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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). 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.

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; 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.

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; 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.

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; or MATH 154 or 157, both with a grade of at least B. Students with credit for MATH 240 make not take this course for further credit. 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; or MATH 155/158 with a grade of at least B, MATH 232 or 240. Students with credit for MATH 310 may not take this course for further credit. Quantitative.

The fundamentals of graphical communication in order to help students think and communicate visually in the context of engineering design. The course focuses on concepts such as isometric, multi-view sketches, section view, and auxiliary views, tolerancing and dimensioning, as well as fundamentals of schematics and printed circuit boards design. Various computer aided design software are used. Students with credit for ENSC 104 or SEE 100 may not take MSE 100 for further credit.

The course teaches fundamentals of informative and persuasive communication for professional engineers and computer scientists in order to assist students in thinking critically about various contemporary technical, social, and ethical issues. It focuses on communicating technical information clearly and concisely, managing issues of persuasion when communicating with diverse audiences, presentation skills, and teamwork. Students with credit for CMPT 105W, SEE 101W, ENSC 102 or ENSC 105W may not take MSE 101W for further credit. Writing.

Reviews the different modes of thought characteristic of science, engineering and computing. Examines the histories and chief current research issues in these fields. Considers the ethical and social responsibilities of engineering and computing work. Students with credit for CMPT 106, ENSC 100 or ENSC 106 may not take MSE 102 for further credit. Breadth-Humanities/Sciences.

First year project course designed to provide students with a first exposure to the challenges of project organization. Students are responsible for designing and constructing a mechanical robot optimized to solve a particular chosen task. The engineering challenges of the project are expected to focus half on mechanical design and half on control algorithm design and implementation. Students with credit for ENSC 182 may not take MSE 110 for further credit.

An introduction to methods to collect and analyse engineering data. Topics include the Engineering data representation, Discrete and continuous probability density functions, Engineering measurements, Error analysis, Introduction to sensor interfaces, Introduction to physical sensors, Introduction to sensor signal conditioning, Noise, Test of hypotheses, Linear and nonlinear regression, and Design of experiments. Prerequisite: PHYS 141 or equivalent. MATH 150 or MATH 151. Students with credit for SEE 241, ENSC 280 or PHYS 231 may not take MSE 210 for further credit.

A course focusing on solving engineering problems with computational methods. Prerequisite: MATH 152 or equivalent, and MATH 232 or equivalent. Students with credit for MACM 316 or SEE 242 may not take this course for further credit.

Materials, their structures, properties and performance; crystal structures and instruments for structure determination; polymers, ceramics, and composites; quality control and reliability. Prerequisite: CHEM 120 or 121; PHYS 140 or 120. Students with credit for SEE 222, ENSC 231 or ENSC 330 may not take MSE 220 for further credit.

Covers fundamental concepts of Statics and Strength of Materials. Statics: 2D and 3D force and moment systems. equilibrium of rigid bodies, analysis of structures, distributed forces, centroids and moments of inertia. Strength of Materials: introduction to stress and strain, axial loading, torsion, pure bending, analysis and design of beams for bending and combined loading, deflection of beams, and transformation of stresses. Prerequisite: PHYS 140, MATH 152. Students with credit for SEE 221, ENSC 281 or ENSC 385 may not take this course for further credit.

Planar and 3D motions kinematics and kinetics of rigid bodies and mechanisms; linkages, gears, cams; synthesis and analysis of mechanisms; consideration of the static and dynamic forces in machines; vibration analysis, response to shock, motion and force transmissibility, vibration isolation. Prerequisite: PHYS 140, MATH 152, and (MATH 260 or MATH 310). Students with credit for ENSC 282 may not take MSE 222 for further credit.

Physical properties of fluids and fundamental concepts in fluid mechanics. Hydrostatics. Conservation laws for mass, momentum and energy. Flow similarity and dimensional analysis as applied to engineering problems in fluid mechanics. Laminar and turbulent flow. Engineering applications such as flow measurement, flow in pipes and fluid forces on moving bodies. Prerequisite: PHYS 140, MATH 251, and (MATH 260 or MATH 310). Students with credit for ENSC 283 or SEE 225 may not take MSE 223 for further credit.

This course will cover the following topics: fundamental electrical circuit quantities, and circuit elements; circuits laws such as Ohm law, Kirchoff's voltage and current laws, along with series and parallel circuits; operational amplifiers; network theorems; nodal and mesh methods; analysis of natural and step response of first (RC and RL), as well as second order (RLC) circuits; real, reactive and rms power concepts. In addition, the course will discuss the worker safety implications of both electricity and common laboratory practices such as soldering. Prerequisite: PHYS 141 or (PHYS 121 and 131), and MATH 232 and (MATH 260 or MATH 310). (MATH 260 or MATH 310) may be taken concurrently. Students with credit for SEE 230 or ENSC 220 may not take MSE 250 for further credit. Quantitative.

