Julian B. Aizenberg and Vladimir P. Budak The Science of Light Engineering, Fields of Application and Theoretical Foundations

Anton M. Mishchenko, Sergei S. Rachkovsky, Vladimir A. Smolin, and Igor V. Yakimenko Results of Spatial Structure of Atmosphere Radiation in a Spectral Range (1.5–2) µm Research

Michail Yu. Kataev and Andrei K. Lukyanov Simulation of Reflected Solar Radiation for Atmosphere Gas Composition Evaluation for Optical Remote Sensing from Space

Nikolai N. Bogdanov, Andrei D. Zhdanov, Dmitriy D. Zhdanov, and Igor S. Potyomin Analysis of Errors in the Relief of Scattering Microstructures in Light-Conducting Systems Modelling

Nicolai I. Shchepetkov, George N. Cherkasov, and Vladimir A. Novikov Lighting of Engineering Structures and Industrial Facilities: New Aspects of the Topic

Zhiqiao WANG Development of LED Light Sources in Landscape Lighting

Boris A. Veklenko The Nature of the Photon and Quantum Optics

George V. Boos The Probability of Detecting Coloured Objects on Coloured Backgrounds Based on a Statistical Model of the Threshold of Colour Vision

Alexander T. Ovcharov, Yuri N. Selyanin, and Yaroslav V. Antsupov A Hybrid Illumination Complex For Combined Illumination Systems: Concepts, State of the Problem, Practical Experience

Vladimir M. Pchelin and Irina E. Makarova Assessment of the Current State and Prospects for Development of Irradiation Systems in Modern Greenhouse Facilities

Sergei A. Pavlov, Sergei L. Koryakin, Natalia E. Sherstenyova, ElenaYu. Maksimova, and Eugene M. Antipov Highly Effective Covering Materials with Quantum Dots for Greenhouses

Hongwu ZENG Optimization of Classroom Illumination System Based on Neural Network Algorithm

Julian B. Aizenberg and Vladimir P. Budak Light & Engineering / Svetotekhnika Journal: A Review of 2017 and Looking Forward to 2018-2020

Leonid B. Prikupets Technological Lighting for Agro-Industrial Instolations in Russia

George V. Boos, Leonid B. Prykupets, Eugene I. Rozovsky, and Raisa I. Stolyarevskaya Standardization of Lighting Fixtures and Installations for Greenhouses

Alexander I. Vasilyev, Sergei V. Kostyuchenko, Nicolai N. Kudryavtsev, Denis A. Sobur, and Dmitry V. Sokolov UV Disinfection Technologies for Water, Air and Surface Treatment

Eugene I. Starovoytov Possible Uses of Equipment in Space to Control Earth Surface Illumination

Eugene I. Rozovsky and Raisa I. Stolyarevskaya Photometry of Lighting Devices: Current State and Prospects for Development

Julian B. Aizenberg and Vladimir P. Budak The Science of Light Engineering, Fields of Application and Theoretical Foundations

Anton M. Mishchenko, Sergei S. Rachkovsky, Vladimir A. Smolin, and Igor V. Yakimenko Results of Spatial Structure of Atmosphere Radiation in a Spectral Range (1.5–2) µm Research

Michail Yu. Kataev and Andrei K. Lukyanov Simulation of Reflected Solar Radiation for Atmosphere Gas Composition Evaluation for Optical Remote Sensing from Space

Nikolai N. Bogdanov, Andrei D. Zhdanov, Dmitriy D. Zhdanov, and Igor S. Potyomin Analysis of Errors in the Relief of Scattering Microstructures in Light-Conducting Systems Modelling

Nicolai I. Shchepetkov, George N. Cherkasov, and Vladimir A. Novikov Lighting of Engineering Structures and Industrial Facilities: New Aspects of the Topic

Zhiqiao WANG Development of LED Light Sources in Landscape Lighting

Boris A. Veklenko The Nature of the Photon and Quantum Optics

George V. Boos The Probability of Detecting Coloured Objects on Coloured Backgrounds Based on a Statistical Model of the Threshold of Colour Vision

Alexander T. Ovcharov, Yuri N. Selyanin, and Yaroslav V. Antsupov A Hybrid Illumination Complex For Combined Illumination Systems: Concepts, State of the Problem, Practical Experience

Vladimir M. Pchelin and Irina E. Makarova Assessment of the Current State and Prospects for Development of Irradiation Systems in Modern Greenhouse Facilities

Sergei A. Pavlov, Sergei L. Koryakin, Natalia E. Sherstenyova, ElenaYu. Maksimova, and Eugene M. Antipov Highly Effective Covering Materials with Quantum Dots for Greenhouses

Hongwu ZENG Optimization of Classroom Illumination System Based on Neural Network Algorithm

Julian B. Aizenberg and Vladimir P. Budak Light & Engineering / Svetotekhnika Journal: A Review of 2017 and Looking Forward to 2018-2020

Leonid B. Prikupets Technological Lighting for Agro-Industrial Instolations in Russia

George V. Boos, Leonid B. Prykupets, Eugene I. Rozovsky, and Raisa I. Stolyarevskaya Standardization of Lighting Fixtures and Installations for Greenhouses

Alexander I. Vasilyev, Sergei V. Kostyuchenko, Nicolai N. Kudryavtsev, Denis A. Sobur, and Dmitry V. Sokolov UV Disinfection Technologies for Water, Air and Surface Treatment

Eugene I. Starovoytov Possible Uses of Equipment in Space to Control Earth Surface Illumination

Eugene I. Rozovsky and Raisa I. Stolyarevskaya Photometry of Lighting Devices: Current State and Prospects for Development

1. Bouguer P. Optical tractate about light gradation, Moscow, The USSSR Academy of Science, 1950.
2. Lambert J.H., Photometria, sive de Mensura et Gradibus luminais, Colorum et Umbrae. Augsburg, 1760.
3. Gershun A.A. Selected manuscripts on photometry and lighting engineering / Moscow, G. Phys.Math. P.H., Leningrad, 1958.
4. Kepler J. Ad vitellionem paralipomena, quibus astronomiae pars optica traditur de modo visionis, & humorum oculi usu, contra options& anatomicos. Frankfurt: C. Marnius & Heirs of J. Aubrius, 1604.
5. Apresyan L.A., Kravtsov Yu.A. Theory of radiation transfer: statistical and wave aspects/ Moscow, Science (Nauka), Main publisher house of phys.math. literature, 1983.
6. Veklenko B.A. The Nature of the Photon and Quantum Optics// Light & Engineering, 2018, V.26, #2, pp. 4–13.
7. Born M., Wolf E. Fundamentals of Optics/ Second edition, Translation from Eng. To Russian Moscow, Science (Nauka), Main publisher house of phys.math. literature, 1973.

