Design and optimization of a Quasi‐Yagi antenna for 5G communications

Ala, Avanthi; Bactavatchalame, Partibane; Karuppiah, Senthamilselvan

doi:10.1002/mop.34184

Micro & Optical Tech Letters

2024

DOI: 10.1002/mop.34184

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Design and optimization of a Quasi‐Yagi antenna for 5G communications

Avanthi Ala,

Partibane Bactavatchalame,

Senthamilselvan Karuppiah

Abstract: A novel Quasi‐Yagi‐Uda antenna on a flexible material is designed and demonstrated in this paper. The antenna is developed on an ultra‐thin polyimide substrate to support dual‐frequency bands centered at 3.8 and 5.2 GHz for 5G and WiFi‐enabled wireless communications. The proposed Quasi‐Yagi‐Uda has a twin‐F‐shaped driven element which is excited using a microstrip line feed. The arms of the driven element are suitably designed to meet the frequency specifications of the proposed antenna. The design of the ant… Show more

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References 17 publications

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Machine learning‐driven design of dual‐band antennas using PGGAN and enhanced feature mapping

Tuen,

Li,

Chi

et al. 2024

IET Microwaves Antenna & Prop

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This paper presents a systematic antenna design methodology that integrates machine learning, leveraging the progressive growth technique of Progressive Growing of GANs (PGGAN) to generate images of various dual‐band PIFA‐like antenna structures. The process involves using data augmentation methods to generate 4180 antenna samples. In the latent space, the authors employ Latin Hypercube Sampling to maintain diversity and combine it with the Hough Transform to enhance the edge features of the antennas while providing labelling functionality. This labelling method strengthens the relationship between antenna frequency and wavelength characteristics. The paper clearly outlines the design process, starting from the simulation of two types of single‐frequency PIFA‐like antennas (2.45 and 5.2 GHz, respectively) to the completion of PGGAN's generation task, resulting in a novel dual‐band Wi‐Fi PIFA‐like antenna structure. The measurement results of the dual‐band antennas exhibit excellent consistency with the simulation results.

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Machine learning‐driven design of dual‐band antennas using PGGAN and enhanced feature mapping

Tuen,

Li,

Chi

et al. 2024

IET Microwaves Antenna & Prop

View full text Add to dashboard Cite

show abstract

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Design and optimization of a Quasi‐Yagi antenna for 5G communications

Cited by 1 publication

References 17 publications

Machine learning‐driven design of dual‐band antennas using PGGAN and enhanced feature mapping

Machine learning‐driven design of dual‐band antennas using PGGAN and enhanced feature mapping

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