Examines the Clean Water Act and its impact on the environment. The course will explore the history of the Act, and various programs established by the Act, including the Section 404 wetlands program and the National Pollutant Discharge Elimination System (NPDES) pollution control program. Subject matter experts from State and Federal agencies, industry, environmental nongovernmental organizations and utilities will provide their perspectives on the Clean Water Act and its effectiveness. Registration Restrictions: Bachelor of Science degree in a science or engineering discipline.
Examines the Clean Water Act and its impact on the environment. The course will explore the history of the Act, and various programs established by the Act, including the Section 404 wetlands program and the National Pollutant Discharge Elimination System (NPDES) pollution control program. Subject matter experts from State and Federal agencies, industry, environmental nongovernmental organizations and utilities will provide their perspectives on the Clean Water Act and its effectiveness. Registration Restrictions: Bachelor of Science degree in a science or engineering discipline.
Explores the complex relationship between environmental regulatory and permitting requirements and their application to engineering and science projects. Registration Restrictions: Admission to Applied Environmental Science and Technology graduate program.
Explores the complex relationship between environmental regulatory and permitting requirements and their application to engineering and science projects. Registration Restrictions: Admission to Applied Environmental Science and Technology graduate program.
Fundamentals and applications of technologies for the remediation of contaminated sites. Site characterization techniques and fundamental microbial, chemical, and physical concepts are presented to provide a basis for the design and operation of specific on-site and in-situ technologies. Registration Restrictions: Registrants must be enrolled in the AEST, CE, or BIOL graduate programs, or gain instructor approval.
Fundamentals and applications of technologies for the remediation of contaminated sites. Site characterization techniques and fundamental microbial, chemical, and physical concepts are presented to provide a basis for the design and operation of specific on-site and in-situ technologies. Registration Restrictions: Registrants must be enrolled in the AEST, CE, or BIOL graduate programs, or gain instructor approval.
Arranged between the advisor and the student. Generally the student has been admitted to candidacy for the master's degree and a thesis committee is formed. The student must take an oral exam defending the thesis. Registration Restrictions: Registrants must be enrolled in the AEST graduate program.
Arranged between the advisor and the student. Generally the student has been admitted to candidacy for the master's degree and a thesis committee is formed. The student must take an oral exam defending the thesis. Registration Restrictions: Registrants must be enrolled in the AEST graduate program.
Arranged between the advisor and the student. Generally the student has been admitted to candidacy for the master's degree and a thesis committee is formed. The student must take an oral exam defending the thesis. Registration Restrictions: Registrants must be enrolled in the AEST graduate program.
Arranged between the advisor and the student. Generally the student has been admitted to candidacy for the master's degree and a thesis committee is formed. The student must take an oral exam defending the thesis. Registration Restrictions: Registrants must be enrolled in the AEST graduate program.
Introduces students to the roles, responsibilities and capabilities of civil engineers within various subdisciplines such as structural, geotechnical, transportation, environmental and water resources engineering. Introduction to the body of knowledge developed by American Society of Civil Engineers (ASCE).
Introduces students to the roles, responsibilities and capabilities of civil engineers within various subdisciplines such as structural, geotechnical, transportation, environmental and water resources engineering. Introduction to the body of knowledge developed by American Society of Civil Engineers (ASCE).
Introduces students to a broad spectrum of engineering challenges unique to cold regions. Physical principles and practical data collection methods, analyses, designs, and construction methods are discussed. Students gain a working knowledge of cold regions engineering problems and modern solutions as a basis for more detailed study. Registration Restrictions: Junior or senior standing in an accredited undergraduate program in engineering. May be stacked with: CE A603
Introduces students to a broad spectrum of engineering challenges unique to cold regions. Physical principles and practical data collection methods, analyses, designs, and construction methods are discussed. Students gain a working knowledge of cold regions engineering problems and modern solutions as a basis for more detailed study. Registration Restrictions: Junior or senior standing in an accredited undergraduate program in engineering. May be stacked with: CE A603
Introduction to planning and engineering of transportation systems and their functions, components and operation. Those systems include highways, airports, railroads and water transportation with emphasis for highways regarding planning and traffic operations.
Introduction to planning and engineering of transportation systems and their functions, components and operation. Those systems include highways, airports, railroads and water transportation with emphasis for highways regarding planning and traffic operations.
Geometrical and structural design, construction, and maintenance of highway facilities and associated economic, social, and environmental consequences. May be stacked with: CE A625
Geometrical and structural design, construction, and maintenance of highway facilities and associated economic, social, and environmental consequences. May be stacked with: CE A625
Introduces concepts of traffic flow simulation, modeling of driver behavior and application of traffic simulation in Intelligent Transportation Systems (ITS). Registration Restrictions: Instructor permission May be stacked with: CE A626
Introduces concepts of traffic flow simulation, modeling of driver behavior and application of traffic simulation in Intelligent Transportation Systems (ITS). Registration Restrictions: Instructor permission May be stacked with: CE A626
Review of statically determinate beams and trusses. Discusses shearing, bending moment and influence of line diagrams for statically determinate and indeterminate structures. Includes the study of deflections, elastic lines, an introduction to matrix and computer analyses.
Review of statically determinate beams and trusses. Discusses shearing, bending moment and influence of line diagrams for statically determinate and indeterminate structures. Includes the study of deflections, elastic lines, an introduction to matrix and computer analyses.
Essentials of structural design in reinforced concrete including building code requirements and standard practice for the design of basic structural elements.
Essentials of structural design in reinforced concrete including building code requirements and standard practice for the design of basic structural elements.
Concepts, principles, and/or procedures related to soil formation and classification, soil compaction, flow of water in soils, stresses in a soil mass, soil settlement, shear strength of soil, subsoil exploration, and frost action.
Concepts, principles, and/or procedures related to soil formation and classification, soil compaction, flow of water in soils, stresses in a soil mass, soil settlement, shear strength of soil, subsoil exploration, and frost action.
Integrative capstone course for civil engineering students to collaborate in multidisciplinary teams to design a complex civil engineering system that meets client needs while protecting public health and safety. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Senior standing
Integrative capstone course for civil engineering students to collaborate in multidisciplinary teams to design a complex civil engineering system that meets client needs while protecting public health and safety. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Senior standing
Introduction to the fundamental theory, analysis and regulations of environmental engineering and applied environmental science. Topics include environmental chemistry, drinking water and wastewater treatment, air pollution and solid waste management. May be stacked with: CE A641
Introduction to the fundamental theory, analysis and regulations of environmental engineering and applied environmental science. Topics include environmental chemistry, drinking water and wastewater treatment, air pollution and solid waste management. May be stacked with: CE A641
Design of systems commonly used in environmental engineering practice with an emphasis on water and wastewater treatment. Design of unit processes and operations will be performed for both potable water and wastewater treatment. Selection of system components, design and performance calculations and complete engineering reports are required.
Design of systems commonly used in environmental engineering practice with an emphasis on water and wastewater treatment. Design of unit processes and operations will be performed for both potable water and wastewater treatment. Selection of system components, design and performance calculations and complete engineering reports are required.
Theory and design of aerobic and anaerobic process for the treatment of wastewater including activated sludge, various surface film reactors, sludge digestion and disposal, and nutrient removal. May be stacked with: CE A646
Theory and design of aerobic and anaerobic process for the treatment of wastewater including activated sludge, various surface film reactors, sludge digestion and disposal, and nutrient removal. May be stacked with: CE A646
The theory and design of advanced unit processes with emphasis on emerging disinfectants, ozone and ultraviolet light disinfection, advanced oxidation, sorbents, and membranes; application of these innovative technologies in the drinking water and wastewater arena. May be stacked with: CE A647
The theory and design of advanced unit processes with emphasis on emerging disinfectants, ozone and ultraviolet light disinfection, advanced oxidation, sorbents, and membranes; application of these innovative technologies in the drinking water and wastewater arena. May be stacked with: CE A647
Application of linear and nonlinear wave theory to the study of coastal processes and the design of coastal structures; wave transformation processes including wind generation, refraction and diffraction. May be stacked with: CE A676
Application of linear and nonlinear wave theory to the study of coastal processes and the design of coastal structures; wave transformation processes including wind generation, refraction and diffraction. May be stacked with: CE A676
Introduces students to a broad spectrum of engineering challenges that are unique to cold regions. Physical principles and practical data collection methods, analyses, designs, and construction methods are discussed. Students gain a working knowledge of cold-region engineering problems and modern solutions as a basis for detailed study. Registration Restrictions: Graduate standing with a baccalaureate degree in engineering. No previous credits for CE A403. May be stacked with: CE A403
Introduces students to a broad spectrum of engineering challenges that are unique to cold regions. Physical principles and practical data collection methods, analyses, designs, and construction methods are discussed. Students gain a working knowledge of cold-region engineering problems and modern solutions as a basis for detailed study. Registration Restrictions: Graduate standing with a baccalaureate degree in engineering. No previous credits for CE A403. May be stacked with: CE A403
Geometrical and structural design, construction, and maintenance of highway facilities and associated economic, social, and environmental consequences. May be stacked with: CE A425
Geometrical and structural design, construction, and maintenance of highway facilities and associated economic, social, and environmental consequences. May be stacked with: CE A425
Introduces concepts of traffic flow simulation, modeling of driver behavior, and application of traffic simulation in Intelligent Transportation Systems. Registration Restrictions: Instructor's permission and graduate standing May be stacked with: CE A426
Introduces concepts of traffic flow simulation, modeling of driver behavior, and application of traffic simulation in Intelligent Transportation Systems. Registration Restrictions: Instructor's permission and graduate standing May be stacked with: CE A426
Fundamental equations for different finite elements as well as computer modeling of engineering structures using these elements are examined. Basic finite elements for truss, beam, frame and triangular plane elements are discussed in detail. The use of finite element software to solve a variety of structural engineering problems is discussed. The results of actual analysis are critically examined in class.