In a concise, but accessible for the first acquaintance form the procedure for the quantization of linear oscillator is set out. By analogy with this procedure the procedure of quantization (second quantization) of classical Maxwell’s electrodynamics is set up. The physical sense of the wave functions arguments of transverse electromagnetic field and its Fourier transformation is set up. One pay attention as for quantum coherent (almost a classic) states of the electromagnetic field and for photonics Fock states. Attention is drawn to the fact of absence the power of the universal content of such concepts as field amplitude, phase and number of particles (photons), which are used by experimenter’s to describe the states of a quantized field. The semi quantitative description the interaction processes of a quantum electromagnetic field with substance is set up. Specified situations are shown in which the discrepancy between the predictions of classical and quantum electrodynamics is noticeable at the macroscopic level.

1. Allenov A.M., Solovyov V.A. Correlation (spatial) relations between luminance fluctuations created by cloudy nonuniformities in the (8–13) µm interval / Proceedings of the IEM, 1995, Issue 25 (160): Atmosphere optics, pp. 3–15.
2. Allenov A.M., Solovyov V.A., Yakimenko I.V., etc. Studies of radiation of optical background in the (3–5) µm and (8–13) µm intervals / Proceedings of the IEM, 1996, Issue 26 (161), Physics of atmosphere, pp. 31–50.
3. Allenov A.M., Solovyov V.A., Yakimenko I.V. Structure of radiation of optical backgrounds in the (0.4–15) µm interval / Proceedings of the IEM, 1997, Issue 28 (163), Physics of atmosphere, pp. 3–41.
4. Allenov A.M., Ivanova N.P. Time changeability of the sky radiation spatial structure in the 8–13 µ interval with cumulus cloud cover / The Optical journal, 2001, V. 68, #3, pp. 43–44.
5. Allenov M.I., Solovyov V.A., etc. Stochastic structure of cloud cover radiation / SPb.: Gidrometeoizdat, 2000, 175 p.
6. Knapp H.W. et al. Discriminating between water and ice clouds using near infrared AVIRIS measurements // Summaries of the ninth JPL Aerborne Earth Science workshop, 2000, Feb 23–25, JPL.
7. Clough S.A., Shephard M.W., Mlawer E.J., Delamere J.S., Iacono M.J., CadyPereira K., Boukabara S., Brown P.D. Atmospheric radiation transfer modelling: a summary of the AER codes // Journal of Quantitative Spectroscopy and Radiation Transfer, 2005, Vol. 91, Issue 2, pp. 233–244.
8. Huang B., Mielikainen J., Oh H., Huang H.L.A. Development of a GPUbased highperformance radiation transfer model for the Infrared Atmospheric Sounding Interferometer (IASI) // Journal of Computational Physics, 2011, Vol. 230, Issue 6, pp. 2207–2221.
9. Lieven C., Hurtmans D., Clerbaux C., HadjiLazaro J., Ngadi Y., Coheur P.F. Retrieval of sulphur dioxide from the infrared atmospheric sounding interferometer (IASI) // Atmospheric Measurement Techniques, 2012, Vol. 5, Issue 3, pp. 581–594.
10. Chen X., Wei H., Xu Q. Infrared atmospheric transmittance calculation model // Infrared and Laser Engineering, 2011, Vol. 40, Issue 5.
11. Mishchenko A.M., Rachkovsky S.S., Smolin V.A., Yakimenko I.V. Experimental studies of spatial distribution of atmospheric background intrinsic radiation in the infrared wave length interval // Radio Engineering, 2017, #2, pp. 119–125.
12. Kriksunov L.Z. Handbook on foundations of infrared facilities. – Moscow: Sovetskoye Radio, 1978, 400 p.
13. V.A. Solovyov et al. Experimental determination of infrared radiation of planes while in flight, [a monograph], scientific­and­theoretical publishing / Ministry of defence of the Russian Federation, Smolensk: MA AAD of RF, 2009, 83 p.
14. Yakimenko I.V. Methods, models and facilities of detecting air targets against atmospheric background using wideangle optoelectronic systems. The second revised edition, SPb.: Lan, 2014, 176 p.

1. Judd D., Vyshetski G. Colour in science and technology. Moscow: Publishing house MIR, 1978, 592 p.
2. Grigoriev A.A. Application of the statistical solution theory for calculation of probability and threshold characteristics of vision organ // Svetotekhnika, 2000, #6, pp. 23Ц25.
3. Grigoriev A.A. Statistical theory of image perception in optoelectronic systems of visualisation: 05.11.07Ц Optical and optoelectronic devices and systems: Abstract of Doctor of Engineering / Moscow: The Moscow Power Institute (MPI TU, 2001, 40 p.
4. Boos G. V., Grigoriev A.A. New approach in the determination of qualitative characteristics of outdoor illumination installations // Light&Engineering, 2016, V.24, #1, pp. 51Ц57.
5. GOST 23198Ц94. Electric lamps. Methods of measuring spectral and colour characteristics.
6. Reference book on lighting engineering / Under the editorship of Yu.B. Aizenberg. The 3rd revised edition, Moscow: Znak, 2006.Ц 972 p.
7. Meshkov V. V., Matveev A.B. Fundamentals of Lighting engineering: Manual for high education institutions: part 2. Physiological optics and colorimetry. The 2nd revised edition, Moscow: Energoatomizdat, 1989, 450 p.
8. Boos G. V., Grigoriev A.A. On colour co-ordinates of primary colours of the RGB colorimetric system // Svetotekhnika, 2016, #3, pp. 30Ц34.
9. Gordyukhina S. V., Grigoriev A.A. A Metod of determining sensitivity of RGB receptors based on the statistical model of vision organ // The Moscow Power Institute Bulletin. Ц ћoscow: The Moscow Power Institute publishing house, 2010, #2, pp. 174Ц178.
10. Grigoriev A. A., Gordyukhina S.V. Determination of specific colour co-ordinates of physiological system // Semiconductor lighting engineering, 2011, #1, pp. 44Ц47.
11. Shestov N.S. Segregation of optical signals against random noise background. Moscow: Sovetskoye radio, 1967, 348 p.
12. Korn G., Korn T. Handbook on mathematics (for scientists and engineers). Moscow: Nauka, 1978, 832 p.
13. Meshkov V.V. Fundamentals of Lighting engineering: Manual for high education institutions: part.1, the 2nd revised edition, Moscow: Energiya, 1979, 368 p.

