An Integrated 3D-Printed Lens with Ultra-Wideband Flower-Shaped Stub Antenna for Ethanol-Water Mixture Characterization

Chudpooti, Nonchanutt; Sangpet, Patchadaporn; Duangrit, Nattapong; Akkaraekthalin, Prayoot; Robertson, I.D.; Somjit, Nutapong

doi:10.1109/ri2c51727.2021.9559770

Cited by 3 publications

(1 citation statement)

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“…While these methods can increase the gain and improve radiation patterns, they also make the antenna larger and more complex. Using a lens integrated with the antenna is a promising approach that has been presented in numerous studies [16]- [23]. Although this is not a new technique, it has often been used to increase the gain and radiation characteristics of UWB antennas.…”

Section: Introductionmentioning

confidence: 99%

An Additive 3D-Printed Hemispherical Lens With Flower-Shaped Stub Slot Ultra-Wideband Antenna for High-Gain Radiation

Chudpooti,

Sangpet,

Pechrkool

et al. 2023

IEEE Access

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This paper presents a 3D-printed hemispherical lens integrated with a planar ultra-wideband (UWB) antenna. The flower-shaped stub slot UWB antenna is made of 0.8-mm FR-4. The operating frequency of the UWB covers 3.10 GHz -11.6 GHz with a nominal gain at zero degrees of 1.74 dBi. To enhance the UWB antenna's high-gain radiation, a 3D-printed additive hemispherical lens is designed and fabricated from acrylonitrile butadiene styrene (ABS). The electrical properties, i.e., relative permittivity and loss tangent, of ABS are 2.66, and 0.003, respectively. Four different lens radii (8 mm, 10 mm, 12 mm, and 14 mm) are chosen to investigate the gain of the antenna. In all four cases, the 3D-printed lens is fixed in place in front of the UWB antenna with an optimum gap of 3 mm chosen to reduce the wave reflection between the lens and source antenna. Based on the measurement results, the reflection coefficient, S11, of four conditions still covers the UWB frequency range. The nominal gain at zero-degree values for lens radii of 8 mm, 10 mm, 12 mm, and 14 mm are 3.43 dBi, 4.22 dBi, 4.73 dBi, and 5.18 dBi, respectively. The proposed additive 3D-printed dielectric lens antenna also offers many advantages, i.e., ease of design and assembly, low-cost fabrication, and size reduction for high-gain antennas. Furthermore, the high-gain antenna provides a narrow half power beamwidth, which can be implemented to increase the resolution of the imaging system.INDEX TERMS UWB antenna, hemispherical dielectric lens, 3D-printred lens antenna

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Section: Introductionmentioning

confidence: 99%