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AERONAUTICAL AND ASTRONAUTICAL ENGINEERING AAE 361 Introduction to Random Variables in Engineering Class 3 (3 cr.)
P: MATH 262. Events, sample space, probability, conditional probability, independence, random variables. Probability mass functions, density functions, and cumulative distribution functions. Derived probability density functions. Bernoulli, Poisson and normal processes.
Applications to engineering problems. Some fundamental limit theorems.
AAE 543 Continuum Mechanics I Class 3 (3 cr.)
P: CE 273 or equivalent. Introduction to Cartesian tensors. Basic principles of continuum mechanics: concepts of deformation, motion, stress and strain; conservation of mass, balance of momenta, continuum thermodynamics, and constitutive equations. Illustrative applications in elasticity, fluid dynamics, and viscoelasticity.
AAE S46 Introduction to Solid Mechanics Class 3 (3 cr.)
P: CE 273 or equivalent. The purpose ofthis course is to provide a broad survey ofthe subject matter of solid mechanics. Topics covered include Cartesian tensor notation, deformation,stress, balance laws, elastic and inelastic behavior of materials, two-and three-dimensional problems, and dynamics of solids.
CIVIL ENGINEERING CE 200 Fundamentals of Surveying Lab. 6 (2 cr.)
P: MATH 163. Basic surveying operations and computations; theories of errors and their analysis; fundamental concepts of horizontal, vertical and angular measurement; horizontal and vertical control systems; traverse computations; location of man-made structures; use of topographic maps.
CE 241 Hydraulics Class 2, Lab. 3 (3 cr.)
P: ME 270. Fluid properties; hydrostatics; kinematics and dynamics of fluid flows;
conservation of mass, energy and momentum; flows in pipes and open channels. Formal laboratory experiments.
CE 273 Mechanics of Materials Class 3 (3 cr.)
P: ME 270 or equivalent. AnalysiS of stress and strain; equations of equilibrium and compatibility; stress-strain laws; extension, torsion, and bending of bars; membrane theory of pressure vessels; elastic stability; selected topics.
CE 320 Construction Engineering and Management Class 3 (3 cr.)
P: MATH 261. An examination of the component parts of the construction industry;
organizational and functional considerations as related to a representative construction firm within this industry; and project management requirements for a representative construction project.
CE 362 Transportation Engineering Class 3 (3 cr.)
P: Junior standing. Functions of transportation. Technological and operating characteristics of transportation systems. The factors in design. Introduction to transportation planning.
CE 370 Water Resources Engineering Class 3 (3 cr.)
P: ME 310. Introduction to hydrology, water resources planning, irrigation, municipal and industrial water supply, hydraulic structures, including dams, spillways, open channels, and pressure conduits.
CE 372 Introductory Structural Analysis Class 4 (4 cr.)
P: CE 273. Analysis of statically determinate structures, including beams and trusses, influence lines and moving loads; statically indeterminate structures including application of moment area and virtual work methods and slope deflection and moment distribution for beams and frames.
CE 374 Structural Design I Class 4 (4 cr.)
P: CE 372. Introduction to the behavior of steel concrete and timber structures, the design of steel, concrete and timber structural members for tensile and compressive loads and their flexure and the behavior of selected structural systems.
CE 382 Soil Mechanics and Foundations Class 4 (4 cr.)
P: CE 273. Identification and classification of soils; engineering behaviors and properties of soils; including compaction, compressibility premeability and shearing resistance; the effect of these soil properties on the design of foundations.
CE 471 Advanced Structural Design Class 3 (3 cr.)
P: CE 374. The design of structural systems, including continuous span bridges, culverts, retaining walls, rigid frames, multi-level buildings, etc.
CE 472 Rigid Frames Class 3, (3 cr.)
P: CE 372. Basic procedures in analysis of rigid frames having members of constant or variable moment of inertia; method of angle changes, slope deflection, and column analogy. Design of rigid frame structures.
CE 497 Civil Engineering Projects Hours and credits to be arranged.
