From the grinding of grains to the drying of meats, humans have been processing their food since the dawn of civilisation. Over the decades, many traditional processing methods have become industrialised, while new processing technologies have emerged, quietly revolutionising our food systems, diets and cultures. In this unit, students will study the biochemical transformations that take place during food processing operations and the key engineering principles underlying industrial food manufacture. Lectures and practical classes will cover applications in diverse food categories to link the theoretical content to an industrial context. After completion of this unit, students will be able to: (1) recognise common food processing operations of importance to food industry; (2) explain the underlying biochemical and physicochemical changes that occur during processing and relate these to end-product qualities; (3) demonstrate current techniques for measuring key biochemical and physicochemical transformations, monitoring processes, and evaluating end-product qualities; (4) appreciate fundamental engineering principles relevant to industrial food processing; and (5) apply an understanding of processing principles to design a processing solution that adds value to a basic food or beverage. The unit will include lectures, laboratory sessions, group work and visits to food processing facilities.

Architectural History/Theory 1 introduces students to the discourse of architectural history and theory. It commences with a concise chronological survey of key periods of architectural history from antiquity to the mid-nineteenth century, providing an overview of the scope of the field and establishing initial points of reference. It then changes focus to investigate more closely the ways in which particular architectural themes and ideas traverse across history, coming to the fore in certain periods and receding in others. Students will interrogate these themes in small groups through intense study of a single significant building, which they will research, document and illustrate in a written report, and re-construct in a suite of finely crafted scale models. They will be introduced to fundamental principles and skills of scholarly research, including locating and evaluating sources, and constructing arguments.

Architectural Technologies 1 introduces students to the roles that environmental considerations, structures and construction play in architecture. The fundamental concepts underpinning each of these key areas are presented and students demonstrate their developing knowledge of them via project-based assignments. These progressively complex tasks initiate students to the knowledge required to successfully analyse and synthesise construction and technical systems in basic buildings.

This course aims at providing students with the conceptual and technical skills required to creatively explore dynamic transactions between art and architecture. Throughout the semester, students will extend their ability to work with complex ideas while drawing on interdisciplinary practices related to the body, time, movement, structure and form. This course provides a space for architecture students to establish parameters and territories for exploration beyond the concerns of conventional architectural projects. From generative form making to performative action, the crossover between art and architecture has always been present within architectural design. This unit looks at developing conceptual and practical disciplines through experimentation with materials. Essential design sensitivities and skills will be developed through different modes of working including lectures, tutorials, presentations and writing as well as the physical engagement with new materials and building processes.

This studio capitalises on the skills and processes gained in the first semester studio to engage with increasingly complex programmatic and contextual issues within the built environment. Fundamental modes of representation in a variety of media will be deployed as a means to comprehend and articulate architecture from multiple integrated perspectives. Designing a small building will be the final project yet based on a series of introductory exercises that will engage with concepts of iteration in a range of scales and media. Students will continue to learn new software and other related techniques while also developing their familiarity with the technical skills necessary to realise a final design presentation including various media. The design projects will explore the necessity of experimentation as a means to communicate fundamental ideas about space, structure and form.

Architectural Technologies 2 explores the roles that environmental considerations, structures and construction play in moderately complex medium-scale buildings. Emphasis is placed on developing in students an active awareness of the impact that technical and constructional decisions have on architectural Architectural Technologies 2 explores the role that environmental, structural and constructional considerations play in moderately complex small-scale buildings. Attention is paid to the impact that choices of materials, detailing, structural systems and energy systems, whether passive or active, have on architectural design. Through project-based learning, students develop an active awareness of the important role that appropriate technical and constructional decisions, including architectural details, play in terms of fulfilling conceptual ambitions in tangible works of architecture. Students develop and demonstrate their developing appreciation of these issues via case study analysis, a group project, individual technical drawings and a final examination. Students develop and demonstrate their awareness of these issues via the analysis of case studies, a large project-based assignment, and a final exam.

Drawing upon skills and knowledge learnt in Art Workshop 1, students will extend their ability to work with complex ideas while drawing on interdisciplinary practices. A diverse range of studios will host the productions and critical discussions of the work in conjunction with a series of lectures and independent research to be attained outside the workshops. By treating art as a field of open-ended experimentation, with direct consequences for architecture, this course encourages architecture students to undertake a self-directed and research based approach that widens their own practice through working across the multiple streams of information specific to contemporary art.

