EE-ELECTRICAL
ENGINEERING
Electrical Engineering Department
EE
111 Introduction to Electrical
Engineering (1)
A
general overview of the field of electrical engineering. Preparation for
successful completion of the Electrical Engineering (EE) program at Cal Poly. 1
lecture. Concurrent: EE 151.
EE
112 Electric Circuit Analysis I (2)
Introduction
to basic circuit analysis. Resistive circuits, voltage and current sources,
network theorems, op-amp circuits. 2 lectures. Prereq-uisite: MATH 142 or
equivalent. Concurrent or prerequisite: PHYS 133.
EE
129 Digital Design (3) (Also listed as
CPE 129)
Number
systems, Boolean algebra, Boolean functions, and minimization. Analysis and
design of combinational logic circuits. Feedback circuits. Analysis and design
of sequential logic circuits. Applying Hardware Description Language (HDL) to
synthesize digital logic circuits in Programmable Logic Devices (PLDs). 3
lectures. Prerequisite: An orientation course in student’s major (EE 111/151
for EE students, CPE/CSC 101 for CPE students), CPE/CSC 101. Concurrent: EE
169.
EE
151 Introduction to Electrical
Engineering Laboratory (1)
A
variety of hands-on experiments and demonstrations in electrical engineering,
providing background and motivation for successful completion of the Electrical
Engineering (EE) program at Cal Poly. 1 laboratory. Concurrent: EE 111.
EE
169 Digital Design Laboratory (1) (Also
listed as CPE 169)
Experiments
to analyze and design combinational and sequential logic circuits with discrete
ICs and PLDs. Introduction to laboratory equipment such as the logic state
analyzer for testing circuits. Introduction to a hardware description language
for logic simulation and design. 1 laboratory. Prerequisite: An orientation
course in student’s major (EE 111/151 for EE students, CPE/CSC 101 for CPE
students), CPE/CSC 101. Concurrent: EE 129.
EE
200 Special Problems for Undergraduates
(1–2)
Individual
investigation, research, studies or surveys of selected problems. Total credit
limited to 4 units, with a maximum of 2 units per quarter. Prerequisite:
Consent of department chair.
EE
201 Electric Circuit Theory (3)
Application
of fundamental circuit laws and theorems to the analysis of DC, and
steady-state single-phase and three-phase circuits. Not for electri-cal
engineering majors. 3 lectures. Prerequisite: MATH 244, PHYS 133.
EE
211 Electric Circuit Analysis II (3)
Continuation
of basic circuit analysis. Energy storage elements, RC and RL circuits, and
phasors. 3 lectures. Prerequisite: EE 112, MATH 143. Concurrent: EE 241.
EE
212 Electric Circuit Analysis III (3)
AC
power, 3-phase circuits. Mutual inductance, series and parallel resonance and
two-port networks. 3 lectures. Prerequisite: MATH 242 (or concurrent), EE 211.
Concurrent: EE 242.
EE
213 Basic Circuit Analysis (4)
Introduction
to basic circuit analysis. Resistive circuits, voltage and current sources,
analysis methods, network theorems. Operational amplifiers, capacitor and
inductors, first-order circuits, and second-order circuits. 4 lectures.
Prerequisite: PHYS 133. Concurrent: MATH 244, EE 253. Suggested: CHEM 124, EE
111/151, IME 156, ENGL 134.
EE
214 Steady-State Circuit Analysis (4)
Steady-state
sinusoidal analysis, AC power, three-phase circuits, mutual inductance,
frequency response, series and parallel resonance, Bode plots, and two-port
networks. 4 lectures. Prerequisite: EE 213/253, MATH 244. Concurrent: EE 254.
EE
228 Continuous-Time Signals and Systems
(4)
Continuous-time
systems analysis, with emphasis on linear time-invariant (LTI) systems.
Classification of continuous-time systems. Convolution and its application to
LTI systems. The
EE
229 Computer Design and Assembly
Language Programming (3) (Also listed as
CPE 229)
Design
and implementation of digital computer circuits via CAD tools for programmable
logic devices (PLDS). Basic computer design with its data path components and
control unit. Introduction to assembly language programming of an off-the-shelf
RISC-based microcontroller. 3 lectures. Prerequisite: EE 129/169. Concurrent:
EE 269.
EE
241 Electric Circuit Analysis Laboratory
II (1)
Use
of electrical and electronic test equipment. Experimental verification of
circuit analysis concepts including Kirchhoff's Laws, Thevenin's Theorem,
maximum power transfer and superposition. 1 laboratory. Concurrent: EE 211,
ENGL 133 or ENGL 134.
