侧面研磨光纤Bragg光栅的外部折射率敏感特性研究

光纤Bragg光栅对外界折射率的变化不灵敏,无法直接作为气体、液体等的敏感元件.侧面研磨的光纤Bragg光栅,一侧包层减小至几微米,其辐射场可通过包层透射到被传感物质,因而被传感物质的折射率的变化可以改变光纤的有效折射率,从而使光栅的Bragg波长产生位移.实验中利用不同浓度的NaCl溶液来改变光纤光栅的外部折射率,Bragg中心波长的偏移量和浓度近似为线性关系.同时,透射功率的变化量和浓度也近似为线性关系.     

镀镍光纤Bragg光栅温度传感特性实验研究

在光纤智能金属结构材料中,为了保护光纤Bragg光栅并使得传感器与基体金属有很好的结合性,在光纤Bragg光栅表面化学镀镍,并实验研究了化学镀镍前后的光纤Bragg光栅的温度传感特性.实验表明：镀镍后的光纤光栅的Bragg波长随温度变化呈现出良好的线性和重复性,Bragg光栅温度灵敏度变大.     

小直径光纤光栅的研制及传感交叉敏感研究

研究了小直径光纤光栅的研制以及传感中的温度应变交叉敏感问题.首先根据耦合模理论,分析了小直径光纤Bragg光栅光谱特性,确定了包覆层为80 μm的单模光纤加工成中心波长为1 528 nm的Bragg光栅的栅长及周期,并研究了小直径光纤光栅与解设备之间的连接方式.其次利用等强度梁的变形特点,结合矩阵法,提出基于等强度悬臂梁双Bragg光纤光栅矩阵算法,对小直径光纤Bragg光栅的交叉敏感问题进行研究.温度和应变的实验辨别误差分别为5%和6%.实验结果表明,该方法可以分离温度和应变对光纤Bragg光栅传感的影响.采用该方法去除交叉影响,K矩阵始终存在逆矩阵,因此对所采用的光栅无特殊要求,从而扩大了光纤光栅选用范围,并将温度和应变识别出来.     

一种基于外差探测的光纤Bragg光栅温度传感器

提出了一种基于光纤Bragg光栅的温度传感器，阐述了光纤Bragg光栅的温度传感机理，用2个相同的光纤Bragg光栅构成折叠式Mach Zehnder(M Z)干涉仪，其中一个光栅作为参考臂，另一个作为传感臂：采用外差探测技术来测量外界的温度物理量。当温度发生变化，Bragg光栅的波长也随之改变。外差探测用来探测传感臂和参考臂由于温度变化引起的输出信号的频率差异。对其动态测量范围和灵敏度也进行了分析。     

岩层变形检测的光纤光栅多点传感理论与工程应用

为了监测松散地层沉降变形,提出了一种用于钻孔中植入式光纤Bragg光栅传感器(FBG)的结构和传感网络系统.基于室内实验结果,给出了用于岩层变形检测的传感光栅波长带宽为6 nm,分析了多点传感信号分辨因子,山光源带宽决定的测试系统最大实际复用能力为6个传感器.设计并实现了一个由18个光纤光栅组成的具有特色的光纤Bragg光栅波分复用/空分复用混合阵列.工程实践表明,光纤光栅传感系统采用双同路布置.可提高系统下放后光纤光栅传感器的成活率.     

采用WDM技术的光纤Bragg光栅传感网络

采用绝对测量原理的波长调制技术,光纤Bragg光栅可组成并行、串行和阵列WDM拓扑结构.分析表明,光纤Bragg光栅网络的工作原理类似于一个多宽带平面镜.利用光谱仪可测量上述光纤Bragg光栅网络的反射谱,其中,光源是宽带为～40nm的掺饵光纤放大器.当网络中的光纤Bragg光栅受扰动后,受扰光栅的反射谱发生相应的变化,即Bragg波长发生相应的偏移.结果表明,当事先确定了光纤光栅的波长调制范围,反射的峰值波长能反应光纤光栅传感网络的信息.值得注意的是～3nm的波长调制范围可满足～100℃和～2000με的参量测量.     

