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PIER PIER B PIER C PIER M PIER Letters
2021-07-12
Compact Four-Band Cactus-Shaped Antenna for 5G and WLAN Applications
By
Juan Zhang,

    Dr. Juan Zhang

    School of Physics and Electronic Info

    Anhui Normal University

    China

    Homepage

Xiaoming Liu,

    Prof. Xiaoming Liu

    School of Physics and Electronic Information

    Anhui Normal University

    China

    Homepage

Chen Wang,

    Dr. Chen Wang

    School of Physics and Electronic Information

    Anhui Normal University

    China

    Homepage

Lu Gan,

    Dr. Lu Gan

    Anhui Normal University

    China

    Homepage

Ye Wang,

    Dr. Ye Wang

    School of Physics and Electronic Information

    Anhui Normal University

    China

    Homepage

Lijun Sun

    Dr. Lijun Sun

    Wuhu CEPREI Information Industry Technology Research Institute

    China

    Homepage

Progress In Electromagnetics Research Letters, Vol. 98, 155-163, 2021
doi:10.2528/PIERL21052902
Abstract
A low-profile coplanar waveguide fed four-band compact antenna for 5G and WLAN applications is presented in this letter. Multiple bands are generated using a cactusshaped patch, which consists of several inverted L-shaped slots and branches. The proposed antenna provides 150 MHz (2.10 GHz-2.25 GHz), 400 MHz (3.25 GHz-3.65 GHz), 1022 MHz (4.42 GHz-5.44 GHz), 1400 MHz (5.60 GHz-7.00 GHz) bandwidths of 10 dB return loss, corresponding to the target N1/N78/N79 5G bands and 5.8 GHz WLAN band, respectively. Moreover, the proposed antenna has a low profile of 21 mm × 29 mm × 1.6 mm, while maintaining tolerable gain in these operation bands. In addition, monopole-like radiation patterns are obtained, which is suitable for wireless communication. In order to verify this design, a prototype has been fabricated and measured. The measured results show satisfactory agreement with the simulated ones.
Citation
Juan Zhang, Xiaoming Liu, Chen Wang, Lu Gan, Ye Wang, and Lijun Sun, "Compact Four-Band Cactus-Shaped Antenna for 5G and WLAN Applications," Progress In Electromagnetics Research Letters, Vol. 98, 155-163, 2021.
doi:10.2528/PIERL21052902
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