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Kumar, H. Vinod
- Inspection on Superwide Band 5G Antennas for Communication Applications
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Authors
Affiliations
1 Department of Tele Communication Engineering, Dayanand Sagar College of Engineering, IN
1 Department of Tele Communication Engineering, Dayanand Sagar College of Engineering, IN
Source
ICTACT Journal on Microelectronics, Vol 7, No 2 (2021), Pagination: 1101-1108Abstract
The 5th Generation (5G) technology requires a higher data rate, superior bandwidth, improved efficiency, and compact antennas for smartphones to facilitate with different types of super wideband antennas are inspected with design methodology, gain, bandwidth, and other performance parameters are analyzed to find applications in 5G technology. The different types of array antenna provide higher gain but fed with a single port demonstrate similar capabilities as a single antenna. The multiple-input multiple-output (MIMO) antenna having the capability of multipath propagation, higher data rate, enhanced capability, and link reliability, which provides the solution to 5G technology. The substrate integrated waveguide (SIW) antennas explore the advantage of classical metallic waveguides such as low radiation loss, high power, high gain, and high selectivity, and also planar antenna consists of low profile, low cost, lightweight, and ease of integration with microwave circuits. The combined capability of SIW with MIMO structure is the potential candidate for 5G smartphones. The simple SIW antenna simulated using high-frequency structured simulation (HFSS) software tool, which provides the multiple band's resonances from 21 GHz to 50 GHz operating band and reflection coefficient |S11| at 28.66 GHz is -58.577 dB as standard value is less than -10dB.Keywords
Approximate Computation, Wallace Multiplier, 3:2 Compressor, Low Power, PDP.References
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- Design of Dual Band Antenna and Antenna Array for 5G Communication Applications
Abstract Views :155 |
PDF Views:0
Authors
Affiliations
1 Department of Tele Communication Engineering, Dayanand Sagar College of Engineering, IN
1 Department of Tele Communication Engineering, Dayanand Sagar College of Engineering, IN
Source
ICTACT Journal on Microelectronics, Vol 7, No 2 (2021), Pagination: 1148-1158Abstract
In this work, the design of a dual-band microstrip patch antenna and antenna array for 5G (5th Generation) mobile communication applications is conferred. The prerequisite for 5G technology is higher data rate, enhanced efficiency, improved gain, wide bandwidth, and compact antennas. The Rogers RT/Duroid 5880 and FR4 substrate is used to design the proposed dual-band inset fed microstrip patch and antenna array resonates at mm-wave frequencies of 28,39.5 GHz and 29,49.8 GHz respectively. The dual-band single element antenna (Rogers) provided with 8.057, 7.337 dB, and 8 × 8 array antenna yields with 25.86, 26.28 dB superior gain and good impedance bandwidth of 1.5,4.3 GHz at 28 and 39.5 GHz resonating frequencies. Moreover, dual-band antenna and array antenna exhibits higher radiation efficiency and reflection coefficient of S11 less than -10 dB at both the frequency bands.Keywords
5G, RT/Duroid, Inset Fed, mm-wave.References
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