V. P. SHESTOPALOV AND HIS SCIENTIFIC SCHOOL: FROM QUASISTATICS TO QUASIOPTICS (to mark V.P.'s birth centenary)

DOI: https://doi.org/10.15407/rpra28.01.080

P. M. Melezhik, A. A. Kirilenko, O. O. Kostenko, S. O. Masalov

Abstract


The paper is dedicated to the memory of V.P. Shestopalov, an outstanding scientist known for his great contributions to radio physics, electronics, theoretical and mathematical physics. While being a holder of many formal academic degrees and titles, like PhD, DSc (Phys.-Math.), Professor, and Fellow Member of the Academy of Sciences, he was particularly honored as the founder of a scientific school vigorously developing diff raction theory and diffractional electronics. Th at school has been associated with the O.Ya. Usikov Institute for Radio Physics and Electronics where Dr. Shestopalov was Director till 1993. Today, we are marking the 100-th anniversary of Victor P. Shestopalov.

Keywords: Victor P. Shestopalov; diffraction; Riemann–Hilbert problem; spectral theory; diffraction-radiation generator

REFERENCES

  1. Melezhik, P.N., Masalov, S.A., Sirenko, Yu.K. eds., 2012. Academician Viktor Petrovich Shestopalov. Service to Science. Kharkiv, Ukraine: IPP Kontrast Publ. (in Russian).

  2. Yakovenko, V.M. ed., 2005. A.Ya. Usikov Institute for Radio Physics and Electronics of the National Academy of Sciences of Ukraine. The 50-th anniversary. Kharkiv, Ukraine: A.Ya. Usikov IRE NAS of Ukraine Publ. (in Russian).

  3. Agranovich, Z.S., Marchenko, V.A., Shestopalov, V.P., 1962. Diffraction of a plane electromagnetic wave from plane metallic gratings. Zhurnal Tekhnicheskoi Fiziki, 32(4), pp 381–394 (in Russian).

  4. Shestopalov, V.P., 1971. The RiemannHilbert Problem Method in Diffraction Theory and Electromagnetic Wave Propagation. Kharkiv, Ukraine: Kharkiv University Publ. (in Russian).

  5. Shestopalov, V.P., Litvinenko, L.N., Masalov, S.A., Sologub, V.G., 1973. Diffraction of Waves by Gratings. Kharkiv, Ukraine: Kharkiv University Publ. (in Russian).

  6. Shestopalov, V.P., 1983. Summator Equations in Contemporary Diffraction Theory. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  7. Shestopalov, V.P., Kirilenko, A.A., Masalov, S.A., 1984. Matrix Convolution-Type Equations in the Diffraction Theory. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  8. Litvinenko, L.N., Prosvirnin, S.L., 1984. Spectral Scattering Operators in the Problems of Wave Diffraction by Plane Screens. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  9. Masalov, S.A., Shcherbak, V.V., 2000. Methods of V.P. Shestopalov’s School in the Th eory of Wave Diffraction. In: V.M. Yakovenko ed., 2000. Radiofizika i elektronika. Kharkov: IRE NAS of Ukraine Publ. 5(2), pp. 13–34 (in Russian).

  10. Shestopalov, V.P., 1997. Physical Foundations of Millimeter and Submillimeter Wave Technologies. Vol. 1. Open Structures. Utrecht, the Netherlands and Tokyo, Japan: CRC Press.

  11. Shestopalov, V.P., 1997. Physical Foundations of Millimeter and Submillimeter Wave Technique. Vol. 2. Sources. Element Base. Radio Systems: Novel Scientifi c Trends. Utrecht, the Netherlands and Tokyo, Japan: CRC Press.

  12. Shestopalov, V.P., Kirilenko, A.A., Masalov, S.A., Sirenko, Yu.K., 1986. Resonant Scattering of Waves. Vol. 1. Diffraction Gratings. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  13. Shestopalov, V.P., Kirilenko, A.A., Rud’, L.A., 1986. Resonant Scattering of Waves. Vol. 2. Waveguide Inhomogeneities. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  14. Vertiy, A.A., Karnaukhov, I.M., Shestopalov, V.P., 1990. Polarization of atomic nuclei using millimeter waves. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  15. Kostenko, A.A., Kuznetsov, O.A., Tolomasov, V.A., Filatov, O.N., Khlopov, G.I., Shestopalov, V.P., 1983. Nonlinear effects in the millimeter wavelength range in bulk semiconductors with a superlattice. Doklady AN USSR, 271(6), pp. 1360–1362 (in Russian).

  16. Shestopalov, V.P., 1987. Spectral Theory and Excitation of Open Structures. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  17. Shestopalov, V.P., 1992. Morse’s Critical Points of Secular Equations. Kyiv, Ukraine: Naukova Dumka Publ. (in Russian).

  18. Shestopalov, V.P., 1998. Diffraction theory and problems of nonlinear physics. Ukr. J. Phys., 43(11), pp. 1381–1392 (in Ukrainian).

  19. Shestopalov, V.P., Yatsik, V.V., 2000. Equations of dispersion and spatial-temporal field evolution in a quasi-homogeneous electrodynamic structure, close to Morse’s critical point. J. Commun. Technol., 45(2), pp. 157–164 (in Russian).

  20. Shestopalov, V.P., 2000. Nonlinear evolutional fi eld equations for bounded media. Reports of the NAS of Ukraine,3, pp. 89–93 (in Russian).

  21. Kirilenko, A.A., Rud’, L.A., Tkachenko, V.I., 1996. Semi-inversion method for an accurate analysis of rectangular waveguide H-plane angular discontinuities. Radio Sci., 31(5), pp. 1271–1280.

