EE 211: Circuits I - Intro to Electrical Engineering for Science & Engineering Students, Study notes of Electrical Engineering

Download EE 211: Circuits I - Intro to Electrical Engineering for Science & Engineering Students and more Study notes Electrical Engineering in PDF only on Docsity! College of Engineering EE Electrical Engineering KEY: # = new course * = course changed † = course dropped University of Kentucky 2012-2013 Undergraduate Bulletin 1 *EE 101 CREATIVITY AND DESIGN IN ELECTRICAL AND COMPUTER ENGINEERING. (3) This course provides an introduction to the process and application of creative design and problem solving within science and engineering. Emphasis is placed on applications and case studies in the areas of electrical and computer engineering. Several laboratory-based engineering problems are used to provide practical settings in which to apply and evaluate constraint- and product-focused strategies for creative design and problem solving. In addition to technical and aesthetic considerations, ethical and cultural influences on the creative process will also be discussed. EE 211 CIRCUITS I. (4) Fundamental laws, principles and analysis techniques for DC and AC linear circuits whose elements consist of passive and active components used in modern engineering practice including the determination of steady state and transient responses. Prereq: MA 114; prereq or concur: PHY 232, 242. EE 221 CIRCUITS II. (3) Analysis and design methods for analog linear circuits whose elements consist of passive and active components used in modern engineering practice, including transfer functions, network parameters, and a design project involving modern design practices. Prereq: EE 211. Concur: MA 214. EE 222 ELECTRICAL ENGINEERING LABORATORY I. (2) Laboratory exercises in the use of measuring instruments. Experiments in R-L-C circuit analysis. Lecture, one hour; laboratory, three hours. Prereq or concur: EE 221. EE 280 DESIGN OF LOGIC CIRCUITS. (3) Boolean algebra; combinational logic circuits; synchronous sequential circuits; asynchronous sequential circuits; design problems using standard integrated circuits. Prereq: CS 115. EE 281 LOGICAL DESIGN LABORATORY. (2) A laboratory involving the design and implementation of logic circuits. Combinational and sequential (both synchronous) design examples using small and medium scale integrated circuits. Lecture, one hour; laboratory, one three-hour session. Prereq: EE 280. EE 305 ELECTRICAL CIRCUITS AND ELECTRONICS. (3) A service course covering electrical engineering principles for engineering or science students with majors outside of electrical engineering. Topics include: circuits analysis, power, electronics, digital logic and instrumentation. Prereq: PHY 232, MA 114. EE 360 INTRODUCTION TO SEMICONDUCTOR DEVICES. (3) Electronic properties of solid-state materials and calculation of charge carriers in semiconductors; structure and physical model of p- n junctions and various diode devices, bipolar transistors, field effect transistors; semiconductor fabrication technologies and microelectronics manufacturing issues. Prereq: PHY 232 and CHE 105. EE 380 MICROCOMPUTER ORGANIZATION. (3) Hardware and software organization of a typical computer; machine language and assembler language programming, interfacing peripheral devices, and input-output programming; real-time computer applications, laboratory included. Prereq: EE 280 or CS 245. (Same as CS 380.) EE 383 INTRODUCTION TO EMBEDDED SYSTEMS. (3) A course in the hardware and software of microprocessors. Assembly language programming, address decoding, hardware interrupts, parallel and serial interfacing with various special purpose integrated circuits. Each student is expected to do homework assignments using microprocessor hardware. Prereq: EE 280 and EE/CS 380. (Same as CS 383.) EE 395 INDEPENDENT WORK IN ELECTRICAL ENGINEERING. (1-6) Special research and problems for individual students who are capable of pursuing independent investigations. May be repeated to a maximum of six credits. Prereq: Consent of instructor. College of Engineering EE Electrical Engineering KEY: # = new course * = course changed † = course dropped University of Kentucky 2012-2013 Undergraduate Bulletin 2 EE 402G ELECTRONIC INSTRUMENTATION AND MEASUREMENTS. (3) Elementary treatment of electronic circuits emphasizing laboratory work. Topics include AC circuits, filters, theory and operation of transistors and other semiconductor devices and a simple treatment of operational amplifiers. Lecture, two hours per week; laboratory, three hours per week. Prereq: PHY 242 or EE 305 or consent of instructor. (Same as PHY 402G.) EE 415G ELECTROMECHANICS. (3) Study of electric machines and electromechanical systems. Prereq: EE 221 with a C or better and PHY 232. EE 416G ENERGY CONVERSION LABORATORY. (2) Laboratory practice and experimental studies related to EE 415G. Lecture one hour; laboratory, three hours. Prereq or concur: EE 415G. EE 421G SIGNALS AND SYSTEMS. (3) An introduction to continuous and discrete signal and system models and analyses. Topics include discrete and continuous convolution, Fourier series, Fourier transforms, and Laplace transforms and Z-transforms