Architecture Studio 2A requires the design of a small scale building or space in an urban context. The design process that is fostered explores the creative tension between intuition and prescription, using accumulative techniques that are intended to elicit unexpected solutions. The exploration of various design techniques of digital drawing, modelling and making are promoted, and combined with the effort in sourcing materials and support, using a combination of multiple tools and machinery in the Faculty's Media Labs including digital fabrication. Students are required to sensitively and imaginatively negotiate between the internal logic of the design approach and urban strategies while considering the representation and visualisation of their process. They become increasingly attentive to the complexities of architectural design, from the interpretation of programmatic requirements in respect to the opportunities and limitations of particular site conditions to the spatial implications of design decisions.

Architecture Studio 2B requires the design of a moderately complex building in an urban context while exploring the historical and theoretical implications of site. Students develop an increased awareness of the broader social, cultural and environmental consequences of architectural decisions. The studio-history combination affords a unique opportunity to critically examine theories of space and the city in conjunction with diverse approaches to the making of modern architecture. Lectures will concentrate on an interdisciplinary approach to understanding architecture and urbanism from the 18th to the 21st centuries. Participatory and collaborative work processes are promoted while students will be required to sensitively and imaginatively negotiate their own approach to designing in the contemporary urban context. Consequently, students will become increasingly attentive to the complexities of architectural design. From integrating historical and theoretical precedent to the application of programmatic requirements as a means of recognising the limits and opportunities of given site conditions, the studio and lectures aim to enhance students' capabilities to reflect on social and political values in design whilst developing an architectural language that reflects a close understanding of spatial relationships embedded in the dialectics of society and power.

Architectural History/Theory 3 surveys contemporary architectural debates through historical precedents, central texts, and present-day criticism on aesthetic design, cultural influences, mass media, and political events. Architectural discourse can be understood as a wide array of interlocking 'regimes of thought', each of which has its own multiple histories, transformations and unique effects. Students will become generally conversant in the principles of these central theories, and will understand some of their terms and references. Contemporary issues will not be taken at face value but interrogated through theoretical principles raised by the assigned readings. Paying close attention to the exchange between thought and action, students will explore the relevance of the discussed theories to the formation of current circumstances, and to the place of architecture within contemporary culture as a whole. Students take responsibility for their own learning, engaging in continuous reflection and developing skills in oral, written, and visual forms of communication to critique, create and articulate knowledge. They will be introduced to fundamental principles and skills of scholarly research, including locating and evaluating sources, and constructing arguments.

Architectural Professional Practice introduces students in the final semester of their undergraduate degree to the professional practice of architecture, focusing on design development within regulatory and practice management frameworks. Students are introduced to the fundamental principles of key regulatory requirements and critically deploy their understandings by investigating local practice case studies. They further develop a capacity to apply their knowledge in a particular context through an architectural design project that they take to Development Application level using current best practice.

Architecture Studio 3A is oriented towards the technical dimensions of architecture, whilst remaining attentive to the deeper cultural and historical context in which such technical knowledge, particularly in regards to structures and sustainability, has arisen and is currently situated. It imparts knowledge and skills that will stimulate compelling architectural projects that are conceptually rigorous, structurally innovating and technically adept. Structural knowledge is developed through a suite of lectures and accompanying practical exercises, and is assessed through technical reports and a final examination. Students simultaneously develop an architectural project in response to a brief in which structural concerns necessarily come to the fore, such as for a habitable bridge. They are required to integrate multiple criteria, including thematic, conceptual, programmatic and technical concerns into a persuasive architectural proposition.

As the culminating design studio for the degree, students are presented with the opportunity to express and represent their own theoretical positioning through the design of a sufficiently complex building. Working with a great deal of autonomy, students will be asked to rigorously demonstrate the technical and representational capacities that have developed across their work in the degree. The studio consolidates the students' abilities in communicating and translating architecture using advanced techniques of graphic visualisation through 3D modelling software and digital fabrication techniques. Students are encouraged to develop hybrid techniques for moving between digital and actual realms while also strengthening their own theoretical position about the contemporary built and unbuilt environments. The aim is to produce conceptually challenging, integrated and compelling pre-professional architectural design projects that confront a variety of spatial contexts.

