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Course Criteria
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4.00 Credits
Course will cover circuits and sensors used to measure physiological systems at an advanced level. Both signal conditioning and sensor characteristics will be addressed. Topics will include measurement of strain, pressure, flow, temperature, biopotentials, and physical circuit construction. The co-requisite laboratory will focus on the practical implementation of electronic devices for biomedical measurements.
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4.00 Credits
Senior design course. Prior faculty approval required or design project proposal.
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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
No course description available.
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2.00 Credits
Study of ethical, social, economic and safety considerations that arise in engineering practice by discussion of appropriate novels, movies, essays, videos and other materials. Presentations by outside speakers.
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4.00 Credits
Advanced topics in the organization, architecture, and implementation of modern memory subsystems. Topics include power, performance, reliability, and QoS issues in DRAM memory systems and Flash-based SSDs; high-performance memory controllers and interfaces; memory system design for datacenters and enterprise systems; and an introduction to emerging resistive memory technologies.
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4.00 Credits
This course provides in-depth discussions of the design and implementation issues of microprocessors and general-purpose computing systems based on them. The course is intended for students doing research in computer architecture or a closely related area to understand the advanced topics in the design of microarchitecture, the coherence and communication substrate, emerging issues and challenges in the design stack (e.g., energy efficiency, reliability, and complexity), and their interplay.
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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
Acoustic wave equation; plane, spherical, and cylindrical wave propagation; reflection and transmission at boundaries; normal modes; absorption and dispersion; radiation from points, spheres, cylinders, pistons, and arrays; diffraction; nonlinear acoustics.
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