Civil Engineering (CE)
130.
Construction Detailing.
(3)
Basics of construction detailing and comprehension of working drawing sets.
160L.
Civil Engineering Design.
(3)
Introduction to engineering graphics (AutoCAD®), computer-aided design; introduction to civil engineering and construction.
171.
Construction Materials and Techniques.
(3)
Plan reading, elementary construction techniques, materials and construction documents; primary emphasis is on the Uniform Building Code plan checking.
Prerequisite: 130.
202.
Engineering Statics.
(3)
Statics of particles and rigid bodies, in two and three dimensions using vector algebra as an analytical tool; centroids; distributed loads; trusses, frames, internal forces, friction.
Prerequisite: MATH 1522 and PHYS 1310.
279.
Mechanical Electrical Systems Construction.
(3)
Materials and equipment used in the electrical and mechanical systems of commercial building, and associated codes and costs, are surveyed and explored.
283.
Surveying and Geomatics.
(3)
Principles of physical measurements and error theory applied to transportation systems, including layout and design. Design elements and standards, sight distance considerations and earthwork calculations applied to horizontal and vertical alignment design.
Prerequisite: MATH 1430 or MATH 1512.
291.
Lower Division Special Topics in Civil Engineering.
(1-3 to a maximum of 6 Δ)
Lower division studies in various areas of civil engineering.
Restriction: freshman or sophomore standing.
302.
Mechanics of Materials.
(3)
Stresses and strains in members subjected to tension, compression, torsion, shear and flexure. Combined and principal stresses; Mohr’s circle construction; buckling. Introduction to statically indeterminate members.
Prerequisite: 202.
Pre- or corequisite: MATH **316.
Restriction: admitted to School of Engineering.
305.
Infrastructure Materials Science.
(4)
Lecture and laboratory studies of the physical, structural, mechanical and chemical properties of infrastructure materials. Micro and nano-scale structure of matter. Experimental determination of material properties.
Prerequisite: ENGL 2210.
Pre- or corequisite: 302 or 371.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
308.
Structural Analysis.
(3)
Analysis of determinate and indeterminate structural systems. Determination of forces and displacements. Classical analysis methods, influence lines and introduction to matrix stiffness formulation.
Prerequisite: 302 and 305.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
331.
Fluid Mechanics.
(4)
Fluid properties; fluids at rest; fluid flow principles, including continuity, energy and momentum; incompressible fluid flow; laboratory study of basic principles of fluid mechanics. Three lectures.
Prerequisite: 202 and ENG 301.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
**335.
Environmental and Water Resources Engineering.
(3)
Basic principles of environmental and water resources engineering: material and energy balances, hydrology, water treatment and distribution, wastewater collection and treatment.
Prerequisite: 331 and CHEM 1215 and CHEM 1215L.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
350.
Engineering Economy.
(3)
(Also offered as ME 350)
A study of methods and techniques used in determining comparative financial desirability of engineering alternatives. Includes time value of money (interest), depreciation methods and modern techniques for analysis of management decisions.
Prerequisite: MATH 1430 or MATH 1512.
Restriction: admitted to School of Engineering and junior or senior standing.
360.
Soil Mechanics.
(4)
Fundamental properties of soils, classification systems, site investigation, permeability, consolidation, compaction and shear. Laboratory tests conducted to determine the properties of soils-related geotechnical engineering problems. Three lectures.
Prerequisite: 302.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
370.
Construction Methods and Equipment.
(3)
Comprehensive study of the ownership and operating costs, production rates and operating characteristics of the major construction equipment types.
Prerequisite: 350.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
371.
Structures for Construction.
(3)
Principles of mechanics, equilibrium conditions, properties of structural materials, structural properties of areas, load-shear-bending moment diagrams, flexural stresses, shearing stresses, deflection, and analysis of simple trusses, beams, columns, and funicular structures.
Prerequisite: 171 and MATH 1430 and PHYS 1230.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
**372.
Principles of Construction.
