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Electrical and Computer Engineering
Engineering
2008-2009 California State University, Fresno General Catalog 311
formance evaluation. Frequency domain
analysis and design methodologies. Applica-tions
and utilization of Matlab in analysis
and design.
ECE 162. Analog Integrated
Circuits and Applications (3)
Prerequisite: ECE 138. Analysis of mono-lithic
operational amplifiers; case studies;
Widlar and Wilson current sources; linear
and nonlinear 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.
ECE 166. Microwave Devices
and Circuits Design (3)
Prerequisite: ECE 136. Microwave theory
and techniques: slow-wave structures, S
parameters, and microwave devices, in-cluding
solid-state devices such as Gunn,
IMPATT, TRAPATT, and BARITT diodes,
and vacuum tubes such as klystrons, reflex
klystrons, traveling-wave tubes, magnetrons
and gyrotrons.
ECE 168. Microwave Amplifier
and Oscillator Design (3)
Prerequisite: ECE 136. Small-signal and
large-signal amplifier designs such as high-gain,
high-power, low-noise, narrow-band
and broadband amplifiers; microwave oscil-lator
designs such as high-power, broadband,
Gunndiode and IMPATT oscillator designs;
power combining and dividing techniques;
reflection amplifier design and microwave
measurements.
ECE 171. Quantum Electronics (3)
Prerequisite: ECE 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.
ECE 172. Sequential Machine
and Automata Theory (3)
Prerequisite: ECE 106. Structure of sequen-tial
machines with particular emphasis on
asynchronous sequential machines; covers;
partitions; decompositions and synthesis
of multiple machines race conditions
and hazards; state identification and fault
detection experiments. Presents design
techniques aimed at circuit performance
that will function reliably with less than
ideal components. Applications include
the design of controllers for robots and
automated machines.
ECE 173. Robotics Fundamentals (3)
Prerequisites: ECE 70/71 or CSCI 40; ECE
90/90L and ECE 85/85L or 90/91L; MATH
77. Introduction to industrial and mobile
robots, forward and inverse kinematics, tra-jectory
planning, sensors, micro controllers,
and laboratory experiments.
ECE 174. Advanced
Computer Architecture (3)
Prerequisites: ECE 115 or 118. Advanced
computing architecture concepts; pipelin-ing;
multiprocessing and multiprogram-ming;
cache and virtual memory; direct
memory access, local and system bus archi-tectures;
instruction set design and coding;
CPU and system performance analysis.
ECE 176. Computer-Aided
Engineering in Digital Design (3)
Prerequisites: ECE 120L or concurrently.
Use of Computer-Aided Engineering tools
in the design and implementation of digi-tal
systems utilizing Applications Specific
Integrated Circuits. Design projects from
specification through implementation using
Field Programmable Gate Arrays (FPGAs)
and Complex Programmable Logic De-vices
(CPLDs); simulation, timing analysis,
Hardware Definition Languages. Hands-on
exposure to current tools.
ECE 186A. Senior Design I (1)
Prerequisites: 30 units of ECE (see advising
notes) or permission of instructor; univer-sity
writing requirement or concurrently.
Design projects in electrical and computer
engineering.
ECE 186B. Senior Design II (3)
Prerequisite: ECE 186A and univer-sity
writing requirement or concurrently.
Completion of approved design projects in
electrical and computer engineering. Project
demonstration and documentation requires
using problem solving, written communica-tion,
and critical thinking skills, as well as
engaging in oral presentations.
ECE 190. Independent Study
(1-3; max total 6)
See Academic Placement — Independent
Study. Approved for RP grading.
ECE 191T. Topics in Electrical
and Computer Engineering
(1-3; max total 6)
Prerequisite: permission of instructor. In-vestigation
of selected electrical engineering
subjects not in current courses.
ECE 193. Electrical and
Computer Engineering
Cooperative Internship (1-6; max 12)
Prerequisite: permission of adviser. Engineer-ing
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. CR/NC grading only.
GRADUATE COURSES
(See Catalog Numbering System.)
Electrical Engineering (EE)
EE 230. Nonlinear Control Systems (3)
Prerequisite: ECE 155 or permission of
instructor. Dynamic systems modeling and
analysis, stability, sliding mode control, fuzzy
logic control, and introduction to relevant
topics. (Formerly EE 291T)
EE 231. Digital Control Systems (3)
Prerequisite: ECE 155 or permission of
instructor. Discrete Time Feedback systems
modeling and analysis, stability, digital con-troller
design, digital transformation of ana-log
controllers, implementation techniques,
and case studies. (Formerly EE 291T)
EE 241. Applied Electromagnetics (3)
Prerequisite: ECE 136 or permission of
coordinator. Electrostatic field boundary
conditions, energy relations, and forces;
multidimensional potential problems;
magnetic field boundary conditions, scalar
and vector potentials, and magnetization;
Maxwell’s equations for stationary and mov-ing
media; energy, force, and momentum in
an electromagnetic field; plane waves; waves
near metallic boundaries; inhomogeneous
wave equation.
EE 243. Modern Methods
in Synchronous Sequential Design (3)
Prerequisite: ECE 172 or permission of
coordinator. Synchronous machine design
with PLDs and FPGAs; algorithmic state
machines; incompletely specified machines;
maximum compatibility classes; partitioning
of sequential machines; state merging and
state splitting.