with application examples including AM modulation and the sampling theorem. Prereq: MA 214 and a C or better in EE 221; coreq: MA 320. EE 422G SIGNALS AND SYSTEMS LABORATORY. (2) Lectures and laboratory exercises on signal and systems modeling. Topics include noise models and analysis, filter design, modulation techniques, sampling, discrete Fourier Transforms, State Variable Models, and feedback design with an emphasis on using computer software for analysis and simulation. Prereq: EE 421G, MA 320. EE 461G INTRODUCTION TO ELECTRONICS. (3) Analysis and design of electronic circuitry incorporating nonlinear electronic elements such as transistors, FET’s, and vacuum tubes. Applications to amplifiers. Prereq: A grade of C or better in EE 221. EE 462G ELECTRONIC CIRCUITS LABORATORY. (2) Experimental exercises in the design and analysis of useful electronic circuits incorporating semiconductor devices: transistors, tunnel and Zener diodes; also, vacuum tubes, integrated circuits and operational amplifiers. Lecture, one hour; laboratory, three hours. Prereq: EE 222; prereq or concur: EE 461G. EE 468G INTRODUCTION TO ENGINEERING ELECTROMAGNETICS. (4) Applications of electromagnetic theory; electrostatic and magnetostatic fields; Maxwell’s field equations; plane waves; transmission lines and waveguides; antennas and radiation. Prereq: MA 213; prereq or concur: EE 221. EE 480 ADVANCED COMPUTER ARCHITECTURE. (3) This course focuses on advanced computer architectures and low-level system software. Topics include RISC architectures, vector and multiprocessor architectures, multiprocessor memory architectures, and multiprocessor interconnection networks. Peripheral devices such as disk arrays, NICs, and video/audio devices are covered. Topics also include device drivers, interrupt processing, advanced assembly language programming techniques, assemblers, linkers, and loaders. Prereq: CS/EE 380. (Same as CS 480G.) EE 490 ELECTRICAL ENGINEERING CAPSTONE DESIGN I. (3) The first semester of a two-semester design sequence for senior students in electrical engineering with an emphasis on the engineering process. Topics important in product design and manufacturing are included, including considerations of economics, safety, and communication. Students are expected to formally propose a design project that includes a problem definition that incorporates engineering standards and realistic constraints. Students work in teams to develop and complete the designs. Lecture, two hours; laboratory, three hours per week. Prereq: Engineering standing and completion of all other required 400-level EE courses, excluding EE 491. EE 491 ELECTRICAL ENGINEERING CAPSTONE DESIGN II. (3) The second semester of a two-semester design sequence for senior students in electrical engineering with an emphasis on the engineering process. Students work in teams to develop and complete the designs. Topics to include engineering ethics, design, documentation, and communication. Prereq: EE 490 completed in the previous semester and Engineering standing. College of Engineering EE Electrical Engineering KEY: # = new course * = course changed † = course dropped University of Kentucky 2012-2013 Undergraduate Bulletin 5 EE 568 FIBER OPTICS. (3) The course presents theory and practice related to (a) fiber optic cable and their fabrication, (b) fiber optic transmitters and detectors, (c) fiber optic communication systems and (d) fiber optic remote sensors. Prereq: EE 468G. (Same as MSE 568.) EE 569 ELECTRONIC PACKAGING SYSTEMS AND MANUFACTURING PROCESSES. (3) Study of packaging systems which interconnect, support, power, cool, protect, and maintain electronic components. The course will address systems at the chip, board, and product levels. Topics include design, properties, materials, manufacture, and performance of various packaging systems. Laboratory will provide familiarity with design software and production equipment and processes. Prereq: EE 211 or EE 305, EE 360 or MSE 402G, or consent of instructor. (Same as MSE 569.) EE 570 FUNDAMENTALS OF NANOELECTRONIC DEVICES AND MATERIALS. (3) Energy bonds in crystals; heterostructures; quantum wells and low dimensional systems; the two-dimensional electron gas and MODFET; transmission in nanostructures; current topics in nanoscale devices. Prereq: EE 360 and engineering standing, or consent of instructor. (Same as ME/MSE 570.) EE 571 FEEDBACK CONTROL DESIGN. (3) System representation via transfer function and state variables, root locus analysis; Bode plots; compensation by root-locus and frequency response methods; state variable feedback; sensitivity analysis; tracking via output feedback; digital control systems. Prereq: EE 421G, EE 422G, engineering standing, and consent of instructor. EE 572 DIGITAL CONTROL OF DYNAMIC SYSTEMS. (3) Zero and first order hold, theory of analog to digital and digital to analog conversion. Z-transform analysis, discrete state variable analysis, discrete estimation techniques, error analysis of discrete systems. Prereq: EE 422G, engineering standing. EE 575 INDUSTRIAL CONTROL. (3) Control technologies for industrial and process control systems, including sensors, actuators, PLCs, and hydraulic and