Fundamental equations for different finite elements as well as computer modeling of engineering structures using these elements are examined. Basic finite elements for truss, beam, frame and triangular plane elements are discussed in detail. The use of finite element software to solve a variety of structural engineering problems is discussed. The results of actual analysis are critically examined in class.
Introduction to the fundamental theory, analysis and regulations of environmental engineering and applied environmental science. Topics include environmental chemistry, drinking water and wastewater treatment, air pollution and solid waste management. May be stacked with: CE A441 Registration Restrictions: Graduate standing in Civil Engineering or enrolled in AEST.
Introduction to the fundamental theory, analysis and regulations of environmental engineering and applied environmental science. Topics include environmental chemistry, drinking water and wastewater treatment, air pollution and solid waste management. May be stacked with: CE A441 Registration Restrictions: Graduate standing in Civil Engineering or enrolled in AEST.
Theory and design of aerobic and anaerobic process for the treatment of wastewater including activated sludge, various surface film reactors, sludge digestion and disposal, and nutrient removal. May be stacked with: CE A446 Registration Restrictions: Graduate standing in Civil Engineering or Applied Environmental Science and Technology.
Theory and design of aerobic and anaerobic process for the treatment of wastewater including activated sludge, various surface film reactors, sludge digestion and disposal, and nutrient removal. May be stacked with: CE A446 Registration Restrictions: Graduate standing in Civil Engineering or Applied Environmental Science and Technology.
The theory and design of advanced unit processes with emphasis on emerging disinfectants, ozone and ultraviolet light disinfection, advanced oxidation, sorbents, and membranes; application of these innovative technologies in the drinking water and wastewater arena. May be stacked with: CE A447 Registration Restrictions: Graduate standing in Civil Engineering or instructor permission.
The theory and design of advanced unit processes with emphasis on emerging disinfectants, ozone and ultraviolet light disinfection, advanced oxidation, sorbents, and membranes; application of these innovative technologies in the drinking water and wastewater arena. May be stacked with: CE A447 Registration Restrictions: Graduate standing in Civil Engineering or instructor permission.
Advanced structural design in steel, including building code requirements and standard practice for the design of steel structures and connections. May be stacked with: CE A452 Registration Restrictions: Graduate standing or instructor approval.
Advanced structural design in steel, including building code requirements and standard practice for the design of steel structures and connections. May be stacked with: CE A452 Registration Restrictions: Graduate standing or instructor approval.
Advanced structural design in steel, including building code requirements and standard practice for the design of steel structures and connections. May be stacked with: CE A452 Registration Restrictions: Graduate standing or instructor approval.
Fundamentals of geohydrology, hydraulics of flow through porous media, well hydraulics, ground water pollution, and ground water resources development.
Fundamentals of geohydrology, hydraulics of flow through porous media, well hydraulics, ground water pollution, and ground water resources development.
Application of linear and nonlinear wave theory to the study of coastal processes and the design of coastal structures; wave transformation processes including wind generation, refraction and diffraction. May be stacked with: CE A476 Registration Restrictions: Graduate standing in Civil Engineering.
Application of linear and nonlinear wave theory to the study of coastal processes and the design of coastal structures; wave transformation processes including wind generation, refraction and diffraction. May be stacked with: CE A476 Registration Restrictions: Graduate standing in Civil Engineering.
Application of linear and nonlinear wave theory to the study of coastal processes and the design of coastal structures; wave transformation processes including wind generation, refraction and diffraction. May be stacked with: CE A476 Registration Restrictions: Graduate standing in Civil Engineering.
Factors are reviewed governing design of engineering works which must contend with the presence of ice. Topics discussed include fundamental ice properties, river, lake, and sea ice processes, ice navigation and control of ice in channels, structural and non-structural ice control measures, ice jams, bearing capacity of floating ice sheets, ice forces on riverine and ocean structures. Registration Restrictions: Graduate standing, with a degree in engineering or physical science, or upper class standing in an accredited undergraduate program in these categories.
Factors are reviewed governing design of engineering works which must contend with the presence of ice. Topics discussed include fundamental ice properties, river, lake, and sea ice processes, ice navigation and control of ice in channels, structural and non-structural ice control measures, ice jams, bearing capacity of floating ice sheets, ice forces on riverine and ocean structures. Registration Restrictions: Graduate standing, with a degree in engineering or physical science, or upper class standing in an accredited undergraduate program in these categories.
Reviews physical principles and current practices associated with planning and design of safe, efficient, and affordable water supply, fire protection, wastewater collection and disposal, and solid waste disposal works in cold regions, with a view toward conditions of rural Arctic Alaska. Registration Restrictions: Graduate standing, with a degree in engineering or physical science, or upper class standing in an accredited undergraduate program in these categories.
Reviews physical principles and current practices associated with planning and design of safe, efficient, and affordable water supply, fire protection, wastewater collection and disposal, and solid waste disposal works in cold regions, with a view toward conditions of rural Arctic Alaska. Registration Restrictions: Graduate standing, with a degree in engineering or physical science, or upper class standing in an accredited undergraduate program in these categories.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
Civil and Arctic Engineering project arranged among the advisor, graduate advisory committee and student to solve a practical engineering problem. Registration Restrictions: Graduate standing with a minimum of 9 graduate credits.
A course to be designed between the student and faculty member to allow students the chance to pursue special advanced interests in engineering at the MS level. Registration Restrictions: Faculty permission.
A course to be designed between the student and faculty member to allow students the chance to pursue special advanced interests in engineering at the MS level. Registration Restrictions: Faculty permission.
A course to be designed between the student and faculty member to allow students the chance to pursue special advanced interests in engineering at the MS level. Registration Restrictions: Faculty permission.
A course to be designed between the student and faculty member to allow students the chance to pursue special advanced interests in engineering at the MS level. Registration Restrictions: Faculty permission.
Offers a broad overview of computer science designed to provide students with an appreciation for and an understanding of the many different aspects of computer science. Topics include discrete mathematics, an introduction to programming languages, algorithmic problem solving, basic concepts in hardware, operating systems, networks, graphics, and an overview of the social context of computing. The following basic computer skills are expected: how to use a web browser, send email, edit with a word processor, copy files, open and save documents, and open and close windows. Special Note: Students who intend to major in computer science may take this course as preparation for their course of study. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA Placement Test required.
Offers a broad overview of computer science designed to provide students with an appreciation for and an understanding of the many different aspects of computer science. Topics include discrete mathematics, an introduction to programming languages, algorithmic problem solving, basic concepts in hardware, operating systems, networks, graphics, and an overview of the social context of computing. The following basic computer skills are expected: how to use a web browser, send email, edit with a word processor, copy files, open and save documents, and open and close windows. Special Note: Students who intend to major in computer science may take this course as preparation for their course of study. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA Placement Test required.
Problem analysis and solution using a selected programming language. Special Note: May be repeated twice for credit with a change in language. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA Placement Test required.
CRN: 38238 Section: P11 Date Range: 01/14-05/06 Section Title: C# in Microsoft Visual Studio
Problem analysis and solution using a selected programming language. Special Note: May be repeated twice for credit with a change in language. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA Placement Test required.
Problem analysis and solution using a selected programming language. Special Note: May be repeated twice for credit with a change in language. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA Placement Test required.
Problem analysis and solution using a selected programming language. Special Note: May be repeated twice for credit with a change in language. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA Placement Test required.
Introduction to the syntax of the Java language and object-orientation with an emphasis on writing programs to solve problems. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA placement test required.
Introduction to the syntax of the Java language and object-orientation with an emphasis on writing programs to solve problems. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA placement test required.
Introduction to the syntax and semantics of the Visual Basic .NET programming language with an emphasis on writing programs to solve problems. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA placement test required.
Introduction to the syntax and semantics of the Visual Basic .NET programming language with an emphasis on writing programs to solve problems. Registration Restrictions: If prerequisite is not satisfied, appropriate SAT or ACT scores or approved UAA placement test required.
An introduction to object-oriented programming techniques and problem solving. This includes basic syntax; sequential, branching, and looping execution; as well as concepts such as inheritance, encapsulation, and polymorphism. Registration Restrictions: Meet prerequisites or placement into MATH A200 or MATH A272.
