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Skripal, Anatolii Vladimirovich
Statistics
Total publications: 42
Scientific articles: 42

Number of views:
This page:705
Abstract pages:9670
Full texts:2606
References:1500
Professor
Doctor of physico-mathematical sciences
E-mail:

https://www.mathnet.ru/eng/person83920
List of publications on Google Scholar
https://elibrary.ru/author_items.asp?authorid=33340
https://orcid.org/0000-0002-9080-0057
https://www.webofscience.com/wos/author/record/E-1327-2013
https://www.scopus.com/authid/detail.url?authorId=57255442300

Publications in Math-Net.Ru Citations
2025
1. A. A. Isaeva, E. A. Isaeva, An. V. Skripal, D. A. Zimnyakov, “Statistical modeling of the depolarizing properties of optically dense dispersive systems in the small-angle scattering mode of probe light propagation”, Izv. Saratov Univ. Math. Mech. Inform., 25:2 (2025),  281–294  mathnet
2. V. D. Prokhorova, O. Yu. Kutikova, A. M. Palaguta, An. V. Skripal, D. V. Ermishin, A. P. Rytik, “Study of the influence of electrical impulses on arterial blood microcirculation using laser Doppler flowmetry”, Izv. Sarat. Univ. Physics, 25:3 (2025),  333–342  mathnet
3. A. A. Sagaidachnyi, I. Yu. Volkov, I. S. Zaletov, D. I. Mayskov, A. V. Fomin, A. Antonov, M. O. Tsoy, An. V. Skripal, “Restoration of microhemodynamics on the human body surface using the fractional derivative of temperature oscillations”, Izv. Sarat. Univ. Physics, 25:3 (2025),  316–332  mathnet
4. An. V. Skripal, D. G. Verkhov, F. Al-Badri, K. V. Mashkov, A. D. Usanov, A. A. Sagaidachnyi, V. A. Klochkov, “The appearance of the venuloarteriolar reflex during measurements microcirculation of blood by laser Doppler flowmetry caused by a change in the position of the hand”, Izv. Sarat. Univ. Physics, 25:1 (2025),  53–66  mathnet
2024
5. D. A. Zimnyakov, M. V. Alonova, An. V. Skripal, M. G. Inkin, S. S. Zaitsev, V. A. Fedorova, “Polarization- and CGR-based binary representations as identifiers of the nucleotide sequences in bioinformatics”, Izvestiya VUZ. Applied Nonlinear Dynamics, 32:4 (2024),  439–459  mathnet
6. M. G. Inkin, D. A. Yakovlev, S. Yu. Dobdin, A. V. Skripal, “Techniques and accuracy of determining the target acceleration from the spectrum of a laser autodyne signal in the presence of nonlinear effects caused by external optical feedback”, Zhurnal Tekhnicheskoi Fiziki, 94:3 (2024),  457–465  mathnet  elib
2023
7. A. A. Sagaidachnyi, I. Yu. Volkov, M. O. Tsoy, A. V. Fomin, D. I. Mayskov, A. Antonov, I. S. Zaletov, An. V. Skripal, “Assessment of spatiotemporal heterogeneity of two-dimensional images on the example of photoplethysmograpic imaging of hemodynamics”, Izv. Sarat. Univ. Physics, 23:2 (2023),  128–140  mathnet 2
8. D. A. Zimnyakov, M. V. Alonova, An. V. Skripal, S. Yu. Dobdin, V. A. Fedorova, “Small-angle polarimetry as a technique for identification of nucleotide sequences in bioinformatics”, Izv. Sarat. Univ. Physics, 23:1 (2023),  46–55  mathnet
9. I. S. Zaletov, A. A. Sagaidachnyi, An. V. Skripal, V. P. Klochkov, D. I. Mayskov, A. V. Fomin, “Interrelation between pulse wave forms in the peripheral arteries registered by methods of impedance rheography and ultrasonic dopplerography”, Izv. Sarat. Univ. Physics, 23:1 (2023),  24–36  mathnet 1
10. A. V. Skripal, S. Yu. Dobdin, M. G. Inkin, A. Dzhafarov, “Measurement of distance by the maximum frequency of the interference signal with harmonic deviation of the wavelength of the self-mixing laser”, Zhurnal Tekhnicheskoi Fiziki, 93:4 (2023),  519–524  mathnet  elib
11. S. Yu. Dobdin, M. G. Inkin, A. Dzhafarov, An. V. Skripal, “Interferometry of absolute distances of laser probe relief meters with harmonic wavelength deviation”, Optics and Spectroscopy, 131:6 (2023),  749–753  mathnet  elib
2022
12. D. I. Mayskov, A. A. Sagaidachnyi, M. D. Matasov, A. V. Fomin, A. V. Skripal, “Influence of the modulation of the blood flow velocity in peripheral vessels on the temperature of the outer wall of the vessel: Finite element modeling of the adjoint problem”, Izv. Saratov Univ. Math. Mech. Inform., 22:3 (2022),  332–344  mathnet
