高指示多波段微带贴片天线的生物医学应用,灵感来自超材料

IF 2.4 Q2 ENGINEERING, MULTIDISCIPLINARY Innovation and Emerging Technologies Pub Date : 2023-01-01 DOI:10.1142/s2737599423500044
P. Arockia Michael Mercy, K. S. Joseph Wilson
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引用次数: 0

摘要

最近医疗技术的进步限制了生物医学应用的设备数量。为了应对现代无线技术的快速发展,人们提出了各种技术来提高新型天线设计的性能。提出了一种基于超材料(MTM)的微带天线结构。这项工作的目的是提出一个利用MTM特性的无线系统的高指向性天线。通过在地面结构上加入MTM结构,提高了指向性。为了提高医学应用天线的性能参数,本研究提供了一种采用分环MTM的多波段贴片天线的设计和分析。劈环谐振器(SRR) MTM结构以一种独特而新颖的方式嵌入天线的地面结构中。因此,在贴片腔中引入了亚波长模式,获得了良好的性能特性。参考天线是一个矩形微带贴片天线,其指向性为1.1823 dB,谐振频率为2.32 GHz[公式:见文本]。优化的SRR MTM位于建议天线的地平面上,以增加天线的指向性。该技术涵盖用于生物医学应用的2.24至3.96 GHz的频率范围[公式:见文本]和用于医疗、工业和科学领域的4.48至9.08 GHz的超宽带(UWB)范围。矩形srr的间隙数是指向性从1.1823增强到8.88823的关键组成部分[公式:见文本]dB。
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High-directive multiband microstrip patch antenna for biomedical applications, inspired by metamaterial
Recent advancements in medical technology impose a limited number of devices for biomedical applications. A variety of techniques are being proposed to improve the performance of novel antenna designs in response to the rapid development of modern wireless technologies. A miniaturised microstrip antenna structure based on metamaterial (MTM) is presented here. The objective of this work is to present a high-directive antenna for wireless systems utilising MTM properties. Directivity is improved by the incorporation of the MTM structure on the ground structure. In order to improve the performance parameters of the antenna for medical applications, this study provides the design and analysis of a multiband patch antenna employing split-ring MTM. The split-ring resonator (SRR) MTM structures are embedded in a unique and novel way in the ground structure of the antenna. So that subwavelength modes get introduced in the patch cavity and a good performance characteristics is obtained. The reference antenna is a rectangular microstrip patch antenna exhibiting a directivity of 1.1823[Formula: see text]dB that resonates at a frequency of 2.32[Formula: see text]GHz. The optimised SRR MTM is positioned in the ground plane of the suggested antenna to increase the directivity of the antenna. This technology covers the frequency range between 2.24 and 3.96[Formula: see text]GHz used for biomedical applications and the ultra-wideband (UWB) range from 4.48 to 9.08[Formula: see text]GHz used for medical applications, industrial and scientific areas. The number of gaps of the rectangular-shaped SRRs is a key component of the enhancement of directivity from 1.1823 to 8.88823[Formula: see text]dB.
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