EE
242 Electric Circuit Analysis Laboratory
III (1)
Observation
of transient and steady-state phenomena, phase-shift circuits, resonance. Use
of phasor diagrams. 1 laboratory. Prerequisite: EE 241 or consent of department
chair. Concurrent: EE 212.
EE
251 Electric Circuits Laboratory (1)
Techniques
of measurement of DC and steady-state AC circuit parameters. Equivalent
circuits, nonlinear elements, resonance. 1 laboratory. Concurrent: EE 201.
EE
253 Basic Circuit Analysis Laboratory
(1)
Use
of electrical and electronic test equipment. Experimental verification of
circuit analysis concepts including Kirchhoff's Laws, Thevenin's Theorem,
maximum power transfer, superposition, and RLC circuit transient behavior. 1
laboratory. Prerequisite: PHYS 133. Concurrent: MATH 244, EE 213. Suggested:
CHEM 124, EE 111/151, IME 156, ENGL 134.
EE
254 Steady-State Circuit Analysis
Laboratory (1)
Observation
of transient and steady-state phenomena, phase-shift circuits, resonance,
mutual inductance, and two-port networks. Use of phasor diagrams. 1 laboratory.
Prerequisite: EE 213/253, MATH 244. Concurrent: EE 214.
EE
255 Energy Conversion Electromagnetics
(3)
Fundamentals
of electro-mechanical energy conversion. Magnetic circuits and electromagnetic
devices. Theory of operation and operating characteristics of transformers, DC
machines, and AC induction and synchronous machines. Stepper motors. 3
lectures. Prerequisite: EE 214/254 or EE 201/251. Concurrent: EE 295.
EE
269 Computer Design and Assembly
Language Programming Laboratory (1) (Also listed as CPE 269)
Experiments
to design and test digital computer circuits and systems with programmable
logic devices (PLDs). Design projects to implement a basic computer with data
path components and control. Assembly language programming projects for an
off-the-shelf RISC-based microcontroller. 1 laboratory. Prerequisite: EE
129/169. Concurrent: EE 229.
EE
295 Energy Conversion Electromagnetics
Laboratory (1)
Single-phase
and three-phase transformers. Starting of rotating machines, evaluation of
characteristics of rotating machines. Stepper motor. 1 laboratory.
Prerequisite: EE 214/254 or EE 201/251. Concurrent: EE 255.
EE
302 Classical Control Systems (3)
Introduction to feedback control systems. System
modeling. Transfer functions. Graphical system representation. System time
response, stability. Root Locus. Frequency response. Compensation. 3 lectures.
Prerequisite: EE 228, EE 255/295. Concurrent: EE 342. Suggested: EE 468.
EE
303 Power Transmission (3)
Electrical
characteristics of three-phase overhead and underground power transmission
lines. Development of models for different types of lines as well as
interconnected power systems. Introduction of per unit calculations.
Introduction of computer simulation methods. 3 lectures. Prerequisite: EE 228.
EE
306 Semiconductor Device Electronics (3)
Internal
operation, semiconductor physics, terminal characteristics, models and
application of diodes (LEDs, solar cells, and photo-diodes) and transistors
(field-effect and bipolar). 3 lectures. Prerequisite: CHEM 124, EE 214/254, IME
156, PHYS 211. Concurrent: EE 346.
EE
307 Digital Electronics and Integrated
Circuits (3)
Analysis,
design, application and interfacing of integrated logic circuits, including
NMOS, CMOS, TTL, ECL, and other logic families. 3 lectures. Prerequisite: EE
229/269, EE 306/346. Concurrent: EE 347.
EE
308 Analog Electronics and Integrated
Circuits (3)
Analysis
and design of integrated circuits for use in analog applications. Gain,
frequency response, and feedback of linear small-signal amplifiers. 3 lectures.
Prerequisite: EE 302/342, EE 307/347. Concurrent: EE 348.
EE
313 Signal Transmission (3)
Distributed-circuit
concepts and traveling waves. Transmission line parameters. Lines with and
without reflection. Standing waves. Smith Chart and its applications.
Transmission line measurements and impedance matching techniques. 3 lectures.
Prerequisite: EE 228. Concurrent: EE 353.
EE
314 Introduction to Communication
Systems (3)
Analog
modulation, including: double-sideband modulation, amplitude modulation,
single-sideband modulation, frequency modulation, phase modulation.
Performances of such systems in the presence of white Gaussian noise. Implementations
of transmitters and receivers. 3 lectures. Prerequisite: STAT 350.
EE
321 Electronics (3)
Semiconductor
devices and circuits. Instrumentation amplifiers, power control rectifiers,
feedback, pulse circuits, digital logic circuits. Not for Electrical
Engineering majors. 3 lectures. Prerequisite: EE 201.
