DocumentCode
1432927
Title
Dynamic spectral power equalization using micro-opto-mechanics
Author
Ford, J.E. ; Walker, J.A.
Author_Institution
Bell Labs., Lucent Technol., Holmdel, NJ, USA
Volume
10
Issue
10
fYear
1998
Firstpage
1440
Lastpage
1442
Abstract
We present a voltage-controlled spectral attenuator for gain shaping and power equalization in wavelength division multiplexed single-mode fiber systems. A micro-opto-mechanical modulator array, where electrostatic deflection of a silicon nitride quarter-wave dielectric layer suspended over a silicon substrate creates a column of variable reflectivity mirrors, is packaged using bulk optics and a diffraction grating to disperse the input spectrum across the device and collect the reflected light into a separate output fiber. The packaged component has 9-dB excess loss, 20-dB dynamic range and 10-μs response. We demonstrate equalization of the amplified spontaneous emission spectrum from an erbium-doped fiber amplifier and of individual laser signals with 10-dB initial variation to less than 0.5-dB variation over a 24-nm passband-free spectrum.
Keywords
diffraction gratings; electro-optical devices; equalisers; micromechanical devices; mirrors; optical communication equipment; optical films; reflectivity; semiconductor device packaging; superradiance; wavelength division multiplexing; /spl mu/s response; 10 mus; 9 dB; amplified spontaneous emission spectrum; bulk optics; dB initial variation; diffraction grating; dynamic range; dynamic spectral power equalization; electrostatic deflection; erbium-doped fiber amplifier; excess loss; gain shaping; individual laser signals; input spectrum; micro-opto-mechanical modulator array; micro-opto-mechanics; packaged; packaged component; passband-free spectrum; power equalization; reflected light collection; separate output fiber; silicon nitride quarter-wave dielectric layer; silicon substrate; variable reflectivity mirrors; voltage-controlled spectral attenuator; wavelength division multiplexed single-mode fiber systems; Dielectric substrates; Electrostatics; Optical arrays; Optical attenuators; Optical fiber devices; Optical modulation; Packaging; Silicon; Voltage; Wavelength division multiplexing;
fLanguage
English
Journal_Title
Photonics Technology Letters, IEEE
Publisher
ieee
ISSN
1041-1135
Type
jour
DOI
10.1109/68.720287
Filename
720287
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