Title :
Ultrahigh-Resolution Ratio-Metric Wavelength Monitors Based on Tunable Microrings on Silicon
Author :
Ao Shen ; Chen Qiu ; Changyun Zhao ; Tingge Dai ; Yinlei Hao ; Xiaoqing Jiang ; Jianyi Yang
Author_Institution :
Dept. of Inf. Sci. & Electron. Eng., Zhejiang Univ., Hangzhou, China
Abstract :
An ultrahigh-resolution ratio-metric wavelength monitor based on microring resonators (MRRs) is demonstrated on silicon. The theoretical wavelength resolution is related to the functional wavelength range and the quality (Q)-factor of the microring. We analyze the relationship and experimentally demonstrate that the functional range and the resolution can be adjusted by thermally tuning the resonance spacing of the MRRs. The resolution is also limited by the noise introduced in the measurements. An ultrahigh experimental resolution of 1.5 pm is obtained within a 0.72 nm functional range and an ultrahigh theoretical extreme resolution of ~0.4$ pm can be expected considering of the intrinsic systems noise only. The causes of the difference between the experimental and theoretical resolution and the measures to reduce the difference are also discussed.
Keywords :
Q-factor; elemental semiconductors; integrated optics; micro-optics; microcavities; microsensors; optical noise; optical resonators; optical sensors; optical testing; optical tuning; optical waveguides; silicon; Si; intrinsic systems noise; quality-factor; thermal tuning; tunable microring resonator-on-silicon; ultrahigh-resolution ratio-metric wavelength monitors; wavelength 0.72 nm; Monitoring; Noise; Optical fiber sensors; Optical waveguides; Temperature measurement; Temperature sensors; Wavelength measurement; Optical sensors; Optical waveguides; Photonic integrated circuits; Resonator filters; Wavelength measurement; optical sensors; optical waveguides; resonator filters; wavelength measurement;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2385792
