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(Courses
normally offered, or offered within the previous three years.)
(F) - Fall Semester; (S) - Spring Semester
CIE 500
Special Topics in Civil Engineering (3) (F, S)
Advanced topics in civil engineering to meet the needs and interests of
the students. TUT. Prerequisite: permission of instructor.
CIE 501,
502 Individual Problems (1?6) (F, S)
For Master of Science or Master of Engineering candidates. Investigation
carried out under the direction of a member of the graduate faculty. TUT.
Prerequisite: permission of instructor and approval of department.
CIE 506
Legal Aspects of Civil Engineering Practice (3) (F)
An overview of those aspects of the American legal system most relevant
to engineering practice. Covered are the law of contracts, agency, association,
property, and labor law, studied both generally and in the context in
which the practicing civil engineer encounters them. Specific topics include
the engineer-client relationship, selection of contractors, construction
survey bonds, line law, and engineering determinations. LEC.
CIE 507
GIS Applications (3) (F)
Applications of Geographic Information Systems (GIS) to Civil Engineering
and Planning Problems for students who wish to gain some hands-on skills
in using GIS as a tool in Civil Engineering and Planning. Basic GIS skills
are first developed including digitizing, coordinate transformation, editing,
development of attribute data and files, joining, data conversion between
different formats-internal and external, use of raster and vector data,
moving and joining data from internal and externals files, use of Grids,
Lattices and TINS for 3?D problems, buffer analysis, use of Macros, printing
and plotting using workstation and PC Arc/Info., Intergraph MGE or equivalent
programs. The GIS System is utilized for studies in project areas such
as land use, risk analysis, geographic design wind characterization, reservoir
location and design, pollution transport, hydrologic analysis, routing,
snow removal management, bridge and pavement management, highway sign
management, and underground peaking power plant location. LEC.
CIE 508
Probabilistic Analysis and Design (3) (S)
An in-depth introduction of probability, statistical analysis, and decision
theory with civil engineering applications. Examples will be drawn from
problems in structural design and reliability; transportation, urban,
and environmental systems; water resources; and engineering economics.
LEC.
CIE 511
Advanced Mechanics of Solids (3) (F)
The course provides an intermediate level treatment of solid mechanics
with emphasis on fundamental concepts and classical solutions. After introducing
the primary field variables and governing equations for the mechanics
of continuous media, the focus shifts toward constitutive model development
and the solution of boundary value problems. Problems in elastic and elastoplastic
media are addressed extensively, while thermoelastic and viscoelastic
response is also considered. LEC
CIE 512
Structural Reliability and Safety (3)
Introduction to the concept of safety factors and reliability of structural
and mechanical systems. Systems with several modes of failure and loading
parameters are considered together with current design techniques incorporating
reliability considerations. Other topics include reliability-based design
codes and structural reliability in the case of dynamic loads. (Also listed
as MAE 554.) LEC. Prerequisite: EAS 305 or CIE 508.
CIE 513
Stability (3)
Static stability of columns, frames, arches, plates, and shells. Bifurcation
buckling vs. limit?point buckling. Nonlinear theories and post-buckling.
Introduction to dynamic stability, including parametric resonance, nonconservative
systems, and suddenly applied loads. Survey of recent research on stability.
LEC.
CIE 515
Advanced Structural Analysis (3) (F)
Theory of structures in historical perspective. Graphic analysis; optimum
shapes; equations of Maxwell and Rankine's duality theorems; flexibility
approach and angle distribution. Slope deflection equations, moment distribution,
and matrix methods. Limit analysis with upper- and lower-bound theorems.
Arches and suspension structures. Yield line methods for in-plane and
bending of plates. LEC.
CIE 516
Advanced Mathematics for Civil Engineers (3) (F)
The course covers a range of topics in applied mathematics that are relevant
to contemporary civil engineers in research and practice. Topics include
linear algebra, linear and nonlinear ordinary differential equations,
generalized Fourier analysis and partial differential equations. Mathematical
modeling of physical processes is emphasized. Numerical and symbolic computational
approaches are also addressed. LEC.
CIE 517
Plates and Shells I (3)
"Exact" theories of plates and shells. Static and dynamic models.
Rational approximations. "Improved" and classical theories.
Relation of approximate plate and shell models to elasticity solutions.
Boundary-value problems in plate and shell theories. Anistrophic and sandwich
plates and shells. Stability considerations, linear and nonlinear models.
(Also listed as MAE 525.) Prerequisite: CIE 621 or equivalent or permission
of instructor.