EE
328 Discrete Time Signals and Systems
(3)
Discrete-time systems and analysis, with emphasis on
linear time-invariant (LTI) systems. Sampling theorem. Classification of
discrete-time systems. Convolution and its application to LTI systems. The z
transform, discrete-time Fourier transform, and discrete Fourier transform.
Introduction to digital filters. 3 lectures. Prerequisite: EE 228. Concurrent:
EE 368.
EE
329 Programmable Logic and
Microprocessor-Based Systems Design (4) (Also listed as CPE 329)
Design, implementation and testing of programmable
logic microproces-sor-based systems. Hardware/software tradeoffs (such as
timing analysis and power considerations), system economics of programmable
logic and microprocessor-based system design. Interfacing hardware components
(such as ADCs/DACs, sensors, transducers). 3 lectures, 1 laboratory.
Prerequisite: EE 307/347.
EE
334 Electromagnetic Fields I (3)
Advanced
treatment of static electric and magnetic fields and their sources. Poisson’s
and Laplace’s equations, and boundary value problems. Maxwell’s equations and
time-varying electromagnetic fields. Plane wave propagation in free space and
in materials. 3 lectures. Prerequisite: PHYS 133, STAT 350.
EE
335 Electromagnetic Fields and
Transmission (4)
Maxwell’s
equations. Plane wave propagation in free space. Static electric and magnetic
fields. Distributed-circuit concepts and transmission line parameters.
Reflections and standing waves. The Smith chart and its applications.
Transmission line measurements and impedance matching techniques. 4 lectures.
Prerequisite: MATH 241, EE 214/254.
EE
336 Microprocessor System Design (4)
(Also listed as CPE 336)
Introduction
to microcontrollers and integrated microprocessor systems. Emphasis on the
Intel 8051 and Motorola 68HC11 families and derivatives. Hardware/software
trade-offs, system economics, and functional configurations. Interface design,
real-time clocks, interrupts, A/D conversion, serial and parallel
communications, watch-dog timers, low power operation, and assembly language
programming techniques. Architecture and design of sampled data and digital
control systems. Case studies of representative applications. 3 lectures, 1
laboratory. Prerequisite: EE 129/169.
EE
342 Classical Control Systems Laboratory
(1)
Laboratory
work pertaining to classical control systems, including servo control,
transient and frequency responses, stability, and computer-aided analysis of
control systems. 1 laboratory. Prerequisite: EE 228, EE 255/295. Concurrent: EE
302. Suggested: EE 368.
EE
346 Semiconductor Device Electronics
Laboratory (1)
Experimental
determination of device characteristics and models. 1 laboratory. Prerequisite:
CHEM 124, EE 214/254, IME 156, PHYS 211. Concurrent: EE 306.
EE
347 Digital
Electronics and Integrated Circuits Laboratory (1) (Title corrected
1/8/04)
Computer simulation and experimental investigation
of the characteristics, applications and interfacing of different logic families.
1 laboratory. Prerequisite: EE 229/269, EE 306/346. Concurrent: EE 307.
EE
348 Analog Electronics and Integrated
Circuits Laboratory (1)
Design,
simulation, construction and testing of solid state amplifiers and sub-circuits
to meet stated specifications. 1 laboratory. Prerequisite: EE 302/342, EE
307/347. Concurrent: EE 308.
EE
353 Signal Transmission Laboratory (1)
Transmission
and reflection measurements. Impedance matching techniques. 1 laboratory.
Prerequisite: EE 368. Concurrent: EE 313.
EE
361 Electronics Laboratory (1)
Instrumentation
amplifiers, feedback, rectifiers and power control, pulse and digital logic
circuits. 1 laboratory. Prerequisite: EE 251. Concurrent: EE 321.
EE
368 Signals and Systems Laboratory (1)
Laboratory
work pertaining to linear systems, including Fourier analysis, time and
frequency responses, and system transfer function. 1 laboratory. Prerequisite:
EE 228. Concurrent: EE 328.
EE
400 Special Problems for Advanced
Undergraduates (1–5)
Individual
investigation, research, studies, or surveys of selected problems. Total credit
limited to 5 units. Prerequisite: Consent of department chair.
EE
401 Electromagnetic Fields II (3)
Reflection
and transmission of normal incidence plane waves at planar boundaries between
two and multiple media. Reflection and refraction of oblique incidence plane
waves at a planar boundary between two different media. Wave guides. Antennas.
3 lectures. Prerequisite: EE 334.
EE
402 Electromagnetic Waves (4)
Maxwell’s
equations and plane wave propagation in materials. Reflection and transmission
of normal and oblique incidence plane waves at planar boundaries between
different media. Wave guides. Antennas. 4 lectures. Prerequisite: EE 335.
