Electrical Engineering (E E)
Note: Students may be expected to purchase supplementary materials for senior
projects and special topic laboratory and activity classes.
1. Introduction to Electrical Engineering (1)
The electrical engineering profession and its career opportunities; engineering
professionalism and ethics; ethics case studies, engineering code of ethics;
introduction to engineering problem solving.
70. Fortran 77 Programming (2)
Prerequisites: algebra; trigonometry. Flow charting, program structure,
computation and arithmetic functions, input-output, transfer of control,
looping, subscripted variables, subprograms, file processing, printer plotting
techniques, terminal and batch processing procedures. (Computer lab fee,
$15)
71. Engineering Computations (3)
Prerequisites: algebra; trigonometry. Use of Pascal and Fortran 77 in engineering
analysis and/or design. A systematic development in program structure, specification,
documentation, testing, and debugging. Cannot be taken for credit if E E
70 has been taken previously. (Computer lab fee, $15)
85. Digital Logic Design (3)
Boolean algebra. Logic gates, number systems, combinatorial logic, minimization
techniques, binary arithmetic. Analysis and design of combinatorial circuits.
Flipflops, multivibrators, registers, and counters. Introduction to sequential
circuits and state machines. Synchronous state machine design.
85L. Digital Logic Design Laboratory (1)
Corequisite: E E 85. Usage, design, and implementation techniques for combinatorial
and sequential circuits. Experiments utilizing logic gates, Karnaugh maps,
multiplexers, decoders, program mable logic devices, latches, flipflops,
counters and shift registers. Combinatorial and state machine design projects.
Computer Assisted Engineering (CAE).
90. Principles of Electrical Circuits (3)
Prerequisites: E E 70 or 71 or C Sci 40; Phys 4B; Math 81 or concurrently.
Direct-current circuit analysis; circuit theorems; transient phenomena in
RLC circuits, phasor concept; sinusoidal steady -state response; power and
RMS calculations in single-phase and polyphase alternating-current circuits;
principles of electrical instruments; computer solutions.
90L. Principles of Electrical Circuits Laboratory (1)
Prerequisite: E E 90 or concurrently. Experiments on direct- and alternating-
current circuits, including single-phase and polyphase systems. Use of electrical
instruments, development of laboratory techniques, and verification of basic
principles. (3 lab hours)
106. Switching Theory and Logical Design (3)
Prerequisite: E E 85 or equivalent. Quine-McCluskey minimization; switching
functions; finite and nonfinite state machines; state assignments; synchronous
and asynchronous machines; incompletely specified sequential circuits; pulse-mode
circuits.
107. Digital Signal Processing (3)
Prerequisites: E E 71 or C Sci 40; E E 85, 124. Data acquisition by computers,
numerical evaluation of Fourier transforms, A/D and D/A conversion, digital
filter design, programming, and emulation of a popular digital signal processor.
114. Physical Electronics (3)
Prerequisites: Phys 4C. Electronic structure of metals, semiconductors and
insulators; energy band structure, modern semiconductor devices such as
p-n junction semiconductors, bipolar and field-effect transistors, integrated
and optoelectronic devices.
116. Microprocessor Architecture and Programming (2)
Prerequisite: E E 71 or C Sci 40; E E 85. Architecture and programming
models of a microprocessor. Assembly Language program specification, development,
testing and documentation.
119. Principles of Computer Architecture (2)
Prerequisite: E E 85, 116. Structural organization, hardware architecture
and design of digital computer systems; number systems and binary representation
of data and binary arithmetic; hardware/software design trade-offs; comparisons
of computer architectures. Introduction to microcomputers.
119L. Principles of Computer Architecture Design Laboratory (1)
Corequisite: E E 119. Experiments on computer architecture and peripheral
equipment; laboratory synthesis of combination and sequential logic circuits
for interfacing.
121. Electromechanical Systems and Energy Conversion (3)
Prerequisites: E E 90, 90L. Principles of direct- and alternating-current
machinery and other energy-conversion devices and associated apparatus.
121L. Electromechanical Systems
and Energy Conversion Laboratory (1)
Corequisite: E E 121. Experiments and computations on direct- and alternating-current
machinery and on other energy- conversion devices and associated apparatus.
(3 lab hours) (
124. Linear Electric Circuit and Systems Analysis (3)
Prerequisites: E E 90, 90L. Operational analysis of discrete and continuous
linear circuits and systems: Z-transforms, Fourier transforms; Fourier series;
state-space representations, computer -aided solutions.
