Серафимович Павел Григорьевич

Scopus/WoS

2023

• 1 Davydov N.S., Evdokimova V.V., Serafimovich P.G. etc. Neural network for step anomaly detection in head motion during fMRI using meta-learning adaptation // Computer Optics 2023. — Vol. 47. Issue 6. № 6. — P. 991-1001
• 2 Bibikov S.A., Petrov M.V., Alekseyev A.P. etc. Color consistency method for cameras with unknown model // Computer Optics 2023. — Vol. 47. Issue 1. № 1. — P. 92-101

2022

• 1 Khonina S.N., Khorin P.A., Serafimovich P.G. etc. Analysis of the wavefront aberrations based on neural networks processing of the interferograms with a conical reference beam // Applied Physics B: Lasers and Optics 2022. — Vol. 128. Issue 3.
• 2 Serafimovich P.G., Dzyuba A.P., Khonina S.N. etc. Using U-net for signal preprocessing in interferometric synthetic aperture radar // Proceedings of SPIE - The International Society for Optical Engineering. — 2022. — Vol. 12295.

2021

• 1 Serafimovich P.G., Dzyuba A.P., Nikonorov A.V. etc. Using a Binary Diffractive Optical Element to Increase the Imaging System Depth of Field in UAV Remote Sensing Tasks // Lecture Notes in Computer Science. — 2021. — Vol. 12667 LNCS. — P. 566-577
• 2 Khorin P.A., Dzyuba A.P., Serafimovich P.G. etc. Neural networks application to determine the types and magnitude of aberrations from the pattern of the point spread function out of the focal plane // Journal of Physics: Conference Series. — 2021. — Vol. 2086. Issue 1.
• 3 Khonina S.N., Volotovskiy S.G., Dzyuba A.P. etc. Power phase apodization study on compensation defocusing and chromatic aberration in the imaging system // Electronics (Switzerland) 2021. — Vol. 10. Issue 11.
• 4 Rodin I. A. , Serafimovich P.G., Popov S.B. Recognition of wavefront aberrations corresponding to individual Zernike functions from the pattern of the point scattering function in the focal plane using neural networks // Proceedings of SPIE - The International Society for Optical Engineering. — 2021. — Vol. 11793.
• 5 Popov S.B., Dzyuba A.P., Serafimovich P.G. The use of a tilted diffractive optical element with an increased depth of field in the problem of accounting and control of railway rolling stock // Proceedings of SPIE - The International Society for Optical Engineering. — 2021. — Vol. 11793.
• 6 Serafimovich P.G., Dzyuba A., Popov S. Using tilted diffractive optical element with depth map estimation to increase depth of field in the end-to-end imaging system // Proceedings of ITNT 2021 - 7th IEEE International Conference on Information Technology and Nanotechnology. — 2021. —
• 7 Serafimovich P., Dzyuba A., Popov S. Using classifier-regressor pipeline in the problem of recognizing wavefront aberrations // Proceedings of ITNT 2021 - 7th IEEE International Conference on Information Technology and Nanotechnology. — 2021. —

