Skripal Anatolii Vladimirovich

Publications in Math-Net.Ru

1. Polarization- and CGR-based binary representations as identifiers of the nucleotide sequences in bioinformatics
   
   Izvestiya VUZ. Applied Nonlinear Dynamics, 32:4 (2024),  439–459
2. 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
3. Small-angle polarimetry as a technique for identification of nucleotide sequences in bioinformatics
   
   Izv. Sarat. Univ. Physics, 23:1 (2023),  46–55
4. 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
5. 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
6. 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
7. Diagnostics of arterial vessels of athletes using doppler ultrasound measurement
   
   Izv. Sarat. Univ. Physics, 22:2 (2022),  141–148
8. Integral mapping of the sweat-gland activity using differential thermography technique
   
   Izv. Sarat. Univ. Physics, 21:3 (2021),  222–232
9. Nanodisplacement measurements by frequency-modulated laser autodyne
   
   Izv. Sarat. Univ. Physics, 21:2 (2021),  157–164
10. 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
11. 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
12. Reflection index of the pulse wave for young athletes
    
    Izv. Sarat. Univ. Physics, 20:2 (2020),  125–133
13. 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
14. Distance measurement with harmonic modulation of self-mixing laser wavelength at external optical feedback
    
    Izv. Sarat. Univ. Physics, 20:2 (2020),  84–91
15. Limiting capabilities of self-mixing interferometry upon sawtooth modulation of a semiconductor laser wavelength
    
    Computer Optics, 43:5 (2019),  796–802
16. 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
17. Method for measuring acceleration by the spectrum of self-mixing signal of semiconductor laser
    
    Izv. Sarat. Univ. Physics, 19:4 (2019),  279–287
18. Self-mixing interferometry for distance measurement using a semiconductor laser with current-modulated wavelength
    
    Computer Optics, 42:1 (2018),  54–59
19. Methods of autodyne interferometry of the distance by injected current modulation of a semiconductor laser
    
    Izv. Sarat. Univ. Physics, 18:3 (2018),  189–201
20. Laser autodyne registration of nanodisplacements under laser wavelength modulation
    
    Kvantovaya Elektronika, 48:6 (2018),  577–581
21. Method of estimation of heart failure during a physical exercise
    
    Computer Research and Modeling, 9:2 (2017),  311–321
22. Autodyne interferometry for range-finding under laser radiation wavelength modulation
    
    Pisma v Zhurnal Tekhnicheskoi Fiziki, 42:17 (2016),  78–86
23. Self-mixing interferometry of distance at wavelength modulation of semiconductor laser
    
    Izv. Sarat. Univ. Physics, 15:3 (2015),  12–18
24. 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
25. Determination of nanovibration amplitudes using frequency-modulated semiconductor laser autodyne
    
    Kvantovaya Elektronika, 44:2 (2014),  184–188
26. 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
27. Measurement of micro- and nanovibrations and displacements using semiconductor laser autodynes
    
    Kvantovaya Elektronika, 41:1 (2011),  86–94