Library Subscription: Guest
Begell Digital Portal Begell Digital Library eBooks Journals References & Proceedings Research Collections
Telecommunications and Radio Engineering
SJR: 0.202 SNIP: 0.2 CiteScore™: 0.23

ISSN Print: 0040-2508
ISSN Online: 1943-6009

Volumes:
Volume 78, 2019 Volume 77, 2018 Volume 76, 2017 Volume 75, 2016 Volume 74, 2015 Volume 73, 2014 Volume 72, 2013 Volume 71, 2012 Volume 70, 2011 Volume 69, 2010 Volume 68, 2009 Volume 67, 2008 Volume 66, 2007 Volume 65, 2006 Volume 64, 2005 Volume 63, 2005 Volume 62, 2004 Volume 61, 2004 Volume 60, 2003 Volume 59, 2003 Volume 58, 2002 Volume 57, 2002 Volume 56, 2001 Volume 55, 2001 Volume 54, 2000 Volume 53, 1999 Volume 52, 1998 Volume 51, 1997

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

ABSTRACT

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

REFERENCES

  1. Brandt, A.A., (1963) Investigation of Dielectrics at Microwave Frequencies, Moscow, Russia: GIFML Publ., (in Russian).

  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).


Articles with similar content:

WAVE PROPAGATION IN A DOUBLE-LAYER BELOW-CUTOFF LOSSY WAVEGUIDE IN THE FREQUENCY RANGE 5...30 GHZ
Telecommunications and Radio Engineering, Vol.76, 2017, issue 1
K. S. Kuznetsova, Z. Ye. Eremenko
METHODS FOR OBTAINING MULTIFREQUENCY LASING IN RESONANT CAVITY OF THE THZ LASER
Telecommunications and Radio Engineering, Vol.75, 2016, issue 4
V. K. Kiseliov, V. P. Radionov, P. K. Nesterov
DIFFRACTION RESONANCE EMISSION OF ELECTROMAGNETIC WAVES BY ELECTRON BEAM CLOSE TO REFLECTION GRATING WITH METAMATERIAL
Telecommunications and Radio Engineering, Vol.71, 2012, issue 3
P.M. Melezchik, A.Yu. Poyedinchuk, O.P. Kusaykin
SURFACE ELECTROMAGNETIC WAVES IN THE PLASMA‐LIKE MEDIUM BORDERING A PERIODIC LAYERED STRUCTURE
Telecommunications and Radio Engineering, Vol.72, 2013, issue 14
Yu. O. Averkov, N. N. Beletskii, Vladimir M. Yakovenko
Time-Domain Methods in the Study of Composite Open Resonance Structures
Telecommunications and Radio Engineering, Vol.57, 2002, issue 8-9
L. G. Velychko, Yurii Konstantinovich Sirenko