Информационно-измерительная система для оценки эксплуатационных характеристик светотехнических устройств

Абульханов Станислав Рафаелевич; Харитонов Сергей Иванович; Abulkhanov Stanislav; Kharitonov Sergei

Информационно-измерительная система для оценки эксплуатационных характеристик светотехнических устройств

Автор: Абульханов Станислав Рафаелевич, Харитонов Сергей Иванович

Журнал: Известия Самарского научного центра Российской академии наук @izvestiya-ssc

Рубрика: Информатика, вычислительная техника и управление

Статья в выпуске: 4-1 т.18, 2016 года.

Бесплатный доступ

Авторами предложена информационно-измерительная система, позволяющая оценивать эксплуатационные характеристики светотехнических устройств. Информационно-измерительная система состоит из четырех основных элементов: программно-аппаратный комплекс для проектирования светотехнических устройств; имитатор воздействия на оптическую поверхность природных и техногенных факторов; блок анализа состояния оптических поверхностей, блок экспериментальных исследований светотехнических устройств. Использование системы позволяет сократить на несколько порядков сроки сертификации оптических устройств по сравнению с испытаниями в естественных условиях.

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Стойкостные натурные испытания, информационно-измерительная система, природные и техногенные факторы, оптическая поверхность

Короткий адрес: https://sciup.org/148204646

IDR: 148204646 | УДК: 683.3.05+

Test bench for simulation of the effects of natural and anthropogenic factors on the optical device

We have developed the design of information-measuring system, allowing to simulate the natural and man-made effects on the optical surface. The design allows changing exposure modes and their combinations, the sequence and duration of the exposure. Use of the system reduces by several orders certification term of optical devices as compared with in vivo tests.

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Список литературы Информационно-измерительная система для оценки эксплуатационных характеристик светотехнических устройств