(3)
Management principles as applied to the conduct and control of a construction contracting business; estimating methods, bidding, construction contracts, bonds, insurance, project planning and scheduling, cost accounting, labor law, labor relations and safety.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
376.
Cost Estimating.
(3)
Using modern, professional estimating techniques and resources, students complete cost estimates on buildings based on the Construction Specifications Institute formatted budgets and quantity take-offs for materials, labor, and equipment.
Prerequisite: 171.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
377.
Construction Scheduling.
(3)
Planning and scheduling of construction activities including network diagramming and calculations with the Critical Path Method (CPM), resource allocation, schedule updating, and computer applications.
Prerequisite: 171.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
382.
Transportation Engineering.
(3)
Multimodal examination of the planning, design and operation of transportation facilities; social aspects and economic evaluation of transportation system improvements; transportation design project.
Prerequisite: 283.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
411 / 511.
Reinforced Concrete Design.
(3)
Structural mechanics of concrete beams, slabs, columns, walls and footings; checking and proportioning of members and connections in accordance with specifications for limit state concrete design.
Prerequisite: 308.
Restriction: admitted to School of Engineering and senior standing.
413 / 513.
Timber and Masonry Design.
(3)
Design of reinforced masonry and timber structures conforming to the latest building codes and specifications; masonry assemblage methods, shear strength, masonry beams, columns and walls; wood connections, load and resistance factors for timber design.
Prerequisite: 308.
Restriction: admitted to School of Engineering and senior standing.
415.
Civil Engineering Design Competition.
(1 to a maximum of 3 Δ)
Students will plan, design, construct, and test projects for competitions such as the American Society of Civil Engineering/American Institute of Steel Construction steel bridge competition and the American Concrete Institute’s concrete canoe competition.
Offered on a CR/NC basis only.
Restriction: admitted to School of Engineering and junior or senior standing.
424 / 524.
Structural Design in Metals.
(3)
Design of steel systems in accordance with LRFD design specifications.
Prerequisite: 308.
Restriction: admitted to School of Engineering and senior standing.
431 / 531.
Physical-Chemical Water and Wastewater Treatment.
(3)
Principles and design of water treatment systems relying on physical-chemical processes: coagulation, flocculation, sedimentation, granular and membrane filtration, reverse osmosis, adsorption, disinfection, and advanced oxidation. Addresses principles of mass balances, chemical reactors, and mass transfer.
Prerequisite: **335.
Restriction: admitted to School of Engineering and senior standing.
433 / 533.
Environmental Microbiology.
(3)
Examination of the fundamental principles of microbiology and biochemistry as they apply to environmental and biochemical engineering. Topics will include microbial cell structure, metabolism, bioenergetics, ecology, molecular methods of analysis, and pollutant degradation.
Restriction: admitted to School of Engineering and senior standing.
436 / 536.
Biological Wastewater Treatment.
(3)
Principles and design of wastewater treatment systems which are dependent on biological organisms. Processes covered include suspended culture and fixed culture systems, nutrient removal, hybrid systems, land application and on-site treatment systems. Emphasis will be placed on fundamental interaction between the organisms, wastes and receiving body of water.
Prerequisite: **335.
Restriction: admitted to School of Engineering and senior standing.
438 / 538.
Sustainable Engineering.
(3)
Evaluation of strategies to improve the environmental performance of industrial processes. Topics include impacts associated with resource consumption and pollution generation, life cycle assessment, environmental management systems, sustainability, techniques for pollution prevention and energy minimization.
Restriction: admitted to School of Engineering and senior standing.
440 / 540.
Design of Hydraulic Systems.
(3)
Applications of the principles of fluid mechanics to the design and analysis of pipe systems. Topics include pipe network analysis, design and selection of hydraulic machinery and analysis of transient and compressible flow.
Prerequisite: 331.
Restriction: admitted to School of Engineering.
441 / 541.
Hydrogeology.