An introduction to object-oriented programming techniques and problem solving. This includes basic syntax; sequential, branching, and looping execution; as well as concepts such as inheritance, encapsulation, and polymorphism. Registration Restrictions: Meet prerequisites or placement into MATH A200 or MATH A272.
An introduction to object-oriented programming techniques and problem solving. This includes basic syntax; sequential, branching, and looping execution; as well as concepts such as inheritance, encapsulation, and polymorphism. Registration Restrictions: Meet prerequisites or placement into MATH A200 or MATH A272.
Introduces the hardware components of computer systems, the organization of those components, and the low-level programming operations that computer systems provide. Includes fundamentals of assembly language programming.
Introduces the hardware components of computer systems, the organization of those components, and the low-level programming operations that computer systems provide. Includes fundamentals of assembly language programming.
Analysis and design of electronic devices used as building blocks for construction of simple digital systems. Presents formats for data storage, number systems and alphanumeric codes, and methods of implementing logical and arithmetic operations within computers. Relates hardware components' capabilities and limitations to design requirements for computer processing, memory, and control functions. Crosslisted with EE A241.
Analysis and design of electronic devices used as building blocks for construction of simple digital systems. Presents formats for data storage, number systems and alphanumeric codes, and methods of implementing logical and arithmetic operations within computers. Relates hardware components' capabilities and limitations to design requirements for computer processing, memory, and control functions. Crosslisted with EE A241.
Object-oriented approach to modeling real-world entities and designing a language-independent software application or system based on that model. The course will include selected programming assignments and projects in a current object-oriented language.
Object-oriented approach to modeling real-world entities and designing a language-independent software application or system based on that model. The course will include selected programming assignments and projects in a current object-oriented language.
Study of the syntax and semantics of widely differing programming languages. Syntax specification, block structure, binding, data structure operators, and control structures. Comparison of several programming languages. The languages will be selected to cover the major topical areas of procedural, functional, logic, and scripting languages. Programming assignments will be given in each language studied.
Study of the syntax and semantics of widely differing programming languages. Syntax specification, block structure, binding, data structure operators, and control structures. Comparison of several programming languages. The languages will be selected to cover the major topical areas of procedural, functional, logic, and scripting languages. Programming assignments will be given in each language studied.
Study of the theory of computing and algorithm analysis and design. Topics in computing theory include: parsing, finite automata and regular languages, pushdown automata and context-free grammars, deterministic and nondeterministic Turing machines, decidability, and computability. Topics in the algorithm domain include: algorithm analysis and complexity, searching/sorting algorithms, mathematical algorithms, and graph theoretic algorithms.
Study of the theory of computing and algorithm analysis and design. Topics in computing theory include: parsing, finite automata and regular languages, pushdown automata and context-free grammars, deterministic and nondeterministic Turing machines, decidability, and computability. Topics in the algorithm domain include: algorithm analysis and complexity, searching/sorting algorithms, mathematical algorithms, and graph theoretic algorithms.
Application of data modeling, relational database concepts and design, normalization theory, and structured query language. Study of underlying data structures and implementations of data processing architectures.
Application of data modeling, relational database concepts and design, normalization theory, and structured query language. Study of underlying data structures and implementations of data processing architectures.
Application of computing skills in a professional work setting. Special Note: This course is open to qualified students with faculty approval, and as placements are available. Special Note: May be taken up to three times, but only 3 credits may be applied towards CS major requirements. Registration Restrictions: Faculty approval.
Application of computing skills in a professional work setting. Special Note: This course is open to qualified students with faculty approval, and as placements are available. Special Note: May be taken up to three times, but only 3 credits may be applied towards CS major requirements. Registration Restrictions: Faculty approval.
Application of computing skills in a professional work setting. Special Note: This course is open to qualified students with faculty approval, and as placements are available. Special Note: May be taken up to three times, but only 3 credits may be applied towards CS major requirements. Registration Restrictions: Faculty approval.
Introduces students to subjects in the broad field of evolutionary computing, including genetic algorithms, evolution strategies, evolutionary programming, and genetic programming. Emphasis will be on the design, implementation, testing, debugging, and verification of correct programs.
Introduces students to subjects in the broad field of evolutionary computing, including genetic algorithms, evolution strategies, evolutionary programming, and genetic programming. Emphasis will be on the design, implementation, testing, debugging, and verification of correct programs.
Application of software development concepts, principles, and practices to a comprehensive, realistic system. The student will analyze, design, document, implement, and deliver a presentation and written report of a software system of moderate complexity under the supervision of the instructor. Registration Restrictions: Senior standing, and completion of GER Tier 1 (basic college-level skills) courses.
Application of software development concepts, principles, and practices to a comprehensive, realistic system. The student will analyze, design, document, implement, and deliver a presentation and written report of a software system of moderate complexity under the supervision of the instructor. Registration Restrictions: Senior standing, and completion of GER Tier 1 (basic college-level skills) courses.
Professional work experience in appropriate areas of computing. The student will analyze, design, and document a realistic computer science project of moderate complexity under the supervision of a qualified professional who has agreed in advance to undertake this role. Special Note: Enrollment will be permitted after a plan for the completion of the project is submitted to and approved by the instructor. Internships are subject to availability of placement. May be taken more than once, but only 3 credits of the upper division credit requirement for the bachelor's degree in CS may be met with CS A495. Students wishing to earn internship credits without the project requirement should enroll in CS A395. Registration Restrictions: Junior or senior standing with minimum of 15 credits in CS courses and faculty permission.
Professional work experience in appropriate areas of computing. The student will analyze, design, and document a realistic computer science project of moderate complexity under the supervision of a qualified professional who has agreed in advance to undertake this role. Special Note: Enrollment will be permitted after a plan for the completion of the project is submitted to and approved by the instructor. Internships are subject to availability of placement. May be taken more than once, but only 3 credits of the upper division credit requirement for the bachelor's degree in CS may be met with CS A495. Students wishing to earn internship credits without the project requirement should enroll in CS A395. Registration Restrictions: Junior or senior standing with minimum of 15 credits in CS courses and faculty permission.
Professional work experience in appropriate areas of computing. The student will analyze, design, and document a realistic computer science project of moderate complexity under the supervision of a qualified professional who has agreed in advance to undertake this role. Special Note: Enrollment will be permitted after a plan for the completion of the project is submitted to and approved by the instructor. Internships are subject to availability of placement. May be taken more than once, but only 3 credits of the upper division credit requirement for the bachelor's degree in CS may be met with CS A495. Students wishing to earn internship credits without the project requirement should enroll in CS A395. Registration Restrictions: Junior or senior standing with minimum of 15 credits in CS courses and faculty permission.
Independent research projects under the supervision of a faculty member. The result will be a paper or presentation prepared to publication standards. Special Note: May be repeated up to a maximum of six credits. Registration Restrictions: Upper division standing and faculty permission.
Independent research projects under the supervision of a faculty member. The result will be a paper or presentation prepared to publication standards. Special Note: May be repeated up to a maximum of six credits. Registration Restrictions: Upper division standing and faculty permission.
Introduction to hardware, operating systems, networking, security, storage, maintenance and related topics in computer systems. This course prepares students for applications across a wide range of computer systems for use in Geomatics and GIS courses as well as basic system management in field situations for Geomatics/GIS applications.
Introduction to hardware, operating systems, networking, security, storage, maintenance and related topics in computer systems. This course prepares students for applications across a wide range of computer systems for use in Geomatics and GIS courses as well as basic system management in field situations for Geomatics/GIS applications.
Introduction to C programming for engineers. Students will learn a programming language that can be used in many aspects of the engineering field, specifically with applications interfacing with hardware devices. Students will gain basic programming skills, including variables, functions, structures, control structures, and conditional statements with applied reinforcement in engineering applications. Projects will focus on engineering applications in different fields.
Introduction to C programming for engineers. Students will learn a programming language that can be used in many aspects of the engineering field, specifically with applications interfacing with hardware devices. Students will gain basic programming skills, including variables, functions, structures, control structures, and conditional statements with applied reinforcement in engineering applications. Projects will focus on engineering applications in different fields.
Object-oriented programming for engineers. Students will learn a programming language that can be used in many aspects of the engineering field. Assignments will focus on engineering applications that communicate with hardware devices through the use of programming skills, including objects, classes, inheritance, hierarchies, polymorphism, recursion, graphical user interfaces, event processing, and exception handling. This course is a cross-over class where students will learn object-oriented concepts in C++ and Java. Projects will focus on engineering applications in different fields.
Object-oriented programming for engineers. Students will learn a programming language that can be used in many aspects of the engineering field. Assignments will focus on engineering applications that communicate with hardware devices through the use of programming skills, including objects, classes, inheritance, hierarchies, polymorphism, recursion, graphical user interfaces, event processing, and exception handling. This course is a cross-over class where students will learn object-oriented concepts in C++ and Java. Projects will focus on engineering applications in different fields.
Introductory course on the inner workings of an operating system from an engineering perspective. Students will create different modules of an operating system, including memory management, threading, networking, and user interface in an environment of engineering applications and designed for hardware in the engineering field and other CSE courses. Students will create components of an operating system designed for hardware in the engineering field and other CSE courses.
