Title :
Computer simulations of fully cascadable picosecond all-optical logic using nonlinear semiconductor etalons
Author :
Richardson, Dean ; Gibbs, H.M. ; Koch, S.W.
Author_Institution :
Opt. Sci. Center, Arizona Univ., Tucson, AZ, USA
fDate :
3/1/1991 12:00:00 AM
Abstract :
A paired semiconductor etalon scheme for all-optical decision making is proposed, and the results of computer simulations of the device concept are presented. In the envisioned architecture, a two-wavelength logic-gate etalon is operated in series with an `upconverter´ etalon to allow cascadable operation on a picosecond time-scale. The paired device achieves a fanout of at least two, as well as good overall contrast, requiring a total input energy of about 75 pJ to perform a single logic operation. The energy requirement might be reduced through the use of multiple-quantum-well materials. The computer simulations of the device behavior are based on a realistic model for the carrier-density-dependent optical nonlinearities of bulk GaAs
Keywords :
digital simulation; integrated optics; nonlinear optics; optical logic; all-optical decision making; architecture; bulk GaAs; cascadable operation; computer simulations; contrast; device concept; energy requirement; fanout; fully cascadable picosecond all-optical logic; multiple-quantum-well materials; nonlinear semiconductor etalons; paired device; paired semiconductor etalon scheme; picosecond time-scale; single logic operation; total input energy; two-wavelength logic-gate etalon; Computer simulation; Fabry-Perot; Frequency; Gallium arsenide; High speed optical techniques; Logic devices; Optical bistability; Optical pumping; Quantum well devices; Switches;
Journal_Title :
Quantum Electronics, IEEE Journal of
