Millimeter-Wave 3-D-Printed Antenna Array Based on Gap-Waveguide Technology and Split E-Plane Waveguide

Palomares‐Caballero, Ángel; Alex‐Amor, Antonio; Valenzuela-Valdés, Juan F.; Padilla, Pablo

doi:10.1109/tap.2020.3008620

Cited by 38 publications

(14 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In recent years, a number of prototypes of gap waveguide components implemented with glide-symmetric holes have been published in the literature, including phase shifters [76], [77], filters [78] and antenna arrays [79]. This concept has rapidly evolved, and some authors have proposed alternative implementations based on glide symmetries.…”

Section: A Gap Waveguide Componentsmentioning

confidence: 99%

On the Benefits of Glide Symmetries for Microwave Devices

et al. 2021

View full text Add to dashboard Cite

Section: A Gap Waveguide Componentsmentioning

confidence: 99%

On the Benefits of Glide Symmetries for Microwave Devices

et al. 2021

View full text Add to dashboard Cite

“…Before the radiation performance measurement of each array configuration, the dielectric losses are estimated, caused by the dielectric substrate employed in the SIW layers. To calculate the estimated value for the tanδ value of the dielectric substrate, a measurement set-up similar to the one presented in [31] to estimate the insertion losses has been adopted. For our case, since we are dealing with SIW technology, the measurement set-up to calculate the insertion losses uses only the longest SIW line of the distribution type-II layer.…”

Section: Measurements and Discussionmentioning

confidence: 99%

A 1-to-8 Fully Modular Stacked SIW Antenna Array for Millimeter-Wave Applications

Segura-Gómez¹,

Palomares‐Caballero²,

Padilla³

2022

Preprint

Self Cite

View full text Add to dashboard Cite

This paper presents a vertically stacked SIW antenna array that enables different array configurations with the minimum number of SIW layers. This achievement lies in the modular feature offered by the proposed design. Specifically, 4 distinct array configurations can be produced with only 3 different design of SIW layers. Depending on the number of SIW layers employed in the stacked antenna, the directivity in the E-plane of radiation is modified. To obtain an equal and in-phase power distribution among the array elements, H- and E-plane corporate feeding networks are efficiently implemented in each array configuration. Array configurations of 1, 2, 4 and 8 radiating layers are offered by the proposed modular array, where each radiating layer is formed by 8 H-plane SIW horn antennas. The simulated directivity for the array configurations ranges from 15.8 dBi to 23.8 dBi and the main beam direction remains fixed along the operating frequency band. The array design has been manufactured and proper agreement between simulated and measured results are observed. The measured impedance bandwidth in all the array configurations is from 35 GHz to 41 GHz (15.79% bandwidth) with a reduction in the E-plane beamwidth as the number of radiating layers increases.

show abstract

“…The technology is widely proven in Ku, K, and Ka bands. However, satisfactory work can also be found in higher bands, as shown in [60]. Some Finally, the realized gain and the total radiation efficiency were evaluated experimentally.…”

Section: Stereolithography (Sla) and Post-metallization Processmentioning

confidence: 99%

“…The technology is widely proven in Ku, K, and Ka bands. However, satisfactory work can also be found in higher bands, as shown in [60]. Some designs with polarization versatility, such as those shown in [53] or [58], can also be implemented with SLA technology obtaining high quality and good performance.…”

Section: Stereolithography (Sla) and Post-metallization Processmentioning

confidence: 99%

Waveguide Manufacturing Technologies for Next-Generation Millimeter-Wave Antennas

et al. 2021

View full text Add to dashboard Cite

Some recent waveguide-based antennas are presented in this paper, designed for the next generation of communication systems operating at the millimeter-wave band. The presented prototypes have been conceived to be manufactured using different state-of-the-art techniques, involving subtractive and additive approaches. All the designs have used the latest developments in the field of manufacturing to guarantee the required accuracy for operation at millimeter-wave frequencies, where tolerances are extremely tight. Different designs will be presented, including a monopulse antenna combining a comparator network, a mode converter, and a spline profile horn; a tunable phase shifter that is integrated into an array to implement reconfigurability of the main lobe direction; and a conformal array antenna. These prototypes were manufactured by diverse approaches taking into account the waveguide configuration, combining parts with high-precision milling, electrical discharge machining, direct metal laser sintering, or stereolithography with spray metallization, showing very competitive performances at the millimeter-wave band till 40 GHz.

show abstract

Millimeter-Wave 3-D-Printed Antenna Array Based on Gap-Waveguide Technology and Split E-Plane Waveguide

Cited by 38 publications

References 27 publications

On the Benefits of Glide Symmetries for Microwave Devices

On the Benefits of Glide Symmetries for Microwave Devices

A 1-to-8 Fully Modular Stacked SIW Antenna Array for Millimeter-Wave Applications

Waveguide Manufacturing Technologies for Next-Generation Millimeter-Wave Antennas

Contact Info

Product

Resources

About