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Course Criteria
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0.00 Credits
No course description available.
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0.00 Credits
No course description available.
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4.00 Credits
Fundamentals of digital logic design methodology including analysis, synthesis, optimization, simulation, and implementation. Multi-level combinational circuits, synchronous sequential circuits, and Finite State Machines. Programmable logic devices (PLD’s), Computer Aided Design tools (CAD) and Very High Speed IC Hardware Description Language (VHDL) and schematic capture.
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4.00 Credits
Signal representation with applications to circuits: AC circuits and phasors, complex frequency, amplifiers and filters, resonance, two-port networks, Laplace transforms. Fourier series, Fourier transforms.
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4.00 Credits
Instruction set principles; processor design, pipelining, data and control hazards; datapath and computer arithmetic; memory systems; I/O and peripheral devices; internetworking. Students learn the challenges, opportunities, and tradeoffs involved in modern microprocessor design. Assignments and labs involve processor and memory subsystem design using hardware description languages (HDL).
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4.00 Credits
intended for physical scientists and (non-electrical) engineers. Electrical concepts will be developed based on modern needs and techniques: Current, Voltage, Components, Microcontrollers, Sources, Operational Amplifiers, Analysis Techniques, First and Second Order Circuits, Timing with Microcontrollers, Sinusoids and AC, Controlling Motors and Power Circuits.
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4.00 Credits
An introduction to the design and analysis of digital and analog integrated circuits. Technologies, such as NMOS, CMOS, GaAs, Bipolar, and BiCMOS will be discussed. Semiconductor processing and device models will be developed and applied. Specific circuit structures will be analyzed and their time/frequency responses evaluated and interpreted.
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4.00 Credits
The objective of this course is to make engineering and physical science majors conversant in the important elements of electric power, from conversion to consumption. We will describe how the principal sources of energy - coal, natural gas, impounded water (hydroelectric), and fissile materials - are exploited to create electric power, to study how it is distributed through the grid and finally then how it is consumed. To assure that students gain a proper appreciation for the factors that determine the real cost of electricity per kilowatt-hour, the subject will be treated in a highly quantitative way. The goal will be to provide students with the information and tools they need for informed analysis of the true prospects and technological challenges of new energy sources, such as biomass, wind power, and oil shales, and assessment of the opportunities to improve distribution and usage efficiency through a Smart Grid.
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4.00 Credits
Communication systems overview, Analog signal transmission and reception, Amplitude and Frequency Modulation: bandwith, power, and complexity trade-offs, elements of random processes. Noise in communication systems, Performance of analog communication systems in the presence of noise. Digital communication system overview, Sampling and quantization, Digital baseband transmisson over aditive white Gaussian noise channels, Optimum reeiver principles, Baseband binary PAM and matched filter receiver, Geometric signal representaion. Introductory information theory
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4.00 Credits
In this course students are introduced to the advanced concepts and principles of dynamic systems and linear control. The course emphasizes a state space approach. Topics covered include state-space models, modes, stability, controllability, observability, transfer function matrices, poles and zeros, and state feedback.
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