(3)
(Also offered as EPS 462 / 562)
Hydrologic and geologic factors controlling groundwater flow, including flow to wells. The hydrologic cycle; interactions between surface and subsurface hydrologic systems; regional flow systems. Groundwater geochemistry and contaminant transport.
Prerequisite: CHEM 1215 and CHEM 1215L and MATH 1522 and PHYS 1310.
Restriction: admitted to School of Engineering and senior standing.
*442.
Hydraulic Engineering and Hydrology.
(3)
Design of water distribution systems and open channels; selection of pumps and turbines; hydraulics of wells; basic engineering hydrology including precipitation, infiltration, runoff, flood routing, statistical measures and water resources planning.
Prerequisite: 331 and MATH 1512.
Restriction: admitted to School of Engineering.
452 / 552.
Building Information Modelling.
(3)
Principles, theory, and techniques of computer building, information modeling applications in the construction industry using AutoDesk Revit Architecture® and Revit Structure® modeling software. Students develop and apply current database technologies based on their respective degrees.
Prerequisite: 160L and 305 and (308 or 371) and (**372 or (376 and 377)).
Restriction: admitted to School of Engineering.
*455.
Engineering Project Management.
(3)
Estimating, proposing, planning, scheduling, quality and cost control and reporting of an engineering project. Case studies of typical engineering projects. Small projects carried out by student teams.
Restriction: admitted to School of Engineering and junior or senior standing.
462 / 562.
Foundation Engineering I.
(3)
Application of principles of soil mechanics to analysis and design of footings, piles, caissons, cofferdams and other substructures.
Prerequisite: 360.
Restriction: admitted to School of Engineering.
466.
Pavement Design.
(3)
Provides an understanding of the analysis and design of flexible and rigid highway pavements. Includes mechanistic-empirical analysis and evaluation of design practices, stresses and strains in pavements, traffic consideration, pavement performance models, and reliability.
Prerequisite: 360.
Restriction: admitted to School of Engineering.
473 / 573.
Construction Law.
(3)
Basic law concepts pertaining to the construction industry in New Mexico, including the Construction Industries Licensing Act, construction contracts, change orders, delay damages, contractor liability, dispute resolution, lien laws and the Miller Acts.
Prerequisite: (**372 or (376 and 377)) and ENGL 2210.
Restriction: admitted to School of Engineering and junior or senior standing.
474 / 574.
Principles of Written Construction Documents.
(3)
This course reviews written documents used throughout construction projects, describing how the documents relate to each other and to drawings. It provides detail on the theory, techniques and format for every aspect of construction documentation.
Prerequisite: (**372 or (376 and 377)) and ENGL 2210.
Restriction: admitted to School of Engineering.
475 / 575.
Construction Safety.
(3)
Basic safety and loss control concepts, practices, and skills to improve construction job site safety; OSHA regulations, accidents, documentation, safety policies and procedures, safe work environments, crisis management, and other safety related topics.
Prerequisite: (**372 or (376 and 377)) and ENGL 2210.
Restriction: admitted to School of Engineering and junior or senior standing.
477 / 577.
Project Controls.
(3)
Time and cost budgeting is used for project control through management information and systems engineering. Topics to include cost integrated scheduling, earned value, probabilistic estimating and scheduling, crashing, trade-off analysis and forecasting.
Prerequisite: **372 or (376 and 377).
Restriction: admitted to School of Engineering and junior or senior standing.
478 / 578.
Temporary Structures in Construction.
(3)
Evaluation of the applicability, advantages, and disadvantages of temporary-construction structures and activities, including scaffolding, formwork systems, earth-retaining structures, and traffic control.
Prerequisite: 308 or 371.
Restriction: admitted to B.S.C.E. Civil Engineering, B.S.Cn.E. Construction Engineering, or B.S.C.M. Construction Management.
481 / 581.
Urban Transportation Planning.
(3)
Planning aspects of highway transportation including transportation goals, transportation forecasting techniques and models, selection between alternate solutions, financing improvements.
Restriction: admitted to School of Engineering.