CIE 519
Structural Dynamics and Earthquake Engineering I (3) (F)
Dynamics of lumped parameter and continuous structural systems. Single
degree-of-freedom systems under various classes of time dependent loads.
Response spectra and unit impulse response. Multi degree-of-freedom systems.
Modal analysis and numerical integration. Seismic response. Two class
periods per week. LEC. Prerequisite: CIE 423 or equivalent, EAS 451 or
equivalent.
CIE 520
Random Vibrations And Stochastic Structural Dynamics (3) (F)
Review of probability theory. A description of random processes and their
origin. Linear with one and several degrees of freedom. Continuous structures.
Nonlinear structures. (Also listed as MAE 536.) LEC. Prerequisites: CIE
508 and CIE 519.
CIE 521
Plastic Analysis and Design (3)
Behavior of steel structures beyond the elastic limit and up to collapse;
consideration of the various factors that may constitute design limitation
studies of industrial frame types and comparison of design based on currently
available allowable stress specification with design based on plastic
design specifications and techniques. LEC. Prerequisite: CIE 324 or equivalent.
CIE 524
Steel Structures (3) (S)
Consideration of the basis and criteria of current design specifications
for metal structures; material behavior; failure under stress, strength
theories, brittle fracture, fatigue, residual stress. Fundamentals of
member performance; bending and extension of beams; uniform and nonuniform
torsion; column buckling including the effects of crookedness and rotation,
inelasticity, residual stress; plate buckling; design of girders. Analysis
of three-dimensional structures by matrix analysis methods; computer applications.
Discussion of designs for tall buildings; literature review. LEC
CIE 525
Concrete Structures (3) (F)
Consideration of the mechanics of reinforced and prestressed concrete
structures and structural elements with emphasis on two- and three-dimensional
systems; deep beams, shear walls, two-way slab systems, yield line theory
of slabs, folded plate structures, thin concrete shells. LEC. Prerequisite:
CIE 423 or equivalent.
CIE 526
Finite Element Structural Analysis (3) (F)
Fundamentals of the finite element method: elasticity, matrix algebra,
calculus of vibrations, energy principles. Axial, beam, isoparametric,
membrane, plate, axisymmetric, three-dimensional, torsion, and fluid finite
elements. Solution methodology and computer programming aspects. Ritz
method, Galerkin's method. Finite elements for stability and dynamics.
LEC. Prerequisite: CIE 423 or equivalent, EAS 451 or equivalent.
CIE 527
Design and Construction of Structural Systems (3) (F)
Deals with the application of structural theory in the design of complete
structural systems for building and bridge. The design process is investigated,
beginning with architectural considerations, proceeding through alternate
plans and their evaluation as a structural solution, and ending with a
final design. Topics include: design procedures, sources of information
for design, sources and nature of loading conditions and combinations,
preliminary design methods and estimates, primary and secondary structural
systems, nonstructural components and interaction. LEC/REC. Prerequisite:
Good working knowledge of basic member design, indeterminate analysis,
and computer methods.
CIE 528
Composite Structures (3)
The concepts of continuous and discontinuous fiber reinforcing, their
mechanical properties, methods of computing elastic constants, theoretical
strength predictions, and structural uses will be presented. A detailed
look at the rapidly expanding types of possible composite materials will
also be presented. LEC.
CIE 529
Pavement Design (3) (F)
The analysis and design of flexible and of rigid pavements. Airport, highway,
and other types of pavements will be considered. Included will be a study
of soils and paving materials, their interaction, their behavior under
various loading conditions, and their ability to perform under all ambient
conditions. Pavement evaluation, maintenance, and recycling are also included.
Laboratory sessions arranged on asphaltic material properties and mixture
design methods. Prerequisite: CIE 437.
CIE 530
Mechanical Behavior of Materials (3) (F)
Behavior of structural materials, such as concrete, soils, and metals.
Topics: nature of soil, its formation and composition; stresses in a soil
mass; effective stress concept; basic stress-strain relationships and
their application; drained and undrained strength characteristics of cohesionless
and cohesive soils; consolidation behavior; Camclay models; incremental
theory of plasticity appled to metal, concrete, and soils; failure theories
for ductile and brittle materials; laboratory methods for determining
stress-strain and strength properties. LEC.
