Experimental demonstration of thin-film dispersion compensation for 50-GHz filters

Experimental demonstration of thin-film dispersion compensation for 50-GHz filters

Dispersion management is critical for next-generation high-bandwidth-utilization fiber-optical networks. Square-top thin-film bandpass filters for 50-GHz dense wavelength-division multiplexing inherently have high chromatic dispersion (CD) in transmission. The imparted dispersion power penalty on th...

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Veröffentlicht in:IEEE photonics technology letters 2003-01, Vol.15 (1), p.66-68
Hauptverfasser: Tilsch, M., Hulse, C.A., Zernik, F.K., Modavis, R.A., Addiego, C.J., Sargent, R.B., O'Brien, N.A., Pinkney, H., Turukhin, A.V.
Format: Artikel
Sprache:eng
Schlagworte:
Band pass filters
Bandpass filters
Chromatic dispersion
Dispersions
Fiber optics
Multiplexing
Networks
Next generation networking
Optical fiber dispersion
Optical fiber filters
Optical fibers
Optical reflection
Passband
Performance loss
Reflection
Simulation
Thin films
Transistors
Wavelength division multiplexing
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Zusammenfassung:Dispersion management is critical for next-generation high-bandwidth-utilization fiber-optical networks. Square-top thin-film bandpass filters for 50-GHz dense wavelength-division multiplexing inherently have high chromatic dispersion (CD) in transmission. The imparted dispersion power penalty on the network is undesirable. However, a second thin-film filter, operating in reflection, can be designed to compensate the CD of the bandpass filter. In this paper we demonstrate experimentally the reduction of the intrinsic CD of a 50-GHz thin-film coupler from /spl plusmn/170 ps/nm to /spl plusmn/50 ps/nm over a 30-GHz passband, through the use of such a cascaded thin-film compensator. Network simulations based on filter performance confirm the reduced dispersion power penalty of the cascade over the individual filter.
ISSN:1041-1135
1941-0174
DOI:10.1109/LPT.2002.805747