, working with the project sponsor, scope initiation and definition, project scope definition tools, WBS, network scheduling techniques, CPA, Just-in-Time philosophy, estimating and budgeting, cash flow management, EVA and application of project management software.

This unit of study is a fourth year core unit of study for the Bachelor of Project Engineering and Management. It is also an elective for other branches of engineering and faculties. The objective of this unit is to provide underpinning knowledge and skills in the application of tools to the project management environment for risk, quality and people management including leading and managing project teams. At the end of this unit, students will be able to understand and apply the tools of team building and project management leadership, as well as apply tools for design and implementation of integrated plans for risk, quality, human resource and procurement. The competency level achieved will enable application of integration tools to a range of simple generic projects as well as provide input to plans for more complex projects. The syllabus comprises team management, project leadership, modern quality management principles and techniques, quality assurance, preparation of quality plans; risk analysis, planning and risk management, as well as linking risk and quality management to human resourcing and procurement methodologies. The use of integrated planning software such as MS Project, Gantt Project and social media tools for project management will be explained and practised. The definitions and processes of Project Management will largely follow the US based Project Management Institutes, PMBOK as is used in the Australian Institution of Project Management Standards at the level of Certified Practising Project Manager, (CPPM). Other International standards such as ICPMA's, ICB3.0 standard will also be covered.

The objectives of this unit are to give students a fundamental knowledge of the legal system and contract terms under which projects are generally conducted. Initially, emphasis will be on contract negotiations and understanding what negotiation is about and how to prepare for negotiations and also how to manage the negotiation so that a suitable outcome for both parties may be achieved. Also being able to deal with difficult opponents will be something that will be considered.
Emphasis will be on the principles of contract formulation, administration and finalisation, including prevention and/or settlement of disputes in projects. The syllabus comprises brief overview of the legal system in Australia and comparison with other legal systems introduction to project delivery systems and the running of a typical project, introduction to contract law and the formation of contracts, the principles of standard form contracts as well as bespoke drafting, an understanding of the risks undertaken by the different contracting parties, a detailed review of a standard contract promoting an understanding of major project issues such as time, variations and payment; implementation and administration; potential liabilities associated with project participation; contract conditions and specifications; understanding insurances and alternate dispute resolution procedures; notification requirements including time bar, understanding the commercial significance of issues such as latent conditions, subcontracting, bank guarantees and security of payment legislation.

This unit of study is a fourth year core unit of study for the Bachelor of Project Engineering and Management (Civil), elective for all other branches of engineering and other faculties. The general aim of this unit is to offer student the opportunity to develop an understanding of the procurement of built facilities and the methods of job allocation in project environments. Students will be engaged in a real construction case study project where key practical concepts which underpin procurement will be taught. At the end of this unit of study, students should be able to: evaluate a client's procurement situation and apply an appropriate procurement route; explain how and why a particular procurement route is chosen; undertake procurement assessment exercises; analyze a contractor's strategic responses in tendering (bidding) decision-making; discuss why a particular bidding strategy is chosen in different contexts; and evaluate a contractor's bidding performance using competitor analysis techniques. The syllabus comprises fundamentals of building procurement, assessment of procurement risks, competitive bidding, cost estimating, the competitive environment in the construction industry, contractors' competitive positioning, contractors' decision-making in bidding competition, bidding strategies and competitor analysis.

