Schedule of Classes

Introduction to the civil engineering professions. Introduction to fundamental engineering concepts; engineering design; engineering ethics; professional societies; introduction to computers and computer applications.

Analysis of two- and three-dimensional force systems by vector algebra. Applications of principles of equilibrium to particles, rigid bodies, and simple structures. Friction, distributed forces, center of gravity, centroids, moments of inertia. U.S. and SI systems of units and applications.

Full-time cooperative education assignment for civil engineering students who alternate periods of full-time school with periods of full-time academic or career-related work in industry. Satisfactory/Unsatisfactory.

Introduction to computing in civil engineering using MATLAB and other software. Arrays, vectors, and matrices, programming in MATLAB, analyzing numeric data, vectors and matrices, analyzing and visualizing data, plotting and graphics.

Theory and applications of measurements of horizontal distances, differences in elevations, horizontal angles, vertical angles, bearings, azimuths, and areas and volumes. Simple horizontal and vertical curves, topographic surveys and mapping. Public land surveying system. Introduction to GPS technology.

Examinations of graphical capabilities of current computer-aided design and drafting (CADD) systems. Theoretical and hands-on applications of the most widely used CADD systems available for Civil Engineering and Construction students.

Kinematics and kinetics of particles and rigid bodies using vector analysis. Kinetics includes principles of force-mass-acceleration, work-energy, and impulse-momentum.

Fluid properties and fluid motion: basic laws of motion in integral form; applications of basic laws in solving fluid flow problems. Hydrostatics, dimensional analysis, similitude, and incompressible viscous flow (both laminar and turbulent) in conduits. Introduction to open channel flow; culverts, sewers, and streams. Laboratory experiments.

Internal forces; stress, strain, and their relations; stresses and deformations in axial and torsional loading; indeterminate problems; stresses and deformations in flexural members; transformation of stresses; introduction to member design; column buckling analysis.

Physical properties of soils, soil profiles, and deposits. Soil strength determination. Flow of water through soil masses. Laboratory experiments.

Analysis of statically determinate structures including influence lines. Deflections by area-moment, conjugate beam, and Castigliano's theorem. Analysis of statically indeterminate structures including influence lines. Classical solutions by consistent displacements, three-moment theorem, moment distribution, and slope deflection methods. Matrix methods for structural analysis by stiffness approach.

Analysis techniques and design procedures for unit operations and unit processes for water and waste water treatment. Techniques for the examination of water and waste water quality.Laboratory experiments.

Theory and design of reinforced concrete structures: beams, columns, slabs, walls, and buildings. Current ACI Code provisions for elastic and ultimate design. Laboratory experiments.

Engineering ethics with applications to sustainable civil infrastructure. Ethical responsibilities to public, clients, and employers. Social responsibility and public participation for civil infrastructure.

Water use and wastewater generation. Conveying and distributing water. Wastewater and stormwater conveyance system design. Design of storage structures and other systems for water conservation and water use; open channel flow, closed conduit flow, hydraulic structures, hydraulic power conversion.

Design of steel structural members. Behavior of members and connections. Theoretical and practical considerations in member selection and joint design.

Introduction to transportation engineering and planning as it relates to highways. Characteristics of highway systems: the driver, vehicle and roadway, traffic engineering studies, highway safety, traffic flow fundamentals, capacity and level of service concepts, intersection traffic control, transportation planning and site impact analysis, geometric design of highways.

Topics of special interest which may vary each time course is offered. Topics are stated in the current Schedule of Classes.

First of a two-semester course design project sequence. Discussions of the relationship between the owner, architect, consultant, superintendent, construction manager, general contractor and subcontractors. Methods of project delivery, Project concepts through construction, design phases, and project challenges. Leadership, ethics, public policy issues, LEED, and basic business management practices. Oral and written report of preliminary plan.

Selected numerical methods and applications chosen to meet current needs for solving problems in civil engineering.

Two- and three-dimensional stress and strain at a point; two-dimensional elasticity; beams on elastic foundations; torsion of noncircular sections; curved beams; unsymmetrical bending; plastic collapse and limit analysis.

Planning and analysis of urban transportation; travel demand models including trip generation, trip distribution, mode choice and traffic assignment; land use planning, site impact analysis and traffic impact studies for proposed developments, and context sensitive solutions.

Distresses in pavements, assessment of asphalt (flexible) and concrete (rigid) pavements, performance tests of pavement materials, material characterization to maintain and rehabilitate pavements, pavement maintenance and rehabilitation methods, life cycle cost analysis of pavement maintenance and rehabilitation.

Research on a topic selected by the student and approved by the chair. Repeatable to a maximum of six hours total.