CIE 531
Design and Construction of Earth Structures (3) (S)
Selection, engineering design, construction, monitoring and performance
evaluation of earth structures. Densification: Soft ground consolidation,
deep dynamic compaction, compaction; Reinforcement: earth retaining systems,
soil nailing, reinforced earth, micropiles, etc.; ground improvement by
admixtures: grouting, soil mixing techniques. LEC
CIE 533
Structural Design and Construction of Foundations (3) (S)
Structural design and construction of foundation systems. Topics will
include: structural design of shallow foundations, such as single footings,
strip footings, and mat foundations; deep foundations, such as piles and
caissons; retaining walls; sheet piles; excavation bracings; tie backs;
and anchors. This is an application-oriented design course in which students
are required to do a real-life project in groups of three from preliminary
design stage to final construction phase. LEC.
CIE 534
Earthquake Engineering and Foundation Dynamics (3) (S)
Fundamental principles and practical design methods of geotechnical earthquake
engineering and machine foundations are presented. The course begins with
basic concepts of seismology, earthquakes, and strong ground motion and
introduces procedures of seismic hazard analysis. Basic principles of
wave propagation are used to develop procedures for ground response analysis
and to provide insight into such important problems as local site effects,
liquefaction, seismic slope stability, and seismic design of retaining
structures. Analysis and design procedures for dynamically loaded shallow
and pile foundations are also discussed. LEC
CIE 535
Geoenvironmental Engineering (3) (F)
Soil/water/contaminant interaction processes, conduction phenomena, hydraulic
conductivity and contaminant transport phenomena; effects of contaminants
on soil properties, design of landfills, waste disposal systems, seepage
barriers and cut-off walls, site characterization, soil remediation. LEC
CIE 541
Groundwater Engineering (3) (S)
Fundamental physics of single- and multi-phase fluid flow and species
transport in the subsurface. Development of general conservation equations
using a volume averaging procedure. Derivation of well hydraulic formulae.
Discussion and modeling of physical, chemical and biological fate of subsurface
contaminants. Overview of numerical modeling procedures for flow and transport
simulation. Introduction to geostatistics and inverse methods. Application
of theory to field problems with emphasis on the remediation of subsurface
contamination. LEC. Prerequisite: Permission of the instructor.
CIE 543
Water Quality Modeling (3) (S)
Introduction to the application of mathematical models for making rational
decisions regarding the management of natural aquatic systems. Computer
models will be developed and used for simulation of fate and transport
of conventional and priority pollutants in streams, lakes and estuaries.
LEC. Prerequisite: CIE 546, CIE 562.
CIE 546
Environmental Fluid Mechanics (3) (F)
Basic equations of unsteady fluid flow are developed, including continuity,
Navier-Stokes equations, and conservation of energy. Transport processes,
including molecular and turbulent diffusion of mass, momentum and heat,
dispersion in open channel flow. The advection-diffusion equation is derived
for mass conservation of a tracer in natural surface water and atmospheric
systems, and specific analytical solutions are discussed for ideal types
of pollutant sources. Jet and plume modeling, sediment transport, stratified
flow and other selected topics are presented. LEC.
CIE 548
Computational Fluid Mechanics (3)
Numerical methods currently available for solving various types of field
flow problems. Flow fields described by elliptic, parabolic and hyperbolic
systems of partial differential equations. Solution techniques for finite
difference methods, particle-in-cell method, method of characteristics
and finite element method. Computer program development of numerical solution
of two-dimensional Navier-Stokes equations, boundary layer equations and
equations of supersonic inviscid gas dynamics. (Also listed as MAE 540).
LEC. Prerequisite: Permission of the instructor.
CIE 550
Hydrologic Engineering (3) (F)
Consideration of hydrologic cycle-water budget, precipitation, evaporation,
transpiration, infiltration, groundwater and surface water flow, storm
analysis, hydrography analysis, snow hydrology; watershed simulation;
frequency and correlation analysis; hydrologic simulation; application
to design of minor and major structures. LEC. Prerequisite: permission
of instructor.
CIE 552
Water Resources Planning & Development (3) (S)
Consideration of economic, financial and environment analysis techniques
and their use in planning for development of flood control, water supply,
storm and land drainage, navigation, hydroelectric power, water quality
control, reaction, and fish and wildlife enhancement. Prerequisite: Permission
of the instructor. LEC.
CIE 554
Numerical Methods in Water Resources and Environmental Engineering (3)
(S)
Methodology for solving initial and boundary value problems encountered
in water resources and environmental engineering. Numerical solution methods
for linear and non-linear systems of algebraic equations, numerical solutions
of ordinary differential equations, finite difference methods, and finite
element methods. Application of methods to solve differential equations
governing biological and chemical reactions and flow and chemical transport
in aquatic systems. LEC. Prerequisite: Permission of the instructor.
