Graduate Courses

Advanced computational methods to solve civil engineering problems. Matrix methods for structural analysis. Numerical differentiation and integration. Solving differential equations with finite difference and Euler and multi-step methods. Analysis of discrete and continuous mechanical systems.

Principles and procedures used in construction management. Advanced topics in planning, management organization, estimating and bidding of construction projects, construction contracts, contract documents, construction insurance and bonds; labor law, labor relations, and project safety; project planning and scheduling techniques, including CPM, PERT; resource allocations; project control and treatment of uncertainty.

Advanced topics in traffic engineering; traffic stream components and characteristics; detailed principles of traffic flow; studies of traffic speed, volume, travel time, delay, and pedestrian; capacity analysis of freeways, highways, signalized and unsignalized intersections; traffic control devices; traffic signals; traffic accidents and safety; and traffic management.

Study of permanent retaining structures, mechanically stabilized earth, and soil nailed walls. Foundations, including footings, piers, and piles, and raft foundations. Temporary shoring of excavations. Advanced slope stability fundamentals.

Advanced topics pertaining to design of structural steel elements for buildings using the LRFD method. Topics include tension members, columns, beams, beam-columns, and bolted and welded connections.

Analysis and design of structural units and building systems. Lateral force resistance to wind and seismic forces: diaphragms and lateral resisting frames. Fundamental aspects of steel, reinforced concrete, masonry, and pre-stressed/post-tension design. Introduction to structural detailing and drawings. Owner, Architectural, and MEP coordination and constraints as it relates to structural engineering. Emphasis on IBC, ASCE loading, ACI and AISC codes.

Advanced principles of analysis of indeterminate structures by slope deflection method; moment distribution method; approximate methods of analysis. Further study of  space structures.

Advanced study of seismic loads and ground motion and resulting response of structures. Response spectra and their application to earthquake analysis of structures. Seismic design criteria and provisions for buildings and other structures. Use of current codes for earthquake resistant design of structures.

Exploration of the advanced principles of Building Information Modeling (BIM) used to improve project outcomes by enabling more rapid visualization and simulation as well as optimized collaboration with intelligent, data-rich models.  Fundamentals of BIM modeling with Autodesk Revit software will be introduced.  Extended course project and research paper will be required.

Advanced topics regarding of different structures around the world. Structural analyses and design of steel, reinforced concrete, masonry and pre-stressed / post-tension components. General aspects of owner, architectural and municipality coordination and basics of societal and environmental demands on structural types.

Advanced topics in GIS & GPS theory and applications for site planning, civil/environmental design and analysis, and infrastructure management.

This course will address advanced topics involved in the design of sustainable facilities and communities. Topics will include: sustainable measures, stormwater management, water use, energy use, appropriate materials, and waste minimization. Guest speakers and field trips will be featured.  Special project will be required.

Advanced study of the hydrologic cycle; rainfall and streamflow measurement and analysis, surface and groundwater occurrence and movement. Prediction of infiltration, evapotranspiration, runoff, and unit hydrograph analysis. Flood and drought probability analysis. Introduction to reservoir operation and flood routing. Design aspects culminate in engineering design reports.

Advanced design of lined or rigid boundary ("engineered") channels, unlined or erodible ("natural") channels, weirs, spillways, stilling basins, culverts, and other hydraulic structures. Students learn how to determine the water surface profile for gradually varied flow conditions. Principles of hydraulic analysis, including specific energy, momentum, critical depth, and uniform flow, will be applied. Students study advanced topics in open channel flow and complete a special project that will be presented as a lecture.

Advanced study of the fundamental concepts required to design and operate processes used for drinking water treatment and distribution and wastewater collection and treatment. Design of physical, chemical, and biological processes for water treatment and wastewater disposal. Design of water supply and wastewater collection infrastructure. Design aspects culminate in engineering design reports. Special report required.

Introduction to the technology used to manage solid and hazardous wastes and remediate sites contaminated with toxic chemicals. Sanitary landfill design, risk assessment, remedial investigations and feasibility studies, fate and transport analysis. Introduction to air pollution modeling and air pollution treatment technologies. Students complete special project.

Credit arranged.

Credit arranged.

Credit arranged.

Faculty-directed student research. Before enrolling, a student must consult with a faculty member to define the project. May be repeated for credit.

Credit arranged.