Introductory course on the inner workings of an operating system from an engineering perspective. Students will create different modules of an operating system, including memory management, threading, networking, and user interface in an environment of engineering applications and designed for hardware in the engineering field and other CSE courses. Students will create components of an operating system designed for hardware in the engineering field and other CSE courses.
Network architectures, layered and Internet protocols, and network service interfaces. Emphasis on design and implementation of networking hardware, including routers bridges, switches, hubs, and repeaters. Local networks, addressing, flow control, queuing, routing protocols, packet-loss with emphasis on engineering design and applications.
Network architectures, layered and Internet protocols, and network service interfaces. Emphasis on design and implementation of networking hardware, including routers bridges, switches, hubs, and repeaters. Local networks, addressing, flow control, queuing, routing protocols, packet-loss with emphasis on engineering design and applications.
A438*Design Computer Engr Systems
3.0
DaysTimeLocationInstructorOpen Seats
Miller, J15
CRN: 31343 Section: 001 Date Range: 01/14-05/04
Capstone course in which computer systems engineering students design a computer component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Capstone course in which computer systems engineering students design a computer component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Analysis and design of digital VLSI (Very Large Scale Integration) circuits including area restrictions, delay minimization, and power minimization. Simulation of VLSI logic in software. CMOS (complementary metal-oxide-semiconductor) design rules, physical design, power consumption, clocking strategies, and transistor theory. Engineering VLSI simulation course project.
Analysis and design of digital VLSI (Very Large Scale Integration) circuits including area restrictions, delay minimization, and power minimization. Simulation of VLSI logic in software. CMOS (complementary metal-oxide-semiconductor) design rules, physical design, power consumption, clocking strategies, and transistor theory. Engineering VLSI simulation course project.
Modern systems abstractions and challenges in developing scalable solutions for increasingly complex computing needs from systems software design perspective. Relationships between software and hardware abstractions are studied while focusing on engineering tradeoffs between correctness and performance. Advanced topics including parallel systems and multi-core models.
Modern systems abstractions and challenges in developing scalable solutions for increasingly complex computing needs from systems software design perspective. Relationships between software and hardware abstractions are studied while focusing on engineering tradeoffs between correctness and performance. Advanced topics including parallel systems and multi-core models.
Introduces electronic devices, their characteristics, uses, and limitations. Covers methods of analysis of circuits containing solid state devices including diodes, bipolar junction transistors, field effect transistors, and operational amplifiers. Covers design and operation of primitive digital devices including logic gates and analog/digital converters. Special Note: Offered Fall Semesters.
Introduces electronic devices, their characteristics, uses, and limitations. Covers methods of analysis of circuits containing solid state devices including diodes, bipolar junction transistors, field effect transistors, and operational amplifiers. Covers design and operation of primitive digital devices including logic gates and analog/digital converters. Special Note: Offered Fall Semesters.
Analysis and design of electronic devices used as building blocks for construction of simple combinational and sequential digital systems. Presents formats for data storage, number systems and alphanumeric codes, and methods of implementing logical and arithmetic operations within computers. Relates hardware components' capabilities and limitations to design requirements for computer processing, memory and control functions. Crosslisted with CSCE A241.
Analysis and design of electronic devices used as building blocks for construction of simple combinational and sequential digital systems. Presents formats for data storage, number systems and alphanumeric codes, and methods of implementing logical and arithmetic operations within computers. Relates hardware components' capabilities and limitations to design requirements for computer processing, memory and control functions. Crosslisted with CSCE A241.
Introduces MATLAB programming skills to students to solve problems in various electrical engineering focus areas including circuit analysis, signal analysis, and communication.
Introduces MATLAB programming skills to students to solve problems in various electrical engineering focus areas including circuit analysis, signal analysis, and communication.
Modeling of mechanical, electrical, fluid and thermal elements and systems. Study of free and forced response by the Laplace transform, transfer function, and state space models. Time domain and frequency domain responses. Coupled systems, system analogy, sensing and actuation principles. Crosslisted with: ME A306
Modeling of mechanical, electrical, fluid and thermal elements and systems. Study of free and forced response by the Laplace transform, transfer function, and state space models. Time domain and frequency domain responses. Coupled systems, system analogy, sensing and actuation principles. Crosslisted with: ME A306
Principles of measurement, instrumentation, Laplace transform, Fourier series, transfer function, steady-state response, calibration, and errors. Signal filtering and amplification, data acquisition, recording, and processing. Methods and devices for measuring strain, force, torque, displacement, velocity, acceleration, pressure, fluid flow properties, and temperature. Mechatronics, sensors, actuators, and controls. Crosslisted with ME A308.
Principles of measurement, instrumentation, Laplace transform, Fourier series, transfer function, steady-state response, calibration, and errors. Signal filtering and amplification, data acquisition, recording, and processing. Methods and devices for measuring strain, force, torque, displacement, velocity, acceleration, pressure, fluid flow properties, and temperature. Mechatronics, sensors, actuators, and controls. Crosslisted with ME A308.
Use of Maxwell's equations in analysis of plane wave propagation, wave reflection, radiation and antennas, waveguides, cavity resonators, transmission lines, and radio propagation. Crosslisted with PHYS A324.
Use of Maxwell's equations in analysis of plane wave propagation, wave reflection, radiation and antennas, waveguides, cavity resonators, transmission lines, and radio propagation. Crosslisted with PHYS A324.
Laboratory experiments using Maxwell's equations in analysis of plane wave propagation, wave reflection, radiation and antennas, waveguides, cavity resonators, transmission lines, and radio propagation.
Laboratory experiments using Maxwell's equations in analysis of plane wave propagation, wave reflection, radiation and antennas, waveguides, cavity resonators, transmission lines, and radio propagation.
Analysis of circuit behavior for passive and active filters. Application of Laplace and Fourier techniques to circuit characterization. This course serves as a laboratory component to EE A353.
Analysis of circuit behavior for passive and active filters. Application of Laplace and Fourier techniques to circuit characterization. This course serves as a laboratory component to EE A353.
Analysis of circuit behavior for passive and active filters. Application of Laplace and Fourier techniques to circuit characterization. This course serves as a laboratory component to EE A353.
Capstone course in which electrical engineering students design an electrical engineering component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Capstone course in which electrical engineering students design an electrical engineering component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Capstone course in which electrical engineering students design an electrical engineering component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Capstone course in which electrical engineering students design an electrical engineering component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Develops the design and fabrication of integrated circuits (ICs) used in computer electronics. Describes the material properties, methods of charge transport, energy exchanges, fundamentals of device fabrication, and fabrication process capabilities and limits. Electrical characteristics, timing considerations, heat and power considerations, and reliability of IC devices.
Develops the design and fabrication of integrated circuits (ICs) used in computer electronics. Describes the material properties, methods of charge transport, energy exchanges, fundamentals of device fabrication, and fabrication process capabilities and limits. Electrical characteristics, timing considerations, heat and power considerations, and reliability of IC devices.
Develops properties and methods of analysis of discrete-time signals, and the techniques used in creating and processing those signals. Topics include discrete-time linear systems, Z-transforms, the Discrete Fourier Transform and Fast Fourier Transform algorithms, digital filter design, system performance analysis and problem-solving. Methods and effects of signal processing are analyzed and evaluated.
Develops properties and methods of analysis of discrete-time signals, and the techniques used in creating and processing those signals. Topics include discrete-time linear systems, Z-transforms, the Discrete Fourier Transform and Fast Fourier Transform algorithms, digital filter design, system performance analysis and problem-solving. Methods and effects of signal processing are analyzed and evaluated.
Emphasis in data transmission, guided and wireless transmission, signal encoding, digital data, multiplexing, and circuit and packet switching. Analyze data communications, networking, protocols and standards.
Emphasis in data transmission, guided and wireless transmission, signal encoding, digital data, multiplexing, and circuit and packet switching. Analyze data communications, networking, protocols and standards.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Orthographic projections, auxiliary views, sectional views, and layer management are explored and implemented in assigned engineering design projects. Part I of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Orthographic projections, auxiliary views, sectional views, and layer management are explored and implemented in assigned engineering design projects. Part I of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Orthographic projections, auxiliary views, sectional views, and layer management are explored and implemented in assigned engineering design projects. Part I of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Object snaps, engineering drawing editing, blocks and external references, multi viewports and views, object linking and embedding, raster image manipulation, and basic 3-D modeling are explored and implemented in assigned engineering design projects. Part II of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Object snaps, engineering drawing editing, blocks and external references, multi viewports and views, object linking and embedding, raster image manipulation, and basic 3-D modeling are explored and implemented in assigned engineering design projects. Part II of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Object snaps, engineering drawing editing, blocks and external references, multi viewports and views, object linking and embedding, raster image manipulation, and basic 3-D modeling are explored and implemented in assigned engineering design projects. Part II of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Surfaces, featured based modeling, solid editing, extraction of orthographic, auxiliary and section views from a 3-D model, printing and plotting are explored and implemented in assigned engineering design projects. Part III of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Surfaces, featured based modeling, solid editing, extraction of orthographic, auxiliary and section views from a 3-D model, printing and plotting are explored and implemented in assigned engineering design projects. Part III of a three part series.