Kazanskiy, N. L., "Research & Education Center of Diffractive Optics," Proceedings of SPIE 8410, 84100R (2012); DOI: 10.1117/12.923233.
Doskolovich, L. L., Golub, M. A., Kazanskiy, N. L., Khramov, A. G., Pavelyev, V. S., Seraphimovich, P. G., Soifer, V. A. and Volotovskiy, S. G., "Software on diffractive optics and computer generated holograms," Proceedings of SPIE 2363, 278-284 (1995).
Golovashkin, D. L. and Kasanskiy, N. L., "Solving Diffractive Optics Problem using Graphics Processing Units," Optical Memory and Neural Networks (Information Optics) 20(2), 85-89 (2011); DOI: 10.3103/S1060992X11020019
Kazanskiy, N. L., Kharitonov, S. I., Soifer, V. A. and Volkov, A. V., "Investigation of lighting devices based on diffractive optical elements," Optical Memory & Neural Networks 9(4), 301-312 (2000).
Methods for Computer Design of Diffractive Optical Elements" Victor A. Soifer eds, A Wiley Interscience Publication. John Wiley & Sons, Inc, 651-671 (2002).
Borodin, S. A., Volkov, A. V. and Kazanskii, N. L., "Device for analyzing nanoroughness and contamination on a substrate from the dynamic state of a liquid drop deposited on its surface," Journal of Optical Technology 76(7), 408-412 (2009); DOI: 10.1364/JOT.76.000408
Kolpakov, V. A. and Ivliev, N. A., "Atomic-Molecular Model of Boundary Friction in Microtribocontacts between the Surfaces of Semiconducting and Dielectric Materials," Technical Physics 60(6), 922-927 (2015); DOI: 10.1134/S1063784215060122
Doskolovich, L. L., Kazanskiy, N. L., Kharitonov, S. I. and Soifer, V. A., "A method of designing diffractive optical elements focusing into plane areas," Journal of Modern Optics 43(7), 1423-1433 (1996); DOI: 10.1080/09500349608232815
Doskolovich, L. L., Kazanskiy, N. L., Soifer, V. A., Kharitonov, S. I. and Perlo, P., "A DOE to form a line-shaped directivity diagram," Journal of Modern Optics 51(13), 1999-2005 (2004); DOI: 10.1080/09500340408232507
Doskolovich, L. L., Kazanskiy, N. L., Kharitonov, S. I., Perlo, P. and Bernard, S., "Designing reflectors to generate a line-shaped directivity diagram," Journal of Modern Optics 52(11), 1529-1536 (2005); DOI: 10.1080/09500340500058082
Doskolovich, L. L., Kazanskiy, N. L. and Bernard, S., "Designing a mirror to form a line-shaped directivity diagram," Journal of Modern Optics 54(3-4), 589-597 (2007); DOI: 10.1080/0950034060102186.
Moiseev, M. A., Doskolovich, L. L. and Kazanskiy, N. L., "Design of high-efficient freeform LED lens for illumination of elongated rectangular regions," Optics Express 19(S3), A225-A233 (2011); DOI: 10.1364/OE.19.00A225.
Kazanskiy, N. and Skidanov, R., "Binary beam splitter," Applied Optics 51(14), 2672-2677 (2012); DOI: 10.1364/AO.51.002672
Aslanov, E. R., Doskolovich, L. L., Moiseev, M. A., Bezus, E.A. and Kazanskiy, N. L., "Design of an optical element forming an axial line segment for efficient LED lighting systems," Optics Express 21(23), 28651-28656 (2013); DOI: 10.1364/OE.21.028651
Dmitriev, A. Yu., Doskolovich, D. L., Doskolovich, L. L. and Kazanskiy, N. L., "Analytic design of refractive optical elements generating one-parameter directivity diagram," Computer Optics 38(2), 207-212 (2014).
Abulkhanov, S. R., "Vibration resistance of headlight design for electric locomotive," Proceedings of Information Technology and Nanotechnology Conference (ITNT-2015), CEUR Workshop Proceedings 1490, 112-121 (2015); DOI: 10.18287/1613-0073-2015-1490-112-121.
Abulkhanov SR, Skuratov D L. "Vibration resistance of headlamp design with light emitting diodes for electric locomotive," Proceedings of Information Technology and Nanotechnology Conference (ITNT-2015), CEUR Workshop Proceedings 1490, 122-132 (2015); DOI: 10.18287/1613-0073-2015-1490-122-132.
Kazanskiy, N. L., Uspleniev, G. V. and Volkov, A. V., "Fabricating and testing diffractive optical elements focusing into a ring and into a twin-spot," Proceedings of SPIE , 193-199 (2001); DOI: 10.1117/12.407678.
Doskolovich, L. L., Kazanskiy, N. L., Khonina, S. N., Skidanov, R. V., Heikkila, N., Siitonen, S. and Turunen, J., "Design and investigation of color separation diffraction gratings," Applied Optics 46(15), 2825-2830 (2007); DOI: 10.1364/AO.46.002825
Kazanskiy, N. L., Khonina, S. N., Skidanov, R. V., Morozov, A. A., Kharitonov, S. I., Volotovskiy, S. G., "Formation of images using multilevel diffractive lens," Computer Optics 38(3), 425-434 (2014).
Kazanskiy, N. L. and Soifer, V. A., "Diffraction investigation of geometric-optical focusators into segment," Optik -International Journal for Light and Electron Optics 96(40), 158-162 (1994).
Kazanskiy, N. L., Kotlyar, V. V. and Soifer, V. A., "Computer-aided design of diffractive optical elements," Optical Engineering 33(10), 3156-3166 (1994).
