Microwave Sensor Array Based on Differential Mode Detection Strategy

0 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE microwave and wireless technology letters Pub Date : 2024-12-04 DOI:10.1109/LMWT.2024.3505961

Leijun Xu;Fanfan Li;Shengqi Zhang;Xue Bai;Qiang Wang;Jianfeng Chen

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Abstract

A novel microwave sensor array utilizing a differential-mode detection strategy is introduced for localized material defect detection. Two types of modified split-ring resonators (SRRs) with unloaded Q-factor above 437 and 290, respectively, are utilized to construct the basic differential sensing elements. By arranging these elements with different sizes, a sensor array can be realized. Since the distinct resonant frequency of each element, multiple transmission zeros are included in the working range. Each resonance zero corresponds to an independent region of the material under test (MUT). Any local defect will cause a split in the corresponding resonant frequency. Therefore, detection results can be obtained simply by observing the split points in the resonance spectrum, eliminating the need for further calibration. This letter presents the coupling mechanisms of the proposed two basic sensing units and the operating principle of the proposed sensor array. A prototype operating from 2.4 to 4.6 GHz with five independent differential units has been designed and fabricated. Three different samples with local defects were used for validation.

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基于差模检测策略的微波传感器阵列

介绍了一种基于差模检测策略的新型微波传感器阵列，用于材料局部缺陷检测。采用两种改型的分环谐振器（SRRs），其空q因子分别大于437和290，构建基本差分传感元件。通过排列这些不同尺寸的元件，可以实现传感器阵列。由于每个元件的谐振频率不同，工作范围内包含多个传输零点。每个共振零对应于被测材料（MUT）的一个独立区域。任何局部缺陷都会导致相应谐振频率的分裂。因此，只需观察共振谱中的分裂点即可获得检测结果，无需进一步校准。本文介绍了所提出的两个基本传感单元的耦合机制和所提出的传感器阵列的工作原理。设计并制作了一个工作频率为2.4 ~ 4.6 GHz、具有5个独立差分单元的样机。用三种不同的带有局部缺陷的样品进行验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE microwave and wireless technology letters

CiteScore

6.00

自引率

0.00%

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