摘要
为了提高压力传感器的灵敏度,利用光子晶体光纤理论及其高双折射特性和可灵活设计的结构特点,设计了一种新型边孔高双折射光子晶体光纤压力传感结构.采用全矢量有限元法并结合COMSOL软件对传感结构的受力和模场分布进行仿真分析,获得压力传感特性随几何结构和自由空间波长的变化关系,通过优化设计得到最优结构参量,进一步获得高压力灵敏度.结果表明,在最优结构下,自由空间波长为1.55μm、压力为200MPa时,偏振相位灵敏度为166.2rad/(MPa·m),所能施加的最大压力为720MPa,相位模式双折射灵敏度保持在4.1×10^-5MPa^-1左右.该研究对提高压力传感器的灵敏度是有帮助的.
In order to improve the sensitivity of a pressure sensor, a novel pressure sensing structure of photonic crystal fiber with side hole and high birefringence was designed, based on the theory of photonic crystal fiber and its high birefringence and flexible design structure. The force and mode field distribution of sensing structure were simulated and analyzed by using full vector finite element method and COMSOL software. The dependence of pressure sensing characteristics on geometrical structure and free space wavelength was obtained. The optimum structural parameters were obtained by optimum design. The high pressure sensitivity was further obtained. The results show that, under the optimal structure, when free space wavelength is 1.55μm and pressure is 200MPa, polarization phase sensitivity is 166.2rad/(MPa·m) and maximum pressure that can be applied is 720MPa. The sensitivity of phase mode birefringence is maintained at about 4.1×10^-5MPa^-1. The research is helpful to improve the sensitivity of pressure sensors.
作者
朱虹茜
叶涛
张克非
ZHU Hongxi;YE Tao;ZHANG Kefei(School of Science, Southwest University of Science and Technology, Mianyang 621010, China;School of Communication and Information Engineering, University of Electronic Science and Technology of China, Chengdu 611731, China;School of Computer Science and Technology, Southwest University of Science and Technology, Mianyang 621010, China)
出处
《激光技术》
CAS
CSCD
北大核心
2019年第4期511-516,共6页
Laser Technology
基金
四川省科学技术厅重点研发基金资助项目(2018GZ0212)
国家级大学生创新创业训练计划资助项目(201810619085)
西南科技大学大学生创新基金资助项目(cx18-041)
关键词
光纤光学
压力传感器
全矢量有限元法
光子晶体光纤
高灵敏度
fiber optics
pressure sensor
full vector finite element method
photonic crystal fiber
high sensitivity
