• Українська
  • English
  • Русский
ISSN 2415-3400 (Online)
ISSN 1028-821X (Print)

MEASUREMENT OF FOAM PLASTICS PERMITTIVITY WITH THE RESONANCE METHOD USING A WAVEGUIDE-DIELECTRIC RESONATOR

heading: 
APPLIED RADIOPHYSICS
Bilous, RI, Vovnyuk, MV, Skuratovskiy, IG, Khazov, OI, Shakhova, AS
Organization: 

O. Ya. Usikov Institute for Radiophysics and Electronics of the National Academy of Sciences of Ukraine
12, Proskura st., Kharkov, 61085, Ukraine
E-mail: briz@ire.kharkov.ua
https://doi.org/10.15407/rej2016.02.087
Language: Russian
Abstract: 

The rapid development of electronic technology is characterized by continuous expanding the potentials of new types of created elements, devices and systems that use porous plastics. Therefore, it is necessary to study the main electrophysical characteristics of these materials. The effective solution to this problem is impossible without the accurate determination of the dielectric constant (e ). This paper presents two methods of measuring the relative low e (1.02...1.1) of foams using a cylindrical waveguide-dielectric resonator on the evanescent waveguide. The measurements of the e  were carried out for four types of foams in the frequency range 10...12 GHz and the estimation errors are presented. In the “direct” method the test material is used as a dielectric element of the resonator. In the “indirect” method the dielectric element is made from ftoroplast, and the test material filled the evanescent sections of the waveguide. The investigations have shown that the “indirect” method gives a decrease of the measurement error in 2.5–5 times compared to the “direct” one. But the “direct” method is easier and allows to measure any permittivities.
Keywords: dielectric element, evanescent waveguide, relative dielectric constant, resonance frequency, waveguide-dielectric resonator

Manuscript submitted 07.04.2016
PACS 07.57.-c; 77.22.-d
Radiofiz. elektron. 2016, 21(2): 87-92
Full text (PDF)

References: 
  1. Rez, I. S. and Poplavko, Yu. M., 1989. Dielectrics. Basic properties and application in electronics. Moscow: Radio i svyaz’ Publ. (in Russian).
  2. Poplavko, Yu. M., Pereverzeva, L. P. and Rayevsky, I. P., 2009. Physics of active dielectrics. Rostov-na-Donu: YuFU Publ. (in Russian).
  3. Skorodumov, A. I., Troshin, G. I. and Kharlanov, Yu. Ya., 1990. Dielectric lens antenna of EHF and microwave ranges. Zarubezhnaya radioelektronika, 4, pp. 93–94 (in Russian).
  4. Ilchenko, М. Е. ed., Vzyatyshev, V. F., Gasanov, L. G., 1989. Dielectric resonators. Moscow: Radio i svyaz’ Publ. (in Russian).
  5. Kapilevich, B.Yu. and Trubekhin, E. R., 1990. Waveguide-dielectric filtering structures. Moscow: Radio i svyaz’ Publ. (in Russian).
  6. Belous, R. I., Makeev, Yu. G., Motornenko, A. P. and Motornenko, L. P., 2012. Method for measurement of dielectric parameters in the microwave range. Radiotekhnika, 168, pp. 103–107 (in Russian).
  7. Zaitsev, A. N., Ivashchenko, P. A. and Melnikov, A. V., 1989. Microwave frequency measurements. Moscow: Izdatelstvo Standartov (in Russian).
  8. Belous, R. I., Makeev, Yu. G. and Motornenko, A. P., 1997. Eigen oscillations and Q-factors of a waveguide-dielectric resonator with a short-circuiting piston. Bulletin of Sumy State University, 1(7), pp. 65–69 (in Russian).
  9. Bronshtein, I. N. and Semendyaev, K. А., 1981. Manual of Mathematics for Engineers and Students. Moscow: Nauka Publ. (in Russian).
  10. Valitov, R. A. and Sretensky, V. N., 1970. Radio technical measurements. Moscow: Sov. Radio Publ. (in Russian).