The aim of this unit is to develop students' ability to formulate projects through critically assessing and developing business case and project plan for a real-life engineering project. This unit is relevant for students who intend to pursue career related to project management. The learning activities focus on the project's viability and early stage planning. Strategic needs and possible project options are identified and assessed based on potential benefits, costs and the strategic context. Suitable site/route needs to be selected for the project based on technical and business considerations. Due consideration should also be given to the project's impact on environment and communities. The project's viability can be indicated using Benefit-Cost ratio as well as non-financial indicators such as number of jobs created and the number of life saved. In deriving these indicators, it is important to take project uncertainties into consideration through using techniques such as sensitivity analysis, decision-tree analysis, probabilistic modelling and Monte Carlo simulation. The objective is to justify investment to address the business needs and recommend the most appropriate response to the business needs.
The early stage planning concentrates on defining project requirements and project delivery strategy. The objective is to seek approval/support for project delivery or to critically evaluate the current project plan, depending on the current stage of the project. The exercise is to develop a plan guide project delivery and transition to operation. The plan should cover, but not limited to, the feasibility analysis, project deliverables, plan of activities necessary to move the project to the next stages, procurement strategy, what's needed to enable delivery (e. g. stakeholder management plan, planning and other approvals, funding, time, control processes, community and environment management plan, marketing and sales plan, and risk management plan) and, what is required to complete delivery and transition to operation stages.

This unit aims to: provide fundamental understanding at advanced level of the behaviour and design of hot-rolled/fabricated and cold-formed steel members; to provide fundamental understanding of newly developed Direct Design Method (DDM) for analysis and design of structural systems; and to develop an understanding of the behaviour and design of steel connections in open and hollow sections. It is anticipated that at the end of this unit of study students should be familiar with the behaviour of steel structures at advanced level in selected areas, including design for local buckling and design for flexural-torsional buckling of columns and beams; have a sound knowledge of AS 4100 in the areas of section capacity determination of slender cross-sections, and flexural-torsional buckling of beams; have a sound knowledge of AS/NZS 4600 in the areas of section capacity determination of slender cross-sections, and flexural-torsional buckling of columns and beams; have knowledge of the use of FEM software in the design of structural systems; have the skills to assess the behaviour of specific connections; have an appreciation of some practical aspects of economical steel connection design. This unit will examine stability theory, Stability design to AS4100 and AS/NZS4600, Direct Design Method, Steel connection design.

This Unit reviews the fundamental concepts of 'elastic' behaviour of reinforced concrete structures and introduces models of behaviour and methods of analysis related to the time-dependent effects of creep and shrinkage (at service loads). This Unit also examines the non-linear (strain-softening) behaviour of reinforced concrete and the related effects concerning the strength of statically-indeterminate reinforced concrete structures. In particular, this Unit examines the concepts of ductility, moment-redistribution and plastic design (for beams and slabs). Strut-and-tie modelling of reinforced concrete members is also described. Design guidelines will reflect requirements of the Australian Standards and Eurocodes.
This Unit will provide students with the following knowledge and skills: understanding of the fundamental concepts and theoretical models concerning the time-dependent structural effects of concrete creep and shrinkage; ability to carry out calculations to estimate 'elastic' load-effects (stresses/strains/deformations) for reinforced concrete structures (at service loads), accounting for the time-dependent effects of concrete creep and shrinkage; understanding of the fundamental concepts and theoretical models of the strain-softening behaviour of reinforced concrete (in flexure); understanding of the fundamental concepts and numerical models of ductility and moment redistribution for reinforced concrete beams; ability to quantitatively assess the ductility and moment-redistribution capacity of reinforced concrete beams; understanding of the fundamental concepts and numerical models of plastic behaviour and design for reinforced concrete beams and slabs (including yield-line analysis); ability to determine the ultimate plastic load-carrying capacity of statically-indeterminate reinforced-concrete beams and slabs; ability to use strut-and-tie models of reinforced concrete behaviour.

This unit will provide students a wide knowledge and understanding of Bridge Engineering enabling them to be future practical bridge engineers. The unit consists of 4 parts, as detailed: Part 1 covers Introduction to Bridge Assets, Sustainability and Bridge Design Investigation. Part 2 covers Bridge Design to AS5100-2017. Part 3 covers Bridge Asset Management - Materials of construction, Asset Managers' challenges, Maintenance, Rehabilitation and Bridge Information System. Part 4 covers Types of Non-Destructive Bridge Load Testing and Structural Health Monitoring, and Benefits of Application of these Procedures.

