Design of a Dual-Polarization All-Metal Vivaldi Array Antenna Using a Metal 3D Printing Method for High-Power Jamming Systems

Ohm, Sungsik; Kang, Eun Kyeong; Lim, Tae Heung; Choo, Hosung

doi:10.1109/access.2023.3262463

Cited by 3 publications

(4 citation statements)

References 29 publications

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“…Next, two square-pipe resin frames are built to realize the thick quasiair substrates using the SLA 3D printing method [17] that can provide high-durability structures with low manufacturing tolerances. The metal cavity wall with the ground plate is then manufactured using the SLM 3D printing method [18] that can provide full-metal body structures with low manufacturing tolerances at a low cost. Finally, the stacked dual-patch antenna, the square-pipe resin frames, and the ground plate are assembled with a metal cavity wall to form a complete antenna structure.…”

Section: Design and Measurement Of A Stacked Dual-patch Antenna With ...mentioning

confidence: 99%

“…Square-pipe resin frames are built for the quasi-air substrate using the stereolithography apparatus (SLA) method [17] that can provide high-durability structures with low manufacturing tolerances. In addition, to increase the front-to-back ratio and suppress the leakage electric fields of the patch antenna, a metal cavity wall is placed around the square-pipe resin frames which is manufactured using the selective laser melting (SLM) method [18]. The stacked dual-patch antenna, the square-pipe resin frames, and the ground plate are then assembled with a metal cavity wall to form a complete antenna structure.…”

Section: Introductionmentioning

confidence: 99%

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Design of a Stacked Dual-Patch Antenna with 3D Printed Thick Quasi-Air Substrates and a Cavity Wall for Wideband Applications

Jang,

Lee,

Choo

2024

Applied Sciences

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In this paper, we propose a stacked dual-patch antenna with 3D printed thick quasi-air substrates and a cavity wall for wideband applications. To achieve the theoretical maximum bandwidth of the patch antenna, the quality factor of the system needs to be minimized. To achieve this, the area of the conductive radiator should be enlarged, while the permittivity of the substrate within the patch must be reduced close to 1. To realize a patch antenna with this maximum bandwidth, the stacked dual-patch configuration is employed to obtain an extended conductive radiator area. In addition, square-pipe resin frames manufactured using a 3D printing method are applied to the proposed antenna to implement a quasi-air substrate structure that has a low permittivity value close to 1. The proposed stacked dual-patch antenna with a quasi-air substrate has a broad bandwidth of 20.7%. The results demonstrate that by using the proposed antenna structure, broadband characteristics close to the fundamental bandwidth limit of the patch antenna can be achieved.

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Section: Design and Measurement Of A Stacked Dual-patch Antenna With ...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design of a Stacked Dual-Patch Antenna with 3D Printed Thick Quasi-Air Substrates and a Cavity Wall for Wideband Applications

Jang,

Lee,

Choo

2024

Applied Sciences

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“…Furthermore, especially at high frequencies, such enclosures are modified to create an environment suitable for the desired test. On the one hand, lining the room with absorbers makes an anechoic chamber that emulates a free-space environment necessary, e.g., for the measurement setups of antenna characterization [1] and wireless coexistence [2]. On the other hand, a resonating and electrically large room creates a reverberation chamber (RC) that emulates a rich multipath environment.…”

Section: Introductionmentioning

confidence: 99%

Empirical Characterization and Modeling of the Propagation Channel Inside the VIRC

Mahfouz,

Vogt-Ardatjew,

Kokkeler

et al. 2024

IEEE Access

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Over-the-air (OTA) testing and electromagnetic compatibility (EMC) measurements are widely performed in classical reverberation chambers. A less-known reverberation chamber, yet a considerably efficient environment for generating multipath conditions, is the vibrating intrinsic reverberation chamber (VIRC). This article thoroughly investigates the radio propagation channel inside the VIRC. The specific channels studied are narrowband single-input single-output (SISO) systems operating in the frequency range from 670-2740 MHz. A relevant application is OTA testing wireless baseband algorithms or modems for wireless sensor networks, specifically low-power wide-area networks such as Narrowband-IoT (NB-IoT), Long Range (LoRa) and Ultra-Narrowband (UNB). The focus is on the first-and second-order temporal and spectral channel characteristics: coherence time, Doppler spectrum, Doppler spread, frequency autocovariance function, coherence bandwidth, rejection rate of chi-squared goodness-of-fit test for Rician distribution, Rician K -factor, and channel gain. Besides the impact of the frequency of operation, the investigation considers the effect of the rotational speed of the VIRC motors, two loading conditions, on the channel characteristics. An analysis of the measurement results shows that the stirring efficiency degrades while the coherence time increases at slow rotational speeds, with loading, and/or at low frequencies. Moreover, empirical models closely fitting the behavior of various investigated characteristics are proposed, for which we provide foundational physical interpretations. A further investigation is carried out to demonstrate the generality and briefly illustrate the potential usability of these models for both EMC and OTA testing.INDEX TERMS Coherence bandwidth, coherence time, Doppler, electromagnetic compatibility (EMC), Kfactor, over-the-air (OTA), Rayleigh, rejection rate, Rician, vibrating intrinsic reverberation chamber (VIRC).

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“…Furthermore, especially at high frequencies, such rooms are modified to create an environment suitable for the desired test. On the one hand, lining the room with absorbers creates an anechoic chamber that emulates a free-space environment necessary, e.g., for the measurement setups of antenna characterization [226] and wireless coexistence [113]. On the other hand, a resonating and electrically large room creates a reverberation chamber (RC) that emulates a rich multipath environment.…”

Section: Introductionmentioning

confidence: 99%

Ultra-narrowband communications : a feasibility study for the 2.4 gHz band

Mahfouz

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Design of a Dual-Polarization All-Metal Vivaldi Array Antenna Using a Metal 3D Printing Method for High-Power Jamming Systems

Cited by 3 publications

References 29 publications

Design of a Stacked Dual-Patch Antenna with 3D Printed Thick Quasi-Air Substrates and a Cavity Wall for Wideband Applications

Design of a Stacked Dual-Patch Antenna with 3D Printed Thick Quasi-Air Substrates and a Cavity Wall for Wideband Applications

Empirical Characterization and Modeling of the Propagation Channel Inside the VIRC

Ultra-narrowband communications : a feasibility study for the 2.4 gHz band

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