Title :
Modular MEMS-based optical cross-connect with large port-count
Author :
Dadap, J.I. ; Chu, P.B. ; Brener, I. ; Pu, C. ; Lee, C.D. ; Bergman, K. ; Bonadeo, N. ; Chau, T. ; Chou, M. ; Doran, R. ; Gibson, R. ; Harel, R. ; Johnson, J.J. ; Lee, S.S. ; Park, S. ; Peale, D.R. ; Rodriguez, R. ; Tong, D. ; Tsai, M. ; Wu, C. ; Zhong, W
Author_Institution :
Tellium Inc., Oceanport, NJ, USA
Abstract :
We describe and demonstrate a modular microelectromechanical systems (MEMS)-based optical cross-connect (OXC) architecture. The OXC port count increases modularly by adding new optical modules, and a maximum cross-connectivity of /spl sim/ 350 /spl times/ 350 can be achieved in the current design. Each optical module has 16 ports with closed-loop servo-controlled MEMS mirrors. Using a prototype OXC system, mounted in a standard telecommunications equipment bay comprising optical modules, folding mirrors, and other optical elements, we demonstrate switching times of less than 10 ms, excellent optical power stability of less than /spl plusmn/ 0.15-dB variation, and immunity to stochastic vibrations. An automatic power peak-up process is performed when the power falls below 0.5-dB off the maximum coupled power for any connection.
Keywords :
micro-optics; micromechanical devices; micromirrors; optical communication equipment; optical couplers; optical switches; folding mirrors; large port-count; maximum cross-connectivity; modular MEMS-based optical cross-connect; modular microelectromechanical systems; optical modules; standard telecommunications equipment bay; stochastic vibrations; switching times; Communication switching; Costs; Fabrics; Lenses; Micromechanical devices; Mirrors; Optical arrays; Optical fiber communication; Optical fiber devices; Optical switches;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2003.819748