光纤光栅传感器交叉敏感问题研究

交叉敏感问题是光纤光栅传感器在实际应用中需面对的一个关键问题。从光纤Bragg光栅的传感理论出发，分析了光纤光栅在同时测量应变和温度时引起交叉敏感的物理机理，建立了带有温度-应变交叉灵敏度系数的光纤Bragg光栅反射波长方程。利用双波长矩阵算法针对上述建立的光纤光栅方程进行了误差分析，获取了在交叉敏感情况下温度和应变的相对误差曲线图。结合相对误差表达式和曲线图分析讨论了交叉敏感对测量带来的影响。结果表明在温度和应力测量中随着测量温度或者应变变化量的增大，忽略交叉敏感项而带来的测量误差越来越明显。     

侧边抛磨光纤光栅的数值模拟和实验研究

本文设计并建立侧边抛磨光纤Bragg光栅的光学模型,通过改变剩余包层的厚度以及抛磨区材料的折射率,模拟计算光栅谐振波长的偏移量以及光栅光谱反射率的变化.实验结果表明,当抛磨区材料折射率越接近光纤纤芯折射率,以及抛磨程度越深(3μm以内),抛磨区材料的折射率的微小变化也会引起光栅谐振波长与光栅光谱反射率明显变化.     

掺铒光纤动态光栅与光纤Bragg光栅Fabry-Perot腔特性研究

提出的一种由掺铒光纤动态光栅和光纤Bragg光栅构成的Fabry-Perot腔。通过建立二能级掺铒光纤动态光栅模型,根据半经典相互作用理论和传输矩阵理论,计算出掺铒光纤动态光栅以及该Fabry-Perot腔的透过率和反射率,并分析动态光栅中相干探测场拉比频率、掺铒光纤长度、光纤Bragg光栅的折射率调制深度以及FabryPerot腔的腔长等参数改变时对动态光栅和Fabry-Perot腔反射谱的影响。该Fabry-Perot腔的一个重要性质是其输出光谱可以通过调节探测场的拉比频率、探测场波长等参数进行动态调制。相比于由两个光纤Bragg光栅构成的Fabry-Perot腔,参数可调的系统比参数固定的系统更加灵活,并且能够克服Fabry-Perot腔两端的光纤Bragg光栅不对称的缺点(如不同的Bragg波长、折射率调制深度等),更有利于Fabry-Perot腔的模式选择。该光纤Fabry-Perot腔可以应用于光纤通信的光信号处理或光纤传感领域。     

有限包层半径光纤Bragg光栅的理论研究

采用光纤波导三层模型,对有限包层半径光纤Bragg光栅导模有效折射率的改变进行了理论分析,结果表明:当包层直径小于16μm时,单模光纤Bragg光栅(纤芯直径为8.3μm)的导模有效折射率才开始发生明显变化.在包层外添加外包层,通过改变外包层的折射率可以实现对光栅Bragg反射波长的调谐,同时对不同芯子直径的光栅Bragg波长移动进行了数值计算.在保证光纤归一化频率不变的前提下,芯径越小Bragg波长调谐范围越大,当包层厚度为1μm时,芯径为a＝2.2μm的光栅Bragg波长调谐范围约为3.9μm.     

Interrogation of fiber-Bragg-grating temperature and strain sensors with a temperature-stabilized VCSEL

The interrogation of fiber-Bragg-grating (FBG) sensors using a vertical-cavity surface-emitting laser (VCSEL) is discussed. A long-wavelength (1.54 μm) VCSEL was used as a wavelength-tunable source by variation in the current. Temperature stabilization was performed with a thermoelectric device. Characteristics of temperature and strain sensing were investigated. FBGs with different reflectivities were compared. For temperature sensing, the root-mean-square error in the measurement was reduced to 1/3 that without temperature stabilization. The dependence of the measurement error on the reflectivities of the FBGs was investigated. The measurement error was larger for FBGs with lower reflectivities in both temperature and strain sensing. Improvement on the sensing with low-reflectivity FBGs is discussed.     

Quasi-distributed fiber Bragg grating sensor system based on a Fourier domain mode locking fiber laser

A novel quasi-distributed fiber Bragg grating (FBG) sensor system based on Fourier domain mode locking (FDML) fiber laser is proposed and demonstrated. The low reflectivity FBGs with the same Bragg wavelength are connected cascaded in a long fiber working as the sensing elements of the sensor system as well as the wavelength and cavity length selecting elements of the FDML laser. By adjusting the driving frequency of the FDML fiber laser, lasing with different selected cavity lengths will be achieved correspondingly. When the wavelength of the working FBG shifts which includes the sensing information, FBG interrogation can be realized both in wavelength and time domain.     

Quasi-distributed temperature sensor combining Fibre Bragg Gratings and temporal reflectometry technique interrogation

Quasi-distributed sensors based on Fibre Bragg Gratings (FBG) usually deal with the concatenation of FBGs of different Bragg wavelengths analyzed through wavelength-sensitive devices. In these sensors, a given wavelengths range is dedicated to one particular FBG. The number of sensing points is directly limited by the source and detector spectral ranges, and by the wavelength spacing between two gratings. This spacing is linked to the maximum possible excursion of the physical parameter to be measured-before superimposition of the reflection spectra of the FBGs.In this paper, an original interrogating device is presented, that allows a very large number of concatenated gratings to be addressed. In this scheme, identical FBGs (same Bragg wavelength and same low reflectivity) are interrogated by the Optical Time Domain Reflectometry technique, for which a commercial device has been extended to a wavelength-tunable system, within an automated experimental set-up. Detection and localization of an important amount of sensing points along a unique optical fibre is demonstrated. Repeatability measurements did exhibit the very good accuracy of the presented sensor.     