2020

• 1 Bryukhovetskiy A.S., Brusilovsky L.I., Kozhin S.P. etc. Human mind has microwave electromagnetic nature and can be recorded and processed // Progress in Brain Research 2020. — Vol. 258. — P. 439-463
• 2 Dzyuba A.P., Khonina S.N., Nikonorov A.V. etc. Calculation of a binary diffractive optical element to increase the imaging system depth of field in the task of classifying images by a neural network // Journal of Physics: Conference Series. — 2020. — Vol. 1695. Issue 1.
• 3 Rodin I. A. , Khonina S.N., Serafimovich P.G. etc. Recognition of wavefront aberrations types corresponding to single zernike functions from the pattern of the point spread function in the focal plane using neural networks // Computer Optics 2020. — Vol. 44. Issue 6. — P. 923-930
• 4 Dzyuba A., Serafimovich P., Khonina S. etc. Application of a neural network for calculating the surface relief of a different level two-zone lens with an increased depth of field // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11516.
• 5 Donon Ya. , Kupriyanov A., Kirsh D. etc. Extended anomaly detection and breakdown prediction in LINAC 4's RF power source output // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
• 6 Dzyuba A., Popov S., Serafimovich P. Phase apodization of the imaging system through separate color channels to increase the depth of field // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
• 7 Plisko A. S. , Serafimovich P., Davydov N. S. etc. Detection of step displacements in fMRI head motion data based on machine learning // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
• 8 Dzyuba A.P., Khonina S.N., Nikonorov A.V. etc. Increasing Depth of Field of Tilted Diffractive Lens in Image Classification Task // 2020 International Multi-Conference on Industrial Engineering and Modern Technologies, FarEastCon 2020. — 2020. —

2019

• 1 Donon Ya. , Kupriyanov A., Kirsh D. etc. Anomaly detection and breakdown prediction in RF power source output: A review of approaches // CEUR Workshop Proceedings. — 2019. — Vol. 2507. — P. 99-104

2017

• 1 Kazanskiy N., Protsenko V., Serafimovich P. Performance analysis of real-time face detection system based on stream data mining frameworks // Procedia Engineering. — 2017. — Vol. 201. — P. 806-816
• 2 Serafimovich P.G., Kazanskiy N.L. Simulation of temporal integration of optical signals with photonic crystal nanobeam cavities // Proceedings of SPIE - The International Society for Optical Engineering. — 2017. — Vol. 10342.

2016

• 1 Kazanskiy N., Protsenko V., Serafimovich P. Performance analysis of sliding window filtering of two dimensional signals based on stream data processing systems // Proceedings of SPIE - The International Society for Optical Engineering. — 2016. — Vol. 9807.
• 2 Serafimovich P.G., Stepikhova M.V., Kazanskiy N.L. etc. On a silicon-based photonic-crystal cavity for the near-IR region: Numerical simulation and formation technology // Semiconductors 2016. — Vol. 50. Issue 8. — P. 1112-1116
• 3 Protsenko V.I., Seraphimovich P.G., Popov S.B. etc. Software and hardware infrastructure for data stream processing // CEUR Workshop Proceedings. — 2016. — Vol. 1638. — P. 782-787
• 4 Egorov A.V., Kazanskiy N.L., Serafimovich P.G. Application of photonic-crystal coupled cavities for increase in sensitivity of optical sensor // Optical Memory and Neural Networks (Information Optics) 2016. — Vol. 25. Issue 1. — P. 25-31
• 5 Serafimovich P.G., Kazanskiy N.L. Optical modulator based on coupled photonic crystal cavities // Journal of Modern Optics 2016. — Vol. 63. Issue 13. — P. 1233-1238

2015

• 1 Serafimovich P.G., Kazanskiy N.L. Active photonic crystal cavities for optical signal integration // Optical Memory and Neural Networks (Information Optics) 2015. — Vol. 24. Issue 4. — P. 260-271
• 2 Egorov A.V., Kazanskiy N.L., Serafimovich P.G. Using Coupled Photonic Crystal Cavities for Increasing of Sensor Sensitivity // Computer Optics 2015. — Vol. 39. Issue 2. — P. 158-162
• 3 Serafimovich P.G., Kazanskiy N.L. Compact multichannel spectrometer based on the array of two-component photonic crystal cavities // Pattern Recognition and Image Analysis 2015. — Vol. 25. Issue 3. — P. 526-531
• 4 Protsenko V.I., Kazanskiy N.L., Serafimovich P.G. Real-time analysis of parameters of multiple object detection systems // Computer Optics 2015. — Vol. 39. Issue 4. — P. 582-591
• 5 Serafimovich P.G. Optical Modulator Based on Coupled Photonic Crystal Cavities // Computer Optics 2015. — Vol. 39. Issue 2. — P. 147-151
• 6 Degtyarev S.A., Serafimovich P.G. Focused Laser-Beam Scanning by the Apertured Probe of a Near-Field Microscope // Radiophysics and Quantum Electronics 2015. — Vol. 57. Issue 8-9. — P. 665-671

