Mechanical Engineering
GENG 622 Risk Management 3 credits Introduction to project risks management and engineering ethics for engineering decision making. Integrated models for technical, schedule, and cost risks. Management of cost-risk contributions. Identification and control of critical paths for project schedule. Implementation of integrated risk management with computer simulation methods. GENG 623 Decision Making under Uncertainty 3 credits Introduction of general techniques for dealing systematically with uncertainty in engineering decision problems. Computer simulation models, sensitivity analysis, and subjective probability assessment for engineering judgment. Probabilistic design criteria, value of information, utility analysis with risk aversion, and trade-off under uncertainty are studied. GENG 624 Project Management 3 credits The course will cover the skills necessary to manage large and small projects in terms of planning and controlling techniques, coordinating and directing techniques, and negotiating techniques. Roles and responsibilities of the project manager and tools and techniques used in managing projects will be discussed along with preparing project records and reports. GENG 685 Advanced Control Systems 3 credits This course treats the analysis and design of linear control systems from the point of view of state space representation. Topics include system modeling, coordinate transformation, controllability, observability, output feedback, state feedback, linear quadratic regulators, and linear estimators. Additionally, an introduction to nonlinear control is presented with the topics of feedback linearization and adaptive control. Applications from interdisciplinary current state-of-of-the-art systems will be presented. GENG 689 Stability Analysis of Multidimensional Dynamic System 3 credits Fundamental concepts of stability for various classes of dynamic systems are examined and discussed. The systems considered include multidimensional lumped-parameter systems that can be described by linear differential equations. The systems under consideration are divided into certain well-defined classes, and various phenomena related to vibrations and stability of these systems are exposed systematically. Although the course examples are drawn from mechanical systems, the general nature of formulation can be applied to systems of similar nature in other disciplines, such as electrical circuits.
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GENG 700-702 Graduate Professional Experience 1 credit Prerequisite: Discipline-specific industrial sponsorship This course complements regular academic education with handson, real-world development exposure. Students are required to be engaged in practical training during the course. International students require Curricular Practical Training (CPT) approval. Topics include issues facing engineering and computing professionals, trends in the fields, job prospects, team and workplace behavior, project leadership as well as reviews of speaking, listening, reading and writing skills. GENG 703 Engineering Analysis 2 3 credits Solving engineering problems using ordinary differential equations, partial differential equation, series solutions to differential equations. Complex analysis applied to engineering problems. GENG 796 Directed Research Project 3 credits Those students choosing their research project option will complete a directed research project. The topic will be approved by a threemember board consisting of the candidate’s major professor, the department chairperson, and the Director of the Graduate Engineering Program. The student will perform the literature search, complete the project, and submit a final report. GENG 797 Thesis 3-6 credits Those students choosing the thesis option will have their topic approved by a three-member board consisting of the candidate’s major professor, the department chairperson, and the Director of the Graduate Engineering Program. The student will perform the literature search, complete the thesis, and submit a final report. Under this option, students must complete a total of 6 Thesis credits. GME 505 Finite Element Method 1 3 credits Fundamentals of matrix algebra; basic approach to finite element analysis; definitions and basic concepts; system analysis fundamentals of elasticity; element formation by direct displacement method; element formulation by Galerkin Criterion (weight residuals method); finite element workshop using finite element program, such as ANSYS, for design and analysis of some structures. GME 507 Optimization in Engineering 3 credits Basic theory, concepts and methods of engineering optimization. Primary techniques from both classical and modern optimizations applied to engineering decision-making.
