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Course Criteria
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1.00 Credits
Electrical devices and circuits laboratory to be taken concurrently with Electrical Engineering 3312. Mode: Laboratory.
Corequisite:
EE 3312 (0254)
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3.00 Credits
Students will learn the basic theory of analog (classical) control systems. The concept of what constitutes a system is learned as well as how to analyze a system by using input-output pairs. The importance of a transfer function and how it characterizes the behavior of a linear time invariant system will be studied. What a feedback system is and how it may change the behavior of a system is learned. Finally, students will learn how to analyze and design linear time invariant control systems using both time domain and frequency domain techniques. Mode: Lecture.
Prerequisite:
EE 3512 (0210) and MATH 3041 (0251)
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1.00 Credits
Experimentation on selected topics in EE 3412: Classical Control Systems.
Prerequisite:
EE 3512 (0210), MATH 3041 (0251)
Corequisite:
EE 3412 (0282)
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4.00 Credits
This course covers continuous time signal models, convolution, and superposition integral and impulse response. Students also study Fourier series and periodic signals, Parseval’s theorem, energy spectral density, Fourier transform and filters, discrete time signals, difference equations, discrete Fourier transform, and discrete convolution. Mode: Lecture.
Prerequisite:
EE 2322 (0165) and MATH 2043 (0127)
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3.00 Credits
To provide the student with an understanding about probability, random variables and random processes and their applications to linear systems. Therefore, the student will learn about the various aspects of probability such as distribution and density functions, conditional probability and various types of random processes such as stationary and nonstationary, ergodic and random processes, the autocorrelation and crosscorrelation, power spectral density, white noise and frequency domain analysis of random signals and their evaluation in linear systems analysis. Mode: Lecture.
Prerequisite:
EE 3512 (0210)
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3.00 Credits
Students study finite-state machines in process control, assembly language programming of the Intel i186EX 16-bit microprocessor and its hardware system implementation. Additional topics include: dynamic RAM read/write and DMA access, hardware interrupts, I/O port addressing, peripheral interface design, microprocessor addressing modes, op codes, and arithmetic computation. Mode: Lecture.
Prerequisite:
EE 2322 (0165), EE 2612 (0156) and EE 2613 (0157)
Corequisite:
EE 3613 (0236)
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1.00 Credits
Laboratory for EE 3612: Microprocessor Systems. This course provides hands-on experience in assembly language programming for Intel i186EX 16-bit microprocessor and its hardware system implementation. The laboratory assignments utilize 80X86 microprocessor simulations using Emu8086 (www.emu8086.com) and hardware experiments with the FlashLite186 microcomputer by JK Microsystems (www.jkmicro.com) with processor bus logic and output signal measurements using the TechTools DigiView logic analyzer in EE 3613: Microprocessor Systems Laboratory. Mode: Laboratory.
Corequisite:
EE 3612 (0235)
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3.00 Credits
This course and co-requisite laboratory considers embedded systems in digital process control and digital signal processing using the Verilog hardware description language and behavioral synthesis using the programmable gate array. Topics include: the controller-datapath construct, nested modules, soft core processing elements, fixed and floating point arithmetic calculations in programmable hardware, interfacing to hard core peripherals and soft core microprocessors.
Prerequisite:
EE 3612 (0235), EE 3613 (0236)
Corequisite:
EE 3623 (0246)
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1.00 Credits
Laboratory for EE 3622 (0245): Embedded System Design. Mode: Laboratory.
Prerequisite:
EE 3612 (0235), EE 3613 (0236)
Corequisite:
EE 3622 (0245)
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3.00 Credits
Engineering applications of electromagnetic field theory including Coulomb’s Law, Gauss’ Law and Faraday’s Law and applications of Poisson’s equations with boundary values, Magnetic flux and the use of Gauss’ and Ampere’s Laws. The course will also consider transmission lines, the development of Maxwell’s equations and the transmission of plane waves in free space and uniform, homogenous, isotropic media. Mode: Lecture.
Prerequisite:
PHYSICS 1062 (C088), EE 2322 (0165), MATH 2043 (0127)
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