CIE 556
Physical/Chemical Unit Processes (3) (S)
Presents the principles of the physical and chemical unit processes used
in water and wastewater treatment. From process principles, design criteria
are developed. Topics include particulate removal, chemical precipitation,
oxidation, ion exchange, air stripping, adsorption, and ion exchange.
LEC. Prerequisites: CIE 440, CIE 564.
CIE 557-558
Engineering Project (1-6)(F-S)
To be used only by Master's degree candidates whose projects have been
approved by the advisor and who are completing their work for the M.S.
or M.Eng. degree. For M.S. degree candidates, approval of the project
advisor is required for registration. A minimum of 3 and a maximum of
6 hours are allowed. TUT/LEC.
CIE 561
Turbulent Flow (3)
The statistical and phenomenological theories of turbulence and turbulence
transport are outlined; correlation functions, spectral function, decay
laws; semi-empirical theories of turbulence. (Also listed as MAE 519)
LEC. Prerequisite: Permission of the instructor.
CIE 564
Chemical Principles in Environmental Engineering (3) (F)
Presents fundamentals in aquatic chemistry as applied to natural waters,
water treatment, and wastewater treatment. Topics include equilibrium
concepts, chemical thermodynamics, acid-base reactions, precipitation
and dissolution, oxidation and reduction, carbonate system chemistry,
and complexation. LEC. Prerequisite: Permission of the instructor.
CIE 567
Advanced Unit Operations and Processes (3) (F)
Advanced study of physical, chemical, and biological treatment processes.
Emphasis on readings from the engineering literature. Topics include mixing
processes, aquasols, chemical kinetics, adsorption at the solid/liquid
interface, water renovation and reuse. LEC. Prerequisite: Permission of
the instructor.
CIE 569
Hazardous Waste Management (3) (S)
This course was developed to provide engineers with an overview of key
hazardous waste management principles. Topics covered in this course include:
basics of organic chemistry and toxicology, regulations, minimization
principles, treatment techniques, and disposal options. LEC. Prerequisites:
CIE or ENS graduate standing or permission of the instructor.
CIE 589
Assessment, Repair and Retrofit of Structures (S)
Methods for condition assessment of structures and components using destructive
semi-destructive and non-destructive techniques, science of deterioration
of construction materials, approaches for repair and retrofit of existing
structures and infrastructure facilities. Structure types include wood,
steel, concrete and composite structures. Assessment methods are covered
in lecture and laboratory sessions to detect effects of chemical, thermal
and physical loadings and for construction defects. Methods for preparing
structures for repair are covered along with techniques for selecting
appropriate repair materials and applications techniques. TQM for repair
and retrofit and the development of international opportunities using
ISO 9000 standards are covered. Problems of carrying out analyses of partially
deteriorated structures are investigated along with the possible application
of sensors to monitor long-term changes in structural condition.
CIE 591
Estimating Construction Materials, Time, and Costs (3) (F)
The capital-cost control cycle for construction planning and management
will be covered. Included will be cost coding, predesign estimating, adjustments
to expected site, material take-off, price and wage conditions, labor
productivity, indirect project costs, construction methods, and estimating
costs for construction
materials, activities, and equipment. LEC.
CIE 592
Construction Planning And Scheduling (3) (F)
Planning and scheduling of construction project with emphasis on network
scheduling techniques: critical path method (CPM), program evaluation
and review techniques (PERT). Other topics include: time-cost trade-off
analysis, resources management, short interval planning, and project monitoring
and control. LEC.
CIE 593
Construction Project Management (3) (S)
Life cycle planning of projects. Project delivery strategies, contract
types. Preconstruction and mobilization. Bid packaging. Value engineering.
Use scheduling techniques. Management of general conditions. Quality control.
Risk Management. Safety on job site. Work site coordination. Public and
labor relations. Project acceptance and closeout. LEC.
CIE 594
Computer Applications in Construction Management (3) (S)
Design of a computer network for a construction firm. Data organization
and security. Construction planning and scheduling using critical path
analysis. Resource allocation. Cost estimating and cost control. Dispatching.
Real time field applications. LEC.
CIE 595
Construction Technology, Equipment, and Safety (3) (S)
Introduction to basic and advanced construction equipment and methods.
