CE-CIVIL
ENGINEERING -- 2003-05 Catalog
Civil & Environmental Engineering Department
CE
111 Introduction to Civil Engineering
(1) (CR/NC)
Broad
overview of the field of civil engineering, including professional societies
and their student chapters, professional licensing and registration,
professional codes of ethics, the elements of engineering design, and the scope
of analysis and design activities undertaken by private- and public-sector
civil design professionals. Credit/No Credit grading only. 1 lecture.
CE
114 Introduction to CAD in Civil and
Environmental Engineering (4)
The
Civil and Environmental Engineering design process. Use of AutoCAD to
illustrate and quantify design alternatives. Practice in creating and
evaluating typical designs drawn from different specialty areas of the field.
Related topics in information technology. 2 lectures, 2 laboratories.
Prerequisite: MATH 141; CSC 110 or equivalent or passing score on qualifying
test of basic computer skills.
CE
200 Special Problems for Undergraduates
(1–2) (CR/NC)
Individual
investigation, research, studies, or surveys of selected problems. Total credit
limited to 4 units, with a maximum of 2 units per quarter. Credit/No Credit
grading only. Prerequisite: Consent of department chair.
CE
201 Strength of Materials (5)
Stresses,
strains, and deformations associated with axial, torsional, and flexural
loading of bars, shafts, and beams. Mohr’s Circle representations of the state
of stress and strain at a point. Buckling of rigid and deformable columns.
Analysis of elementary determinate and indeterminate mechanical and structural
systems. Equivalent in content to CE 204 and CE 205. 5 lectures. Prerequisite:
ME 211.
CE
204 Strength of Materials I (3)
Stresses,
strains, and deformations associated with axial, torsional, and flexural
loading of bars, shafts, and beams. Analysis of elementary determinate and
indeterminate mechanical and structural systems. 3 lectures. Prerequisite: ME
211.
CE
205 Strength of Materials II (2)
Mohr’s
Circle representations of the state of stress and strain at a point. Analysis
of beam deflections and rotations. Shear force and bending moment diagrams for
indeterminate beams. Buckling of rigid and deformable columns. 2 lectures.
Prerequisite: CE 204.
CE
206 Strength of Materials Laboratory
(1)
Introduction
to experimental stress analysis. Verification of analytical equations through
strain gage measurements of axially, torsionally, and flexurally loaded
specimens. 1 laboratory. Prerequisite or concurrent: CE 201 or CE 205.
CE
221 Fundamentals of Transportation
Engineering (3)
The
characteristics and functions of highway, air, rail, transit and other modes of
urban and intercity transportation. History of transportation design,
operations, and planning. Evaluation of costs, benefits, and environmental
considerations. 3 lectures. Prerequisite: MATH 141.
CE
222 Fundamentals of Transportation
Engineering Laboratory (2)
Application
of principles of transportation planning, operations, and design. Emphasis on
urban transportation planning and operations, and the design of urban and
intercity highway and rail facilities. 2 laboratories. Prerequisite: CE 221.
CE
259 Civil Engineering Materials (2)
Experimental
determination of mechanical properties of concrete, asphalt, and soils as required
for engineering applications. Experimental verification of assumptions made in
mechanics of materials procedures. Use of strain measuring devices.
Prepara-tion of technical reports. 2 laboratories. Prerequisite: CE 204.
CE
336 Water Resources Engineering (4)
Hydraulics
of open channel flow, flow through hydraulic structures, stream flow and stream
flow hydrographs, hydrologic routing. 4 lectures. Prerequisite: ME 341.
CE
337 Hydraulics Laboratory (1)
Application
of basic fluid dynamic principles to various mechanical systems. Exposure to
experimental problems and techniques with guided laboratory projects related to
civil engineering discipline. 1 laboratory. Prerequisite: ME 341.