CE 498 Civil Engineering Design Project (3 cr.)
P: CE 372. Planning, design, and analysis of a civil project; integrated and realistic group project involves as much as possible all major aspects of the civil engineering profession.
CE 510 Urban Planning Administration Class 3 (3 cr.)
P: CE 512. The role of planners and planning administration within the context of government and urban politics; an exploration of the decision-making process in planning; the practical aspects of administering planning functions and planning offices at the federal, state, regional, local, and consultant levels.
CE 511 History of Urban Planning and Urban Design Class 3 (3 cr.)
A study of the layout and physical development of cities from ancient times to present day with reference to changing concepts of pattern and form, political and social relationships, and functions. The study includes early Greek and Roman cities, early American and European contributions, the Garden City movement, British new towns, planners and their theories, and examples of planned twentieth-century cities.
CE 512 Introduction to Comprehensive Urban Planning Class 3 (3 cr.)
An introductory course which provides a framework for better understanding of the current urban planning process. Concepts and emerging trends are covered as well as an introduction into methods and techniques.
CE 551 Environmental Engineering and Administration Class 3 (3 cr.)
Engineering and administrative functions in the control of environmental factors affecting man's health and survival.
CE 557 Air Pollution - Effects and Control Class 3 (3 cr.)
P: CE 241 or equivalent. Definition of ambient and in-plant air pollution problems.
Discussion of the legal aspects including federal and state regulations and agency procedures meteorological fundamentals including transport and dispersion of pollutants. Urban planning considerations and pollutant dispersion in cities. Biological effects on materials, plants, and humans. Mobile sources including auto, truck, aircraft, and control techniques. Discussion of systems for industrial air pollution control. Discussion of odor measurement and control.
CE 574 Introduction to Structural Reliability Class 3 (3 cr.)
P: MATH 261 and CE 372 or consent of instructor. Elements of probability theory and its application to structural engineering; statistical distributions of load; probable strength of structural elements and machine parts; safety analysis and reliability prediction of structural and mechanical systems; reliability-based designs.
CE 577 Theory of Plates Class 3 (3 cr.)
P: MATH 262 or equivalent. Analysis of circular, rectangular, and continuous plates by classical, numerical and approximate methods.
ELECTRICAL ENGINEERING EE 201 linear Circuit Analysis I Class 3 (3 cr.)
P or corequisites: MATH 261. Volt-ampere characteristics for circuit elements; independent and dependent sources; Kirchhoff's laws and circuit equations. Source transformations;
Thevenin's and Norton's theorems; superposition. Transient response of RC, Rl, and RlC circuits.
Sinusiodal steady-state and impedance. Instantaneous and average power. (Students enrolling in EE 201 should enroll concurrently in EE 207.)
EE 202 Linear Circuit Analysis II Class 3 (3 cr.)
P: EE 201. Continuation of EE 201. Use of computer-aided design programs. Bode diagrams, complex plane, resonance, and coupled circuits. Two-port network parameters. Fourier series.
State variable formulation.
EE 207 Electronic Measurement Techniques lab. 3 (1 cr.)
P or corequisite: EE 201. Experimental exercises in the use of laboratory instruments, device characteristics, waveform analysis, frequency and transient response, and transistor circuits.
EE 208 Electronic Deyices and DesilJllLaboratory lab. 3 (1 cr.)
P: EE 207. Corequisite: EE 255. laboratory experiments in the measurement of electronic device characteristics. Design of biasing networks, smafl-signal amplifiers and switching circuits.
EE 255 Introduction to Electronics Analysis and Design Class 3 (3 cr.)
P: EE 201. Diode, bipolar transistor and fET circuit models for the design and analYSis of electronic circuits. Single and multistage analysis and design. Computer aided design calculations, amplifier operating point design, frequency response and Bode plots. Switching of the transistor from saturation to cut-off, charge control concepts, logicfamilies and gates. (Students enrolling in EE 255 are encouraged to enroll concurrently in EE 206.)
