Design Of Wide Band Compact Bend Triangular Resonator Artificial Magnetic Conductor And Its Application For Antenna Gain Enhancement

In this paper, a compact bend triangular resonator (CBTR) structure is proposed as artificial magnetic conductor (AMC) to enhance antenna gain for wide frequency bandwidth. This paper presents the metamaterial properties of the CBTR structure like absorbance and reflection phase. The CBTR unit cell gives in-phase reflection (0 degrees +/- 90 degrees) for 55.2% bandwidth. The CBTR unit-cell reflection phase analysis is presented for the different height of normal incident wave. The CBTR AMC performance is validated using a wideband dipole antenna. For -6-dB impedance bandwidth, the standalone dipole antenna covers ultrawide frequency range 3.1-12 GHz and for -10-dB impedance bandwidth, antenna has dual band frequency response 3.4-4.4 GHz and 8.3-11 GHz. The antenna shows good impedance matching and radiation characteristics for frequency range, where the unit-cell reflection phase is 135 degrees to 45 degrees for frequency range 2.5-6.5 GHz (bandwidth of 88.8%). The broadside directivity of 7 dBi is achieved for the dipole antenna with CBTR AMC in the frequency range of 2.5-6.5 GHz and broadside gain of >5 dBi in the frequency range of 3.2-6.7 GHz (bandwidth of 70.7%). The antenna efficiency of 60% (minimum) is achieved for the frequency range of 3.68.0 GHz (75.8%). The proposed CBTR design is orthogonally symmetric and is useful for dual-polarized wideband frequency applications like wireless local area network (WLAN) (2.4-2.5 and 5.15-5.85 GHz) and new radio (NR) 5G sub-6-GHz (3.3-5.0 GHz).