This course offers a practical immersion in a live campus construction project, providing direct exposure to the roles and duties of Project Engineers, Managers, and Superintendents. By engaging in field activities, meetings, and context analysis, participants gain valuable hands-on understanding of construction management, problem-solving, and the decision-making process, preparing them with the competencies valued by industry experts.

Direct stiffness analysis of frames and grids; second order frame analysis; uniform torsion of non-circular sections; influence functions; introduction to work and energy theorems; polynomial approximation and approximate stiffness matrices for framed structures; topics in beam analysis including shear deformable beams, beams on elastic foundations and elastic foundations. Prerequisite: CE 3300 or equivalent.

Applies basic engineering principles, analytical procedures and design methodology to special problems of current interest in civil engineering. Topic for each semester are announced at the time of course enrollment.

An introductory to sustainability metrics and the engineering tools of industrial ecology, most notably life cycle assessment (LCA). Case studies from various engineering disciplines will be explored. Students will undertake an open-ended LCA project related to their thesis research or improving the sustainability of UVA operations. Prerequisite: SEAS 4th-year or Grad standing.

This class focuses on the next generation of buildings where smart devices, Internet of Things (IoT) systems, machine learning applications, and simulations platforms will be utilized to contextualize the changes in indoor environments and occupants¿ needs, allowing building systems (e.g., HVAC, lighting, blinds) to dynamically adjust themselves to enhance the indoor environmental conditions from the health, comfort, and energy perspectives.

This course focuses on urban stormwater management, covering its effects on infrastructure and ecosystems, hydrologic principles, regulations, and both structural and non-structural management strategies. It includes practical projects and modeling tools, with options for graduate customization to align with academic and career objectives. Graduate students have opportunity to customize class to their academic and professional goals.

This course covers the basic principles of aquatic chemistry as applied to problems in natural and engineered waters. Four specific reaction types will be covered including 1) acid-base, 2) precipitation-dissolution, 3) complexation, and 4) oxidation-reduction. Problem solving skills will be developed using graphical and analytical techniques. Students will also develop computer simulation skills. Taught concurrently with CE 4100

Stresses the quantitative description and the physical basis of hydrology. Both deterministic and stochastic methodology are applied to the analysis of the hydrologic cycle, namely, precipitation, evaporation, overland flow and stream flow, infiltration, and groundwater flow. The use of compute simulation models, especially microcomputer based models, is emphasized. Prerequisite: Instructor permission.

Economic theory and applications enhance transport demand analysis, transport pricing, welfare considerations and policy evaluation. This course illustrates the fundamentals of transport economics (costs, benefits and pricing), describes key factors that affect these (movement and location choice), and introduces different methods of economic analysis for quantifying the trends in and interactions across these topics. Pre/Co-requisite: CE 6410

Detailed study of special topics in civil engineering. Master's-level graduate students. Prerequisites: to be listed for each section as needed