Title :
Wavelength and Bandwidth Tunable TPA Semiconductor Microcavity Detector for High-Speed Signal Processing in WDM Systems
Author :
Bondarczuk, Krzysztof ; Boucher, Yann G. ; Besnard, Pascal ; Reid, Douglas ; Barry, Liam P.
Author_Institution :
Res. Inst. for Networks & Commun. Eng., Dublin City Univ., Dublin, Ireland
Abstract :
We propose a novel design for a semiconductor microcavity nonlinear detector, based on two-photon absorption, for high-speed signal processing applications in future wavelength division multiplexing (WDM) systems. By inserting a phase section and a gain section in the resonant cavity, we could achieve wavelength and bandwidth tunability of the nonlinear detector. Theoretical investigation is carried out in the frame of an extended transfer matrix formalism, leading to the self-consistent calculation of the device properties. We model the design and characteristics of a GaAs/AlGaAs microcavity suitable for selective processing of different WDM channels, operating at various data rates and modulation formats.
Keywords :
III-V semiconductors; SCF calculations; aluminium compounds; cavity resonators; gallium arsenide; light absorption; micro-optics; microcavities; optical design techniques; optical information processing; optical tuning; two-photon processes; wavelength division multiplexing; GaAs-AlGaAs; WDM systems; bandwidth tunable semiconductor microcavity detector; gain section; high-speed signal processing; nonlinear detector; phase section; resonant cavity; self-consistent calculation; transfer matrix formalism; two-photon absorption; wavelength division multiplexing; wavelength tunable semiconductor microcavity detector; Absorption; Cavity resonators; Gallium arsenide; Microcavities; Mirrors; Nonlinear optics; All-optical signal processing; modeling; multisection vertical-cavity device; transfer matrix formalism; transparent networks; two-photon absorption;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2010.2052589
