Title :
Novel analog self-electrooptic-effect devices
Author :
Miller, David A B
Author_Institution :
AT&T Bell Labs., Holmdel, NJ, USA
fDate :
2/1/1993 12:00:00 AM
Abstract :
Circuits and modes of operation for quantum-well self-electrooptic-effect devices (SEEDs) are proposed that allow analog processing of optical images and arrays. Analog functions performed include addition, subtraction, uniform amplification, replication, spatial differentiation, convolution, cross-correlation, and optically controllable weights for matrix-vector processors or neural networks. Many of the devices can operate with differential parts of light beams, allowing full bipolar analog processes, and other devices can convert between differential and single-beam representations. Many of the circuits could be made using the existing SEED array process. The devices should be sensitive enough to allow direct processing at video frame rates of scenes under normal room illumination. Operating speeds of up to nanoseconds are predicted for proportionately higher powers
Keywords :
SEEDs; image processing; integrated optoelectronics; optical information processing; optical neural nets; semiconductor quantum wells; addition; analog processing; analog self-electrooptic-effect devices; arrays; circuits; convolution; cross-correlation; differential representation; direct processing; full bipolar analog processes; matrix-vector processors; neural networks; normal room illumination; operation modes; optical images; optically controllable weights; quantum well SEED; replication; self linearised modulation; single-beam representations; spatial differentiation; subtraction; uniform amplification; video frame rates; Circuits; Convolution; Optical arrays; Optical computing; Optical control; Optical devices; Optical fiber networks; Optical sensors; Quantum well devices; Stimulated emission;
Journal_Title :
Quantum Electronics, IEEE Journal of