Concurrent: EE 442.
EE
403 Fiber Optic Communication (3)
Propagation
of light in optical fibers, attenuation and bandwidth. LED and Laser Diode
sources for use with optical fibers. Optical sources, detectors, and receivers.
Design of optical communication systems with applications in telecommunications
and local area networks (LANs). 3 lectures. Prerequisite: EE 335 or PHYS 323.
EE
405 High-frequency Amplifier Design (3)
Design
of modern electronic amplifiers and amplifier systems with advanced techniques.
UHF and microwave small signal amplifier design utilizing microstrip
transmission lines, S parameters of GaAs FET, and bipolar transistors. Low
noise, broadband, and power amplifier designs. Oscillator designs. 3 lectures.
Prerequisite: EE 308/348, EE 335. Concurrent: EE 445.
EE
406 Power Systems Analysis I (4)
Introduction
to electric power systems. Representation of power systems and its components
including transmission lines, synchronous machines, transformers and loads. One
line diagrams and per unit calculations. symmetrical faults. Load flow
analysis. 4 lectures. Prerequisite: EE 335, EE 255/295.
EE
407 Power Systems Analysis II (4)
Symmetrical components, unbalanced faults, power system
stability, system protection, relays and relay systems, power system instrumentation
and measurement techniques, economic operation. 4 lectures. Prerequisite: EE
406.
EE
409 Electronic Design (3)
Design
of electronic systems and subsystems using analog and digital integrated
circuits. Design principles and techniques. Analysis and design of feedback
amplifiers; operational amplifier applications. Design of analog/digital and
digital/analog converters. Power supply design. Emphasis on IC implementation.
3 lectures. Prerequisite: EE 308/348, EE 328/368, EE 329. Concurrent: EE 449.
EE
410 Power Electronics I (4)
Introduction to power electronics and power
semiconductor devices. Analysis, performance characterization, and design of
power electronics converters such as: rectifiers, DC choppers, AC voltage
controllers, and single-phase inverters. Operation of DC motor drives. Use of
commercially available software. 3 lectures, 1 laboratory. Prerequisite: EE
409/449 (or concurrent) and EE 255/295, or EE 321 and consent of instructor.
EE
411 Power Electronics II (4)
Switching
losses. Analysis, performance characterization, and design of snubber circuits
and resonant converters. Operation of DC transmission lines, flexible AC
transmission system (FACTS) controllers, three-phase inverters, and AC motor
drives. Use of commercially available software. 3 lectures, 1 laboratory.
Prerequisite: EE 410.
EE
412 Advanced Analog Circuits (3)
Application
of linear integrated circuits to data acquisition problems: transducer
interfacing, linear and nonlinear preprocessing, phase-locked loops, and high
performance quantization and recovery (A/D, D/A conversion). 3 lectures.
Prerequisite: EE 409/449, EE 314.
EE
413 Advanced Electronic Design (4)
Advanced
design of electronic circuits and subsystems. Design as a process.
Implementation of specific design projects. Automated test using GPIB
instruments. 3 lectures, 1 laboratory. Prerequisite: CSC 101, EE 409/449.
EE
415 Communication Systems Design (3)
Design
of modern electronic communication and telemetry systems. Emphasis: practical
implementation and comparative evaluation of various modulation systems. 3
lectures. Prerequisite: EE 409/449, EE 314.
EE
416 Digital Communication Systems (3)
Baseband
(PCM, PAM, DM) signals and transmission. Bandpass (PSK, FSK, ASK) modulation
and demodulation techniques. Digital communication signals in the presence of
noise and detection of signals in Gaussian noise. Other topics such as:
quantization, multiplexing and multiple access, spread spectrum techniques,
coding, synchronization. 3 lectures. Prerequisite: EE 314, EE 328.
EE
417 Alternating Current Machines (4)
Alternating
current machines. Generalized, operational and dynamic analysis. Steady-state
and transient operation of synchronous machines and linear induction machines.
3 lectures, 1 laboratory. Prerequisite: EE 255/295.
EE
418 Photonic Engineering (3)
Modern
optical design with emphasis on the use of computers to design simple optical
systems and to evaluate existing optical designs. Paraxial and exact ray
tracing through thin and thick lenses, mirrors, and prisms. Radiometry and
photometry. Electro-optic, acousto-optic, and magneto-optic modulators and
their applications. Thermal detectors, semiconductor detectors, and charge
coupled device (CCD) arrays. 3 lectures. Prerequisite: EE 335 or PHYS 323.
