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Course Criteria
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3.00 Credits
Semiconductor physics, atomic models and crystal structures. Quantum theory, energy bands, motion of charge carriers, minority/majority carrier profiles and pn junctions. Manufacturing processes for and operating characteristics of diodes, bipolar transistors and field effect devices. Prerequisite: EEE 108. Graded: Graded Student. Units: 3.0
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1.00 Credits
Provides senior level undergraduates with hands-on experience in optical engineering and design . Experiments involving laser characteristics, spectral radiometry, diffraction, polarization, modulation of light, holography and spatial filtering will be performed. Laboratory three hours. Prerequisite: EEE 161, EEE 180, EEE 165; EEE 165 may be taken concurrently, and GWAR certification before Fall 09, WPJ score of 70+, or at least a C- in ENGL 109 M/W. Graded: Graded Student. Units: 1.0
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4.00 Credits
Topics include: microcomputer systems, microprocessor architecture, machine and assembly language programming, timing operations, bus arbitration and exception processing logic, addressing modes, parallel and serial ports, memory, assemblers and development systems. The lab uses development systems and target systems in the Computer Engineering laboratory to assemble, link, test and debug and run various assignments. Lecture three hours; laboratory three hours. Prerequisite: Junior status, EEE 64. Graded: Graded Student. Units: 4.0
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3.00 Credits
Rigorous development of the fundamental relationships governing time-domain and frequency-domain analysis of linear continuous-time and discrete-time systems. Topics include Fourier, Laplace and z-transforms, sampling theorem, modulation, system stability, and digital filters. Prerequisite: EEE 117; EEE 117 may be taken concurrently. Graded: Graded Student. Units: 3.0
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3.00 Credits
Focuses on the application of linear systems theory to design and analysis of digital signal processing systems. Discrete systems, the z transform, and discrete Fourier transform are reviewed. Design of infinite impulse response filters, finite impulse response filters, and digital spectral analysis systems is presented. Computer simulation is used to study the performance of filters and spectral analysis systems. Signal processing architectures are introduced. Lecture three hours. Prerequisite: EEE 64 or equivalent, EEE 180. Graded: Graded Student. Units: 3.0
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1.00 Credits
Provides senior level undergraduate students with experience in the software/hardware design of discrete-time systems, and modern DSP techniques. Laboratory projects will include the following: spectral analysis of analog and digital signals, design of sampling and quantizer circuits, design and realization of IIR and FIR Digital Filters. Hardware projects will include acquisition, analysis, and filtering of speech, biomedical and video signals using Digital Signal Processors (DSPs). Prerequisite: EEE 180, EEE 181; EEE 181 may be taken concurrently. Graded: Graded Student. Units: 1.0
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3.00 Credits
Review of fundamentals, probability, information, distortion by channel, sampling, pulse code modulation, companding, link power calculation, noise figure, pseudo noise. Matched filter detection of binary signals, bit error rate, inter-symbol interference, zero-forcing equalizers. Effects of additive white Gaussian noise in pulse code modulation, spread spectrum in multiple access, cellular radio and other wireless applications. Procedure for making design trade offs will be discussed. Prerequisite: EEE 161, EEE 180, EEE 185; EEE 185 may be taken concurrently. Graded: Graded Student. Units: 3.0
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3.00 Credits
Dynamic system modeling by transfer function and state-space methods using differential equation, time-response and frequency-response methods. Determination of steady-state errors due to step, ramp and parabolic inputs and disturbances for closed-loop systems. Mapping of block diagrams and state-space representations to signal flow graphs (SFG) as well as finding the transfer function of the system represented by the SFG by Mason's Rule. Closed-loop system stability is examined via poles and eigenvalues and by using the Routh-Hurwitz criterion. Introduction to observability and controllability of systems. Design of compensators for feedback systems using root-locus, frequency response and state-space methods. Introduction to digital control. Computer simulation methods such as MATLAB and SIMULINK are used to support the above subjects. Prerequisite: EEE 180. Graded: Graded Student. Units: 3.0
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3.00 Credits
Review of signal and system analysis, sampling theorem and Nyquist's criteria for pulse shaping, signal distortion over a channel, study of digital and analog communication systems, line coding, signal to noise ratios, performance comparison of various communication systems. Prerequisite: EEE 180, ENGR 120; ENGR 120 may be taken concurrently. Graded: Graded Student. Units: 3.0
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1.00 Credits
Experimental study of modulation and demodulation in AM, FM, and digital communication systems, A/D and D/A conversion, measurement of power spectra, noise characterization in frequency domain. Prerequisite: EEE 117 (EEE 185 may be taken concurrently), and (GWAR Certification before Fall 09, or WPJ score of 70+, or at least a C- in ENGL 109M/W). Graded: Graded Student. Units: 1.0
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