126. Electromagnetic Theory and Applications I (3)
Prerequisite: E E 90 or concurrently. Electrostatics; boundary value problems;
magnetostatics; time -varying fields; Maxwell's equations.
128. Electronics I (3)
Prerequisite: E E 90 or concurrently. Characteristics and properties of
solid state devices; theory and analysis of electronic circuits; power supply
design; device and circuit models; single- and multi-stage amplifier analysis
and design; feedback amplifiers; computer solutions as appropriate.
128L. Electronics I Laboratory (1)
Prerequisite: E E 128 or concurrently. Experiments on static and dynamic
characteristics of solid state devices and electronic circuits; computer
solutions as appropriate. (3 lab hours)
132. Design of Digital Systems (3)
Prerequisites: E E 115, 118. Design of Digital Systems utilizing microprocessors;
application of assembly programming language to input/output programming,
interrupts and traps, DMA and memory management.
134. Communication Engineering (3)
Prerequisite: E E 124. Mathematical modeling of signals and noise; informational
theory; analog and digital communication theory; radar and satellite link
system design; system noise temperature modeling; project design to pre-established
specifications.
136. Electromagnetic Theory and Applications II (3)
Prerequisite: E E 126. Plane wave propagation and reflection; transmission
of electromagnetic energy over wires at power and communication frequencies;
waveguide; antenna analysis and design; methods for computer solution.
136L. Electromagnetic Theory and Applications Laboratory (1)
Corequisite: E E 136. Experiments on the transmission of electromagnetic
energy through wires, wave guides, and space; filters and antennas; impedance
matching; cross-over networks; location of faults on lines. (3 lab hours)
138. Electronics II (3)
Prerequisites: E E 124, 128, 128L. Analysis and design of high frequency
and power amplifiers; dc and operational amplifiers; LC and crystal oscillators,
modulators and demodulators for communica tions; active filters. Emphasis
on modern design methods including applications of active integrated circuits.
138L. Electronics II Laboratory (1)
Corequisite: E E 138. Design oriented experiments to study the characteristics,
limitations, and design trade-offs of circuits from E E 138. Emphasis on
circuit and system design to meet preestablished specifications. Design
project included; computer solutions as appropriate. (3 lab hours)
140. VLSI Circuit and System Design (3)
Prerequisites: E E 85, 114, 124 (or concurrently), 128, 128L. Design and
analysis of LSI/VLSI chips, circuits, and systems; logic and mask designs
for bipolar, MOS, and CMOS logic families; ROM and RAM memories: CAD/CAM,
full-custom, and semi-custom design approaches; IC layout rules.
144. Integrated Circuit Design and Fabrication (3)
Prerequisite: E E 114. Diffusion and ion implantation processes in silicon
device fabrication; the planar process; CVD methodology in GaAs devices;
design layout rules; impurity profile shaping, measurement, and its relationship
to device performance; laboratory measurement and characterization techniques
for ICs; laboratory demonstrations.
146. Computer Networking and Distributed Processing (3)
Prerequisites: E E 115, 118. Analysis and design of modern computer networks.
Topics to be introduced include routing flow and congestion control, packet,
message and circuit switching, and recover. Examples of current implemented
networks and network architectures.
148. Analysis and Design of Digital Circuits (3)
Prerequisites: E E 85, 128. Analysis and design of solid state digital circuits
utilizing various logic families suitable for integration: TTL, ECL, NMOS,
CMOS; logic gates; multivibrators; ROM, PROM, EPROM, and EEPROM; SRAM and
DRAM; PLDs, Gate Arrays, and other digital ASICs.
151. Electrical Power Systems (3)
Prerequisites: E E 121, 121L (or concurrently). Power system networks and
equipment, steady-state operation, short-circuit analysis, power system
stability analysis by digital computation, synchronous generator excitation
and governor systems, system load representation, numerical analysis techniques.
(
152. Symmetrical Components and Short Circuit Analysis (3)
Prerequisites: E E 121, 121L (or concurrently). Theory of symmetrical components
and their use in power systems analysis; sequence impedances of system components;
applications in fault calculations.
153. Electromechanical Energy Conversion Machines and Devices (3)
Prerequisite: E E 121, 121L (or concurrently). Processes of electromechanical
energy conversion, modeling at rotating machines. computer-aided steady
state analysis at direct-current and alternating-current machines; special
purpose devices; single-phase induction machines, linear machines; stepper
motors; solid state motor control. Emphasis on current development and design
procedures.
