Skidanov Roman Vasil'evich

Publications in Math-Net.Ru

1. Ensembles of spectral-spatial convolutional neural network models for classifying soil types in hyperspectral images
   
   Computer Optics, 47:5 (2023),  795–805
2. Color imaging using a system based on 3 diffractive lenses
   
   Computer Optics, 47:5 (2023),  716–724
3. Agricultural plant hyperspectral imaging dataset
   
   Computer Optics, 47:3 (2023),  442–450
4. Spectral lenses to highlight blood vessels in the skin
   
   Computer Optics, 46:6 (2022),  899–904
5. Neural network-aided classification of hyperspectral vegetation images with a training sample generated using an adaptive vegetation index
   
   Computer Optics, 45:6 (2021),  887–896
6. Deep learning-based video stream reconstruction in mass-production diffractive optical systems
   
   Computer Optics, 45:1 (2021),  130–141
7. Experimental study of an image lens based on diffraction lenses for correct aberrations
   
   Optics and Spectroscopy, 129:4 (2021),  443–447
8. Experiment with a diffractive lens with a fixed focus position at several given wavelengths
   
   Computer Optics, 44:1 (2020),  22–28
9. Limiting the number of quantisation levels of a harmonic lens as a method for improving the quality of the generated image
   
   Kvantovaya Elektronika, 50:7 (2020),  675–678
10. Control of laser-beam spatial distribution for correcting the shape and refraction of eye cornea
    
    Kvantovaya Elektronika, 50:1 (2020),  87–93
11. Calculation of a diffractive lens having a fixed focal position at several prescribed wavelengths
    
    Computer Optics, 43:6 (2019),  946–955
12. Imaging systems based on generalized lenses
    
    Computer Optics, 43:5 (2019),  789–795
13. Experimental investigation of the stability of Bessel beams in the atmosphere
    
    Computer Optics, 43:3 (2019),  376–384
14. Microturbines formed with the aid of direct laser recording on photoresist
    
    Zhurnal Tekhnicheskoi Fiziki, 88:6 (2018),  888–891
15. Calibration of an imaging hyperspectrometer
    
    Computer Optics, 41:6 (2017),  869–874
16. Harmonic lens with an annular aperture
    
    Computer Optics, 41:6 (2017),  842–847
17. A dual-range spectrometer based on the Offner scheme
    
    Computer Optics, 40:6 (2016),  968–971
18. An imaging spectrometer based on a discrete interference filter
    
    Computer Optics, 39:5 (2015),  716–720
19. Diffractive vortex lenses for forming light vortex beams
    
    Computer Optics, 39:5 (2015),  674–677
20. Comparative study of the spectral characteristics of aspheric lenses
    
    Computer Optics, 39:3 (2015),  363–369
21. Study of an imaging spectrometer based on a diffraction lens
    
    Computer Optics, 39:2 (2015),  218–223
22. An algorithm for designing a DOE to form optical traps of a preset configuration
    
    Computer Optics, 39:2 (2015),  181–186
23. Manipulation of light-absorbing particles in air with optical bottle arrays
    
    Computer Optics, 38:4 (2014),  722–726
24. Manipulation of micro-objects using linear traps generated by vortex axicons
    
    Computer Optics, 38:4 (2014),  717–721
25. Diffractive optical elements for forming radially polarized light, based on the use stack of Stoletov
    
    Computer Optics, 38:4 (2014),  614–618
26. Formation of Bessel beams by vortex axicons
    
    Computer Optics, 38:3 (2014),  463–468
27. Formation of images using multilevel diffractive lens
    
    Computer Optics, 38:3 (2014),  425–434
28. A simple method of the formation nondiffracting hollow optical beams with intensity distribution in form of a regular polygon contour
    
    Computer Optics, 38:2 (2014),  243–248
29. Rotating elegant Bessel-Gaussian beams
    
    Computer Optics, 38:2 (2014),  162–170
30. Diffractive optical elements for the formation of combinations of vortex beams in the problem manipulation of microobjects
    
    Computer Optics, 38:1 (2014),  65–71
31. The modificaction of laser beam for optimization of optical trap force characteristics
    
    Computer Optics, 37:4 (2013),  431–435
32. Численное исследование дифракции света на дифракционных линзах
    
    Vestn. Samar. Gos. Tekhn. Univ., Ser. Fiz.-Mat. Nauki [J. Samara State Tech. Univ., Ser. Phys. Math. Sci.], 9 (2000),  174–179


33. In memory of professor Alexey Volkov
    
    Computer Optics, 39:1 (2015),  136–142