Applied engineering design course focusing on engineering graphics concepts using applied Computer-Aided Design (CAD) tools. Surfaces, featured based modeling, solid editing, extraction of orthographic, auxiliary and section views from a 3-D model, printing and plotting are explored and implemented in assigned engineering design projects. Part III of a three part series.
An introduction to engineering, both as a profession and as a field of study. Introduces students to the roles, responsibilities and capabilities of civil, computer systems, electrical and mechanical engineers.
An introduction to engineering, both as a profession and as a field of study. Introduces students to the roles, responsibilities and capabilities of civil, computer systems, electrical and mechanical engineers.
An introduction to engineering, both as a profession and as a field of study. Introduces students to the roles, responsibilities and capabilities of civil, computer systems, electrical and mechanical engineers.
An introduction to engineering, both as a profession and as a field of study. Introduces students to the roles, responsibilities and capabilities of civil, computer systems, electrical and mechanical engineers.
An introduction to engineering, both as a profession and as a field of study. Introduces students to the roles, responsibilities and capabilities of civil, computer systems, electrical and mechanical engineers.
Presents the basic skills required of engineers for using computers to solve engineering problems and presenting results in a professional form. Application of computation methods and tools for practicing engineering. Introduction to computer programming and engineering problem solving softwares including visual basic in spreadsheets, Matlab, and Mathcad.
Presents the basic skills required of engineers for using computers to solve engineering problems and presenting results in a professional form. Application of computation methods and tools for practicing engineering. Introduction to computer programming and engineering problem solving softwares including visual basic in spreadsheets, Matlab, and Mathcad.
Presents the basic skills required of engineers for using computers to solve engineering problems and presenting results in a professional form. Application of computation methods and tools for practicing engineering. Introduction to computer programming and engineering problem solving softwares including visual basic in spreadsheets, Matlab, and Mathcad.
Presents the basic skills required of engineers for using computers to solve engineering problems and presenting results in a professional form. Application of computation methods and tools for practicing engineering. Introduction to computer programming and engineering problem solving softwares including visual basic in spreadsheets, Matlab, and Mathcad.
Presents the basic skills required of engineers for using computers to solve engineering problems and presenting results in a professional form. Application of computation methods and tools for practicing engineering. Introduction to computer programming and engineering problem solving softwares including visual basic in spreadsheets, Matlab, and Mathcad.
Professional work experience designed to provide students with the opportunity to investigate the practical applications of engineering design within engineering organizations. Assignments and projects arranged with cooperating organizations and agencies. Registration Restrictions: Instructor permission.
Professional work experience designed to provide students with the opportunity to investigate the practical applications of engineering design within engineering organizations. Assignments and projects arranged with cooperating organizations and agencies. Registration Restrictions: Instructor permission.
Introduces the fundamentals of engineering graphics and provides training in visualization skills necessary for graphically presenting of engineering ideas using standard drawing techniques and Computer Aided Design (CAD).
Introduces the fundamentals of engineering graphics and provides training in visualization skills necessary for graphically presenting of engineering ideas using standard drawing techniques and Computer Aided Design (CAD).
Static and dynamic analysis of particles and rigid bodies. Statics topics covered include Newton's laws of motion, Newton's law of gravitational attraction, force and force systems, equilibrium, structural analysis, internal forces, friction, and center of gravity and centroid. Dynamics topics covered include particle and rigid body kinematics and kinetics, force and acceleration, work and energy, impulse and momentum, and vibrations.
Static and dynamic analysis of particles and rigid bodies. Statics topics covered include Newton's laws of motion, Newton's law of gravitational attraction, force and force systems, equilibrium, structural analysis, internal forces, friction, and center of gravity and centroid. Dynamics topics covered include particle and rigid body kinematics and kinetics, force and acceleration, work and energy, impulse and momentum, and vibrations.
Principles and analysis of static force systems, equilibrium, distributed forces, centroids, centers of gravity, moments of inertia, structures, friction, and virtual work.
Principles and analysis of static force systems, equilibrium, distributed forces, centroids, centers of gravity, moments of inertia, structures, friction, and virtual work.
Kinematics and kinetics of particles and rigid bodies with applications of Newton's second law and principles of work-energy, impulse-momentum, and vibration.
Kinematics and kinetics of particles and rigid bodies with applications of Newton's second law and principles of work-energy, impulse-momentum, and vibration.
Kinematics and kinetics of particles and rigid bodies with applications of Newton's second law and principles of work-energy, impulse-momentum, and vibration.
Electrical fundamentals: elementary circuit analysis, network theorems, steady state, and transient analysis of DC circuits with resistors and one energy storage device (L or C). Steady state analysis of AC circuits with resistors, capacitors, and inductors using complex number and phasor representation. Power in DC and AC circuits. Transformers, meters, and applications of simple electrical components and circuits.
Electrical fundamentals: elementary circuit analysis, network theorems, steady state, and transient analysis of DC circuits with resistors and one energy storage device (L or C). Steady state analysis of AC circuits with resistors, capacitors, and inductors using complex number and phasor representation. Power in DC and AC circuits. Transformers, meters, and applications of simple electrical components and circuits.
Stress-strain relations, axially loaded and torsional members, review of shear and bending moment diagrams for beams, flexural and shearing stresses, deflections of beams, plane stress, combined stresses, buckling of columns, elementary design of beams and columns.
Stress-strain relations, axially loaded and torsional members, review of shear and bending moment diagrams for beams, flexural and shearing stresses, deflections of beams, plane stress, combined stresses, buckling of columns, elementary design of beams and columns.
Introduction to physical properties and behavior of fluids. Topics include hydrostatics and dynamics of liquids and gases, dimensional analysis, fluid forces on immersed bodies, pipe flow, fluid machinery, and open channel flow.
Introduction to physical properties and behavior of fluids. Topics include hydrostatics and dynamics of liquids and gases, dimensional analysis, fluid forces on immersed bodies, pipe flow, fluid machinery, and open channel flow.
Provides supplemental explanation and practical exercises applying physical properties and behavior of fluids, including hydrostatics, fluid forces, pipe flow, fluid machinery, and open channel flow.
Provides supplemental explanation and practical exercises applying physical properties and behavior of fluids, including hydrostatics, fluid forces, pipe flow, fluid machinery, and open channel flow.
Provides supplemental explanation and practical exercises applying physical properties and behavior of fluids, including hydrostatics, fluid forces, pipe flow, fluid machinery, and open channel flow.
Thermodynamics systems, properties, processes, and cycles. Fundamental principles of thermodynamics (first and second laws), and elementary applications.
Thermodynamics systems, properties, processes, and cycles. Fundamental principles of thermodynamics (first and second laws), and elementary applications.
Introduces students to a broad spectrum of engineering challenges that are unique to cold regions of the world. Physical principles and practical data collection, analysis, design, and construction methods are discussed. Students gain a working knowledge of cold regions engineering problems and modern solutions. Registration Restrictions: Degree in engineering, architecture, landscape architecture, geomatics, or physical science, upper class standing in an undergraduate program in these categories, or instructor permission.
Introduces students to a broad spectrum of engineering challenges that are unique to cold regions of the world. Physical principles and practical data collection, analysis, design, and construction methods are discussed. Students gain a working knowledge of cold regions engineering problems and modern solutions. Registration Restrictions: Degree in engineering, architecture, landscape architecture, geomatics, or physical science, upper class standing in an undergraduate program in these categories, or instructor permission.
Fundamentals of engineering economy, project scheduling, estimating, legal principles, professional ethics, and human relations. Special Note: Not offered for credit toward the Master of Science in engineering management or science management. Offered Spring Semesters.
Fundamentals of engineering economy, project scheduling, estimating, legal principles, professional ethics, and human relations. Special Note: Not offered for credit toward the Master of Science in engineering management or science management. Offered Spring Semesters.
The science of fiscal decision making. Graduate level studies in problems of replacement, economic selections, income tax accounting, engineering evaluation and introduction to the problems of depreciation.
The science of fiscal decision making. Graduate level studies in problems of replacement, economic selections, income tax accounting, engineering evaluation and introduction to the problems of depreciation.
Principles, practices and procedures used in the preparation of engineering cost estimates. Exposition of the basic concepts and steps required to develop engineering type, labor and material based, and parametric cost estimates. Preparation of cost proposals and study of bidding procedures. Students will manage the student project teams, prepare a research paper, and make a class presentation. Registration Restrictions: BS degree in Engineering or in a physical science or faculty permission.
Principles, practices and procedures used in the preparation of engineering cost estimates. Exposition of the basic concepts and steps required to develop engineering type, labor and material based, and parametric cost estimates. Preparation of cost proposals and study of bidding procedures. Students will manage the student project teams, prepare a research paper, and make a class presentation. Registration Restrictions: BS degree in Engineering or in a physical science or faculty permission.