EE
419 Digital Signal Processing (3)
Review
of Z-transform, convolution and discrete Fourier Transform. Digital filter
design. Fast Fourier Transform. Theory and applications of digital signal
processors. 3 lectures. Prerequisite: CSC 101, EE 328/368. Concurrent: EE 459.
EE
420 Direct Energy Conversion (3)
Direct
energy conversion, and storage, with consideration of resources, batteries,
fuel cells, thermoelectricity, thermionic generators, solar energy, cells, MHD,
power generation, and related topics. 3 lectures. Recommended as a complement
to ME 415. Prerequisite: ME 302.
EE
421 Solid-state Microelectronics (3)
Physical
basis of solid-state microelectronics. Passive and active integrated circuit
components in Bipolar, MOS, thin and thick film systems. Diffusion, oxidation,
ion implantation and other fabrication techniques. Microcircuit layout and
design: system development, reliability and economic considerations. Future
trends. 3 lectures. Prerequisite: EE 307.
EE
422 Polymer Electronics Laboratory (1)
Experimental
procedures in polymer electronics. Investigation of the characteristics of a
polymer electronic device. 1 laboratory. Prerequisite: EE 347 or MATE 345.
EE
425 Analog Filter Design (3)
Approximation
Theory. All pole filters. Frequency transformations. Elements of passive
synthesis. Time delay filters. Theory and design of active filters. Sensitivity
analysis. 3 lectures. Prerequisite: EE 409/449. Concurrent: EE 455.
EE
427 Digital Computer Subsystems (3)
(Also listed as CPE 427)
Design
of components and subsystems in digital computers. Use of modern techniques and
devices (CPLDs and FPGAs) in implementation. Consideration given to cost/speed
tradeoffs. Implementation of a basic digital computer using pre-designed
subsystems. 3 lectures. Prerequisite: EE 307/347. Concurrent: EE 467.
EE
431 Computer-Aided Design of VLSI
Devices (4)
Design
of VLSI circuits, design of subsystems using static CMOS, transmission gates,
and other methods. Variety of CAD tools for design, verification, test, and
simulation. Several design projects. 3 lectures, 1 laboratory. Prerequisite: EE
307/347, EE 308/348 or consent of instructor.
EE
432 Digital Control Systems (3)
Theory
and applications of digital computers in linear control systems. Discrete time
methods are used in analysis and design studies. Digital control systems are
synthesized. 3 lectures. Prerequisite: EE 302/342, EE 328/368. Concurrent: EE
472.
EE
433 Computer-Aided Design in Magnetics
(4)
Variational
principles, integral and partial differential equation methods. Application of
integral and partial differential equation methods to electromagnetic field
problems. Computer-aided design of electrical devices. Use of commercially
available software. 3 lectures, 1 laboratory. Prerequisite: EE 255/295, EE 335.
EE
438 Digital Computer Systems (3) (Also
listed as CPE 438)
Design
of computer ALUs, microprogram controllers, memory systems, and I/0
controllers. Use of LSI components in CPU design. Microprogram and nanoprogram
development. 3 lectures. Prerequisite: EE 427 or consent of instructor.
EE
439 Computer Peripheral Interfacing (3)
(Also listed as CPE 439)
Design
of the more common computer peripherals with the emphasis on the controller and
interfacing aspects. Use of microprocessors and/or LSI controller chips in the
design of intelligent peripherals. 3 lectures. Prerequisite: EE 329, or consent
of instructor.
EE
442 Signal Transmission Laboratory (1)
Transmission
line characterization. Load determination and standing wave patterns using the
slotted line technique. Application of the Smith Chart in transmission line
characterization and impedance matching techniques. Time domain response to
voltage pulses. 1 laboratory. Prerequisite: EE 335. Concurrent: EE 402.
EE
443 Fiber Optics Laboratory (1)
Experimental
investigation of the properties of optical fibers, sources, and detectors.
Measurement of fiber physical characteristics, attenuation, losses, and
bandwidth. Evaluation of an analog and digital fiber optic data link. 1 laboratory.
Concurrent or prerequisite: EE 403.
EE
444 Power Systems Laboratory (1)
Protective
relaying, coordination, and relay calibration. Power control using
transformers, parallel operation of generators, and computer simulation of
power systems. 1 laboratory. Prerequisite: EE 406.
EE
445 High Frequency Amplifier Design
Laboratory (1)
Experimental
investigation employing advanced techniques. Design of high-frequency
electronic amplifiers utilizing S-parameters of bipolar transistors, network
analyzers, and computer simulation techniques. 1 laboratory. Prerequisite: EE
308/348, EE 335. Concurrent or prerequisite: EE 405.
