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engineering problems. Application of MATLAB software. Prerequisite: MATH 304
3 credits, Spring
ME 405: Finite Element Method Basic approach to finite element method, and theoretical foundation of the method, including fundamentals of matrix algebra. Element formulation for solid mechanics and thermal analysis problems, by the direct method, potential energy and Galerkin's method of weighted residuals. Use of modern finite element analysis software such as ANSYS for analysis and design. Prerequisites: MATH 304, ME 214, ME 337 3 credits, Fall ME 407: Engineering Optimization Fundamentals of vector and matrix algebra, economic analysis, numerical methods for solution of linear and nonlinear equations. Basic theory, concepts and methods of engineering optimization. Primary techniques from both classical and modern optimization as applied to engineering decision making. Prerequisites: ME 214, ME 312, ME 350, ME 403 3 credits, Spring ME 410: Thermal Systems Design This course reviews the fundamentals of thermal systems design and optimization. Basic considerations in thermal systems design will be discussed. General approach to system analysis, modeling, simulation and optimization will be introduced. Various optimization techniques and methods will also be presented and discussed. Prerequisites: MATH 304, ME 312, ME 336, ME 337 3 credits, Spring ME 411: Alternative Energy Systems Various alternative energy systems are introduced, their operation discussed and their performance evaluated. Prerequisites: ME 312, 336, 337 3 credits ME 427: Internal Combustion Engines This course introduces and reviews the fundamentals of internal combustion engines, including spark-ignition and compression-ignition engines. General engine systems and working cycles are described. Engine thermodynamics, gas exchange and combustion processes, engine fluid flow and heat transfer, and fuel injection systems are analyzed. The course also reviews the formation of engine exhaust emissions and methods for controlling the emissions of the internal combustion engines. Engine design and consideration of the effects of design and operating factors are introduced. Prerequisite: ME 440 3 credits ME 440: Advanced Thermodynamics Application of first, second, and third law of thermodynamics, thermodynamic cycles, mixtures, chemical reactions, phase and chemical equilibrium, irreversibility and availability. Prerequisite: ME 312 3 credits, Fall ME 441: Lubrication Systems Design Application of math & engineering science principles of lubrication in the design of mechanical systems. Understanding bearing classes & selection, lubricant properties, and bearing materials. Design concepts and engineering science in hydrodynamic bearings, gas lubricated bearings, elastohydrodynamic bearings, and antifriction bearings. Prerequisites: ME 335, ME 336 3 credits ME 444: Advanced Strength of Materials Application of selected advanced engineering theories for analysis and design of structural components under static loading. Topics include: curved beams, inelastic action, beams on elastic foundation, plate theory, contact stresses; other topics as time and interest permit. Use of computer resources for solution of engineering design problems. Prerequisite: ME 214 3 credits, Spring