Zhurnal Radioelektroniki - Journal of Radio Electronics. eISSN 1684-1719. 2021. No. 5
Contents

Full text in Russian (pdf)

Russian page

 

DOI https://doi.org/10.30898/1684-1719.2021.5.1

UDC 621.372.512

 

Method for the synthesis of broadband devices with an optimal characteristic of the power conversion factor, matching the time-varying load impedance

 

P. V. Boykachev, I. A. Dubovik, V. O. Isaev

Military Academy of the Republic of Belarus, Minsk 220057, Belarus

 

 The paper was received on April 27, 2021 

 

Abstract. A method is proposed for the synthesis of broadband matching devices that adapt radio engineering systems to the changing load impedance in a wide range of natural conditions of their operation. The results of experimental studies of the effect of operating conditions on the impedance of VHF and UHF radio antennas with matching devices are presented. An invariant of the sensitivity of the reflection coefficient function to changes in the load impedance is obtained, on the basis of which a complex criterion for the synthesis of broadband matching devices is developed. A broadband matching circuit was synthesized for the AD-44/CW-TA-30-512 antenna device, which provides a gain in the potentially achievable radio line range of up to 5% in relation to the standard matching device. An analytical mathematical model of a broadband matching device is developed and based on it, a matching device adaptive to the changing impedance of the AD-25/CW-3512 antenna is synthesized, providing an average gain in the potentially achievable range of the radio line from 2% to 15% in the framework of the presented experimental studies.

Key words: broadband matching, invariant, sensitivity, impedance, synthesis technique.

References

1. Dik A.M., Kashkarov A.V., Makaterchik A.V. Radiostantsii maloy i sredney moshchnosti [Radio stations of small and medium power]. Minsk, BGUIR Publ. 2014.  108 p. (In Russian)

2. Boykachev P.V., Dubovik I.A., Isaev V.O. Results of the study of the influence of operating conditions on the impedance of the antenna devices radios VHF/UHF.  Vestnik  VARB [Bulletin of Belarus Military Academy]. 2019. No.2(63). P.32-40. 9In Russian)

3. Trival antene. Datasheet AD-44/CW-TA-30-512. Slovenia, 2019.

4. Trival antene. Datasheet AD-25/CW-3512. Slovenia, 2019.

5. Manual for the radio station R-180 KLSI. 46. 464429. 002 RE. (In Russian)

6. Grishin V.P., Ipatov Yu.M., Kazarinov Yu.M. Radiotekhnicheskiye sistemy  [Radio Engineering Systems]. Moscow, Vysshaya Shkola Publ., 1990. 496 p. (In Russian)

7. Geher K. Theory of network tolerances. Budapest, Akademiai Kiado. 1973.

8. Hudsman L.P., Allen P.E. Introduction to the theory and design of active filters. McGraw-Hill. 1980.

9. Filippovich G.A. Shirokopolosnoye soglasovaniye soprotivleniy [Broadband Matching of Resistances]. Minsk, Belarus Military Academy. 2004. (In Russian)

10. Dubovik I.A., Boykachev P.V., Isaev V.O., Yantsevich M.A. Adaptive coordination of broadband radio engineering devices to the changing load impedance. International Scientific Conference on Military Technology Problems, Problems of Defense and Security, theUuse of Dual-use Technologi.  Minsk, May 16-17, 2017. P.50-53. (In Russian)

11. Yarman B.S. Design of Ultra Wideband Antenna Matching Networks. Istanbul, Springler. 2008. 308 p.

12. MWO Software Guide: NI AWR Design Environment v14 Edition. El Segundo, CA.-2018.

13. Lannet A.A. Optimal'nyy sintez lineynykh elektricheskikh tsepey [Optimal synthesis of linear electrical circuits]. Moscow, Svyaz’ Publ. 1969. 294 p. (In Russian)

14. Nebylov A.V. Garantirovaniye tochnosti upravleniya [Guaranteeing the Accuracy of Control]. Moscow, Nauka Fizmatlit Publ. 1998. 293 p. (In Russian)

15. Polushin P.A., Samoilov A.G., Samoilov S.A. Adaptation of high-frequency load impedance matching circuits. Symposium with international participation Aerokosmicheskiye pribornyye tekhnologii” [Aerospace Instrument Technologies]. Moscow. 1999. P.34-35. (In Russian)

16. Konovalov G.F.  Radioavtomatika [Radio Automatics]. Moscow, Vysshaya Shkola Publ. 1990. 335 p. (In Russian)

17. Filanovsky I. M., Persianov A. Yu., Rybin V. K., Skhemy s preobrazovatelem soprotivleniya [Schemes with a Resistance Converter]. Leningrad, Energiya Publ. 1973. (In Russian)

18. Dubovik I.A., Boykachev P.V. A matching circuit for a broadband antenna device of the R-180 radio station based on the invariant of the sensitivity of the reflection coefficient function. Sbornik nauchnykh trudov NII VS [Collection of scientific papers of the Research Institute of the Armed Forces].  2020. No. 2(10).  P.111-120. (In Russian)

19. Korolyuk V.S. et al. Spravochnik po teorii veroyatnostey i matematicheskoy statistike  [Handbook of Probability Theory and Mathematical Statistics]. Moscow, Nauka Publ. 1985. 640 p. (In Russian)

20. Dubovik I.A., Boikachev P.V., Isaev V.O., Dmitrenko A.A. Synthesis methods of matching circuits for broadband wireless devices c an unstable load impedance. Doklady BGUIR [Reports of  Belarusian State University of Informatics and Radioelectronics]. 2021. No.19(1). P.61-69. (In Russian)

21. Dubovik I.A., Boltachev P.V., Isaev V.O. Complex criterion for the synthesis of broadband impedance matching devices based on invariant sensitivity. In Informatsionnyye radiosistemy i radiotekhnologii [Information Radio Systems and Radio Technologies]. Minsk, Belarusian State University of Informatics and Radioelectronics. 2020. P.41-44. (In Russian)

22. Kurushin A.A., Plastikov A.N. Proyektirovaniye SVCH ustroystv v srede CST Microwave Studio [Design of Microwave Devices in the CST Microwave Studio Environment]. Moscow, MPEI Publishing House. 2011. 155 p. (In Russian)

23. Tekhnika svyazi [Communication technology. Online resourse]. Access mode: https://t-c.by/wp-content/uploads/2019/10/Katalog-TVN.pdf.Accessed 10.04.2021. (In Russian)

 

For citation:

Dubovik I.A., Boykachev P.V., Isaev V.O. Method for the synthesis of broadband devices with an optimal characteristic of the power conversion factor, matching the time-varying load impedance. Zhurnal Radioelektroniki [Journal of Radio Electronics]. 2021. No.5. https://doi.org/10.30898/1684-1719.2021.5.1 (In Russian)