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Students will build collaborative and creative skills necessary to become effective innovators through hands-on application via interdisciplinary teamwork. Entrepreneurship and innovation of all types will be addressed including social, commercial, creative, sustainable and technological perspectives. Prerequisite: 12 units. Breadth-Social Sciences.

An introduction to computing science and computer programming, using a systems oriented language, such as C or C++. This course introduces basic computing science concepts. Topics will include: elementary data types, control structures, functions, arrays and strings, fundamental algorithms, computer organization and memory management. Prerequisite: BC Math 12 (or equivalent, or any of MATH 100, 150, 151, 154, or 157, with a minimum grade of C-). Students with credit for CMPT 102, 120, 128 or 166 may not take this course for further credit. Students who have taken CMPT 125, 129 or 135 first may not then take this course for further credit. Quantitative/Breadth-Science.

A second course in systems-oriented programming and computing science that builds upon the foundation set in CMPT 130 using a systems-oriented language such as C or C++. Topics: a review of the basic elements of programming; introduction to object-oriented programming (OOP); techniques for designing and testing programs; use and implementation of elementary data structures and algorithms; introduction to embedded systems programming. Prerequisite: CMPT 130 with a minimum grade of C-. Students with credit for CMPT 125, 126, or 129 may not take this course for further credit. Quantitative.

Riemann sum, Fundamental Theorem of Calculus, definite, indefinite and improper integrals, approximate integration, integration techniques, applications of integration. First-order separable differential equations and growth models. Sequences and series, series tests, power series, convergence and applications of power series. Prerequisite: MATH 150 or 151, with a minimum grade of C-; or MATH 154 or 157 with a grade of at least B. Students with credit for MATH 155 or 158 may not take this course for further credit. Quantitative.

Linear equations, matrices, determinants. Introduction to vector spaces and linear transformations and bases. Complex numbers. Eigenvalues and eigenvectors; diagonalization. Inner products and orthogonality; least squares problems. An emphasis on applications involving matrix and vector calculations. Prerequisite: MATH 150 or 151 or MACM 101, with a minimum grade of C-; or MATH 154 or 157, both with a grade of at least B. Students with credit for MATH 240 may not take this course for further credit. Quantitative.

Rectangular, cylindrical and spherical coordinates. Vectors, lines, planes, cylinders, quadric surfaces. Vector functions, curves, motion in space. Differential and integral calculus of several variables. Vector fields, line integrals, fundamental theorem for line integrals, Green's theorem. Prerequisite: MATH 152 with a minimum grade of C-; or MATH 155 or MATH 158 with a grade of at least B. Recommended: It is recommended that MATH 240 or 232 be taken before or concurrently with MATH 251. Quantitative.

First-order differential equations, second- and higher-order linear equations, series solutions, introduction to Laplace transform, systems and numerical methods, applications in the physical, biological and social sciences. Prerequisite: MATH 152 with a minimum grade of C-; or MATH 155 or 158, with a grade of at least B; MATH 232 or 240, with a minimum grade of C-. Students with credit for MATH 310 may not take this course for further credit. Quantitative.

A general calculus-based introduction to mechanics taught in an integrated lecture-laboratory environment. Topics include translational and rotational motion, momentum, energy, gravitation, and selected topics in modern physics. Prerequisite: BC Principles of Physics 12, or PHYS 100 or equivalent, with a minimum grade of C-. Corequisite: MATH 150 or 151 or 154. Students with credit for PHYS 125 or 120 or 101 may not take this course for further credit. Quantitative/Breadth-Science.

A general calculus-based introduction to electricity, magnetism and optics taught in an integrated lecture-laboratory environment. Topics include electricity, magnetism, simple circuits, optics and topics from applied physics. Prerequisite: PHYS 120 or PHYS 125 or PHYS 140 or MSE 103, with a minimum grade of C-, or PHYS 101 with a minimum grade of B. Corequisite: MATH 152 or MATH 155. Students with credit for PHYS 126 or 121 or 102 may not take this course for further credit. Quantitative/Breadth-Science.

