M型少模光纤中模间受激布里渊散射特性及其温度和应变传感特性

李雪健; 曹敏; 汤敏; 芈月安; 陶洪; 古皓; 任文华; 简伟; 任国斌

doi:10.7498/aps.69.20200103

摘要

少模光纤的受激布里渊散射对于分布式温度/应变传感具有重要应用价值. 本文提出一种纤芯折射率呈M型分布的少模光纤, 详细研究了光学模式LP₀₁和LP₁₁模式内及模式间的布里渊增益谱. 研究结果表明: LP₀₁-LP₁₁模式对的布里渊增益谱中, 其相邻两个布里渊散射峰的频率间隔较宽、增益峰值较大且峰值相差较小. 通过优化光纤结构参数, 提高了基于LP₀₁-LP₁₁模式对布里渊增益谱的温度和应变传感性能, 最小误差分别为0.23 ℃和5.67 με. 该研究对探究少模光纤中模式内及模式间的受激布里渊散射特性具有一定的指导意义, 对提升同时温度和应变传感测量的性能具有一定参考价值.

关键词:

Abstract

Stimulated Brillouin scattering (SBS) in a few-mode fiber (FMF) is of significance for the distributed temperature and strain sensing. An FMF with M-shaped refractive index distribution (M-FMF) is proposed in order to improve the performance of simultaneous temperature and strain sensing based on SBS. Propagation of four optical modes is supported by the M-FMF, so that the Brillouin gain spectrum (BGS) can be obtained by both intra-mode and inter-mode SBS. The BGSs produced by the interactions of LP₀₁-LP₀₁ mode pair, LP₀₁-LP₁₁ mode pair, and LP₁₁-LP₁₁ mode pair are analyzed, respectively. Meanwhile, the temperature and strain sensing performance based on the BGS of LP₀₁-LP₁₁ mode pair are studied in detail. Considering a common step-index FMF, only one obvious scattering peak is usually present in the BGS obtained from the interaction between different optical mode pairs, therefore, it is inconvenient to achieve multi-parameter sensing measurement. In this paper, the BGS of LP₀₁-LP₁₁ mode pair has two scattering peaks, which are contributed by the acousto-optic coupling between the acoustic modes L_1n(n = 1, 2) and the optical modes LP₀₁ and LP₁₁. The two Brillouin scattering peaks have large gain values of 0.1004 m^–1·W^–1 and 0.0463 m^–1·W^–1, respectively. More importantly, the gain difference between two Brillouin scattering peaks is small, and the frequency interval is 75 MHz, which can be applied to simultaneous temperature and strain sensing. The influences of the refractive index and the fiber core radius on the BGS of LP₀₁-LP₁₁ mode pair are studied. By selecting the optimal structure parameters, we discuss the effect of temperature and strain on the BGS of LP₀₁-LP₁₁ mode pair. The errors for simultaneous temperature and strain measurement are reduced to 0.23 ℃ and 5.67 με. Compared with other reported results, our obtained temperature and strain sensitivity are high and sensing errors are low in the considered M-FMF. In other words, based on the BGS of LP₀₁-LP₁₁ mode pair, the performance of temperature and strain sensing are improved in the M-FMF. This work is of great significance for studying intra-mode and inter-mode SBS in an FMF. Moreover, the results also provide a guideline for further improving the performance of simultaneous temperature and strain sensing.

