Schedule of Classes

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.

State-of-the-art algorithms used in solving complex engineering problems. Mathematical models involving ordinary and partial differential equations. Initial value, boundary value, and transient problems in civil engineering.

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.

Basic probabilistic and statistical decision making principles used in civil engineering design and practice. Probabilistics models and decision theory.

Pavement engineering and design. Selection testing, and use of highway pavement construction materials in relation to function, environment, and cost. Structural properties of asphalt (flexible) and concrete (rigid) pavements; 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.

Introduction to engineering economics with applications to assessment of sustainable alternatives in infrastructure, ability to engage in life-long learning, knowledge of contemporary issues, understanding professional and ethical responsibility, and ability to function on multi-disciplinary teams. Applications of systems engineering concepts including optimization.

Analysis and design of footings, raft foundations, retaining walls, piles, and caissons, based on current theories and design considerations in soil mechanics, concrete, and steel.

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.

Introduction to hydrological cycle. Hydrologic measurements and monitoring. Surface water hydrology: runoff and the catchment, hydrographs, unit hydrographs, hydrograph routing, urban and small watershed hydrology, hydrologic design, synthetic streamflows, simulation models, applications of probability and statistics to surface water hydrology.

Detailed design of systems. Application of engineering design principles to realistic projects in structural engineering, environmental engineering, site development. Codes and standards, feasibility studies, consideration of design alternatives, selection criteria including systems sustainability, and aesthetics. Oral and written report of final design with specifications, engineering drawings, and project cost estimates.

Sustainability as it is expressed in environmental regulations and policies for conventional and hazardous wastes in air, water, and groundwater. Toxicological, risk assessment, risk-based engineering, and regulatory aspects for the sustainable management of all types of waste.

Sources, composition, and properties of solid waste. Transport of solid wastes and design of transfer stations. Separation, transformation, and recycling of waste materials. Landfill siting. Leachate generation, collection, and removal systems. Liner system design. Landfill settlement and stability analysis. Accelerated treatment of solid waste. Methane recovery from landfills. Closure, restoration, and rehabilitation of landfills. Case studies.

Structural framing systems; rigid frame design; design of bracing; design of simple rigid and moment resisting connections; torsion of steel open sections; design of beams subjected to torsion; design of steel plate girders; design of composite beams.

Advanced topics in flexural design; torsion in beams; behavior and design of slender columns; biaxial bending of columns; design of two-way slabs; behavior and design of frame-wall structural systems; inelastic analysis of flexural members; use of strut and tie analysis; yield line analysis; design of mat foundations.

Safety aspects of streets and highways; planning, implementation, and evaluation of highway safety improvement projects and programs. Highway risk analysis and risk management systems.

Application of engineering economy for transportation systems; analysis of congestion costs, highway transportation costs, and road user consequences. Identification and measurement of highway benefits, concepts of value and time, and willingness to pay; discount rate and vest charge; concepts of depreciation and service life; life cycle cost analysis; evaluation of transportation alternatives and evaluation of completed projects/programs.

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

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