CE
351 Structural Analysis (5)
Analysis
for member forces and deflections of determinate and indeterminate structures,
including trusses, beams, and frames. General theorems, influence diagrams, and
energy methods. 5 lectures. Prerequisite: CE 201 or CE 205.
CE
355 Reinforced Concrete Design (3)
Analytical
and design principles of reinforced concrete in designing civil engineering
systems. Origin of code requirements. Fundamentals of proportioning. Details of
elements and structural systems. 3 lectures. Prerequisite: CE 259, CE 351.
CE
381 Geotechnical Engineering (4)
Engineering
geology, elementary mass-volume relations, clay-water interaction, soil
classification, soil compaction, geostatic stress distributions, 1-D and 2-D
steady-state flow, shear strength under drained and undrained conditions. 4
lectures. Prerequisite: CE 205, ME 341.
CE
382 Geotechnical Engineering Laboratory
(1)
Use
of standard laboratory test methods to determine physical, mechanical, and
hydraulic properties of soil. 1 laboratory. Co-requisite: CE 381.
CE
400 Special Problems for Advanced
Undergraduates (1–2)
Individual
investigation, research, studies, or surveys of selected problems. Total credit
limited to 4 units, with a maximum of 2 units per quarter. Prerequisite:
Consent of department chair.
CE
401 Linear Elasticity (4)
The
concept of stress and the development of balance laws. Development of
displacement, strain and compatibility relations. Material response and
constitution. Solution formulations and uniqueness. Two-dimensional problems in
elasticity. 4 lectures. Prerequisite: CE 351.
CE
402 Advanced Strength of Materials (4)
Development
of reduced order theories such as torsion, beams and columns from the general
three-dimensional continuum. Application and limitation of these theories are
discussed. Similarities are drawn between analytical formulas and code base
rules and/or formulas. 4 lectures. Prerequisite: CE 401.
CE
407 Structural Dynamics (4)
Effect
of vibration and transient loads on structural elements. Dynamics load factors,
support motion, damping and natural frequencies of multidimensional structural
systems. Modal analysis. 3 lectures, 1 laboratory. Prerequisite: CE 351, ME
212.
CE
421 Traffic Engineering (4)
Improvement
of urban circulation on freeways, city streets, and parking facilities. Traffic
monitoring and control. Traffic data systems. Centralized versus decentralized
control. Use of traffic simulation. New technologies. 3 lectures, 1 laboratory.
Prerequisite: CE 221 or consent of instructor.
CE
422 Highway Geometrics and Design (4)
Location
and safe geometric design of highway and other transportation facilities.
Earthwork and drainage related to highway, railway, dock, and airport design.
Theory and practice in design of alignments, highway cross-sections,
intersections, interchanges, and freeways in urban and rural areas. 2 lectures,
2 laboratories. Prerequisite: CE 221 or consent of instructor.
CE
424 Public Transportation (4)
Interdisciplinary
aspects of public transportation problems, systems-team design approach to
solutions. History and present state of public transportation; role of public
transportation in urban environment; legislative, political, social, and
economic aspects of public transportation systems. Methodology and procedures
for transit planning. Review of transit studies. 3 lectures, 1 laboratory.
Prerequisite: CE 221 or consent of instructor.
CE
431 Coastal Hydraulics I (3)
Waves
and their characteristics, types of waves, water wave theories, orbital
velocities, refraction of waves, wave diffraction, wave reflection, application
of linear theory to wave forces on cylindrical structures, submerged pipelines
and vertical flat barriers (sea walls), wave uprush, rubble mound breakwaters.
3 lectures. Prerequisite: ME 341.
CE
432 Coastal Hydraulics II (3)
Reformed breaker height determination, wave runup
analysis using a reformed breaker height. Wave setback analysis. Pile height
determination. Criteria for types of breaking waves. Revetment analysis,
rip-rap revetment design, wave forces on pilings. 3 lectures. Prerequisite: CE
431.
