Electrical EngineeringThe Ohio State University
Electrical Engineering
One view of the new Photonics Lab.
In the Department of Electrical Engineering, the optics area is trans- disciplinary across several technical areas. Most, but not all, optics-related courses will have the middle digit of the course number as "1", representing electromagnetics, or "3" representing Solid State and Physical Electronics. At Ohio State, courses beginning with "6" and "7" are open to both graduates and undergraduates, while course beginning with "8" or "9" are open only to graduate students. OSU is on the quarter system. The following courses are currently offered:
EE731 Fiber Optics Prof. Anderson or Prof. Clymer , 3 units, Spring. Waveguiding in optical fibers, fiber losses, optical sources (LEDs and lasers), numerical aperture, coupling, detectors and receivers, noise sources, optical link analysis. Includes brief introduction to fiber sensors. Prerequisites: EE311, EE321 or equivalents, or permission.
EE732 Quantum Electron Devices: Lasers Prof. Anderson or Prof. Clymer , 4 units, Odd Autumns (i.e. 1999, 2001...). Interaction of radiation with atomic systems, theory of laser oscillation, electro-optic effects, propagation of laser beams, optical resonators, specific laser systems. Prerequisites: EE432 and EE513, or graduate standing in engineering, physics, chemistry, etc., or permission.
EE737 Photonics Lab Prof. Anderson , 4 credits, odd winter quarters- will run next in Winter 2001. Lab
includes experiments in fiber optic communications, optical sensing, solar
cells, acousto-optics, quantum well detectors, laser diode physics, and liquid
crystals. Students do some subset of these experiments. In the process, you'll
learn to use optics-related equipment including spectrometers,lock-in
amplifiers, infrared viewers, CCD cameras and laser beam diagnostic
machines.
The Optical Sensing experiment is a design
project. You can design (and build) any kind of optical sensor you want!
(Temperature, pressure, roommate detector...)
In Liquid Crystals,
you can make your own liquid crystal light shutter!
In Acousto-
Optics, you build a scanner and and optical switch!
In Quantum
Well Detectors, you will believe in excitons and all that stuff we
told you in quantum mechanics!
In Solar Cells, you'll compare
the efficiencies of a variety of solar cell designs and materials!
In Fiber
Optic Communication, you'll learn to cleave and couple fibers, and
loook at bit-error-rate as a function of splice loss (you may personally mess up
the splice!).
In Lasers Diode Physics, you'll actually see the
difference (in a variety of convincing ways) the differences between
spontaneous and stimulated emission, and you'll also get to fool around with
the laser cavity to look for mode hopping!
InHolography, you'll make holograms! Need we say more?
InOptical Spatial Filtering you'll perform some optical image processing! Get a feel for some ideas in optical computing.
There is an ancillary lecture
covering additional useful practical optics topics, such as optical laboratory
components, detectors, flat panel displays, and particularly laser safety.
Prerequisites: EE432 and EE 312 or grad standing in engineering.
EE833 Optical Effects in Materials and Devices Prof. Anderson, 3 units, even autumns (i.e., 2000, 2002...). Topics include Pockels effect, electro-optic effect, acousto-optic effect, liquid crystal birefringence effect for various states, multiple quantum-well optical switches, magneto-optic effect, Kerr rotation, optical storage materials (laser disks). Prof. Anderson, for more info.
EE917 Advanced Topics in Optics Prof. Collins This course is offered whenever the mood seizes Prof. Collins, and it does happen from time to time! Contact him for next projected offering. Topics: Fiber and integrated optics and their applications, optical transfer functions, aberrations, optical thick holograms, numerical optical computing, and liquid crystals. Prerequisite: EE716 or permission of Instructor.
EE713 Elements of Radio Wave Propagation Prof. Johnson 3 credits,
spring. Practical calculations and
procedures for predicting refraction and reflection by a plane or spherical
earth; tropospheric, ionosphereic, and scatter propagation. Prerequisites:
EE513 (electromagnetics, waveguides, diffraction) or equivalent.
EE730 (Currently EE 694R) Fundamentals of Semiconductors for Microelectronics and Optoelectronics Prof. Ringel 3 units, autumn. Background for further studies in electronic and optical semiconductor devices. Crystal structure, electronic band theory, optical properties of semiconductors, electron transport, compound semiconductors and quantum wells, applications to electronic and optoelectronic devices. Prerequisites: EE 432 or permission.
EE832 High-speed Semiconductor Devices Prof. Roblin 3 credits, even springs ('96, '98). Principles underlying the operation and application of high-speed solid state active devices, electron transport in high fields, Gunn effect, superlattices, heterostructures, and modulation doped devices. Many of these structures are used in optoelectronic devices. Prerequisites: EE730
EE863 Machine Vision Prof. Boyer , 3 units, winter. See Prof. Boyer to verify
scheduling. Computer vision systems, image models, edge detection, feature
extraction, segmentatic shape representation, morphology, structural
descriptions, object modeling, matching, knowledge bases, semantic
knowledge, architectures, and depth perception. Prerequisites: EE650 and
EE700.