Here you will find all availble EECS courses listed alphabetically. The tabs above futher organize the courses by the starting letter of the course name. If there is a courses that you cannot find listed, or have questions about a course that are not answered by the courses description feel free to Contact Us.
A colloquium series related to electrical engineering, computer engineering and computer science Course will be graded Satisfactory/Fail. Required for all EECS graduate students.
Prerequisite(s): No Prerequisite.
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An introductory course on electric power generation and transmission. Topics will include: electric power system components; environmental impact; renewable energy sources; power system networks and flow; synchronous generators; transformers; high voltage transmission systems; power quality; stability; blackouts. Prerequisites: EECS 212 or EECS 315 and EECS 220 or PHSX 212.
Prerequisite(s): EECS 212 or EECS 315 and EECS 220 or PHSX 212
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Introduction to DC and AC electrical circuit analysis techniques, AC power calculations, transformers, three-phase systems, magnetic circuits, and DC and AC machines with a focus on applications. Not open to electrical or computer engineering majors.
Prerequisite(s): A course in differential equations and eight hours of physics.
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A study of unwanted generation and reception of radio-frequency radiation from analog and digital electronic systems and how these emissions/receptions can be reduced. Topics covered include sources of radiation, grounding, shielding, crosstalk, electrostatic discharge, and practical design and layout schemes for reducing unwanted radiation and reception. Also covered are the major governmental electromagnetic compatibility (EMC) regulations and standards that apply to commercial electronic devices and system
Prerequisite(s): EECS 220 and EECS 312
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Polarimetric plane-wave propagation, including the complex propagation matrix and Stokes vector representation. Electromagnetic scattering, including the scattering matrix, Mueller matrix, scattering cross-section, absorption cross-section, Mie scattering, and Rayleigh scattering. Volume scattering in random media, including the Born approximation, Rayleigh scattering statistics, multiple scattering mechanisms, Radiative transfer theory, and volume scattering above a dielectric half-space. Propagation through random media, including the extinction coefficient, the optical theorem, and the distorted Born approximation. Scattering from rough surfaces, including the Kirchoff, Physical Optics, and small-pertubation models.
Prerequisite(s): EECS 720.
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Topics in electromagnetics relevant to wireless communications, optics and fiberoptics, radar and remote sensing. Subjects covered included space waves, guided waves, radiation and antennas, scattering, electromagnetic properties of materials, and optics.
Prerequisite(s): EECS 420 or equivalent
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Vector analysis. Electrostatic and magnetostatic fields in a vacuum and material media. Electromagnetic fields and Maxwell's equations for time-varying sources. The relationship between field and circuit theory. Simple applications of Maxwell's equations.
Prerequisite(s): MATH 220, MATH 290, PHSX 211 and EECS 211
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This course applies electromagnetic analysis to high frequency devices and systems where wave propagation effects cannot be neglected. Topics covered include waves, transmission lines, space waves, waveguides, radiation, and antennas. Laboratory experiments include transmission line, waveguide, and antenna measurements and characterizations. 3 hours lecture, 1 hour laboratory.
Prerequisite(s): EECS 220 and upper-level EECS eligibility
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Introduction to diodes, BJT’s and MOSFET’s and their use in electronic circuits, especially digital circuits.
Prerequisite(s): Upper-level EECS eligibility. Corequisite: EECS 212
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Discrete and integrated amplifier analysis and design. Introduction to feedback amplifier analysis and design. Introduction to feedback amplifiers.
Prerequisite(s): EECS 312 and upper-level EECS eligibility
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Feedback amplifier circuit analysis, power amplifiers, analog IC op-amp techniques and analysis, filter approximation and realization, oscillators, wave generators and shapers.
Prerequisite(s): EECS 412
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An introduction to crystal structures, and metal, insulator, and semiconductor properties. Topics covered include the thermal, electric, dielectric, and optical properties of these materials. A significant portion of this course is devoted to the properties of semiconductors and semiconductor devices.
Prerequisite(s): PHSX 313 and upper-level EECS eligibility
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Introduction to operational amplifiers, semiconductors, digital circuits and systems, and electronic instrumentation and measurements with a focus on applications. Not open to electrical or computer engineering majors. Students may not receive credit for both EECS 316 and EECS 317.
Prerequisite(s): EECS 315
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This course will cover emerging and proposed techniques and issues in embedded and real time computer systems. Topics will include new paradigms, enabling technologies, and challenges resulting from emerging application domains
Prerequisite(s): EECS 645 and EECS 678
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A study of communication channels and the coding problem. An introduction to finite fields and linear block codes such as cyclic, Hamming, Golay, BCH, and Reed-Solomon. Convolutional codes and the Viberbi algorithm are also covered. Other topics include trellis coded modulation, iterative (turbo) codes, LDPC codes.
Prerequisite(s): EECS 862
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