EE 261 Digital Systems Design I Class 3 (3 cr.)
P or corequisite: EE 201 or consent of instructor. Introduction to logic design. Topics include binary and decimal arithmetic, binary codes, basic digital devices, logic design using state machines, read-only memory implementation of digital machines, linked-state machines, and analog/digital conversion. (Students enrolling in EE 261 are encouraged to enroll concurrently in EE 267.)
EE 267 Introductory Digital Subsystems Laboratory lab. 3 (1 cr.)
P or corequisite: EE 261. laboratory experiments designed to follow EE 261 course material requiring the design and implementation of a variety of digital logic circuits ranging from simple combinational logic circuits to complex sequential logiC circuits utilizing integrated circuit counters, shift registers and binary arithmetic elements.
EE 301 Signals and Systems Class 4 (4 cr.)
P: EE 201 and MATH 262. Description of deterministic signals through the use of fourier Series, fourier, laplace, and Z-Transforms. System description treated by differential and difference equations including transform methods. Computation of system response to both continuous and discrete inputs.
EE 302 Probabilistic Methods in Electrical Engineering Class 3 (3 cr.)
P: MATH 262; P or corequisite: EE 301. An introductory treatment of probability theory including distribution and density functions, moments and random variables. Applications of normal and exponential distributions. Estimation of means, variances, correlation and spectral density functions. Random processes and response of linear systems to random inputs.
EE 311 Electric and Magnetic Fields Class 3 (3 cr.)
P: MATH 262 and PHYS 251. Continued study of vector calculus, electrostatics, and magnetostatics. Maxwell's equations, introduction to electro-magnetic waves, transmission lines, and radiation from antennas. (Students may not receive credit for EE 311 and PHYS 330.)
EE 321 Introduction to Electric Energy Englneerlns Class 3 (3 cr.)
P: EE 202; P or corequisite: EE 311. Energy needs and sources, transformers, electro- mechanical and non-conventional energy conversion, transmission, power systems character- istics.
EE 350 Non Linear Circuits and Deyices Laboratory Class 1, lab. 2 (2 cr.)
P: EE 206, EE 255. laboratory exercises in application of modern devices, nonlinear synthesis and first-order nonlinear networks.
EE 360 Microprocessor Applications Laboratory lab. 3 (1 cr.)
P or C: EE 361, laboratory experiments in the design and implementation of microcomputer system hardware and software. Interface devices such as UART's, PIA's and 0/ A converters are
studied in a variety of applications, including microcomputer input/output, data transfer, data conversion, man-machine interface and real-time control. A design project illustrates overall system design.
EE 361 Microcomputer System Design and Applications Class 3 (3 cr.)
P: ENGR 109 or equivalent, EE 301 and EE 261. Introduction to digital system design at the register transfer level: design incorporating register transfer modules, microprocessors, memory devices and other MSI and LSI circuits; applications to digital interface and instrumentation, waveform generators and analyzers, signal processing, special purpose stored program computers; case studies in engineering applications of digital systems.
EE 369 Introduction to Finite-State Machines Class 3 (3 cr.)
P: EE 261. Introduction to finite-state machines and discrete mathematical structures. Topics include foundation of discrete mathematics,groups and semi-groups, counting and enumeration, applications of Boolean algebra and group theory to computer design, group codes in computer systems, basic models of finite-state machines, state and machine identification experiments, regular expressions and machine specification.
EE 402 Semiconductor Devices and Circuit Models Class 4 (4 cr.)
P: EE 311 and PHYS 342. Conduction processes in solids. The operation of solid state devices is analyzed from a microscopic and equivalent circuit point of view.
EE 425 Elements of Electro-mechanical Enel'lY Conversion Class 3 (3 cr.)
P: 301 and EE 311; or EE 321. Basic principles of electromechanical energy conversion and modern aspects of dynamic circuit theory including the concept of the arbitrary reference frame.
Elementary induction, synchronous, and direct current machines are analyzed.
