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A wideband and directive metasurface FPC antenna with toroidal metal structure loading

Published online by Cambridge University Press:  06 October 2021

Parul Dawar
Affiliation:
Electronics and Communication Engineering Department, Guru Tegh Bahadur Institute of Technology, Delhi, India
Mahmoud A. Abdalla*
Affiliation:
Electromagnetic Waves Group, Department of Electronic Engineering, Military Technical College, Cairo, Egypt
*
Author for correspondence: Mahmoud A. Abdalla, E-mail: maaabdalla@ieee.org

Abstract

In this paper, a novel metasurface-based Fabry−Perot cavity antenna loaded with toroidal metal structures is presented. The antenna is compact, wideband, and has high directivity and a high front-to-back ratio. The idea of the antenna is based on loading a microstrip narrow band patch antenna resonating at 4.5 GHz by a single layer metasurface superstrate and with a toroidal metal structure. The metasurface superstrate comprises a periodic array of square patch cells. Compared to conventional microstrip antenna, the front to back lobe ratio is increased from 7 to 20 dB and the directivity is increased by 7 dB. Also, the antenna impedance bandwidth is 34% which is increased four times. This is the first-ever antenna with enhanced bandwidth and directivity using a single layer of metasurface and that too made up of periodic cell array and has application as an energy harvester.

Type
Metamaterials and Photonic Bandgap Structures
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press in association with the European Microwave Association

