Angular-precision enhancement in free-space micromachined optical switches

Author

Li, L.Y. ; Goldstein, Evan L. ; Tkach, Robert W.

Author_Institution

AT&T Labs.-Res., Red Bank, NJ, USA

Volume

11

Issue

10

fYear

1999

Firstpage

1253

Lastpage

1255

Abstract

Free-space micromachined optical-switching technology has emerged as a promising means of building the large-scale optical crossconnects that will be needed in future optical-transport networks. Although this technology has rapidly demonstrated promising optical performance, its ability to expand to the required port-count has yet to be demonstrated, In particular, the tight angular tolerances imposed by free-space interconnection present a significant challenge, In this letter, we demonstrate integrated mechanical structures that are capable of achieving better than 0.1/spl deg/ micromirror angular repeatability, thus opening the path to high-port-count optical crossconnects that live within cross-office optical-loss budgets.

Keywords

electro-optical switches; measurement errors; micro-optics; micromechanical devices; mirrors; optical communication equipment; optical interconnections; optical losses; 0.1/spl deg/ micromirror angular repeatability; angular-precision enhancement; cross-office optical-loss budgets; free-space interconnection; free-space micromachined optical switches; integrated mechanical structures; large-scale optical crossconnects; optical-transport networks; path to high-port-count optical crossconnects; port-count; ree-space micromachined optical-switching technology; tight angular tolerances; Fasteners; Integrated optics; Micromechanical devices; Micromirrors; Mirrors; Optical crosstalk; Optical fiber networks; Optical fiber polarization; Optical interconnections; Optical switches;

fLanguage

English

Journal_Title

Photonics Technology Letters, IEEE

Publisher

ieee

ISSN

1041-1135

Type

jour

DOI

10.1109/68.789708

Filename

789708