Title :
Multistate optical memory based on serially interconnected lasers
Author :
Zhang, Shaoxian ; Owens, Dan ; Liu, Yong ; Hill, Martin ; Lenstra, Daan ; Tzanakaki, Anna ; Khoe, Giok-Djan ; Dorren, H.J.S.
Author_Institution :
COBRA Res. Inst., Eindhoven Univ. of Technol., Netherlands
Abstract :
A multistate optical memory based on serially interconnected lasers is presented. We show that only one of the lasers can lase at a time, thus, the state of the optical memory is determined by the wavelength of the dominant laser. The light from the dominant laser suppresses its neighboring lasers through gain saturation, but still receives amplification by the active element of the suppressed lasers, compensating for coupling losses. This light passes through each of the successive lasers, simultaneously suppressing and being amplified. By this mechanism, all other lasers are suppressed. A five-state optical memory based on this concept is experimentally demonstrated. The contrast ratio between different states is over 30 dB. Dynamic flip-flop operation based on two different all-optical switching methods is also demonstrated.
Keywords :
flip-flops; integrated optoelectronics; laser cavity resonators; optical couplers; optical interconnections; optical losses; optical storage; optical switches; semiconductor optical amplifiers; Fabry-Perot cavity; all-optical switching; contrast ratio; coupling losses; dynamic flip-flop operation; five-state optical memory; gain saturation; multistate optical memory; semiconductor optical amplifier; serially interconnected lasers; Optical bistability; Optical coupling; Optical interconnections; Optical saturation; Optical signal processing; Power lasers; Ring lasers; Semiconductor lasers; Semiconductor optical amplifiers; Stimulated emission; Multivalued optical logic; optical bistability; optical memories; semiconductor optical amplifiers (SOAs);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2005.853527