Issues and case studies of policy development, strategy, planning and management of technology in the overall corporate environment. Registration Restrictions: Graduate standing. Crosslisted with BA A617.
Issues and case studies of policy development, strategy, planning and management of technology in the overall corporate environment. Registration Restrictions: Graduate standing. Crosslisted with BA A617.
Introduction to Geomatic, subdivision, and boundary computations. Intersection of lines. Methods of adjusting Geomatic data. Design and determination of curvilineal and required areas. Adjustment of retracement surveys. Computations of circular curves. Introduction to the current industry standard hand held calculator. Registration Restrictions: See admission requirements. Special Note: Offered Spring Semesters.
Introduction to Geomatic, subdivision, and boundary computations. Intersection of lines. Methods of adjusting Geomatic data. Design and determination of curvilineal and required areas. Adjustment of retracement surveys. Computations of circular curves. Introduction to the current industry standard hand held calculator. Registration Restrictions: See admission requirements. Special Note: Offered Spring Semesters.
Introduction to Geomatics and survey measurement techniques, including the use of levels, theodolites, and total stations, and GPS. Methods of recording and reducing field data. Use of hand-held calculators to compute directions, survey errors, closures, adjustments, and area. Geomatics projects and field trips. Review of historical survey techniques and the Public Land Survey System. Introduction to horizontal curves. Registration Restrictions: See admission requirements. Special Note: Offered Fall Semesters.
Introduction to Geomatics and survey measurement techniques, including the use of levels, theodolites, and total stations, and GPS. Methods of recording and reducing field data. Use of hand-held calculators to compute directions, survey errors, closures, adjustments, and area. Geomatics projects and field trips. Review of historical survey techniques and the Public Land Survey System. Introduction to horizontal curves. Registration Restrictions: See admission requirements. Special Note: Offered Fall Semesters.
Use of computational devices with applications in Geomatics. The basics of Reverse Polish Notation and keystroke programming will be covered. Use of Excel and MATLAB to solve geomatics problems will be emphasized. Special Note: To be taken concurrently with ENGR A161. Registration Restrictions: Prerequisites may be waived by instructor based on student's prior experience.
Use of computational devices with applications in Geomatics. The basics of Reverse Polish Notation and keystroke programming will be covered. Use of Excel and MATLAB to solve geomatics problems will be emphasized. Special Note: To be taken concurrently with ENGR A161. Registration Restrictions: Prerequisites may be waived by instructor based on student's prior experience.
Introduction to photo interpretation and imaging systems. Geometry of photogrammetry. Theory of electromagnetic spectrum. Application of remote sensing in engineering, archaeology, agriculture, and forestry using image analysis software. Registration Restrictions: Computer competency (see admission requirements) or instructor approval. Special Note: Offered Spring Semesters.
Introduction to photo interpretation and imaging systems. Geometry of photogrammetry. Theory of electromagnetic spectrum. Application of remote sensing in engineering, archaeology, agriculture, and forestry using image analysis software. Registration Restrictions: Computer competency (see admission requirements) or instructor approval. Special Note: Offered Spring Semesters.
Basic construction surveying procedures, including staking for roads, buildings and excavations; use of maps, construction plans, datums and co-ordinate systems; machine control systems. The course is predominantly field work.
Basic construction surveying procedures, including staking for roads, buildings and excavations; use of maps, construction plans, datums and co-ordinate systems; machine control systems. The course is predominantly field work.
Basic construction surveying procedures, including staking for roads, buildings and excavations; use of maps, construction plans, datums and co-ordinate systems; machine control systems. The course is predominantly field work.
An intermediate level digital terrain cartography course for Geomatics majors and non-majors. Autodesk Land Development Desktop and CAD Overlay will be used to introduce Autodesk Civil/Survey Software. Lectures and projects will include digital terrain modeling, alignments, cross-sections, volume computations, and provide a base graphic communications knowledge that is essential for success in future Geomatics courses and in professional employment. Special Note: Offered Spring Semesters.
An intermediate level digital terrain cartography course for Geomatics majors and non-majors. Autodesk Land Development Desktop and CAD Overlay will be used to introduce Autodesk Civil/Survey Software. Lectures and projects will include digital terrain modeling, alignments, cross-sections, volume computations, and provide a base graphic communications knowledge that is essential for success in future Geomatics courses and in professional employment. Special Note: Offered Spring Semesters.
An introduction to the engineering design process as used by geomatics professionals. Conceptualization, feasibility assessment, human factors, design management and implementation in geomatics problem solving. The course has an emphasis on developing open-ended problem-solving skills, including solving ethical and legal geomatics problems. Continuation of GEO A301.
An introduction to the engineering design process as used by geomatics professionals. Conceptualization, feasibility assessment, human factors, design management and implementation in geomatics problem solving. The course has an emphasis on developing open-ended problem-solving skills, including solving ethical and legal geomatics problems. Continuation of GEO A301.
Introduction to fundamentals concepts, including physical planning, transportation, housing, land use, urban development and preservation. Population movement to cities and suburbs; rural depopulation. Regional growth and development. Political and economic development drivers. History, theory and ethics of planning. Virtual environments. GIS and support tools for planning decisions. Registration Restrictions: Junior or senior standing.
Introduction to fundamentals concepts, including physical planning, transportation, housing, land use, urban development and preservation. Population movement to cities and suburbs; rural depopulation. Regional growth and development. Political and economic development drivers. History, theory and ethics of planning. Virtual environments. GIS and support tools for planning decisions. Registration Restrictions: Junior or senior standing.
Concepts governing land development. Analysis of soil, topography, geometry, environmental impact, aesthetic and economic principles in land planning. Permitting process. Federal, state, and municipality platting regulations. Automated subdivision design and platting. Ethical considerations when developing land. Special Note: Offered Fall Semesters.
Concepts governing land development. Analysis of soil, topography, geometry, environmental impact, aesthetic and economic principles in land planning. Permitting process. Federal, state, and municipality platting regulations. Automated subdivision design and platting. Ethical considerations when developing land. Special Note: Offered Fall Semesters.
Analysis of errors and adjustments in Geomatics measurements. Propagation of errors and variances. Statistical analyses and error ellipses. Geomatics accuracies and standards. Theory and methods of weighted, non-linear least squares adjustment.
Analysis of errors and adjustments in Geomatics measurements. Propagation of errors and variances. Statistical analyses and error ellipses. Geomatics accuracies and standards. Theory and methods of weighted, non-linear least squares adjustment.
Analysis of errors and adjustments in Geomatics measurements. Propagation of errors and variances. Statistical analyses and error ellipses. Geomatics accuracies and standards. Theory and methods of weighted, non-linear least squares adjustment.
Procedures and sources for legal research, Alaska Easement Law, Alaska State Statutes and Administrative Code applicable to land surveying, current BLM procedures and regulations, surveying platting procedures, Defective Survey Act, lotted sections, floodplains and wetlands, water boundary case law, ALTA/ASCM survey procedures, writing and interpreting legal descriptions. Special Note: Offered Spring Semesters.
Procedures and sources for legal research, Alaska Easement Law, Alaska State Statutes and Administrative Code applicable to land surveying, current BLM procedures and regulations, surveying platting procedures, Defective Survey Act, lotted sections, floodplains and wetlands, water boundary case law, ALTA/ASCM survey procedures, writing and interpreting legal descriptions. Special Note: Offered Spring Semesters.
Projects in Geomatics and Geographic Information Systems (GIS). Research, design, data compilation, analysis and mapping for a Geomatics project. Professional standards and ethical concerns for Geomatics professionals. Registration Restrictions: Prerequisites may be waived by instructor based on student's prior experience. Completion of GER Tier I (basic college-level skills) courses.
Projects in Geomatics and Geographic Information Systems (GIS). Research, design, data compilation, analysis and mapping for a Geomatics project. Professional standards and ethical concerns for Geomatics professionals. Registration Restrictions: Prerequisites may be waived by instructor based on student's prior experience. Completion of GER Tier I (basic college-level skills) courses.
The theory and practice of positioning systems, primarily Global Navigation Satellite Systems (GNSS). Data collection, quality assessment, analysis and adjustment. Connection to Inertial Navigation Systems (INS) and other applications.
The theory and practice of positioning systems, primarily Global Navigation Satellite Systems (GNSS). Data collection, quality assessment, analysis and adjustment. Connection to Inertial Navigation Systems (INS) and other applications.
Theory of analytical photogrammetry including mathematical development of the rotation matrix, interior, relative, and absolute orientation. Programming of photogrammetric adjustments. Theory of strip and block adjustments. Independent projects in photogrammetric mapping. Special Note: Offered Alternate Spring Semesters.
Theory of analytical photogrammetry including mathematical development of the rotation matrix, interior, relative, and absolute orientation. Programming of photogrammetric adjustments. Theory of strip and block adjustments. Independent projects in photogrammetric mapping. Special Note: Offered Alternate Spring Semesters.
Introduction to fundamentals of GIS, including common uses and technical concepts, e.g., data structures (raster and vector), data sources, metadata, databases, coordinate systems, geocoding, spatial analysis, georeferencing, cartographic design and map compilation. Investigation of spatial data quality and accuracy. Application of GIS analysis functions and standard query languages. Application of GIS to real-world problems.