Keywords:

作者及机构信息

北京交通大学光波技术研究所, 全光网络与现代通信网教育部重点实验室, 北京　100044

通信作者: 任国斌, gbren@bjtu.edu.cn

基金项目: 国家级-国家自然科学基金(61875008，61275092)

Authors and contacts

Key Laboratory of All Optical Network and Advanced Telecommunication Network, Ministry of Education, Institute of Lightwave Technology, Beijing Jiaotong University, Beijing 100044, China

Corresponding author: Ren Guo-Bin, gbren@bjtu.edu.cn

文章全文 : translate this paragraph

参考文献

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[2]	Randel S, Ryf R, Sierra A, Winzer P J, Gnauck A H, Bolle A C, Essiambre R J, Peckham D W, McCurdy A, Lingle R 2011 Opt. Express 19 16697 Google Scholar
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[4]	Cowie G J, Yu D, Chieng Y T 1997 J. Lightwave Technol. 15 1198 Google Scholar
[5]	Li B W, Wei X M, Wang X, Wong K K Y 2014 IEEE Photonics Technol. Lett. 26 2387 Google Scholar
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施引文献

图 1 SI-FMF中${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$模式对的BGS (插图为SI-FMF的结构分布)

Fig. 1. The BGS of ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$ mode pair in SI-FMF (Inset: The structure of SI-FMF).

下载: 全尺寸图片幻灯片

图 2 M-FMF的结构分布以及光学模式的模场分布　(a) M-FMF的结构分布; (b) ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$; (c) ${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$; (d) ${\rm{L}}{{\rm{P}}_{{\rm{21}}}}$; (e) ${\rm{L}}{{\rm{P}}_{{\rm{02}}}}$

Fig. 2. The structure of M-FMF and the field distribution of optical modes in M-FMF: (a) The structure of M-FMF: (b) ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$; (c) ${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$; (d) ${\rm{L}}{{\rm{P}}_{{\rm{21}}}}$; (e) ${\rm{L}}{{\rm{P}}_{{\rm{02}}}}$.

下载: 全尺寸图片幻灯片

图 3 不同光学模式对的BGS　(a) ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}\text-{\rm{L}}{{\rm{P}}_{{\rm{01}}}}$; (b) ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$; (c) ${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$

Fig. 3. The BGS of different optical mode pairs: (a) ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}\text-{\rm{L}}{{\rm{P}}_{{\rm{01}}}}$; (b) ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$; (c) ${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$.

下载: 全尺寸图片幻灯片

图 4 M-FMF的结构对${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$模式对BGS的影响　(a) n₁; (b) n₂; (c) r₁; (d) r₂

Fig. 4. The BGS of ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$ mode pair in M-FMF versus: (a) n₁; (b) n₂; (c) r₁; (d) r₂.

下载: 全尺寸图片幻灯片

图 5 ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$模式对激励的声学模式的位移场分布　(a) ${{\rm{L}}_{{\rm{11}}}}$; (b) ${{\rm{L}}_{{\rm{12}}}}$

Fig. 5. The displacement field distribution of acoustic mode excited by the interaction of ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$ mode pair: (a) ${{\rm{L}}_{{\rm{11}}}}$; (b) ${{\rm{L}}_{{\rm{12}}}}$.

下载: 全尺寸图片幻灯片

图 6 ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$模式对的BGS随温度和应变的变化　(a) BGS随温度的变化; (b) BGS随应变的变化

Fig. 6. The BGS of ${\rm{L}}{{\rm{P}}_{{\rm{01}}}}$-${\rm{L}}{{\rm{P}}_{{\rm{11}}}}$ mode pair versus: (a) Temperature; (b) strain.

下载: 全尺寸图片幻灯片

图 7 声学模式${{\rm{L}}_{{\rm{11}}}}$和${{\rm{L}}_{{\rm{12}}}}$对应散射峰的BFS随温度和应变的变化　(a) BFS随温度的变化关系; (b) BFS随应变的变化关系

Fig. 7. The BFS corresponding to ${{\rm{L}}_{{\rm{11}}}}$ and ${{\rm{L}}_{{\rm{12}}}}$ acoustic modes versus: (a) Temperature; (b) strain.

下载: 全尺寸图片幻灯片

表 1 不同光学模式对与声学模式之间相互耦合的声光有效面积(单位: μm²)

Table 1. Acousto-optic effective area by the coupling between different optical mode pairs and acoustic modes (in μm²).