1. OSN–АPК 2.10.24.001–04 Lighting norms for agricultural enterprises, buildings and constructions. Moscow, 2004.
2. Kansvol N. More light in the barn // New agriculture. Moscow, 2006, № 1, pp. 58–62.
3. Kansvol N., Mathias S. FurmehrlichtinsMelkstandsorgon. // Fortschritliche Landwist, 2013, № 4, pp. 14–15.
4. https://ltcompany.com/ru/products/types/industrial-luminaires/up-to-5-meters/inox-led/inox-led-70-ovp-5000k/
5. http://varton.ru/products/product/158/
6. http://www.agroinvestor.ru/companies/article/12053-pyat-novykh-ferm-za-vosem-let/.
7. http://www.bashinform.ru/news/731905/
8. https://agrobelarus.by/articles/nauka/kakoy_svet_nuzhen_v_svinarnike_/.
9. Каvtarashvili А. Sh. Technology of increasing the efficiency of production of chicken eggs / Dissertation of doctor of agricultural sciences (specialty 06.02.04), Sergiyev Posad, 1999, 366 p.
10. Mukhamedina А.R. The impact of light on behaviour and productivity of birds // Veterinary, 2005, № 6, pp. 16–18.
11. https://www.hartmann-light.ru/————kltfx.
12. http://refportal.com/news/business/spravochnik-po-ndt-v-pishievoy-promishlennosti-poyavitsya-v-217-godu/.
13. Gladin D.V. Lighting in poultry: The past and the present. http://www.ntp-ts.ru/upload/iblock/1f0/past_and_present.pdf.
14. Ruchin А.B. Influence of photoperiod on growth, physiological and hematological indices of juvenile Siberian sturgeon // RAS news, Biological series, 6, pp. 698–704.
15. Vkasov V.А., Maslova N.I., Ponomarev S.V., Bakaneva Yu.М. The effect of light on growth and development of fish // Herald of АGTU. Series: Fish farming, 2013, № 2, pp. 24–33.
16. http://www.akvagroup.com/products/cage-farming-aquaculture/underwater-lights.
17. http://aquafarmer.ru/.
18. http://www.akvagroup.com/news/image-gallery
19. Grigoryev S.S., Sedova N.А. Industrial fish farming // Handbook. Kamchatka State University, Part 1, 2008, 353 p.
20. Poedinok N.L. The use of artificial light in mushroom cultivation // Biotechnology ACTA, 2013, № 6, pp. 58–70.
21. Purschwitz I., Muller S., Kasther Ch. Sealing the rainbow: light sensing in fungi. // Current Opinion in Microbiology, 2006, Vol. 9, No. 6, pp. 566–571.
22. Devochkina N.L. Intensive growing of oyster mushrooms in greenhouse // Greenhouses in Russia, 2009, № 3, pp. 23–26.
23. Glushakov О.V., Alekseeva К.L. Growing of oyster mushrooms in “Agrico Ltd.”, Chuvash Republic // Greenhouses in Russia, 2017, № 2, pp. 28–29.
24. http://gribportal.ru/vyrashchivanie/vyrashchivanie-veshenok-v-domashnih-usloviyah-dlya-novichkov/
25. Prikupets L.B. Light culture. A rational approach to the choice of lighting system // Greenhouses in Russia, 2016, № 1, pp. 56–61.
26. http://galad.ru/catalog/? FILTER [KLASS_PROD]=1503
27. Prikupets L.B. Light culture. Lamps are operating. When shall be replaced? // Greenhouses in Russia, 2015, № 1, pp. 52–53.
28. Emelin А.А., Prikupetz L.B., Tarakanov I.G. The spectrum effect in LED irradiators for growing lettuce // Svetotekhnika, 2015, № 4, pp. 47–52.
29. Yemelin A.A., Prikupets L.B., Tarakanov I.G. Spectral Aspect when Using Light-Emitting Diode Irradiators for Salad Plant Cultivation under Photoculture Conditions // Light& Engineering, 2015, Vol. 23, No. 4, pp. 41–45.
30. Boos G.V., Prikupets L.B., Terehov V.G. Tarakanov I.G. Studies in the field of plant irradiation with LEDs //The 10th Asia Lighting Conference, Shanghai, China, August 17–18, 2017, http://asialightingconference.org/index.php.
31. Prikupets L.B., Terehov V.G., Tarakanov I.G. LED and HPS luminaires in Russian greenhouses // Lux Europa 2017, Ljubljana, Slovenia, September 18–20, 2017, http://www.luxeuropa2017.eu/
32. http://www.lighting.philips.ru/products/horticulture.
33. http://innovatube.com/2016/12/26/ cac-cong-nghe-moi-duoc-mong-cho-nam-2017-phan-2/
34. http://fibonacci.farm/models
35. Prikupets L.B., Yemelin A.A. The use of LED-irradiators for growing lettuce: economy aspect // Greenhouses in Russia, 2013, № 3, pp. 66–68.
36. https://www.vegprice.ru/news/tag/0/7965-philipslighting, application date: 05.07.2017.
37. Tooming H.G., Gulyaev B.I. Methods of measuring photosynthetic active radiation // Manual, Мoscow, Nauka, 1967, 143 p.
38. Vornorm DIN5031 Teil 1 (1985) “Strahlungsphysik im optischen Bereich”.
39. Kuzmin, V.N., Nikolaev, S.E. Methods and devices for quick evaluation of efficiency of optic radiation in photoculture // Svetotekhnika, 2016, № 4, pp. 41–43.
40. Kuzmin, V.N., Nikolaev, S.E. Methods and Devices for quick evaluation of efficiency of optic radiation under Photoculture Conditions //Light & Engineering, 2016, No. 4, pp. 99–104.
41. RD-АPK 1.10.09.01–14 Methodical recommendations on design of greenhouses for cultivation of vegetables and seedlings. Moscow, 2014.
42. GOST R57671–2017 “Irradiation devices with LED light sources for greenhouses. General specifications”. 43. PNST 211–2017 “The exposure of plants by LED light sources. Methods of measurements”.
44. Rozovskiy E.I., Prikupets L.B., Stolyarevskaya R.I. Standardization in the field of lighting equipment and installations for greenhouses // Svetotekhnika, 2017, № 6, pp.69–74.
45. Rozovskiy E.I., Prikupets L.B., Stolyarevskaya R.I. Standardization in the field of lighting equipment and installations for greenhouses // Light& Engineering, 2018, Vol. 26, No. 1, pp.——-.
46. ANSI/ASABE S640 “Quantities and Units of Electromagnetic Radiation for Plants (Photosynthetic Organisms)”.
47. Jianzhong J. Stakeholders make progress on LED lighting horticulture standards // LEDs Magazine, June, 2015, pp. 39–41.