This course will provide students broader knowledge in timber design and structural rehabilitation. In the first section of the subject, students will learn the engineering properties of timber and requirements to be met for specification of the design, installation and maintenance of timber structures. It includes grading and structural properties; design actions; design of timber columns, beams, tension members and connections; principles of limit state design and serviceability; methods of testing; quality standards and maintenance of timber structures based on AS 1720. 1-2010 timber structures-design methods, and AS NZS 4063. 1-2010 characterization of structural timber-test methods.
The second part covers monitoring, rehabilitation and strengthening techniques of existing structures (concrete/steel/timber/masonry). Students will be introduced to structural inspection and evaluation; durability and deterioration; destructive and non-destructive testing; and design of strengthening systems including advanced fibre reinforced polymer (FRP) materials, epoxy injection, steel plate bonding, and post tensioning according to relevant Australian, ACI and European guidelines.

The aim of this unit of study is to provide students with an introduction to the knowledge and skills necessary to design and implement sustainable humanitarian engineering projects. The context for the delivery of humanitarian engineering projects are set in developing countries, disaster relief situations, indigenous communities and our societies at large. Sustainability it critical to the long term impact of any engineering project. Students will learn about how engineering fits within a range of sustainability frameworks. Systems thinking, inter-disciplinary approaches, partnerships and government policy are some of the topics that will be covered. This unit of study is the 4th year elective for Humanitarian Engineering major and is open to all undergraduate engineers who have completed the pre-requisites.

The aim of this unit of study is to provide fieldwork experience for undergraduate engineering students. The unit of study is one of the four subjects offered in the Humanitarian Engineering Major. The fieldwork will be between two to four weeks in either a developing country or remote communities in Australia. From this fieldwork experience, students will learn about the diversity of communities in need and how engineering can be used to address some of these problems. The fieldwork will focus on applying the human-centered design process to a student identified design challenge in the community. It is not anticipated that there will be any implemented project at the conclusion of the fieldwork. However, the fieldwork design challenge will result in student-generated ideas that the local partner organisation might wish to develop further. The fieldwork unit will require students to demonstrate an applied use of engineering skills, cross-cultural competence, effective communication, resilience and an ability to work closely in teams. Enrolment in this subject is competitive and is open to undergraduate engineering students from any stream of engineering.

Geoenvironmental Engineering is an applied science concerned with the protection of soil and aquifers from human activities. It can be divided into 2 main branches: waste containment and treatment of pollution sites. The former is usually a preventative activity, whereas the latter is corrective, i.e., it occurs after pollution has taken place. Geoenvironmental Engineering draws on fundamental science, especially fluid flow and contaminant migration in soil and the physics and chemistry of low-permeability material such as clay. The goal of CIVL5351 is to introduce you to the science behind Geoenvironmental Engineering and develop your skills at designing barrier systems for groundwater protection.
Learning Outcomes: 1. Analyse flow regime in saturated and unsaturated soils using Darcy¿s Law; 2. Analyse contaminant migration in soil using coupled flow and reactive diffusion-advection equations; 3. Describe the main processes of clay-water interactions and their influence on behaviour of barrier systems; 4. Design a contaminant barrier system satisfying groundwater quality requirements; 5. Assess the feasibility of waste-to-energy conversion; 6. Conduct research on a geoenvironmental topic; 7. Build simulation models and appraise quality of their predictions.
Syllabus Summary: introduction to geoenvironmental engineering; integrated waste management and life cycle assessment; soil composition and mineralogy; types and characteristics of contaminants; theory of water seepage in saturated and unsaturated soils; theory of reactive contaminant transport in soil including molecular diffusion, mechanical dispersion and advective flow; analytical and numerical solutions of reactive diffusion advection equation; design of barrier systems; geosynthetics and geomembranes; defects and leakage rates; methane generation in landfills and waste-to-energy potential.

