2018 IEEE International Conference on Environment and Electrical Engineering and 2018 IEEE Industrial and Commercial Power Syst 2018

DOI: 10.1109/eeeic.2018.8494590

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3-Axial EMC Field Probe Design Using Hexagonal Shaped Ultra Wide-Bandwidth Fractal Dipole Antenna for Frequency Range 0.5 to 12 GHz

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“…The focus is majorly on the parameters of the antenna and the behavior of the antenna at futuristic frequencies. The authors [12] proposed a Hexagonal shaped ultra-wide bandwidth Fractal dipole antenna for frequency range 0.5 to 12GHz.The simulation is carried out to focus on the gain of the antenna which was around 6.9dBi for various angles of penetration. The proposed fractal module is very tiny in its size and shape which can be used for vehicular communications.…”

Section: Related Workmentioning

confidence: 99%

Fractal Geometry Based Chakra-shaped Microstrip Patch Antenna Array for Vehicular Communications Under 5G Environments

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2022

Preprint

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In this paper, fractal geometry based two printed antenna structures are proposed for vehicular communication in 5G wireless communication networks. Initially, a 48×39 mm2 single element fractal patch antenna is designed and tested which shows dual band resonance at around 28.1 GHz and 32.5 GHz. In order to improve different antenna characteristic descriptors such as bandwidth, reflection coefficient, voltage standing wave ratio (VSWR), and gain, number of fractal radiating elements have been increased to four and constructed an array of patches such that it can be used for multiple applications in the field of vehicular communications. For better performance, the antenna is replicated in the form of a 2×2 patch array such that the performance can be increased by at least 20%. The proposed array model is fabricated on a Rogers RT duroid 5880tm material of size 115×82 mm2 and tested using Agilent Technologies N5247A VNA. The measured results confirm the validity of the designed model for intended applications. The proposed array antenna operates at distinct quintuple bands in the frequency range of 25—36 GHz for vehicular communication within the proposed lower fifth generation (5G) channel. The proposed array configuration shows a good peak gain of 6.72dB within the operating bands.

“…The focus is majorly on the parameters of the antenna and the behavior of the antenna at futuristic frequencies. The authors [12] proposed a Hexagonal shaped ultra-wide bandwidth Fractal dipole antenna for frequency range 0.5 to 12GHz.The simulation is carried out to focus on the gain of the antenna which was around 6.9dBi for various angles of penetration. The proposed fractal module is very tiny in its size and shape which can be used for vehicular communications.…”

Section: Related Workmentioning

confidence: 99%

Fractal Geometry Based Chakra-shaped Microstrip Patch Antenna Array for Vehicular Communications Under 5G Environments

¹

,

²

,

³

2022

Preprint

View full text Add to dashboard Cite

In this paper, fractal geometry based two printed antenna structures are proposed for vehicular communication in 5G wireless communication networks. Initially, a 48×39 mm2 single element fractal patch antenna is designed and tested which shows dual band resonance at around 28.1 GHz and 32.5 GHz. In order to improve different antenna characteristic descriptors such as bandwidth, reflection coefficient, voltage standing wave ratio (VSWR), and gain, number of fractal radiating elements have been increased to four and constructed an array of patches such that it can be used for multiple applications in the field of vehicular communications. For better performance, the antenna is replicated in the form of a 2×2 patch array such that the performance can be increased by at least 20%. The proposed array model is fabricated on a Rogers RT duroid 5880tm material of size 115×82 mm2 and tested using Agilent Technologies N5247A VNA. The measured results confirm the validity of the designed model for intended applications. The proposed array antenna operates at distinct quintuple bands in the frequency range of 25—36 GHz for vehicular communication within the proposed lower fifth generation (5G) channel. The proposed array configuration shows a good peak gain of 6.72dB within the operating bands.

Fractal geometry-based chakra-shaped microstrip patch antenna array for vehicular communications under 5G environments

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2022

Journal of Information and Telecommunication

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Analysis and Design of Planner Wide Band Antenna for Wireless Communication Applications

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2021

Design Methodologies and Tools for 5G Network Development and Application

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Microstrip patch antennas are widely used for enormous wireless applications as they are very compact in size and easy to fabricate and are highly recommended for multiband applications. The antenna must be designed in such a way that a single antenna can be used for multiple applications and multiple frequency ranges with smooth shifting of operating frequency. The antenna must be a wideband such that it can witness the communication between the devices in wireless environment for various applications. This chapter brings some of the important designs which are proposed by various remarkable authors whose contribution towards the wireless communication is a state of the art. The chapter gives a clear-cut idea about how the patch has changed its directions from a traditional design to an utmost complicated yet easy to fabricate fractal in nature multiband application antenna.

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