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The course addresses risk and decision analysis for geotechnical and structural engineering systems based on statistics and reliability modeling.Students will learn to make probabilistic predictions of the behavior of geotechnical and structural engineering systems by characterizing and quantifying the uncertainties associated with the material properties and external forces, and propagating them through the relevant prediction equations.Solution methodologies and computer programming are discussed including the Ritz method, Galerkin's method and finite elements for stability and dynamics.
This course examines the behavior of structural materials, such as concrete, soils, and metals.
Topics covered in this course include the nature of soil, its formation and composition; stresses in a soil mass; effective stress; basic stress-strain relationships and their application; drained and undrained characteristics of cohesionless and cohesive soils; consolidation; Camclay models; incremental theory of plasticity applied to metal, concrete, and soils; failure theories for ductile and brittle materials; and laboratory methods for determining stress-strain and strength properties.
The course reviews variational calculus and introduces the fundamental concept of structural stability.
The goal is to develop the background needed to understand the principles behind structural instability and to analyze buckling/post-buckling behavior of conventional structural components and periodic structures.
Topics addressed in the course include a soils and paving materials and their interaction; pavement behavior under different loading conditions and ambient conditions; and pavement evaluation, maintenance, and recycling.
Laboratory work on asphaltic material properties and mixture design methods is undertaken.
It will emphasize fundamental concepts and analytical solution techniques.
This course is the first of a two-course sequence on Structural Dynamics and Earthquake Engineering.
This course is an advanced course in reinforced concrete.
Topics addressed in the course include concrete materials; moment-curvature relationships; response of components to flexure, axial force and shearing force; anchorage; strut-and-tie models; limit analysis and design of slabs; seismic design of reinforced concrete buildings that include moment frames and/or shear walls; and seismic analysis and design of safety-related nuclear structures. Prerequisites: CIE 423 (or equivalent) and CIE 429 (or equivalent).