|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
3.00 Credits
Lecture-2 hours; laboratory-3 hours. Prerequisite:course 146A. Restricted to Electrical, Computer, and Electrical/Materials Science majors and Electrical Engineering graduate students. Non-majors accommodated when space available. Fabrication processes for CMOS VLSI. Laboratory projects examine deposition of thin films, ion implantation, process simulation, anisotropic plasma etching, sputter metallization, and C-V analysis. Topics include isolation, projection alignment, epilayer growth, thin gate oxidation, and rapid thermal annealing.-II. (II.)
-
4.00 Credits
Lecture-4 hours. Prerequisite: Engineering 6 (may be taken concurrently), course 100. Characterization and analysis of continuous-time linear systems. Fourier series and transforms with applications. Introduction to communication systems. Transfer functions and block diagrams. Elements of feedback systems. Stability of linear systems.-II, III. (II, III.)
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:course 150A. Characterization and analysis of discrete time systems. Difference equation models. Ztransform analysis methods. Discrete and fast Fourier transforms. Introduction to digital filter design.-I. (I.)
-
4.00 Credits
Lecture-2 hours; laboratory-4 hours. Prerequisite:courses 100, 150A, 180A. Study of instrumentation interfacing systems, including software development, hardware interfacing, transducers, dynamic response, signal conditioning, A/D conversion, and data transmission.-II. (II.)
-
4.00 Credits
Lecture-2 hours; laboratory-6 hours. Prerequisite:courses 70 and 150B. Theory and practice of realtime digital signal processing. Fundamentals of realtime systems. Programmable architectures including I/O, memory, peripherals, interrupts, DMA. Interfacing issues with A/D and D/A converters to a programmable DSP. Specification driven design and implementation of simple DSP applications.-III. (III.)
-
4.00 Credits
Lecture-3 hours; laboratory-3 hours. Prerequisite:course 150A. Analysis and design of feedback control systems. Examples are drawn from electrical and mechanical systems as well as other engineering fields. Mathematical modeling of systems, stability criteria, root-locus and frequency domain design methods.-I. (I.)
-
4.00 Credits
Lecture-3 hours; laboratory-3 hours. Prerequisite:course 157A. Control system design; transfer-function and state-space methods; sampled-data implementation, digital control. Laboratory includes feedback system experiments and simulation studies.- II. (II.)
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:course 157A. Design methods for feedback control systems, including quantitative feedback theory and linear quadratic regulators.-III. (III.)
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:course 150A. Signal analysis based on Fourier methods. Fourier series and transforms; time-sampling, convolution, and filtering; spectral density; modulation: carrier-amplitude, carrier-frequency, and pulse-amplitude.-I. (I.)
-
4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisites:course 100. Probabilistic and statistical analysis of electrical and computer systems. Discrete and continuous random variables, expectation and moments. Transformation of random variables. Joint and conditional densities. Limit theorems and statistics. Noise models, system reliability and testing.-I, III. (I, III.) Abdel-Ghaffar, Ding, Levy, Scaglione, Tuqan, Zhao
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2024 AcademyOne, Inc.
|
|
|