The simulation of the electromagnetic wave propagation plays an important role in predicting the performance of wireless transmission and communication systems. This research paper performs a numerical simulation using the finite element method (FEM) to study electromagnetic propagation through both conductive and dielectric media. The simulations are made using the COMSOL Multiphysics software which notably implements the finite element method. The microwave is produced by a Vivaldi antenna at the respective frequencies of 2.6 and 5 GHz and the propagation equation is formulated from Maxwell’s equations. The results obtained show that in the air, strong electric fields are observed in the slot and the micro-strip line for the two frequencies, they are even greater when the wave propagates in the glass and very weak for the copper. The 3D evolutions of the wave in air and glass present comparable values at equal frequencies, the curves being more regular in air (dielectric). The radiation patterns produced for air and glass are directional, with a large main lobe, which is narrower at 5 GHz. For copper, the wave propagation is quite uniform in space, and the radiation patterns show two main lobes with a much larger size at 2.6 GHz than at 5 GHz. The propagation medium would therefore influence the range of values of the gain of the antenna.
References
[1]
Šesnić, S. and Poljak, D. (2013) Antenna Model of the Horizontal Grounding Electrode for Transient Impedance Calculation: Analytical Versus Boundary Element Method. Engineering Analysis with Boundary Elements, 37, 909-913. https://doi.org/10.1016/j.enganabound.2013.03.008
[2]
Sarkar, C. (2014) Some Parametric Studies on Vivaldi Antenna. International Journal of u-and e-Service, Science and Technology, 7, 323-328. https://doi.org/10.14257/ijunesst.2014.7.4.29
[3]
Diao, Y. and Hirata, A. (2021) Assessment of mmWave Exposure from Antenna Based on Transformation of Spherical Wave Expansion to Plane Wave Expansion. IEEE Access, 9, 111608-111615. https://doi.org/10.1109/ACCESS.2021.3103813
[4]
Constantinescu, C., et al. (2020) High Frequency Analysis of the Vivaldi Antenna Parameters. 2020 International Conference and Exposition on Electrical and Power Engineering (EPE), Iasi, 22-23 October 2020, 376-381. https://doi.org/10.1109/EPE50722.2020.9305674
[5]
Zhou, L., Tang, M., Qian, J., Zhang, Y.-P., and Mao, J. (2021) Vivaldi Antenna Array with Heat Dissipation Enhancement for Millimeter-Wave Applications. IEEE Transactions on Antennas and Propagation, 70, 288-295. https://doi.org/10.1109/TAP.2021.3091625
[6]
Ostadrahimi, M., Noghanian, S., and Shafai, L. (2012) A Novel Antenna Design Technique Using Finite Element Method and Transmission Line Theory. Microwave and Optical Technology Letters, 54, 126-133. https://doi.org/10.1002/mop.26516
[7]
Xue, M.-F. and Jin, J.-M. (2015) Domain Decomposition Methods for Finite Element Analysis of Large-Scale Electromagnetic Problems. The Applied Computational Electromagnetics Society Journal, 29, 990-1002.
[8]
Calò, G., et al. (2018) Integrated Vivaldi Antennas, an Enabling Technology for Optical Wireless Networks on Chip. Proceedings of the 3rd International Workshop on Advanced Interconnect Solutions and Technologies for Emerging Computing Systems, Manchester, January 2018, 1-4. https://doi.org/10.1145/3186608.3186609