13. D. A. Zimnyakov, M. V. Alonova, V. A. Fedorova, A. V. Skripal, “Statistical properties of GB speckle patterns: Influence of the phase modulation depth of the synthesized GB apertures”, Izv. Sarat. Univ. Physics, 22:3 (2022),  194–206  mathnet
14. An. V. Skripal, A. V. Fomin, A. S. Bakhmetyev, N. B. Brilenok, A. A. Sagaidachnyi, S. Yu. Dobdin, A. S. Tikhonova, “Diagnostics of arterial vessels of athletes using doppler ultrasound measurement”, Izv. Sarat. Univ. Physics, 22:2 (2022),  141–148  mathnet
2021
15. D. I. Mayskov, A. A. Sagaidachnyi, I. S. Zaletov, A. V. Fomin, An. V. Skripal, “Integral mapping of the sweat-gland activity using differential thermography technique”, Izv. Sarat. Univ. Physics, 21:3 (2021),  222–232  mathnet 2
16. S. Yu. Dobdin, A. Dzhafarov, M. P. Shchedrinov, M. G. Inkin, An. V. Skripal, “Nanodisplacement measurements by frequency-modulated laser autodyne”, Izv. Sarat. Univ. Physics, 21:2 (2021),  157–164  mathnet
17. A. V. Skripal, S. Yu. Dobdin, A. Dzhafarov, I. A. Chernetsova, “Analysis of the pulse waveform in arterial vessels using the spectrum of the autodyne signal of a laser interferometer”, Kvantovaya Elektronika, 51:1 (2021),  33–37  mathnet  elib [Quantum Electron., 51:1 (2021), 33–37  isi  scopus] 1
2020
18. R. T. Baatyrov, M. Yu. Kalinkin, A. D. Usanov, S. Yu. Dobdin, A. V. Skripal, “Estimation of the value of reverse blood flow in the artery by the second derivative of the pulse pressure wave”, Izv. Sarat. Univ. Physics, 20:3 (2020),  178–182  mathnet 1
19. A. V. Skripal, A. S. Bakhmetyev, N. B. Brilenok, S. Yu. Dobdin, A. A. Sagaidachnyi, R. T. Baatyrov, A. D. Usanov, A. S. Tikhonova, “Reflection index of the pulse wave for young athletes”, Izv. Sarat. Univ. Physics, 20:2 (2020),  125–133  mathnet 3
20. A. A. Sagaidachnyi, D. I. Mayskov, I. S. Zaletov, A. V. Fomin, A. V. Skripal, “Detection of the single sweat glands activity via the macro thermography techniques and its relation with skin temperature and peripheral hemodynamics”, Izv. Sarat. Univ. Physics, 20:2 (2020),  103–115  mathnet 3
21. A. V. Skripal, S. Yu. Dobdin, A. Dzhafarov, K. A. Sadchikova, V. B. Feklistov, “Distance measurement with harmonic modulation of self-mixing laser wavelength at external optical feedback”, Izv. Sarat. Univ. Physics, 20:2 (2020),  84–91  mathnet 2
2019
22. D. A. Usanov, A. V. Skripal, S. Yu. Dobdin, A. Dzhafarov, I. Sokolenko, “Limiting capabilities of self-mixing interferometry upon sawtooth modulation of a semiconductor laser wavelength”, Computer Optics, 43:5 (2019),  796–802  mathnet 5
23. R. G. Chabbarov, N. V. Ostrovsky, A. V. Skripal, A. K. Sanbaev, A. D. Usanov, D. I. Mayskov, “Application of thermal imaging diagnostics in assessment of inflammatory response after sclerotherapy in patients with lower limb daricose disease”, Izv. Sarat. Univ. Physics, 19:4 (2019),  304–311  mathnet 2
24. A. V. Skripal, S. Yu. Dobdin, A. Dzhafarov, K. A. Sadchikova, I. A. Dubrovskaia, “Method for measuring acceleration by the spectrum of self-mixing signal of semiconductor laser”, Izv. Sarat. Univ. Physics, 19:4 (2019),  279–287  mathnet 1
2018
25. D. A. Usanov, A. V. Skripal, E. I. Astakhov, I. Kostuchenko, S. Yu. Dobdin, “Self-mixing interferometry for distance measurement using a semiconductor laser with current-modulated wavelength”, Computer Optics, 42:1 (2018),  54–59  mathnet 3
26. D. A. Usanov, A. V. Skripal, S. Yu. Dobdin, E. I. Astakhov, I. Kostuchenko, A. Dzhafarov, “Methods of autodyne interferometry of the distance by injected current modulation of a semiconductor laser”, Izv. Sarat. Univ. Physics, 18:3 (2018),  189–201  mathnet 2
27. D. A. Usanov, A. V. Skripal, E. I. Astakhov, S. Yu. Dobdin, “Laser autodyne registration of nanodisplacements under laser wavelength modulation”, Kvantovaya Elektronika, 48:6 (2018),  577–581  mathnet  elib [Quantum Electron., 48:6 (2018), 577–581  isi  scopus] 3
2017
28. D. A. Usanov, A. V. Skripal, A. P. Averyanov, S. Yu. Dobdin, E. O. Kashchavtsev, “Method of estimation of heart failure during a physical exercise”, Computer Research and Modeling, 9:2 (2017),  311–321  mathnet 2