Earth moving, excavation, and lifting. Loading, hauling, compaction, and
finishing. Rock excavation. Foundations. Form work and concrete construction.
Steel construction. Wood construction. Masonry construction. Equipment,
economics and productivity improvement techniques are also presented.
LEC.
CIE 596
Expert Systems in Civil Engineering (3)
An overview of Artificial Intelligence and Knowledge-Based Expert Systems
(KBES). Architecture of KBES. Languages and tools. Survey of existing
tools and systems. Knowledge acquisition techniques. Building a knowledge-based
expert system. LEC/LAB.
CIE 597
Construction Safety and Health Management (3) (S)
The course covers the various causes of construction accidents and the
strategies that can be adopted to prevent worksite injuries and illnesses.
The Workers' Compensation Laws and the OSHA Standards for construction
industry are discussed. Other topics included are: economics of construction
safety management, temporary structures, system safety, ergonomic applications,
safety legislation, health hazards and hazard communication standards.
Model safety programs for the owner and for the contractor are also discussed.
LEC.
CIE 616
Experimental Structural Dynamics (3) (S)
Study of advanced experimentation and instrumentation in structural engineering.
Includes scale modeling, test planning and information accuracy, data
acquisition systems, instrumentation based on analog computers, strainage,
ultrasonic, and electromagnetic resonance. Hands-on experiments using
servohydraulic equipment and shaking tables for earthquake simulators.
Two class periods or one lab session per week.
CIE 617
Advanced Finite Elements (3) (S)
A second course in finite element methods with emphasis on application
to problems in structural engineering and solid mechanics. Topics include
finite element fundamentals and variational formulations, isoperimetric
element formulations, advanced material models (viscoelastic, elastoplastic),
dynamic analysis (modal analysis, time domain analysis), geometric nonlinearities
and contact mechanics. LEC.
CIE 619
Structural Dynamics And Earthquake Engineering II (3) (S)
Topics are centered around earthquake-resistant design of structures.
Introduction to mechanics of earthquakes and characteristics of the strong
ground motions; responses of structures and mechanical behavior of structural
elements under seismic loadings. Techniques to analyze linear and nonlinear
dynamic responses of structures. Discussion of selected research topics.
Regulation of building codes. Applications of basic principles to the
design of buildings, groups and individual projects. Two class periods
per week. LEC. Prerequisite: CIE 519, CIE 515, CIE 428, CIE 425 or equivalents.
CIE 621
Elasticity (3) (F)
Analysis of strain and stress in a three-dimensional continuum. Constitutive
relations for elastic Solids. The field equations of elasticity. Uniqueness
theorems. Problems involving one-, two-, and Three-dimensional bodies.
Thermodynamics and thermoelasticity. (Also listed as MAE 621.) LEC.
CIE 623
Plastic Behavior of Material (3) (S)
Yield conditions and flow laws for rigid-perfectly plastic, rigid-strain
hardening elastic perfectly plastic and elastic strain hardening materials.
Minimum principles and theorems of limit analysis. (Also listed as MAE
623.) LEC. Prerequisite: CIE 511.
CIE 625
Aseismic Base Isolation (3) (F)
Basic concepts of aseismic base isolation, prominent base isolation systems,
base isolation configuration. Analysis and design of elastomeric and sliding
bearings. Energy dissipation devices. Analysis and design of isolation
systems. Testing of base-isolated structures and components. Case studies.
Code provisions. LEC.
CIE 626
Passive And Active Structural Control (3)
Study of theory and applications of passive and active energy dissipation
in structural engineering. Basic principles of energy management and general
concepts of energy dissipation systems. Current methods of passive and
active structural control. System design and practical considerations.
Optimization of control systems. Implementational issues, case studies,
and code provisions. LEC. Prerequisites: CIE 519 and preferably CIE 625
or permission of instructor.
CIE 630
Geotechnical Insitu and Lab Testing (3) (S)
Testing and interpretation of stress-strain behavior, fluid and transport
phenomena, and compressibility characteristics of soils. Laboratory testing.
