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Erschienen in: Measurement Techniques 10/2021

21.01.2021 | RADIO MEASUREMENTS

Using an Automated Complex Micron to Determine Measurement Error of Microwave Radio Interferometers

verfasst von: D. E. Bezrukov, N. S. Kornev, N. A. Makarichev, K. V. Mineev, A. V. Nazarov, D. A. Tregubenko

Erschienen in: Measurement Techniques | Ausgabe 10/2021

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Abstract

This article presents the technique of radio interferometry measurements and a theoretical estimate of the measuring error of the reflecting surface displacement. The displacements are measured using microwave radio interferometers. This article describes the automated complex Micron design as well as its operating principle. The complex is designed to experimentally determine the error in measuring the reflecting surface displacement as well as to conduct primary and periodic verification of microwave radio interferometers. The complex Micron comprises a measuring tool of the precision class 3, that is, an incremental linear displacement transducer LIR-7A, which measures the reflecting surface displacement of the test object. Verification of the longitudinal displacement measuring line is provided for the complex Micron so that the LIR-7A transducer can be verified without dismantling it. Parallel slip gauges or similar standards can be used as the initial standard for verification. The measured displacement values, determined during verification and obtained through an alternative method providing the required accuracy of radio interferometry measurements, were compared.

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Literatur
1.
Zurück zum Zitat V. A. Kanakov, S. V. Katin, N. S. Kornev, et al., “State and prospects for the development of microwave radio-interferometry for diagnostics of gas-dynamic processes,” Antenny, No. 1 (221), 49–54 (2016). V. A. Kanakov, S. V. Katin, N. S. Kornev, et al., “State and prospects for the development of microwave radio-interferometry for diagnostics of gas-dynamic processes,” Antenny, No. 1 (221), 49–54 (2016).
2.
Zurück zum Zitat V. M. Belsky, A. L. Mikhailov, A. V. Rodionov, and A. A. Sedov, “Microwave diagnostics of shock-wave and detonation processes,” Fiz. Goren. Vzryva, No. 6, 29–41 (2011). V. M. Belsky, A. L. Mikhailov, A. V. Rodionov, and A. A. Sedov, “Microwave diagnostics of shock-wave and detonation processes,” Fiz. Goren. Vzryva, No. 6, 29–41 (2011).
3.
Zurück zum Zitat V. A. Kanakov, S. Yu. Lupov, Yu. I. Orekhov, and A. V. Rodionov, “Methods for extracting information about the displacement of the section boundaries in gas-dynamic experiments using radio interferometers of the millimeter wavelength range,” Izv. Vyssh. Ucheb. Zav. Radiofi zika, No. 3, 234–246 (2008). V. A. Kanakov, S. Yu. Lupov, Yu. I. Orekhov, and A. V. Rodionov, “Methods for extracting information about the displacement of the section boundaries in gas-dynamic experiments using radio interferometers of the millimeter wavelength range,” Izv. Vyssh. Ucheb. Zav. Radiofi zika, No. 3, 234–246 (2008).
4.
Zurück zum Zitat A. L. Mikhailov, Noninvasive Methods for Diagnostics of High Rate Processes, VNIIEF, Sarov (2015). A. L. Mikhailov, Noninvasive Methods for Diagnostics of High Rate Processes, VNIIEF, Sarov (2015).
5.
Zurück zum Zitat S. S. Mokrushin, N. B. Anikin, S. N. Malyugina, et al., “Interferometer with time-frequency densification of signals for studying the properties of materials in shock-wave experiments,” Prib. Tekhn. Eksperim., No. 4, 107–110 (2014). S. S. Mokrushin, N. B. Anikin, S. N. Malyugina, et al., “Interferometer with time-frequency densification of signals for studying the properties of materials in shock-wave experiments,” Prib. Tekhn. Eksperim., No. 4, 107–110 (2014).