Introduces the basic electronic components, amplifiers, diodes, and oscillators. Fundamentals of logic design. Prerequisite: MSE 250 or ENSC 220 or SEE 230. Students with credit for SEE 231, ENSC 225 or ENSC 226 may not take MSE 251 for further credit.

The objectives of this course are to cover the modelling and analysis of continuous and discrete signals using linear techniques. Topics covered include: a review of Laplace transforms; methods for the basic modelling of physical systems; discrete and continuous convolution; impulse and step response; transfer functions and filtering; the continuous Fourier transform and its relationship to the Laplace transform; frequency response and Bode plots; sampling; the Z-transform. Prerequisite: MSE 250 (or ENSC 220) and (MATH 260 or MATH 310). Students with credit for ENSC 380 or SEE 341 may not take MSE 280 for further credit.

Covers topics in decision theory and engineering economics including: gap analysis, multi-attribute utility theory, discounted cash flow fundamentals, inflation, depreciation, tax, financial analysis, uncertaintly and optimization. Prerequisite: More than 75 units. Students with credit for SEE 300, ENSC 201, ENSC 311, ENSC 410 or ENSC 411 may not take MSE 300 for further credit.

This course provides an introduction to sensors and actuators for electromechanical, computer-controlled machines and devices. Topics include operating principles, design considerations, and applications of analog sensors, digital transducers, stepper motors, continuous-drive actuators, and drive system electronics. Component integration and design considerations are studied through examples selected from applications of machine tools, mechatronics, precision machines, robotics, aerospace systems, and ground and underwater vehicles. Laboratory exercises strengthen the understanding of component performance, system design and integration. Prerequisite: MSE 280 or ENSC 380. Students with credit for ENSC 387 may not take MSE 310 for further credit.

An introduction to microelectromechanical systems, covering thin film processing technologies, bulk and surface micromachining, and MEMS applications. Prerequisite: MSE 222 (or ENSC 282), MSE 251 (or ENSC 226). Students with credit for ENSC 331 may not take MSE 311 for further credit.

Interweaves mechanisms, electronics, sensors, and control strategies with software and information technology to examine the demands and ideas of customers and find the most efficient, cost-effective method to transform their goals into successful commercial products. Most of the term is devoted to a significant design project in which student groups work independently and competitively, applying the design process to a project goal set by the faculty co-ordinator. Prerequisite: MSE 110 (or ENSC 182), MSE 320 (or ENSC 382), MSE 381 (or ENSC 383). MSE 381 may be taken concurrently. Students with credit for ENSC 384 may not take MSE 312 for further credit.

Review of stress and strain in solids, superposition, energy theorems, theories of failure, elastic and inelastic analysis of symmetrical bending, torsion of circular members, and virtual work. Adequacy assessment and synthesis of machine elements with a focus on the design process. Static failure of ductile and brittle materials, fatigue analysis of structures. Topics include the design of welds, bolted connections, springs and shafts. Solution strategies include both analytical and finite element methods. Prerequisite: MSE 100 or ENSC 104, MSE 220 or ENSC 231, MSE 221 or ENSC 281. MSE 100 may be taken concurrently. Students with credit for ENSC 382 may not take MSE 320 for further credit.

Energy transfer as work and heat, the First Law of thermodynamics. Properties and states of simple substances. Control-mass and control-volume analyses. Entropy, the Second Law of thermodynamics. Carnot cycle. Energy conversion systems; internal combustion engines, power plants and refrigeration cycles. Heat transfer by conduction, convection, and radiation. Formulation and solution of steady and transient problems. Cooling of microelectronics, thermal solutions. Prerequisite: MATH 251, PHYS 140, and MSE 223. Students with credit for ENSC 388 may not take MSE 321 for further credit.

Introduction to digital systems and number representation. Combinational systems and sequential logic. Counter design and registers. Synchronous sequential design. Microprocessor applications, memory and I/O systems. Microcontrollers: features, architecture and programming model. Introduction to assembly language and microcontroller programming. Addressing modes, assembling and linking programs. Timer/counter programming. ADC, DAC, and sensor interfacing. Prerequisite: CMPT 130 and either MSE 251 or ENSC 226.

3-phase circuits, power quality, and transformers, Characteristic of power semiconductor devices, Line frequency controlled rectifiers, Buck, boost, and buck-boost dc-dc power converters, Pulse Width Modulation (PWM) techniques, Voltage source inverters and full-bridge topology, Introduction to dc machines, Introduction to stepper motors, Introduction to induction motors, Introduction to synchronous machines. Prerequisite: MSE 251 (previously ENSC 226). Students with credit for SEE 331 may not take MSE 353 for further credit.

Introduction to systems modeling and analysis. Application to engineering systems including: mechanical, electrical, thermal, and fluid systems. Allows the student to acquire, in a time-efficient and uncomplicated manner, knowledge in the formation and construction of dynamic models. The simulation models that the student will design in this course accommodate these analyses, with the construction of realistic hypotheses and elaborate behavior models. Prerequisite: MSE 221 (or ENSC 281 or SEE 221), MSE 222 (or ENSC 282), MSE 280 (or ENSC 380 or SEE 341). Students with credit for ENSC 381 may not take MSE 380 for further credit.