This unit investigates the fundamentals of accounting and aims to provide a broad understanding of the role of accounting in the context of business and society. The format of the unit is designed to show that there are many uses of accounting data. The focus moves from accountability to decision making; both functions are explained through examples such as the 'double entry equation', and from an output (financial statements) perspective. Some more technical aspects of accounting are outlined, including the elements of assets, liabilities, revenues and expenses within simple, familiar scenarios. Besides developing an understanding of the role of accounting via conventional financial reports, recent developments including the discharge of accountability by companies through the release of corporate social and environmental reports and the global financial crisis, are explored through an accounting lens.

Chemistry 1A is built on a satisfactory prior knowledge of the HSC Chemistry course. Chemistry 1A covers chemical theory and physical chemistry. Lectures: A series of 39 lectures, three per week throughout the semester.

Chemistry 1B is built on a satisfactory prior knowledge of Chemistry 1A and covers inorganic and organic chemistry. Successful completion of Chemistry 1B is an acceptable prerequisite for entry into Intermediate Chemistry units of study. Lectures: A series of 39 lectures, three per week throughout the semester.

This is one of the two core units of study for students considering majoring in chemistry, and for students of other disciplines who wish to acquire a good general background in chemistry. The unit considers fundamental questions of molecular structure, chemical reactivity, and molecular spectroscopy: What are chemical reactions and what makes them happen? How can we follow and understand them? How can we exploit them to make useful molecules? This course includes the organic and medicinal chemistry of aromatic and carbonyl compounds, organic reaction mechanisms, molecular spectroscopy, quantum chemistry, and molecular orbital theory.

This is the second core unit of study for students considering majoring in chemistry, and for students seeking a good general background in chemistry. The unit continues the consideration of molecular structure and chemical reactivity. Topics include the structure and bonding of inorganic compounds, the properties of metal complexes, materials chemistry and nanotechnology, thermodynamics and kinetics.

Life is chemistry, and this unit of study examines the key chemical processes that underlie all living systems. Lectures cover the chemistry of carbohydrates, lipids and DNA, the mechanisms of organic and biochemical reactions that occur in biological systems, chemical analysis of biological systems, the inorganic chemistry of metalloproteins, biomineralisation, biopolymers and biocolloids, and the application of spectroscopic techniques to biological systems. The practical course includes the chemical characterisation of biopolymers, experimental investigations of iron binding proteins, organic and inorganic chemical analysis, and the characterisation of anti-inflammatory drugs.

The identification of chemical species and quantitative determination of how much of each species is present are the essential first steps in solving all chemical puzzles. In this course students learn analytical techniques and chemical problem solving in the context of forensic and environmental chemistry. The lectures on environmental chemistry cover atmospheric chemistry (including air pollution, global warming and ozone depletion), and water/soil chemistry (including bio-geochemical cycling, chemical speciation, catalysis and green chemistry). The forensic component of the course examines the gathering and analysis of evidence, using a variety of chemical techniques, and the development of specialised forensic techniques in the analysis of trace evidence. Students will also study forensic analyses of inorganic, organic and biological materials (dust, soil, inks, paints, documents, etc) in police, customs and insurance investigations and learn how a wide range of techniques are used to examine forensic evidence.

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.

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.

This unit introduces students to several related areas of discrete mathematics, which serve their interests for further study in pure and applied mathematics, computer science and engineering. Topics to be covered in the first part of the unit include recursion and induction, generating functions and recurrences, combinatorics. Topics covered in the second part of the unit include Eulerian and Hamiltonian graphs, the theory of trees (used in the study of data structures), planar graphs, the study of chromatic polynomials (important in scheduling problems).

The lectures in this unit of study introduce the "Central Dogma" of molecular biology and genetics -i.e., the molecular basis of life. The course begins with the information macromolecules in living cells: DNA, RNA and protein, and explores how their structures allow them to fulfill their various biological roles. This is followed by a review of how DNA is organised into genes leading to discussion of replication and gene expression (transcription and translation). The unit concludes with an introduction to the techniques of molecular biology and, in particular, how these techniques have led to an explosion of interest and research in Molecular Biology. The practical component complements the lectures by exposing students to experiments which explore the measurement of enzyme activity, the isolation of DNA and the 'cutting' of DNA using restriction enzymes. However, a key aim of the practicals is to give students higher level generic skills in computing, communication, criticism, data analysis/evaluation and experimental design.