EE
449 Electronic Design Laboratory (1)
Design
of electronic systems and subsystems using integrated circuits. 1 laboratory.
Prerequisite: EE 308/348, EE 328/368, EE 329. Concurrent: EE 409.
EE
455 Analog Filter Design Laboratory (1)
Advanced
laboratory study of sensitivity and stability of active networks prescribed for
realization of transfer functions by active network synthesis techniques.
Formal experiments and individual project work. 1 laboratory. Prerequisite: EE
409/449. Concurrent: EE 425.
EE
456 Communication Systems Laboratory (1)
Methods
of analog and digital modulation and demodulation. Emphasis on spectral analysis,
bandwidth requirements and other practical considerations of modulation and
demodulation. 1 laboratory. Prerequisite: EE 328/368, EE 314.
EE
458 Photonic Engineering Laboratory (1)
Experimental
investigation of the techniques used in processing optical signals. Formal
experiments on electro-optic modulation, acousto-optic modulation. Construction
of an RF spectrum analyzer. Analog processing of optical signals, and
charge-coupled array devices. 1 laboratory. Prerequisite or concurrent: EE 418.
EE
459 Digital Signal Processing Laboratory
(1)
Experiments
in digital filter design and digital signal processing emphasizing various
areas of applications (communications, audio signals, speech processing).
Formal experiments and individual project work. 1 laboratory. Prerequisite: CSC
101, EE 328/368. Concurrent: EE 419.
EE
460 Senior Project Preparation (1)
Methods
for project planning including Gantt Chart, critical paths, time and cost
estimates. Experience in subsystem definition. Case studies and examples.
Ethical code of conduct in the engineering profession. Definition and planning
of senior project. 1 lecture. Prerequisite: EE 314, EE 335. Prerequisite or
concurrent: EE 409/449.
EE
461, 462 Senior Project (3) (2)
Selection
and completion of a project under faculty supervision. Projects typical of
problems which graduates must solve in their fields of employment. Project
results are presented in a formal report. Minimum 150 hours total time.
Prerequisite: EE 409/449, EE 460.
EE
463, 464 Senior Project Design
Laboratory (3) (2)
Selection
and completion of a project under faculty supervision. Projects typical of
problems which graduates must solve in their fields of employment. Project
results are presented in a formal report. EE 463: 3 laboratories; prerequisite:
EE 409/449, EE 460. EE 464: 2 laboratories; prerequisite: EE 463. Note:
although EE 463, 464 substitute for EE 461, 462, students may not use repeat
credit for the purpose of increasing GPA.
EE
467 Digital Computer Subsystems Laboratory
(1)
(Also listed as CPE 467)
Introduction
to industrial grade CAD tools. Design and implementation of digital computer
subsystems using SPLDs, CPLDs, and FPGAs. 1 laboratory. Prerequisite: EE
307/347. Concurrent: EE 427.
EE
470 Selected Advanced Topics (1–4)
Directed
group study of selected topics for advanced students. Open to undergraduate and
graduate students. Class Schedule
will list topic selected. Total credit limited to 8 units. 1–4 lectures.
Prerequisite: Consent of instructor.
EE
471 Selected Advanced Laboratory (1–4)
Directed
group laboratory study of selected topics for advanced students. Open to
undergraduate and graduate students. Class
Schedule will list topic selected. Total credit limited to 8 units. 1–4
laboratories. Prerequisite: Consent of instructor.
EE
472 Digital Control Systems Laboratory
(1)
Design
and programming of microprocessor-based digital controls for electro-mechanical
plants. Topics include digital control laws, translation of transfer functions
into algorithms, assembly language programming, real-time software design,
sample rate selection, finite word-length considerations. 1 laboratory.
Prerequisite: EE 302/342, EE 328/368. Concurrent: EE 432.
EE
485 Cooperative Education Experience (6)
(CR/NC)
Part-time
work experience in business, industry, government, and other areas of student
career interest. Positions are paid and usually require relocation and
registration in course for two consecutive quarters. Formal report and
evaluation by work supervisor required. Credit/No Credit grading only. Total
credit limited to 16 units. Prerequisite: Sophomore standing and consent of
instructor.
EE
495 Cooperative Education Experience
(12) (CR/NC)
Full-time
work experience in business, industry, government, and other areas of student
career interest. Positions are paid and usually require relocation and
registration in course for two consecutive quarters. Formal report and
evaluation by work supervisor required. Credit/No Credit grading only. Total
credit limited to 16 units. Prerequisite: Sophomore standing and consent of
instructor.
EE
500 Individual Study (1–3)
Advanced
study planned and completed under the direction of a member of the department
faculty. Open only to graduate students who have demonstrated ability to do
independent work. Enrollment by petition. Prerequisite: Consent of department
chair, graduate advisor, and supervising faculty member. Total credit limit at
discretion of graduate advisor, not to exceed 9 units.
