|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
3.00 Credits
Credits: 3 Introduces solid-state physics and its application to semiconductors and semiconductor devices. Topics include band theory, doping, p-n junctions, diffusion theory, low-frequency circuits, devices including bipolar transistor, MOSFET, CMOS, and photo transistors. Prerequisites MATH 214, ECE 305, and a grade of C or better in ECE 333; or permission of instructor. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0 When Offered S
-
3.00 Credits
Credits: 3 Analysis and design of discrete and integrated switching circuits. Topics include transient characteristics of diodes, bipolar, and field-effect transistors; MOS and bipolar inverters; nonregenerative and regenerative circuits; TTL, ECL, IIL, NMOS, and CMOS technologies; semiconductor memories; VLSI design principles; and SPICE circuit analysis. Prerequisites Grade of C or better in ECE 331 and 333. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0 When Offered F, S
-
3.00 Credits
Prerequisite: grade of C or better in ECE 333. Second course in linear electronics. Covers differential amplifi ers, feedback circuits, power amplifi ers, feedback amplifi er frequency response, analog integrated circuits, operational amplifi er systems, oscillators, wide band and microwave amplifi ers, and computer-aided design. s
-
1.00 Credits
Credits: 1 Second lab course in linear electronics involving analysis and design of topics listed in ECE 433. Prerequisites ECE 334
-
1.00 Credits
Credits: 1 Lab experiments for topics covered in ECE 431. Prerequisites ECE 334
-
3.00 Credits
Credits: 3 Introduces fundamentals of microelectronic semiconductor device fabrication technology. Processing steps include photolithography, oxidation, diffusion, ionimplantation, chemical vapor deposition, ohmic contact metalization, interconnects, packaging, MOS process integration, and bipolar process integration. Laboratory project integral to course. Prerequisites ECE 333 or 430, or permission of instructor. Hours of Lecture or Seminar per week 2 Hours of Lab or Studio per week 3
-
3.00 Credits
Credits: 3 General overview of operating a digital computer. Topics include computer arithmetic, arithmetic unit, hardwired and microprogrammed control, memory, register-to-register, input-output operations, and behavioral modeling of computer organization using VHDL. Prerequisites Grade of C or better in ECE 331. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0 When Offered F, S, SUM
-
4.00 Credits
Credits: 4 Explores designing with single-chip microcomputers and microcomputer interfacing. Topics include role of microcomputers compared with microprocessors and other computers, microcomputer architecture and organization, real-time control issues, assembly language programming for control, design of control software, input/output methods, design tools, and available single-chip microcomputers. Students select project and design, and construct system including single-chip microcomputer and ancillary hardware to implement control system. Prerequisites Grade of C or better in CS 211 and ECE 332 and 445; and 90 credits toward electrical or computer engineering degree. Notes This course is highly recommended for ECE 492/493 students interested in using microcontroller technology in their senior design projects. It should be taken before ECE 493. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 3 When Offered F
-
4.00 Credits
Credits: 4 Practical introduction to modeling of digital systems with VHDL for logic synthesis. Overview and comparative analysis of design flow and tools for FPGAs and standard-cell ASICs. Discusses verification of digital systems using testbenches, prototyping boards and modern testing equipment, and illustrates VHDL-based design methodology with multiple examples from communications, control, DSP, and cryptography. Laboratory experiments create link between simulation and actual hardware implementation based on FPGA boards. Prerequisites Grade of C or better in ECE 445. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 3 When Offered S
-
3.00 Credits
Credits: 3 Introduces mobile robotic systems. Topics include overview of power systems, motors, behavior-based programming, sensors, and sensor integration. Design projects conceived, developed, implemented, and presented. Prerequisites CS 112, ECE 280 and ECE 331 and either ECE 332 or ECE 303, all with grade of C or better. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2024 AcademyOne, Inc.
|
|
|