EE 432 Elements of Power System Engineering Class 3 (3 cr.)
P: EE 321 or consent of instructor. Fundamental concepts and operation consideration of power systems, basic component model representations, steady state performance, operating strategies, and control of power systems.
EE 440 Transmission of Information Class 3 Lab. 3 (4 cr.)
P: EE 301 and EE 302. Applications of the principles of signal analysis to amplitude, phase, and frequency modulation systems. Behavior of receivers in the presence of noise. Pulse code modulation and multiplex systems. Emphasis on engineering applications of theory to communication system design.
EE 446 Digital Computational Techniques for Electronic Circuits Class 3 (3 cr.)
P: EE 202 and EE 255. Algorithmic and computational aspects of electronic circuit analysis, both linear and nonlinear. Numerical methods such as Newton-Raphson and various integration formulas. Sparse matrices and implicit integration techniques. Worst case and tolerance analysis.
EE 4SS Splid State Circuit Analysis and Design I Class 3 (3 cr.)
P: EE 202 and EE 255. P or corequisite EE 402. Analysis and design of circuitry containing both discrete and integrated solid state elements. Applications involving bipolar and field effect transistors, diodes, electro-optic devices, and thermal components. Emphasis is on the design engineer's approach to electronic circuit problems.
EE 482 Automatic Control Systems Class 3 (3 cr.)
P or corequisite: ME 340. Component and system transfer functions. Transient response to deterministic inputs and definition of time domain specifications. Open and dosed loop frequency response. Bode diagrams, Nyquist diagrams, root locus, and frequency specifications.
Stability and relative stability criteria. Introduction to synthesis.
EE 491 Engineering Design Project (1-2 cr.)
P: Senior standing and consent of a faculty sponsor. The student selects an engineering design project and works under the direction of the faculty sponsor. Suitable projects may be from the local industrial, municipal, state and educational communities. May be repeated for a maximum of four credits.
EE S181ntroduction to Automatic Control Systems Class 3 (3 cr.)
P: Graduate standing (for nonelectrical engineering majors). Mathematical modeling of a system. Linear systems analysiS in the time and frequency domains. State variables and transfer functions. Stability, controllability, and observability. Feedback control design techniques.
Equalizer synthesis on Bode-Nyquist and root-locus diagrams. Analytic design and parameter optimization techniques.
EE 519 Control Theory II Class 3 (3 cr.)
P: EE 518 (for nonelectrical engineering majors). The approximation of common nonlinearities by describing functions and the analysis of resultant system behavior. Review of matrix analysis. State-space formulation, solution and design. Introduction to optimization and computational methods.
EE 532 Computational Methods for Power System Analysis Class 3 (3 cr.)
P: EE 432 or consent of instructor. System, modeling and matrix analysis of three-phase power networks. Applications of numerical methods and computers to the solution of a variety of problems related to the planning, design and operation of electric power systems.
EE 543 Disital Tec:hniques in Spectral Analysis. Estimation. and Filtering Class 3 (3 cr.) P: EE 302. Practical techniques for the analysis of discrete-time signals and sampled continuous-time Signals. Characterization of deterministic and random discrete-time signals, discrete Fourier transform, spectral analysis and correlation function estimation, periodograms and window functions, optimum detection algorithms, maximum likelihood and Bayes estimation, Kalman filtering.
EE 554 Electronic Instrumentation and Control Orcuits Class 3 (3 cr.)
P: Senior standing. Analysis and design of special amplifiers, pulse circuits, operational circuits, DC amplifiers, and transducers used in instrumentation, control, and computation.
EE 595 Selected Topics in Electrical Engineering Hours and credits to be arranged.
EE 600 Random Variables and Signals Class 3 (3 cr.)
P: EE 440, EE 602 or EE 302 or graduate standing. Engineering applications of probability theory. Problems of events, independence, random variables, distribution and density functions, expectations, and characteristic functions. Dependence, correlation, and regression; multi- variate Gaussian distribution. Stochastic processes, stationary, ergodicity, correlation functions, spectral densities, random inputs to linear systems; Gaussian processes.