CE
434 Groundwater Hydraulics and
Hydrology (3)
Differential
equations of groundwater flow, Darcy Law, solutions of the steady and unsteady
flow, differential equations for confined and unconfined flows. Pumping test
design. Groundwater models, leaky aquifers. Saltwater intrusion. 3 lectures.
Prerequisite: CE 336.
CE
440 Hydraulic Systems Engineering (3)
Water
and wastewater flows. Design of water distribution systems, transmission and
storage reservoirs, wastewater collection systems, and storm water systems.
Pumps and pump systems, flow measurements. Water sources for municipal supply.
3 lectures. Corequisite: CE 336.
CE
453 Structural Steel Design (3)
Design
and behavior of the elements of steel structures. Proportioning of members and
connections. Introduction to plastic design. 3 lectures. Prerequisite: CE 351.
CE
454 Structural Design (4)
Design
of reinforced concrete, steel and timber structures. Loading standards, code
design methods, connection design. Comprehensive design projects. 2 lectures, 2
laboratories. Prerequisite: CE 351, CE 355, CE 453.
CE
457 Bridge Engineering (4)
Fundamentals
of the structural analysis and design of highway bridges. Construction
materials in bridges. Loads on highway bridges. Load path and distribution in
bridge superstructure. Design of reinforced concrete, pre-stressed concrete,
steel plate girder, and composite bridges. 3 lectures, 1 laboratory.
Prerequisite: CE 351, CE 355, CE 453.
CE
458 Fiber Reinforced Polymer (FRP)
Design (4)
Properties
and mechanical characteristics of Fiber Reinforced Polymer (FRP) composite
materials; applications in civil engineering structures as primary or secondary
reinforcement; and design techniques based on newly developed ACI 440 design
guidelines and worldwide experience in FRP design. 3 lectures, 1 laboratory.
Prerequisite: CE 351 and CE 355.
CE 459
FRP Strengthening of Reinforced Concrete Structures (4)
Flexural
and shear strengthening reinforced and prestressed concrete members using fiber
reinforced polymer composite plates and laminates; seismic repair and
rehabilitation of columns, slabs, beams and structures. Focus on design
philosophy and design methodology, based on the current understanding of
FRP-strengthening techniques. 3 lectures, 1 laboratory. Prerequisite: CE 355.
CE
461, 462 Senior Project (2) (2)
Completion
of a 120-hour integrated civil research, analysis, and/or design project that
is representative of those encountered in professional practice. Prerequisite:
Senior standing and consent of the supervising faculty member.
CE
464 Professional Practice (3)
Examination
of the non-technical issues that are dealt with on a regular basis by the
design professional, including professional ethics, marketing and business
development, professional engagement, personnel and project management, risk
management, professional liability insurance, and dispute resolution. 3
seminars. Prerequisite: Senior standing.
CE
466 Senior Project Design Laboratory I
(2)
Selection
and initial work on a project by individuals or team which is typical of
problems graduates must solve in their fields of employment. Project involves,
but is not limited to, physical modeling, testing and design. The project may
include students/elements from other disciplines. Formulation of outline,
literature review, project schedule, initial analyses and interim report. 2
laboratories. Prerequisite: Senior standing and consent of instructor. Note:
although CE 466, 467 substitute for CE 461, 462, students may not use repeat credit
for the purpose of increasing GPA.
CE
467 Senior Project Design Laboratory II
(2)
Continuation
of CE 466. Continuation of research methodology: problem statement, method,
results, analysis, synthesis, project design, construction (when feasible), and
evaluation/conclusions. Project results are presented in formal written reports
for reference library and formal oral reports. 2 laboratories. Prerequisite: CE
466.
CE
470 Selected Advanced Topics (1–4)
Directed
group study of selected topics for advanced students. Open to undergraduate and
graduate students. Class Schedule
will list topic selected. Total credit limited to 8 units. 1 to 4 lectures.
