A 1.55 μm Wideband 1 × 2 Photonic Power Splitter With Arbitrary Ratio: Characterization and Forward Modeling

Chip-based photonic systems have undergone substantial progress over the last decade. However, the realization of photonic devices still depends largely on intuition-based trial-and-error methods, with a limited focus on characteristic analysis. In this work, we demonstrate an in-depth investigation...

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Bibliographic Details
Published in:IEEE access 2022, Vol.10, p.20149-20158
Main Authors: Rahman, Lubaba Tazrian, Akhter, Mahmud Elahi, Sayem, Faizul Rakib, Hossain, Mainul, Ahmed, Rajib, Elahi, M. M. Lutfe, Ali, Khaleda, Islam, Sharnali
Format: Article
Language:English
Subjects:
Algorithms
Aluminum oxide
artificial neural network
Artificial neural networks
Broadband
Deep learning
Dielectrics
Engraving
Forward modeling
Learning theory
Machine learning
Modelling
Optical communication
Optical losses
optical power splitter
Optical reflection
Photonics
Power splitters
Reflection
Silicon
Silicon dioxide
Silicon nitride
Splitting
Substrates
Transmittance
Trial and error methods
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Summary:Chip-based photonic systems have undergone substantial progress over the last decade. However, the realization of photonic devices still depends largely on intuition-based trial-and-error methods, with a limited focus on characteristic analysis. In this work, we demonstrate an in-depth investigation of photonic power splitters by considering the transmission properties of 16,000 unique ultra-compact silicon-based structures engraved with SiO 2 , Al 2 O 3 , and Si 3 N 4 nanoholes. The characterization has been performed using finite-difference time-domain (FDTD) simulations for each dielectric material and both TE and TM polarizations at the fundamental modes in a wideband optical communication spectrum ranging from 1.45 to 1.65~\mu \text{m} . The corresponding transmissions, splitting ratio, and reflection loss were calculated, generating a dataset that can be used for both forward and inverse modeling purposes, using Machine Learning (ML) and Deep Learning (DL) algorithms. With an optimized hole radius of 35 nm, the proposed device area footprint of 2\,\,\mu \text{m}\,\,\times 2\,\,\mu \text{m} is among the smallest with the best transmission reported to date. Si 3 N 4 holes show excellent transmission because they offer 90% transmittance in 96% of the data while exhibiting maximum fabrication tolerance. Forward modeling analysis, predicting the transmission properties, was performed using both Linear Model (LM) and Artificial Neural Network (ANN), where LM showed marginally better accuracy than ANN in foreseeing the transmittance. The proposed observation will aid in achieving robust, optimized optical power splitters with a wide range of splitting ratios in lesser time.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2022.3151722