Title :
High-density micromachined polygon optical crossconnects exploiting network connection-symmetry
Author :
Lin, L.Y. ; Goldstein, E.L. ; Simmons, J.M. ; Tkach, R.W.
Author_Institution :
AT&T Bell Labs., Red Bank, NJ, USA
Abstract :
Optical-layer crossconnects with high port count appear to be emerging as key elements for provisioning and restoration in future wavelength-division-multiplexed networks. We demonstrate here a means of achieving high-density optical crossconnects utilizing free-space micromachined optical switches that exploit connection-symmetry in core-transport networks. The micromachined polygon switches proposed here are strictly nonblocking. Measured insertion losses of 3.1-3.5 dB for a 16/spl times/16 (8/spl times/8 bidirectional) switch suggest the promise of scaling to large port count.
Keywords :
electro-optical switches; integrated optoelectronics; micromachining; optical communication equipment; optical interconnections; optical losses; symmetry; wavelength division multiplexing; 3.1 to 3.5 dB; bidirectional switch; connection-symmetry; core-transport networks; free-space micromachined optical switches; future wavelength-division-multiplexed networks; high port count; high-density micromachined polygon optical crossconnects; high-density optical crossconnects; insertion losses; large port count; micromachined polygon switches; network connection-symmetry; optical-layer crossconnects; strictly nonblocking; Fabrics; Insertion loss; Intelligent networks; Loss measurement; Optical crosstalk; Optical fiber networks; Optical losses; Optical switches; Symmetric matrices; Wavelength measurement;
Journal_Title :
Photonics Technology Letters, IEEE
