Circular Open-Cavity Resonator for Microwave Characterization of Free-Flowing Materials

IF 1.5

IEEE Open Journal of Instrumentation and Measurement Pub Date : 2025-08-01 DOI:10.1109/OJIM.2025.3594383

Joseph T. Filbert;Matthew R. Dvorsky;Reza Zoughi

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Abstract

Accurate, fast, and in-line determination of the microwave properties of free-flowing materials, such as gases, liquids, and powders, remains a challenge. This work details the development of a novel microwave resonant sensor based on a circular open-cavity design using a circular waveguide feed operating in the TE01 circular waveguide mode, to address this issue. This open-cavity design allows a free-flowing material under test (MUT), to pass through the cavity enabling in-line measurement of its reflection coefficient, which can then be used to estimate its effective dielectric and magnetic properties. A forward model describing the electromagnetic (EM) behavior of the sensor is derived using modal analysis and subsequently validated using full-wave simulation. The forward model facilitates accurate inversion of the measured reflection coefficient (i.e., S-parameter, S11) data for determining the effective dielectric or magnetic properties of the MUT. To demonstrate the efficacy of the sensor, measurements of an offline (static, not flowing) powder, as well as a flowing metal powder, are presented.

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圆形开腔谐振器用于自由流动材料的微波表征

准确、快速、在线地测定自由流动材料（如气体、液体和粉末）的微波特性仍然是一个挑战。这项工作详细介绍了一种基于圆形开腔设计的新型微波谐振传感器的开发，该传感器使用在TE01圆形波导模式下工作的圆形波导馈电来解决这个问题。这种开腔设计允许自由流动的被测材料（MUT）通过空腔，从而可以在线测量其反射系数，然后可用于估计其有效介电和磁性能。利用模态分析导出了描述传感器电磁（EM）行为的正演模型，并随后使用全波仿真进行了验证。正演模型有助于精确反演实测反射系数（即s参数，S11）数据，以确定MUT的有效介电或磁性能。为了证明该传感器的有效性，给出了离线（静态，不流动）粉末和流动金属粉末的测量结果。

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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IEEE Open Journal of Instrumentation and Measurement

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