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Course Criteria
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1.00 Credits
Experimentation on selected topics in Control Theory. Mode: Laboratory.
Corequisite:
EE 4412 (0350)
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3.00 Credits
Subjects for this course include: discrete data and digital control systems, signal conversions and processing, the Z transform and state variable techniques applied to digital control system, time and frequency domain analysis techniques, stability of digital control systems, etc. The students are required to design and implement a digital control system in groups and are assigned with different tasks. Mode: Lecture.
Prerequisite:
EE 3412 (0282) and EE 4412 (0350)
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3.00 Credits
This course and co-requisite laboratory considers techniques of digital signaling and data communication with amplitude, frequency and phase modulation and demodulation in the presence of noise using MATLAB/Simulink simulation. Topics include: the optimum correlation receiver in baseband and bandpass systems, binary and multiple level signaling, time and frequency division multiplexing, error detection and correction, analog-to-digital conversion and traditional analog amplitude and frequency modulation.
Prerequisite:
EE 3512 (0210), EE 3522 (0230)
Corequisite:
EE 4513 (0301)
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1.00 Credits
Laboratory for Electrical Engineering 4512 (0300): Analog and Digital Communications. Mode: Laboratory.
Corequisite:
EE 4512 (0300)
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3.00 Credits
Course topics include: Discrete-time signals and systems, Random signals, Sampling process, Digital processing of analog signals, Discrete-time Fourier Transforms (DTFT), Filter types and characteristics, Filter design, Finite Impulse Response (FIR) systems, linear phase FIR filters, Infinite Impulse Response (IIR) systems, Discrete Fourier Transforms (DFT), Fast Fourier Transform (FFT), Circular convolution, Transfer functions, and Applications of digital signal processing. Mode: Lecture.
Prerequisite:
EE 3522 (0230) or equivalent
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3.00 Credits
This course considers the design and implementation of data communication for computer systems. Parallel bus architectures and serial data protocols are implemented in simulation using the Verilog hardware description language and behavioral synthesis using the programmable gate array. Topics include: the PC/104+, Multibus and VME parallel buses, the SPI, I2C, USB, Firewire, MIL-STD-1553B serial buses and the performance of error correction and routing for protocols for wired and wireless communication.
Prerequisite:
C+IN SC 1057 (C071)
Corequisite:
EE 4512 (0300)
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3.00 Credits
This course considers digital data communication with complex modulation and error detection and correction in the presence of noise using MATLAB/Simulink simulation. Topics include: quadrature amplitude and continuous phase modulation, frequency hopping and spread spectrum modulation, linear, block, cyclic, convolutional and CRC codes, fading and multipath interference, Doppler shift in mobile environments and the performance of cellular and wireless communication systems.
Prerequisite:
EE 4512 (0300)
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3.00 Credits
This course focuses on Verilog hardware description language and its applications to digital hardware system design including CPU and memory, as well as synchronous and asynchronous events and multitasking in the design of computational and data communication processors. The course will also consider computer-aided-design software and simulators, and hardware description language compilers. Mode: Lecture.
Prerequisite:
EE 3612 (0235)
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3.00 Credits
This course introduces the modern power systems and its changing landscape. Topics include the basics of power generation and transformers, AC transmission and distribution, power flow, economic dispatch, transient and stability analysis, short circuit analysis, and HVDC systems. Mode: Lecture.
Prerequisite:
EE 2322 (0165) and 3312 (0254)
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3.00 Credits
Clips from Hollywood disaster movies will drive our inquiry into geologic phenomena. Can you really drive over a lava flow in a jeep? (Dante’s Peak) Are we foolish not to prepare for a major earthquake in New York City? (Aftershock) Could global warming melt the polar ice caps turning “dry land” into a myth? (Waterworld) Would the impact of an asteroid the “size of Texas” kill half the Earth by heat and freeze the remainder in a nuclear winter? (Armageddon) Learn the fundamentals of plate tectonics, how petrologic properties control volcanic explosivity, how to calculate earthquake locations from seismic data, and prepare a disaster readiness plan for a major U.S. city. Note: This course fulfills a Science & Technology (GS) requirement for students under GenEd and Science & Technology Second Level (SB) for students under Core.
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