Er-doped superfluorescent fiber source with a //sup +/sub -//0.5-ppm long-term mean-wavelength stability

Abstract

We report an Er-doped superfluorescent fiber source (SFS) with a record mean-wavelength stability of /spl plusmn/0.5 ppm over 17 h. This breakthrough was achieved in a double-pass SFS by implementing several improvements, namely 1) controlling all the parameters that affect its mean wavelength, including the pump diode temperature and current, 2) reducing polarization-induced drifts in mean wavelength with a Faraday rotator mirror and a long Er-doped fiber (EDF), and 3) getting rid of polarization controllers to eliminate polarization-dependent loss. The long-term mean-wavelength variations of this SFS were due almost entirely to variations in the EDF temperature. When the SFS temperature was allowed to vary, by calibrating its mean-wavelength dependence on temperature, it was possible to predict the mean wavelength to a /spl plusmn/2-ppm precision by simply measuring the EDF temperature. The same configuration was also implemented with a different Er-doped fiber to achieve an even lower dependence on EDF temperature. When controlling the temperature of this second SFS to about /spl plusmn/0.5/spl deg/C, it exhibited a stability of /spl plusmn/0.5 ppm over 17 h. These new developments constitute an important step toward a practical high-grade fiber-optic gyroscope.