Acta Optica Sinica, Volume. 43, Issue 23, 2313003(2023)
Silicon Mode Splitter Obtained by Inverse Design Based on Adjoint Method
References(29)
[1] Ellis A D, Zhao J, Cotter D. Approaching the non-linear Shannon limit[J]. Journal of Lightwave Technology, 28, 423-433(2010).
[2] Morizur J F, Nicholls L, Jian P et al. Programmable unitary spatial mode manipulation[J]. Journal of the Optical Society of America A, 27, 2524-2531(2010).
[3] Chang S H, Chung H S, Fontaine N K et al. Mode division multiplexed optical transmission enabled by all-fiber mode multiplexer[J]. Optics Express, 22, 14229-14236(2014).
[4] Hanzawa N, Saitoh K, Sakamoto T et al. Two-mode PLC-based mode multi/demultiplexer for mode and wavelength division multiplexed transmission[J]. Optics Express, 21, 25752-25760(2013).
[5] Liao J W, Zhang L X, Liu M L et al. Mode splitter without changing the mode order in SOI waveguide[J]. IEEE Photonics Technology Letters, 28, 2597-2600(2016).
[6] Hada S L, Rahman B M A. Design of compact mode splitters using identical coupled waveguides with slots[J]. OSA Continuum, 2, 848-861(2019).
[7] Jiang W F, Wang X G. Ultra-broadband mode splitter based on phase controlling of bridged subwavelength grating[J]. Journal of Lightwave Technology, 38, 2414-2422(2020).
[8] Jiang W F, Xu S Y. Experimental realization of broadband mode-splitting using bridged subwavelength grating[J]. Journal of Lightwave Technology, 39, 6239-6245(2021).
[9] Mao S Q, Hu J Z, Zhang H Y et al. Optimal design and experimental demonstration of a silicon-based ultra-compact mode splitter[J]. Optics Letters, 47, 4167-4170(2022).
[10] Ma Y X, Zhao Y, Shi Y C et al. Silicon add-drop multiplexer based on π phase-shifted antisymmetric Bragg grating[J]. IEEE Journal of Quantum Electronics, 57, 8400308(2021).
[11] Guo Z Z, Wu S B, Xiao J B. Compact and flexible mode-order converter based on mode transitions composed of asymmetric tapers and subwavelength gratings[J]. Journal of Lightwave Technology, 39, 5563-5572(2021).
[12] Ahmmed K T, Chan H P, Li B H. Scalable selective high order mode pass filter architecture with asymmetric directional couplers[J]. Optics Express, 28, 28465-28478(2020).
[13] Li Q, Hao X, Zhao Y L. Universal design of ultra-broadband and ultra-compact high order mode pass filters based on enhanced absorption in ultrathin metal layers[J]. IEEE Photonics Journal, 14, 2212608(2021).
[14] Priti R B, Bazargani H P, Xiong Y L et al. Mode selecting switch using multimode interference for on-chip optical interconnects[J]. Optics Letters, 42, 4131-4134(2017).
[15] Priti R B, Liboiron-Ladouceur O. Reconfigurable and scalable multimode silicon photonics switch for energy-efficient mode-division-multiplexing systems[J]. Journal of Lightwave Technology, 37, 3851-3860(2019).
[16] Wu H, Li C L, Song L J et al. Ultra-sharp multimode waveguide bends with subwavelength gratings[J]. Laser & Photonics Reviews, 13, 1800119(2019).
[17] Sun C L, Yu Y, Chen G Y et al. Ultra-compact bent multimode silicon waveguide with ultralow inter-mode crosstalk[J]. Optics Letters, 42, 3004-3007(2017).
[18] Xu Y H, Ma H S, Xie T et al. Ultra-compact power splitters with low loss in arbitrary direction based on inverse design method[J]. Photonics, 8, 516(2021).
[19] Shen B, Wang P, Polson R et al. Integrated metamaterials for efficient and compact free-space-to-waveguide coupling[J]. Optics Express, 22, 27175-27182(2014).
[20] Han D, Ma Z Y, Wang J L et al. Inverse design of metamaterial absorber sensor based on particle swarm optimization[J]. Chinese Journal of Lasers, 49, 1714001(2022).
[21] Li Y H, Lü J, Jiang L et al. Reverse design of photonic devices based on hybrid particle swarm optimization[J]. Laser & Optoelectronics Progress, 59, 1113001(2022).
[22] Ju X W, Zhu G F, Huang F et al. Reverse design of pixel-type terahertz band-pass filters[J]. Optics Express, 30, 957-965(2022).
[23] Zhang C, Kang G G, Wang J et al. Inverse design of soliton microcomb based on genetic algorithm and deep learning[J]. Optics Express, 30, 44395-44407(2022).
[24] Vercruysse D, Sapra N V, Su L et al. Analytical level set fabrication constraints for inverse design[J]. Scientific Reports, 9, 8999(2019).
[25] Xu J F, Liu Y J, Guo X Y et al. Inverse design of a dual-mode 3-dB optical power splitter with a 445 nm bandwidth[J]. Optics Express, 30, 26266-26274(2022).
[26] Shen B, Wang P, Polson R et al. An integrated-nanophotonics polarization beam splitter with 2.4×2.4 μm2 footprint[J]. Nature Photonics, 9, 378-382(2015).
[27] Xu K, Liu L, Wen X et al. Integrated photonic power divider with arbitrary power ratios[J]. Optics Letters, 42, 855-858(2017).
[28] Piggott A Y, Lu J, Babinec T M et al. Inverse design and implementation of a wavelength demultiplexing grating coupler[J]. Scientific Reports, 4, 7210(2014).
[29] Wang K Y, Ren X S, Chang W J et al. Inverse design of digital nanophotonic devices using the adjoint method[J]. Photonics Research, 8, 528-533(2020).
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Tao Chen, Siqiang Mao, Hongdan Wan, Jingli Wang, Weifeng Jiang. Silicon Mode Splitter Obtained by Inverse Design Based on Adjoint Method[J]. Acta Optica Sinica, 2023, 43(23): 2313003
Paper Information
Category: Integrated Optics
Received: Jun. 15, 2023
Accepted: Sep. 5, 2023
Published Online: Dec. 8, 2023
The Author Email: Jingli Wang (jlwang@njupt.edu.cn), Weifeng Jiang (jwf@njupt.edu.cn)
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