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Course Criteria
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3.00 Credits
Description: Classification and characteristics of composite materials; mechanical behavior of composite materials, micro- and macro-mechanical behavior of laminae; mechanical behavior of laminates; mechanical behavior of short fiber composites. Graduate-level requirements include an additional project on composite materials. Grading: Regular grades are awarded for this course: A B C D E. Special course fee required: Special fee may apply for web delivered sections. See the M.Eng Website (http://www.oneflexibledegree.com) for details. May be convened with: A ME 462. Usually offered: Spring.
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3.00 Credits
Description: Finite element methods, including material nonlinearity (elastic, plastic, viscoelastic); geometric nonlinearity (finite deformations), numerical solution methods, and nonlinear programs. Grading: Regular grades are awarded for this course: A B C D E. Special course fee required: Special fee may apply for web delivered sections. See the M.Eng Website (http://www.oneflexibledegree.com) for details. Prerequisite(s): A ME 561. Usually offered: Fall.
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3.00 Credits
Description: Mathematical preliminaries, motion and deformation, balance laws of mechanics, state of stress and equations of motion, constitutive equations, uniqueness, Betti-Rayleigh reciprocity theorem, applications from classical elasticity. Grading: Regular grades are awarded for this course: A B C D E. Usually offered: Fall.
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3.00 Credits
Description: Review of fundamental principles of mechanics of deformable bodies, plasticity, thermoelasticity, viscoelasticity and creep. Grading: Regular grades are awarded for this course: A B C D E. Prerequisite(s): A ME 564A. Usually offered: Spring.
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3.00 Credits
Description: This course aims at providing basic knowledge in recent design optimization methods and tools. Typical examples of design optimization problems involve the minimization of structural weight and cost while satisfying performance constraints. Emphasis will be on applied design optimization and its application in the context of simulation-based design. Techniques ranging from optimal sizing, shape, and topology optimization to design of experiments and response surfaces will be presented. Graduate-level requirements include a specific final project (more geared towards algorithmic and mathematical aspects) and during the practical lab sessions, the graduate students will be required to report on more questions. Grading: Regular grades are awarded for this course: A B C D E. Prerequisite(s): or Concurrent registration, Finite element course (undergraduate or graduate). May be convened with: A ME 465. Usually offered: Fall.
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3.00 Credits
Description: Subjects selected yearly from: biosolids, biofluids, biotransport; physiological systems; bioheat transfer. Graduate-level requirements include a project and additional reading assignments. Grading: Regular grades are awarded for this course: A B C D E. Identical to: BME 566. May be convened with: A ME 466. Usually offered: Spring.
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3.00 Credits
Description: Computational geometry, graphics programming, solid modeling, projections and transformations, display generation, hidden lines and surface algorithms, computer aided design and computer integrated manufacturing, spatial reasoning. Grading: Regular grades are awarded for this course: A B C D E. Identical to: ECE 567; ECE is home department. Usually offered: Fall.
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3.00 Credits
Description: Times-to-failure distributions, including the normal, lognormal, exponential, Weibull, Rayleigh, binomial, Poisson, mean time between failures (MTBF); failure-rate and reliability determination for early, useful and wear-out lives; equipment reliability prediction; series, parallel, standby reliability; multimode function and logic; spare parts provisioning; reliability growth; reliability allocation; Failure Modes, Effects, and Criticality Analyses; Fault Tree Analysis. Graduate-level requirements include a special report of 30 pages on a specific reliability engineering topic. Grading: Regular grades are awarded for this course: A B C D E. May be convened with: A ME 472. Usually offered: Fall.
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3.00 Credits
Description: Conventional mechanical design review; commonly used distributions in mechanical reliability field; application of probability theory and statistics to mechanical and structural design; modern mechanical reliability methods; design philosophy. Graduate-level requirements include additional homework with focus on theoretical considerations, and a research project. Grading: Regular grades are awarded for this course: A B C D E. May be convened with: A ME 473. Usually offered: Fall.
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3.00 Credits
Description: Probability and statistics with applications to reliability engineering, discrete and continuous statistical models for engineering variables, fundamentals of statistics, extreme value distribution, uniform distribution, reliability of systems operating at various stress levels, load sharing reliability. Graduate-level requirements include additional assignments and independent study, Monte Carlo simulation. Grading: Regular grades are awarded for this course: A B C D E. May be convened with: A ME 474. Usually offered: Fall.
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