Introduction to fundamentals of GIS, including common uses and technical concepts, e.g., data structures (raster and vector), data sources, metadata, databases, coordinate systems, geocoding, spatial analysis, georeferencing, cartographic design and map compilation. Investigation of spatial data quality and accuracy. Application of GIS analysis functions and standard query languages. Application of GIS to real-world problems.
Introduction to fundamentals of GIS, including common uses and technical concepts, e.g., data structures (raster and vector), data sources, metadata, databases, coordinate systems, geocoding, spatial analysis, georeferencing, cartographic design and map compilation. Investigation of spatial data quality and accuracy. Application of GIS analysis functions and standard query languages. Application of GIS to real-world problems.
Introduction to fundamentals of GIS, including common uses and technical concepts, e.g., data structures (raster and vector), data sources, metadata, databases, coordinate systems, geocoding, spatial analysis, georeferencing, cartographic design and map compilation. Investigation of spatial data quality and accuracy. Application of GIS analysis functions and standard query languages. Application of GIS to real-world problems.
History and philosophy of land, surveying, and land information systems in North America and other regions. Land data systems. Overview of methods for describing and interpreting land descriptions as well as data acquisition, methods, design, and applications for LIS. Issues of accuracy assessment, public lands, and information.
History and philosophy of land, surveying, and land information systems in North America and other regions. Land data systems. Overview of methods for describing and interpreting land descriptions as well as data acquisition, methods, design, and applications for LIS. Issues of accuracy assessment, public lands, and information.
Spatial database system philosophy and concepts including decision making criteria, design, planning, implementation and management. Discussion of spatial data standards, legal issues, and national spatial data policies. Project implementation and management. GIS in organizational contexts. Human-computer interactions and GIS.
Spatial database system philosophy and concepts including decision making criteria, design, planning, implementation and management. Discussion of spatial data standards, legal issues, and national spatial data policies. Project implementation and management. GIS in organizational contexts. Human-computer interactions and GIS.
Integration of GPS, INS, GIS, photogrammetry, remote sensing, terrestrial surveying and related technology and techniques. Scripting and development in various geo-spatial packages. Data translation/transfer techniques. Web-based approaches to spatial information management and dissemination. Mobile and server technologies for spatial information.
Integration of GPS, INS, GIS, photogrammetry, remote sensing, terrestrial surveying and related technology and techniques. Scripting and development in various geo-spatial packages. Data translation/transfer techniques. Web-based approaches to spatial information management and dissemination. Mobile and server technologies for spatial information.
Integration of GPS, INS, GIS, photogrammetry, remote sensing, terrestrial surveying and related technology and techniques. Scripting and development in various geo-spatial packages. Data translation/transfer techniques. Web-based approaches to spatial information management and dissemination. Mobile and server technologies for spatial information.
This course is an introduction to the use of solid modeling in engineering. The process of creating solid parts, assemblies, and fabrication-ready drawings in addition to kinematics linkages will be covered. Rapid prototyping technologies such as three dimensional printing will be used as laboratory exercises.
This course is an introduction to the use of solid modeling in engineering. The process of creating solid parts, assemblies, and fabrication-ready drawings in addition to kinematics linkages will be covered. Rapid prototyping technologies such as three dimensional printing will be used as laboratory exercises.
Modeling of mechanical, electrical, fluid and thermal elements and systems. Study of free and forced response by the Laplace transform, transfer function and state space models. Time domain and frequency domain responses. Coupled systems, system analogy, sensing and actuation principles. Crosslisted with: EE A306
Modeling of mechanical, electrical, fluid and thermal elements and systems. Study of free and forced response by the Laplace transform, transfer function and state space models. Time domain and frequency domain responses. Coupled systems, system analogy, sensing and actuation principles. Crosslisted with: EE A306
Principles of measurement, instrumentation, Laplace transform, Fourier series, transfer function, steady-state response, calibration, and errors. Signal filtering and amplification, data acquisition, recording, and processing. Methods and devices for measuring strain, force, torque, displacement, velocity, acceleration, pressure, fluid flow properties, and temperature. Mechatronics, sensors, actuators, and controls. Crosslisted with EE A308.
Principles of measurement, instrumentation, Laplace transform, Fourier series, transfer function, steady-state response, calibration, and errors. Signal filtering and amplification, data acquisition, recording, and processing. Methods and devices for measuring strain, force, torque, displacement, velocity, acceleration, pressure, fluid flow properties, and temperature. Mechatronics, sensors, actuators, and controls. Crosslisted with EE A308.
Investigation and design of power and refrigeration cycles (Rankine, Brayton, Otto, and Diesel), compressible flow (isentropic, shock waves, and flow in ducts with friction), and combustion and gas vapor mixtures.
Investigation and design of power and refrigeration cycles (Rankine, Brayton, Otto, and Diesel), compressible flow (isentropic, shock waves, and flow in ducts with friction), and combustion and gas vapor mixtures.
Study and investigate the processing, structures, properties and performance of materials including metals, ceramics, polymers, and composites. Materials design and selection for engineering applications.
Study and investigate the processing, structures, properties and performance of materials including metals, ceramics, polymers, and composites. Materials design and selection for engineering applications.
Design and analysis of machines by analytical, experimental and computer methods. Identification of requirements and conceptual design of mechanical systems, detailed design of components, strength, life, reliability, and cost analysis.
Design and analysis of machines by analytical, experimental and computer methods. Identification of requirements and conceptual design of mechanical systems, detailed design of components, strength, life, reliability, and cost analysis.
Capstone course in which mechanical engineering students design a mechanical engineering component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Capstone course in which mechanical engineering students design a mechanical engineering component or system starting with the initial design specification to the implementation and testing. Students apply knowledge and skills learned in their undergraduate curriculum. Registration Restrictions: Student must be in senior year of BSE degree program or obtain faculty permission. Completion of GER Tier 1 (basic college-level skills) courses.
Advanced topics in fluid mechanics, including derivation of flow equations, ideal fluid flows, incompressible viscous flows and compressible inviscid flows. Special Note: Not available for credit to students who have completed ME A642. May be stacked with: ME A642
Advanced topics in fluid mechanics, including derivation of flow equations, ideal fluid flows, incompressible viscous flows and compressible inviscid flows. Special Note: Not available for credit to students who have completed ME A642. May be stacked with: ME A642
The study and design of renewable energy systems from a technical engineering standpoint. Solar, hydrokinetic, conventional hydroelectric, wind, geothermal, and biological energy systems will be examined. Additional topics include feasibility analysis and energy storage techniques. Special Note: Not available for credit to students who have completed ME A653. May be stacked with: ME A653
The study and design of renewable energy systems from a technical engineering standpoint. Solar, hydrokinetic, conventional hydroelectric, wind, geothermal, and biological energy systems will be examined. Additional topics include feasibility analysis and energy storage techniques. Special Note: Not available for credit to students who have completed ME A653. May be stacked with: ME A653
Design of thermal and heating, ventilation, and air-conditioning (HVAC) systems with emphasis on economic considerations and optimization. Concepts of thermodynamics, fluid mechanics and heat transfer will be integrated under a design framework. A semester long project is conducted to design a thermal system, perform system simulations, and to optimize the design based on economic and technical considerations. Special Note: Not available for credit to students who have completed ME A655. May be stacked with: ME A655
Design of thermal and heating, ventilation, and air-conditioning (HVAC) systems with emphasis on economic considerations and optimization. Concepts of thermodynamics, fluid mechanics and heat transfer will be integrated under a design framework. A semester long project is conducted to design a thermal system, perform system simulations, and to optimize the design based on economic and technical considerations. Special Note: Not available for credit to students who have completed ME A655. May be stacked with: ME A655
Design of thermal and heating, ventilation, and air-conditioning (HVAC) systems with emphasis on economic considerations and optimization. Concepts of thermodynamics, fluid mechanics and heat transfer will be integrated under a design framework. A semester long project is conducted to design a thermal system, perform system simulations, and to optimize the design based on economic and technical considerations. Special Note: Not available for credit to students who have completed ME A655. May be stacked with: ME A655
Advanced topics in fluid mechanics, including derivation of flow equations, ideal fluid flows, incompressible viscous flows and compressible inviscid flows. Special Note: Not available for credit to students who have completed ME A442. Registration Restrictions: Graduate standing or instructor permission. May be stacked with: ME A442
Advanced topics in fluid mechanics, including derivation of flow equations, ideal fluid flows, incompressible viscous flows and compressible inviscid flows. Special Note: Not available for credit to students who have completed ME A442. Registration Restrictions: Graduate standing or instructor permission. May be stacked with: ME A442
The study and design of renewable energy systems from a technical engineering standpoint. Solar, hydrokinetic, conventional hydroelectric, wind, geothermal, and biological energy systems will be examined. Additional topics include feasibility analysis and energy storage techniques. Special Note: Not available for credit to students who have completed ME A453. May be stacked with: ME A453
The study and design of renewable energy systems from a technical engineering standpoint. Solar, hydrokinetic, conventional hydroelectric, wind, geothermal, and biological energy systems will be examined. Additional topics include feasibility analysis and energy storage techniques. Special Note: Not available for credit to students who have completed ME A453. May be stacked with: ME A453
Design of thermal and heating, ventilation, and air-conditioning (HVAC) systems with emphasis on economic considerations and optimization. Concepts of thermodynamics, fluid mechanics and heat transfer will be integrated under a design framework. A semester long project is conducted to design a thermal system, perform system simulations, and to optimize the design based on economic and technical considerations. Special Note: Not available for credit to students who have completed ME A455. Registration Restrictions: Graduate standing or instructor permission. May be stacked with: ME A455
Design of thermal and heating, ventilation, and air-conditioning (HVAC) systems with emphasis on economic considerations and optimization. Concepts of thermodynamics, fluid mechanics and heat transfer will be integrated under a design framework. A semester long project is conducted to design a thermal system, perform system simulations, and to optimize the design based on economic and technical considerations. Special Note: Not available for credit to students who have completed ME A455. Registration Restrictions: Graduate standing or instructor permission. May be stacked with: ME A455
Design of thermal and heating, ventilation, and air-conditioning (HVAC) systems with emphasis on economic considerations and optimization. Concepts of thermodynamics, fluid mechanics and heat transfer will be integrated under a design framework. A semester long project is conducted to design a thermal system, perform system simulations, and to optimize the design based on economic and technical considerations. Special Note: Not available for credit to students who have completed ME A455. Registration Restrictions: Graduate standing or instructor permission. May be stacked with: ME A455
Current issues and topics related to project management including, but not limited to: Project Management Professional Certification preparation, Microsoft Project Software Training, Successful Project Management, Senior Project Management, Technical Project Management, and Managing Project Managers.