2014

• 1 Kazanskiy N.L., Serafimovich P.G. Coupled-resonator optical waveguides for temporal integration of optical signals // Optics Express 2014. — Vol. 22. Issue 11. — P. 14004-14013
• 2 Serafimovich P.G., Kazanskiy N.L., Khonina S.N. Sandwich-typed resonator cavity based on a regular photonic crystal nanobeam // Journal of Physics: Conference Series. — 2014. — Vol. 490. Issue 1.
• 3 Kazanskiy N.L., Serafimovich P.G. Using photonic crystal nanobeam cavities for integration of optical signal // Computer Optics 2014. — Vol. 38. Issue 2. — P. 181-187
• 4 Serafimovich P.G. Use of coupled photonic crystal nanobeam cavities for temporal integration of optical signals // Proceedings of SPIE - The International Society for Optical Engineering. — 2014. — Vol. 9533.
• 5 Kazanskiy N.L., Serafimovich P.G., Zimichev E.A. Spectral-spatial classification of hyperspectral images with k-means++ partitional clustering // Proceedings of SPIE - The International Society for Optical Engineering. — 2014. — Vol. 9533.
• 6 Serafimovich P.G. Diffraction analysis of focusing optical elements // Proceedings of SPIE - The International Society for Optical Engineering. — 2014. — Vol. 9156.
• 7 Kazanskiy N.L., Protsenko V.I., Serafimovich P.G. Comparison of system performance for streaming data analysis in image processing tasks by sliding window // Computer Optics 2014. — Vol. 38. Issue 4. — P. 804-810
• 8 Zimichev E.A., Kazanskiy N.L., Serafimovich P.G. Spectral-spatial classification with k-means++ particional clustering // Computer Optics 2014. — Vol. 38. Issue 2. — P. 281-286

2013

• 1 Serafimovich P.G. Two-component nanocavity based on a regular photonic crystal nanobeam // Computer Optics 2013. — Vol. 37. Issue 2. — P. 155-159
• 2 Kazanskiy N.L., Serafimovich P.G. Cloud computing for nanophotonic simulations // Lecture Notes in Computer Science. — 2013. — Vol. 7715 LNCS. — P. 54-67
• 3 Kazanskiy N.L., Serafimovich P.G., Khonina S.N. Use of photonic crystal cavities for temporal differentiation of optical signals // Optics Letters 2013. — Vol. 38. Issue 7. — P. 1149-1151
• 4 Serafimovich P.G., Kazanskiy N.L., Khonina S.N. Two-component cavity based on a regular photonic crystal nanobeam // Applied Optics 2013. — Vol. 52. Issue 23. — P. 5830-5834

2012

• 1 Kazanskiy N.L., Serafimovich P.G., Khonina S.N. Use of photonic crystal resonators for differentiation of optical impulses in time // Computer Optics 2012. — Vol. 36. Issue 4. — P. 474-478
• 2 Kazanskiy N.L., Serafimovich P.G. Cloud computing for rigorous coupled-wave analysis // Advances in Optical Technologies 2012. —
• 3 Khonina S.N., Serafimovich P.G., Savel'ev D.A. etc. Diffraction at binary microaxicons in the near field // Journal of Optical Technology 2012. — Vol. 79. Issue 10. — P. 626-631
• 4 Kazanskiy N.L., Serafimovich P.G., Khonina S.N. Enhancement of spatial modal overlap for photonic crystal nanocavities // Computer Optics 2012. — Vol. 36. Issue 2. — P. 199-204
• 5 KAZANSKIY N.L., SERAFIMOVICh P.G., KhONINA S. N. Повышение пространственного перекрытия резонансных мод фотоннокристаллического нанорезонатора // Computer Optics 2012. — № 36(2). — P. 199-204