Prerequisite: Consent of instructor.
CE
471 Selected Advanced Laboratory (1–4)
Directed
group laboratory study of selected topics for advanced students. Open to
undergraduate and graduate students. Class
Schedule will list topic selected. Total credit limited to 8 units. 1 to 4
laboratories. Prerequisite: Consent of instructor.
CE
481 Analysis and Design of Shallow
Foundations (4)
Immediate
settlement, consolidation settlement, rate of consolidation, and creep. Stress
distributions beneath loaded areas. Methods for accelerating and/or reducing
settlement.
Analysis
of bearing capacity for generalized conditions. Design of reinforced concrete
spread footings. Standard field and laboratory testing. 3 lectures, 1
laboratory. Prerequisite: CE 381, CE 382.
CE
482 Conventional Subsurface Exploration
(4)
Subsurface
exploration and sampling techniques. Laboratory analysis of material
variability. Preparation of subsurface exploration reports. 2 lectures, 2
laboratories. Prerequisite: CE 481.
CE
483 Environmental Geotechnology (4)
Application
of geotechnical engineering principles to environmental engineering problems.
Site characterization and assessment. Sampling and monitoring procedures.
Design of waste containment systems. Site remediation. Computer-aided analysis.
4 lectures. Prerequisite: CE 481.
CE
485 Cooperative Education Experience
(6) (CR/NC)
Part-time
work experience in business, industry, government, and other areas of student
career interest. Positions are paid and usually require relocation and
registration in course for two consecutive quarters. Formal report and
evaluation by work supervisor required. Credit/No Credit grading only. Total
credit limited to 16 units. Prerequisite: Sophomore standing and consent of
instructor.
CE
495 Cooperative Education Experience
(12) (CR/NC)
Full-time
work experience in business, industry, government, and other areas of student
career interest. Positions are paid and usually require relocation and
registration in course for two consecutive quarters. Formal report and
evaluation by work supervisor required. Credit/No Credit grading only. Total
credit limited to 16 units. Prerequisite: Sophomore standing and consent of
instructor.
CE
500 Individual Study (1–3)
Advanced
study planned and completed under the direction of a member of the department
faculty. Open only to graduate students who have demonstrated ability to do
independent work. Enrollment by petition. Prerequisite: Consent of department
chair, graduate advisor and supervising faculty member.
CE
501 Advanced Matrix Analysis of
Structures I (4)
Matrix
terminology and operations. Matrix procedures for analysis of two-dimensional
frameworks. Development of stiffness, flexibility and mixed methods.
Development of algorithms and programs for use in the analysis of structural
frameworks. Discussion of modeling issues and limitations. 3 lectures, 1 laboratory.
Prerequisite: CE 351 or consent of instructor.
CE
502 Advanced Matrix Analysis of
Structures II (4)
Matrix
procedures for analysis of three-dimensional frameworks. Development of
algorithms and programs for use in the analysis of structural frameworks.
Additional topics to include: member releases, nonprismatic members, elastic
supports, offset connections and oblique supports. 3 lectures, 1 laboratory.
Prerequisite: CE 501 or consent of instructor.
CE
504 Advanced Finite Element Analysis I
(4)
Finite
element theory and analysis for one-dimensional equations. Strong, weak and
variational formulations. Physical and isoparametric spaces. Error estimates
and numerical integration. Development of one-dimensional finite element
algorithms using industry based software. Discussion modeling issues and
limitations. 3 lectures, 1 laboratory. Prerequisite: CE 501.
CE
505 Advanced Finite Element Analysis II
(4)
Finite
element theory and analysis for multi-dimensional equations. Variational
formulations and their significance. Isoparametric formulation and numerical
integration. Development of two and three-dimensional finite element algorithms
using industry based software. Discussion modeling issues and limitations. 3
lectures, 1 laboratory. Prerequisite: CE 504.
