Simultaneous measurement of mode dependent loss and mode coupling in few mode fibers by analyzing the Rayleigh backscattering amplitudes

Feng Liu; Guijun Hu; Congcong Song; Weicheng Chen; Cuiguang Chen; Jiake Chen

doi:10.1364/AO.57.008894

Applied Optics
Vol. 57,
Issue 30,
pp. 8894-8902
(2018)
•https://doi.org/10.1364/AO.57.008894

Simultaneous measurement of mode dependent loss and mode coupling in few mode fibers by analyzing the Rayleigh backscattering amplitudes

Feng Liu, Guijun Hu, Congcong Song, Weicheng Chen, Cuiguang Chen, and Jiake Chen

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Feng Liu, Guijun Hu, Congcong Song, Weicheng Chen, Cuiguang Chen, and Jiake Chen, "Simultaneous measurement of mode dependent loss and mode coupling in few mode fibers by analyzing the Rayleigh backscattering amplitudes," Appl. Opt. 57, 8894-8902 (2018)

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Related Topics
Table of Contents Category
- Fiber Optics, Fiber Sensors, and Optical Communications
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About this Article
History
- Original Manuscript: June 8, 2018
- Revised Manuscript: September 19, 2018
- Manuscript Accepted: September 20, 2018
- Published: October 16, 2018

Abstract

In this paper, we propose and experimentally demonstrate a nondestructive method for simultaneously measuring the mode-dependent loss (MDL) and mode coupling (MC) in few-mode fibers (FMFs). The method is based on analyzing the Rayleigh backscattering amplitudes obtained with an optical time domain reflectometer (OTDR). The experimental results show that, in about 4 km six-mode FMF, the MDL and MC values are 0.132 dB and $- 23.13 dB / km$ between ${LP}_{01}$ and ${LP}_{11 a}$ , 0.176 dB and $- 23.73 dB / km$ between ${LP}_{01}$ and ${LP}_{11 b}$ , 0.272 dB and $- 26.17 dB / km$ between ${LP}_{01}$ and ${LP}_{21 a}$ , 0.284 dB and $- 26.70 dB / km$ between ${LP}_{01}$ and ${LP}_{21 b}$ , and 0.380 dB and $- 20.21 dB / km$ between ${LP}_{01}$ and ${LP}_{02}$ . And it also demonstrated that the proposed scheme can be scalable to measure MDL and MC between higher-order modes. The values of the MC and MDL obtained by the proposed method agree well with that by the conventional transmission method. However, the proposed method has the merits of simultaneous and single-end measurement of MDL and MC in the FMF and could be a good solution to the characterization of FMFs used in large-capacity mode-division-multiplexing transmission systems.

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Insertion Loss (dB)	${LP}_{01}$ Port	${LP}_{11 a}$ Port	${LP}_{11 b}$ Port	${LP}_{21 a}$ Port	${LP}_{21 b}$ Port	${LP}_{02}$ Port
PL 1	5.467	1.549	2.194	2.932	3.411	8.984
PL 2	1.167	1.278	2.094	2.802	3.365	4.390

	Transfer
Receive	${LP}_{01}$	${LP}_{11 a}$	${LP}_{11 b}$	${LP}_{21 a}$	${LP}_{21 b}$	${LP}_{02}$
${LP}_{01}$	—	−17.18	−16.36	−22.73	−23.81	−23.38
${LP}_{11 a}$	−19.09	—	−15.64	−16.67	−19.32	−20.74
${LP}_{11 b}$	−18.61	−14.38	—	−17.58	−18.13	−19.70
${LP}_{21 a}$	−27.67	−16.43	−16.92	—	−15.14	−19.18
${LP}_{21 b}$	−28.15	−17.62	−17.75	−14.96	—	−18.41
${LP}_{02}$	−24.94	−19.23	−18.78	−22.34	−19.27	—

Item	Value
Fiber length	4.002 km
Core diameter	13.28 μm
Cladding diameter	125.26 μm
Mode field diameter at 1550 nm	9.25 μm
Cutoff wavelength	1325 nm
Differential group delay [ ${LP}_{11}$ , ${LP}_{21}$ , ${LP}_{02}$ ]– ${LP}_{01}$	5.91, 11.8112.63 ps/m
Refractive index of the cladding and core	1.4560, 1.4722
Core-cladding relative index difference	1.1%

