CEE 280: Advanced Structural Analysis
Theoretical development and computer implementation of direct stiffness method of structural analysis; virtual work principles; computation of element stiffness matrices and load vectors; direct assembly procedures; equation solution techniques. Analysis of two- and three-dimensional truss and frame structures, thermal loads, and substructuring and condensation techniques for large systems. Practical modeling techniques and programming assignments. Introduction to nonlinear analysis concepts. Prerequisites: elementary structural analysis and matrix algebra.
Terms: Aut
| Units: 3-4
Instructors:
Deierlein, G. (PI)
CEE 282: Nonlinear Structural Analysis
Introduction to methods of geometric and material nonlinear analysis, emphasizing modeling approaches for framed structures. Large-displacement analysis, concentrated and distributed plasticity models, and nonlinear solution methods. Applications to frame stability and performance-based seismic design. Assignments emphasize computer implementation and applications. Prerequisites: 280 and an advanced course in structural behavior (e.g., 285A, 285B or equivalent).
Terms: Win
| Units: 3-4
Instructors:
Deierlein, G. (PI)
CEE 284: Finite Element Methods in Structural Dynamics
Computational methods for structural dynamics analysis of discrete and continuous systems in free and forced vibration; finite element formulation; modal analysis; numerical methods; introduction to nonlinear dynamics; advanced topics. Prerequisites: 280, 283.
Terms: Aut
| Units: 3-4
Instructors:
Law, K. (PI)
CEE 307: Structural Design Optimization
Introduction to optimization (design variables, objective functions, constraints, etc); Multi-objective concept; Pareto optimization; Solution of optimization problems using differential and variational calculus; Mathematical programming methods; Lagrange multipliers and mini-max problems; Penalty function methods; Karush-Kuhn-Tucker (KKT) optimality conditions; Sensitivity analysis (analytical, semi-analytical and numerical methods); Introduction to topology optimization; Optimization process in practice (many applications); Graphics statics. Rapid prototyping and 3D printing techniques; Prerequisite:
CEE 280 or equivalent in advanced structural analysis, and Matlab programming. Recommended:
CEE 281 or equivalent in finite element analysis.
Terms: Aut
| Units: 4
Instructors:
Paulino, G. (PI)
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