The lectures in this unit of study introduce the "Central Dogma" of molecular biology and genetics, i.e., the molecular basis of life. The course begins with the information macro-molecules in living cells: DNA,RNA and protein, and explores how their structures allow them to fulfill their various biological roles. This is followed by a review of how DNA is organised into genes leading to discussion of replication and gene expression (transcription and translation). The unit concludes with an introduction to the techniques of molecular biology and, in particular, how these techniques have led to an explosion of interest and research in Molecular Biology. The practical component complements the lectures by exposing students to experiments which explore the measurement of enzyme activity, the isolation of DNA and the 'cutting' of DNA using restriction enzymes. However,a key aim of the practicals is to give students higher level generic skills in computing, communication, criticism, data analysis/evaluation and experimental design. The advanced component is designed for students interested in continuing in molecular biology. It consists of 7 advanced lectures (replacing 7 regular lectures) and 3 advanced laboratory sessions (replacing 3 regular practical classes). The advanced lectures will focus on the experiments which led to key discoveries in molecular biology. The advanced practical sessions will give students the opportunity to explore alternative molecular biology experimental techniques. Attendance at MBLG1999 seminars is strongly encouraged.

This unit examines the relationships among marketing organisations and final consumers in terms of production-distribution channels or value chains. It focuses on consumer responses to various marketing decisions (product mixes, price levels, distribution channels, promotions, etc.) made by private and public organisations to create, develop, defend, and sometimes eliminate, product markets. Emphasis is placed on identifying new ways of satisfying the needs and wants, and creating value for consumers. While this unit is heavily based on theory, practical application of the concepts to "real world" situations is also essential. Specific topics of study include: market segmentation strategies; market planning; product decisions; new product development; branding strategies; channels of distribution; promotion and advertising; pricing strategies; and customer database management.

This unit of study is for students who gained 65 marks or better in HSC Physics or equivalent. The lecture series contains three modules on the topics of mechanics, thermal physics, and oscillations and waves.

This unit of study is designed for students majoring in physical and engineering sciences and emphasis is placed on applications of physical principles to the technological world. The lecture series contains modules on the topics of fluids, electromagnetism, and quantum physics.

This unit of study is intended for students who have a strong background in Physics and an interest in studying more advanced topics. It proceeds faster than Physics 1 (Regular), covering further and more difficult material. The lecture series contains modules on the topics of mechanics, thermal physics, oscillations and waves and chaos. The laboratory work also provides an introduction to computational physics using chaos theory as the topic of study.

This unit of study is designed to build on the knowledge gained in Junior Physics, to provide Electrical Engineering students with the knowledge of relevant topics of Physics at the Intermediate level, and with associated skills. Completion of the unit provides a solid foundation for further studies in Electrical Engineering and related engineering areas. The aims of this unit are linked to the generic attributes required of graduates of the University in knowledge skills, thinking skills, personal skills and attributes, and practical skills. By the end of this unit of study, students will be able to describe and apply concepts in optics, electromagnetism and basic solid state physics and technology at the Intermediate level. They will be able to use computational techniques to analyze optics problems. The modules in this unit of study are: Optics (13 lectures): The wave nature of light, optical phenomena and the interaction of light with matter: interference and diffraction effects; fundamental limits to resolution of optical instruments; polarisation; dispersion; coherence. These are presented within the context of several key optical technologies including lasers, CD/DVD players, optical fibre communication systems, gratings and Mach Zehnder modulation. Electromagnetic Properties of Matter (12 lectures): Electric and magnetic effects in materials; the combination of electric and magnetic fields to produce light and other electromagnetic waves in vacuum and matter. Solid State and Device Physics (13 lectures): Introduction to quantum mechanics, Fermi-Dirac statistics, electronic properties of solids (metal, semiconductors and insulators), doping and the semiconductor PN junction; introduction to nanotechnology; fabrication technologies, nano-imaging technologies, nanoelectronics. Computational Physics (10 sessions of 2 hours each): In a computing laboratory students use Matlab-based simulation software to conduct virtual experiments in optics, which illustrate and extend the relevant lectures. Students also gain experience in the use of computers to solve problems in physics.