2011

• 1 Kazanskiy N.L., Serafimovich P.G. Cloud computing for nanophotonics simulations // Computer Optics 2011. — Vol. 35. Issue 3. — P. 320-328
• 2 KAZANSKIY N.L., SERAFIMOVICh P.G. Использование инфраструктуры облачных вычислений для моделирования сложных нанофотонных структур // Computer Optics 2011. — № №35, том 3.. — P. 320-328
• 3 Kazanskiy N.L., Serafimovich P.G., Khonina S.N. Optical nanoresonator in the ridge of photonic crystal waveguides crossing // Computer Optics 2011. — Vol. 35. Issue 4. — P. 426-431

2010

• 1 KAZANSKIY N.L., POPOV S.B., SERAFIMOVICh P.G. etc. ИСПОЛЬЗОВАНИЕ ВОЛНОВОДНОГО РЕЗОНАНСА ДЛЯ СОЗДАНИЯ НАНООПТИЧЕСКИХ СПЕКТРАЛЬНЫХ ПРОПУСКАЮЩИХ ФИЛЬТРОВ // Computer Optics 2010. — № т. 34,№2. — P. 162-169
• 2 Kazanskiy N.L., Serafimovich P.G., Khonina S.N. Harnessing the guided-mode resonance to design nanooptical transmission spectral filters // Optical Memory and Neural Networks (Information Optics) 2010. — Vol. 19. Issue 4. — P. 318-324
• 3 Volotovskiy S. G. , Kazanskiy N.L., Popov S.B. etc. Performance analysis of image parallel processing applications // Computer Optics 2010. — Vol. 34. Issue 4. — P. 567-572
• 4 Kazanskiy N.L., Serafimovich P.G., Popov S.B. etc. Using guided-mode resonance to design nano-optical spectral transmission filters // Computer Optics 2010. — Vol. 34. Issue 2. — P. 162-168
• 5 VOLOTOVSKIY S.G., KAZANSKIY N.L., POPOV S.B. etc. Оценка производительности приложений параллельной обработки изображений // Computer Optics 2010. — № т. 34, № 4.. — P. 567-573

2005

• 1 Serafimovich P.G., Cheong B.H., Ahn P.S. etc. DMD illumination using Diffractive Optical Elements // Digest of Technical Papers - SID International Symposium. — 2005. — Vol. 36. Issue 1. — P. 902-905

2004

• 1 Serafimovich P.G., Ahn P.S., Shin J.K. The vortex mask design for irregular arrays of contact holes // Proceedings of SPIE - The International Society for Optical Engineering. — 2004. — Vol. 5401. — P. 37-40

1998

• 1 Kotlyar V.V., Seraphimovich P.G., Soifer V.A. An iterative algorithm for designing diffractive optical elements with regularization // Optics and Lasers in Engineering 1998. — Vol. 29. Issue 4-5. — P. 261-268

1996

• 1 Andreev N.E., Bychkov S.S., Kotlyar V.V. etc. Formation of high-power hollow bessel light beams // Quantum Electronics 1996. — Vol. 26. Issue 2. — P. 126-130
• 2 Andreev N.E., Bychkov S.S., Kotlyar V.V. etc. Formation of high-power hollow Bessel light beams // Kvantovaya Elektronika 1996. — Vol. 23. Issue 2. — P. 134