EE 602 Lumped System Theory Class 3 (3 cr.)
P: EE 440, EE 482 or graduate standing. Basic methods of modern system theory. Time domain techniques for both linear and nonlinear systems. Characterization of both continuous and descrete-time linear systems in the time and frequency domains. Energy relationships and the restriction that positive energy storage places on physical systems.
EE 604 Electromagnetic Reid Theory Class 3 (3 cr.)
P: EE 311 or graduate standing. Review of general concepts, (Maxwell's equations, materials interaction, boundary conditions, energy flow), statics (laPlace's equation, Poisson's equation, mapping), distributed parameter systems (classification of solutions, transmission lines and waveguide), radiation and antennas (arrays, rec:iprocity, Huygen's principle), a selected special topic (e.g., quantum electronics, plasmas, coupled modes, relativity).
EE 606 Solid State and Magnetic Devices Class 3 (3 cr.)
P: Senior or graduate standing. A brief introduction to the theory of solids which is followed by the formulation of the equations for semiconductor devices. The P-N junction theory is formulated and solved for several different conditions illustrating a number of devices. The tunnel diode is studied as an example of tunneling. The transistor is presented with emphasiS on microwave, power, switching. The SCR is studied in detail as well as the IFET. Other devices include the IGFET, charge-coupled, Schottky diode, I-C fabrication. Magnetic materials and devices are presented.
EE 608 Foundations of Computer Engineering Class 3 (3 cr.)
P: EE 369, or graduate standing. Mini and micro computer organization including hard wired and micro programmed control units, interfacing requirements (software and hardware), using interrupt, automatic priority interrupt and direct memory access input/output systems. Data structures, including linked lists and binary trees, sorting and tree searching algorithms, Hashing.
Finite state machine models, decomposition of sequential machines, initial and terminal state identification and machine identification.
EE 650 Topics In Solid State Deyices and Materials Class 3 (3 cr.)
Class3 (five weeks). 1 cr. Admission by consent of instructor. (May be repeated for credit.) An introductory treatment of selected device and materials related topics. Topics will change from semester to semester and will be announced in advance. The list of possible topics includes solid state microwave deVices, opto-electronics, laser-quantum electronics, magnetics, noise in semiconductor devices, acoustic wave devices, energy conversion, device fabrication, electroceramics, MOS deVices, thin-film devices and memory devices.
EE 654 Deyice Related Semlcondoctor Phenomena Class 3 (3 cr.)
P: EE 606. Detailed examination and sample device application of semiconductor phenomena central to semiconductor device operation. Topics covered will be temperature dependence of fundamental parameters, recombination-generation statistics, noise, photo phenomena, and radiation effects.
EE 674 Topological Methods of Network Analysis Class 3 (3 cr.)
P: EE 301 or graduate standing. Fundamentals of graph theory. Signal flow graph method of circuit and system analysis. Network equilibrium equations in explicit form. Formulation of state equations. Topological formulas for network functions. The maximum flow problem. Network reliability analysis.
EE 680 Introdoctlon to Modern Control Theory Class 3 (3 cr.)
P: EE 602 or 583. Discussion of basic theoretical methods in modern control theory. Topics include parameter optimization techniques, maximum principle and dynamic programming approaches to optimal control problems, second variation techniques and sufficient conditions, singular control and introduction to adaptive control.
EE 697 Selected Topics in Electrical Englneerins Hours and credits to be arranged.
GENERAL ENGINEERING ENGR 100 Freshman Engineerins Lectures Class 1 (1 cr.) An introduction to the engineering profession.
ENGR 109 Introduction to Computer Programmlns Class 2 (2 cr.)
An introduction to Fortran programming for engineering freshmen with some emphasis on solutions to engineering problems.
ENGR 190 Bementary Englneerlns Design Class 2, lab. 2 (3 cr.) An introduction to engineering design.
