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Course Criteria
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4.00 Credits
This is a two-month clinical and surgical rotation on service with an orthopaedic sports medicine surgeon and a team of surgical residents.
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3.00 Credits
Study of forces, moments, free-body diagrams, friction, equilibrium, first and second moments of lines, centers of pressure, mass and gravity, and moments of inertia. (3-0)
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3.00 Credits
Thermodynamic properties, heat and work, first and second laws, processes, ideal and nonideal cycles. (3-0)
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3.00 Credits
Introduction of stress and strain, stress transformations, analysis of stresses, strain, and deflections in axial members, beams, and torsional shafts. Analysis of pressure vessels. (3-0)
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3.00 Credits
The theory and analysis of vibrating systems including single and multi-degrees of freedom, free and forced, vibrations, with and without damping. (3-0)
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3.00 Credits
Introduction to the basic theory and techniques of finite element analysis beginning from energy concepts and the foundational constitutive equations.Engineering applications will focus on one- and two-dimensional formulations for classical beams, frames, trusses and electrical network applications.Introduction to typical workflow of finite element analysis using modern computer technologies. (3-0)
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3.00 Credits
See ELC 4330 for course information.
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3.00 Credits
Steady and unsteady heat conduction including numerical solutions, thermal boundary layer concepts and applications to free and forced convection. Thermal radiation concepts. Heat exchanger design. (3-0)
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3.00 Credits
Introduction to compressible flow, including flows with simple area change, heat addition, friction, and shock waves. Analysis, parametric design, and performance of ramjets, turbojets, turbofans, and turboprops. Introduction to the operating principles of major engine components. Introduction to rockets. (3-0)
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3.00 Credits
Systematic approach for selection of materials and manufacturing process in design that balances performance requirements with cost of materials and manufacturing. Material properties, manufacturing processes and types of materials. Advanced computer software and case studies are used to illustrate application of principles. (3-0)
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