Design of microstrip patch antenna with multiple slots for satellite communication

Reddy, Mekala Harinath; Joany, R.M.; Manikandan, G.; Nisha, A. Sahaya Anselin

doi:10.1109/iccsp.2017.8286482

Cited by 5 publications

(3 citation statements)

References 6 publications

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“…From Table VII, it can be observed analysis comparison between the proposed multiband rectangular microstrip patch and other rectangular antenna structures over previous multiband patch antenna design, such as [4], [5], [6], [7], [8], [9], [10], [15], [19] and [21]. The design recorded in [4-5-6-7-9-10] the patch antenna work in multi-band frequency, but band-width and gain less than compared with the proposed design.…”

Section: E Comparison With Other Studiesmentioning

confidence: 96%

“…The design recorded in [4-5-6-7-9-10] the patch antenna work in multi-band frequency, but band-width and gain less than compared with the proposed design. Reference [8][9][10][11][12][13][14][15][16][17][18][19][20][21] in this works antenna operates in single-band therefore, bandwidth, gain and reflection coefficient (S 11 ) less than comparing with multiband frequency proposed antenna. The design recorded in [19] the patch operates in dual-band compared with proposed multiband antenna.…”

Section: E Comparison With Other Studiesmentioning

confidence: 99%

“…The gain and directivity are 3.488, and 3.544 dB respectively. The RT duroid material size 9.5 x 8 x 1.6 mm3 to design microstrip antenna with Ɛr =2.2 have loss tangent 0.0009 [8]. The microstrip patch is fabricated and tested on substrate FR-4 with size 70×70×1.6mm3, Ɛr= 4.4.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Design of Multi-band Microstrip Patch Antennas for Mid-band 5G Wireless Communication

Mazen¹,

Emran²,

Shalaby³

et al. 2021

IJACSA

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Recently, the best antenna structures have considered microstrip patch antenna due to their simple construction, low cost, minimum weight, and the fact that they can be effortlessly integrated with circuits. To achieve multiband operation an antenna is designed with an etching rectangle and circle slot on the surface of the patch to achieve multi-band frequency capabilities in mid-band 5G applications. Inset-fed structure type of fed of all antenna printed and fabricated on the brow of the Rogers RT5880 substrate. Then, prototype structures of the microstrip patch antenna were acquired during the design process until achieving the desired antennas. The antenna_1 achieved tri-band characteristics covering the WiMAX band including 2.51 -2.55 GHz, WLAN, and S-band including 3.80 -3.87 GHz and C-and X-band including 6.19 -6.60 GHz. The antenna_2 gives dual-band characteristics covering C-band and X-band including (6.72 -7.92 GHz) with a peak under -45 dB suitable for mid-band 5G applications. High impedance bandwidth increases between (70 MHz-1.25 GHz) for wireless applications. The proposed microstrip patch antennas were simulated using CST MWS-2015 and were experimentally tested to verify the fundamental characteristics of the proposed design, it offers multiple-band operation with high stable gain and good directional radiation characteristics results.

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