At present, in optical remote sensing of atmosphere from space, a new problem class appears: to determine little gas components (carbon dioxide, methane, etc.), which cause greenhouse effect. Concentration of these gases in atmosphere is less than one percent, which rigidly limits accuracy of satellite measurements and of simulating spatial concentration of the radiation (signal) flow reflected by Earth. In the article, a description of simulating signals received by satellite spectrometer in nearinfrared spectrum region is given. The signals are solar radiation passed through an atmosphere layer and reflected from Earth surface. It is calculated based on parametrical radiation atmosphere scattering and absorption model, which takes into consideration both multidimensional atmosphere parameter structure and Earth surface relief. Accounting such information allows you to go from measurement of spatial radiation flux to calculations of gas concentration for an arbitrary geographical Earth surface point and for any time point. As an example, calculations for Fourier spectrometer for spectrum measurement near IR region with an average spectral resolution are presented. The spectrometer was installed on the GOSAT satellite of the Space Agency of Japan. A comparison of computed and of really measured values of the signal received by the satellite shows that deviation for the Sun zenith angle equal to 30o does not exceed 3 %.

1. Gushchin G.P. Studies of atmospheric ozone. Leningrad: Gidrometeoizdat, 1963, 289 p.
2. Khrgian A.H. Physics of atmospheric ozone. Leningrad: Gidrometeoizdat, 1973, 285 p.
3. Malkevich M.S. Optical studies of atmosphere from satellites. Moscow: Nauka, 1973, 303 p.
4. Kondratyev K. Ya., Timofeev Yu.M. Meteorological sounding of atmosphere from space. Leningrad: Gidrometeoizdat, 1978, 280 p.
5. Timofeev YU. M., Vasilyev A.V. Fundamentals of theoretical atmospheric optics. SPb., 2007, 152 p.
6. Hoffman N., Preetham A.J. Real­time light­atmosphere interactions for outdoor scenes. // Graphics programming methods, 2003, pp. 337–352.
7. Otterman, J. Singlescattering solution for radiative transfer through a turbid atmosphere. // Appl. Opt, 1978, Vol.1, No.17(21), pp. 3431–3438.
8. http://smsc.cnes.fr/IASI.
9. http://www.sciamachy.org.
10. http://www.gosat.nies.go.jp.
11. IPCC, Synthesis Report, Section 2.4: Attribution of climate change, in IPCC AR4 SYR2007.v 12. Solomon S., Qin D., Manning M., Chen Z., Marquis M., Averyt K.B., Tignor M., Miller H.L. (eds). IPCC2007: Climate Change 2007: The Physical Science Basis. // Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 996p.
13. Pachauri R.K., Meyer L.A. (eds.) IPCC2014: Climate Change 2014: Synthesis Report. Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, IPCC, Geneva, Switzerland, 151p.
14. Katayev M. Yu. A program simulation system of solar radiation reflected from Earth surface /M. Yu. Katayev, I.V. Boychenko // TUSUR Reports, 2009, #1(19), Part1, pp. 88–95.
15. Krylov A.S., Vtyurin A.N., Gerasimova Yu.V. Data processing of infrared Fourier of spectroscopy. A textbook of methodics. Pre­print #832 Ф. Krasnoyarsk: Institute of physics of the Siberian Branch of the Russian Academy of Science, 2005, 48 p.
16. Hopfner M., Emde C. Comparison of single and multiple scattering approaches for the simulation of limbemission observations in the midIR // Journal of Quantitative Spectroscopy & Radiative Transfer, 2005, Vol. 91, No. 3, pp.275–285.
17. Breon F., Frouin R., Gautier C. Downwelling longwave irradiance at the ocean surface: An assessment of in situ measurements and parameterizations // J. Appl. Meteorology, 1991, Vol. 30, No.1, pp.17–31.
18. Kane Van, R., Gillespie, A.R. Interpretation and topographic compensation of conifer canopy selfshadowing // Remote Sensing of Environment, 2008, Vol. 112, No. 10, pp.3820–3822.
19. Farr, T.G., Hensley, S., Rodriguez, E., Martin, J., Kobrick, M. The shuttle radar topography mission // CEOS SAR Workshop, Toulouse 26–29 Oct. 1999, Noordwijk, 2000, pp. 361–363.
20. Rothman, L.S., Gordon, I.E., Babikov, Y. et al. The HITRAN2012 Molecular Spectroscopic Database // Journal of Quantitative Spectroscopy and Radiation Transfer, 2013, Vol.130, No. 11, pp. 4–50.
21. http://www.ncep.noaa.gov/.
22. Hess, M., Koepke, P., Schult, I. Optical Properties of Aerosols and clouds: The software package OPAC // Bull. Am. Met. Soc., 1998, Vol. 79, No. 5, pp. 831–844.
23. Thuillier, G., Herse, M., Simon, P.C., Labs, D., Mandel, H., Gillotay, D., Foujols, T. The solar spectral irradiance from 200 to 2400 nm as measured by the SOLSPEC spectrometer from the ATLAS1–2–3 and EURECA missions // Sol. Phys., 2003, Vol. 214, No. 1, pp. 1–22.
24. Katayev M. Yu., Lukyanov A.K. Parallel technologies in the simulation problem of a satellite Fourier spectrometer signal // The Seventh Siberian conference on parallel and highperformance calculations. Report program and theses, November, 12–14, 2013, Tomsk: Publishing House of the Tomsk University, 2013, pp. 23–24.

