Fundamentals of traffic flow including its characheristics and their relationships; Mathematical models that describe traffic flow dynamics at multiple levels of detail; Solutions and applications of these models that capture traffic flow phenomena such as congestion and queue dissipation.

With lab. Interpretation of geology for the purpose of planning, siting, design, and construction of engineered facilities. Includes plate tectonics, mineral and rock identification, engineering geologic mapping, air photo interpretation, residual soils, glaciation, and engineering problems associated with geologic features. Prerequisite: CE-ENGIN 320.

Chemical equilibrium principles of acids-bases, dissolution-precipitation, oxidation-reduction, and complexation applied to understanding the chemistry of surface waters, groundwaters, and water and wastewater treatment.

Design, selection, and use of instrumentation for geotechnical engineering purposes. Laboratory and field instrumentation considered. Topics include: purpose of instrumentation, planning projects, procurement of instruments and services, measuring devices, and examples of applications. Lab demonstration.

Chemical equilibrium principles of acids-bases, dissolution-precipitation, oxidation-reduction, and complexation applied to understanding the chemistry of surface waters, groundwaters, and water and wastewater treatment.

Traffic control at intersections with an emphasis on intersection signalization; warrants that justify the installation of signals; signal sequence, timing, and phasing; pre-timed and actuated signals; traffic detection and signal controllers; computer simulation and modeling; algorithms and tools for evaluating the effectiveness of signals.

Description not available at this time

Relationship of public transportation to technological innovation; financing and regulation; supply, demand, and price considerations; performance evaluation; routing and scheduling; application of microcomputers; and project planning and design. Prerequisites: CE-ENGIN 310.

A historical overview of public transportation and a summary of existing and future transit and paratransit systems and technologies; application of intelligent transportation system (ITS) technologies (including advanced communication, sensor, and information processing technologies) in the implementation of transit and paratransit operations; public transit systems costs, demand, pricing, and performance evaluation; project planning including routing, scheduling, preliminary design and ownership and organizational options; and systems planning.

Introduction to fundamental principles and concepts necessary to carry out meaningful and appropriate geographic analysis with geographic information science (GIS). Reinforcement of key issues in GIS such as geographic coordinate systems, map projections, spatial analysis, use of remotely sensed data, and visualization of spatial data. Laboratory exercises use database query, database manipulation, and spatial analysis to address problems in hydrology, water treatment, renewable energy, and transportation with an emphasis on engineering design.