基于少模-无芯-少模光纤结构的高灵敏度折射率传感器

光纤折射率传感器广泛应用于各种复杂环境的监测。设计了一种基于少模光纤（fewmode fiber,FMF）–无芯光纤（coreless fiber,CLF）–FMF结构的高灵敏度折射率传感器。该传感器由2小段FMF之间熔接1段减薄的CLF组成马赫-增德尔干涉仪（Mach–Zehnder interference,MZI）,测量外界折射率,利用光纤布拉格光栅（fiber Bragg grating,FBG）进行温度补偿。MZI干涉光谱中的谐振波谷同时受折射率和温度影响,FBG只受温度的影响。利用MZI和FBG的折射率和温度灵敏度系数构建灵敏度矩阵,实现折射率和温度的同步测量。实验结果表明,MZI折射率灵敏度为345.66 nm/RIU,温度灵敏度为0.013 4 nm/℃;FBG的温度灵敏度为0.010 4 nm/℃。     

Multiple fiber Bragg grating interrogation based on a spectrum-limited Fourier domain mode-locking fiber laser

A novel fiber Bragg grating (FBG) sensing system based on a spectrum-limited Fourier domain mode-locking (SL-FDML) fiber laser is proposed. Multiple FBGs cascaded in a long fiber are utilized as both the sensors in the system and the wavelength-selected components in the SL-FDML fiber laser. Both wavelength-division multiplexing and spatial-division multiplexing techniques are demonstrated for interrogation of multiple FBGs by mapping the wavelength measurement to the time measurement and by adjusting the driving frequency of the SL-FDML fiber laser. The proposed FBG sensing system, employing techniques of the wavelength- and spatial-domain interrogation of multiple FBGs, can be used in remote and quasi-distributed multipoint sensing.     

弯曲光纤布拉格光栅靶式流量传感器的研究

设计了一种基于光纤布拉格光栅(FBG)的弯曲靶式流量传感器,采用COMSOL软件仿真了弯曲靶臂受力时的应变分布规律,并将两支FBGs分别粘贴于靶臂的外侧和内侧进行应力测试,仿真与实验结果表明在外力作用下靶臂外侧和内侧分别产生拉应变和压应变,FBGs反射中心波长产生红移和蓝移。同时,测试了该结构的温度特性,在20 ℃~40 ℃两支FBGs反射中心波长均与温度呈线性关系,从而可消除温度对测量结果的影响。随后搭建了弯曲靶式FBG流量传感器测量装置,在0~800 L/H范围内的测量结果表明,两支FBGs反射中心波长与水流量呈较好的线性关系,其流量灵敏度为48 L/H。     

可分离温度影响的FBG应变测量方法

光纤布拉格光栅在通信和传感领域具有广泛的应用。利用光纤布拉格光栅中心波长的偏移，可以测量温度和应变等多种物理量，但必须解决光栅对温度和应变的交叉敏感问题。该文简要分析了光纤光栅作为传感器的基本原理及其优点，设计了利用参考光栅法分离温度影响以及利用掺铒光纤的自发发射放大特性分离温度影响的2种应变测量方法。最后，介绍了一种利用倾斜光纤光栅的主模和边模对布拉格光栅中心波长的偏移进行解调的方法，该方法成功地分离了温度对应变测量的影响。     

A linearity interrogation technique with enlarged dynamic range for fiber Bragg grating sensing

An exact linearity interrogation technique with enlarged dynamic range for fiber Bragg grating (FBG) sensor has been analyzed theoretically and demonstrated experimentally. The technique bases on two matched FBGs for receiving the reflected signal from the sensor FBG and two photodiodes (PDs) for collecting the reflected signal from the two receiver FBGs. The linear expression between the nature logarithm of the output ratio of the two PDs and Bragg wavelength of the sensor FBG is obtained on the condition that the bandwidths of the two receiver FBGs being equal to each other. The wavelength of the sensor FBG can be interrogated simply and accurately by the linearity technique according to the expression. In addition, a new tunable paralleled matched gratings interrogation scheme is proposed. The interrogation range can be enlarged and multiple FBG sensors can be interrogated simultaneously with the tunable interrogation scheme.