Inverse design of an ultra-compact low-loss single-step-etched polarization rotator based on adjoint method staged optimization

On-chip polarization control plays a crucial role in photonic integrated circuits implemented on silicon-on-insulator platforms, with key components including polarization rotators. Here, by combining boundary shape optimization and topology optimization in the adjoint method for staged optimization...

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Bibliographic Details
Published in:Physics letters. A 2025-02, Vol.532, p.130193, Article 130193
Main Authors: Liang, Haoyuan, Liu, Qiang, Geng, Minming, Wei, Kejin, Zhang, Zhenrong
Format: Article
Language:English
Subjects:
Adjoint method
Inverse design
Polarization rotator
SOI
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Summary:On-chip polarization control plays a crucial role in photonic integrated circuits implemented on silicon-on-insulator platforms, with key components including polarization rotators. Here, by combining boundary shape optimization and topology optimization in the adjoint method for staged optimization, we designed a polarization rotator enabling polarization conversion from TM0 to TE0 via a polarization rotation part and a mode conversion part. Simulation results indicate that using the staged optimization method can further improve the performance of the polarization rotator while maintaining device compactness. With a compact footprint of 1.05 × 12.00 μm2, the polarization rotator exhibited low insertion loss (< 0.44 dB) and high extinction ratio (> 24 dB) in the wavelength range from 1530 nm to 1570 nm. The device has a simple structure, requiring only a single-step etching, and it exhibits a certain tolerance to fabrication imperfections. •Designed an ultra-compact, low-loss, single-step-etched polarization rotator.•Applied adjoint method inverse design to reduce device size and enhance performance.•Combined boundary shape and topology optimization to improve performance and maintain compactness.
ISSN:0375-9601
DOI:10.1016/j.physleta.2024.130193