六边形CSRR微带谐振器测量介电常数的研究
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摘要
介电常数是表征材料介电特性的物理量,随着微波电介质在航空器、船舶及车辆和通信等领域的广泛应用,介电常数的精确测量成为人们研究的一个重要内容。为了提高介电常数的测量精度,文章首先提出一种加载六边形互补开口谐振环(CSRR)的微波无损平面传感器。将六边形CSRR微带谐振器与传统的四边形CSRR微带谐振器进行对比,分析结果表明,六边形CSRR较四边形CSRR微带谐振器具有较高的灵敏度,且品质因数也有一定的提高。然后,研究了六边形CSRR微带谐振器谐振频率的变化与介电常数的相互作用规律,仿真结果表明,当待测样品的介电常数变大时,其谐振频率变小,且谐振频率的负二次方与介电常数呈线性关系;将仿真数据进行数据拟合得到介电常数与谐振频率之间的解析式,验证了通过测量加载待测样品时传感器的谐振频率实现对待测样品介电常数测量的可能性,对以后的工程设计具有重要的参考价值。
The dielectric constant is a physical quantity that characterizes the dielectric properties of a material.With the use of microwave dielectrics in aircraft,ships,vehicles,communications,and other fields,the accurate measurement of dielectric constant has become a hot research topic.In order to improve the measurement accuracy of dielectric constant,a microwave non-destructive planar sensor loaded with hexagonal Complementary Split Ring Resonator(CSRR)is proposed.Comparing with the traditional quadrilateral CSRR microstrip resonator,the analysis results show that the hexagonal CSRR microstrip resonator has higher sensitivity than the quadrilateral CSRR,and the quality factor is also improved.Then,the interaction of the resonant frequency and the dielectric constant of the hexagonal CSRR microstrip resonator is studied.The simulation results show that when the dielectric constant of the measured sample becomes larger,the resonant frequency becomes smaller.The negative quadratic and the dielectric constant are linearly related.The analytical data of the dielectric constant and the resonant frequency are obtained by fitting the data of the simulation data,which are verified by measuring the resonant frequency of the sample when loading the measured sample.The proposed measurement method has important reference value in future engineering design.
The dielectric constant is a physical quantity that characterizes the dielectric properties of a material.With the use of microwave dielectrics in aircraft,ships,vehicles,communications,and other fields,the accurate measurement of dielectric constant has become a hot research topic.In order to improve the measurement accuracy of dielectric constant,a microwave non-destructive planar sensor loaded with hexagonal Complementary Split Ring Resonator(CSRR)is proposed.Comparing with the traditional quadrilateral CSRR microstrip resonator,the analysis results show that the hexagonal CSRR microstrip resonator has higher sensitivity than the quadrilateral CSRR,and the quality factor is also improved.Then,the interaction of the resonant frequency and the dielectric constant of the hexagonal CSRR microstrip resonator is studied.The simulation results show that when the dielectric constant of the measured sample becomes larger,the resonant frequency becomes smaller.The negative quadratic and the dielectric constant are linearly related.The analytical data of the dielectric constant and the resonant frequency are obtained by fitting the data of the simulation data,which are verified by measuring the resonant frequency of the sample when loading the measured sample.The proposed measurement method has important reference value in future engineering design.
引文
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[2] Jha A K,Akhtar M J.Automated RF Measurement System for Detecting Adulteration in Edible Fluids[C]//2013IEEE Applied Electromagnetics Conference.Bhubaneswar,India:IEEE,2015:1-2.
[3] Celik N,Gagarin R,Huang G C,et al.Microwave Stethoscope:Development and Benchmarking of a Vital Signs Sensor Using Computer-Controlled Phantoms and Human Studies[J].IEEE Transactions on Biomedical Engineering,2014,61(8):2341-2349.
[4] Boybay M S,Ramahi O M.Non-Destructive Thickness Measurement Using Quasi-Static Resonators[J].IEEE Microwave&Wireless Components Letters,2013,23(4):217-219.
[5] Jha A K,Akhtar M J.A Generalized Rectangular Cavity Approach for Determination of Complex Permittivity of Materials[J].IEEE Transactions on Instrumentation&Measurement,2014,63(11):2632-2641.
[6] Shete M,Shaji M,Akhtar M J.Design of a Coplanar Sensor for RF Characterization of Thin Dielectric Samples[J].IEEE Sensors Journal,2013,13(12):4706-4715.
[7] Narayanan P M.Microstrip Transmission Line Method for Broadband Permittivity Measurement of Dielectric Substrates[J].IEEE Transactions on Microwave Theory&Techniques,2014,62(11):2784-2790.
[8]马闯,杨晓东,谢浩,等.利用微波传感器检测生化溶液浓度[J].化学工程与装备,2016,36(4):215-218.
[9] Akhtar Z A M J.Time Domain Microwave Technique for Dielectric Imaging of Multi-Layered Media[J].Journal of Electromagnetic Waves&Applications,2015,29(3):386-401.
[10]Lee H J,Lee J H,Moon H S,et al.A Planar SplitRing Resonator-based Microwave Biosensor for LabelFree Detection of Bio-Molecules[J].Sensors&Actuators B Chemical,2012,169(13):26-31.
[11]Withayachumnankul W,Jaruwongrungsee K,Tuantranont A,et al.Metamaterial-based Microfluidic Sensor for Dielectric Characterization[J].Sensors&Actuators A Physical,2013,189:233-237.
[12]Ebrahimi A,Withayachumnankul W,Alsarawi S,et al.High-Sensitivity Metamaterial-Inspired Sensor for Microfluidic Dielectric Characterization[J].IEEE Sensors Journal,2014,14(5):1345-1351.
[13]何婉霞,肖中银,姜逸飞.基于新型CSRR结构的SIW双频滤波器[J].电子测量技术,2017,(10):176-180.
[14]李芳,李超.微波异向介质:平面电路实现及应用[M].北京:电子工业出版社,2011.
[15]Ebrahimmi A,Withayachumnankul W,Aisarawi S F,et al.Dual-Mode Behavior of the Complementary Electric-LC Resonators Loaded on Transmission Line:Analysis and applications[J].Journal of Applied Physics,2014,116(8):P083705-1.