Doskolovich, L. L., Kazanskiy, N. L., Soifer, V. A. and Tzaregorodtzev, A. Ye., "Analysis of quasiperiodic and geometric optical solutions of the problem of focusing into an axial segment," Optik -International Journal for Light and Electron Optics 101(2), 37-41 (1995).
Khonina, S. N., Kazanskii, N. L., Ustinov, A. V. and Volotovskii, S. G., "The lensacon: nonparaxial effects," Journal of Optical Technology 78(11), 724-729 (2011); DOI: 10.1364/JOT.78.000724
Kazanskiy, N. L. and Serafimovich, P. G., "Cloud Computing for Rigorous Coupled-Wave Analysis," Advances in Optical Technologies 2012, Article ID 398341, 7 (2012); DOI: 10.1155/2012/398341.
Kazanskiy, N. L. and Serafimovich, P. G., "Cloud Computing for Nanophotonic Simulations," Lecture Notes in Computer Science 7715, 54-67 (2013); DOI: 10.1007/978-3-642-38250-5_7.
Kazanskiy, N. L., Murzin, S. P., Osetrov, Ye. L. and Tregub, V. I., "Synthesis of nanoporous structures in metallic materials under laser action," Optics and Lasers in Engineering 49(11), 1264-1267 (2011); DOI: 10.1016/j.optlaseng.2011.07.001
Volkov, A. V., Kazanskiy, N. L., Moiseev, O. Ju. and Soifer, V. A., "Method for the Diffractive Microrelief Formation Using the Layered Photoresist Growth," Optics and Lasers in Engineering 29(4-5), 281-288 (1998).
Zol'nikov, K. P., Uvarov, T. Yu., Psakh'e, S. G., "Anisotropy of the Plastic Deformation and Fracture Processes in a Dynamically Loaded Crystallite," Technical Physics Letters 27(4), 263-265 (2001); DOI: 10.1134/1.1370196
Kazanskii, N. L., Kolpakov, V. A. and Kolpakov, A. I., "Anisotropic etching of SiO2 in high-voltage gas-discharge plasmas," Russian Microelectronics 3(3), 169-182 (2004); DOI: 10.1023/B:RUMI.0000026175.29416.eb
Pavelyev, V. S., Borodin, S. A., Kazanskiy, N. L., Kostyuk, G. F. and Volkov, A. V., "Formation of diffractive microrelief on diamond film surface," Optics & Laser Technology 399(6), 1234-1238 (2007); DOI: 10.1016/j.optlastec.2006.08.004.
Kazanskii, N. L. and Kolpakov, V. A., "Effect of Bulk Modification of Polymers in a Directional Low-Temperature Plasma Flow," Technical Physics 54(9), 1184-1289 (2009); DOI: 10.1134/S1063784209090060.
Abul'khanov, S. R., Kazanskii, N. L., Doskolovich, L. L., Kazakova, O. Y., "Manufacture of diffractive optical elements by cutting on numerically controlled machine tools," Russian Engineering Research 31(12), 1268-1272 (2011); DOI: 10.3103/S1068798X11120033
Bezus, E.A., Doskolovich, L. L. and Kazanskiy, N. L., "Evanescent-wave interferometric nanoscale photolithography using guided-mode resonant gratings," Microelectronic Engineering 88(2), 170-174 (2011); DOI: 10.1016/j.mee.2010.10.006
Bezus, E.A., Doskolovich, L. L. and Kazanskiy, N. L., "Interference pattern formation in evanescent electromagnetic waves using waveguide diffraction gratings," Quantum Electronics 41(8), 759-764 (2011); DOI: 10.1070/QE2011v041n08ABEH014500.
Kazanskiy, N. L., Kolpakov, V. A. and Podlipnov, V. V., "Gas discharge devices generating the directed fluxes of off-electrode plasma," Vacuum 101, 291-297 (2014); DOI: 10.1016/j.Vacuum.2013.09.014.
Volkov, A. V., Kazanskiy, N. L., Moiseev O. Yu. and Poletayev S. D., "Thermal Oxidative Degradation of Molybdenum Films under Laser Ablation," Technical Physics 60(2), 265-269 (2015); DOI: 10.1134/S1063784215020255.
Abulhanov, S. R., Kazanskiy, N. L., Kharitonov, S. I., "Installation for measuring optically transparent surfaces," RF patent number 2489703 of November 8, 2011.
Абульханов С.Р., Харитонов С.И. Стенд для определения стойкости оптически прозрачных поверхностей на воздействие природных и техногенных факторов//Известия Самарского научного центра РАН. 2015. Т. 17. № 2. С.237-242.
Kazanskiy, N. L. and Popov, S. B., "Machine Vision System for Singularity Detection in Monitoring the Long Process," Optical Memory and Neural Networks (Information Optics) 19(1), 23-30 (2010); DOI: 10.3103/S1060992X10010042
Kazanskiy, N. L. and Popov, S. B., "Distributed Storage and Parallel Processing for Large-Size Optical Images," Proceedings of SPIE 8410, 84100I (2012); DOI: 10.1117/12.928441.
Kazanskiy, N. L. and Popov, S. B., "The distributed vision system of the registration of the railway train," Computer Optics 36(3), 419-428 (2012).
Karpeev, S. V., Pavelyev, V. S., Khonina, S. N., Kazanskiy, N. L., Gavrilov, A. V. and Eropolov, V. A., "Fibre sensors based on transverse mode selection," Journal of Modern Optics 54(6), 833-844 (2007); DOI: 10.1080/09500340601066125
Egorov, A. V., Kazanskiy, N. L., Serafimovich, P. G., "Using coupled photonic crystal cavities for increasing of sensor sensitivity," Computer Optics 39(2), 158-162 (2015).