pneumatic control elements. Prereq: Engineering standing or graduate standing. EE 579 NEURAL ENGINEERING: MERGING ENGINEERING WITH NEUROSCIENCE. (3) A multidisciplinary approach combining engineering principles for systems analysis and control, knowledge of biological control mechanisms, and computational properties of biological neural networks in the development of engineering neural networks for control applications. Topics include: equivalent circuit models for biological neurons and networks, non-linear differential equation representations, biological control strategies for rhythmic movements, design and development of controller for robot function, proposal development and presentation. Prereq: EE 422G and Engineering Standing or consent of instructor. (Same as BME 579.) EE 581 ADVANCED LOGICAL DESIGN. (3) Medium-scale and large-scale digital components; register-transfers; bus-structures; controller/process organizations. Design of arithmetic processors and stored-program computers. Microprogramming. Prereq: EE 280 and EE/CS 380; engineering standing or upper division computer science standing. EE 582 HARDWARE DESCRIPTION LANGUAGES AND PROGRAMMABLE LOGIC. (3) A study of hardware description languages including netlists, VHDL and Verilog; their use in digital design methodologies including modeling techniques, design verification, simulation, synthesis, and implementation in programmable and fabricated logic media. Programmable logic topics include CPLD and FPGA architectures, programming technologies and techniques. Prereq: EE/CS 380 and engineering standing. EE 584 INTRODUCTION OF VLSI DESIGN AND TESTING. (3) Introduction to the design and layout of Very Large Scale Integrated (VLSI) Circuits for complex digital systems; fundamentals of the VLSI fabrication process; and introduction to VLSI testing and structured design for testability techniques. Prereq: Engineering standing and EE 360 or CS 215 or consent of instructor. College of Engineering EE Electrical Engineering KEY: # = new course * = course changed † = course dropped University of Kentucky 2012-2013 Undergraduate Bulletin 6 EE 585 FAULT TOLERANT COMPUTING. (3) Fault models in logic networks will be developed and then various testing techniques for detection of faults in logic networks will be discussed. Systematic approach for designing logic networks for testability will be introduced. Self testing and fault tolerant design of logic systems using coding theory will be covered. Prereq: EE 581 or consent of the instructor, engineering standing or upper division computer science standing. EE 586 COMMUNICATION AND SWITCHING NETWORKS. (3) Fundamentals of modern communication networking and telecommunications, data transmission, multiplexing, circuit switching networks, network topology routing and control, computer communication, packet switching networks, congestion control, frame relay, ATM switching networks, traffic and congestion control. Prereq: EE 280. EE 587 MICROCOMPUTER SYSTEMS DESIGN. (3) A course in the design of microcomputer systems for hardware engineers which includes the following topics: use of uncommitted logic arrays in instruction set design; hardware support for operating systems and programming languages; customizing microcomputers for specific execution environments; and control of concurrency. Prereq: EE 581 and EE 583, or consent of instructor. Engineering standing or upper division computer science standing. (Same as CS 587.) EE 588 REAL-TIME DIGITAL SYSTEMS. (3) This course will cover features typically found in real-time and embedded systems. Topics will include scheduling, synchronization, and architectural features of single and multiple processor real-time and embedded systems. Prereq: EE 380, C programming experience, engineering standing or upper division computer science standing, or consent of instructor. EE 589 ADVANCED VLSI. (3) An advanced class in topics related to Very Large Scale Integration. Example topics are advanced simulation, yield impact, memory design, statistical analysis and date reduction. Prereq: EE 584, engineering standing. EE 595 INDEPENDENT PROBLEMS. (1-3) For electrical engineers. A problem, approved by the chairperson of the department, provides an objective for study and research. May be repeated to a maximum of six credits. Prereq: 2.5 standing and engineering standing. EE 599 TOPICS IN ELECTRICAL ENGINEERING (Subtitle required). (2-3) A detailed investigation of a topic of current significance in electrical engineering such as biomedical instrumentation, digital filter design, active networks, advanced electrical devices, digital communications, display of electronics. May be repeated to a maximum of six credits, but only three credits can be earned under the same title. A particular topic may be offered at most twice under the EE 599 number. Prereq: Equivalent of two 400-level courses in electrical engineering, consent of instructor and engineering standing. PREREQUISITE FOR GRADUATE WORK: Students desiring to take any of the following courses should have a thorough working knowledge of chemistry, physics and mathematics. For major work, a candidate must hold a bachelor’s degree in electrical engineering or