482 / 582.
Highway and Traffic Engineering.
(3)
Principles of the geometric design and operation of streets and highways, including planning aspects, traffic design and control and highway safety. Application of these principles to actual situations.
Prerequisite: 382.
Restriction: admitted to School of Engineering and junior or senior standing.
*491-*492.
Special Topics in Civil Engineering.
(1-3, 1-3 to a maximum of 6 Δ)
Advanced studies in various areas of civil engineering.
Restriction: admitted to School of Engineering.
493.
Special Topics in Civil Engineering - Honors.
(1-3 to a maximum of 6 Δ)
A course exploring a topic not covered by the standard curriculum but of interest to faculty and students in a particular semester.
Restriction: admitted to School of Engineering.
494.
Honors Seminar.
(3 to a maximum of 6 Δ)
Course emphasizes investigation, evaluation, and discussion of areas of specialized knowledge or inquiry
relevant to the profession or field of study.
Restriction: admitted to School of Engineering.
495.
Construction Internship.
(1)
Practical construction industry experience (both home office and field). Students spend designated period of time with owner or contractor. Evaluation by both instructor and industry sponsor, emphasizing student’s understanding of observed project management operations.
Restriction: admitted to School of Engineering and junior or senior standing.
497L.
Design Construction Integration.
(3)
Comprehensive, creative construction management of a typical construction project, including estimating, scheduling, document preparation, constructibility site analysis and quality, safety, equipment and material plans. Both written and oral presentations are required.
Pre- or corequisite: 477.
Restriction: admitted to School of Engineering and senior standing.
499.
Design of Civil Engineering Systems.
(3)
Comprehensive, creative design of a typical civil engineering project, including cost analysis. Detailed study based on written proposals by student teams, both written and oral reports required. To be taken in the student’s last semester.
Prerequisite: 308 and 331 and 350 and 360.
Restriction: admitted to School of Engineering and senior standing.
501.
Advanced Mechanics of Materials.
(3)
(Also offered as ME 501/401)
State of stress and strain at a point, stress-strain relationships; topics in beam theory such as unsymmetrical bending, curved beams, and elastic foundations; torsion of noncircular cross-sections, energy principles.
502.
Finite Element Methods in Solid Mechanics.
(3)
Topics in finite element analysis with applications to problems in a two and three dimensional, solid continuum.
504.
Fracture Mechanics.
(3)
This course explains principles of crack initiation propagation and the fracture process in construction materials including glass, metals, concrete and polymers.
506.
Prestressed Concrete.
(3)
Theoretical and practical aspects of behavior and design of prestressed concrete structures.
511 / 411.
Reinforced Concrete Design.
(3)
Structural mechanics of concrete beams, slabs, columns, walls and footings; checking and proportioning of members and connections in accordance with specifications for limit state concrete design.
513 / 413.
Timber and Masonry Design.
(3)
Design of reinforced masonry and timber structures conforming to the latest building codes and specifications; masonry assemblage methods, shear strength, masonry beams, columns and walls; wood connections, load and resistance factors for timber design.
515.
Design of Reinforced Concrete Structures with Fiber Reinforced Polymers.
(3)
Design of new reinforced concrete structures using fiber reinforced polymer (FRP) reinforcement and strengthening of existing reinforced and prestressed concrete structures using FRP materials.
518.
Theory of Structural Stability.
(3)
General concept of stability of elastic and inelastic systems: columns, beam-columns, frames, plates and torsional stability. Equilibrium, energy and dynamic methods, nonlinear systems, nonconservative problems, discretized mathematical models.
521.
Structural Dynamics and Earthquake Engineering.
(3)
Theory of structural vibrations; response spectra for design; viscous and tuned mass damping; multi-degree-of-freedom analysis using normal mode method; designs under earthquake excitations; seismic design provisions in building codes; final design project.
524 / 424.
Structural Design in Metals.
(3)
Design of steel systems in accordance with LRFD design specifications.
531 / 431.