This course is an introduction to the analysis, design, and applications of continuous time linear control systems. Topics include transfer function representation of open and closed loop systems, time domain specifications and steady state error, sensitivity analysis, time and frequency response, and stability criteria. It includes a treatment of methods for the analysis of control systems based on the root locus, Bode plots and Nyquist criterion, and their use in the design of PID, and lead-lag compensation. Lab work is included in this course. Prerequisite: MSE 280 (or ENSC 380). Students with credit for ENSC 383 or SEE 342 may not take MSE 381 for further credit.

This course provides an introduction to the engineering profession, professional practice, engineering law and ethics, including the issues of worker and public safety. It also offers opportunities to explore the social implications and environmental impacts of technologies, including sustainability, and to consider engineers' responsibility to society. Prerequisite: 100 units including one of MSE 102, ENSC 100, ENSC 106, or CMPT 106. Students with credit for ENSC 406 or SEE 402 may not take MSE 402 for further credit.

Through the development of a business plan, MSE 405W simulates entrepreneurial activities associated with launching a technology-based start-up company. In a traditional lecture and tutorial format, students are introduced to practical and theoretical business subject-matter in engineering. Students participate in a team project and use collaborative writing strategies to produce a business plan and presentation relating to a technology-based start-up venture. Components of the business plan are submitted in multiple stages including a concept summary, proposal, marketing and operation plans, and executive summary. Prerequisite: MSE 300 or ENSC 311. Students with credits for ENSC 312 may not take this course for further credit. Writing.

Students will combine their technical and mechatronic design knowledge to conceive, and design a product. A comprehensive report is required at the end of the term. Prerequisite: Completion of at least 24 units from the upper division list of MSE curriculum courses and completion of two co-op terms (MSE 293 or MSE 294 and MSE 393 or MSE 394). Must not be taken concurrently with MSE 493 or MSE 494. Students with credit for ENSC 405W or SEE 410W may not take this course for further credit.

Students will apply their technical knowledge to develop a prototype system representing a product that was designed earlier in MSE 410. Students will then present it to a panel of engineers, faculty and student members. Prerequisite: MSE 410. Must not be taken concurrently with MSE 493 or MSE 494. Students with credit for ENSC 442 or SEE 411 may not take MSE 411 for further credit.

Supervised study, research and preliminary work leading to a formal proposal for the thesis project work in MSE 499. This activity can be directly augmented by other course work and by directed study. The locale of the work may be external to the University or within a University laboratory, or may bridge the two locations. Supervision may be by technical personnel at an external organization, or by faculty members, or through some combination. At least one of the supervisors must be a registered professional engineer. A plan for the student's MSE 498 activities must be submitted to the school at the time of enrolment in the course. Completion of the undergraduate thesis project proposal is the formal requirement of this course and the basis upon which it is graded. Grading will be on a pass/fail basis. Prerequisite: At least 115 units or permission of the academic supervisor.

A thesis is based on the research or development project that incorporates a significant level of engineering design. This work is typically undertaken in the student's final year, but in no case before the student has completed 115 units. Registration for MSE 499 takes place in the term in which the thesis will be presented and defended. The locale of the work, supervision and other arrangements follow those for MSE 498. Grading of the thesis will be on a pass/fail basis, but recognition will be given to outstanding work. Prerequisite: MSE 498.

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, 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.

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 has the same lecture component as CHEM 121 but no laboratory work. Students who intend to take further courses in chemistry should also take CHEM 125 or alternatively take CHEM 121 instead. Prerequisite: Chemistry 12 with a minimum grade of C, or CHEM 110 or 111 with a minimum grade of C-. Students with credit for CHEM 121 or CHEM 123 may not take this course for further credit. Quantitative/Breadth-Science.

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 C, 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.

Supervised study, research and preliminary work leading to a formal proposal for the thesis project work in MSE 499. This activity can be directly augmented by other course work and by directed study. The locale of the work may be external to the University or within a University laboratory, or may bridge the two locations. Supervision may be by technical personnel at an external organization, or by faculty members, or through some combination. At least one of the supervisors must be a registered professional engineer. A plan for the student's MSE 498 activities must be submitted to the school at the time of enrolment in the course. Completion of the undergraduate thesis project proposal is the formal requirement of this course and the basis upon which it is graded. Grading will be on a pass/fail basis. Prerequisite: At least 115 units or permission of the academic supervisor.

A thesis is based on the research or development project that incorporates a significant level of engineering design. This work is typically undertaken in the student's final year, but in no case before the student has completed 115 units. Registration for MSE 499 takes place in the term in which the thesis will be presented and defended. The locale of the work, supervision and other arrangements follow those for MSE 498. Grading of the thesis will be on a pass/fail basis, but recognition will be given to outstanding work. Prerequisite: MSE 498.