EE
502 Microwave Engineering (4)
Application
of Maxwell’s equations and boundary value problems to waveguide structures.
Striplines and microstrip lines. S-parameters. Microwave equivalent circuit
theorem. Passive microwave devices. Charge and field interactions in
oscillators and amplifiers. Transferred electron devices, avalanche
transit-time devices, and microwave transistors. Circuits associated with
oscillators and reflection type amplifiers. 4 seminars. Prerequisite: EE 402 or
equivalent.
EE
511 Electric Machines Theory (3)
Advanced
topics in electric machines theory. Introduction to Park's transformation.
Analysis of electric machines using Kron's generalized concept. Excitation
systems. 3 seminars. Prerequisite: EE 255 or equivalent, and graduate standing
or consent of instructor.
EE
513 Control Systems Theory (4)
State
representation of dynamic systems. Mathematical models of physical devices,
controllability and observability. Design of closed-loop systems. Optimal control
theory. 4 seminars. Prerequisite: EE 302 or equivalent, and graduate standing
or consent of instructor.
EE
514 Advanced Topics in Automatic Control
(4)
Summary
course covering five selected graduate-level topics in automatic control theory
and practice; implementation issues in digital control, nonlinear control
theory and design, LQ and time optimal control, variable structure control, and
fuzzy logic/model-free control. 4 seminars. Prerequisite: EE 513 or equivalent,
EE 328 or similar course on discrete-time linear systems.
EE
515 Discrete Time Filters (4)
Advanced topics in filter design and implementation.
Emphasis placed on current applications and on the processing of real signals.
Topics may include signal analysis via spectral estimation, short time Fourier
transforms, and spectrograms. Effects of coefficient quantization, and limits
of practical filters. State space realization. Optimal and adaptive filters for
signal prediction, system identification, and noise cancellation. Techniques
implemented in programming assignments. 4 seminars. Prerequisite: EE 314 or
equivalent, and graduate standing or consent of instructor.
EE
517 Information Theory (4)
Introduction to information theory and coding. Self
and mutual information. Discrete and continuous information sources and
transmission channels. Additive white Gaussian noise channel. Channel capacity.
The Source- and Channel-Coding Theorems. Data compression. Huffman code. Block
codes, including Hamming and linear codes. Parity and syndrome decoding.
Convolutional codes. 4 seminars. Prerequisite: EE 314 or equivalent, EE 525,
and graduate standing or consent of instructor.
EE
518 Advanced Power System Analysis (3)
Symmetrical
components. Unbalanced faults. Analysis by digital computer simulation. Load
flow studies. Elements of power system stability. 3 seminars. Prerequisite: EE
406 or equivalent, and graduate standing or consent of instructor.
EE
519 Power System Design (4)
Design
studies involving aspects of an electric power system. Current industrial
designs. Computer simulation techniques used extensively. 4 seminars.
Prerequisite: EE 518, and graduate standing or consent of instructor.
EE
520 Solar-Photovoltaic Systems Design
(3)
Solar
cell and storage battery theory, examination of insolation variability and
optimization techniques, principles of grounding protection and control, a
survey of power conditioning equipment and system integration techniques. 3
seminars. Prerequisite: Graduate standing or consent of instructor.
EE
521 Computer Systems (4)
Organization
of modern general purpose, high speed digital computer systems. Arithmetic
units, control units, memories and memory subsystems. Peripheral equipment.
Cost and speed trade-offs in the design of such systems. 4 seminars.
Prerequisite: EE 437 or equivalent, or consent of instructor.
EE
522 Microprocessor-Based Digital System
Design (4)
Design
and implementation of microprocessor-based digital systems. Their analysis and
cost effective use in system design problems. Data acquisition and control
systems. Role of microperipheral controllers. Laboratory problems associated
with interfacing microprocessors to various systems. 3 seminars, 1 laboratory.
Prerequisite: EE 329 or equivalent, or consent of instructor.
EE
523 Digital Systems Design (3)
Design
of asynchronous sequential machines and pulse mode logic circuits. Selected
automata theory topics include state compatibility analysis, state partition
analysis, threshold logic, fuzzy logic. Modern digital system design. Analysis
of MOS-LSI multiphase logic structures. Comparison of digital subsystems.
Microprocessor as a digital subsystem module. 3 seminars. Prerequisite: EE 307
or equivalent, and graduate standing or consent of instructor.