its equivalent. EE 601 ELECTROMAGNETIC ENERGY CONVERSION I. (3) Generalized electric machine theory; parameter determination. Energy conversion in continuous media including magnetohydrodynam- ics. Prereq: Consent of instructor. EE 603 POWER ELECTRONICS. (3) Study of solid-state power electronic devices and their applications in power conditioned electric motor drive systems. Examination of control philosophies, steady-state models, and numerical simulation of characterizing differential equations. Current topics of interest from the literature. Prereq: EE 517 and EE 571 or consent of instructor. EE 604 SWITCH MODE CONVERTERS. (3) Study of analysis techniques for switching mode converters and associated control practices. Boost, buck, buck-boost, flyback, and Cuk topologies in both continuous and discontinuous conduction modes are presented. Numerical solution, state-space averaging, and linearization techniques are applied to predict performance and formulate transfer characteristics. Prereq: EE 517 or consent of instructor. College of Engineering EE Electrical Engineering KEY: # = new course * = course changed † = course dropped University of Kentucky 2012-2013 Undergraduate Bulletin 7 EE 605 SYSTEMS FOR FACTORY INFORMATION AND CONTROL. (3) Systems approach to manufacturing. Hardware and software for real time control and reporting. Sensor and actuators, controllers, networks, databases, hierarchical and distributed control, CAD/CAM systems, flexible manufacturing systems, group technology, modeling and simulation of factory operations. Lecture, two hours; laboratory, two hours. Prereq: MFS 505. (Same as MFS 605.) EE 606 SEMINAR AND PROJECT IN MANUFACTURING SYSTEMS ENGINEERING. (3) A project course for manufacturing systems. Course consists of seminar presentations by outside professionals and faculty and a course project on a realistic manufacturing systems assignment. Lecture, two hours; laboratory, two hours. (Same as ME/MFS 606.) EE 611 DETERMINISTIC SYSTEMS. (3) Concepts of linear systems, singularity functions, convolution and superposition integrals, state-variable method for linear systems, relation between transfer function and state-variable equations, fundamental matrix, state-transition matrix, unit-impulse response matrix, and transmission matrix. Prereq: EE 421G. EE 613 OPTIMAL CONTROL THEORY. (3) State-space modeling of control systems; variational techniques; system optimization by maximum principle, dynamic programming; Hamilton-Jacobi equations design of linear optimal systems; computational methods for solving boundary value problems. Prereq: EE 611. EE 614 ADAPTIVE CONTROL. (3) Real-time parameter estimation; deterministic self-tuning regulators; stochastic and predictive self-tuning regulators; model-reference systems; auto-tuning; gain scheduling; practical issues; design and simulation projects. Prereq: EE 611. EE 619 PROBLEMS SEMINAR IN OPERATIONS RESEARCH. (3) In this course, the student is exposed to the art of applying the tools of operations research to real world problems. The seminar is generally conducted by a group of faculty members from the various disciplines to which operations research is applicable. Prereq: MA 617 and STA 525 or consent of instructor. EE 621 ELECTROMAGNETIC FIELDS. (3) Development of electromagnetic field theory from the basic postulates of Maxwell’s equations in differential and integral forms, solution to static, quasistatic, and wave-propagation problems. Radiation from dipole antenna elements. Prereq: EE 468G. EE 622 ADVANCED ELECTRODYNAMICS. (3) Solution methods for applied electrodynamics problems; uniqueness, equivalence, duality, reciprocity; linear space methods; wave solutions in separable coordinate systems; classical problems in cartesian, cylindrical, and spherical coordinates. Prereq: EE 468G. EE 624 COMPUTATIONAL ELECTROMAGNETICS: THE FINITE-DIFFERENCE TIME-DOMAIN. (3) A course on the application of the finite-difference time-domain (FDTD) technique for the full-wave simulation of time-dependent electromagnetic waves in complex media. Representative topics in the course include: The Yee-algorithm, numerical dispersion and stability, physical source models, absorbing boundaries and perfectly matched layered media, near-field to far-field transformations, modeling of microwave circuits and antennas, parameter extraction, lumped load models, non-uniform and non-orthogonal grid methods, and current topics in FDTD. Prereq: EE 621 or consent of instructor. EE 625 COMPUTATIONAL ELECTROMAGNETICS. (3) This advanced course in computational electromagnetics primarily covers moment method and finite element method solutions to scattering problems. Representative topics of the course include surface and volume equivalence principles, scattering by material cylinders, scattering by periodic structures and absorbing boundary condition models. Prereq: EE 525, EE 621, or consent of instructor. EE 630 DIGITAL SIGNAL PROCESSING. (3) An introductory treatment of the basic concepts of signal processing via time and frequency domain (Z-transform) methods and a survey of procedures for designing, implementing and using digital signal processors. Prereq: EE 512 or consent of instructor.