CE
521 Airfield and Highway Pavement
Designs (4)
Theories,
principles, and procedures in the structural design of highway and airfield
pavements. Design of rigid and flexible pavements. Construction and maintenance
procedures for pavements and stabilized bases. 3 lectures, 1 laboratory.
Prerequisite: CE 221, CE 259, graduate standing or consent of instructor.
CE
522 Advanced Transportation Design (4)
Application
of computers to advanced highway and transportation systems and geometrics. Use
of computers for the solution of transportation facility design problems. 2
lectures, 2 laboratories. Prerequisite: CE 221, graduate standing, or consent
of instructor.
CE
523 Transportation Systems Planning (4)
Planning
of urban and regional multimodel transportation systems. Selection of routes
and types of systems based on economic, social, technological, and other
characteristics. 2 lectures, 2 laboratories. Prerequisite: CE 221, graduate
standing, or consent of instructor.
CE
525 Airport Planning and Design (4)
Historical
background of aviation and airport development; financing; estimating demand;
aircraft characteristics; airport capacity; airspace and air traffic control;
site selection; airport configuration; geometric design of landing area;
planning and development of terminal areas; lighting; pavement design and
drainage. 3 lectures, 1 laboratory. Prerequisite: CE 221, graduate standing, or
consent of instructor.
CE
528 Transportation Analysis (4)
Principles
and applications of engineering systems analysis to transportation using
examples from different modes. Identification of transportation benefits,
costs, user and non-user impacts, vehicle operating characteristics,
programming and scheduling. 3 lectures, 1 laboratory. Prerequisite: CE 221,
graduate standing, or consent of instructor.
CE
529 Modeling and Simulation in
Transportation (4)
Theory
and operation of transportation systems, the systems approach, simulation
techniques. Use of available software packages. Simulation model development,
calibration and use. 2 lectures, 2 laboratories. Prerequisite: CE 221, graduate
standing, or consent of instructor.
CE
533 Advanced Water Resources
Engineering (3)
Matrix
and simulation methods in hydrology, statistical studies in hydrology and their
applications to civil engineering problems. Generalized hydrologic
characteristics. Hydrologic simulation, computer applications, urban and small
watershed hydrology, macroscopic and microscopic approach. Storm water
management models. Hydrologic design. 3 lectures. Prerequisite: CE 336 or
graduate standing.
CE
535 Water Resources Systems Planning
and Analysis (3)
Water
resources planning, development, system analysis and optimization. Dynamic
programming, multi-objective water resource systems. 3 lectures. Prerequisite:
CE 336.
CE
537 Groundwater Contamination (3)
Sources
and types of groundwater contamination, contamination transport mechanisms.
Sorption and other chemical reactions. Numerical modeling of contaminant
transport. Nonaqueous phase liquids. Groundwater remediation and design. 3
lectures. Prerequisite: CE 114; co-requisite: CE 434 or equivalent.
CE
555 Advanced Civil Engineering
Materials Laboratory (2)
Fundamental
properties of new and advanced materials. Experimental techniques. Fracture
characteristics and composite response of cement matrix composites. New
materials and products to advanced applications such as automation. 2
laboratories. Prerequisite: CE 259 or graduate standing.
CE
557 Seismic Analysis and Design for
Civil Engineers (4)
Extension
of the basic principles of structural dynamics to analysis of civil structures
(buildings, bridges, tanks, etc.) to earthquake loading. Code based (Uniform
Building Code and AASHTO) earthquake resistant design of civil structures. 3
lectures, 1 laboratory. Prerequisite: CE 407.
CE
559 Advanced Structural Design (4)
Advanced
analysis, design and behavior of structural concrete. Reinforced, prestressed,
and precast concrete elements. Linear and nonlinear structural systems. Origin
of code requirements. Detailed design of prestressed concrete components of
civil engineering systems for buildings and highway construction. Beams, slabs,
columns, continuous systems, walls, connections, and composite systems. 4
lectures. Prerequisite: CE 355 or graduate standing.