6.
Zurück zum Zitat A. V. Pavlenko, S. N. Malyugina, V. V. Pereshitov, and I. N. Lisitsina, “VISAR two-channel laser interferometry complex for studying the properties of materials under shock-wave loading,” Prib. Tekhn. Eksperim., No. 2, 127–129 (2013). A. V. Pavlenko, S. N. Malyugina, V. V. Pereshitov, and I. N. Lisitsina, “VISAR two-channel laser interferometry complex for studying the properties of materials under shock-wave loading,” Prib. Tekhn. Eksperim., No. 2, 127–129 (2013).
7.
Zurück zum Zitat E. A. Chudakov, A. V. Fedorov, S. A. Finyushin, et al., “Registration of the velocity and specifi c mass of the flow of particles ejected from the surface of metals during their shock-wave loading,” Fiz. Goren. Vzryva, No. 5, 90–95 (2018). E. A. Chudakov, A. V. Fedorov, S. A. Finyushin, et al., “Registration of the velocity and specifi c mass of the flow of particles ejected from the surface of metals during their shock-wave loading,” Fiz. Goren. Vzryva, No. 5, 90–95 (2018).
8.
Zurück zum Zitat K. A. Panov, V. A. Komrachkov, and I. S. Tselikov, “x-Ray studies of the process of interaction of shock and detonation waves in explosives,” Fiz. Goren. Vzryva, No. 3, 132–138 (2007). K. A. Panov, V. A. Komrachkov, and I. S. Tselikov, “x-Ray studies of the process of interaction of shock and detonation waves in explosives,” Fiz. Goren. Vzryva, No. 3, 132–138 (2007).
9.
Zurück zum Zitat A. N. Vlasov, A. V. Zhuravlev, V. A. Pashentsev, et al., “x-Ray study of the dynamics of the development of dust jets from the metal surface,” Fiz. Goren. Vzryva, No. 5, 90–95 (2018). A. N. Vlasov, A. V. Zhuravlev, V. A. Pashentsev, et al., “x-Ray study of the dynamics of the development of dust jets from the metal surface,” Fiz. Goren. Vzryva, No. 5, 90–95 (2018).
10.
Zurück zum Zitat V. A. Arinin, S. A. Kartanov, Yu. P. Kuropatkin, et al., “New possibilities of proton radiography for registration of high rate gas-dynamic processes,” Fiz. Goren. Vzryva, No. 5, 3–12 (2018). V. A. Arinin, S. A. Kartanov, Yu. P. Kuropatkin, et al., “New possibilities of proton radiography for registration of high rate gas-dynamic processes,” Fiz. Goren. Vzryva, No. 5, 3–12 (2018).
11.
Zurück zum Zitat B. C. Koch, C. R. Acad. Sci. Paris, 236, 661–663 (1953). B. C. Koch, C. R. Acad. Sci. Paris, 236, 661–663 (1953).
12.
Zurück zum Zitat G. F. Cawsey, G. F. Farrands, and S. Thomas, Proc. Roy. Soc. London. Ser. A: Math. Phys. Sci., 248, 499–521 (1958).ADS G. F. Cawsey, G. F. Farrands, and S. Thomas, Proc. Roy. Soc. London. Ser. A: Math. Phys. Sci., 248, 499–521 (1958).ADS
13.
Zurück zum Zitat G. H. McCall, W. L. Bongianni, and G. A. Miranda, Rev. Sci. Instrum., No. 8, 1612–1618 (1985).CrossRefADS G. H. McCall, W. L. Bongianni, and G. A. Miranda, Rev. Sci. Instrum., No. 8, 1612–1618 (1985).CrossRefADS
14.
Zurück zum Zitat B. R. Levin, Theoretical Foundations of Statistical Radio Engineering, Radio i Svyaz, Moscow (1989).MATH B. R. Levin, Theoretical Foundations of Statistical Radio Engineering, Radio i Svyaz, Moscow (1989).MATH
Metadaten
Titel
Using an Automated Complex Micron to Determine Measurement Error of Microwave Radio Interferometers
verfasst von
D. E. Bezrukov
N. S. Kornev
N. A. Makarichev
K. V. Mineev
A. V. Nazarov
D. A. Tregubenko
Publikationsdatum
21.01.2021
Verlag
Springer US
Erschienen in
Measurement Techniques / Ausgabe 10/2021
Print ISSN: 0543-1972
Elektronische ISSN: 1573-8906
DOI
https://doi.org/10.1007/s11018-021-01861-0

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