Doskolovich, L. L., Kazanskiy, N. L., Soifer, V. A., Perlo, P. and Repetto, P., "Design of DOEs for wavelength division and focusing," Journal of Modern Optics 52(6), 917-926 (2005); DOI: 10.1080/09500340512331313953
Khonina, S. N., Kazanskiy, N. L. and Volotovsky, S. G., "Vortex phase transmission function as a factor to reduce the focal spot of high-aperture focusing system," Journal of Modern Optics 58(9), 748-760 (2011); DOI: 10.1080/09500340.2011.568710
Khonina, S. N., Kazanskiy, N. L. and Volotovsky, S. G., "Influence of Vortex Transmission Phase Function on Intensity Distribution in the Focal Area of High-Aperture Focusing System," Optical Memory and Neural Networks (Information Optics) 20(1), 23-42 (2011); DOI: 10.3103/S1060992X11010024
Khonina, S. N., Savelyev, D. A., and Kazanskiy, N. L., "Vortex phase elements as detectors of polarization state," Optics Express 23(14), 17845-17859 (2015); DOI: 10.1364/OE.23.017845
Khonina, S. N., Savelyev, D. A., and Kazanskiy, N. L., "Analysis of polarization states at sharp focusing," Optik -International Journal for Light and Electron Optics 127(6), 3372-3378 (2016); doi: 10.1016/j.ijleo.2015.12.108.
Kazanskiy, N. L., Serafimovich, P. G. and Khonina, S. N., "Harnessing the Guided-Mode Resonance to Design Nanooptical Transmission Spectral Filters," Optical Memory and Neural Networks (Information Optics) 19(4), 318-324 (2010); DOI: 10.3103/S1060992X10040090
Bezus, E.A., Doskolovich, L. L., Kazanskiy, N. L., Soifer, V. A. and Kharitonov, S. I., "Design of diffractive lenses for focusing surface plasmons," Journal of Optics 12(1), 015001 (2010); DOI: 10.1088/2040-8978/12/1/015001
Bykov, D. A., Doskolovich, L. L., Soifer, V. A. and Kazanskiy, N. L., "Extraordinary Magneto-Optical Effect of a Change in the Phase of Diffraction Orders in Dielectric Diffraction Gratings," Journal of Experimental and Theoretical Physics 111(6), 967-974 (2010); DOI: 10.1134/S1063776110120095
Bezus, E.A., Doskolovich, L. L. and Kazanskiy, N. L., "Scattering suppression in plasmonic optics using a simple two-layer dielectric structure," Applied Physics Letters 98(22), 221108 (2011); DOI: 10.1063/1.3597620
Bezus, E.A., Doskolovich, L. L., Kazanskiy, N. L. and Soifer, V. A., "Scattering in elements of plasmon optics suppressed by two-layer dielectric structures," Technical Physics Letters 37(12), 1091-1095 (2011); DOI: 10.1134/S1063785011120030
Kazanskiy, N. L., Serafimovich, P. G. and Khonina, S. N., "Use of photonic crystal cavities for temporal differentiation of optical signals," Optics Letters 38(7), 1149-1151 (2013); DOI: 10.1364/OL.38.001149
Bezus, E.A., Doskolovich, L. L. and Kazanskiy, N. L., "Low-scattering surface plasmon refraction with isotropic materials," Optics Express 22(11), 13547-13554 (2014).
Kazanskiy, N. L. and Serafimovich, P. G., "Coupled-resonator optical waveguides for temporal integration of optical signals," Optics Express 22(11), 14004-14013 (2014).
Kazanskiy, N. L., Kharitonov, S. I., Khonina, S. N., Volotovskiy, S. G., Strelkov, Yu. S., "Simulation of hyperspectrometer on spectral linear variable filters," Computer Optics 38(2), 256-270 (2014).
Kazanskiy, N. L., Kharitonov, S. I., Karsakov, A. V., Khonina, S. N., "Modeling action of a hyperspectrometer based on the Offner scheme within geometric optics," Computer Optics 38(2), 271-280 (2014).
Kazanskiy, N. L., Kharitonov, S. I., Khonina, S. N., "Simulation of a hyperspectrometer based on linear spectral filters using vector Bessel beams," Computer Optics 38(4), 770-776 (2014).
Kazanskiy, N. L., Kharitonov, S. I., Doskolovich, L. L., and Pavelyev, A. V., "Modeling the performance of a spaceborne hyperspectrometer based on the Offner scheme," Computer Optics 39(1), 70-76 (2015).
Golovin, A. D., Demin, A. V., "Simulation model of a multichannel Offner hyperspectrometer," Computer Optics 39(4), 521-528 (2015); DOI: 10.18287/0134-2452-2015-39-4-521-528.
Kalaev, M. P., Semkin, N. D., Novikov, L. S., "Space Debris and Micrometeoroid Impact on Spacecraft Elements: Experimental Simulation," Inorganic Materials: Applied Research 4(3), 205-210 (2013); DOI: 10.1134/S2075113313030052
Semkin, N. D., Piyakov, A. V., Voronov, K. E., Kalaev, M. P., Telegin, A. M., "An Injector of Charged Liquid Particles," Instruments and Experimental Techniques 56(2), 225-232 (2013); DOI: 10.1134/S0020441213010235
Semkin, N. D., Pomelnikov, R. A., Telegin, A. M., "Expansion of a shock plasma in the accelerating field of a parallel-plate capacitor in a time-of-flight mass spectrometer," Technical Physics 59(5), 663-669 (2014); DOI: 10.1134/S1063784214050284

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