1995

• 1 Kotlyar Viktor V., Seraphimovich P.G., Soifer Viktor A. Iterative weight-based method for calculating kinoforms // Proceedings of SPIE - The International Society for Optical Engineering. — 1995. — Vol. 2363. — P. 177-183
• 2 Doskolovich Leonid L., Golub Mikhail A., Kazanskiy Nikolay L. etc. Software on diffractive optics and computer-generated holograms // Proceedings of SPIE - The International Society for Optical Engineering. — 1995. — Vol. 2363. — P. 278-284
• 3 Kotlyar V.V., Serafimovich P.G., Soifer V.A. Weighting iterative method for calculating kinoform // Optics and Spectroscopy (English translation of Optika i Spektroskopiya) 1995. — Vol. 78. Issue 1. — P. 132-134
• 4 Kotlyar V.V., Seraphimovich P.G., Zalyalov O.K. Noise-insensitive iterative method for interferogram processing // Optics and laser technology 1995. — Vol. 27. Issue 4. — P. 251-254

1994

• 1 Kotlyar V.V., Serafimovich P.G. Adaptive iterative method of calculating kinoforms // Optics and Spectroscopy (English translation of Optika i Spektroskopiya) 1994. — Vol. 77. Issue 4. — P. 606-609

ВАК

2015

• 1 Egorov A.V., Казанский Н. Л. , Серафимович П. Г. Using Coupled Photonic Crystal Cavities for Increasing of Sensor Sensitivity // Компьютерная оптика. — 2015. — Т. 39. Вып. 2. — С. 158-162
• 2 Проценко В. И. , Казанский Н. Л. , Серафимович П. Г. Real-time analysis of parameters of multiple object detection systems // Компьютерная оптика. — 2015. — Т. 39. Вып. 4. — С. 582-591

2013

• 1 Серафимович П. Г. Two-component nanocavity based on a regular photonic crystal nanobeam // Компьютерная оптика. — 2013. — Т. 37. Вып. 2. — С. 155-159

2012

• 1 ХОНИНА С. Н., САВЕЛЬЕВ Д.А., Пустовой И.А. и др. Дифракция на бинарных микроаксиконах в ближней зоне // Оптический журнал. — 2012. — № – Т.79. – №10.. — С. 22-29
• 2 КАЗАНСКИЙ Н.Л., СЕРАФИМОВИЧ П.Г., ХОНИНА С. Н. Повышение пространственного перекрытия резонансных мод фотоннокристаллического нанорезонатора // Компьютерная оптика. — 2012. — № 36(2). — С. 199-204

2011

• 1 КАЗАНСКИЙ Н.Л., СЕРАФИМОВИЧ П.Г. Использование инфраструктуры облачных вычислений для моделирования сложных нанофотонных структур // Компьютерная оптика. — 2011. — № №35, том 3.. — С. 320-328

2010

• 1 КАЗАНСКИЙ Н.Л., ПОПОВ С.Б., СЕРАФИМОВИЧ П.Г. и др. ИСПОЛЬЗОВАНИЕ ВОЛНОВОДНОГО РЕЗОНАНСА ДЛЯ СОЗДАНИЯ НАНООПТИЧЕСКИХ СПЕКТРАЛЬНЫХ ПРОПУСКАЮЩИХ ФИЛЬТРОВ // Компьютерная оптика. — 2010. — № т. 34,№2. — С. 162-169
• 2 ВОЛОТОВСКИЙ С.Г., КАЗАНСКИЙ Н.Л., ПОПОВ С.Б. и др. Оценка производительности приложений параллельной обработки изображений // Компьютерная оптика. — 2010. — № т. 34, № 4.. — С. 567-573

Другие

2015

• 1 Kazanskiy N.L., Serafimovich P.G. Photonic Crystal Cavities for Optical Signal Processing // International Conference on Applied Physics, Simulation and Computers (APSAC 2015). — 2015. — P. 134-139

2010

• 1 КАЗАНСКИЙ Н.Л., СЕРАФИМОВИЧ П.Г., ХОНИНА С. Н. Использование параллельных методов оптимизациидля создания нанооптических спектральных пропускающих фильтров // 7-ая Международная научно-практическая конференция ГОЛОЭКСПО-2010. — 2010. — С. 52-62