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Publications in Math-Net.Ru |
Citations |
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2023 |
1. |
A. I. Kashapov, L. L. Doskolovich, E. A. Bezus, N. V. Golovastikov, D. A. Bykov, “Second-order optical differentiation of a 3D light beam at oblique incidence using a multilayer metal-dielectric structure”, Computer Optics, 47:6 (2023), 845–855 |
2. |
D. A. Bykov, E. A. Bezus, L. L. Doskolovich, “Coupled-mode theory for resonant gratings with a varying period”, Computer Optics, 47:3 (2023), 341–349 |
2
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2022 |
3. |
V. V. Podlipnov, D. A. Bykov, D. Nesterenko, “Structural and optical properties of thin CdTe films in the visible and infrared regions”, Computer Optics, 46:3 (2022), 415–421 |
4. |
A. A. Mingazov, L. L. Doskolovich, D. A. Bykov, E. V. Byzov, “Support quadric method in non-imaging optics problems that can be reformulated as a mass transfer problem”, Computer Optics, 46:3 (2022), 353–365 |
5. |
L. L. Doskolovich, A. A. Mingazov, E. V. Byzov, D. A. Bykov, E. A. Bezus, “Method for calculating the eikonal function and its application to design of diffractive optical elements for optical beam shaping”, Computer Optics, 46:2 (2022), 173–183 |
6
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2021 |
6. |
L. L. Doskolovich, D. A. Bykov, A. A. Mingazov, E. A. Bezus, “Method for calculating a refractive optical element forming given illuminance distribution and wavefront”, Computer Optics, 45:6 (2021), 818–827 |
2
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7. |
A. I. Kashapov, L. L. Doskolovich, D. A. Bykov, E. A. Bezus, D. Nesterenko, “Optical differentiator based on a trilayer metal-dielectric structure”, Computer Optics, 45:3 (2021), 356–363 |
3
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8. |
L. L. Doskolovich, D. A. Bykov, G. I. Greisukh, Yu. S. Strelkov, “Design of a stigmatic lens with minimal Fresnel losses”, Computer Optics, 45:3 (2021), 350–355 |
2
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9. |
A. A. Mingazov, L. L. Doskolovich, D. A. Bykov, “Supporting quadric method for collimated beams”, Computer Optics, 45:1 (2021), 29–37 |
1
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2020 |
10. |
E. S. Andreev, E. V. Byzov, D. A. Bykov, M. A. Moiseev, N. L. Kazanskii, L. L. Doskolovich, “Design and fabrication of a freeform mirror generating a uniform illuminance distribution in a rectangular region”, Computer Optics, 44:4 (2020), 540–546 |
8
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2019 |
11. |
A. A. Mingazov, L. L. Doskolovich, D. A. Bykov, N. L. Kazanskiy, “The two reflector design problem for forming a flat wavefront from a point source as an optimal mass transfer problem”, Computer Optics, 43:6 (2019), 968–975 |
5
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12. |
L. L. Doskolovich, E. A. Bezus, D. A. Bykov, R. V. Skidanov, N. L. Kazanskiy, “Calculation of a diffractive lens having a fixed focal position at several prescribed wavelengths”, Computer Optics, 43:6 (2019), 946–955 |
15
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13. |
L. L. Doskolovich, A. A. Mingazov, D. A. Bykov, E. A. Bezus, “Formulation of the inverse problem of calculating the optical surface for an illuminating beam with a plane wavefront as the Monge–Kantorovich problem”, Computer Optics, 43:5 (2019), 705–713 |
7
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2018 |
14. |
L. L. Doskolovich, K. V. Andreeva, D. A. Bykov, “Design of an axisymmetric optical element generating a prescribed illuminance distribution and wavefront”, Computer Optics, 42:5 (2018), 772–778 |
1
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15. |
A. A. Mingazov, D. A. Bykov, L. L. Doskolovich, N. L. Kazanskii, “Variational interpretation of the eikonal calculation problem from the condition of generating a prescribed irradiance distribution”, Computer Optics, 42:4 (2018), 568–573 |
5
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16. |
L. L. Doskolovich, A. A. Mingazov, D. A. Bykov, E. S. Andreev, “Variational approach to eikonal function computation”, Computer Optics, 42:4 (2018), 557–567 |
1
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17. |
E. A. Bezus, D. A. Bykov, L. L. Doskolovich, “On the relation between the propagation constant of Bloch surface waves and the thickness of the upper layer of a photonic crystal”, Computer Optics, 42:1 (2018), 22–27 |
8
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2017 |
18. |
N. V. Golovastikov, D. A. Bykov, L. L. Doskolovich, “Temporal differentiation and integration of 3D optical pulses using phase-shifted Bragg gratings”, Computer Optics, 41:1 (2017), 13–21 |
25
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2015 |
19. |
D. A. Bykov, L. L. Doskolovich, “On the use of the Fourier modal method for calculation of localized eigenmodes of integrated optical resonators”, Computer Optics, 39:5 (2015), 663–673 |
8
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20. |
L. L. Doskolovich, N. V. Golovastikov, D. A. Bykov, S. I. Kharitonov, “Resonant approximation of phase-shifted Bragg grating (PSBG) spectra”, Computer Optics, 39:3 (2015), 311–318 |
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2014 |
21. |
L. L. Doskolovich, E. A. Bezus, D. A. Bykov, “On the compensation of the diffraction orders overlap effect in the Offner spectrometer”, Computer Optics, 38:4 (2014), 777–781 |
22. |
D. A. Bykov, L. L. Doskolovich, “On the diffraction of an optical beam by a phase shifted Bragg grating”, Computer Optics, 38:4 (2014), 590–597 |
23. |
N. V. Golovastikov, D. A. Bykov, L. L. Doskolovich, “Spatial integration of optical beams using phase-shifted Bragg grating”, Computer Optics, 38:3 (2014), 372–376 |
24. |
E. A. Bezus, L. L. Doskolovich, D. A. Bykov, V. A. Soifer, “Phase modulation of Bloch surface waves with the use of a diffraction microrelief at the boundary of a one-dimensional photonic crystal”, Pis'ma v Zh. Èksper. Teoret. Fiz., 99:2 (2014), 67–71 ; JETP Letters, 99:2 (2014), 63–66 |
22
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25. |
N. V. Golovastikov, D. A. Bykov, L. L. Doskolovich, “Resonant diffraction gratings for spatial differentiation of optical beams”, Kvantovaya Elektronika, 44:10 (2014), 984–988 [Quantum Electron., 44:10 (2014), 984–988 ] |
38
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2012 |
26. |
D. A. Bykov, L. L. Doskolovich, V. A. Soifer, “Integration of optical pulses by resonant diffraction gratings”, Pis'ma v Zh. Èksper. Teoret. Fiz., 95:1 (2012), 8–12 ; JETP Letters, 95:1 (2012), 6–9 |
9
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2009 |
27. |
A. N. Kalish, V. I. Belotelov, D. A. Bykov, L. L. Doskolovich, A. K. Zvezdin, “Magnetooptical Effects in Plasmonic Bilayered Heterostructures”, Kazan. Gos. Univ. Uchen. Zap. Ser. Fiz.-Mat. Nauki, 151:1 (2009), 95–102 |
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