EE 245. Communications
Engineering (3)
Prerequisite: ECE 134 or permission of
coordinator. Basic modulation concepts;
statistical properties of signals; transmission
systems optimization against noise; digital
Object Description
| Title | 2008-09 General Catalog |
| Creator | California State University, Fresno |
| Format | PDF Document |
| Date of publication | 2008-05 |
| Subjects | California State University, Fresno. Curricula. Catalogs |
| Object type | Document |
| Location | Fresno, California |
| Language | eng |
Description
| Title | Page 311 |
| Full Text Search | Electrical and Computer Engineering Engineering 2008-2009 California State University, Fresno General Catalog 311 formance evaluation. Frequency domain analysis and design methodologies. Applica-tions and utilization of Matlab in analysis and design. ECE 162. Analog Integrated Circuits and Applications (3) Prerequisite: ECE 138. Analysis of mono-lithic operational amplifiers; case studies; Widlar and Wilson current sources; linear and nonlinear 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. ECE 166. Microwave Devices and Circuits Design (3) Prerequisite: ECE 136. Microwave theory and techniques: slow-wave structures, S parameters, and microwave devices, in-cluding solid-state devices such as Gunn, IMPATT, TRAPATT, and BARITT diodes, and vacuum tubes such as klystrons, reflex klystrons, traveling-wave tubes, magnetrons and gyrotrons. ECE 168. Microwave Amplifier and Oscillator Design (3) Prerequisite: ECE 136. Small-signal and large-signal amplifier designs such as high-gain, high-power, low-noise, narrow-band and broadband amplifiers; microwave oscil-lator designs such as high-power, broadband, Gunndiode and IMPATT oscillator designs; power combining and dividing techniques; reflection amplifier design and microwave measurements. ECE 171. Quantum Electronics (3) Prerequisite: ECE 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. ECE 172. Sequential Machine and Automata Theory (3) Prerequisite: ECE 106. Structure of sequen-tial machines with particular emphasis on asynchronous sequential machines; covers; partitions; decompositions and synthesis of multiple machines race conditions and hazards; state identification and fault detection experiments. Presents design techniques aimed at circuit performance that will function reliably with less than ideal components. Applications include the design of controllers for robots and automated machines. ECE 173. Robotics Fundamentals (3) Prerequisites: ECE 70/71 or CSCI 40; ECE 90/90L and ECE 85/85L or 90/91L; MATH 77. Introduction to industrial and mobile robots, forward and inverse kinematics, tra-jectory planning, sensors, micro controllers, and laboratory experiments. ECE 174. Advanced Computer Architecture (3) Prerequisites: ECE 115 or 118. Advanced computing architecture concepts; pipelin-ing; multiprocessing and multiprogram-ming; cache and virtual memory; direct memory access, local and system bus archi-tectures; instruction set design and coding; CPU and system performance analysis. ECE 176. Computer-Aided Engineering in Digital Design (3) Prerequisites: ECE 120L or concurrently. Use of Computer-Aided Engineering tools in the design and implementation of digi-tal systems utilizing Applications Specific Integrated Circuits. Design projects from specification through implementation using Field Programmable Gate Arrays (FPGAs) and Complex Programmable Logic De-vices (CPLDs); simulation, timing analysis, Hardware Definition Languages. Hands-on exposure to current tools. ECE 186A. Senior Design I (1) Prerequisites: 30 units of ECE (see advising notes) or permission of instructor; univer-sity writing requirement or concurrently. Design projects in electrical and computer engineering. ECE 186B. Senior Design II (3) Prerequisite: ECE 186A and univer-sity writing requirement or concurrently. Completion of approved design projects in electrical and computer engineering. Project demonstration and documentation requires using problem solving, written communica-tion, and critical thinking skills, as well as engaging in oral presentations. ECE 190. Independent Study (1-3; max total 6) See Academic Placement — Independent Study. Approved for RP grading. ECE 191T. Topics in Electrical and Computer Engineering (1-3; max total 6) Prerequisite: permission of instructor. In-vestigation of selected electrical engineering subjects not in current courses. ECE 193. Electrical and Computer Engineering Cooperative Internship (1-6; max 12) Prerequisite: permission of adviser. Engineer-ing 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. CR/NC grading only. GRADUATE COURSES (See Catalog Numbering System.) Electrical Engineering (EE) EE 230. Nonlinear Control Systems (3) Prerequisite: ECE 155 or permission of instructor. Dynamic systems modeling and analysis, stability, sliding mode control, fuzzy logic control, and introduction to relevant topics. (Formerly EE 291T) EE 231. Digital Control Systems (3) Prerequisite: ECE 155 or permission of instructor. Discrete Time Feedback systems modeling and analysis, stability, digital con-troller design, digital transformation of ana-log controllers, implementation techniques, and case studies. (Formerly EE 291T) EE 241. Applied Electromagnetics (3) Prerequisite: ECE 136 or permission of coordinator. Electrostatic field boundary conditions, energy relations, and forces; multidimensional potential problems; magnetic field boundary conditions, scalar and vector potentials, and magnetization; Maxwell’s equations for stationary and mov-ing media; energy, force, and momentum in an electromagnetic field; plane waves; waves near metallic boundaries; inhomogeneous wave equation. EE 243. Modern Methods in Synchronous Sequential Design (3) Prerequisite: ECE 172 or permission of coordinator. Synchronous machine design with PLDs and FPGAs; algorithmic state machines; incompletely specified machines; maximum compatibility classes; partitioning of sequential machines; state merging and state splitting. EE 245. Communications Engineering (3) Prerequisite: ECE 134 or permission of coordinator. Basic modulation concepts; statistical properties of signals; transmission systems optimization against noise; digital |
