一种全光纤电流传感器温度补偿方法

熊显名; 闵旺; 秦祖军

doi:10.7510/jgjs.issn.1001-3806.2014.06.008

一种全光纤电流传感器温度补偿方法

1.
桂林电子科技大学电子工程与自动化学院, 桂林 541004

作者简介: 熊显名(1964-),男,研究员,主要研究方向为光电测试、计算机辅助测试及光学遥感测试。E-mail:478266449@qq.com.

中图分类号: TP212.4

A method of temperature compensation for all optical fiber current sensors

1.
College of Electronic Engineering and Automation, Guilin University of Electronic Science and Technology, Guilin 541004, China
CLC number: TP212.4

摘要: 为了解决传感光纤的弯曲、扭转以及外界工作环境的变化导致全光纤电流传感器测量精度降低的问题,提出了一种基于输出椭圆偏振光长轴斜率的全光纤电流传感器温度补偿方法。论证了椭圆偏振光长轴斜率能够反应输出椭圆偏振光的光椭率的大小,利用TMS320F28335和对应算法求出斜率,实验中使用输出椭圆偏振光长轴斜率对传感器进行修正并进行了实际测量。结果表明,基于该修正方法的测量系统,实现了在单次变温条件20℃~60℃内变化时测量结果偏差满足0.2s。这一结果对全光纤实用化研究是有帮助的。
- 激光技术 /
- 全光纤电流互感器 /
- 温度补偿 /
- 椭圆偏振光长轴斜率
Abstract: In order to solve the low measurement precision of all optical fiber current sensors induced by the bend and twist of sensor fiber and the change of external environment, a new method was proposed to realize the temperature compensation based on the longer axis slope of elliptic polarized light. It was demonstrated that elliptical polarized light long axis slope can response the change of the output light elasticity. The slope was calculated by TMS320F28335 and some algorithms. The sensor was modified by the elliptical polarized light long axis slope and some actual measurements was done. The experiment results show that the measurement system based on the revised method can meet the required precision of 0.2s in a single temperature change of 20℃~60℃.The result is helpful for the research of all optical fiber current sensors.
- laser technique /
- all optical fiber current sensor /
- temperature compensation /
- the longer axis slope of elliptic polarized light

[1]	FANG Zh,QIU Y Ch,LI Sh. The development of optical current transducers[J].Electric Power Construction,2002,23(12):42-44(in Chinese).
[2]	BRIAN C. Optical fiber sensor technologies: opportunities and-perhaps-pitfalls[J].Journal of Lightwave Technology,2004,22(1):38-50.
[3]	ZIEGLER S, WOODWARD R C, IU H H Ch. Current sensing techniques: a review[J].IEEE Seneors Journal,2009,4(9):354-376.
[4]	BOHNERT K, GABUS P, KOSTOVIC J, et al. Optical fiber sensors for the electric power industry[J].Optics and Lasers in Engineering,2005,43(3/5):511-526.
[5]	GAO P,MA J H,YANG N, et al. Electronic transducer technology and its current development[J].Southern Power System Technology,2009,3(3):39-42(in Chinese).
[6]	LEE B H, ROH S Y, PARK J H. Current status of micro- and nano-structured optical fiber sensors[J]. Optical Fiber Technology,2009,15(3):209-221.
[7]	BRGIDA A C S, NASCIMENTO I M, CHESINI G, et al. Fabrication of a spun elliptically birefringent photonic crystal fiber and its characterization as an electrical current sensor[J].Proceedings of the SPIE,2003,8794:F1-F4.
[8]	MICHIE A, CANNING J, BASSET I, et al. Spun elliptically birefringent photonic crystal fibre for current sensing[J].Measurement Science and Technology,2007,18(10):3070-3074.
[9]	XIONG X M,FANG J C,WANG L. Research on dual optical path all-fiber current transformer[J]. Laser Infrared,2013,43(5):536-539(in Chinese).
[10]	NI Zh B,SONG L K,LIU J P, et al. Measurement of birefringence of a single axis crystal varying with temperature based on double light paths[J]. Laser Technology,2007,31(4):358-363(in Chinese).
[11]	LIANG Q T. Physical optics[M].3rd ed.Beijing:Publishing House of Electronics Industry,2007:57-59(in Chinese).
[12]	KANG Ch, WANG Zh P, HUANG Z J, et al. Influence of reflection-induced retardance of non-polarizing beam splitter upon the polarization state of the output light of faraday mirror optical current transformer[J].Acat Optica Sinica,2006,26(12):1857-1860(in Chinese).
[13]	ZHANG W, NING Y N, GRATTAN K T V, et al. Analysis of the effect of vibration-induced noise in different fibre leads used in an optical current-measurement system[J]. Sensors and Actuators,1997,A63(2):113-118.
[14]	LIAO P,MO Sh W.1310nm/1550nm semiconductor laser power supply for the optic fiber measurement[J].Laser Technology,2013,37(4):541-546(in Chinese).
[15]	IEC STANDARDS.IEC60044-8 instrument transformers-part 8:electronic current transformers[S].Geneva,Switzerland:Internation Electro Technical Commission,2002.
[16]	TANG D D, ROSE A H, DAY G W, et al. Annealing of linear birefringence in single-mode fiber coils: application to optical fiber current sensors[J].Journal of Lightwave Technology,1991,8(9):1031-1037.

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一种全光纤电流传感器温度补偿方法

作者简介: 熊显名(1964-),男,研究员,主要研究方向为光电测试、计算机辅助测试及光学遥感测试。E-mail:478266449@qq.com.

A method of temperature compensation for all optical fiber current sensors

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一种全光纤电流传感器温度补偿方法

作者简介: 熊显名(1964-),男,研究员,主要研究方向为光电测试、计算机辅助测试及光学遥感测试。E-mail:478266449@qq.com

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A method of temperature compensation for all optical fiber current sensors

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一种全光纤电流传感器温度补偿方法

作者简介: 熊显名(1964-),男,研究员,主要研究方向为光电测试、计算机辅助测试及光学遥感测试。E-mail:478266449@qq.com.

A method of temperature compensation for all optical fiber current sensors

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一种全光纤电流传感器温度补偿方法

作者简介: 熊显名(1964-),男,研究员,主要研究方向为光电测试、计算机辅助测试及光学遥感测试。E-mail:478266449@qq.com

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A method of temperature compensation for all optical fiber current sensors

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