Bi-periodic linear antenna array

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription or Fee Access

Abstract

А series-fed antenna containing two parallel linear arrays in a common aperture is proposed in this letter. Elements of the arrays are elementary resonant radiators. Proposed antenna can operate both in a dual-frequency mode and in a mode with one extended frequency range. Such an antenna in the dual-band mode provides a maximum gain in a given direction in two separate frequency ranges. The convergence of the frequency ranges forms one common extended frequency range. An approximate approach for synthesizing the antenna is proposed. Using the HFSS system, several variants of a bi-periodic slotted waveguide antenna array are investigated. Numerical modeling confirms the results of the approximate theory. It is shown that the proposed array can operate in both specified modes, which significantly expands the functionality of antennas of this type.

Full Text

Restricted Access

About the authors

S. E. Bankov

Kotelnikov Institut of Radioengineering and Electronics RAS

Author for correspondence.
Email: sbankov@yandex.ru
Russian Federation, Mokhovaya Str. 11, build.7, Moscow, 125009

M. D. Duplenkova

Kotelnikov Institut of Radioengineering and Electronics RAS

Email: sbankov@yandex.ru
Russian Federation, Mokhovaya Str. 11, build.7, Moscow, 125009

References

  1. Уолтер К.Х. Антенны бегущей волны. М: Энергия, 1970.
  2. Casula G. A., Mazzarella G., Montisci G., Muntoni G. // Electronics. 2021. V. 10. № 11. С. 1311.
  3. Hirokawa J., Miyagawa T., Ando M., Goto N. // Dig. IEEE Antennas and Propagation Society Intern. Symp. Chicago. 18-25Jun. 1992. N.Y.: IEEE. 1992. V.3. P. 1471.
  4. Casula G. A., Montisci G., Mazzarell, G. et al. // J. Electromagnetic Waves and Appl. 2013. V. 27. № 17. P. 2155.
  5. Kang Y., Noh E., Kim K. // IEEE Antennas and Wireless Propag. Lett. 2020. V. 19. № 8. P. 1395.
  6. Mishra G., Sharma S. K., Chieh J. C. S. // IEEE Trans. 2020. V. АР-68. № 12. P. 7947.
  7. Yi H., Li L., Han J., Shi Y. // IEEE Access. 2019. V. 7. P. 111466.
  8. Chaudhuri S., Kshetrimayum R.S., Sonkar R.K., Mishra M. // Electron. Lett. 2019. V. 55. № 20. P. 1071.
  9. Hirokawa J., Ando M., Goto N. et al. // IEEE Trans. 1995. V. VT-44. № 4. P. 749.
  10. Банков С.Е. // РЭ. 2004. Т. 49. № 6. С. 701.
  11. Goto N. Single-Layered Radial Line Slot Antenna. US Patent № 5175561. Publ. December 29,1992.
  12. Cheng Y.J., Hong W., Fan K., Wu Y. // IEEE Trans. 2011.V. AP-59. № 1. P. 40.
  13. Qiu L., Xiao K., Chai S. L. et al. // IEEE Trans. 2016. V. AP-64. № 11. P. 4639.
  14. Zhang L., Li L., Yi H. // 2018 Cross Strait Quad-Regional Radio Science and Wireless Technology Conf. (CSQRWC). Xuzhou. 21-24 Jul. N.Y.: IEEE, 2018. Paper No. 8455559.
  15. Ishimaru A., Bernard G. // IRE Trans. 1962. V. AP-10. № 2. P. 151.
  16. Банков С.Е., Ан Дж. // РЭ. 2007. Т. 52. № 8. С. 932.
  17. Банков С.Е. Антенные решетки с последовательным питанием. М.: Физматлит, 2013.
  18. Баскаков С.И. Радиотехнические цепи с распределенными параметрами. М.: Радио и связь, 1980.
  19. Сазонов Д.М. Антенны и устройства СВЧ. М: Мир, 1989.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download
2. Fig. 1. Equivalent circuit of the ARPP: 1, 2,…N are the numbers of elementary emitters.

Download (29KB)
Indexing metadata
3. Fig. 2. Frequency dependence of the radiation angle of the ARPP: non-resonant (1) and resonant (2) emitters.

Download (63KB)
Indexing metadata
4. Fig. 3. Frequency dependence of wave attenuation in ARPP.

Download (57KB)
Indexing metadata
5. Fig. 4. Frequency dependence of the control and measurement equipment of the ARPP with resonant emitters.

Download (50KB)
Indexing metadata
6. Fig. 5. Schematic representation of a biperiodic ARPP.

Download (31KB)
Indexing metadata
7. Fig. 6. Frequency dependence of the ARPP instrumentation in dual-frequency mode.

Download (69KB)
Indexing metadata
8. Fig. 7. Normalized radiation patterns of a biperiodic array at frequencies of 10.8 (1) and 12.2 GHz (2).

Download (81KB)
Indexing metadata
9. Fig. 8. Frequency dependence of the instrumentation in single-range mode.

Download (58KB)
Indexing metadata
10. Fig. 9. Normalized radiation patterns of a biperiodic array at frequencies of 11.18 (1) and 11.78 GHz (2).

Download (75KB)
Indexing metadata
11. Fig. 10. Models of a biperiodic array for electrodynamic modeling: with a flat screen (a) and a flat horn (b).

Download (88KB)
Indexing metadata
12. Fig. 11. Fragment of the lattice.

Download (42KB)
Indexing metadata
13. Fig. 12. Frequency dependence of the scattering parameters of a grating with a screen in dual-range mode: reflection (1) and transmission (2) coefficients.

Download (76KB)
Indexing metadata
14. Fig. 13. Frequency response of the amplifier array with a screen in dual-band mode.

Download (66KB)
Indexing metadata
15. Fig. 14. Directional patterns of the array with a screen in the XOZ plane (a) and in the azimuthal plane (b) in dual-band mode at frequencies of 9.9 (1) and 11.3 GHz (2).

Download (109KB)
Indexing metadata
16. Fig. 15. Frequency response of the amplifier array with a horn in dual-band mode.

Download (65KB)
Indexing metadata
17. Fig. 16. Directional patterns of an array with a horn in the XOZ plane (a) and in the azimuthal plane (b) in dual-band mode at frequencies of 9.8 (1) and 10.6 GHz (2).

Download (112KB)
Indexing metadata
18. Fig. 17. Frequency response of the amplifier array with a horn in single-range mode.

Download (53KB)
Indexing metadata
19. Fig. 18. Directional patterns of an array with a horn in the XOZ plane (a) and in the azimuthal plane (b) in single-band mode at frequencies of 9.4 (1) and 10.1 GHz (2).

Download (117KB)
Indexing metadata

Copyright (c) 2024 Russian Academy of Sciences