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Mechanical Engineering: A course to allow the introduction of new topics in Mechanical Engineering as needs arise, by regular and visiting staff.

Offered by: Mechanical Engineering

• (3-0-6)

• Terms
  • Fall 2024
  • Winter 2025
• Instructors
  • Changhong Cao
  • Andrew J Higgins

Mechanical Engineering: A course to allow the introduction of new topics in Mechanical Engineering as needs arise, by regular and visiting staff.

Offered by: Mechanical Engineering

• (3-0-6)

• Terms
  • Winter 2025
• Instructors
  • Audrey Sedal

Mechanical Engineering: A course to allow the introduction of new topics in Mechanical Engineering as needs arise, by regular and visiting staff.

Offered by: Mechanical Engineering

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Vibratory and acoustic disturbances propagated in homogeneous media. Modelling of acoustic systems using lumped-parameters. Simple sound wave fields, transverse waves in strings and bars, longitudinal waves in bars, and transverse waves in membranes, beams, and plates. Basic wave propagation phenomena and sound source models.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisites: MATH 271 and MECH 315
• Offered only in even years.

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: State-space modelling and related linear algebra. Controllability and observability of linear time-invariant systems and corresponding tests, system realizations. Stability: Bounded-Input-Bounded-Output (BIBO), internal, Lyapunov. Linear state feedback control: pole placement and root locus design methods, linear quadratic regulator. State observers: full- and reduced-order designs, separation principle, Linear Quadratic Gaussian (LQG) design. Introduction to optimal control and optimal state estimation.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite: MECH 412 or MECH 419.

• Terms
  • Winter 2025
• Instructors
  • James R Forbes

Mechanical Engineering: Fundamentals of unsteady gasdynamics. Shock and detonation waves in gases and condensed material. Condensed explosives: hydrodynamic theory, equations of state, initiation. Shock interactions. Blast wave theory, similarity methods, blast scaling.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisites: MECH 341, MECH 430.
• Restriction: Not open to students who have taken MECH 615

• Terms
  • Winter 2025
• Instructors
  • Evgeny Timofeev

Mechanical Engineering: Fundamentals of computational fluid dynamics. Numerical methods for hyperbolic conservation laws: first- and higher-order upwind schemes; monotonicity and Godunov theorem; total-variation-diminishing schemes; Riemann solvers; treatment of source terms; multi-dimensional methods. Introduction to grid generation and adaptation. Methodology for the comparison of numerical and experimental results.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite(s): MECH 430 or permission of instructor

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: A study of the present impact of computers and automation on manufacturing. Computer-aided systems. Information modelling. Information system structures. Study of several types of production systems. Integration issues: inter-and intra-enterprise. Laboratory experience with manufacturing software systems.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite: Permission of the instructor

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: A study of the design issues present in product life cycle demands. Computer-aided systems. Rapid prototyping. Design for manufacturability. Integration of mechanics, electronics and software in products. Effect on design of product cost, maintainability, recycling, marketability.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite (Undergraduate): Permission of the instructor
• **This course will be held on July 14-26, 31, August 1, 2 and there will be an exam due on August 16, 2020.
• **Due to the intensive nature of this course, the standard add/drop and withdrawal deadlines do not apply. Add/drop is the first lecture day and withdrawal is the second lecture day.

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Fiber-reinforced composites. Stress, strain, and strength of composite laminates and honeycomb structures. Failure modes and failure criteria. Environmental effects. Manufacturing processes. Design of composite structures. Computer modelling of composites. Computer techniques are utilized throughout the course.

Offered by: Mechanical Engineering

• (3-0-6)
• Corequisite: MECH 321 or equivalent/instructor's permission.

• Terms
  • Fall 2024
• Instructors
  • Larry Lessard

Mechanical Engineering: Kinematics and dynamics of a UAV. Aerodynamic forces and moments on a fixed-wing UAV. Application of linear systems analysis for fixed-wing UAVs. Flight control and autopilots for UAVs. Navigation sensors and state estimation based on Kalman filtering. Guidance strategies and the basics of path planning.

Offered by: Mechanical Engineering

• 3-0-6
• Prerequisite: MECH 412 or MECH 419 or Permission of the Instructor

• Terms
  • Fall 2024
• Instructors
  • Inna Sharf

Mechanical Engineering: Aircraft performance criteria such as range, endurance, rate of climb, maximum ceiling for steady and accelerated flight. Landing and take-off distances. Static and dynamic stability in the longitudinal (stick-fixed and stick-free) and coupled lateral and directional modes. Control response for all three modes.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite (Undergraduate): (MECH 412 or MECH 419), MECH 533
• Prerequisite (Graduate): MECH 533

• Terms
  • Winter 2025
• Instructors
  • Meyer Nahon

Mechanical Engineering: Kinematics: equations of motion; vorticity and circulation, conformal mapping and flow round simple bodies. Two-dimensional flow round aerofoils. Three-dimensional flows; high and low aspect-ratio wings; airscrews. Wind tunnel interference. Similarity rules for subsonic irrotational flows.

Offered by: Mechanical Engineering

• (3-1-5)
• Prerequisite (Undergraduate): MECH 331

• Terms
  • Fall 2024
• Instructors
  • Jovan Nedic

Mechanical Engineering: Pollutants from power production and their effects on the environment. Mechanisms of pollutant formation in combustion. Photochemical pollutants and smog, atmospheric dispersion. Pollutant generation from internal combustion engines and stationary power plants. Methods of pollution control (exhaust gas treatment, absorption, filtration, scrubbers, etc.).