An interdisciplinary approach to transforming energy systems in pursuit of sustainable climate and society. Perspectives include thermodynamics, resource potentials, technological potentials, economic evaluation, implementation of transformative public policies, political-economy assessment of policy constraints, national and sub-national governance options, behavioural change potentials, global diplomacy, and pursuit of greater equity within and between countries. Prerequisite: 45 units. Breadth-Social Sciences.

Introduction to graphical communication in the context of engineering design. Students learn to think and communicate visually. With the use of computer aided design (CAD) tools, students learn the theory and practice of design by dissecting, graphically representing, and redesigning products. Students with credit for MSE 100 or IAT 106 may not take this course for further credit.

Fundamentals of communicating technical information clearly and concisely for professional engineers. A focus on communicating persuasively about various contemporary technical, social, ethical and environmental issues with technical and non-technical audiences. Students will practice providing constructive feedback to peers, giving presentations and working in a team. Students with credit for CMPT 105W, ENSC 102, ENSC 105W, or MSE 101W may not take this course for further credit. Writing.

Energy availability and sources, environmental consequences of energy supply and consumption, and societal impacts. Explores the environmental, economic, social, and political implications of the choices a society makes to meet its energy needs. Definitions of sustainability. Special emphasis on communication skills.

Introduction to the process of sustainable engineering design. Historical perspective on role of energy, resources and technology in society. Development and demonstration of sustainability thinking through research, case study and design project undertaken by teams of students with integration of socio-economic factors and planning. Course introduces Project Based Learning methods. Prerequisite: SEE 110.

Introduction to solid mechanics including statics, stress, strain, and deformation. Equilibrium conditions, axial loading, torsional loading, pure bending, stresses and deflections in rods and beams. Prerequisite: PHYS 140, MATH 152. Students with credit for ENSC 281, MSE 221, or ENSC 385 may not take this course for further credit.

Introduction to engineering materials by control of their structures to achieve different properties and performance. Techniques for modern materials engineering practice. Covers crystal and non-crystal structures and instruments for structure determination; principles of material failure, polymers, ceramics, nano-materials, and composites; electronic materials, and electro-chemical energy materials; quality control and reliability. Prerequisite: PHYS 140, CHEM 121 or (CHEM 122 and CHEM 126). Students with credit for MSE 220 or ENSC 330 may not take this course for further credit.

Basic energy concepts and definitions; first and second laws of thermodynamics; ideal and real gases; thermodynamic properties; with emphasis on analysis and applications to energy systems engineering. Prerequisite: MATH 251.

The fundamentals of fluid mechanics for engineers, emphasizing the basics of fluid statics and fluid motion, with applications in energy system engineering. Prerequisite: PHYS 140, MATH 251, (MATH 260 or MATH 310). Students with credit for ENSC 283 or MSE 223 may not take this course for further credit.

Fundamental elements of electrical circuits; circuit laws; series-parallel circuits; charging and discharging characteristics of DC RL and RC circuits, methods of circuit analysis including network theorems; mesh and nodal analysis; Real, Reactive and Apparent power calculation, capacitor sizing and power factor improvement. Covers safety implications of electricity and common laboratory practices. Prerequisite: PHYS 141, MATH 232. Corequisite: (MATH 260 or MATH 310). Students with credit for ENSC 220 or MSE 250 may not take this course for further credit.

Analysis of the basic electronic components, amplifiers, diodes, semiconductors, transistors and MOSFETs. Introduction to specific instrumentation, including actuators and sensors. Design of electronic circuits based on real world scenarios. Prerequisite: SEE 230. Students with credit for MSE 251 or ENSC 225 may not take this course for further credit.

An introduction to methods for collecting and analysing engineering data. Topics include engineering data representation, probability density functions, engineering measurements, error analysis, test of hypotheses, regression, and design of experiments. Prerequisite: PHYS 141, MATH 232. Corequisite: MATH 251. Students with credit for ENSC 280 and MSE 210 may not take this course for further credit.

Apply numerical methods to solve engineering problems with an emphasis on sustainable energy engineering. Prerequisite: MATH 152, MATH 232. Students with credit for MSE 211 may not take this course for further credit.

Principles, operation, and analysis of three phase systems, magnetic circuits, transformers and electromechanical energy conversion systems and their applications. Prerequisite: SEE 230, SEE 221, (MATH 260 or MATH 310).

