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Most published authors (scientific articles only) of the journal
scientific articles published in peer review journal, serial, conference publications, indexed in international bibliographical databases and/or having DOI index
|
| 1. |
V. V. Kotlyar |
123 |
| 2. |
A. A. Kovalev |
73 |
| 3. |
S. N. Khonina |
68 |
| 4. |
L. L. Doskolovich |
52 |
| 5. |
A. G. Nalimov |
49 |
| 6. |
S. S. Stafeev |
48 |
| 7. |
N. L. Kazanskii |
45 |
| 8. |
V. V. Myasnikov |
29 |
| 9. |
S. I. Kharitonov |
28 |
| 10. |
R. V. Skidanov |
27 |
| 11. |
A. P. Porfirev |
26 |
| 12. |
S. V. Karpeev |
24 |
| 13. |
D. A. Bykov |
23 |
| 14. |
E. S. Kozlova |
22 |
| 15. |
S. G. Volotovsky |
21 |
| 16. |
A. V. Kupriyanov |
20 |
| 17. |
V. V. Podlipnov |
20 |
| 18. |
Yu. V. Vizilter |
17 |
| 19. |
A. V. Volyar |
17 |
| 20. |
S. A. Degtyarev |
16 |
| 21. |
M. A. Moiseev |
16 |
| 22. |
A. V. Ustinov |
16 |
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40 most published authors of the journal |
|
| Most cited authors of the journal |
| 1. |
N. L. Kazanskii |
605 |
| 2. |
S. N. Khonina |
539 |
| 3. |
V. V. Kotlyar |
510 |
| 4. |
A. G. Nalimov |
269 |
| 5. |
S. I. Kharitonov |
269 |
| 6. |
A. A. Kovalev |
263 |
| 7. |
L. L. Doskolovich |
260 |
| 8. |
S. S. Stafeev |
229 |
| 9. |
A. V. Kupriyanov |
208 |
| 10. |
V. V. Podlipnov |
201 |
| 11. |
R. V. Skidanov |
188 |
| 12. |
A. V. Nikonorov |
181 |
| 13. |
A. V. Volyar |
169 |
| 14. |
V. V. Myasnikov |
159 |
| 15. |
S. V. Karpeev |
153 |
| 16. |
Ya. E. Akimova |
152 |
| 17. |
S. G. Volotovsky |
150 |
| 18. |
E. S. Kozlova |
149 |
| 19. |
M. V. Bretsko |
148 |
| 20. |
N. A. Ivliev |
148 |
|
40 most cited authors of the journal |
|
| Most cited articles of the journal |
| 1. |
MIDV-500: a dataset for identity document analysis and recognition on mobile devices in video stream
V. V. Arlazarov, K. B. Bulatov, T. S. Chernov, V. L. Arlazarov
Computer Optics, 2019, 43:5, 818–824 |
72 |
| 2. |
Detection of objects in the images: from likelihood relationships towards scalable and efficient neural networks
N. A. Andriyanov, V. E. Dementiev, A. G. Tashlinskiy
Computer Optics, 2022, 46:1, 139–159 |
66 |
| 3. |
Image restoration in diffractive optical systems using deep learning and deconvolution
A. V. Nikonorov, M. V. Petrov, S. A. Bibikov, V. V. Kutikova, A. A. Morozov, N. L. Kazanskiy
Computer Optics, 2017, 41:6, 875–887 |
64 |
| 4. |
Injectional multilens molding parameters optimization
N. L. Kazanskiy, I. S. Stepanenko, A. I. Khaimovich, S. V. Kravchenko, E. V. Byzov, M. A. Moiseev
Computer Optics, 2016, 40:2, 203–214 |
59 |
| 5. |
Addressed fiber Bragg structures in quasi-distributed microwave-photonic sensor systems
O. G. Morozov, A. Zh. Sakhabutdinov
Computer Optics, 2019, 43:4, 535–543 |
51 |
| 6. |
On the use of a multi-raster input of one-dimensional signals in two-dimensional optical correlators
M. S. Kuzmin, V. V. Davydov, S. A. Rogov
Computer Optics, 2019, 43:3, 391–396 |
49 |
| 7. |
Russian traffic sign images dataset
V. I. Shakhuro, A. S. Konushin
Computer Optics, 2016, 40:2, 294–300 |
48 |
| 8. |
A vector optical vortex generated and focused using a metalens
V. V. Kotlyar, A. G. Nalimov
Computer Optics, 2017, 41:5, 645–654 |
47 |
| 9. |
Hyperspectral image segmentation using dimensionality reduction and classical segmentation approaches
E. V. Myasnikov
Computer Optics, 2017, 41:4, 564–572 |
46 |
| 10. |
Achievements in the development of plasmonic waveguide sensors for measuring the refractive index
N. L. Kazanskiy, M. Butt, S. A. Degtyarev, S. N. Khonina
Computer Optics, 2020, 44:3, 295–318 |
43 |
| 11. |
Optical elements based on silicon photonics
M. Butt, S. N. Khonina, N. L. Kazanskiy
Computer Optics, 2019, 43:6, 1079–1083 |
42 |
| 12. |
Method for forecasting changes in time series parameters in digital information management systems
Yu. A. Kropotov, A. Yu. Proskuryakov, A. A. Belov
Computer Optics, 2018, 42:6, 1093–1100 |
39 |
| 13. |
Vegetation type recognition in hyperspectral images using a conjugacy indicator
