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Course Criteria
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3.00 Credits
- 3 credits This course will cover system design methods that are applied to intelligent electromechanical devices, as well as an analysis of dynamic response, performance and reliability. Students will model and simulate a proposed capstone senior project. Prerequisite: MCE410
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2.00 Credits
- 2 credits This course is designed to cover both the philosophy and the technology beyond the design phase of a product. It is intended to cover basic manufacturing processes. Topics include chip and chipless machining, numerical control, measurement and inspection techniques and manufacturing requirements, six sigma and the role of documentation and standards including ISO 9000 and ISO 9001.
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3.00 Credits
- 3 credits This course covers the concepts necessary to apply the laws of mechanics to rigid body equilibrium. Topics include vectors, equilibrium of particles and rigid bodies. The study will concentrate on equivalent systems and how they apply to frames, trusses and beams. This course will also cover topics on centroids, moment of inertia and friction. Prerequisites: MAT125 and PHY125
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4.00 Credits
- 4 credits This course discusses the fundamentals of thermodynamics, which include system concepts, state of equilibrium, processes of properties, zeroth, first, second laws of thermodynamics and flow and non-flow processes. Carnot cycle and efficiencies of reversible conversions, irreversibility, entropy concepts, ideal gases, and mixtures involving ideal gases are covered. The principles of heat transfer analysis as applied to heat conduction, heat convection, heat radiation and heat exchangers are also covered. Topics include one- and twodimensional heat transfer analysis, conduction heat transfer by finite difference technique, radiation heat transfer, unsteady-state heat transfer, and heat exchangers. Prerequisites: MAT225 and MEE115, PHY220
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3.00 Credits
- 3 credits Course content includes rectilinear, curvilinear, and dynamic motion, kinetics of rigid bodies, plane motion of rigid bodies and an introduction to mechanical vibration. This course will cover topics on linear motion, projectile motion, conservation of energy, impact and momentum, and the free and force vibration of a single degree freedom system. Prerequisites: MAT225 and MEE115, PHY220
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4.00 Credits
- 4 credits (3 credits lecture and 1 credit lab) This course covers the concepts of stress, strain, stress-strain diagrams, elasticity, thermal stress, torsion, and beam analysis and design. This course will also cover topics on beam deflection, and statically indeterminate beam analysis, and column theory. Laboratory experiments involving materials testing such as tensile test, torsion test and bending test by strain gauge will be conducted. Prerequisites: MAT225 and MEE115
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3.00 Credits
- 3 credits This course deals with materials classification and their characteristic properties, atomic structure, the concept of the unit cell of a crystalline solid, and study of the phase diagram. Material characteristics related to mechanical properties are emphasized. Material failures and failure due to stress concentration, fatigue and impact are discussed. Brief study of composite material and criteria for material selection based on maximization of strength with respect to both minimum mass and minimum cost will be studied. Prerequisites: MAT125 and PHY125
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3.00 Credits
- 3 credits Topics covered are analytical and numerical solution to the differential equation of a physical problem, root determination with application to the mechanical and electrical engineering type problems, estimating first and higher derivatives using Taylor series expansion with finite difference technique and solution to the systems of linear algebraic equations with application to mechanical and electrical engineering problems. Prerequisites: MAT325, PHY125 and MEE215
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3.00 Credits
- 3 credits In this course students will be introduced to the concepts of the theory of structural reliability and the reliabilitybased design formulas. The tools needed in this course are probability, statistics, and basic mechanics courses. Upon completion of this course, students will be expected to perform structural load and strength analysis, as well as to solve structural reliability problems, including design and safety checking under quasistatic loads. Prerequisites: MAT325, MEE220 and MEE340
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4.00 Credits
- 4 credits This introductory course in machine design utilize the principles of statics, dynamics and strength of materials in design of machine parts, such as shafts, keys, couplings, gears, spring, and bolts that work safely, reliably and well. Topics covered include principal stresses, theory of failure, fatigue, dynamic loading, free and forced vibration of undamped and damped systems, and design of isolators. Prerequisites: MEE215, MEE220, MEE235 and MAT325
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