1. Aizenberg J.B. Hollow Light Guides. Ц Moscow: Znack Publishing House, 2009. 208 p.
2. Ovcharov A. T., Selyanin Yu.N. Solatube Technology: Prospect in architecture and building in Russia // Light & Engineering, 2016, V.24, #2, pp. 4Ц11.
3. Brones D. A., Lesley R.P. Upper light integrated lamps: a combination of natural and artificial illumination for energy saving // Svetotekhnika, 2002, #6, pp. 33Ц37.
4. Mingozzi A., Bottiglioni S., Kasalone R. The Arthelio combined illumination installation with hollow light guides // Svetotekhnika, 2002, #1, pp. 18Ц22.
5. Ayzenberg Yu.B., Buob E., Zigner R., Korobko A.A., Pyatigorsky V.M. A heliostat-LED illumination system for school recreation halls // Svetotekhnika, 1996, #8, pp. 8Ц25.
6. Ayzenberg Yu. B., Buob E., Meissen T. A heliostat-LED illumination system for school recreation halls // Svetotekhnika, 2002, # 4, pp. 24Ц25.
7. Ayzenberg Yu.B. Integral systems of room illumination without a sufficient natural light // Svetotekhnika, 2003, #1, pp. 22Ц28.
8. Ovcharov A.T. Hybrid luminaires of combined illumination with an automatic control system // Electronic information systems, 2015, #4(7), pp. 22Ц34.
9. SolatubeЃ M74 Smart LED//SOLAR hybrid illumination system: magic light. [Company Website]. Cop. 2004Ц2015. URL: http://www.solatube.su/katalog- modeley-solatube-i-solar-star/zenitnyie-fonari-novogo- pokoleniya-sistemyi-solnechnogo-osveshheniya-solatube- m74-skyvault/ (addressing date: 9/15/2017).
10. SolarspotЃ LED systems Ц Intelligent Lighting Solutions // SOLARSPOT: Tubular Daylighting Systems. [Company website]. Cop.2017 URL: http://solarspot.it/en/ products-comm/solarspot-led-systems (дата обращени¤: 15.09.2017).
11. Delivering healthy natural light inside// Monodraught Ltd. [Company website]. Cop.2017 URL: https://www.monodraught.com/products/natural-lighting (дата обращени¤: 15.09.2017).
12. GOST P 55392Ц2012 Illumination devices and systems. Terms and definittions.
13. GOST P 54814Ц2011/IEC/TS62504:2011 Light emitting diodes and LED modules for general illumination. Terms and definitions.
14. Pain T. Development of hollow light guides in Great Britain // Svetotekhnika, 2004, #3, pp. 39Ц45.
15. Solovyov A. K. A comparative heat-engineering calculation of upper natural illumination systems (roof lights and hollow tubular light guides) // Engineering- construction journal, 2014, #2, pp. 24Ц35.
16. Solovyov A.K. Hollow tubular light guides: their application for natural building illumination and for energy saving // Svetotekhnika, 2011, #5, pp. 41Ц47.
17. Kuznetsov A. L., Oseledets E. Yu., Solovyov A.K., Stolyarov M.V. An experience of application of hollow tubular light guides for natural illumination in Russia // Svetotekhnika, 2011, #6, pp. 4Ц11.

1. RTD10–95 “Regulations for Technical Design of Greenhouses and Complexes for Growing Vegetables and Seedlings”.
2. RD-АPK 1.10.09.01–14 “Guidelines for technological design of greenhouses and greenhouse combines for cultivation of vegetables and seedlings” Moscow: Ministry of Agriculture of the Russian Federation, 2014, 109 p.
3. Prikupets L.B. “GALAD” greenhouse fixtures for plants photoculture // Svetotekhnika, 2016, № 5, pp. 47–49.
4. GOST R57671–2017 “Irradiating devices with light emitting diodes for greenhouses, General technical terms”.
5. Draft of the standard 211–2017 “Irradiation of plants by light-emitting diodes, Methods of measurements”.
6. Wright J. Industry Standards for Greenhouse Lighting on the Horizon // http://www.greenhousegrower.com/ technology/industry-standards-for-greenhouse-lighting-on-the-horizon/.
7. ANSI/ASABE S640 “Quantities and Units of Electromagnetic Radiation for Plants (Photosynthetic Organisms)”.
8. Stolyarevskaya R.I., Rozovskiy Е.I. Current status and development of lighting fixtures photometry // Svetotekhnika, 2017, № 4, pp. 4–13.
9. Emelin А.А, Prikupets L.B., Tarakanov I.G. Spectral Aspect when Using Light Emitting Diode Irradiators for Salad Plant Cultivation under Photoculture Conditions // Svetotekhnika, 2015, № 4, pp. 47–52.
10. Emelin A.A., Prikupets L.B., Tarakanov I.G. Spectral Aspect when Using Light-Emitting Diode Irradiators for Salad Plant Cultivation under Photoculture Conditions // Light & Engineering, 2015, Vol. 23, No. 4, pp. 55–62.
11. Prikupets L.B. Technological Lighting for Agro-Industry in Russia // Svetotekhnika, 2017, № 6, pp.6–14.
12. Prikupets L.B. Technological Lighting for Agro-Industry in Russia // Light & Engineering, #1, 2018, pp. 4–12.
13. Jianzhong J. Stakeholders make progress on LED lighting horticulture standards // LEDs Magazine, June, 2015, pp. 39–41.
14. FR.1.37.2017.27374 “Method for measurement of photosynthetic photon flux of LED luminaires designed for greenhouses with the aid of goniophotometer RIGО 801 and spectroradiometer CAS140”, 2017, 31 pages, certificate of registration № 03/22.06.2017–01.00276–2014.
15. FR.1.37.2017.27376 “Method for plants illumination measurements by the luxmeter TKALUX in industrial greenhouses lit by LED luminaires”, 2017, 22 pages, certificate of registration № 05/22.06.2017–01.00276–2014.
16. FR.1.37.2017.27375 “Method for photosynthetic irradiance measurement with quantum sensor “LI-190R” in industrial greenhouses illuminated by LED installations”, 2107, 24 pages, certificate of registration № 04/23.06.2017–01.00276–2014.
17. FR.1.37.2017.27373 “Method for lighting characteristics measurement and calculation of power efficiency of LED installations for irradiation of plants in greenhouses”, 2017, 47 pages, certificate of registration № 02/28.04.2017–01.00276–2014.
18. Prikupets L.B., Tikhomirov А.А. Optimization of radiation spectrum for cultivation of vegetables under photoculture conditions // Svetotekhnika, 1992, № 3, pp. 5–7.
19. Boos G.V., Prikupets L.B., Terekhov V.G., Tarakanov I.G. Studies in the field of plant irradiation with LEDs // 10th Asia Lighting Conference, Shanghai, China, August 17–18, 2017. http://asialightingconference.org/index.php.