Triaxial, direct shear, simple shear, torsional shear tests, instrumentation,
data acquisition, interpretation, applications, and limitations. Consolidations
tests, hydraulic conductivity tests (including chemical flow). Insitu
tests and interpretation: SPT, CPT (including piezocone, resistivity cone),
pressuremeter, dilatometer, SASW, etc. Instrumentation and monitoring
of earth structures: settlements, displacements, earth pressure, inclinometer,
pore pressure. LEC/LAB
CIE 641
Advanced Topics in Groundwater Engineering (3) (F)
Mass transport in groundwater systems will be considered, with a focus
on investigation and remediation of subsurface contamination. Emphasis
will be placed on formulation and solution of governing mass and energy
balance equations. Topics of interest include advective-dispersive transport,
geostatistical analysis of spatial heterogeneity, multiphase flow and
transport, design of pump-and-treat systems, computer modeling, and emerging
biological and chemical in-situ remedial technologies. Practical applications
as well as theory will be addressed, including the analysis of remedial
designs using commercial software. LEC
CIE 644
Seismology (3) (S)
Introduction of the main concepts of Earthquake Source Mechanics and Elements
of the Theory of Elastic Wave Propagation. Modern approaches to the problem
of Earthquake strong Ground Motion Synthesis and Prediction. LEC.
CIE 645
Boundary Element Methods in Engineering (3)
Divergence theorems; integration of differential equations and formulation
of boundary integral representations; one-dimensional problems; two-dimensional
problems of potential flow and elastostatics; three-dimensional and axisymmetric
problems; parametric representation of geometry and functions; advanced
numerical integration; time dependent and nonlinear problems; computer
implementation. LEC. Prerequisite: CIE 526.
CIE 646
Geophysical Solid Mechanics (3)
A survey of the theories of elasticity, plasticity, viscoelasticity, rheology,
and their application to explain the static and dynamical behavior of
the solid earth. Covers topics such as stress and strain in the solid
earth, constitutive equations. Viscous flow, fracture, and yielding. Wave
propagation and earthquakes. Rock mechanics, faults, stresses around voids
and openings, instability, folding and linking, etc. (Also listed as Geology
549.) LEC. Prerequisite: Mathematics 241, Strength of Materials or equivalent.
CIE 655
Environmental Engineering Design (3) (F)
Application of biological and physical/chemical treatment principles for
the design of water and wastewater treatment facilities. Topics include
legislation and regulation, water or wastewater characterization, interpretation
of laboratory and pilot plant data, alternative process selection, design
fundamentals, and cost analysis. Group design projects will include drinking
water or industrial process water treatment, biological wastewater treatment,
and industrial or hazardous waste treatment. Guest lectures and field
trips. LEC. Prerequisites: CIE 556, CIE 568.
CIE 662
Methods of Pollutant Analysis (3) (S)
This course covers fundamental and practical aspects of chemical and physical
analysis methods in environmental matrices. Emphasis is placed on chemical
and data analysis techniques applicable to drinking water, municipal wastewater
and industrial waste samples. Laboratory sessions and heavy reliance on
the current literature will extend the material developed in the lectures
and class discussions. LEC/LAB. Prerequisite: CIE 564 or permission of
the instructor.
CIE 664
Organic Chemical Principles (2) (S)
Presents fundamentals in organic chemistry as applied to natural waters,
water treatment, and wastewater treatment. Topics include organic nomenclature,
thermodynamics, aliphatic substitution, electrophilic substitution, oxidation-reduction,
linear free energy relationships, structure-activity relationships, and
adsorption. LEC. Prerequisite: CIE 564, CIE 565 or permission of the instructor.
CIE 665
Environmental Processing of Organic Chemicals (3) (S)
This course examines the physical and chemical processes that control
the fate and transport of organic chemicals in the natural environment.
The course will focus on organic compounds that are persistent, pose health
risk to ecosystems, and tend to bioaccumulate. Students will analyze current
scientific literature and address current issues in environmental organic
chemistry.
SEAS
Graduate Courses
EAS 521
Principles Of Engineering Management I (3)
Introduction to the management functions of planning, organization, leadership,
and control for engineers, scientists, and other technical professionals.
Methods for setting objectives, decision-making, forecasting, and budgeting.
How to select an organizational structure and clarify work relationships.
Techniques for written and oral communication will be emphasized throughout
the course.
EAS 522
Principles Of Engineering Management II (3) (S)
Introduction to the fundamentals of managerial accounting, marketing of
technology-based products or services, and basics in financial management.
Overview of quantitative models related to investment decisions, equipment
replacement, capacity expansion, and capital budgeting.
EAS 589,
590 Case Studies in Engineering Management (3)
This capstone course should be taken in the last semester of the student's
program. A case-oriented course which examines in detail the role of the
engineering manager as strategic planner and policy maker. Five or six
case studies will be presented for discussion, analysis, and report. The
use and efficacy of engineering management methods will be evaluated for
each case.
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