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Course Criteria
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1.00 - 3.00 Credits
Laboratory to accompany EE 3350. Fundamental elements of communications systems hardware; use of spectrum analyzers and other measurement instruments typically encountered in communication systems; design of active filters in communications systems; analog frequency and amplitude modulators and demodulators; data communication systems. Corequisite: EE 3350. Pre- or corequisite: ECS 3390. (0-1) S
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3.00 Credits
Survey of advanced mathematics topics needed in the study of engineering. Topics include vector differential calculus, vector integral calculus, integral theorems, complex variables, complex integration, series, residues and numerical methods. Examples are provided from microelectronics and communications. Corequisite: MATH 2420. (Same as CEMECH 3300) (3-0) S
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3.00 Credits
Analysis and design of RC, RL, and RLC electrical networks. Sinusoidal steady state analysis of passive networks using phasor representation; mesh and nodal analyses. Introduction to the concept of impulse response and frequency analysis using the Laplace transform. Prerequisites: MATH 2420, PHYS 2326. Corequisite: CE/EE/TE 3101. (Same as CE/TE 3301) (3-0) S
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3.00 Credits
Introduces the fundamentals of continuous and discrete-time signal processing. Linear system analysis including convolution and impulse response, Fourier series, Fourier transform and applications, discrete-time signal analysis, sampling and z-transform. Prerequisite: CE/EE 3300. Corequisite: CE/EE/TE 3102. (Same as CE/TE 3302) (3-0) S
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3.00 Credits
Theory and application of solid state electronic devices. Physical principles of carrier motion in semiconductors leading to operating principles and circuit models for diodes, bipolar transistors, and field effect transistors. Introduction to integrated circuits. Prerequisite CE/EE/TE 3301. Corequisite: CE/EE 3110. (Same as CE 3110) (3-0) S
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3.00 Credits
Analysis and design of electronic circuits using diodes, transistors and operational amplifiers with feedback. Gain and stability of basic amplifier circuits using BJT's, JFET's and MOSFET's; classes oamplifiers; performance of ideal and non-ideal operational amplifiers. Prerequisite: CE/EE 3310. Corequisite: CE/EE 3111. (Same as CE 3311) (3-0) S
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3.00 Credits
Boolean logic. Design and analysis of combinational logic circuits using SSI and MSI. Design and analysis of synchronous state machines. State minimization and assignment. Design of arithmetic circuits: adders, multipliers and shifters. Students cannot get credit for both CS 4341 and CE/EE 3320. Prerequisite: CE/EE 2310. Corequisite: CE/EE 3120. (Same as CE 3320) (3-0) S
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3.00 Credits
Axioms of probability, conditional probability, Bayes theorem, random variables, probability density/mass function (pdf/pmf), cumulative distribution function, expected value, functions of random variables, joint, conditional and marginal pdfs/pmfs for multiple random variables, moments, central limit theorem, elementary statistics, empirical distribution. Students cannot get credit for both CS/SE 3341 and CE/EE/TE 3341. Prerequisite: MATH 2419. Recommended corequisite: MATH 2420. (Same as CE/MECH/TE 3341) (3-0) S
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3.00 Credits
Fundamentals of communications systems. Review of probability theory and Fourier transforms. Filtering and noise. Modulation and demodulation techniques, including amplitude, phase and pulse code. Time division multiplexing. This class may be offered as either regular or honors sections (H). Prerequisites: CE/EE 3300, CE/EE/TE 3302, and CE/EE/TE 3341. Corequisite: EE 3150. (3-0) S
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1.00 - 3.00 Credits
This course provides hands-on learning of RF and microwave fundamentals in a laboratory setting. The weekly lab sessions are designed, both in subject material and timeframe, to compliment the theory taught in EE 4368. The goal of this laboratory is to enable students to become familiar with RF test equipment, measurement techniques and design procedures. The second half of this lab involves design of microwave transmission media (primarily microstrip), impedance matching circuits and characterization of microwave transistors, culminating in the complete design, fabrication and test of a single-stage microwave amplifier. Pre- or corequisite: EE 4368. (0-1) Y
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