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Telecommunications and Radio Engineering
SJR: 0.202 SNIP: 0.2 CiteScore™: 0.23

ISSN Imprimir: 0040-2508
ISSN On-line: 1943-6009

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Telecommunications and Radio Engineering

DOI: 10.1615/TelecomRadEng.v78.i11.20
pages 939-947

SENSOR FOR MEASURING THE PERMITTIVITY OF SOLID AND GASEOUS SUBSTANCES ON THE BASIS OF A FABRY- PEROT RESONATOR WITH EVANESCENT HOLES IN THE MIRRORS

A. V. Gribovsky
Institute of Radio Astronomy, National Academy of Sciences of Ukraine, 4 Mystetstv St., Kharkiv 61002, Ukraine

RESUMO

The paper suggests a design of a sensor for measuring and monitoring the permittivity of solid and gaseous substances. The sensor is based on a Fabry-Perot resonator with evanescent rectangular holes in its mirrors. Numerical simulations of the characteristic of the sensor with a dielectric plate and that placed in a gaseous medium demonstrate a possibility of high precision measurements of the dielectric constant of solid and gaseous substances within a wide frequency range

Referências

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  2. Yegorov, V.N., (2007) Resonance method of investigating dielectrics at microwaves: A review, Pribory and Tekhnika Eksperimenta, 2, pp. 5-38, (in Russian).

  3. Chernikov, A.D. and Kundenko, N.P., (2012) An analysis of resonance systems for measuring electrophysical parameters of substances, Energosberezhenie. Energetika. Energoaudit, 3(97), pp. 56-62, (in Russian).

  4. Zwick, T., Chandrasekhar, A., Baks, C.W., Pfeiffer, U.R. et al., (2006) Determination of the Complex Permittivity of Packaging Materials at Millimeter-Wave Frequencies, IEEE Transactions on Microwave Theory and Techniques, 54(3), pp. 1001-1010.

  5. Gui, Y., Dou, W., and Yin, K., (2009) Open Resonator Technique of Non-Planar Dielectric Objects at Millimeter Wavelengths, Progress in Electromagnetics Research M, 9, pp. 185-197.

  6. Dudorov, S.N., Lioubtchenko, D.V., Mallat, J.A., and Raisanen, A.V., (2005) Millimeter-Wave Permittivity Measurement of Deposited Dielectric Films Using the Spherical Open Resonator, IEEE Microwave and Wireless Components Letters, 15(9), pp. 564-566.

  7. Tarasova, G.V. and Tyutyunnik, V.V., (2006) Molecular-optic monitoring of emergency situations associated with accidental effluence of explosive gases, Problemy Nadzvychaynykh Situatsiy, Proceedings of ACZ of Ukraine, Kharkiv, Ukraine: Folio Publ., (in Russian).

  8. Gribovsky, A.V. and Kuzmichev, I.K., (2016) A Fabry-Perot resonator formed by two screens with rectangular holes, Radiofizika and Radioastronomiya, 21(1), pp. 58-64, (in Russian).

  9. Gribovsky, A.V., (2017) A Quasi-Periodic Sequence of the Fabry-Perot Resonators on the Basis of Planar Screens of Finite Thickness with Rectangular Holes, Telecommunications and Radio Engineering, 76(16), pp. 1417-1422.

  10. Gribovsky, A.V., Prosvirnin, S.L., and Reznik, I.I., (1997) Reflected phased antenna array of rectangular waveguides of finite length, Radiofizika and Radioastronomia, 2(1), pp. 52-60, (in Russian).

  11. Lytvynenko, L.N., Prosvirnin, S.L., Pogarsky, S.A., and Kaliberda, M.E., (2017) Wave Diffraction by Periodic Multi-Layer Structures, Kharkiv, Ukraine: V.N. Karazin National University of Kharkiv Publ., (in Russian).


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