Physical-Chemical Water and Wastewater Treatment.
(3)
Principles and design of water treatment systems relying on physical-chemical processes: coagulation, flocculation, sedimentation, granular and membrane filtration, reverse osmosis, adsorption, disinfection, and advanced oxidation. Addresses principles of mass balances, chemical reactors, and mass transfer.
533 / 433.
Environmental Microbiology.
(3)
Examination of the fundamental principles of microbiology and biochemistry as they apply to environmental and biochemical engineering. Topics will include microbial cell structure, metabolism, bioenergetics, ecology, molecular methods of analysis, and pollutant degradation.
534.
Environmental Engineering Chemistry.
(3)
A comprehensive survey including acid-base and precipitation equilibria, complexation of metals, transformation occurring in the environment adsorption, ion exchange. The approach will be quantitative and aimed at developing the student's ability to predict consequences of environmental manipulation, treatment processes and phenomena observed in the field.
536 / 436.
Biological Wastewater Treatment.
(3)
Principles and design of wastewater treatment systems which are dependent on biological organisms. Processes covered include suspended culture and fixed culture systems, nutrient removal, hybrid systems, land application and on-site treatment systems. Emphasis will be placed on fundamental interaction between the organisms, wastes and receiving body of water.
538 / 438.
Sustainable Engineering.
(3)
Evaluation of strategies to improve the environmental performance of industrial processes. Topics include impacts associated with resource consumption and pollution generation, life cycle assessment, environmental management systems, sustainability, techniques for pollution prevention and energy minimization.
540 / 440.
Design of Hydraulic Systems.
(3)
Applications of the principles of fluid mechanics to the design and analysis of pipe systems. Topics include pipe network analysis, design and selection of hydraulic machinery and analysis of transient and compressible flow.
541 / 441.
Hydrogeology.
(3)
(Also offered as EPS 562 / 462)
Hydrologic and geologic factors controlling groundwater flow, including flow to wells. The hydrologic cycle; interactions between surface and subsurface hydrologic systems; regional flow systems. Groundwater geochemistry and contaminant transport.
542.
Intermediate Hydrology.
(3)
Hydrometeorology, interception, depression storage, infiltration, hydrograph analysis, flood routing, urban hydrology, groundwater analysis and utilization.
545.
Open Channel Hydraulics.
(3)
Open channel hydraulics; specific energy and specific force; steady and unsteady flow; gradually varied flow; rapidly varied flow; computation of water surface profiles.
547.
GIS in Water Resources Engineering.
(3)
Principles and operation of geographic information systems using Arc GIS, work with surface and subsurface digital representations of the environment considering hydrologic and transportation processes. Course project is required.
548.
Fuzzy Logic and Applications.
(3)
Theory of fuzzy sets; foundations of fuzzy logic. Fuzzy logic is shown to contain evidence, possibility and probability logics; course emphasizes engineering applications; control, pattern recognition, damage assessment, decisions; hardware/software demonstrations.
549.
Vadose Zone Hydrology.
(3)
Principles and applications of water, energy and solute transport in the near-surface environment. Topics covered include moisture characteristic curves, unsaturated hydraulic conductivity, Richards equation and numerical solutions. Processes studied include infiltration, redistribution, evapotranspiration and recharge.
551.
Problems.
(1-3 to a maximum of 6 Δ)
Advanced reading, analysis, design or research.
552 / 452.
Building Information Modelling.
(3)
Principles, theory, and techniques of computer building, information modeling applications in the construction industry using AutoDesk Revit Architecture® and Revit Structure® modeling software. Students develop and apply current database technologies based on their respective degrees.
Prerequisite: 160L and 305 and (308 or 371) and (**372 or (376 and 377)).
556.
Soils in Construction.
(3)
Introduction to the nature of soils and how soil materials influence construction activities. Includes soil characteristics, properties, classification, contract documents, soils reports, embankments, excavation, foundation construction, haul roads, erosion mitigation, and dewatering.
558.
Construction Materials.
