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Course Criteria
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3.00 Credits
Laminar and turbulent flows; boundary layer and free shear flows (jets, wakes, etc.); descriptions of velocity, shear stress and pressure measurements, and aerodynamic drag.
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3.00 Credits
Characterization of sediments; physical principles governing fluvial, estuarial and coastal transport of cohesionless and cohesive sediments, including incipient motion, stable channel design, bedforms, and bedload and suspended transport.
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3.00 Credits
Study of turbulence and basic flow equations as they impact the environment. Includes slender flows including circular and plane turbulent jets, jets in crossflows, wall, surface jets and plumes; near-field and far-field analysis of discharge in rivers including continuous momentum discharges, nonbouyant plumes and passive slugs; mixing in lakes and reservoirs; and stratified flows.
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4.00 Credits
Students solve open-ended, real world risk engineering problems utilizing a team project design process including development, project management, and economic decision making. Design and report methodologies for use in work-related projects are employed, and communication skills are reinforced through report presentations. This online course is limited to industry professionals in the Risk Engineering and System Analytics (RESA) master of engineering and RESA certificate programs. Preq: Consent of instructor and enrollment in the RESA master of engineering program or the RESA certificate program. Coreq: CE 8701.
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0.00 Credits
Non-credit laboratory to accompany CE 8700. Coreq: CE 8700.
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3.00 Credits
This course illustrates the problem of fire hazard in civil engineering infrastructure, including buildings, bridges, and tunnels. It also presents state-of-the-art methodologies and techniques to analyze and design structures for fire safety. The approaches that are presented to evaluate fire resistance of structures range from simplified methods to advanced analysis, incorporating finite element based models.
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3.00 Credits
Students learn applications of numerical modeling, finite difference, finite volume and finite element, as tools for solving complex problems in the areas of hydraulics/fluid mechanics. Students learn techniques of developing and analyzing computational models for parabolic, elliptic and hyperbolic equations used in the area of hydraulics.
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3.00 Credits
Many natural and engineered materials such as soils, concrete, metals and biomaterials generally exhibit an irreversible (inelastic) behavior such that when an applied load is removed, only a fraction of the deformation is recovered. This course focuses on constituitive models developed for inelastic materials, their implementation within nonlinear finite element programs, and applications in various engineering disciplines. Equal emphasis is placed on the theory behind inelastic material models and their computational implementation and applications.
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1.00 Credits
Research design problems from field of structures, construction, soil mechanics, transportation, ocean and coastal engineering, or materials engineering. Subject matter varies with interest and experience of student and instructor.
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1.00 Credits
Research design problems from field of structures, construction, soil mechanics, transportation, ocean and coastal engineering, or materials engineering. Subject matter varies with interest and experience of student and instructor.
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