5G sub-6GHz和毫米波频率的万圣节结构微带MIMO散热器

2023 2nd International Conference on Paradigm Shifts in Communications Embedded Systems, Machine Learning and Signal Processing (PCEMS) Pub Date : 2023-04-05 DOI:10.1109/PCEMS58491.2023.10136106

K. Raju, A. Kavitha, C. Kaitepalli

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引用次数: 0

摘要

第五代移动技术标准能够提供高数据速率、低延迟通信和大规模设备连接。5G面临的挑战之一是频谱使用，本文介绍了各国在sub-6GHz和毫米波频率范围内分配给5G的不同频段，为了5G系统的有效分布和应对频谱使用的挑战，开发了一种能够在sub-6GHz和mm波段工作的双宽带三元MIMO辐射结构。单元件散热器主要设计在尺寸为6.4 X 6.4 X 0.25 mm3的Rogers/RT duroid基片上，采用万圣节结构，并采用宽矩形槽接地。采用万圣节结构增强增益，地面宽矩形槽增强带宽。单单元辐射器谐振在25.18 ~ 29.39 ghz频段，增益为4。69 dbi。MIMO天线结构是通过将尺寸扩展到S.4 X . 23而开发的。SX0.25mm3，它能够在5.12-5.97GHz和12.83-40.4GHz双频段工作，相对于-10dB的回波损耗，并且相对于相邻的散热器观察到小于-10dB的隔离。下波段获得的最大增益为6。7dBi及以上波段为17。36 dbi。结果表明，该天线结构非常适合5G应用。

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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Halloween Structured Microstrip MIMO Radiator at 5G sub-6GHz and mm-wave Frequencies

The 5th generation mobile technology standards have the guts to deliver high data rates, low latency communications, and massive device connectivity. One of the challenge in front of 5G was spectrum usage, this article was presented, different frequency bands allocated to 5G in the range of sub-6GHz and millimeter wave frequencies in various countries and for the efficient distribution of the 5G systems and in order to meet the challenge of spectrum usage, developed a dual wideband three elements MIMO radiating structure capable to operate in sub-6GHz and mm-wave bands. Primarily the single element radiator was designed on 6.4 X 6.4 X 0.25 mm3 dimensioned Rogers/RT duroid substrate with Halloween structure incorporated patch and grounded with wide rectangular slot. The incorporation of Halloween structure was given gain enhancement and wide rectangular slot on ground was given bandwidth enhancement. The single element radiator was resonated in the band 25.18-29.39GHz with the gain of 4. 69dBi. The MIMO antenna structure was developed by extending the dimensions to S.4 X 23. SX0.25mm3, it was capable to operate in dual bands 5.12-5.97GHz and 12.83-40.4GHz with respect to the -10dB return losses and less than -10dB isolation was observed with respect to adjacent radiators. The Maximum gain obtained over the lower band was 6. 7dBi and higher band was 17. 36dBi. The results demonstrated that the presented antenna structure is well suitable for 5G Applications.

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来源期刊

2023 2nd International Conference on Paradigm Shifts in Communications Embedded Systems, Machine Learning and Signal Processing (PCEMS)

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