  22. Kirilenko, A., Rud’, L., Tkachenko, V., 2001. CAD of evanescent-mode bandpass filters based on the short ridged waveguide sections. Int. J. RF Microw. Comput.-Aided Eng. 11(6). P. 354–365.

  23. Sirenko, Yu., Yashina, N., and Strom, S., 2006. Transient electromagnetic processes in periodic and waveguide resonators: mathematical models, algorithms and treatment of numerical results. Springer-Verlag, Ser. Springer Series in Optical Sciences. Vol. 122. 362 p.

  24. Tuchkin, Yu.A., 2020. On the analytical regularization method in scattering and diff raction. In: Kobayashi, K., Smith, P.D. eds., 2020. Advances in Mathematical Methods for Electromagnetics. London, UK: Institution of Engineering and Technology Publ. Chap. 13. P. 303–328.

  25. Sirenko, Yu.K., Strom, S. eds., 2010. Modern Theory of Gratings. Resonant Scattering: Analysis Techniques and Phenomena. Springer-Verlag, Ser. Springer Series in Optical Sciences. Vol. 153. 386 p.

  26. Vinogradov, S.S., Smith, P.D., Vinogradova, E.D., 2001–2002. Canonical problems in scattering and potential theory. Pt. 1. Canonical structures in potential theory. 2001. 392 p. Pt. 2. Acoustic and electromagnetic diff raction by canonical structures. 2002. 520 p. (Chapman & Hall/CRC monographs and surveys in pure and applied mathematics; Vol. 127). Chapman and Hall/CRC.

  27. Sirenko, Yu., Melezhik, P., Poyedinchuk, A., Sautbekov, S., Shmat’ko, A., Sirenko, K., Vertiy, A., Yashina, N., 2019. Radiation of electromagnetic waves induced by electron beam passage over artificial material periodic interfaces. In: Brewer N. ed., 2019. An Essential Guide to Electrodynamics. New York, USA: Nova Science Publ. Chap. 5. P. 169–206.

  28. Melezhik, P., Poyedinchuk, A., Sirenko, Yu., Yashina, N., 2020. Diffraction boundary value problems for electromagnetic theory of inhomogeneous multilayered media. Riccati equation method. In: Avci M. ed., 2020. A Closer Look at Boundary Value Problems. New York, USA: Nova Science Publ., Chap. 4. P. 125–182.

  29. Melezhik, P., Razskazovskiy, V., Reznichenko, N., Zuykov, V., Varavin, A., Sidorenko, Y., Provalov, S., Yanovsky, F, 2011. High-efficiency millimeter-wave coherent radar for airport surface movement monitoring and control. Aviation, 15(2), pp. 38–43.

  30. Tret’yakov, O.A., Tret’yakova, S.S., Shestopalov, V.P., 1965. Emission of electromagnetic waves by an electron beam moving above a diffraction grating. J. Commun. Technol. Electron., 10(7), pp. 1233–1243 (in Russian).

  31. Tret’yakov, O.A., Chernyakov, E.I., Shestopalov, V.P., 1966. Th eory of the Smith–Purcell effect. Radiophys. Quantum Electron., 9(2), pp. 341–351.

  32. Balaklitskiy, I.M, Skrynnik, B.K., Tret’yakov, O.A., Shestopalov, V.P., 1969. Millimeter and submillimeter wave diffraction-radiation generator. Ukr. J. Phys., 14(4), pp. 539–552 (in Russian).

  33. Balaklitskii, I.M., Skrynnik, B.K., Tsvyk, A.I., and Shestopalov, V.P., 1975. Possibility of developing diffraction-radiation pulsed generators. Radiophys. Quantum Electron., 18(10), pp. 1129–1136.

  34. Shestopalov, V.P. ed., Vertiy, A.A., Ermak, G.P., Skrynnik, B.K., Khlopov, G.I., Tsvyk, A.I., 1991. Diffraction-radiation generators. Kyiv, Ukraine: Naukova Dumka Publ., 320 с.

  35. Korneenkov, V.K., Miroshnichenko, V.S., and Shestopalov, V.P., 1985. Field Distributions in the Open Cavity of a diffraction-radiation generator. Radiophys. Quantum Electron., 28(12), pp. 1096–1100.

  36. Korneenkov, V.K., Miroshnichenko, V.S., Tsvyk, A.I., Shestopalov, V.P., 1982. On the stochastic oscillations excited in the diffraction-radiation generator (free electrons laser). Doklady AN USSR, 5, pp. 59–61 (in Russian).

  37. Kovalyov, I.O., Miroshnichenko, V.S., Senkevich, Y.B., 2018. Diff raction Radiation Oscillator with Frequency Tuning on Mutual Coupled Modes in an Open Resonant System. Prog. Electromagn. Res. C (PIER C), 87,pp. 1—11.

  38. Miroshnichenko, V.S., Senkevich, E.B., Pivovarova, A.G., Yudintsev, D.V., 2010. Mode excitation in a generator of diffraction-radiation with a multistage interaction space. Radiophys. Quantum Electron., 53(3), pp. 182—190.

  39. Konyukhov, S.N., Dranovsky, V.I., and Tsymbal, V.N. eds., 2007. Radar technologies and means for real-time remote sensing of the Earth from aerial and space carriers. Kyiv, Ukraine: Julia Print Publ. (in Russian).

  40. Shestopalov, V.P., 2000. On one probable pattern of the structure and evolution of our Universe. Reports of the NAS of Ukraine, 1, pp. 65–69 (in Russian).

  41. Shestopalov, V.P., 1999. Fractals and diffraction theory. Reports of the NAS of Ukraine, 3, pp. 96–100 (in Russian).

  42. Shestopalov, V.P., 2001. On a possible scenario of space and time evolution of self-organizing biophysical structures. Biophysics, 46(2), pp. 359–368 (in Russian).


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