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

This paper proposes an all-metal Vivaldi array antenna with a wide-angle impedance matching (WAIM) layer for high-power jamming systems. To reduce fabrication complexity and time, the proposed array antenna is manufactured using a metal 3D printing method. The Vivaldi unit cell, composed of a radiat...

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Bibliographic Details
Published in:IEEE access 2023-01, Vol.11, p.1-1
Main Authors: Ohm, Sungsik, Kang, Eunjung, Lim, Tae Heung, Choo, Hosung
Format: Article
Language:English
Subjects:
3-D printers
3D printing
all-metal Vivaldi array
Anechoic chambers
Antenna arrays
Antenna radiation patterns
Antennas
Beam steering
Boresights
Broadband antennas
Dual polarization (waves)
High-power jamming systems
Impedance
Impedance matching
Jamming
Metals
Simulation
Three dimensional printing
Unit cell
unit cell array
wide angle impedance matching
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Summary:This paper proposes an all-metal Vivaldi array antenna with a wide-angle impedance matching (WAIM) layer for high-power jamming systems. To reduce fabrication complexity and time, the proposed array antenna is manufactured using a metal 3D printing method. The Vivaldi unit cell, composed of a radiating flare part and an inner cavity, is extended into an 8 × 8 array with a ±45° slant configuration. To further enhance the beam steering angle, the WAIM layer is placed on top of the proposed array antenna. The performances of the proposed array antenna, such as its active reflection coefficients (ARC), gains, and array radiation patterns, are investigated in a full anechoic chamber. At a steering angle of (θ 0 = 45°, ϕ 0 = 25°), the measured and simulated average ARCs of the center element (Port 36) with the WAIM layer are -13.2 dB and -18.5 dB, respectively. At 4 GHz, the measured and simulated bore-sight gains of the proposed array antenna are 19 dBi and 20.6 dBi, respectively. In addition, the measured and simulated bore-sight gains for the (θ 0 = 45°, ϕ 0 = 0°) steering angle in the zx -plane are 18 dBi and 21 dBi, respectively. In the zy -plane, bore-sight gains for the (θ 0 = 45°, ϕ 0 = 0°) steering angle are 19.3 dBi by measurement and 19.1 dBi by simulation. These results demonstrate that the proposed array antenna is suitable for high-power jamming systems because stable bore-sight gains are observed even at wide steering angles without unwanted grating lobes.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2023.3262463