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选择性填充光子晶体光纤的高灵敏温度传感 被引量:3

Temperature Sensing Based on Selective-Filled PCF
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摘要 为了研制具有更高灵敏特性的温度传感器,文章提出利用光子带隙效应,在PCF(光子晶体光纤)中选择性填充热敏液体实现高灵敏温度传感。应用全矢量平面波展开法计算光纤带隙,带隙及其宽度随温度规律性漂移。当在包层空气孔中选择不同位置和结构填充热敏液体时,发现仅填充内层空气孔时,带隙随温度漂移造成的变化率最大。当在包层第一层空气孔中填充热敏液体,晶格周期Λ=9μm,空气填充率分别选取d/Λ=0.9和d/Λ=0.5时,带隙边界波长检测和带隙宽度检测的温度灵敏度分别可达到22.07和7.01nm/℃,具有精确度高和系统结构简单的优点。 For the development of a temperature sensor with still higher sensitivity,this paper proposes to selectively fill ther-mosensitive fluid into the PCF by using the photonic bandgap effect so as to achieve highly sensitive temperature sensing.It calculates the bandgap using the full vector plane wave expansion method and the bandgap and its width drift regularly with temperature.When the thermosensitive fluid is selectively filled in the different locations and structures of the cladding air holes it is found that when only the inner air holes are filled,the variation caused by the bandgap with temperature drift is the maximum;When the 1 st-layer air holes of the cladding is filled with the fluid,the lattice periodΛ = 9 μm and air-filling ratio are repectively selected as d/Λ = 0.9 and d/Λ = 0.5,the temperature sensitivity in bandgap boundary wavelength detection and band-gap width detection can be 22.07 and 7.01 nm/℃ respectively,which shows the advantages in high accuracy and simple system structure.
出处 《光通信研究》 北大核心 2016年第1期55-58,共4页 Study on Optical Communications
关键词 光纤光学 光子晶体光纤 温度传感器 选择性液体填充 光子带隙 fiber optics PCF temperature sensor selective liquid filling photonic bandgap
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参考文献13

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