Exceptional-point-enhanced sensing in an all-fiber bending sensor

IF 15.3 1区 物理与天体物理 Q1 OPTICS
Zheng Li, Jingxu Chen, Lingzhi Li, Jiejun Zhang, Jianping Yao
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引用次数: 0

Abstract

An exceptional-point (EP) enhanced fiber-optic bending sensor is reported. The sensor is implemented based on parity-time (PT)-symmetry using two coupled Fabry-Perot (FP) resonators consisting of three cascaded fiber Bragg gratings (FBGs) inscribed in an erbium-ytterbium co-doped fiber (EYDF). The EP is achieved by controlling the pumping power to manipulate the gain and loss of the gain and loss FP resonators. Once a bending force is applied to the gain FP resonator to make the operation of the system away from its EP, frequency splitting occurs, and the frequency spacing is a nonlinear function of the bending curvature, with an increased slope near the EP. Thus, by measuring the frequency spacing, the bending information is measured with increased sensitivity. To achieve high-speed and high-resolution interrogation, the optical spectral response of the sensor is converted to the microwave domain by implementing a dual-passband microwave-photonic filter (MPF), with the spacing between the two passbands equal to that of the frequency splitting. The proposed sensor is evaluated experimentally. A curvature sensing range from 0.28 to 2.74 m−1 is achieved with an accuracy of 7.56×10−4 m−1 and a sensitivity of 1.32 GHz/m−1, which is more than 4 times higher than those reported previously.
全光纤弯曲传感器中的异常点增强传感
报道了一种异常点增强型光纤弯曲传感器。该传感器基于奇偶时间(PT)对称性实现,使用两个耦合法布里-珀罗(FP)谐振腔,该谐振腔由三个级联光纤布拉格光栅(fbg)组成,内嵌在铒镱共掺光纤(EYDF)中。EP是通过控制泵浦功率来控制增益和损耗FP谐振器的增益和损耗来实现的。一旦对增益FP谐振器施加弯曲力,使系统的工作远离其EP,就会发生频率分裂,并且频率间距是弯曲曲率的非线性函数,在EP附近斜率增加。因此,通过测量频率间隔,弯曲信息的测量具有更高的灵敏度。为了实现高速高分辨率的问讯,传感器的光谱响应通过实现双通带微波光子滤波器(MPF)转换到微波域,两个通带之间的间隔等于频率分裂的间隔。实验对该传感器进行了验证。曲率传感范围为0.28 ~ 2.74 m−1,精度为7.56×10−4 m−1,灵敏度为1.32 GHz/m−1,比以往报道的曲率传感精度提高了4倍以上。
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来源期刊
CiteScore
19.30
自引率
7.10%
发文量
128
期刊介绍: Opto-Electronic Advances (OEA) is a distinguished scientific journal that has made significant strides since its inception in March 2018. Here's a collated summary of its key features and accomplishments: Impact Factor and Ranking: OEA boasts an impressive Impact Factor of 14.1, which positions it within the Q1 quartiles of the Optics category. This high ranking indicates that the journal is among the top 25% of its field in terms of citation impact. Open Access and Peer Review: As an open access journal, OEA ensures that research findings are freely available to the global scientific community, promoting wider dissemination and collaboration. It upholds rigorous academic standards through a peer review process, ensuring the quality and integrity of the published research. Database Indexing: OEA's content is indexed in several prestigious databases, including the Science Citation Index (SCI), Engineering Index (EI), Scopus, Chemical Abstracts (CA), and the Index to Chinese Periodical Articles (ICI). This broad indexing facilitates easy access to the journal's articles by researchers worldwide. Scope and Purpose: OEA is committed to serving as a platform for the exchange of knowledge through the publication of high-quality empirical and theoretical research papers. It covers a wide range of topics within the broad area of optics, photonics, and optoelectronics, catering to researchers, academicians, professionals, practitioners, and students alike.
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