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite (Undergraduate): MECH 331, MECH 341.

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Introduction to propulsion: turboprops, turbofans and turbojets. Review of thermodynamic cycles. Euler turbine equation. Velocity triangles. Axial-flow compressors and pumps. Centrifugal compressors and pumps. Axial-flow turbines. Loss mechanisms. Dimensional analysis of turbomachines. Performance maps. 3-D effects. Introduction to numerical methods in turbomachines. Prediction of performance of gas turbines.

Offered by: Mechanical Engineering

• (3-0-6)
• Corequisites: MECH 430
• Prerequisite: MECH 331.

• Terms
  • Fall 2024
• Instructors
  • Wagdi George Habashi

Mechanical Engineering: Aircraft and spacecraft structural components and loads. Bending, shear, torsion and buckling of thin-walled open and closed sections. Structural idealization. Principle of stiffener / web construction. Trusses and isogrid structures. Wing spars and box beams. Fuselage frames and wing ribs. Analysis of riveted, bolted and adhesive joints. Sandwich structures analysis. Thermoelasticity analysis for spacecraft structures.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite: MECH 321 or equivalent
• Restriction: Not open to students who have taken MECH 432.

• Terms
  • Fall 2024
• Instructors
  • Christopher Mruczek

Mechanical Engineering: Fundamental equations. Basic flow singularities. Boundary element methods. Source, doublet and vortex panel methods for 2D and 3D incompressible and compressible flows. Method of characteristics. Euler equations for inviscid rotational flows. Finite-difference and finite-volume methods. Explicit and implicit time-integration methods. Quasi 1D solutions. Nozzle and confined aerofoil applications.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite: MECH 309 or MATH 317, MECH 533.

• Terms
  • Winter 2025
• Instructors
  • Sivakumaran Nadarajah

Mechanical Engineering: Review of central force motion; Hohmann and other coplanar transfers, rotation of the orbital plane, patched conic method. Orbital perturbations due to the earth's oblateness, solar-lunar attraction, solar radiation pressure and atmospheric drag. Attitude dynamics of a rigid spacecraft; attitude stabilization and control; attitude manoeuvers; large space structures.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite (Undergraduate): MECH 220. Corequisite: MECH 412 or MECH 419

• Terms
  • Fall 2024
• Instructors
  • Mahdi Chehreghani

Mechanical Engineering: Material systems/selection process. Cost vs. performance. Laminate layup procedures. Theory and application of filament winding of composite cylinders. Regular oven and autoclave oven curing, analysis of resulting material performance. Practical design considerations and tooling. Analysis of environmental considerations. Joining techniques. Analysis of test methods. Theory of repair techniques.

Offered by: Mechanical Engineering

• (3-3-3)
• Prerequisite: MECH 530

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Mechanics of proteins (collagen, keratin), polysaccharides (cellulose, chitin), cells, skin, bone, teeth, seashells, insect and arthropod cuticles. Emphasis on microstructure-property-function relationships and on multiscale approach. State-of-the-art experimental and modelling techniques. Self-healing and adaptive biological materials.

Offered by: Mechanical Engineering

• (3-1-5)
• Prerequisites: MECH 210, MIME 260 or MIME 261, or permission of instructor

• Terms
  • Winter 2025
• Instructors
  • Jianyu Li

Mechanical Engineering: Overview of hierarchical solids exhibiting cellular structure. Cell size, shape and topology of bending and stretching dominated materials, including periodic microtruss lattice, plant cellular tissue and trabecular bone. Theories for modelling the mechanics and the physical properties; design and optimization of multifunctional cellular solids for ultralight aerospace and biomedical applications.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisites: MECH 210, MIME 260 or MIME 261, or permission of instructor

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Introduction to continuous systems. Discretization methods. Vibrations of Euler-Bernoulli and Timoshenko beams. Boundary conditions, intermediate supports and penalty method. Strain-displacement relationships for plates/shells. Vibrations of plates and shells. Sloshing and added mass. Effect of geometric imperfections and thermal loads. Introduction to nonlinear dynamics and stability. Introduction to experimental techniques.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite: MECH 315 or MECH 419
• Restriction: Not open to students who have taken MECH 643

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Introduction to nonlinear dynamics and stability; softening and hardening systems; bifurcations; Lyapunov exponents; nonlinear strain-displacement relationships; Lagrangian description; plates and shells; nonlinear vibrations of plates and shells; reduced-order models; stability of shells with cardiovascular application; supersonic flutter of circular cylindrical shells (rockets).

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisite: MECH 315 or MECH 419

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year

Mechanical Engineering: Introduction to microelectromechanical systems (MEMS). Micromachining techniques (thin-film deposition; lithography; etching; bonding). Microscale mechanical behaviour (deformation and fracture; residual stresses; adhesion; experimental techniques). Materials- and process-selection. Process integration. Design of microdevice components to meet specified performance and reliability targets using realistic manufacturing processes.

Offered by: Mechanical Engineering

• (3-0-6)
• Prerequisites: MECH 309, MECH 321, (MECH 315 or MECH 419)

• Terms
  • This course is not scheduled for the 2024 academic year
• Instructors
  • There are no professors associated with this course for the 2024 academic year