Title :
Modeling of MEMS tunable optoelectronic device mirror
Author :
Lin, Chien-chung ; Martin, Wayne A. ; Harris, James S., Jr. ; Chan, Edward
Author_Institution :
Solid State & Photonics Lab., Stanford Univ., CA, USA
Abstract :
The rapid growth of data communication requires more information to be sent through the existing fiber system. This demand can be met using WDM. However, such systems will require many different fixed wavelength devices or tunable devices. Surface micromachined tunable optoelectronic devices provide a potentially low-cost solution for WDM transmitting/receiving systems. To optimize optical performance and tunability of devices, a highly reflecting tunable mirror is needed. Among the materials which are commonly used, AlOx/GaAs possesses the largest refractive index contrast. This huge contrast will achieve a higher reflectance and greater bandwidth with a smaller number of DBR pairs when compared to other material combinations. We previously reported a new type of top DBR mirror using AlOx/GaAs which also has a lower tuning voltage. The design issues of this new mirror structure are discussed. Two different top membrane structures were fabricated and their performance compared
Keywords :
aluminium compounds; gallium arsenide; laser mirrors; laser tuning; membranes; micro-optics; optical communication equipment; wavelength division multiplexing; AlO-GaAs; AlOx/GaAs mirror; DBR pairs; MEMS tunable optoelectronic device mirror; WDM systems; highly reflecting tunable mirror; lower tuning voltage; membrane structures; modeling; performance; top DBR mirror; Data communication; Distributed Bragg reflectors; Gallium arsenide; Micromechanical devices; Mirrors; Optical fiber communication; Optical fiber devices; Optical surface waves; Optoelectronic devices; Wavelength division multiplexing;
Conference_Titel :
Optical MEMS, 2000 IEEE/LEOS International Conference on
Conference_Location :
Kauai, HI
Print_ISBN :
0-7803-6257-8
DOI :
10.1109/OMEMS.2000.879646