1. Shponkina Yu. Energy saving in electrical energy industry // ER, 2014, #3 (57), pp. 22–24.
2. Chang­Yi Li, Jui­Wen Pan “High­efficiency backlight module with two guiding modes” // Applied Optics, 2014, Vol. 53, # 8, pp. 1503–1511.
3. Young Chul Kim, TaeSik Oh, Yong Min Lee “Optimized pattern design of lightguide plate (LGP)” // Optica Applicata, 2011, Vol. XLI, No. 4, pp. 863–872.
4. Zhdanov D.D., Zhdanov A.D., Potyomin I.S. A quick method of constructing local equidistant distributions of micro geometrical objects of illumination systems // Optics and spectroscopy, 2015. #2, pp. 329–336.
5. ChaoHeng Chien, ZhiPeng Chen “Design and fabrication of the concentric circle light guiding plate for LEDbacklight module by MEMS technique” // Microsyst. Technol, 2007, #13, pp. 1529–1535, DOI 10.1007/s00542–006–0365y.
6. ChiungFang Huang, YungKang Shen, Yi Lin, JenChang Yang “Luminance and brightness field distribution of light guiding plate for backlight panel (BLP) by micro moulding” // Polymers for advanced technologies, 2008, Vol. 19, Issue 12, pp. 1887–1893.
7. URL: http://denso.com/; http://densoeurope.com/products/informationsafetysystems/instrumentclusters/ (addressing date: 5/20/2017).
8. United States Patent 13/562,888 July 31, 2012. Light emitting device and system providing white light with various colour temperatures / US20120293093 A1, Nov 22, 2012/ Kim; YuSik. Samsung Electronics Co., Ltd. (KR).
9. United States Patent 15/048,476 Feb.19. 2016. Electronic device / US2017/0097614 A1, Apr.6, 2017/ Pilgoo Kang, Dongseuck KO and other. LG Electronics Inc.
10. United States Patent 14/918,591 October 21, 2015. Light guide plate, backlight module and display device / US9,557,469 B2 January 31, 2017/ Chang, ChiaYin and other. Radiant OptoElectronics Corporation.
11. Davenport T.L.R., Cassarly W.J. Optimizing Density Patterns to Achieve Desired Light Extraction for Displays // Proc. SPIE, 2007, Vol. 6342, p. 63420T.
12. United States Patent 14/632,377 February 26, 2015. Backlight module having a frame element, light bar, light guiding plate and light bar cover / US9,739,930 B2, August 22, 2017// Lo; ChingI. INNOLUX CORPORATION.
13. Zhdanov D.D., Sokolov V.G., Potemin I.S., Voloboy A.G, Galaktionov V.A., Kirilov N. Modeling and Computer Design of Liquid Crystal Display Backlight with Light Polarization Film // Optical Review, 2014, Vol. 21, No. 5, pp. 642–650.
14. ChengHuan Yang, SenYeu Yang “A highbrightness light guide plate with high precise doublesided microstructures fabricated using the fixed boundary hot embossing technique” // Journal of Micromechanics and Microengineering, 2013, Vol. 23, p. 035033.
15. ChengHsienWu and ChienHung Lu “Fabrication of an LCD light guide plate using closeddie hot embossing” // Journal of Micromechanics and Microengineering, 2008, Vol. 18, p. 035006.
16. JenChin Yang, ChungChing Huang Using UV rolltoplate imprint lithography to fabricate light guide plates with microdot patterns // Micro & Nano Letters, 2012, Vol. 7, Issue 3, pp. 244–247.
17. Peiyun Yi, Hao Wu, Chengpeng Zhang, Linfa Peng, Xinmin Lai “Rolltoroll UV imprinting lithography for micro/nanostructures” // Journal of Vacuum Science & Technology B, 2015, Vol. 33, No. 6, p. 060801.
18. TunChien Teng, MingFeng Kuo “Optical characteristic of the light guide plate with microstructures engraved by laser” // Proc. of SPIE, 2012, Vol. 8485.
19. Bogdanov N.N., Zhdanov A.D., Zhdanov D.D., Potemin I.S. Design of Ergonomic Illumination Systems for Cultural, Medical and Educational Facilities / EVA 2017 Saint Petersburg: Electronic Imaging and the Visual Arts: International conference, St. Petersburg, June 22–23, 2017: Conference Proceedings, St. Petersburg: ITMO university, 2017, pp. 106–111.
20. Luoa Xichun, Chenga Kai, Webba Dave, Wardle Frank “Design of ultraprecision machine tools with applications to manufacture of miniature and micro components // Journal of Materials Processing Technology, 2005, Vol. 167, pp. 515–528.
21. TunChien Teng, MingFeng Kuo “Highly precise optical model for simulating light guide plate using LED light source” // Optics Express, 2010, Vol. 18, Issue 21, p. 22208.
22. Lumicept – Integra Inc. URL: http://www.integra. jp/en/products/lumicept (addressing date: 25.05.2017).
23. ASAP. URL: http://www.breault.com/software/softwareoverview.php (addressing date: 20.05.2017).
24. TracePro. URL: https://www.lambdares.com/tracepro/ (addressing date: 25.05.2017).
25. LightTools. URL: http://www.opticalres.com/lt/ltprodds_f.html (addressing date: 19.05.2017).
26. SPEOS. URL: https://www.optisworld.com/productofferinglightsimulationvirtualrealitysoftware/SPEOS (addressing date: 21.05.2017).
27. Sokolov V.G., Zhdanov D.D., Potemin I.S., Garbul A.A., Voloboy A.G., Galaktionov V.A., Kirilov N. Reconstruction of scattering properties of rough airdielectric boundary // Optical Review, 2016, Vol. 23, Issue 5, pp. 834–841, DOI: 10.1007/s10043–016–0250–6.

