Tunable frequency-multiplying optoelectronic oscillator based on a dual-parallel Mach-Zehnder modulator incorporating a phase-shifted fiber Bragg grating

A tunable frequency-multiplying optoelectronic oscillator(OEO) based on a dual-parallel Mach-Zehnder modulator(DPMZM) is proposed and experimentally demonstrated. In the proposed system, the tunable fundamental microware signal is generated by a tunable optoelectronic oscillator incorporating a phase-shifted fiber Bragg grating(PS-FBG). By adjusting the DC bias of the DPMZM, the frequency-doubled microwave signal with a tunable frequency range from 11 GHz to 20 GHz and the frequency-quadrupled microwave signal with a tunable frequency range from 22.5 GHz to 26 GHz are generated. The phase noises of the fundamental, frequency-doubled and frequency-quadrupled signals at 10 k Hz offset frequency are-105.9 d Bc/Hz,-103.3 d Bc/Hz and-86.2 d Bc/Hz, respectively.

Study on the Characters of Phase-Shifted Fiber Bragg Grating in Asymmetric Perturbation and Its Application in Fiber Laser Acoustic Sensor

A n-phase-shifted fiber Bragg grating theoretical model is established, and the effects of an asymmetric and symmetrical perturbation field on a phase-shifted fiber Bragg grating are investigated in this paper. The trends of wavelength shifting caused by effective refraction index of phase shift grating in symmetric and asymmetric acoustic field are investigated in detail. Then, the fiber laser acoustic sensors packaged in asymmetric and symmetrical structures are designed and tested, respectively. The results show that the acoustic response of the wavelength of the distributed feedback （DFB） fiber laser （FL） in an asymmetric packaging structure is much more sensitive than in that in the symmetrical structure. The sensor packaged in the asymmetrical structure has a better low frequency （0Hz-500Hz） performance and a higher sensitivity than that in the symmetrical structure, and the sensitivity is improved about 15dB in average and 32.7dB in maximum. It provides a new method to improve the sensitivity of the fiber acoustic sensor.

复合材料基体裂纹光纤光栅非线性超声Lamb波检测试验研究

针对复合材料基体裂纹引起的超声非线性问题,研究了一种具有比例–积分–微分反馈控制的高灵敏度、大带宽相移光纤光栅超声检测系统。利用相移光栅系统检测在复合材料中传播的超声Lamb波信号,对Lamb波进行数据处理,分离出了频率为2.0MHz的二次谐波成分。结果表明,随着裂纹个数的增加,相对非线性参数线性增长,且相比压电传感器检测结果,相移光栅检测的相对非线性参数具有更高的增长速率。提出的相移光纤光栅传感系统可应用于复合材料的基体裂纹损伤评估,且具有很高的可靠性。

基于啁啾相移光纤光栅的多波长滤波器的研究

使用Ⅴ-Ⅰ传输矩阵法分析了相移量、相移点位置以及啁啾系数对啁啾相移光纤光栅透射谱特性的影响,并分析了在啁啾光纤光栅中同时引入多相移时生成的多陷波滤波器的波长间隔,发现其与以同样的位置引入单相移时陷波滤波器的波长偏离间隔基本一致。依据仿真分析结果,可以优化啁啾相移光栅相移数量、位置间隔、啁啾系数和相移量的参数选择,设计出实际需要的多波长滤波器。

基于π相移光栅的温度传感特性研究

提出了一种简易的利用π相移光栅(π-PSFBG)实现温度测量的传感系统。系统利用了π相移光栅的窄带特征,可显著提高系统灵敏度,系统结构简单,易于操作。通过实验验证了该传感器的温度传感特性,结果显示:随着温度的升高,π-PSFBG的中心波长呈线性变化,线性拟合度R2为0. 999 5,温度灵敏度约为10. 2 pm/℃。

基于相移光纤光栅有机聚合物电光调制器研究

将相移光纤光栅(PSFBG)有机聚合物相结合,利用相移光纤光栅的窄带透射峰特性,设计了一种D型结构的全光纤电光调制器,并对其进行理论分析。主要研究了聚合物到纤芯中心的距离、聚合物厚度以及聚合物折射率对相移光纤光栅中心波长漂移量的影响,分析了高频调制电压下相移光纤光栅的传输谱的变化。研究结果表明,通过选择合适参数,当聚合物折射率变化为10-4时,中心波长漂移量可以达到10-2nm;同时,高频电压调制下,相移光纤光栅传输谱的形状以及中心波长还会受光栅长度和调制频率的影响。

基于CPM-FBG的单频窄线宽DFB光纤激光器

利用电弧放电对光纤Bragg光栅(FBG)折射率的调制作用,提出了基于折射率周期调制(CPM)FBG的单频窄线宽分布反馈(DFB)光纤激光器方案。建立了CPM-FBG的数学模型并进行了仿真,验证了CPM-FBG的相移光栅特性;在掺铒光纤(EDF)上制作出CPM-FBG,形成了DFB单频窄线宽光纤激光器,激光器阈值功率为25.4mW,3dB线宽为805Hz,边摸抑制比大于48.8dB。

相移光纤光栅对超声波信号的频率响应特性研究

为实现利用相移光纤Bragg光栅(phase-shifted fiber Bragg grating,PS-FBG)代替压电陶瓷(piezoelectric ceramics,PZT)进行结构损伤检测,本文研究了PS-FBG对100 kHz—1.5 MHz范围内的超声波信号的频率响应特性。搭建了超声波激励信号的产生平台和高灵敏度光纤光栅平衡传感系统,利用幅度分析法对连续超声波激励下的传感器响应信号进行分析。由于薄板存在共振频率的问题,使用时间长度为0.5 ms的突发型激励信号,并用能量分析法评估传感器的响应情况。实验结果表明,PS-FBG传感器的频率响应在±3.49 dB范围内,由此可得PS-FBG传感器对100 kHz—1.5 MHz范围内的超声波信号具有宽谱响应的特性。