ENGR 196 Enslneering Problem SolYins Class 3 (3 cr.)
Corequisite: MATH 163. Introduction to and practice in the use of mathematics in engineering, computer programming, model building, n~merical and dimensional analysis, application of vector and linear algebra and graphical solutions.
ENGR 200 Engineering Industrial Practice I (5 cr.)
P: Sophomore standing and prior acceptance into the cooperative program. Permission of the Faculty Co-op Advisor. An initial engineering cooperative assignment with a participating industrial employer accompanied by written reports as assigned.
ENGR 250 Ensineering Industrial Practice" (5 cr.)
P: Permission of the Faculty Co-op Advisor. For students on engineering cooperative assignment.
ENGR 1OO Engineering Industrial Practice III (5 cr.)
P: Permission of the Faculty Co-op Advisor. For students on engineering cooperative assignment.
ENGR J09 The Practice of Engineering Class 3 (3 cr.)
Professional ethics, engineering opportunities, job application and evaluation, government regulation and business law, engineering economics and management.
ENCR 3SO Engineering Industrial Practice IV (5 cr.)
P: Permission of the Faculty Co-op Advisor. For students on engineering cooperative assignment.
ENCR 400 Engineering Industrial Practice V (5 cr.)
P: Permission of the Faculty Co-op Advisor. For students on engineering cooperative assignment.
INDUSTRIAL ENGINEERING
IE 270 Manufacturing Processes Class 1, lab. 2 (2 cr.)
Fundamentals of the principal manufacturing processes, materials and material testing.
Manufacturing process planning, and economic factors. Experimental turning, drilling, milling, grinding, and other laboratory work in the areas of foundry, heat treatment, material testing and metrology.
IE 356 Human Factors in Engineering Design Class 3 (3 cr.)
P : STAT 511. Engineering design and analysis of man-machine systems. Study of man's input, output, and processing subsystems. Measurement of human factors. Environmental and task considerations in the design and performance of total systems.
IE 530 Quality Control Class 3 (3 cr.)
P; STAT 511 or equivalent. Principles and practices of quality control in industry;
administrative and engineering aspects of quality control programs; introduction to statistical quality control.
IE 532 Reliability Class 3 (3 cr.)
P: STAT 511 or equivalent. Reliability of components and multicomponent systems.
Application of quantitative methods to the design and evaluation of engineering and industrial systems and of processes for assuring reliability of performance. Economic and manufacturing control activities related to product engineering aspects of reliability. Principles of maintainability.
Product failure and legal liability.
IE 533 Research Design and Analysis Class 3 (3 cr.)
P: STAT 511 or equivalent. Procedure for the effective planning, design and analysis of experimental research studies of industrial problems in order to optimize utilization of experimental equipmer.t and resources. Interpretation of research results using univariate statistical analysis techniques.
IE 535 Mathematical Programming of Industrial Problems Class 3 (3 cr.)
P: consent of instructor. Development of analytical techniques for the solution of engineering and economic problems. Construction of mathematical models, with emphasis on linear models and linear programming.
IE 536 Operations Research Class 3 (3 cr.)
P; STAT 511, IE 543 or consent of instructor. (Not available to students with credit in IE 336.) An introduction to the literature and methodology of operations research (exclusive of linear programming). Applications to process design, inventory and production control, scheduling, waiting-line and replacement problems.
IE 543 Manufacturing Analysis Class 3 (3 cr.)
P: Senior standing. Organization for production, manufacturing processes, process design, production control, forecasting, inventory control, estimating, data processing and system designing.
IE 544 Manufacturing Management Class 3 (3 cr.)
P: Senior standing. Work methods and measurement, job evaluation, and fundamentals of engineering economy and accounting as applied to manufacturing.
IE 545 Engineering Economic Analysis Class 3 (3 cr.)
Analysis of engineering costs and capital investments. Applications of classical optimization, mathematical programming, the theory of the firm, and the theory of production to the analysis of investment proposals. Evaluation and selection of individual projects and formulation of capital investment programs.