Compact and low-loss 1 × 3 polarization-insensitive optical power splitter using cascaded tapered silicon waveguides

Hongxiang Li; Weiwei Chen; Pengjun Wang; Pengjun Wang; Shixun Dai; Shixun Dai; Yuxiao Liu; Qiang Fu; Jun Li; Yan Li; Tingge Dai; Hui Yu; Jianyi Yang

doi:10.1364/OL.401036

Optics Letters
Vol. 45,
Issue 19,
pp. 5596-5599
(2020)
•https://doi.org/10.1364/OL.401036

Compact and low-loss 1 × 3 polarization-insensitive optical power splitter using cascaded tapered silicon waveguides

Hongxiang Li, Weiwei Chen, Pengjun Wang, Shixun Dai, Yuxiao Liu, Qiang Fu, Jun Li, Yan Li, Tingge Dai, Hui Yu, and Jianyi Yang

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Hongxiang Li, Weiwei Chen, Pengjun Wang, Shixun Dai, Yuxiao Liu, Qiang Fu, Jun Li, Yan Li, Tingge Dai, Hui Yu, and Jianyi Yang, "Compact and low-loss 1 × 3 polarization-insensitive optical power splitter using cascaded tapered silicon waveguides," Opt. Lett. 45, 5596-5599 (2020)

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- Integrated Optics
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About this Article
History
- Original Manuscript: June 26, 2020
- Revised Manuscript: August 16, 2020
- Manuscript Accepted: September 2, 2020
- Published: September 30, 2020

Abstract

In this Letter, a ${1} \times {3}$ polarization-insensitive optical power splitter based on cascaded tapered silicon waveguides is proposed and experimentally demonstrated on a silicon-on-insulator platform. By utilizing the particle swarm optimization algorithm and the finite difference time domain method, the structural parameters of the coupling regions are carefully designed to achieve polarization-insensitive property, compact size, low insertion loss, high uniformity, and broad bandwidth. The coupling length can be as short as 7.3 µm. Our measurement results show that, at 1550 nm, the insertion losses of the fabricated device operating in transverse electric (TE) and transverse magnetic (TM) polarizations are, respectively, 0.068 dB and 0.62 dB. Within a bandwidth from 1525 to 1575 nm, the insertion loss is lower than 0.82 dB and the uniformity is less than 1 dB for the fabricated device operating in TE polarization, while the fabricated device operating in TM polarization can have an insertion loss smaller than 1.50 dB and a uniformity lower than 1 dB from 1528 to 1582 nm.

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Symbol	Value/µm	Symbol	Value/µm	Symbol	Value/µm
$w_{t 1}$	0.11	$w_{t 2}$	0.18	$w_{t 3}$	0.255
$w_{t 4}$	0.328	$w_{t 5}$	0.4	$w_{t 6}$	0.44
$w_{t 7}$	0.463	$w_{t 8}$	0.455	$w_{t 9}$	0.447
$w_{t 10}$	0.438	$w_{t 11}$	0.43

$Δ W / n m$	Polarization	IL/dB (1.55 µm)	U/dB (1.55 µm)	1 dB-BW/nm
0	TE	0.016	0.058	110
	TM	0.065	0.021	90
10	TE	0.015	0.05	120
	TM	0.067	0.046	90
−10	TE	0.016	0.145	60
	TM	0.065	0.04	90

	Length/µm			MFS/µm	IL/dB		U/dB
Ref.	Length/µm	Ch	$h$ /µm	MFS/µm	TE	TM	TE	TM
[8]	34890	2	5.00	5.00	11.43	11.80	0.23	0.82
					1550 nm		1550 nm
[9]	$\sim 145$	2	0.22	0.23	$< 1.80$	$< 1.50$	$< 1.10$	$< 1.10$
					1520–1600 nm		1520–1600 nm
[12]	$\sim 20$	2	0.22	0.03	$< 0.19$	$< 0.14$	0.07	0.02
					1530–1600 nm		1550 nm
Ours	$\sim 17.3$	3	0.22	0.11	$< 0.82$	$< 1.50$	$< 1.00$	$< 1.00$
					1528–1575 nm		1528–1575 nm

Symbol	Value/µm	Symbol	Value/µm	Symbol	Value/µm
$w_{t 1}$	0.11	$w_{t 2}$	0.18	$w_{t 3}$	0.255
$w_{t 4}$	0.328	$w_{t 5}$	0.4	$w_{t 6}$	0.44
$w_{t 7}$	0.463	$w_{t 8}$	0.455	$w_{t 9}$	0.447
$w_{t 10}$	0.438	$w_{t 11}$	0.43

$Δ W / n m$	Polarization	IL/dB (1.55 µm)	U/dB (1.55 µm)	1 dB-BW/nm
0	TE	0.016	0.058	110
	TM	0.065	0.021	90
10	TE	0.015	0.05	120
	TM	0.067	0.046	90
−10	TE	0.016	0.145	60
	TM	0.065	0.04	90

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Optics Letters