Economic and entrepreneurial concepts important to engineers who manage projects, run businesses, or need to decide on the most efficient method for accomplishing a task. Topics include: financial accounting and metrics, economic equivalence, rates of return, depreciation, income taxes, project and cost-benefit analyses, capital budgeting, financing methods, risk and uncertainty, business plans. Prerequisite: A minimum of 65 units OR a minimum of 55 units plus two-term co-op work. Students with credit for MSE 300 may not take this course for further credit.

Integrated design methodology for sustainable engineering problems; implementation through an energy system project undertaken in a project based learning environment. Introduction to modelling, simulation and optimization of energy systems. Global and local regulatory and policy frameworks. Demonstration of integrated sustainability thinking through design project, report and presentation. Special emphasis on communication skills. Prerequisite: Completion of one co-op work term; SEE 251, 224, 242.

Introduces the basic principles of heat and mass transfer with analysis and application to real-world sustainable energy systems. Prerequisite: PHYS 141, SEE 224, SEE 225.

Introduction to the fundamentals of power electronic circuits, components, and operation, and principles of electric power conversion in DC and AC applications. Prerequisite: SEE 231 and SEE 251. Students with credit for MSE 353 may not take this course for further credit.

Interconnected power systems including generators, transformers, electric motors and transmission lines; active and reactive power flow; symmetrical components; symmetrical and unsymmetrical short circuit fault calculations; protection systems, circuit breakers, transient stability, and grid voltage and frequency control. Labs, field trips and projects related to power grid operation, control, and design. Prerequisite: SEE 251, SEE 331.

Modelling and analysis of continuous and discrete signals using linear techniques. Laplace transforms; methods for basic modelling of physical systems; discrete and continuous convolution; impulse and step response; transfer functions and filtering; continuous Fourier transform and its relationship to the Laplace transform; frequency response and Bode plots; sampling; Z-transform. Prerequisite: SEE 242, SEE 230. Students with credit for MSE 280 or ENSC 380 may not take this course for further credit.

Fundamentals of feedback control system design and analysis, including practical and theoretical aspects. Significant lab component in which students design controllers and evaluate their robustness to modeling errors and nonlinearities. Prerequisite: SEE 341. Students with credit for ENSC 383 or MSE 381 may not take this course for further credit.

Combines biotechnology and engineering for materials and energy harvesting for a broad range of industrial and environmental applications. Offers an in-depth understanding of underlying principles of bioprocesses, which leads to design and operation of a variety of innovative biosensors, control systems and full-scale bioreactors. Sustainable engineering applications include food processing and preservation, biofuel production, and energy generation from waste streams. Prerequisite: (MATH 260 or MATH 310), and SEE 224. Corequisite: SEE 324. MSE students who completed MSE 321 can take this course upon approval of the course instructor.

Application of thermodynamics, chemistry, and transport physics to energy conversion technologies and systems. Analysis of energy conversion systems with emphasis on efficiency, performance, and environmental impact. Prerequisite: SEE 222, SEE 224.

The characteristics, applications, limitations, and environmental impacts of various energy storage technologies and techniques are analyzed, compared and implemented in a lab setting. Electrochemical, mechanical, thermal and emerging energy storage options are considered. Prerequisite: SEE 222, SEE 331, SEE 324.

An introduction to the engineering profession, law and ethics, and the engineers' responsibility to society. Students will explore issues related to worker and public safety and the social implications and environmental impacts of engineering. Includes how to successfully negotiate the transition to the next career stage. Special emphasis on communication skills. Prerequisite: SEE 110; Minimum of 100 units OR 80 units plus two-term co-op work. Students with credit for ENSC 406 or MSE 402 may not take this course for further credit.

Focuses on project management, technical writing skills, and teamwork skills and strategies within the context of an engineering design project. Documentation includes project proposal, project management plan, design concept, and detail design providing functional and design specifications. A final group presentation is required. A first in a two-course capstone sequence. SEE 411 must be taken in the term directly following the successful completion of SEE 410W. Grades awarded in SEE 410W are conditional on the successful completion of SEE 411 in the subsequent term. Prerequisite: Completion of at least 24 units from the upper division list of SEE courses and completion of two co-op terms. SEE students cannot take MSE 410, MSE 411, ENSC 405W or ENSC 440 for further credit. Writing.

