Publication de 12 numéros par an
ISSN Imprimer: 0040-2508
ISSN En ligne: 1943-6009
Indexed in
HYBRID SIGNALS IN THE LOCAL MICROWAVE DIAGNOSTICS OF SMALL OBJECTS
RÉSUMÉ
The paper substantiates the concept of the formation of hybrid signals in local microwave diagnostics based on resonant measuring transducers with a coaxial microprobe aperture. The concept of hybrid signals in this topic was introduced for the first time and implies in the process of diagnostics the complexing of several different measurements, aimed at eliminating the influence of interfering factors.
Details are considered, for example, the influence of the distance between the tip and the sample, and the geometry of the tip. Some analysis of the emerging interfering factors is present and methods for suppressing them are discussed. The possibility of measuring the properties of an object determined by the value of its complex dielectric constant is considered, and methods of suppressing interfering factors of electronic origin are shown. In particular, hybrid signals are proposed that are invariant to the parameters of the microwave oscillator, microwave detector, and modulation amplitude in the AFC system.
-
Wallis, T.M. and Kabos, P., (2017) Measurement Techniques for Radio Frequency Nanoelectronics, Cambridge University Press, London, 314 p.
-
Anlage, S.M., Talanov, V.V., and Schwartz, A.R., (2007) Principles of near-field microwave microscopy, in: Scanning Probe Microscopy: electrical and electromechanical phenomena at nanoscale, New York: Springer-Verlag, 1, pp, 215-253.
-
Akhmanaev, V.B., Detinko, M.V., Medvedev, Yu.V., and Petrov, A.S., (1986) Non-destructive non-contact microwave resonator methods for local monitoring of the electrophysical parameters of semiconductor materials, Defectoscopy, 1, pp. 23-35, (in Russian).
-
Gordienko, Yu.Ye., (1996) Resonator measuring transducers in the diagnosis of micro-layered structures, Radio Engineering, 100, 253-260, (in Russian).
-
Voropaev, P.V., Mitrofanov, A.B., Bidenko, V.A., and Zorenko, A.V., (2010, Methods of microwave plasma diagnostics, News of the National Technical University of Ukraine "KPI", Seriya: Radotehnika. Radioaparatobuduvannya, 42, pp. 170-177, (in Russian).
-
Tselev, A., Velmurugan, J., Ievlev, A.V., Kalinin, S.V., and Kolmakov, A., (2016) Seeing through Walls at the Nanoscale: Microwave Microscopy of Enclosed Objects and Processes in Liquids, ACS Nano, 10(3), pp. 3562-3570.
-
Boyko, V.V., Ivanov, V.K., Silin, A.O., Stadnik, A.M. et al., (2009) Radiophysical fundamentals and experience in the application of microwave electromagnetic fields in surgery, New Word, 1, pp. 166, (in Russian).
-
Rakhmankulov, D.L., Shavshukova, S.Yu., Vikhareva, I.N., and Chanyshev, R.R., (2008) The use of microwave radiation to extract metals from industrial waste, Bashkir Chemical Journal, 15(2), pp. 53-56, (in Russian).
-
Kasatkin, V.V., Kudryashova, A.G., Kopysova, T.S., and Ushakova, N.F., (2013) Experience in the application of microwave energy in food production, Food Industry, 10, pp. 30-32.
-
Inoue, R., Odate, Y., Tanabe, E., Kitano, H., and Maeda, A., (2004) Data Analysis of the Extraction of Dielectric Properties From Insulating Substrates Utilizing the Evanescent Perturbation Method, IEEE Transactions on Microwave Theory and Technique, 4(2), pp. 522-533.
-
Gordienko, Yu.Ye., Levchenko, A.V., Polishchuk, A.V., Prokaza, A.M., and Shcherban, I.M., (2017) Resonator aperture microwave sensors for small objects properties testing, Telecommunications and Radio Engineering, 76(18), pp. 1649-1659.
-
Gordienko, Yu.Ye., Lepikh, Ya.I, Dzyadevich, S.V. et al., (2011) Smart Measuring Systems on the Base of New-Deneration Microelectronic Sensors, Odessa, Ukraine: Astroprint, 352 p., (in Russian).
-
Bondarenko, I.M., Gordienko, Yu.O., and Panchenko, O.Yu., (2019) Directly that Problem Mikrokhvilovih Dosledzhen Volovmisnih Materials and Structures, Kharkiv, Ukraine: FOP Panov A.M., 320 p., (in Ukrainian).
-
Han, W., (2009) Introduction to Scanning Microwave Microscopy Mode, Agilent Technologies, Application Note 5989-8881EN.
-
Tselev, A., Anlage, S.M., Ma, Z., and Melngailis, J., (2007) Broadband dielectric microwave microscopy on micron length scales, Review of Scientific Instruments, 78.
-
Imtiaz, A. and Anlage, S.M., (2006) Effect of tip geometry on contrast and spatial resolution of near-field microwave microscope, Jorn. of Appl. Phys, 100.
-
Gordienko, Yu.Ye., Shiyan, O.P., and Shcherban, I.M., (2016) Suppressing the effects of interfering factors in local microwave diagnostics, Telecommunications and Radio Engineering, 75(14), pp. 1221-1229.
-
Gao, C. and Xiang, X.-D, (2002) Quantitative complex electrical impedance microscopy by scanning evanescent microwave microscope, Materials Characterization, 48, pp. 117-125.
-
Gao, C., Xiang, X.-D, Hu, B., Takeuchi, I., Chang, K.-S., and Wang, G., (2005) Quantitative scanning evanescent microwave microscopy and its applications in characterization of functional materials libraries, Meas. Sci. Technol., 16(1), pp. 248-260.
-
Gordienko, Yu.Ye., Levchenko, A.V., and Shcherban, I.M., (2018) The principles of physical decoding of images in the SMM, Journal of Physics and Engineering Surfaces, 3(1), pp. 17-23.