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ENME Engineering, Mechanical( The A. James Clark School of Engineering) ENME201 Careers in Mechanical Engineering; (1 credit) Grade Method: S-F.The Mechanical Engineering Curriculum, Career Paths. Research areas in the Mechanical Engineering Department. The Mechanical Engineering Profession. ENME232 (PermReq) Thermodynamics; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: PHYS260 and PHYS261 (Formerly: PHYS262). Introduction to thermodynamics. Thermodynamic properties of matter. First and second laws of thermodynamics, cycles, reactions, and mixtures. ENME271 (PermReq) Introduction to Matlab; (3 credits) Grade Method: REG. Prerequisite: ENES221. Develop the skills to generate readable, compact and verifiably correct MATLAB scripts and functions to obtain numerical solutions to a wide range of engineering models and to display the results with fully annotated graphics. Learn structured programming. ENME320 (PermReq) Thermodynamics; (3 credits) Grade Method: REG/P-F/AUD. Prerequisites: MATH141; and {PHYS260 and PHYS261 (Formerly: PHYS262)}. The properties, characteristics and fundamental equations of gases and vapors. Application of the first and second laws of thermodynamics in the analysis of basic heat engines, air compression vapor cycles. Flow and non-flow processes for gases and vapors. ENME331 (PermReq) Fluid Mechanics; (3 credits) Grade Method: REG/P-F/AUD. Prerequisites: ENME232 and ENES221. Principles of fluid mechanics. Mass, momentum and energy conservation. Hydrostatics. Control volume analysis. Internal and external flow. Boundary layers. Modern measurement techniques. Computer analysis. Laboratory experiments. ENME332 (PermReq) Transfer Processes; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: ENME331. The principles of heat transfer. Conduction in solids. Convection. Radiation. Modern measurement techniques. Computer analysis. ENME350 (PermReq) Electronics and Instrumentation I; (3 credits) Grade Method: REG. Prerequisite: PHYS270 and 271 {Formerly PHYS263}. Credit will be granted for only one of the following: ENME252 or ENME350. Formerly ENME 252. Modern instrumentation. Basic circuit design, standard microelectronic circuits. Digital data acquisition and control. Signal conditioning. Instrumentation interfacing. Designing and testing of analog circuits. Laboratory experiments. ENME351 (PermReq) Electronics and Instrumentation II; (3 credits) Grade Method: REG/P-F/AUD. Prerequisites: ENME350 and (PHY 270 and 271 {Formerly PHYS263}). Continuation of ENME 350. Modern instrumentation. Basic circuit design, standard microelectronic circuits. Digital data acquisition and control. Signal conditioning. Instrumentation interfacing. Designing and testing of analog circuits. Laboratory experiments. ENME361 (PermReq) Vibration, Controls and Optimization I; (3 credits) Grade Method: REG/P-F/AUD. Prerequisites: ENES220, ENES221, ENME271, and MATH246. For ENME majors only. Fundamentals of vibration, controls and optimization. Analysis and design in time, Laplace and frequency domains. Mathematical description of system response, system stability, control and optimization. Optimal design of mechanical systems. Those sections that begin with a letter are taught via ITV and are not intended for College Park campus students. ENME371 (PermReq) Product Engineering and Manufacturing; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: ENES221, ENME392, or STAT400. For ENME majors only. Business aspects of engineering product development. Relationship of design and manufacturing. Product specification. Statistical process control. Design team development. The development process. ENME382 (PermReq) Engineering Materials and Manufacturing Processes; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: ENES220. Basic material structures and properties. Mechanical behavior of materials. Manufacturing processes theory. Materials processing. Quality assurance. Laboratory experiments. ENME392 (PermReq) Statistical Methods for Product and Processes Development; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: MATH241. Integrated statistical methodology for the improvement of products and processes in terms of performance, quality and cost. Designed experimentation. Statistical process control. Software application. Laboratory activities. Delivered via ITV. ENME400 Machine Design; (3 credits) Grade Method: REG/P-F/AUD. Senior standing. Working stresses, stress concentration, stress analysis and repeated loadings. Design of machine elements. Kinematics of mechanisms. ENME408 (PermReq) Selected Topics in Engineering Design: Automotive Design; (3 credits) Grade Method: REG/P-F/AUD. ENME414 (PermReq) Computer-Aided Design; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: MATH241 or equivalent. Introduction to computer graphics. Plotting and drawing with computer software. Principles of writing interactive software. The applications of computer graphics in computer-aided design. Computer-aided design project. Design technical elective. ENME423 (PermReq) Building Cooling Heating and Power Systems; (3 credits) Grade Method: REG/P-F/AUD. Prerequisite: ENME232 and ENME332. Introduction to the evaluation of cooling, heating and power requirements of buildings. Description, design and evaluation of state-of-the-art and emerging integrated cooling, heating and power systems (engines, micro-turbines, absorption and desiccant systems) as they are applied to buildings. The course uses the Chesapeake building facility and the campus cogeneration facility as real-life demonstration examples. Delivered via ITV. ENME462 (PermReq) Vibrations, Controls, and Optimization II; (3 credits) Grade Method: REG/P-F/AUD. Prerequisites: ENME351 and ENME361. Formerly ENME 362. Continuation of ENME 361. Fundamentals of vibration, controls, and optimization. Analysis and design in time, Laplace and frequency domains. Mathematical descriptions of system response, system stability, control and optimization. Optimal design of mechanical systems. Delivered via ITV. ENME472 (PermReq) Integrated Product and Process Development; (3 credits) Grade Method: REG/P-F/AUD. CORE Capstone (CS) Course. Prerequisite: ENME371. Integration of product development with the development process. Design strategies. Product architecture. Design for manufacturing. Selection of materials. Design for assembly. ENME473 (PermReq) Mechanical Design of Electronic Systems; (3 credits) Grade Method: REG/P-F/AUD. Prerequisites: ENME310; and ENME360; and ENME321. Design considerations in the packaging of electronic systems. Production of circuit boards and design of electronic assemblies. Vibration, shock, fatigue and thermal considerations. Delivered via ITV. ENME488 (PermReq) Special Problems; (3 credits) Grade Method: REG/P-F/AUD. Individual Instruction course: contact department or instructor to obtain section number. Limited to mechanical engineering seniors. ENME489 (PermReq) Special Topics in Mechanical Engineering; (3 credits) Grade Method: REG/P-F/AUD. Individual Instruction course: contact department or instructor to obtain section number. ENME489A Special Topics in Mechanical Engineering: Air Pollution; (3 credits) Grade Method: REG/P-F/AUD. ENME489B (PermReq) Special Topics in Mechanical Engineering: Lean Six Sigma; (3 credits) Grade Method: REG/P-F/AUD. ENME489F Special Topics in Mechanical Engineering: Micro-Electro-Mechanicalal Systems I (MEMS I); (3 credits) Grade Method: REG/P-F/AUD. Also offered as ENME808K. ENME489J Special Topics in Mechanical Engineering: Production Management; (3 credits) Grade Method: REG/P-F/AUD. ENME489N Special Topics in Mechanical Engineering: Fundamentals of Nuclear Power; (3 credits) Grade Method: REG/AUD. ENME489R Special Topics in Mechanical Engineering: Medical Robotics; (3 credits) Grade Method: REG/P-F/AUD. Also offered as ENME808M. ENME489V Special Topics in Mechanical Engineering; (3 credits) Grade Method: REG/P-F/AUD. ENME489X Special Topics in Mechanical Engineering: Ambidextrous Thinking; (3 credits) Grade Method: REG/P-F/AUD. ENME489Z (PermReq) Special Topics in Mechanical Engineering: Advanced Strength of Materials; (3 credits) Grade Method: REG/AUD. ENME600 Engineering Design Methods; (3 credits) Grade Method: REG/AUD. Prerequisite: Graduate Standing or permission of instructor. 3 semester hours. Not open to students who have completed ENME 808F during Spring 1999 semester or the Fall 1996 semester.. An introductory graduate level course in critical thinking about formal methods for design in Mechanical Engineering. Course participants gain background on these methods and the creative potential each offers to designers. Participants will formulate, present, and discuss their own opinions on the value and appropriate use of design materials for mechanical engineering. ENME605 Advanced Systems Control; (3 credits) Grade Method: REG/AUD. Prerequisite: ENME 403 or permission of instructor. Modern control theory for both continuous and discrete systems. State space representation is reviewed and the concepts of controllability and observability are discussed. Design methods of deterministic observers are presented and optimal control theory is formulated. Control techniques for modifying system characteristics are discussed. ENME610 Engineering Optimization; (3 credits) Grade Method: REG/AUD. Prerequisite: Graduate Standing or permission of instructor. 3 semester hours. Overview of applied single- and multi- objective optimization and decision making concepts and techniques with applications in engineering design and/or manufacturing problems. Topics include formulation examples, concepts, optimality conditions, unconstrained/constrained methods, and post-optimality sensitivity analysis. Students are expected to work on a semester-long real-world multi-objective engineering project. ENME631 Advanced Conduction and Radiation Heat Transfer; (3 credits) Grade Method: REG/AUD. Prerequisites: {ENME 315; and ENME 321; and ENME 700 or equivalent} or permission of instructor. Theory of conduction and radiation. Diffused and directional, poly- and mono-chromatic sources. Quantitative optics. Radiation in enclosures. Participating media. Integrodifferential equations. Multidimensional, transient and steady-state conduction. Phase change. Coordinate system transformations. ENME633 Molecular Thermodynamics; (3 credits) Grade Method: REG/AUD. Prerequisite: permission of department. Also offered as ENNU 625. An examination of the interactions between molecules, which govern thermodynamics relevant to engineering, will be conducted. We will investigate both classical and statistical approaches to thermodynamics for understanding topics such as phase change, wetting of surfaces, chemical reactions, adsorption, and