Current issues and topics related to project management including, but not limited to: Project Management Professional Certification preparation, Microsoft Project Software Training, Successful Project Management, Senior Project Management, Technical Project Management, and Managing Project Managers.
Current issues and topics related to project management including, but not limited to: Project Management Professional Certification preparation, Microsoft Project Software Training, Successful Project Management, Senior Project Management, Technical Project Management, and Managing Project Managers.
CRN: 40591 Section: 004 Date Range: 01/23-01/23 Section Title: Intro to Project Mgmt-DNR
Current issues and topics related to project management including, but not limited to: Project Management Professional Certification preparation, Microsoft Project Software Training, Successful Project Management, Senior Project Management, Technical Project Management, and Managing Project Managers.
CRN: 41525 Section: 006 Date Range: 04/10-04/11 Section Title: PM Using MS Project 2010
Current issues and topics related to project management including, but not limited to: Project Management Professional Certification preparation, Microsoft Project Software Training, Successful Project Management, Senior Project Management, Technical Project Management, and Managing Project Managers.
Current issues and topics related to project management including, but not limited to: Project Management Professional Certification preparation, Microsoft Project Software Training, Successful Project Management, Senior Project Management, Technical Project Management, and Managing Project Managers.
Fundamental concepts of project process, stakeholders and organization environment necessary for successful project management. Team-based term projects will be developed, discussed, and presented. Major project management software will be introduced. Registration Restrictions: Graduate level standing. Special Note: It is highly recommended that PM A601 be taken in the first semester.
Fundamental concepts of project process, stakeholders and organization environment necessary for successful project management. Team-based term projects will be developed, discussed, and presented. Major project management software will be introduced. Registration Restrictions: Graduate level standing. Special Note: It is highly recommended that PM A601 be taken in the first semester.
Fundamental concepts of project process, stakeholders and organization environment necessary for successful project management. Team-based term projects will be developed, discussed, and presented. Major project management software will be introduced. Registration Restrictions: Graduate level standing. Special Note: It is highly recommended that PM A601 be taken in the first semester.
Application of project management processes from project inception through closeout. Integration of project management processes in all nine Knowledge Areas through use of hands-on, end-to-end project case studies. Demonstrates mastery of project leadership, project requirements definition, stakeholder management, change control, schedule management, risk management, professional responsibility, effective communication and teamwork. Registration Restrictions: Graduate level standing and PM Department approval
Application of project management processes from project inception through closeout. Integration of project management processes in all nine Knowledge Areas through use of hands-on, end-to-end project case studies. Demonstrates mastery of project leadership, project requirements definition, stakeholder management, change control, schedule management, risk management, professional responsibility, effective communication and teamwork. Registration Restrictions: Graduate level standing and PM Department approval
Application of project management processes from project inception through closeout. Integration of project management processes in all nine Knowledge Areas through use of hands-on, end-to-end project case studies. Demonstrates mastery of project leadership, project requirements definition, stakeholder management, change control, schedule management, risk management, professional responsibility, effective communication and teamwork. Registration Restrictions: Graduate level standing and PM Department approval
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations when initiating and planning complex projects. Introduce tools, methods and critical issues associated with the initiation and planning of a project management plan. Students will function in teams and will be challenged with preparing and planning projects with real-world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations when initiating and planning complex projects. Introduce tools, methods and critical issues associated with the initiation and planning of a project management plan. Students will function in teams and will be challenged with preparing and planning projects with real-world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations when initiating and planning complex projects. Introduce tools, methods and critical issues associated with the initiation and planning of a project management plan. Students will function in teams and will be challenged with preparing and planning projects with real-world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations when in the executing, monitoring and controlling phases of basic and complex projects. Introduce tools, methods and critical issues associated with the execution, monitoring and controlling of a project management plan. Students will function as teams and will be challenged with monitoring and controlling projects with real world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations when in the executing, monitoring and controlling phases of basic and complex projects. Introduce tools, methods and critical issues associated with the execution, monitoring and controlling of a project management plan. Students will function as teams and will be challenged with monitoring and controlling projects with real world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations when in the executing, monitoring and controlling phases of basic and complex projects. Introduce tools, methods and critical issues associated with the execution, monitoring and controlling of a project management plan. Students will function as teams and will be challenged with monitoring and controlling projects with real world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations for operational integration and closure processes of complex projects. Introduce tools, methods and critical issues associated with the operation integration and closure processes of completing a project management plan. Students will function in teams and will be challenged with re-prioritizations and re-assignments projects across various industries with real-world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations for operational integration and closure processes of complex projects. Introduce tools, methods and critical issues associated with the operation integration and closure processes of completing a project management plan. Students will function in teams and will be challenged with re-prioritizations and re-assignments projects across various industries with real-world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Explore in depth Project Management (PM) Knowledge Areas, tools and techniques, and the necessary considerations for operational integration and closure processes of complex projects. Introduce tools, methods and critical issues associated with the operation integration and closure processes of completing a project management plan. Students will function in teams and will be challenged with re-prioritizations and re-assignments projects across various industries with real-world relevance. Registration Restrictions: PM Department approval and graduate level standing.
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Initiating, planning and research component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Demonstrates mastery of project management principles, processes, tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
A686BCapstone: Execute/Cntrl/Close
3.0
DaysTimeLocationInstructorOpen Seats
F03:30PM-5:30PMPiccard, L14
CRN: 38933 Section: 001 Date Range: 01/25-01/25
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Executing, controlling and closing component of a sponsored, student-selected and faculty-approved capstone project undertaken to research and/or contribute new concepts, tools and capabilities to address relevant project management challenges. Course results will demonstrate mastery of project management principles, processes, and tools/techniques and cumulative knowledge gained from prior coursework as specifically applied to project initiating and planning processes. Registration Restrictions: Graduate level standing and PM Department approval
Exploration of advanced issues, unique areas and specialized topics related to project management. Special Note: May be repeated with a change in subtitle. Registration Restrictions: Admission to the MSPM program or ESPM Department approval.
Exploration of advanced issues, unique areas and specialized topics related to project management. Special Note: May be repeated with a change in subtitle. Registration Restrictions: Admission to the MSPM program or ESPM Department approval.
Exploration of advanced issues, unique areas and specialized topics related to project management. Special Note: May be repeated with a change in subtitle. Registration Restrictions: Admission to the MSPM program or ESPM Department approval.
Explore the application tools widely used in project management areas and learn how to utilize them with ease. Registration Restrictions: ESPM Department approval
Explore the application tools widely used in project management areas and learn how to utilize them with ease. Registration Restrictions: ESPM Department approval
Explore the application tools widely used in project management areas and learn how to utilize them with ease. Registration Restrictions: ESPM Department approval
Provides students with opportunities to practice learned project management skills in a professional environment. Professional work experience designed to provide students with the opportunity to investigate the practical applications of project management within an organization. Assignments and projects arranged with cooperating organizations and agencies. Registration Restrictions: Graduate level standing and PM department approval.
Provides students with opportunities to practice learned project management skills in a professional environment. Professional work experience designed to provide students with the opportunity to investigate the practical applications of project management within an organization. Assignments and projects arranged with cooperating organizations and agencies. Registration Restrictions: Graduate level standing and PM department approval.
Provide Website Feedback
