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Course Criteria
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3.00 Credits
Fatigue design methods; fatigue fracture mechanisms; cyclic deformation behavior and material cyclic properties; stress-based, and fracture mechanics-based methodologies to fatigue life prediction of smooth and notched members subjected to constant or variable amplitude loadings.
Prerequisite:
CIVE 1160 FOR LEVEL UG WITH MIN. GRADE OF D-
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3.00 Credits
This course provides greater knowledge on the atomic bonding, crystal structure, crystal imperfections, phases and interfaces, microstructures, phase diagrams, phase transformation, transport and diffusion, metal deformation, fracture of materials, deterioration of materials, electronic and physical properties of ceramics.
Prerequisite:
MIME 1650 FOR LEVEL UG WITH MIN. GRADE OF C- AND PHYS 2130 FOR LEVEL UG WITH MIN. GRADE OF C-
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3.00 Credits
An in?depth study of the broad range of engineering materials used in the construction of motor vehicles. Inter?relations between materials microstructure, components manufacturing process and components service behavior.
Prerequisite:
(MIME 1650 FOR LEVEL UG WITH MIN. GRADE OF C- AND PHYS 2130 FOR LEVEL UG WITH MIN. GRADE OF C-)
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3.00 Credits
Polymers and rubber are introduced through lecture and lab components at three levels- 1) synthesis and characterization, 2) thermal, molecular and mechanical properties, and 3) design considerations for engineering applications.
Prerequisite:
(MIME 1650 FOR LEVEL UG WITH MIN. GRADE OF C- AND PHYS 2130 FOR LEVEL UG WITH MIN. GRADE OF C-)
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3.00 Credits
The failure analysis is a procedure to determine the physical cause of the failure of an element, component or industrial equipment. The course will be focused on material related and will present an introduction to the principles of failure analysis and the fundamental aspects to conduct a failure analysis investigation. A key component of the course is the discussion of real cases of failures (case studies), i.e. failures in mining machinery, chemical processing equipment, energy production, systems, aircraft and petrochemical industry components. This course provides the connection between mechanisms that are responsible for material failures and will address the characterization techniques used in failure analysis. Fundamental failure mechanisms in various materials applications including fracture of metals and alloys, failure in electronic devices, and environmental factor induced failures will be covered. Each categorized phenomenon will be approached by historical events to reveal the application and connection between the mechanism and the incidents.
Prerequisite:
(MIME 1650 FOR LEVEL UG WITH MIN. GRADE OF C- AND PHYS 2130 FOR LEVEL UG WITH MIN. GRADE OF C-)
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3.00 Credits
This course focuses on the technical aspects of sustainable energy technologies, such as wind, solar, biomass, ocean waves/tides, geothermal, and hydropower; it also covers issues and applications related to storage, transportation, distribution, industrial usage, and buildings. The course investigates the progress, challenges, and opportunities of each technology to be both technically feasible and economically viable.
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3.00 Credits
This course covers the major aspects of automotive control, including engine, driveline, and complete vehicle control. This includes applications such as fuel and ignition control, ABS systems, gear-shifting, and vehicle velocity estimation.
Prerequisite:
MIME 3380 FOR LEVEL UG WITH MIN. GRADE OF D-
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0.00 - 3.00 Credits
This course will give students hands-on experience with mechatronic systems and components. The laboratory will be used to demonstrate several mechatronics systems including inverted pendulums, suites of sensors and motors, and other more complex systems. A major part of the course will be a semester-long project where the students conceive, design, and build a mechatronic device.
Prerequisite:
MIME 3380 FOR LEVEL UG WITH MIN. GRADE OF D-
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3.00 Credits
This course will introduce the range of common components used in automation, including actuators, sensors, motors, linear guides, energy chain, industrial robots and light curtains. Students will practice (with feedback) walking through the design process in specifying, sizing, laying out and integrating these components.
Prerequisite:
MIME 1100 FOR LEVEL UG WITH MIN. GRADE OF D- AND MIME 2300 FOR LEVEL UG WITH MIN. GRADE OF D- AND CIVE 1160 FOR LEVEL UG WITH MIN. GRADE OF D-
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0.00 - 3.00 Credits
This course will review the basics of using MATLAB, identify best-practices applicable to MATLAB and other programming languages, and provide examples of more-advanced functionality such as image processing, Simulink control of mechatronic systems, numerically solving differential equations, GPU computation, and optimization. Programming experience would be helpful, but this would also be a good opportunity to rapidly grow programming skills with an easy-to-learn language.
Prerequisite:
MATH 2860 FOR LEVEL UG WITH MIN. GRADE OF D-
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