The objectives of this unit are to gain an understanding of the design process in foundation engineering, to understand the importance of site investigation and field testing, and to learn how to deal with uncertainty. To achieve these objectives students are asked to design foundations using real data. Students will develop the ability to interpret the results of a site investigation; to use laboratory and field data to design simple foundations; develop an appreciation of the interaction between the soil, foundation system and the supported structure. The syllabus is comprised of field testing, site characterisation, interpretation of field data, design of pile raft and surface footings, support of excavations, soil improvement, and geotechnical report writing.

Geotechnical hazards include landslides, rock falls and mud flows. They are triggered by soil/rock failure due to natural or human causes. The objective of this Unit of Study is to develop the ability to assess and mitigate the risks associated to such events.
Students will learn how to estimate when and where these events are likely to occur, how to define safety zones and how to design effective protection structures. The syllabus is comprised of (i) Landslide Risk Assessment and Management procedures (ii) post-failure and out of equilibrium soil mechanics applied to prediction of rock fall, landslide and mud flow run-out distance and impact force on structures; (iii) design of geotechnical protection structures using Finite Element modelling.
Senior geotechnical engineers from major companies will deliver some guest lectures presenting on practical case study involving geotechnical hazards throughout the semester.

The objective of this unit is to provide students with fundamental knowledge of finite element analysis and how to apply this knowledge to the solution of civil engineering problems at intermediate and advanced levels.
At the end of this unit, students should acquire knowledge of methods of formulating finite element equations, basic element types, the use of finite element methods for solving problems in structural, geotechnical and continuum analysis and the use of finite element software packages. The syllabus comprises introduction to finite element theory, analysis of bars, beams and columns, and assemblages of these structural elements; analysis of elastic continua; problems of plane strain, plane stress and axial symmetry; use, testing and validation of finite element software packages; and extensions to apply this knowledge to problems encountered in engineering practice.
On completion of this unit, students will have gained the following knowledge and skills:
1. Knowledge of methods of formulating finite element equations. This will provide students with an insight into the principles at the basis of the FE elements available in commercial FE software.
2. Knowledge of basic element types. Students will be able to evaluate the adequacy of different elements in providing accurate and reliable results.
3. Knowledge of the use of finite element methods for solving problems in structural and geotechnical engineering applications. Students will be exposed to some applications to enable them to gain familiarity with FE analyses.
4. Knowledge of the use of finite element programming and modeling.
5. Extended knowledge of the application of FE to solve civil engineering problems.

The objectives of this unit are to demonstrate how the granular structure of soil materials controls their engineering behaviour; translate particle micromechanics to improve macroscopic engineering predictions; and establish the intimate connection of geotechnical engineering to other disciplines where granular materials play a pivotal role, including mining engineering, bulk materials handling, and geophysics. Similarly, this course will cohesively connect geotechnical engineering with fluids engineering principles, as well as enhance students' background in materials science. At the end of this unit students will be able to understand and use Discrete Element Method to evaluate and solve geotechnical problems such as rockfall interactions with surrounding terrain. They will also critically analyse pile penetration and silo discharge in light of granular mechanisms; apply soil rheology to carry out parametric study of landslide flows; and understand and use dimensionless analysis principles to predict resistive forces on obstacles. Strong focus will be dedicated for communicating students' results using written methods appropriate for professional engineers.

Students will gain insight into energy consumption of building systems and how this is expected to vary considering different building solutions from an engineering design viewpoint in the context of climate change. The Unit of Study is articulated in the following four components. In the initial part of the Unit of Study, students are exposed to the fundamental concepts related to energy and its generation as well as to the current infrastructure supporting its distribution in cities and rural areas. Based on selected case studies that differ for the building typology, basic calculation approaches required for the estimation of the energy consumption of buildings are outlined and applied in the second part of the Unit of Study. In this manner, students will be exposed to an understanding of the expected impact that different structural typologies and construction materials have on the energy performance of a building. The third part of the Unit of Study presents the concepts and design principles of NZEB and how these can be successfully implemented in modern construction from an engineering viewpoint. In the final part of the Unit of Study, students are exposed to latest trends in building technologies and building-to-grid integration techniques aimed at minimising energy consumption and at reducing the likelihood of blackouts as well as peak energy demands. This part provides also insight into strategies adopted for the deployment of smart building systems and how these interact with the energy supply in the context of smart cities. All parts of the Unit of Study will be supported by the presentation of selected case studies.