S. A. Bibikov, N. L. Kazanskiy, V. A. Fursov
Computer Optics, 2018, 42:5, 846–854 |
38 |
| 14. |
Modeling the performance of a spaceborne hyperspectrometer based on the Offner scheme
N. L. Kazanskiy, S. I. Kharitonov, L. L. Doskolovich, A. V. Pavelev
Computer Optics, 2015, 39:1, 70–76 |
38 |
| 15. |
Characteristics of sharp focusing of vortex Laguerre-Gaussian beams
D. A. Savelyev, S. N. Khonina
Computer Optics, 2015, 39:5, 654–662 |
37 |
| 16. |
Investigation of algorithms for coagulate arrangement in fundus images
A. S. Shirokanev, D. V. Kirsh, N. Yu. Ilyasova, A. V. Kupriyanov
Computer Optics, 2018, 42:4, 712–721 |
36 |
| 17. |
Reconstruction of anatomical structures using statistical shape modeling
N. A. Smelkina, R. N. Kosarev, A. V. Nikonorov, I. M. Bairikov, K. N. Ryabov, E. V. Avdeev, N. L. Kazanskiy
Computer Optics, 2017, 41:6, 897–904 |
35 |
| 18. |
Crop growth monitoring through Sentinel and Landsat data based NDVI time-series
M. Boori, K. Choudhary, A. V. Kupriyanov
Computer Optics, 2020, 44:3, 409–419 |
32 |
| 19. |
U-Net-bin: hacking the document image binarization contest
P. V. Bezmaternykh, D. A. Ilin, D. P. Nikolaev
Computer Optics, 2019, 43:5, 825–832 |
31 |
| 20. |
Using coupled photonic crystal cavities for increasing of sensor sensitivity
A. V. Egorov, N. L. Kazanskiy, P. G. Serafimovich
Computer Optics, 2015, 39:2, 158–162 |
31 |
|
40 most cited articles of the journal |
|
| Most requested articles of the journal |
|
|
| 1. |
Face photo retrieval based on sketches
G. Kukharev, N. L. Shchegoleva
Computer Optics, 2016, 40:5, 729–739 | 16 |
| 2. |
An efficient algorithm for non-rigid object registration
A. Yu. Makovetskii, S. M. Voronin, V. I. Kober, A. V. Voronin
Computer Optics, 2020, 44:1, 67–73 | 14 |
| 3. |
A remote sensing and GIS based approach for land use/cover, inundation and vulnerability analysis in Moscow, Russia
K. Choudhary, M. Boori, A. V. Kupriyanov
Computer Optics, 2019, 43:1, 90–98 | 13 |
| 4. |
Study of an imaging spectrometer based on a diffraction lens
R. V. Skidanov, V. A. Blank, A. A. Morozov
Computer Optics, 2015, 39:2, 218–223 | 12 |
| 5. |
The modificaction of laser beam for optimization of optical trap force characteristics
R. V. Skidanov, M. A. Rykov
Computer Optics, 2013, 37:4, 431–435 | 12 |
| 6. |
Classification of rare traffic signs
B. V. Faizov, V. I. Shakhuro, V. V. Sanzharov, A. S. Konouchine
Computer Optics, 2020, 44:2, 236–243 | 12 |
| 7. |
Biometric data and machine learning methods in the diagnosis and monitoring of neurodegenerative diseases: a review
I. A. Hodashinsky, K. S. Sarin, M. B. Bardamova, M. O. Svetlakov, A. O. Slezkin, N. P. Koryshev
Computer Optics, 2022, 46:6, 988–1019 | 12 |
| 8. |
On a phase-shift of waves at the medium interface
E. V. Mekhonoshina, V. Ya. Modorskii
Computer Optics, 2015, 39:3, 385–391 | 11 |
| 9. |
Calculation of eigenfunctions for imaging two-lens system with axial symmetry
M. S. Kirilenko, S. N. Khonina
Computer Optics, 2014, 38:3, 412–417 | 11 |
| 10. |
Interferometric testing of steep cylindrical surfaces with on-axis CGHs
A. G. Poleshchuk, R. K. Nasyrov, J.-M. Asfour
Computer Optics, 2016, 40:5, 625–528 | 11 |
|
| Total publications: |
1232 |
| Scientific articles: |
1219 |
| Authors: |
1622 |
| Citations: |
6637 |
| Cited articles: |
925 |
 |
Impact Factor Web of Science |
|
for 2024:
1.200 |
|
for 2023:
1.100 |
|
Scopus Metrics |
|
2024 |
SJR |
0.265 |
|
2023 |
CiteScore |
4.200 |
|
2023 |
SNIP |
0.575 |
|
2023 |
SJR |
0.251 |
|
2022 |
SJR |
0.321 |
|
2021 |
SJR |
0.508 |
|
2020 |
SJR |
0.491 |
|
2019 |
SJR |
0.586 |
|
2018 |
CiteScore |
2.370 |
|
2018 |
SJR |
0.535 |
|
2017 |
CiteScore |
1.790 |
|
2017 |
SNIP |
1.681 |
|
2017 |
SJR |
0.457 |
|
2016 |
CiteScore |
1.610 |
|
2016 |
SNIP |
1.495 |
|
2016 |
SJR |
0.348 |
|
2015 |
CiteScore |
1.220 |
|
2015 |
SNIP |
1.261 |
|
2015 |
IPP |
1.185 |
|
2015 |
SJR |
0.445 |
|
2014 |
CiteScore |
0.730 |
|
2014 |
SNIP |
0.846 |
|
2014 |
IPP |
0.656 |
|
2014 |
SJR |
0.285 |
|
2013 |
SNIP |
0.397 |
|
2013 |
IPP |
0.341 |
|
2013 |
SJR |
0.198 |
|
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