155. Control Systems (3)
Prerequisites: E E 124. Analysis, design, and synthesis of linear control
systems; modeling, performance evaluation, frequency response, and stability.
162. Analog Integrated Circuits and Applications (3)
Prerequisite: E E 138. Analysis of monolithic operational amplifiers; case
studies; Widlar and Wilson current sources; linear and non-linear applications;
multipliers, phase-lock loops, phase detectors; higher order active filters;
all-pass equalizers; D/A and A/D converters; oscillators, function generators;
mixers, modulators, regulators; system design.
166. Microwave Devices and Circuits Design (3)
Prerequisite: E E 136. Microwave theory and techniques: slow-wave structures,
S parameters, and microwave devices, including solid-state devices including
klystrons, reflex klystrons, traveling-wave tubes, magnetrons and gyrotrons.
168. Microwave Amplifier and Oscillator Design (3)
Prerequisite: E E 136. Small-signal and large-signal amplifier designs such
as high-gain, high -power, low-noise, narrow-band and broadband amplifiers;
microwave oscillator designs such as high-power, broadband, Gunndiode and
IMPATT oscillator designs; power combining and dividing techniques; reflection
amplifier design and microwave measurements.
171. Quantum Electronics (3)
Prerequisite: E E 126. Review of wave properties; cavity mode theory; radiation
laws; theory and morphology of lasers; laser and fiber-optic communications;
designs of optical communication systems and components.
172. Sequential Machine and Automata Theory (3)
Prerequisite: E E 106. Structure of sequential machines; covers; partitions;
decompositions and synthesis of multiple machines. State identification
and fault detection experiments; memory characteristics of finite automata.
173. Digital Controls and Robotics (3)
Prerequisites: E E 85, 121, 124. Introduction to digital controls; development
and classification of robots; components and operation of robots, types
of sensors; vision sensors; artificial intelligence; classroom demonstrations
and practice with a robot.
174. Comparative Microcomputer Architecture (3)
Prerequisites: E E 119. Advanced microcomputer concepts including pipelining,
memory cache, virtual memory, and Op Code encoding. Detailed studies of
several contemporary microprocessors including their utilization in computer
systems. (Former E E 120)
176. Computer-Aided Circuit Design (3)
Prerequisites: E E 124, 128, 128L. Computer simulation of analog circuits.
Computer-aided engineering of digital circuits including schematic capture
and logic simulation. Computer-aided design of application specific integrated
circuits including programmable logic devices, gate arrays, and standard
cell devices.
180. Senior Project (2)
Prerequisites: senior standing in computer engineering or permission
of instructor; I E 182W or concurrently; approved subject. Study of a problem
under supervision of faculty member; final typewritten report required.
Individual project except by special permission. When taken in addition
to E E 183A, B, C, or D, this course satisfies the senior major requirement
for the B.S. in Electrical Engineering.
183A. Electronic Circuits and Electrical Networks Laboratory (1)
Prerequisites: E E 124, 138, 138L. Signal measurement and analysis techniques
for communication networks; discrete, hybrid, and integrated electronic
circuit design and testing; analog and digital filter realization; computer-aided
analysis and design of circuits and networks. (3 lab hours)
183B. Digital Devices and Systems Laboratory (1)
Prerequisites: E E 85, 128. Familiarization with a real-time microcomputer
board, assembly language programming techniques, I/O interfacing, documentation,
debugging, and testing. (3 lab hours)
183C. Physical Electronics and Electromagnetics Laboratory (1)
Prerequisites: E E 114, 128, 128L, 136, 136L. Solid state device and
characterization; rf component design with stripline and microchip techniques;
electromagnetic signal analysis; noise reduction techniques; antenna pattern
measurements; laser system design. (3 lab hours) (
183D. Electrical Power and Control Systems Laboratory (1)
Prerequisite: E E 121, I21L, 155 (or concurrently). Measurement of characteristics
and testing of power systems, computer-aided design and simulation of power
and control systems; design and testing of feedback control systems; parametric
study of control system implementation. (3 lab hours)
190. Independent Study (1-3; max see reference)
See Academic Placement -- Independent Study.
191T. Topics in Electrical and Computer Engineering
(1-3; max total 6)
Prerequisite: permission of instructor. Investigation of selected electrical
engineering subjects not in current courses.
193. Electrical and Computer Engineering
Cooperative Internship (3-4)
Prerequisite: permission of adviser. Engineering practice in an industrial
or governmental installation over a period of about seven months duration.
Each period must span a summer-fall or spring-summer interval. This course
cannot be used to meet graduation requirements.