|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
3.00 Credits
Advanced theory of control to linear systems with application to textile processing systems. Transfer matrices, controllability/observability, LQR. Algebraic treatment of feedback systems, coprime factorization. Analytic and harmonic functions, Hdesign.
-
3.00 Credits
Steady state and transient analysis of circuits with emphasis on circuit theory and computer methods. Consideration of many analysis techniques, including linear nodal, signal flow graph, state equation, time-domain and functional simulation and analysis of sampled data systems. Sensitivity and tolerance analysis, macromodeling of large circuits and nonlinear circuit theory.
-
3.00 Credits
Development and examination of techniques for design of microwave and millimeterwave components and systems. Specific topics include mixer, oscillator and amplifier performance and design. This course will focus on the use of S-parameters to aid inthe design of circuits used in mm-wave and microwave circuits. Emphasis will be made on the microwave/mm-wave properties of transistors, matching networks and how these properties are utlized for design for noise, power, mixer or oscillator performance. Computer aided design techniques will be addressed.
-
3.00 Credits
Survey of advanced computer microarchitecture concepts. Modern superscalar microarchitecture, complexity-effective processors, multithreading, advanced speculation techniques, fault-tolerant microarchitectures, power and energy management, impact of new technology on microarchitecture. Students build on a complex simulator which is the basis for independent research projects.
-
3.00 Credits
Materials and device-related electronic properties of semiconductors. Included topics: energy band structure, electrical and thermal transport phenomena, scattering processes, localized energy states, equilibrium and non-equilibrium semiconductor statistics.
-
3.00 Credits
Materials and device-related properties of compound optical semiconductors. Included topics: band structure, heterojunctions and quantum wells, optical constants, waveguides and optical cavities, absorption and emission processes in semiconductors, photodetectors, light emitting diodes, semiconductor lasers.
-
3.00 Credits
Basic physical phenomena responsible for operation of solids-state devices. Examination and utilization of semiconductor transport equations to explain principles of device operation. Various solid-state electronics devices studied in detail.
-
3.00 Credits
Development of advanced engineering concepts at the quantum level relevant to nanoscience, nanoelectronics, and quantum photonics. Topics include tunneling phenomena, specifics of time dependent and time independent perturbation methodology for addressing applications under consideration, including the WKB approach, and an introduction to second quantization for engineers. Applications include, but are not limited to, tunneling in a two-level system, molecular rotation through excitation, field emission, van der Waal interactions, optical absorption in quantum wells, and electron transport through model molecules.
-
3.00 Credits
Advanced topics in dynamical systems and multivariable control. Current research and recent developments in the field.
-
3.00 Credits
Techniques and processes encountered in growth and characterization of epitaxial semiconductor thin films. Interactions of gases at solid interfaces and gas phase dynamics related to epitaxial processes. Example of growth techniques are: solution growth, molecular beam epitaxy and chemical vapor deposition. Film characterization includes electrical, structural, optical, and chemical techniques. Issues involved in epitaxial growth such as: lattice match, critical layer thickness, heterostructures, superlattices and quantum wells.
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2024 AcademyOne, Inc.
|
|
|