Title :
1D MEMS-based wavelength switching subsystem
Author :
Mechels, Steve ; Muller, Lilac ; Morley, G. Dave ; Tillett, Doug
fDate :
3/1/2003 12:00:00 AM
Abstract :
Over the past few years, micro-electromechanical systems (MEMS) have emerged as a leading technology for realizing transparent optical switching subsystems. MEMS technology allows high-precision micromechanical components such as micromirrors to be mass produced at low cost. These components can be precisely controlled to provide reliable high-speed switching of optical beams in free space. Additionally, MEMS offers solutions that are scalable in both port (fiber) count and the ability to switch large numbers of wavelengths (> 100) per fiber. To date, most of this interest has focused on two-dimensional and three-dimensional MEMS optical crossconnect architectures. We introduce a wavelength-selective switch based on one-dimensional MEMS technology and discuss its performance, reliability, and superior scaling properties. We also review several important applications for this technology in all-optical networks.
Keywords :
micromechanical devices; micromirrors; optical switches; wavelength division multiplexing; 1D MEMS technology; 2D MEMS optical crossconnect; DWDM; all-optical networks; dense wavelength-division multiplexing; fiber count; high-precision micromechanical components; micro-electromechanical systems; micromirrors; one-dimensional MEMS technology; optical beams; port count; reliable high-speed switching; scaling properties; transparent optical switching subsystems; two-dimensional MEMS optical crossconnect architecture; wavelength switching subsystem; Costs; High speed optical techniques; Microelectromechanical systems; Micromechanical devices; Micromirrors; Optical beams; Optical control; Optical switches; Space technology; Telecommunication network reliability;
Journal_Title :
Communications Magazine, IEEE
DOI :
10.1109/MCOM.2003.1186550