2016
29. D. A. Usanov, An. V. Skripal, E. I. Astakhov, S. Yu. Dobdin, “Autodyne interferometry for range-finding under laser radiation wavelength modulation”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 42:17 (2016),  78–86  mathnet  elib; Tech. Phys. Lett., 42:9 (2016), 919–922 5
2015
30. E. I. Astakhov, D. A. Usanov, A. V. Skripal, S. Yu. Dobdin, “Self-mixing interferometry of distance at wavelength modulation of semiconductor laser”, Izv. Sarat. Univ. Physics, 15:3 (2015),  12–18  mathnet 5
2014
31. A. A. Sagaidachnyi, D. A. Usanov, A. V. Skripal, A. V. Fomin, “Thermo-Electrical Analogy of Skin Properties and Low-Pass Filter, Correlation between Skin Temperature and Blood Flow Oscillations in Extremities”, Mat. Biolog. Bioinform., 9:2 (2014),  309–318  mathnet 3
32. D. A. Usanov, An. V. Skripal, E. I. Astakhov, “Determination of nanovibration amplitudes using frequency-modulated semiconductor laser autodyne”, Kvantovaya Elektronika, 44:2 (2014),  184–188  mathnet  elib [Quantum Electron., 44:2 (2014), 184–188  isi  scopus] 12
2013
33. D. A. Usanov, A. V. Skripal, E. I. Astakhov, “Measurements of the nanovibration amplitude by a frequency-modulated laser autodyne”, Zhurnal Tekhnicheskoi Fiziki, 83:12 (2013),  152–154  mathnet  elib; Tech. Phys., 58:12 (2013), 1856–1858 3
34. D. A. Usanov, A. V. Skripal, E. O. Kashchavtsev, S. Yu. Dobdin, “Acceleration measurements upon micro- and nanodisplacements of an object using the autodyne signal of a semiconductor laser with allowance for the external optical feedback”, Zhurnal Tekhnicheskoi Fiziki, 83:7 (2013),  156–158  mathnet  elib; Tech. Phys., 58:7 (2013), 1083–1085 2
35. D. A. Usanov, A. V. Skripal, E. O. Kashchavtsev, “Determining the cardiovascular pulse waveform using a semiconductor laser autodyne signal”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 39:5 (2013),  82–87  mathnet  elib; Tech. Phys. Lett., 39:3 (2013), 268–270 4
2012
36. D. A. Usanov, A. V. Skripal, T. B. Usanova, S. Yu. Dobdin, “Analysis of elastic properties of a spherical shell using a semiconductor laser autodyne”, Zhurnal Tekhnicheskoi Fiziki, 82:6 (2012),  156–159  mathnet  elib; Tech. Phys., 57:6 (2012), 888–891
37. D. A. Usanov, A. V. Skripal, E. O. Kashchavtsev, M. Yu. Kalinkin, “Measuring the amplitude of nanovibrations using a semiconductor laser autodyne with allowance for the feedback effect”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 38:12 (2012),  81–86  mathnet  elib; Tech. Phys. Lett., 38:6 (2012), 590–592 3
38. D. A. Usanov, A. V. Skripal, T. B. Usanova, S. Yu. Dobdin, “Measuring intraocular pressure using semiconductor laser autodyne”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 38:3 (2012),  69–74  mathnet; Tech. Phys. Lett., 38:2 (2012), 135–137 1
39. D. A. Usanov, An. V. Skripal, S. Yu. Dobdin, “Measurement of the mechanical deformations of an elastic spherical shell, filled with an incompressible fluid, with the help of a semiconductor laser autodyne”, Kvantovaya Elektronika, 42:4 (2012),  372–374  mathnet  elib [Quantum Electron., 42:4 (2012), 372–374  isi  scopus] 2
2011
40. D. A. Usanov, An. V. Skripal, S. Yu. Dobdin, “Determining characteristics of oscillations of elastic spherical shell filled with incompressible fluid measured using semiconductor laser autodyne”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 37:18 (2011),  65–72  mathnet  elib; Tech. Phys. Lett., 37:9 (2011), 873–876 1
41. D. A. Usanov, An. V. Skripal, “Measurement of micro- and nanovibrations and displacements using semiconductor laser autodynes”, Kvantovaya Elektronika, 41:1 (2011),  86–94  mathnet  elib [Quantum Electron., 41:1 (2011), 86–94  isi  scopus] 19
2010
42. D. A. Usanov, An. V. Skripal, S. Yu. Dobdin, “Determining acceleration from micro- and nanodisplacements measured using autodyne signal of semiconductor laser on quantum-confined structures”, Pisma v Zhurnal Tekhnicheskoi Fiziki, 36:21 (2010),  78–84  mathnet  elib; Tech. Phys. Lett., 36:11 (2010), 1009–1011 4

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