1. Karmazinov F.V., Kostyuchenko S.V., Kudryavtsev N.N., Hramenkov S.V. Ultra-violet technologies in the modern world: A collective monograph / Dolgoprudny: Intellekt Publishing House, 2012, 392 p.
2. Alshin V.M., Bezdelin S.M., Volkov S.V., Gilbukh A. Ya., Drozhzhin V.V., Zhukov V.I., Kalinsky A.V., Kostyuchenko S.V., Kudryavtsev N.I., Kurkin G.A., Smirnov A.D., Yakimenko A.V . Application of UV water irradiation technology instead of primary chlorination // Water supply and sanitary engineering// 1996, #12, pp. 13–16.
3. Sanitary regulations and standards SanPiN2.1.5.980–00. 2.1.5. “Water disposal of the inhabited places, sanitary protection of water objects. Hygienic requirements to protection of surface water. Health regulations and standards”.
4. Novikov Yu. V., Tsyplakov G.V., Tulakin A.V., Ampleeva G.P., Trukhina G.M., Korolyov A.A., Bogdanov M.V., Zholdakova Z.I., Kostyuchenko S.V., Yakimenko A.V. Hygienic aspects of sewage water disinfection using ultra-violet radiation // Hygiene and sanitation. 2000, #1, pp. 12–14.
5. Sanitary regulations and standards СанПиН 2.1.4.1074–01 “Drinking water. Hygienic requirements to water quality of centralised systems of drinkable water supply. Quality control. Hygienic requirements to safety of hot water supply”.
6. Dziminkas Ch. A, Kostyuchenko S.V . Consolidation of modern technologies when preparing drinking water at Sludnensky waterwork. Nizhny Novgorod // Water purification Water treatment Water supply, 2011, #3, pp.52–60.
7. Kostyuchenko S.V., Nefedov Yu. I., Zaytseva S.G. Experience of water services of St. Petersburg when introducing safe disinfection technologies of drinking water // Water purification. Water treatment. Water supply. 2008, #17, pp. 43–49.
8. Chyornei G., Kudryavtsev N.N., Kostyuchenko S.V., Volkov S.V., Khan A.S., Levchenko D.A. Multibarrier disinfection system. Introduction of modern disinfection methods when preparing drinking water in the system of centralised water supply of Budapest // Voda Magazine, 2012, #1.
9. Kostyuchenko S.V., Volkov S.V., Kuzmin A.V., Lysyi E.O., Ortel E., Davydov D.V., Tkachyov A.A., Baranov V.L. Experience of introducing modern disinfection systems using ultra-violet radiation in Beijing (People’s Republic of China) //Voda Magazine. 2017, #5, pp. 16–19.
10. Kovalsky W.J. Ultraviolet Germicidal Irradiation Handbook. Berlin: Springer, 2009.
11. Vilk M.F., Polyakova V.A., Lebedeva N.S., Gipp E.K., Bolshakov B.V., Karev A.V., Kostyuchenko S.V., Dubrovskaya T.A., Yershov A.V., Kudryavtsev N.N. Application of ultra-violet irradiation of air in Moscow underground // Hygiene and sanitary. 2007, #2, pp. 17–23.
12. Vasserman A.L., Shandala M.G., Yuzbashev V.G. Ultra-violet radiation for prevention of infection diseases. Moscow: Meditsina, 2003, 208 p.
13. Sanitary regulations and standards SanPiN2.1.3.2630–10 “Sanitary and epidemiologic requirements to the organisations accomplishing medical activity”.
14. Advanced Oxidation Processes for Water and Wastewater Treatment / Ed. by S. Parson, 2004, IWA Publishing, ISBN: 1-843390175. 15. UV LED market to grow from $90m to $520m in 2019 // Semiconductor today, 2015, Vol.10, issue 1, Feb., pp. 80–81.
16. Kneissl M., Kolbe T., Wurtele M., Hoa E. Development of UV–LED Disinfection: Report within WP2.5: Compact Units for Decentralised Water Supply. Techneau. Feb., 2010.
17. Pagan J. UV–C LEDs versus Mercury Vapor – A System Level Comparison / Proc. IUVA Congress, Vanсouver, 2016.
18. Beck S.E., Jeanis K.M., Inden K.G., Ryu H., Boczek L., Cashdollar J., Lawal O.R. Optimizing Pathogen Inactivation at Low Energy Cost with a Tailored, Multiple-Wavelength UV LED Unit / Proc. IUVA Congress, Vanсouver, 2016.
19. URL: https://www.aquisense.com/ (addressing date: 20.06.2017)
20. Moe С. UV–C Light Emitting Diodes // Radtech Report. 2014, Issue 1, pp. 45–49.
21. Pagan J., Lawal O. Coming of age – UVC–LED Technology Update // IUVA news. 2015, Vol. 17, Issue 1.
22. Pagan J., Lawal O. Proposed Testing Protocol for Measurement of UV–C LED Lamp Output // IUVA news, 2015, Vol. 17, Issue 2, 9 p.
23. Reference book on lighting engineering / Under the editorship of Yu.B. Ayzenberg. The 3rd revised edition, Moscow: Znak, 2006, 972 p.
24. van der Meer М., van Lierop F., Sokolov D. The analysis of modern low pressure amalgam lamp characteristics. URL: http://www.dafp.de/wp-content/uploads/2015/10/The-analysis-of-modern-low-pressure-amalgam-characteristics.pdf (addressing date: 20.06.2017).
25. Vasilyak L.M., Vasserman A.L. Disinfection of air and surfaces using pulse UV radiation // Hi+Med. High technologies in medicine, 2014, V. 5, #27.

1. Tikhomirov A.A., Sharupich V.P., Lisovsky G.M. Photoculture of plants: biophysical and biochemical fundamentals. Novosibirsk: The publishing house of the Siberian Branch of the Russian Academy of Science, 2000, 213 p.
2. Shpolsky E.V. Absorption spectrum of chlorophyll in a solution and in natural state // Bulletin of the Academy of Sciences of the USSR. Biology series, 1947, #3, pp. 391Ц406.
3. Sventitsky I.I. Evaluation of photosynthesis efficiency of optical radiation // Svetotekhnika, 1965, #4, pp. 19Ц24.
4. Tikhomirov A.A., Lisovsky G.M., Sidko F. Ya. Spectral light composition and producing capacity of plants// Novosibirsk: Nauka, 1991.
5. McCree, K.J. The Action Spectrum, Absorptance and Quantum Yield of Photosynthesis in Crop Plants // Agricultural and Forest Meteorology, 1972, Vol. 9, pp. 191Ц216.
6. Molchanov A.G., Samoylenko V.V. Energy saving optical irradiation of industrial greenhouses// Stavropol: ARGUS, 2013, 120 p.
7. Shulgin I.A. A plant and the Sun// Leningrad: Gidrometeoizdat, 1973.
8. Ivanitsky A.E., Koval E.O., Rayda V.S. Fluorescent properties of polyethylene films with photophosphor additives // Fluorescence and accompanying phenomena. Transactions of the VIIth All-Russian workshop, November 13Ц18, 2001, Irkutsk, 2002.
9. Vasilyev R.B., Dirin D.N. Quantum dots: synthesis, properties, application. Moscow: FNM, 2007. 10. Adirovich E.M. Fluorescence and laws of spectrum transformation // Achievements of physical sciences// 1950, V. 4, #3, pp. 341Ц368.
11. Kondratyev K. Ya. Actinometry// Leningrad.: The hydrometeorological publishing house, 1965, 685 p.
12. Pavlov S.A., Maksimova E. Yu., Koryakin S.L., Sherstneva N.E., Antipov E.M. An evaluation of subpixel luminosity of a fluorescent video monitor based on quantum dots of CdSe/CdS/ZnS // Russian nanotechnologies, 2016, V. 11, #3Ц4, pp. 64Ц68.
13. Pavlov S.A., Krikushenko V.V., Antipov E.M., Voronets N.B. Maksimova E. Yu., Shersneva N.V., Koryakin S.L. Luminuos efficacy and efficiency of fluorescence of polymeric layers containing colloidal semiconductor phosphors based on quantum dots of CdSe/ CdS/ZnS // Optics and spectroscopy. 2015. V. 119, #2, pp. 133Ц137.
14. Antipov E.M., Koryakin S.L., Maksimova E. Yu., Pavlov S.A., Sherstneva N.E. Formation features of radiation chromaticity of CdSe/CdS/ ZnS quantum dots dispersions in multicomponent systems // Svetotekhnika, 2017, #4, pp. 31Ц34.
15. Antipov, E.M., Sergey L. Koryakin, S.L., Elena Yu. Maksimova, E.Y., Sergey A. Pavlov, S.A., Natalya E. Sherestnyova, N.E. Features of Forming CdSe/ CdS/ZnS Quantum Points Dispersion Radiation Chromaticity in Multicomponent Systems // Light & Engineering, 2017, Vol. 25, No. 3, pp. 244Ц249.
16. Sivkov S.I. Calculation methods of solar radiation characteristics// Leningrad: The hydrometeorological publishing house, 1968, 232 p.
17. Tooming H.G. Solar radiation and harvest formation Ц Leningrad: Gidrometeoizdat, 1977, 200 p.
18. Tooming H., Niylisk H. Transition coefficients from integral radiation to PAR under natural conditions // In: Photoactinometric studies of plant cover. Tallinn: Valgus, 1967, pp. 140Ц149.
19. Shain S.S., et. al. Light and plant development. Moscow: Selkhozizdat, 1963, 622 p.
20. Leman V.M. A course of plant photoculture. Moscow: Vysshaya Shkola, 1976, 271 p. 21. Pavlov S.A., Voronets N.B. Quantum points and harvest // ESU. Chemical sciences, 2014, #10, pp. 89Ц91.