	LP₀₁-LP₀₁	LP₀₁-LP₁₁	LP₁₁-LP₁₁
	m = 0	m = 1	m = 0	m = 2
L_m₁	251.63	208.71	156.24	180.74
L_m₂	162.48	449.52	1.65 × 10³	1.09 × 10³
L_m₃	2.12 × 10⁵	4.54 × 10⁴	3.82 × 10³	1.11 × 10⁴

下载: 导出CSV

表 2 不同研究报道中基于SBS的温度应变系数和误差

Table 2. The coefficients and errors of temperature and strain based on SBS in different literatures.

Fiber	$C_T^1$/MHz·℃^–1	$C_T^2$/MHz·℃^–1	$C_S^1$/MHz·℃^–1	$C_S^2$/MHz·℃^–1	δT/℃	δS/με
M-FMF	4.3400	3.9315	0.19373	0.17715	0.23	5.67
M-SMF^[25]	1.5187	1.1642	0.06640	0.05280	0.47	12.30
SSMF^[26]	1.1900	1.1500	0.06228	0.05009	0.93	19.48
SMF^[27]	1.1900	1.1190	0.03560	0.04030	0.90	28.80
IPGIF^[37]	0.74323	0.9016	0.04202	0.03825	0.85	17.40
GIFMF^[38]	5.2700	4.300	0.23700	0.18900	1.80	41.00
c-core FMF^[39]	1.0169	0.9909	0.05924	0.04872	1.20	21.90
e-core FMF^[40]	1.2420	1.2780	0.06130	0.03640	0.37	7.61