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References

Lajevardi, M and Kamyab, M (2017) Ultraminiaturized metamaterial-inspired SIW textile antenna for off-body applications. IEEE Antennas and Wireless Propagation Letters 16, 31553158.CrossRefGoogle Scholar
Sharma, SK, Abdalla, MA and Chaudhary, RK (2017) An electrically small SICRR metamaterial`-inspired dual-band antenna for WLAN and WiMAX applications. Microwave and Optical Technology Letters 59, 573578.CrossRefGoogle Scholar
Singh, H, Sohi, BS and Gupta, A (2021) Designing and performance evaluation of metamaterial inspired antenna for 4 G and 5 G applications. International Journal of Electronics 108, 10351057.CrossRefGoogle Scholar
Kanth, VK and Raghavan, S (2020) Ultrathin wideband slot and patch FSS elements with sharp band edge characteristics. International Journal of Electronics 107, 13651385.CrossRefGoogle Scholar
Trentini, GV (1956) Partially reflecting sheet arrays. IRE Transactions on Antennas and Propagation 4, 666671.CrossRefGoogle Scholar
Chacko, PB, Augustin, G and Denidni, TA (2016) FPC Antennas: c-band point-to-point communication systems. IEEE Antennas and Propagation Magazine 58, 5664.CrossRefGoogle Scholar
Holloway, LC, Kuester, EF, Gordon, JA, O'Hara, J, Booth, J and Smith, DR (2012) An overview of the theory and applications of metasurfaces: the two-dimensional equivalents of metamaterials. IEEE Antennas and Propagation Magazine 54, 1035.CrossRefGoogle Scholar
Wang, J, Li, Y, Jiang, ZH, Shi, T, Tang, MC, Zhi Ning Chen, ZZ and Qiu, CW (2020) Metantenna: when metasurface meets antenna again. IEEE Transactions on Antennas and Propagation 68, 13321347.CrossRefGoogle Scholar
Xiang, H, Ge, L, Liu, L, Jiang, T, Zhang, ZQ, Chan, CT and Han, D (2017) A generic minimal discrete model for toroidal moments and Iits experimental realization. Physical Review B 95, 045403.CrossRefGoogle Scholar
Fedotov, VA, Rogacheva, AV, Savinov, V, Tsai, DP and Zheludev, NI (2013) Resonant transparency and non-trivial non-radiating excitations in toroidal metamaterials. Scientific Reports 3, 2967.CrossRefGoogle ScholarPubMed
Miroshnichenko, AE (2015) Nonradiating anapole modes in dielectric nanoparticles. Nature Communications 6, 8069.CrossRefGoogle ScholarPubMed
Wu, MF, Meng, FY and Wu, Q (2005) A compact equivalent circuit model for the SRR structure in metamaterials. Asia-Pacific Microwave Conference Proceedings 1, 14.Google Scholar
Lee, YJ, Yeo, J, Mittra, R and Park, WS (2005) Thin Frequency Selective Surface (FSS) superstrate with different periodicities for dual-band directivity enhancement. Proceedings of the IEEE International Workshop on Antenna Technology: Small Antennas and Novel Metamaterials (IWAT ‘05), pp. 375378.Google Scholar
Ji, L, Fu, G and Gong, S-X (2016) Array-Fed beam-scanning partially reflective surface (PRS) antenna. Progress in Electromagnetics Research Letters 58, 7379.CrossRefGoogle Scholar
Liu, A, Lei, S, Shi, X and Li, L (2013) Study of antenna superstrates using metamaterials for directivity enhancement based on Fabry-Perot resonant cavity. International Journal of Antennas and Propagation, 2013, 110.Google Scholar
Razi, ZM, Bahadori, N and Rezaei, P (2013) A comparative study on the directivity enhancement of the Patch, SRR and Omega unit cells as Fabry−Perot superstrate. 2nd Asian symposium on electromagnetics and photonics engineering, pp. 147148.Google Scholar
Razi, ZM, Rezaei, PR and Bahadori, N (2013) Directivity improvement of microstrip antenna with S metamaterial unit cell as Fabry−Perot cavity superstrate. 2nd Asian symposium on electromagnetics and photonics engineering, pp. 127128.Google Scholar
Razi, ZM and Rezaei, P (2013) Design and simulation of directivity microstrip patch antenna by Fabry-Perot Omega unit cells. IEEE APS International Symposium on Antennas and Propagation, pp. 762763.Google Scholar
Microwave Journal e-book (2018) Selection of PCB materials for 5G. Rogers Corporation, p. 3.Google Scholar
Bilotti, F, Toscano, A, Vegni, L, Aydin, K, Alici, KB and Ozbay, E (2007) Equivalent-circuit models for the design of metamaterials based on artificial magnetic inclusions. IEEE Transactions on Microwave Theory and Techniques 55, 28652873.CrossRefGoogle Scholar
Rydström, S and Lindhe, O (2006) Efficient calculations of antenna radiation patterns using the fast Fourier transform. AIP Conference Proceedings 7, 834.CrossRefGoogle Scholar
Dubovik, VM and Cheshkov, AA (1975) Multipole expansion in classical and quantum field theory and radiation. Soviet Journal of Particles and Nuclei 5, 318.Google Scholar
Radescu, EE and Vaman, G (2002) Exact calculation of the angular momentum loss, recoil force, and radiation intensity for an arbitrary source in terms of electric, magnetic, and toroid multipoles. Physical Review E 65, 046609.CrossRefGoogle ScholarPubMed
Tatartschuk, E, Gneiding, N, Hesmer, F, Radkovskaya, A and Shamonina, E (2012) Mapping inter-element coupling in metamaterials: scaling down to infrared. Journal of Applied Physics 111, 094904.Google Scholar
Griffiths, DJ (1999) Introduction to Electrodynamics, 3rd Edn. New Jersey, NJ, USA: Prentice-Hall.Google Scholar
Altshuler, EE, O'Donnell, TH and Yaghjian, AD (2005) A monopole super directive array. IEEE Transactions on Antennas & Propagation 53, 26532661.CrossRefGoogle Scholar
Jagtap, SD, Gupta, RK, Chaskar, N, Kharche, SU and Thakare, R (2018) Gain and bandwidth enhancement of circularly polarized MSA using PRS and AMC layers. Progress In Electromagnetics Research 87, 107118.CrossRefGoogle Scholar
Feresidis, AP and Vardaxoglou, JC (2001) High gain planar antenna using optimized partially reflective surfaces. IEEE Proceedings of Microwave & Antennas Propagation, 345350.CrossRefGoogle Scholar
Vaidya, AR, Gupta, RK, Mishra, SK and Mukherjee, J (2014) Right-hand/left-hand circularly polarized high-gain antennas using partially reflective surfaces. IEEE Antennas and Wireless Propagation Letters 13, 431434.CrossRefGoogle Scholar
Singh, AK, Abegaonkar, MP and Koul, SK (2017) High-gain and high-aperture-efficiency cavity resonator antenna using metamaterial superstrate. IEEE Antennas and Wireless Propagation Letters 16, 23882391.CrossRefGoogle Scholar
Chacko, BP, Augustin, G and Denidni, TA (2014) FPC Antennas, C-band, point to point communication. IEEE Antennas and Propagation Magazine 62, 1926.Google Scholar
Vaid, S and Mittal, A (2017) Wideband orthogonally polarized resonant cavity antenna with dual layer Jerusalem cross partially reactive surface. Progress In Electromagnetics Research C 72, 105113.CrossRefGoogle Scholar
Oliner, AA (2002) A periodic-structure negative-refractive-index medium without resonant elements. IEEE-APS URSI International Symposium 41, 105113.Google Scholar
Monsoriu, JA, Depine, RA and Silvestre, E (2007) Non-Bragg band gaps in 1D metamaterial aperiodic multilayers. Journal of European Optical Society Rapid Publication 2, 191194.CrossRefGoogle Scholar