Project management skills are just as crucial to success as engineering skills. Therefore, it is essential to understand how projects are planned, executed, and managed.The purpose of this course is to introduce the principles of project management. The course will equip students with the concepts, tools, and language of project management that can be applied to any project size and type.

In this course, students will learn how to use Building Information Modeling to 1) support the decision-making over a project life cycle and 2) improve coordination between stakeholders throughout the design and construction stages. With this hands-on course, students will learn how to integrate all project models to visualize construction process and better predict, manage, and communicate project outcomes.

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.

We will explore terminology and concepts for characterizing and mathematically modeling human impacts on microbial systems and vice versa. Special consideration will be given to microbe-mediated cycling of organic materials (i.e., pollutants) in natural and engineered systems, including: conventional water and wastewater treatment, municipal landfills, pristine and contaminated groundwater and surface waters, etc.

The goal of this course is to illustrate the importance of uncertainty analysis in hydrology. Topics include extreme value theory applied to floods & droughts, regionalization methods for predictions in ungauged basins, & trend analysis of historical time series. Students should leave the course with an understanding of how to apply these methods in practice to design civil infrastructure systems that are robust to hydrologic uncertainty. Prerequisite: APMA 3100 and CE 3220 or Equivalent

Study of the dynamic behavior of such structures as beams, rigid frames, floors, bridges, and multi-story buildings under the action of various disturbing forces such as wind, blasts, earthquakes, vehicles, machinery, etc.; dynamic modeling of single, multidegree of freedom, and continuous systems; damping; numerical integration; Prerequisite: Concrete and metal structure design.