Title :
Performance of multiwavelength simultaneous monitoring circuit employing arrayed-waveguide grating
Author :
Teshima, Mitsuhiro ; Koga, Masafumi ; Sato, Ken-Ichi
Author_Institution :
NTT Opt. Network Syst. Lab., Kanagawa, Japan
fDate :
10/1/1996 12:00:00 AM
Abstract :
This paper proposes a novel multiwavelength simultaneous monitoring (MSM) circuit that uses the wavelength crossover properties of an arrayed-waveguide grating (AWG). The MSM circuit consists of an AWG, a stabilized semiconductor laser as a reference light, and logarithmic amplifiers. The AWG chip is a simple planar-lightwave-circuit chip. It functions as multiple optical filters, and make it possible to monitor multiple wavelengths simultaneously. The MSM circuit, locked to the reference wavelength produced by a semiconductor laser stabilized to the 1547.49 mn 13C2 H2 absorption line, achieved 10 MHz resolution and 30 MHz stability for 24 h in the stable polarization state. Measurement accuracy of better than 1.1 GHz can be realized even if the state of polarization of the input light fluctuates at random. Multiwavelength simultaneous monitoring is successfully demonstrated using tunable lasers
Keywords :
arrays; diffraction gratings; laser frequency stability; laser tuning; light polarisation; optical planar waveguides; optical variables measurement; optical waveguide filters; semiconductor lasers; 1547.49 nm; 24 h; 30 MHz; 13C2H2 absorption line; AWG chip; acetylene; arrayed-waveguide grating; logarithmic amplifiers; measurement accuracy; multiple optical filters; multiwavelength simultaneous monitoring circuit; performance; reference light; reference wavelength; resolution; simple planar-lightwave-circuit chip; stability; stabilized semiconductor laser; stable polarization state; tunable lasers; wavelength crossover properties; Absorption; Arrayed waveguide gratings; Circuits; Laser stability; Monitoring; Optical filters; Optical polarization; Semiconductor laser arrays; Semiconductor lasers; Semiconductor optical amplifiers;
Journal_Title :
Lightwave Technology, Journal of