(3)
An in-depth introduction on all major construction materials including steel, wood, concrete, masonry, polymers and asphalt. Introduces principles of sustainable construction materials as well as new construction materials and technologies.
562 / 462.
Foundation Engineering I.
(3)
Application of principles of soil mechanics to analysis and design of footings, piles, caissons, cofferdams and other substructures.
566.
Pavement Design.
(3)
Pavement design principles, including a review of methods for soil testing and characterization, base selection, subgrade stabilization and surfacing material design. Procedures for new pavement design and existing pavement testing and evaluation will be covered.
570.
Construction Operations.
(3)
Comprehensive study of the design and simulation of construction operations.
571.
Sustainable Design and Construction.
(3)
Principles of sustainable design and construction, including life-cycle cost analysis, evaluation of economic and environmental impacts, state-of-the-art technology, and LEED certification.
573 / 473.
Construction Law.
(3)
Basic law concepts pertaining to the construction industry in New Mexico, including the Construction Industries Licensing Act, construction contracts, change orders, delay damages, contractor liability, dispute resolution, lien laws and the Miller Acts.
574 / 474.
Principles of Written Construction Documents.
(3)
This course reviews written documents used throughout construction projects, describing how the documents relate to each other and to drawings. It provides detail on the theory, techniques and format for every aspect of construction documentation.
575 / 475.
Construction Safety.
(3)
Basic safety and loss control concepts, practices, and skills to improve construction job site safety; OSHA regulations, accidents, documentation, safety policies and procedures, safe work environments, crisis management, and other safety related topics.
576.
Project Delivery Systems.
(3)
Defining characteristics of various project delivery systems, processes to solicit and procure those services. Responsibilities, risks and rewards for owners, designers, and contractors under various PDS.
577 / 477.
Project Controls.
(3)
Time and cost budgeting is used for project control through management information and systems engineering. Topics to include cost integrated scheduling, earned value, probabilistic estimating and scheduling, crashing, trade-off analysis and forecasting.
578 / 478.
Temporary Structures in Construction .
(3)
Evaluation of the applicability, advantages, and disadvantages of temporary-construction structures and activities, including scaffolding, formwork systems, earth-retaining structures, and traffic control.
581 / 481.
Urban Transportation Planning.
(3)
Planning aspects of highway transportation including transportation goals, transportation forecasting techniques and models, selection between alternate solutions, financing improvements.
582 / 482.
Highway and Traffic Engineering.
(3)
Principles of the geometric design and operation of streets and highways, including planning aspects, traffic design and control and highway safety. Application of these principles to actual situations.
588.
Master's Project.
(1-6)
Development of project concept, investigation of needs, initial data collection and assembly of written and field materials necessary to conduct a professional project. Exploration of alternative means to conduct the project.
Prerequisite: completion of 12 credit hours of 500-level coursework.
Restriction: admitted to M.S. Civil Engineering or M.Eng. Civil Engineering or M.C.M. Construction Management.
598.
Selected Topics.
(1-3 to a maximum of 6 Δ)
A course offered by Civil Engineering faculty which presents a detailed examination of developing sciences and technologies in a classroom setting.
{Offered upon demand}
599.
Master's Thesis.
(1-6, no limit Δ)
Faculty-supervised investigative study that results in the development and writing of a master’s thesis.
Offered on a CR/NC basis only.
650.
Research.
(1-6 to a maximum of 12 Δ)
A faculty-supervised course culminating in a comprehensive paper or research proposal that integrates knowledge attained through coursework, research, and experience.
Restriction: CE majors only.
691.
Graduate Seminar.
(1 to a maximum of 4 Δ)
Course emphasizes investigation, evaluation, and discussion of areas of specialized knowledge or inquiry relevant to the profession or field of study.
Offered on a CR/NC basis only.
699.
Dissertation.
(3-12, no limit Δ)
Faculty-supervised investigative study that results in the development and writing of a doctoral dissertation.
Offered on a CR/NC basis only.