CIVE.5040 Advanced Strength Of Material (3cr)
Stress and strain at a point; curved beam theory, unsymmetrical bending, shear center, torsion of non-circular sections; theories of failure; selected topics in solid mechanics.
CIVE.5050 Construction Safety (3cr)
This course introduces fundamental and advanced topics on the properties of concrete materials. Fundamental topics include the formation, structure, mechanical behavior, durability, fracture, and deterioration of concrete. Theoretical treatments on the deformation, fracture and deterioration of concrete are also addressed. Advanced topics include the electromagnetic properties of concrete, high performance concrete (HPC), high-strength concrete (HSC), fiber-reinforced concrete, other special concretes, and the green construction of concrete.
CIVE.5110 Inspection and Monitoring of Civil Infrastructure (3cr)
In this course, principles and applications of
inspection and monitoring techniques for the
condition assessment of
aged/damaged/deteriorated civil infrastructure
systems such as buildings, bridges, and
pipelines, are introduced. Current
nondestructive testing/evaluation (NDT/E)
methods including optical, acoustic/ultrasonic,
thermal, magnetic/electrical, radiographic,
microwave/radar techniques are addressed with a
consideration of their theoretical background.
Wired and wireless structural health monitoring
(SHM) systems for civil infrastructure are also
covered. Applications using inspection and
monitoring techniques are discussed with
practical issues in each application.
CIVE.5120 Structural Stability (3cr)
This course provides a concise introduction to the principles and applications of structural stability for their practical use in the design of steel frame structures. Concepts of elastic and plastic theories are introduced. Stability problems of structural members including columns, beam-columns, rigid frames, and beams are studied. Approaches in evaluating stability problems, including energy and numerical methods, are also addressed.
CIVE.5150 Cementitious Materials for Sustainable Concrete (3cr)
This course is designed for introducing advanced topics in cement hydration chemistry, materials characterization and concrete sustainability. Advanced topics in chemistry of commonly used cementitious materials, micro-structure, mechanical properties, durability ad sustainability will be offered. Students will learn and practice to characterize and analyze the roles of chemical admixtures and supplementary cementitious materials in concrete property improvement. Chemical issues involved in the engineering behavior of concrete will be offered. A service-learning project about sustainable concrete will be provided. Emerging topics such as self-healing concrete, self-consolidating concrete, mart concrete, 3D concrete printing and ultra-high performance concrete will also be covered.
Requirements:
CIVE.3100 Engineering Materials, or CIVE.5050 Concrete Materials, or Permission of Instructor.
CIVE.5210 Reliability Analysis (3cr)
A review of the elementary principles of probability and statistics followed by advanced topics including decision analysis, Monte Carlo simulation, and system reliability. In-depth quantitative treatment in the modeling of engineering problems, evaluation of system reliability, and risk-benefit decision management.
CIVE.5280 Drilled Deep Foundations (3cr)
Design and analyses of drilled deep foundations including: Deep foundations classification and historical perspective. Cost analysis of foundations. Construction methods and monitoring techniques. Static capacity and displacement analyses of a single drilled foundation and a group under vertical and lateral loads. Traditional and alternative load test methods - standards, construction, interpretation, and simulation. Integrity testing methods. Reliability based design using the Load and Resistance Factor design (LRFD) methodology application for drilled deep foundations.
Requirements:
CIVE.5310 Advanced Soil Mechanics, or Permission of Instructor.
CIVE.5300 Driven Deep Foundations (3cr)
design and analyses of driven deep foundations including: Deep foundations classification and historical perspective. Effects of pile installation. Static capacity and settlement analysis of a single pile and a pile group under vertical loads. Insight of pile resistance including soil behavior and interfacial friction. Driven pile load test standards, construction, interpretation, and simulation. Dynamic analysis of driven piles, the wave equation analysis, dynamic measurements during driving and their interpretation. Reliability based design using the Load and Resistance Factor design (LRFD) methodology application for driven deep foundations.
Requirements:
CIVE.5310 Pre-req
CIVE.5310 Advanced Soil Mechanics (3cr)
Theories of soil mechanics and their application. Drained and undrained stress-strain and strength behavior of soils. Lateral earth pressures, bearing capacity, slope stability, seepage and consolidation. Lab and insitu testing.
CIVE.5340 Soil Dynamics and Earthquake Engineering (3cr)
Effects of dynamic loading on foundations and earth structures. Single and multiple degree-of-freedom systems. Modal analysis. Basic seismology. Stress-strain and strength behavior of soils during cyclic and dynamic loading, including liquefaction. Soil amplification. Effect of earthquakes on retaining walls and dams. Dynamically loaded foundations.
CIVE.5390 Ground Improvement (3cr)
Design and construction methods for strengthening the properties and behavior of soils. Highway embankments, soil nailing, soil grouting, landslide investigation and mitigation, dynamic compaction, stone columns.
CIVE.5410 Traffic Engineering (3cr)
Engineering principles for safe and efficient movement of goods and people on streets and highways, including aspects of (a) transportation planning; (b) geometric design; (c) traffic operations and control; (d) traffic safety, and; (e) management of transportation facilities. Topics include: traffic stream characteristics; traffic engineering studies; capacity and level-of-service analysis; traffic control; simulation of traffic operations; accident studies; parking studies; environmental impacts.
CIVE.5510 Advanced Steel Design (3cr)
Elastic and plastic design of structural steel systems, residual stresses, local buckling, beam-columns, torsion and biaxial bending, composite steel-concrete members, load and resistance factor design.
CIVE.5560 Finite Element Analysis (3cr)
Finite element theory and formulation, software applications, static and dynamic finite element analysis of structures and components.
CIVE.5570 Structural Dynamics (3cr)
Analysis of typical structures subjected to dynamic force or ground excitation using direct integration of equations of motion, modal analysis and approximate methods.
CIVE.5760 GIS Applications in Civil and Environmental Engineering (3cr)
This course is to introduce students to the basic concepts of Geographic Information Systems (GIS) and GIS applications in Civil and Environmental Engineering. Topics to be covered include GIS data and maps, queries, map digitization, data management, spatial analysis, network analysis, geocoding, coordination systems and map projections, editing. Examples related to transportation, environmental, geotechnical and structural engineering will be provided to help students better understand how to apply GIS in the real world and gain hands-on experience. This course will consist of lectures and computer work.
CIVE.5810 Engineering Systems Analysis (3cr)
The course presents advanced methods of operations research, management science and economic analysis that are used in the design, planning and management of engineering systems. Main topics covered, include: the systems analysis methodology, optimization concepts, mathematical programming techniques, Network analysis and design, project planning and scheduling, decision analysis, queuing systems, simulation methods, economic evaluation. The examples and problems presented in the course illustrate how the analysis methods are used in a variety of systems applications, such as: civil engineering, environmental systems, transportation systems, construction management, water resources, urban development, etc.