electrochemical processes. Statistical approaches and molecular simulation tools will be studied to understand how molecular analysis can be translated to macroscopic phenomena. ENME640 Fundamentals of Fluid Mechanics; (3 credits) Grade Method: REG/AUD. Prerequisite: Partial differential equations at the level of MATH 462 or permission of department. Formerly ENME 651. Equations governing the conservation of mass, momentum, vorticity and energy in fluid flows. Low Reynolds number flows. Boundary layers. The equations are illustrated by analyzing a number of simple flows. Emphasis is placed on physical understanding to facilitate the study of advanced topics in fluid mechanics. ENME646 Computational Fluid Dynamics; (3 credits) Grade Method: REG/AUD. Prerequisite: Graduate-level fluid mechanics, or permission of department. Fundamentals of numerical analysis of engineers. Inversion of large, sparse matrices. Numerical solution of the incompressible Navier-Stokes equations in Cartesian and curvilinear grids. Application to turbulent flows and micro-fluidics. ENME662 Linear Vibrations; (3 credits) Grade Method: REG/AUD. Prerequisite: ENME 360 or equivalent or permission of instructor. Development of equations governing small oscillations and spatially continuous systems. Newton's equations, Hamilton's principle, and Lagrange's equations. Free and forced vibrations of mechanical systems. Modal analysis. Finite element discretization and reductions of continuous systems. Numerical methods. Random vibrations. ENME670 Continuum Mechanics; (3 credits) Grade Method: REG/AUD. Mechanics of deformable bodies, finite deformation and strain measures, kinematics of continua and global and local balance laws. Thermodynamics of continua, first and second laws. Introduction to constitutive theory for elastic solids, viscous fluids and memory dependent materials. Examples of exact solutions for linear and hyper elastic solids and Stokesian fluids. ENME673 Energy and Variational Methods in Applied Mechanics; (3 credits) Grade Method: REG/AUD. Application of variational principles to mechanics. Includes virtual work, potential energy, strain energy, Castigliano's generalized complementary energy, and the principles of Hellinger-Reissner and Hamilton. Legendre transforms and the foundations of the calculus of variations. Singularities and stability in a potential energy function. Applications to rigid, linear and non-linear elastic, and nonconservative examples. Approximation techniques such as Ritz, Petrov-Galerkin, least-squares, etc. Presents the basis for the finite element method. ENME690 Mechanical Fundamentals of Electronic Systems; (3 credits) Grade Method: REG/AUD. An understanding of the fundamental mechanical principles used in design of electronic devices and their integration into electronic systems will be provided. Focus will be placed on the effect of materials compatibility, thermal stress, mechanical stress, and environmental exposure on product performance, durability and cost. Both electronic devices and package assemblies will be considered. Analysis of package assemblies to understand thermal and mechanical stress effects will be emphasized through student projects. ENME770 Life Cycle Cost and System Sustainment Analysis; (3 credits) Grade Method: REG/AUD. This course melds elements of traditional engineering economics with manufacturing process and sustainment modeling, and life cycle cost management concepts to form a practical foundation for predicting the cost of products and systems. Various manufacturing cost analysis methods will be presented including: process-flow, parametric, cost of ownership, and activity based costing. The effects of learning curves, data uncertainty, test and rework processes, and defects will be considered. Aspects of system sustainment including the impact on the life cycle (and life cycle costs) of reliability, maintenance, environmental impact, and obsolscence will be treated. ENME799 (PermReq) Master's Thesis Research; (1-6 credits) Grade Method: REG. Individual Instruction course: contact department or instructor to obtain section number. ENME808 Advanced Topics in Mechanical Engineering; (3 credits) Grade Method: REG/AUD. Individual Instruction course: contact department or instructor to obtain section number. ENME808A Advanced Topics in Mechanical Engineering: Prognostics and Health Management; (3 credits) Grade Method: REG/AUD. ENME808B Advanced Topics in Mechanical Engineering: Emerging Manufacturing Technologies; (3 credits) Grade Method: REG/AUD. ENME808K Advanced Topics in Mechanical Engineering: Micro-Electro-Mechanicalal Systems I (MEMS I); (3 credits) Grade Method: REG. Also offered as ENME489F. ENME808M Advanced Topics in Mechanical Engineering: Medical Robotics; (3 credits) Grade Method: REG/AUD. Also offered as ENME489R. ENME808N Advanced Topics in Mechanical Engineering: Nanomechanics I; (3 credits) Grade Method: REG/AUD. ENME808W Advanced Topics in Mechanical Engineering; (2-3 credits) Grade Method: REG/AUD. ENME898 Pre-Candidacy Research; (1-8 credits) Grade Method: REG. Individual Instruction course: contact department or instructor to obtain section number. ENME899 (PermReq) Doctoral Dissertation Research; (6 credits) Grade Method: REG. Individual Instruction course: contact department or instructor to obtain section number.
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