An Improved Method to Measure, Characterize, and Model Microstrip Antennas in the W Band

IF 1.6 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Instrumentation & Measurement Magazine Pub Date : 2024-04-01 DOI:10.1109/MIM.2024.10472981

R. Murphy‐Arteaga, Edgar Colín-Beltrán, María T. Serrano-Serrano, Chudy Nwachukwu, Svetlana Carsof Sejas Garcia, R. Torres‐Torres

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引用次数: 0

Abstract

The rapid evolution of wireless technology demands an ever-growing number of connected devices, and hence, a greater availability of antennas for a gamut of applications in different frequency ranges [1]–[3]. The size, materials, and geometry of antennas, however, depend on the application as well as on important considerations, including resonant frequency, bandwidth, gain, efficiency, shape of the radiation pattern, input impedance, and many more [4]. Hence, a universal measuring technique for antennas cannot be derived, and in general, each case requires that it be treated individually. In addition, as frequency of measurement increases, more effects must be taken into account when interpreting data; one of relevance is that introduced by the surface roughness at the interface between the printed circuit board (PCB) substrate and the metal foil that serves as a conductor [5]–[6]. In fact, the surface roughness of the copper foil is necessary to achieve good adherence to the dielectric substrate, and thus, it is voluntarily included in the manufacturing process. Unfortunately, the variation of the metal surface from the ideal smooth case increases the resistance of the foil at microwave frequencies. In consequence, it negatively impacts the electrical performance of structures and should be considered when assessing the response of antennas on PCB.

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测量、鉴定和模拟 W 波段微带天线的改进方法

无线技术的飞速发展要求连接设备的数量不断增加，因此，不同频率范围的各种应用需要更多的天线[1]-[3]。然而，天线的尺寸、材料和几何形状取决于应用以及重要的考虑因素，包括谐振频率、带宽、增益、效率、辐射图形状、输入阻抗等[4]。因此，无法推导出通用的天线测量技术，一般来说，每种情况都需要单独处理。此外，随着测量频率的增加，在解释数据时必须考虑更多的影响；其中一个相关影响是印刷电路板（PCB）基板与作为导体的金属箔之间的界面表面粗糙度所带来的影响[5]-[6]。事实上，铜箔的表面粗糙度是实现与介质基板良好粘附的必要条件，因此在制造过程中会自愿加入。遗憾的是，金属表面与理想的光滑状态不同，会增加铜箔在微波频率下的电阻。因此，它会对结构的电气性能产生负面影响，在评估印刷电路板上天线的响应时应加以考虑。

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 Instrumentation & Measurement Magazine 工程技术-工程：电子与电气

CiteScore

4.20

自引率

4.80%

发文量

147

审稿时长

>12 weeks

期刊介绍： IEEE Instrumentation & Measurement Magazine is a bimonthly publication. It publishes in February, April, June, August, October, and December of each year. The magazine covers a wide variety of topics in instrumentation, measurement, and systems that measure or instrument equipment or other systems. The magazine has the goal of providing readable introductions and overviews of technology in instrumentation and measurement to a wide engineering audience. It does this through articles, tutorials, columns, and departments. Its goal is to cross disciplines to encourage further research and development in instrumentation and measurement.