This is the second course in the team-based, two-course capstone sequence. Students synthesize their learning across the SEE program to research, design, build and test the hardware and/or software implementation of a working system. Includes shop training workshops, engineering standards on how to design for safety, and human factors. Final output will include a prototype or other proof-of-concept, a final presentation, and other documentation commensurate to the needs of the project. Prerequisite: SEE 410W. Must be taken in the term immediately following 410W. In order to obtain credit, students must successfully complete both SEE 410W and SEE 411. SEE students cannot take MSE 410, MSE 411, ENSC 405W or ENSC 440 for credit.

Introduction and application of Finite Element Analysis (FEA) to energy systems design problems involving engineering mechanics, heat transfer and machine elements. Includes an introduction to commercial FEA software and applications to practical problems. Concepts relating to engineering mechanics and machine elements are developed in the context of design projects. Prerequisite: SEE 100, SEE 221, and SEE 324.

Fundamentals of communication networks: reference models, layered architecture. Physical layer analysis and design. Performance analysis of communication protocols at the data link, network, and transport layers. Medium access control, congestion control, routing. Network security, privacy, and social issues. Tools for simulation and analysis of communication networks. Prerequisite: SEE 341.

Designed for students specializing in mathematics, physics, chemistry, computing science and engineering. Topics as for Math 151 with a more extensive review of functions, their properties and their graphs. Recommended for students with no previous knowledge of Calculus. In addition to regularly scheduled lectures, students enrolled in this course are encouraged to come for assistance to the Calculus Workshop (Burnaby), or Math Open Lab (Surrey). Prerequisite: Pre-Calculus 12 (or equivalent) with a grade of at least B+, or MATH 100 with a grade of at least B-, or achieving a satisfactory grade on the ¶¡ÏãÔ°AV Calculus Readiness Test. Students with credit for either MATH 151, 154 or 157 may not take MATH 150 for further credit. Quantitative.

Designed for students specializing in mathematics, physics, chemistry, computing science and engineering. Logarithmic and exponential functions, trigonometric functions, inverse functions. Limits, continuity, and derivatives. Techniques of differentiation, including logarithmic and implicit differentiation. The Mean Value Theorem. Applications of differentiation including extrema, curve sketching, Newton's method. Introduction to modeling with differential equations. Polar coordinates, parametric curves. Prerequisite: Pre-Calculus 12 (or equivalent) with a grade of at least A, or MATH 100 with a grade of at least B, or achieving a satisfactory grade on the ¶¡ÏãÔ°AV Calculus Readiness Test. Students with credit for either MATH 150, 154 or 157 may not take MATH 151 for further credit. Quantitative.

Atomic and molecular structure; chemical bonding; thermochemistry; elements; periodic table; gases liquids, solids, and solutions. This course includes a laboratory component. Prerequisite: Chemistry 12 with a minimum grade of B, or CHEM 109 or 111 with a minimum grade of C-. Students with credit for CHEM 120 or 125 may not take this course for further credit. Quantitative/Breadth-Science.

Chemical equilibria; electrochemistry; chemical thermodynamics; kinetics. Students who intend to take further laboratory courses in chemistry should take CHEM 122 concurrently with CHEM 126. Prerequisite: CHEM 120 or 121 with a minimum grade of C-. Students with credit for CHEM 124 or CHEM 180 may not take this course for further credit. Quantitative.

Experiments in chemical equilibrium, acids and bases, qualitative analysis, electrochemistry and chemical kinetics. Prerequisite: CHEM 121 with a minimum grade of C-. Corequisite: CHEM 122. Quantitative.

An introduction to the design of Very Large Scale Integrated (VLSI) circuits and systems (System-on-Chip, SoC) using mainly CMOS technology. SoC design techniques and applications will be covered. Basic topics will include: CMOS technology and circuit layout rules; combinational and sequential logic; logic simulation; systems design; design for verification and testability; and embedded-processor design and application. An advanced digital design flow based on the VHDL hardware description language will be introduced and exercised in the labs. Prerequisite: (ENSC 225 or MSE 251 or SEE 231) and ENSC 350, all with a minimum grade of C- and a minimum of 80 units.

