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Undergraduate Transportation Courses:

• : This course introduces students to transportation planning concepts and methods, including travel demand forecasting, transportation economics, and societal impacts such as environmental and safety issues. Quantitative techniques like discrete choice models, regression methods, and optimization techniques are also covered.
• : Students learn about the principles and practice of transportation engineering, traffic flow theory, multimodal level of service analysis, and traffic control. The course also covers geometric and pavement design fundamentals and the impact of modern technologies on transportation systems.

General Civil Engineering Courses:

• : This course emphasizes student responsibilities for learning and critical thinking. It reinforces concepts from math, physics, and computer science and covers academic success strategies such as time management, critical thinking, and professional communication.
• : Aimed at engineering majors, this course transitions students from Python to C++ programming, with a focus on common C++ techniques. It includes crash sessions with online lectures and exercises.
• : The course teaches graphical methods for civil engineering projects, including structural plans, topographic mapping, and the use of modern computer software.
• : Topics include laws of motion, vector algebra, equilibrium of rigid bodies, internal forces, friction, and stability of equilibrium.
• : This introductory course covers fundamental surveying techniques.
• : Students learn to solve civil engineering problems using algorithmic formulation, flowcharts, and various computational tools, including microcomputers and symbolic calculations software.
• : The course covers large-scale civil engineering systems analysis, modeling, and optimization, with applications in management and planning.
• : Topics include stresses and strains, deformations, Mohr circles, and stability of columns.
• : This course focuses on structural determinacy, analysis of trusses and frames, influence lines, and computer applications.
• : Students explore geotechnical engineering, soil properties, consolidation, shear strength, and slope stability.
• : The course examines the behavior of fluids at rest and in motion, with applications in flow dynamics and boundary layers.
• : Topics include hydraulic system analysis, pipe networks, pumps, turbines, and hydrology applications.
• : Students learn about NEPA, environmental impacts of engineering projects, pollutant transport, and federal regulations.
• : This self-study course reviews core civil engineering topics and prepares students for the Fundamentals of Engineering exam.
• : The course covers project management, ethical responsibilities, project life cycle analysis, and dispute resolution.
• : Students study kinematics, kinetics, energy methods, and vibration analysis for civil engineering structures.
• : The course introduces finite element methods for analyzing trusses, frames, and plane strain elements.
• : This course focuses on reinforced concrete design, including beams, slabs, and columns, with considerations for safety factors and serviceability.
• : Topics include the design of structural frames, load and resistance factor design, and public safety implications.
• : The course covers water pollution, hydrologic cycles, contaminant transport, and pollution remediation.
• : Students learn about the design parameters for water and wastewater treatment processes using bench-scale experiments and computer software.
• : This capstone project emphasizes multi-disciplinary collaboration and incorporates various engineering constraints.
• : Students engage in independent study projects under faculty supervision, focusing on design, experimental investigation, or analytical study.
• : This course reviews core civil engineering topics and tests student competence through a self-study format.
• : The course covers functional design of traffic facilities using computer-aided design methods.
• : Students learn about designing rail facilities, track structures, and maintenance technologies.
• : Topics include elasticity, stress analysis, torsion, and buckling criteria.
• : The course focuses on highway design, pavement type, earthwork, drainage, and maintenance.
• : Students learn about construction planning, scheduling, operations, and environmental impact mitigation.
• : This course explores urban transportation systems, safety considerations, and technology applications.
• : The course covers urban freight distribution, data collection strategies, and decision-making methodologies.