EE
524 Solid State Electronics (3)
Physical
theory of solid-state devices. Properties of metal-semiconductor junctions and
p-n junctions. Derivation of properties of diodes, transistors, and four-layer
devices from basic physical and mathematical considerations. 3 seminars. Prerequisite:
PHYS 412 or equivalent, and graduate standing or consent of instructor.
EE
525 Stochastic Processes for Engineers
(4)
Probability
and stochastic processes used in random signal analysis. Response of linear
systems to random inputs. Auto-correlation and power spectral densities.
Applications in signal processing using the discrete Kalman filter. 4 seminars.
Prerequisite: STAT 350 or equivalent, and graduate standing or consent of
instructor.
EE
526 Digital Communications (4)
M-ary
signals. Vector space representation of signals. Optimum receiver principles.
Common signal sets. Signal space dimensionality versus time-bandwidth product.
4 seminars. Prerequisite: EE 314 or equivalent, EE 525, and graduate standing
or consent of instructor.
EE
527 Advanced Topics in Power Electronics
(4)
Static
variable speed AC and DC drives. Phase-controlled rectifiers and choppers in DC
motor control. PWM in three-phase inverters, sinusoidal modulation techniques,
control strategies for AC three-phase variable speed motor control using
voltage source inverters, current source inverters and speed control of AC
motors. Torque and speed pulsations. HVDC converters and DC transmission. 4
seminars. Prerequisite: EE 410 or equivalent, EE 411 or equivalent, and graduate
standing or consent of instructor.
EE
528 Digital Image Processing (4)
Processing
and interpretation of images by computer. Emphasis on current applications with
real images used in programming assignments. Topics may include histogram
equalization, 2-D convolution, correlation, frequency-domain processing, median
filtering, compression, Hough transform, segmentation and region growing,
morphological operations, texture description, shape description, Bayes
classifier. 4 seminars. Prerequisite: EE 314 or equivalent, EE 525, and
graduate standing or consent of instructor.
EE
529 Advanced Topics in Microwave Device
Electronics (3)
Emphasis
on device and circuit principles of active microwave solid-state devices, their
noise aspects and systems applications. 3 seminars. Prerequisite: EE 402 or
equivalent, PHYS 412 or equivalent, and graduate standing or consent of
instructor.
EE
530 Photonic Systems (4)
Design
of radiametric information optics and imaging systems. Remote sensing, guidance
and tracking, fiber optic and laser communications. Component modeling and
optimization of systems for detection of radiant flux with maximum signal to
noise ratio. Modeling of source, intervening media, optical subsystem, focal
plane, signal-conditioning electronics, and output and display. 4 seminars.
Prerequisite: EE 402 or equivalent, EE 314 or equivalent, and graduate standing
or consent of instructor.
EE
533 Antennas (4)
Principles
of antenna theory. Antenna parameters, radiation integrals. Duality and reciprocity
theorems. Wire antennas. Antenna arrays. Traveling wave antennas. Broadband and
frequency independent antennas. Aperture and reflector antennas. Microstrip
antennas. Antenna design. 4 seminars. Prerequisite: EE 402 or equivalent.
EE
541 Advanced Microwave Laboratory (2)
Experimental
measurement in waveguide and microstrip circuits employing the advanced Network
Analyzer. Design of both passive and active microwave circuits using
microstrip. Graphical and analytical design techniques as well as the use of
computer-aided design codes. 2 laboratories. Prerequisite: EE 402 or
equivalent. Concurrent or prerequisite: EE 502, and graduate standing or
consent of instructor.
EE
544 Solid-state Electronics Laboratory
(1)
Experimental
procedures in solid-state electronics. Investigation and improvement of the
characteristics of a solid-state electronic device. 1 laboratory. Prerequisite:
Graduate standing or consent of instructor. Concurrent: EE 524, and graduate
standing or consent of instructor.
EE
563 Graduate Seminar (1) (CR/NC)
Current
developments in the fields of electrical and electronic engineer-ing.
Participation by students, faculty and guest lecturers. Open to gradu-ate
students with a background in electrical or electronic engineering. Credit/No
Credit grading only. Total credit limited to 3 units. 1 seminar.
EE
570 Selected Advanced Topics (1–4)
Directed
group study of selected topics for advanced students. Open to graduate students
and selected seniors with electrical and electronic engineering background. Class Schedule will list topic selected.
Total credit limited to 8 units. 1–4 seminars. Prerequisite: Graduate standing
or consent of instructor.
EE
599 Design Project (Thesis) (2) (2) (5)
Each
individual or group will select, with faculty guidance and approval, a topic
for independent research or investigation resulting in a thesis or project to
be used to satisfy the requirement for the degree. An appropriate experimental
or analytical thesis or project may be accepted. Prerequisite: Graduate
standing and consent of instructor.