Zhurnal Radioelektroniki - Journal of Radio Electronics. eISSN 1684-1719. 2021. №10
ContentsFull text in Russian (pdf)
DOI: https://doi.org/10.30898/1684-1719.2021.10.3
UDC: 621.396.677
MODELING OF AN ULTRA-WIDEBAND GHZ RANGE ANTENNA WITH RECURSIVE TOPOLOGY
V. E. Drach1,2, R. A. Mishenev2, А. А. Shmelkova2
1 Sochi State University, 354000, Sochi, 94 Plastunskaya St.
2 Bauman Moscow State Technical University (Kaluga Branch), 248000, Kaluga, 2 Bazhenov St.
The paper was received October 04, 2021
Abstract. For decades the development of telecommunications devices shows an inspiring progress. Nowadays, a wide range of multifunctional wireless telecommunications devices with small weight and size characteristics is being developed, since these are portable devices. One of the most important elements of such a device is the antenna. The antenna has a number of conflicting requirements: a wide frequency band, compact size, simple manufacturing technology, low price, the ability to work in several frequency bands, etc. One of the promising types of ultra-wideband antennas with a high gain is fractal antennas with a recursive topological pattern.
Key words: fractal, antenna, UWB, HFSS, modeling
1. Ilichev V.Y. Investigation of characteristics of fractal wire antennas made in the form of Koch curve. European Journal of Natural History. 2021. No.2. P.41-46.
2. Simin A., Kholodnyak D. Multilayer integrated circuits of microwave microwave frequencies based on ceramics with low temperature firing. Komponenty I tehnologii [Components and Technologies]. 2005. No.49. https://kit-e.ru/svch/integralnye-shemy-sverhvysokih-chastot-svch/(In Russian)
3. Abdrakhmanova G.I., Bagmanov V.Kh. Ultra-wideband antenna based on fractal structures. Elektrotehnicheskiei I nformacionnye kompleksy i sistemy [Electrical and information complexes and systems]. 2013. V.3. No.3. P.52-59. (In Russian)
4. Romeu J., Soler J. Generalized Sierpinski fractal multiband antenna. IEEE Transactionson Antennas and Propagation. 2001. V.49. No.8. P.1237-1239.
5. Krzysztofik W.J. Take advantage of fractal geometry in the antenna technology of Modern Communications. 11th International Conference on Telecommunications in Modern Satellite, Cable and Broadcasting Services (TELSIKS). 2013. P.419-428.
6. Potapov A.A., Matveev E.N. Fractal electrodynamics, scaling of fractal antennas based on ring structures and multiscale frequency selective 3D media or fractal "sandwiches": transition to fractal nanostructures. Radiotehnica i electronica [Radio engineering and electronics]. 2010. T.55. No.10. P.1157-1177. (In Russian)
7. Yogaprasad K., Anitha V.R. CPW Fed Hexa-to-Hexa Fractal Antenna for Multiband Applications. Microelectronics, Electromagnetics and Telecommunications. Springer Singapore: Lecture Notes in Electrical Engineering. V.655. P.277-283. https://doi.org/10.1007/978-981-15-3828-5_29
8. Mezache Z. Analysis of multiband graphene-based terahertz square-ring fractal antenna. Ukrainian Journal of Physical Optics. 2020. V.21. No.2. P.93-102.
9. Samadpour-Hendevari M., Pourziad A., Nikmehr S. Design methodology of the fractal annular ring antennas with the wideband operation. IET Microwaves Antennas & Propagation. 2019. V.13. No.14. P.2464-2469.
For citation:
Drach V.E., Mishenev R.A., Shmelkova A.A. Modeling of an ultra-wideband GHz range antenna with recursive topology. Zhurnal Radioelektroniki [Journal of Radio Electronics] [online]. 2021. №10. https://doi.org/10.30898/1684-1719.2021.10.3 (In Russian)