CE
570 Selected Advanced Topics (1–4)
Directed
group study of selected topics for advanced students. Open to graduate
students. Class Schedule will list
topic selected. Total credit limited to 8 units. 1–4 seminars. Prerequisite:
Graduate standing or consent of instructor.
CE
571 Selected Advanced Laboratory (1–4)
Directed
group laboratory study of selected topics for advanced students. Open to
undergraduate and graduate students. Class
Schedule will list topic selected. Total credit limited to 8 units. 1–4
laboratories. Prerequisite: Graduate standing or consent of instructor.
CE
573 Public Works Administration (3)
Management
and engineering of infrastructure and related systems in public jurisdictions.
Utility systems, streets and highways, illumination, distribution systems, etc.
Personnel management, financing, public relations, and contract management. 3
seminars. Prerequisite: Graduate standing or consent of instructor.
CE
574 Computer Applications in Civil
Engineering (3)
Overview
of computer application, hardware and software alternatives, use of selected
application programs, CAD, microcomputers, management and application of
resources. 1 lecture, 2 laboratories. Prerequisite: Graduate standing or
consent of instructor.
CE
581 Advanced Geotechnical Engineering
(4)
Advanced
topics in saturated flow, unsaturated flow, and consolidation.
Stress-strain-deformation response of soils under both drained and undrained
loading. Soil stabilization, and ground modification. Conventional and advanced
field and laboratory strength testing. 2 lectures, 2 laboratories.
Prerequisite: CE 481 or graduate standing.
CE
582 Advanced Geotechnical Testing (4)
Standard
penetration, cone penetration, and flat-plate dilatometer testing. Equipment
operation and maintenance. Interpretation of SPT/CPT/DMT sounding data.
Stratigraphic analysis. CPT/DMT-based analysis and design of shallow and deep
foundations. 2 lectures, 2 laboratories. Prerequisite: CE 481 or graduate
standing.
CE
583 Geotechnical Earthquake Engineering
(4)
Introduction
to engineering seismology, dynamic behavior of soils, seismic site response
analysis, seismic earth pressures, seismic stability of slopes, soil
liquefaction and lateral spreading, and mitigation techniques. Computer-aided
analysis. 4 lectures. Prerequisite: CE 481 or graduate standing.
CE
584 Lateral Support Systems (4)
Classical
and modern earth pressure theories. Lateral earth pressure calculations for
general subsurface conditions. Analysis and design of reinforced concrete
cantilever walls, sheetpile walls, soldier-pile walls, tie-back walls, and
mechanically-stabilized earth. Computer-aided analysis and design. 4 lectures.
Prerequisite: CE 481 or graduate standing.
CE
585 Slope Stability Analysis (4)
Analysis
of stability by planar, circular arc, piecewise-linear, and composite-surface
techniques. Analysis of earth-fill dams and reservoirs for static, steady flow,
sudden drawdown, and seismic loading conditions. Field instrumentation. Methods
for slope remediation and stabilization. Computer-aided analysis. 4 lectures.
Prerequisite: CE 481 or graduate standing.
CE
586 Analysis and Design of Deep
Foundations (4)
Bearing
capacity and settlement analysis of drilled shafts and driven piles. Analysis
and design of single piles and pile groups for vertical, lateral, and combined
loading. Construction procedures, field inspection, and load-testing.
Computer-aided analysis and design. 4 lectures. Prerequisite: CE 481 or
graduate standing.
CE
591 Graduate Seminar (1)
Examination
of current research activities and analysis/design philosophies in civil and
environmental engineering practice. 1 seminar. Prerequisite: Graduate standing.
CE
599 Design Project (Thesis) (2) (2) (5)
Each
individual or group will be assigned a project for solution under faculty
supervision as a requirement for the master's degree, culminating in a written
report/thesis. Prerequisite: Graduate standing.