Lectures provide the theory of integrated circuit fabrication. Students fabricate diodes, transistors and test structures in the laboratory. Topics: clean room practice, thermal oxidation and diffusion, photolithography, thin film deposition, etching, ion implantation, packaging, CMOS and bipolar processes. Prerequisite: ENSC 225 or MSE 251 or PHYS 365 or SEE 231, with a minimum grade of C- and permission of the instructor and a minimum of 80 units. Enrollment in this course is by application only.

An introduction to manufacturing systems: industrial robotics, manufacturing system components and definitions, material handling systems, production lines, assembly systems, robotic cell design, cellular manufacturing, flexible manufacturing systems, quality control, manufacturing support systems. Prerequisite: MSE 310 (or ENSC 387)and a minimum of 80 credits. Students with credit for ENSC 432 may not take MSE 480 for further credit.

Examines modern industrial control systems and applications. Topics include: review of industrial sensors and actuators; computer interfacing; ladder logic and programmable logic controllers; industrial computer and programming methods; industrial networks; human-machine interfaces; supervisory control and data acquisition (SCADA); manufacturing execution systems; and enterprise-wide integration. Prerequisite: MSE 352 (or ENSC 252) and MSE 381 (or ENSC 383) and a minimum of 80 credits. Students with credit for ENSC 484 may not take MSE 481 for further credit.

Additive manufacturing processes; Design for additive manufacturing; Problem-based additive manufacturing, Project-based additive manufacturing; Light-based 3D printing, Metal 3D printing. Extrusion-based 3D printing; 3D printed electronics; Direct digital manufacturing; 4D printing. Prerequisite: SEE 100, SEE 221, SEE 222.

Electronics manufacturing and assembly technologies and processes in the context of sustainability. PCB and interconnect technologies, component selection and handling, material properties and selection, thermal, mechanical and environmental effects, product testing, environmental and legal standards. Prerequisite: SEE 221, SEE 231.

Manufacturing processes and Engineering materials in the context of sustainable manufacturing. Manufacturing technologies and process flow. Productivity and green manufacturing practices. Engineering material selection. Manufacturing processes including forming, separating, fabrication, conditioning and finishing. Prerequisite: SEE 221, SEE 310.

Implementation and design of embedded computer systems used in various real-time applications including energy systems, power electronics, and automation. Prerequisite: CMPT 130, SEE 231.

Introduction to modeling energy systems for buildings, focusing on envelope and mechanical systems, and their effects on energy use. Using the applicable codes and standards to define schedules for the buildings, calculate heating and cooling loads, and set sustainability targets. Applying industry standard software to model, and experiment with innovative methods to enhance energy use, and reach sustainability targets. Prerequisite: SEE 310 and SEE 324. MSE students who completed MSE 321 can take this course upon approval of the course instructor.

Special topics in sustainable energy engineering. Students may repeat this course for further credit under a different topic. Prerequisite: Permission of the undergraduate curriculum chair.

Special topics in sustainable energy engineering. Students may repeat this course for further credit under a different topic. Prerequisite: Permission of the undergraduate curriculum chair.

Special topics in sustainable energy engineering. Students may repeat this course for further credit under a different topic. Prerequisite: Permission of the undergraduate curriculum chair.

An empirical and theoretical examination of the geographical aspects of transportation systems. Prerequisite: At least 45 units, including GEOG 100.

Contemporary cases and conceptualizations of gentrification and related processes of urban change. Central themes include: political, economic, social, and cultural manifestations of gentrification; class, gender, and racialization; the role of development, planning, architecture, the arts, and resistance movements; and gentrification’s global geographies. Prerequisite: At least 45 units, including GEOG 100. Students with credit for GEOG 362 may not take this course for further credit. Writing.

Contemporary cases and conceptualizations of gentrification and related processes of urban change. Central themes include: political, economic, social, and cultural manifestations of gentrification; class, gender, and racialization; the role of development, planning, architecture, the arts, and resistance movements; and gentrification’s global geographies. Prerequisite: At least 45 units, including GEOG 100. Students with credit for GEOG 362W may not take this course for further credit.