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Course Criteria
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3.00 Credits
Active participation in research, under the supervision of a faculty adviser, leading to a doctoral dissertation. Grades of IP are assigned until the dissertation has been publicly defended, approved by the doctoral committee, and accepted by the Office of Graduate Education to be archived in a standard format in the library. Grades will then be listed as S. Credit Hours: Up to 30
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3.00 Credits
Techniques for the analysis and simulation of linear electric circuits, and measurements of their properties. Topics include resistive and energy-storage elements, controlled sources and operational amplifiers, systematic analysis methods, AC steady state, power and three-phase systems, magnetic coupling and transformers, transients, s-plane representation and analysis, frequency response, and Laplace transform and computer-aided methods. Prerequisites/Corequisites: Prerequisites: MATH 2400 and PHYS 1200. When Offered: Fall, spring, and summer terms annually. Credit Hours: 4 Contact, Lecture or Lab Hours: 6 contact hours
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3.00 Credits
The physics and operation of semiconductor diodes, bipolar junction transistors, and field-effect transistors in elementary analog circuits. Amplifier biasing, small-signal analysis, and frequency response. Elementary bipolar and MOSFET digital circuits, analog-to-digital and digital-to- analog conversion. Prerequisites/Corequisites: Prerequisite: ECSE 2010. When Offered: Fall, spring, and summer terms annually. Credit Hours: 4 Contact, Lecture or Lab Hours: 6 contact hours
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3.00 Credits
Development and application of Maxwell's equations in free space and within materials. Introduction to vector calculus and computer-aided analysis and design methods in electromagnetics. Applications include calculation of lumped circuit elements from field theory, plane wave propagation in various materials, and reflection from boundaries. Transmission line concepts, Smith charts, and other design tools for distributed circuits. Prerequisites/Corequisites: Prerequisite: ECSE 2010. When Offered: Fall, spring, and summer terms annually. Credit Hours: 4 Contact, Lecture or Lab Hours: 6 contact hours
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3.00 Credits
An introductory survey of microelectronics technology emphasizing physical properties of semiconductors, device and circuit fabrication, semiconductor device operation, IC layout and design, and related CAD software. Topics include semiconductor crystals; energy bands; electronics and holes; dopant impurities; fabrication and operation of diodes, bipolar junction transistors, and field-effect transistors; CMOS chip design. Prerequisites/Corequisites: Prerequisite: ECSE 2010. Corequisite: ECSE 2100 or PHYS 4210. When Offered: Fall and spring terms annually. Credit Hours: 4 Contact, Lecture or Lab Hours: 6 contact hours
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4.00 Credits
Time and frequency-domain representation of continuous-and discrete-time signals and systems, and solutions of their response. Simulation of linear systems. Fourier series and transform. Laplace transform and z-transform. Stability, feedback systems, and root-locus analysis and design. Applications involving communication and control systems. Prerequisites/Corequisites: Prerequisite: ECSE 2010. When Offered: Fall, spring, and summer terms annually. Credit Hours: 4
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3.00 Credits
Design-oriented introduction to computer components and operations. Standard codes, number systems, base conversions, and computer arithmetic. Boolean algebra, minimization and synthesis techniques for combinational and sequential logic. Races, hazards, and asynchronous behavior. Registers, arithmetic logic units, memory structure, buses, and control units. Machine language programming, instruction fetch and execution, input-output devices, interrupts, and microprogram sequencers. Software and hardware tools. Prerequisites/Corequisites: Prerequisite: CSCI 1100. Corequisite: ENGR 2350. When Offered: Fall, spring, and summer terms annually. Credit Hours: 4 Contact, Lecture or Lab Hours: 6 contact hours
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3.00 Credits
Quantitative basis of modern computer architecture, processor design, memory hierarchy, and input/output methods. Layered operating system structures, process and storage management. Layered network organization, network protocols, switching, local and wide area networks. Examples from Unix and the Internet. Prerequisites/Corequisites: Prerequisite: ECSE 2610. When Offered: Spring term annually. Credit Hours: 4 Contact, Lecture or Lab Hours: 6 contact hours
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3.00 Credits
An introduction to sensing and imaging methods using electromagnetic radiation, including hands-on experiments. Topics include physical principles of sensing/imaging, instrumentation anddata acquisition strategies and computational methods for image formation and sensing. Emphasis is placed on imaging with visible light and near infrared spectrum, diffuse optical imaging and spectroscopy, x-ray imaging and computed tomography and radar. Application areas include medicine and biology, security and surveillance, environmental and chemical sensing, and buried or hidden objects. Prerequisites/Corequisites: Prerequisites: PHYS 1200 and MATH 2400. When Offered: Spring term annually Cross Listed: Cross-listed as BMED 2800. Students cannot receive credit for both this course and BMED 2800. Credit Hours: 3
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1.00 Credits
Introduction to research as a professional activity in electrical, computer, and systems engineering for participants in the ECSE Honors Program. Admission to the program is by application or invitation only, made during the fall term of the sophomore year. This seminar can be taken more than once. When Offered: Spring term annually. Credit Hours: 1 Contact, Lecture or Lab Hours: 2 contact hours
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