This unit of study will introduce the fundamentals of meteorology governing wind flow, details of extreme wind events, wind structure, statistical distribution of the wind, the effect of topography and terrain changes on wind profile, investigate the fluid flow around bluff bodies, and detail the design of civil engineering structures for wind loading.
This unit will provide students with the following knowledge and skills: On completion of this course students will have an understanding of the governing principles of wind engineering, how to predict the extreme wind speed and analyse anemographs, predict the effect of terrain and topography on velocity and turbulence, understand flow patterns around bodies, how to predict the pressure distribution and wind loading on bodies and structures, dynamic response of structures, and how all the above relates to AS1170.2.

The objectives of this unit of study are to develop an understanding of the processes occurring in lakes, reservoirs, streams and coastal seas, an introduction to transport and mixing in inland waters, and to the design the design of marine structures. The unit will cover the mass and heat budget in stored water bodies, mixing, and the implications for water quality. In streams, natural river systems will be discussed, and the principles of sediment transport and scour, monitoring and management will be introduced. The basic equations for linear and nonlinear wave theories in coastal seas will be introduced, and wave forces on structures and an introduction to design of offshore structures will be discussed.

This unit of study aims to provide an introduction to the intersections of theory and applications in Transport Networks, Geography, and Land Use. It describes how to characterize networks, (topology, hierarchy, morphology), and how that affects the use of those networks. The course is a mix between a lecture and a student-led seminar, with students responsible for researching and presenting on a number of the topics, as well as developing a course text in a wikibook format. Students will learn the basics of networks and how transportation systems function on them.

This unit of study aims to provide an introduction to the theory and practice of transport models as used for traffic operations. Topics include: travel demand forecasting; choice modelling; agent-based modeling; queuing and traffic flow; intelligent transport systems; the microscopic and macroscopic fundamental diagrams; highway operation; congestion control; static, quasi-dynamic and dynamic network equilibrium; the four-step (generation, distribution, mode choice and assignment) transport model; macroscopic models vs microscopic simulation; transport data sources and survey methodology; introduction to the main transport modelling software packages; coordinated control.

This subject aims to provide an environment for students to learn essential facts and develop models and frameworks to understand the development of transport policy, the making of transport plans, and the deployment of transport technologies. The unit uses a mixture of traditional lectures, and interactive learning through case studies and role playing. Both the lectures and the cases allow the students to develop an inductive understanding of transportation. The unit will be successful if at the end, the student has developed a worldview on transportation (not necessarily the same as the instructor's), and has an appreciation for merits and demerits of various perspectives on transport issues. The course seeks an integrative approach for transport, and though the stories in lecture will be told mode by mode, there are a number of opportunities to see the relationships between modes, in their structure in function, and in the learning as one mode adopts successful (and unsuccessful) attributes of others.

This unit of study uses a hands-on, data driven approach to exploring foundational concepts in transport. Students will undertake focussed study of a selection of highly influential texts in the field and develop skills to recreate, evaluate and improve upon these seminal analyses.
The students will use an integrated approach, drawing on perspectives from multiple disciplines and exercising their judgement regarding social, environmental and economic sustainability. Mastery of the concepts will be demonstrated through submitted technical analysis as well as clear written and graphical communication.

This unit requires students to use a number of advanced experimental tools and techniques which they learn through project-based learning as well as a structured theoretical lecture program. It will be very useful as co-requisite study for students engaged in an experimental honours thesis topic. It also covers issues of basic electronic circuitry and signal processing, various analysis techniques using both simple and advanced statistics, and advanced data processing methods such as PIV and Fourier filtering. It will also prepare students for further research in industry or academia.