下载: 导出CSV

[1]	Essiambre R J, Kramer G, Winzer P J, Foschini G J, Goebel B 2010 J. Lightwave Technol. 28 662 Google Scholar
[2]	Randel S, Ryf R, Sierra A, Winzer P J, Gnauck A H, Bolle A C, Essiambre R J, Peckham D W, McCurdy A, Lingle R 2011 Opt. Express 19 16697 Google Scholar
[3]	Smith S P, Zarinetchi F, Ezekiel S 1991 Opt. Lett. 16 393 Google Scholar
[4]	Cowie G J, Yu D, Chieng Y T 1997 J. Lightwave Technol. 15 1198 Google Scholar
[5]	Li B W, Wei X M, Wang X, Wong K K Y 2014 IEEE Photonics Technol. Lett. 26 2387 Google Scholar
[6]	Alahbabi M N, Cho Y T, Newson T P 2004 Opt. Lett. 29 26 Google Scholar
[7]	Zadok A, Zilka E, Eyal A, Thévenaz L, Tur M 2008 Opt. Express 16 21692 Google Scholar
[8]	刘玉 2012 硕士学位论文 (陕西: 西北大学) Liu Y 2012 M.S. Dissertation (Shanxi: Northwest University) (in Chinese)
[9]	Herráez M G, Song K Y, Thévenaz L 2006 Opt. Express 14 1395 Google Scholar
[10]	Loayssa A, Benito D, Garde M J 2000 Opt. Lett. 25 1234 Google Scholar
[11]	Preussler S, Schneider T 2015 Opt. Eng. 55 031110 Google Scholar
[12]	Ballmann C W, Meng Z K, Traverso A J, Scully M O, Yakovlev V V 2017 Optica 4 124 Google Scholar
[13]	Krug B, Koukourakis N, Czarske J W 2019 Opt. Express 27 26910 Google Scholar
[14]	Kobyakov A, Sauer M, Chowdhury D 2010 Adv. Opt. Photonics 2 1 Google Scholar
[15]	Koyamada Y, Sato S, Nakamura S, Sotobayashi H, Chujo W 2004 J. Lightwave Technol. 22 631 Google Scholar
[16]	Nikles M, Thevenaz L, Robert P A 1997 J. Lightwave Technol. 15 1842 Google Scholar
[17]	Zou L F, Bao X Y, Afshar S, Chen L 2004 Opt. Lett. 29 1485 Google Scholar
[18]	Horiguchi T, Kurashima T, Tateda M 1989 IEEE Photonics Technol. Lett. 1 107 Google Scholar
[19]	Mocofanescu A, Wang L, Jain R, Shaw K D, Gavrielides A, Peterson P, Sharma M P 2005 Opt. Express 13 2019 Google Scholar
[20]	Floch S L, Cambon P 2003 J. Opt. Soc. Am. A 20 1132 Google Scholar
[21]	王振宝, 邵碧波, 张磊, 闫燕, 杨鹏翎, 陈绍武 2011 激光与光电子学进展 48 090603 Google Scholar Wang Z B, Shao B B, Zhang L, Yan Y, Yang P L, Chen S W 2011 Laser Optoelect. Prog. 48 090603 Google Scholar
[22]	Afshar S, Kalosha V P, Bao X Y, Chen L 2005 Opt. Lett. 30 2685 Google Scholar
[23]	Liu A P 2007 Opt. Express 15 977 Google Scholar
[24]	Li H L, Zhang W, Huang Y D, Peng J D 2011 Chin. Phys. B 20 104211 Google Scholar
[25]	Dong Y, Ren G B, Xiao H, Gao Y X, Li H S, Xiao S Y, Jian S S 2017 IEEE Photonics Technol. Lett. 29 1955 Google Scholar
[26]	Xing C, Ke C J, Guo Z, Yang K Y, Wang H Y, Zhong Y B, Liu D M 2018 Opt. Express 26 28793 Google Scholar
[27]	Xiao S Y, Dong Y, Xiao H, Ren G B, Jian S S 2018 IEEE Sens. J. 18 1087
[28]	Song K Y, Kim Y H, Kim B Y 2013 Opt. Lett. 38 1805 Google Scholar
[29]	Song K Y, Kim Y H 2013 Opt. Lett. 38 4841 Google Scholar
[30]	Ke W W, Wang X J, Tang X 2014 IEEE J. Sel. Top. Quantum Electron. 20 305 Google Scholar
[31]	Minardo A, Bernini R, Zeni L 2014 Opt. Express 22 17480 Google Scholar
[32]	Song K Y, Kim Y H 2014 Optical Fiber Communications Conference San Francisco, CA, USA, March 9–13, 2014 pW3D.6
[33]	张燕君, 高皓雷, 付兴虎, 田永胜 2017 物理学报 66 024207 Google Scholar Zhang Y J, Gao H L, Fu X H, Tian Y S 2017 Acta Phys. Sin. 66 024207 Google Scholar
[34]	王旭, 秦祖军, 熊显名, 张文涛 2019 激光与光电子进展 56 162901 Google Scholar Wang X, Qin Z J, Xiong X M, Zhang W T 2019 Laser Optoelect. Prog. 56 162901 Google Scholar
[35]	Lü H B, Zhou P, Wang X L, Jiang Z F 2015 J. Lightwave Technol. 33 4464 Google Scholar
[36]	Zou W W, He Z Y, Hotate K 2009 Opt. Express 17 1248 Google Scholar
[37]	Xu Y P, Ren M Q, Lu Y, Lu P, Lu P, Bao X Y, Wang L X, Messaddeq Y, Larochelle S 2016 Opt. Lett. 41 1138 Google Scholar
[38]	Zhou X, Guo Z, Ke C J, Liu D M 2016 IEEE Photonics Conference(IPC) Waikoloa, HI, October 2–6, 2016 p817
[39]	Li A, Wang Y F, Hu Q, Shieh W 2015 Opt. Express 23 1139 Google Scholar
[40]	Fang J, Milione G, Stone J, Peng G Z, Li M J, Ip E, Li Y W, Ji P N, Huang Y K, Huang M F, Murakami S, Shieh W, Wang T 2019 Opt. Lett. 44 1096 Google Scholar
[41]	Weng Y, Ip E, Pan Z Q, Wang T 2015 Opt. Express 23 9024 Google Scholar

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