A Polarization-Insensitive High-Resolution Micro-Spectrometer Using (N + 3) × (N + 3) Arrayed Waveguide Grating On SOI Platform

Ultra-compact on-chip spectrometers with high resolution and large bandwidth play a crucial role in miniaturized spectroscopic analysis systems. Here we present a novel polarization-insensitive micro-spectrometer with high resolution and large bandwidth based on a ( N + 3) × ( N + 3) arrayed wavegui...

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Bibliographic Details
Published in:Journal of lightwave technology 2023-01, Vol.41 (1), p.226-232
Main Authors: Zou, Jun, Li, Lingfeng, Zhuang, Yuan, Wang, Changhui, Zhang, Ming, Le, Zichun, Wang, Xuyang, Cai, Gaozhe, Feng, Shilun, He, Jian-Jun
Format: Article
Language:English
Subjects:
Arrayed waveguide grating
Arrayed waveguide gratings
Bandwidths
Bragg gratings
Channel spacing
Channels
Couplers
High resolution
Noise levels
Optical device fabrication
Optical polarization
Optical waveguides
Polarization
polarization insensitivity
Silicon
silicon photonics
SOI (semiconductors)
spectrometer-on-a-chip
Spectrometers
System-on-chip
Wave propagation
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Summary:Ultra-compact on-chip spectrometers with high resolution and large bandwidth play a crucial role in miniaturized spectroscopic analysis systems. Here we present a novel polarization-insensitive micro-spectrometer with high resolution and large bandwidth based on a ( N + 3) × ( N + 3) arrayed waveguide grating (AWG) on silicon-on-insulator (SOI) platform. The proposed AWG can be viewed as two same 3 × N AWGs with each one having three input waveguides with channel spacing of 4/3 Δ λ and N output waveguides with channel spacing of Δ λ . The three input waveguides are time division multiplexed, i.e., they are excited one by one in sequence. As a result, combining all spectral responses of each input, a micro-spectrometer with channel wavelength spacing enhanced to one-third Δ λ and channel number enlarged to 3 × ( N - 2) is achieved, only using N output channels. The polarization diversity scheme is utilized to address the polarization sensitive issue of silicon nano-waveguide, i.e., the AWG operates at a counter-propagating manner to process each polarization, respectively. In experiment, we demonstrate a micro-spectrometer with 81 channels and channel wavelength spacing of 0.4 nm by employing a 32 × 32 AWG on the SOI platform. The footprint of the fabricated micro-spectrometer is only 1.1 × 2.35 mm 2 . Experimental results show that the spectrometer has on-chip losses ranging from -5.8 to -2.5 dB, noise level of better than 17 dB, polarization dependent wavelength shift (PD λ ) of less than 0.07 nm and polarization dependent loss (PDL) of less than 1.5 dB, for all 81 wavelength channels. The resolution of the micro-spectrometer is mainly dependent on the 3-dB bandwidth of each channel and is simulated to be ∼0.65 nm. The proposed ultracompact and polarization insensitive high-resolution on-chip spectrometer provides a very promising approach for achieving miniaturized spectrometer-on-a-chip with good performance for applications such as in fiber Bragg grating (FBG) sensor readout unit and optical waveguide sensor systems.
ISSN:0733-8724
1558-2213
DOI:10.1109/JLT.2022.3209233