基于光纤电流传感器的韦尔代常数优化测量法

庄静; 肖悦娱; 彭蕾; 颜锦奎

doi:doi:10.3788/aos201232.1128003

光学学报, 2012, 32 (11): 1128003, 网络出版: 2012-08-28

基于光纤电流传感器的韦尔代常数优化测量法

Measurement of Verdet Constant in Fiber Optical Current Transducer Using an Optimization Method

论文大纲

庄静 ^*肖悦娱彭蕾颜锦奎

作者单位

上海大学特种光纤与光接入网省部共建重点实验室, 上海 200072

光纤光学韦尔代常数萨格纳克干涉光纤电流传感器 fiber optics Verdet constant Sagnac interferometer fiber optical current transducer

摘要

韦尔代常数(Verdet)是决定光纤电流传感器(FOCT)灵敏度的重要因素之一。根据萨格纳克(Sagnac)干涉原理计算得到校准信号，并测量FOCT的实际输出信号，通过比较这两组信号建立目标函数，基于单纯形算法进行参数优化，从而得到石英光纤的韦尔代常数。实验结果与经典模型计算结果基本吻合。FOCT的输出信号经过测量电路会引入相位差；另外受到调制器和外界环境的影响，干涉回路的工作点会产生漂移，导致输出信号不对称而产生直流量。考虑到以上因素，提出的这种方法还能同时测量出电路的相位差、干涉回路的工作点以及反映非线性畸变的直流量。

Abstract

Verdet constant is one of important parameters which can determine sensitivity of a fiber optical current transducer (FOCT). Calibration signal is calculated based on Sagnac interference principle, and the output signal of FOCT is measured. By comparing above these two sets of signals, an objective function is established, and then the parameters of the function are optimized based on a Nelder-Mead simplex method. Thereby the Verdet constant of silica fiber is measured. Experimental results are in good agreement with the results calculated by classical models. Phase delay is added to the output signal when it goes through the measuring circuits. Influenced by rotator and changing environment, the working point of the interference loop drifts. As a result, the output signal becomes asymmetric and creates the direct current quantity. Considering all these situations, the phase delay, working point and direct current quantity which reflects the nonlinear distortion can also be obtained by this method.

参考文献

[1] 许玲, 姚寿铨. 温度对扭转光纤环性能的影响［J］. 激光技术, 2005, 29(1): 52～55

Xu Ling, Yao Shouquan. Effects of temperature on the performance of twisted optic fiber loop［J］. Laser technology, 2005, 29(1): 52～55

[2] J. W. Dawson, T. W. MacDougall, E. Hernandez. Verdet constant limited temperature response of a fiber-optic current sensor［J］. IEEE Photonic. Technol. Lett., 1995, 7(12): 1468～1470

[3] J. Noda, T. Hosaka, Y. Sasaki et al.. Dispersion of Verdet constant in stress-birefringent silica fiber［J］. Electron. Lett., 1984, 20(22): 906～908

[4] A. H. Rose, S. M. Etzel, C. M. Wang. Verdet constant dispersion in annealed optical fiber current sensors［J］. J. Lightwave Technol., 1997, 15(5): 803～807

[5] 王政平, 李庆波, 齐异等. Verdet常数色散对光学电流传感器灵敏度影响的理论研究［J］. 哈尔滨工程大学学报, 2004, 25(2): 189～191

Wang Zhengping, Li Qingbo, Qi Yi et al.. Theoretical study of the effect of the Verdet constant dispersion upon the sensitivity of an optical current sensor［J］. J. Harbin Engineering University, 2004, 25(2): 189～191

[6] W. B. Garn, R. S. Caird, C. M. Fowler et al.. Measurement of Faraday rotation in megagauss fields over the continuous visible spectrum［J］. Rev. Sci. Instrum., 1968, 39(9): 1313～1317

[7] A. M. Smith. Polarization and magnetooptic properties of single-mode optical fibers［J］. Appl. Opt., 1978, 17(1): 52～56

[8] H. S. Lassing, A. A. M. Oomens, R. Woltjer et al.. Development of a magnetooptic current sensor for high pulsed currents［J］. Rev. Sci. Instrum., 1986, 57(5): 851～854

[9] M. N. Deeter, G. W. Day, A. H. Rose. Handbook of Laser Science and Technology, Supplement 2: Optical Materials［M］. Boca Raton: CRC Press, 1995. 367～402

[10] A. H. Smith. Faraday effect in single-mode optical fibre using an injection laser light source［J］. Electron. Lett., 1980, 16(6): 206～208

[11] 董小鹏, 戴文华. 存在固有双折射光纤费尔德常数的测量［J］. 光学学报, 1995, 15(10): 1452～1457

Dong Xiaopeng, Dai Wenhua. Measurement of Verdet constant for fibers with intrinsic linear birefringence［J］. Acta Optica Sinica, 1995, 15(10): 1452～1457

[12] 王加新, 姚寿铨. 扭转光纤环Verdet系数的干涉法测量［J］. 上海大学学报, 2007, 13(2): 122～124

Wang Jiaxin, Yao Shouquan. Interference method for measuring Verdet coefficient of twisted fiber rings［J］. J. Shanghai University, 2007, 13(2): 122～124

[13] He Wen, M. A. Terrel, H. Kim et al.. Measurements of the birefringence and Verdet constant in an air-code fiber［J］. J. Lightwave Technol., 2009, 27(15): 3194～3201

[14] 廖延彪, 黎敏, 张敏等. 光纤传感技术与应用［M］. 北京:清华大学出版社, 2009. 7～19

Liao Yanbiao, Li Min, Zhang Min et al.. Optical Fiber Sensing Techniques and Applications ［M］. Beijing: Tsinghua University Press, 2009. 7～19

[15] J. Blake. In-line Sagnac interferometer current sensor［J］. IEEE T. Power Deliver., 1996, 11(1): 116～121

[16] 李绪友, 郝金会, 杨汉瑞等. 消除萨格纳克FOCT振动干扰的光纤补偿环研究［J］. 中国激光, 2012, 39(2): 0205005

Li Xuyou, Hao Jinhui, Yang Hanrui et al.. Research on the compensating fiber loop for eliminating vibration in Sagnac optic current sensor［J］. Chinese J. Lasers, 2012, 39(2): 0205005

[17] 何竞翼, 刘德明, 张新亮等. 光纤偏振态自动补偿的光纤电流互感器［J］. 光学学报, 1999, 19(12): 1678～1681

He Jingyi, Liu Deming, Zhang Xinliang et al.. Polarization state auto-compensated optical fiber current transducer［J］. Acta Optica Sinica, 1999, 19(12): 1678～1681

[18] 董小鹏, B. C. B. Chu, K. S. Chiang. 可补偿偏置漂移的扭转FOCT［J］. 光学学报, 1999, 19(7): 981～987

Dong Xiaopeng, B. C. B. Chu, K. S. Chiang. Twisted fibre electric current sensor with compensation for arbitrary bias phase shift［J］. Acta Optica Sinica, 1999, 19(7): 981～987

庄静, 肖悦娱, 彭蕾, 颜锦奎. 基于光纤电流传感器的韦尔代常数优化测量法[J]. 光学学报, 2012, 32(11): 1128003. Zhuang Jing, Xiao Yueyu, Peng Lei, Yan Jinkui. Measurement of Verdet Constant in Fiber Optical Current Transducer Using an Optimization Method[J]. Acta Optica Sinica, 2012, 32(11): 1128003.

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