Experimental realization of 140-GHz metallic lens antenna with designable multiple beams

Haolin Li; Mingze Li; Hongda Lu; Weihua Yu

doi:10.1109/LAWP.2025.3567631

Experimental realization of 140-GHz metallic lens antenna with designable multiple beams

Haolin Li, Mingze Li, Hongda Lu, Weihua Yu^*

^*Corresponding author for this work

School of Integrated Circuits and Electronics, Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

This letter proposes a new approach to realize a metallic Luneburg lens multibeam antenna with designable beams at 140 GHz, which is fed by multiple rectangular waveguides. The beam shape can be controlled by shifting the feeding position, which is based on the transformation between focusing and defocusing state. According to the above method, the whole coverage range and the overlapping level of the adjacent beams are both flexibly designable. The theoretical analysis and experimental realization of this antenna are conducted at the 140 GHz band. The prototypes are fabricated with high-precision 3-D printing and gold-sputtering techniques. The measured results verify the beam's designability and feasibility in terahertz band. Under this theoretical framework, the beam coverage strategy can be flexibly adjusted to meet different requirements of terahertz communication.

Original language	English
Journal	IEEE Antennas and Wireless Propagation Letters
DOIs	https://doi.org/10.1109/LAWP.2025.3567631
Publication status	Accepted/In press - 2025
Externally published	Yes

Keywords

Luneburg lens antenna
designable
multiple beams antenna

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10.1109/LAWP.2025.3567631

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title = "Experimental realization of 140-GHz metallic lens antenna with designable multiple beams",

abstract = "This letter proposes a new approach to realize a metallic Luneburg lens multibeam antenna with designable beams at 140 GHz, which is fed by multiple rectangular waveguides. The beam shape can be controlled by shifting the feeding position, which is based on the transformation between focusing and defocusing state. According to the above method, the whole coverage range and the overlapping level of the adjacent beams are both flexibly designable. The theoretical analysis and experimental realization of this antenna are conducted at the 140 GHz band. The prototypes are fabricated with high-precision 3-D printing and gold-sputtering techniques. The measured results verify the beam's designability and feasibility in terahertz band. Under this theoretical framework, the beam coverage strategy can be flexibly adjusted to meet different requirements of terahertz communication.",

keywords = "Luneburg lens antenna, designable, multiple beams antenna",

author = "Haolin Li and Mingze Li and Hongda Lu and Weihua Yu",

note = "Publisher Copyright: {\textcopyright} 2002-2011 IEEE.",

year = "2025",

doi = "10.1109/LAWP.2025.3567631",

language = "English",

journal = "IEEE Antennas and Wireless Propagation Letters",

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T1 - Experimental realization of 140-GHz metallic lens antenna with designable multiple beams

AU - Li, Haolin

AU - Li, Mingze

AU - Lu, Hongda

AU - Yu, Weihua

PY - 2025

Y1 - 2025

N2 - This letter proposes a new approach to realize a metallic Luneburg lens multibeam antenna with designable beams at 140 GHz, which is fed by multiple rectangular waveguides. The beam shape can be controlled by shifting the feeding position, which is based on the transformation between focusing and defocusing state. According to the above method, the whole coverage range and the overlapping level of the adjacent beams are both flexibly designable. The theoretical analysis and experimental realization of this antenna are conducted at the 140 GHz band. The prototypes are fabricated with high-precision 3-D printing and gold-sputtering techniques. The measured results verify the beam's designability and feasibility in terahertz band. Under this theoretical framework, the beam coverage strategy can be flexibly adjusted to meet different requirements of terahertz communication.

AB - This letter proposes a new approach to realize a metallic Luneburg lens multibeam antenna with designable beams at 140 GHz, which is fed by multiple rectangular waveguides. The beam shape can be controlled by shifting the feeding position, which is based on the transformation between focusing and defocusing state. According to the above method, the whole coverage range and the overlapping level of the adjacent beams are both flexibly designable. The theoretical analysis and experimental realization of this antenna are conducted at the 140 GHz band. The prototypes are fabricated with high-precision 3-D printing and gold-sputtering techniques. The measured results verify the beam's designability and feasibility in terahertz band. Under this theoretical framework, the beam coverage strategy can be flexibly adjusted to meet different requirements of terahertz communication.

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JO - IEEE Antennas and Wireless Propagation Letters

JF - IEEE Antennas and Wireless Propagation Letters

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Experimental realization of 140-GHz metallic lens antenna with designable multiple beams

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Keywords

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