MC and Cross-Talk Values (dB/km and dB)	Present Method	Conventional Transmission Method	Difference Between Two Methods
${LP}_{01} \to {LP}_{11 a}$	−23.13 (−17.11)	−24.00 (−17.98)	0.87 (0.87)
${LP}_{01} \to {LP}_{11 b}$	−23.73 (−17.70)	( $M C_{01 \to 11}$ )	0.27 (0.28)
${LP}_{01} \to {LP}_{21 a}$	−26.17 (−20.15)	−26.68 (−20.66)	0.51 (0.51)
${LP}_{01} \to {LP}_{21 b}$	−26.70 (−20.68)	( $M C_{01 \to 21}$ )	−0.02 (−0.02)
${LP}_{01} \to {LP}_{02}$	−20.21 (−14.19)	−20.84 (−14.82)	0.63 (0.63)
${LP}_{11 a} \to {LP}_{21 a}$	−19.85 (−13.82)	−19.23 (−13.21)	−0.62 (−0.61)
${LP}_{11 a} \to {LP}_{21 b}$	−19.36 (−13.34)	( $M C_{11 \to 21}$ )	−0.13 (−0.13)
${LP}_{11 a} \to {LP}_{02}$	−21.42 (−15.40)	−21.34 (−15.32)	−0.08 (−0.008)
${LP}_{11 b} \to {LP}_{02}$	−21.19 (−15.17)	( $M C_{11 \to 02}$ )	0.15 (0.15)
${LP}_{11 b} \to {LP}_{21 a}$	−19.06 (−13.04)	−19.23 (−13.21)	0.17 (0.17)
${LP}_{11 b} \to {LP}_{21 b}$	−19.48 (−13.46)	( $M C_{11 \to 21}$ )	−0.25 (−0.25)
${LP}_{21 a} \to {LP}_{02}$	−18.54 (−12.52)	−18.08 (−12.06)	−0.46 (−0.46)
${LP}_{21 b} \to {LP}_{02}$	−18.73 (−12.71)	( $M C_{21 \to 02}$ )	−0.65 (−0.65)

MDL Values (dB)	Present Method	Conventional Transmission Method	Difference Between Two Methods
${LP}_{01} \leftrightarrow {LP}_{11 a}$	0.132	0.158	−0.026
${LP}_{01} \leftrightarrow {LP}_{11 b}$	0.176	( $M D L_{01 \leftrightarrow 11}$ )	0.018
${LP}_{01} \leftrightarrow {LP}_{21 a}$	0.280	0.289	0.009
${LP}_{01} \leftrightarrow {LP}_{21 b}$	0.284	( $M D L_{01 \leftrightarrow 21}$ )	0.005
${LP}_{01} \leftrightarrow {LP}_{02}$	0.380	0.394	−0.014
${LP}_{11 a} \leftrightarrow {LP}_{21 a}$	0.148	0.131	0.017
${LP}_{11 a} \leftrightarrow {LP}_{21 b}$	0.152	( $M D L_{11 \leftrightarrow 21}$ )	0.021
${LP}_{11 a} \leftrightarrow {LP}_{02}$	0.248	0.236	0.012
${LP}_{11 b} \leftrightarrow {LP}_{02}$	0.204	( $M D L_{11 \leftrightarrow 02}$ )	−0.032
${LP}_{11 b} \leftrightarrow {LP}_{21 a}$	0.104	0.131	−0.027
${LP}_{11 b} \leftrightarrow {LP}_{21 b}$	0.108	( $M D L_{11 \leftrightarrow 21}$ )	−0.023
${LP}_{21 a} \leftrightarrow {LP}_{02}$	0.100	0.105	−0.005
${LP}_{21 b} \leftrightarrow {LP}_{02}$	0.096	( $M D L_{21 \leftrightarrow 02}$ )	−0.009

	$M D L_{1, 2} (dB)$	$M C_{1, 2} (dB / km)$
1	0.1320	−23.131
2	0.1316	−23.138
3	0.1337	−23.126
4	0.1324	−23.134
5	0.1309	−23.136
6	0.1327	−23.131
7	0.1318	−23.140
8	0.1302	−23.128
STD	0.001	0.0046

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Applied Optics