1. Buckingham A.G., Watson H.M. Basic concepts of orbiting reflectors // Journal of Spacecraft. 1968, Vol. 5, No 7, pp.852Ц853.
2. Ehricke K.A. Space Light: Space Industrial Enhancement of the Solar Option // Acta Astronautica. 1979, Vol. 6, December, pp.1515Ц1633.
3. Canady J.E., Allen J.L. Illumination from Space with orbiting Solar-reflector Spacecraft. URL: https://ntrs. nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19820025545. pdf (Addressing date: 11.07.2017).
4. Early J.T. Space-Based solar Shield to offset Greenhouse effect // Journals of The British Interplanetary Society.1989, Vol. 42, pp.567Ц569.
5. Lukyanov A.V. A shielding disc in the light-gravitation balance point against Earth and planets overheat // Space studies. 1992, V. 30, Issue, pp.1127Ц135.
6. Angel R. Feasibility of cooling the Earth with a cloud of small spacecraft near the inner Lagrange point (L1) // Proceedings of the National Academy of Sciences 103, no. 46?17184Ц17189; doi: 10.1073/pnas.0608163103. URL: http://www.pnas.org/content/103/46/17184.full (Addressing date: 11.07.17)
7. Semyonov V. F., Sizentsev G.A., Sotnikov B.I., Sytin O.G. A system of orbital illumination of subpolar cities // News of the RAS. Power engineering. 2006, #1, pp. 21Ц30.
8. Raikunov G. G., Komkov V.A., Melnikov V.M., Harlov B.N. Centrifugal frameless large-size space structures. Moscow: Fizmatlit, 2009, 448 p.
9. Semyonov Yu. P., Branets V.N., Grigoriev Yu.I., Zelenshchikov N.I., Koshelev V.A., Melnikov V.M., Platonov V.N., Sevastyanov N.N., Syromyatnikov V.S. Space experiment on opening a film frameless reflector of D = 20 m (УZnamya-2Ф) // Space studies. 1994, V.32, Issue 4Ц5, pp.186Ц193.
10. Sizentsev G. A., Sotnikov B.I. A concept of space system of earth atmosphere thermal mode adjustment // Izvestiya of the RAS. Power engineering. 2009, #2, pp. 91Ц100.
11. Sizentsev G. A. A space system to solve power climate problems of Earth // Space equipment and technologies. 2013, #3, pp. 82Ц95.
12. Bogdanov K.A. Problems of movement control of a space vehicle with rotating solar sail: monograph / Editorship of S.N. Timakov. Korolyov: Energiya RKK, 2016, 116 p.
13. Starovoytov E.I. Evaluation of weakening the Sun radiation by a space system of adjusting temperature mode of earth atmosphere // Science and education (MSTU of N.E. Bauman). 2014, #7. Electronic scientific and technological publishing. DOI: 10.7463/0714.0719558. URL: http://technomag.edu.ru/jour/article/view/651/653 (Addressing date: 7/11/2017).
14. Barmasov A. V., Barmasova A.M., Yakovleva T. Yu. Biosphere and physical factors. Light environmental pollution // Proceedings of the Russian State Hydrometeorological University. 2014, #33, pp. 84Ц101.
15. Meyer L.A., Sullivan S.M.P. Bright lights, big city: influences of ecological light pollution on reciprocal streamЦriparian invertebrate fluxes // Ecological Applications. 2013, 23(6), pp. 1322Ц1330.
16. Yorzinski J.L., Chisholm S., Byerley S.D., Coy J.R., Aziz A., Wolf J.A., Gnerlich A.C. Artificial light pollution increases nocturnal vigilance in peahens // Yorzinski et al. (2015), PeerJ, DOI 10.7717/peerj.1174.
17. ffrench-Constant R.H., Somers-Yeates R., Bennie J., Economou T., Hodgson D., Spalding A., McGregor P.K. 2016. Light pollution is associated with earlier tree budburst across the United Kingdom. Proc. R. Soc. B283: 20160813. URL: http://dx.doi.org/10.1098/ rspb.2016.0813 (Addressing date: 7/11/2017).
18. Aladov A.V., Zakgeym A.L., Mizerov M.N., Chernyakov A.E. Concerning Biological Equivalent of Radiation of Light Emitting Diode and Lamp Light Sources with Correlated Colour Temperature of 1800 K-10000 K // Light & Engineering Journal, 2012, V.20, #3, pp.9Ц14, (Svetotekhnika, 2012, #3, pp. 7Ц10, Russian).
19. Kaptsov V. A., Sosunov N.N., Shishchenko I.I., Viktorov V.S., Tulushev V.N., Deynego V.N., Bukhareva E.A., Murashova M. A, Shishchenko A.A. Functional state of visual analyser when using traditional and LED light sources // Hygiene and sanitation. 2014, # 4, pp. 120Ц123.
20. Animal Spatial Cognition: Comparative, Neural & Computational Approaches. Edited and Published by Michael F. Brown and Robert G. Cook In cooperation with Comparative Cognition Press of the Comparative Cognition Society. November, 2006 / Bingman V., Jechura T., Kahn M.C. Behavioral and Neural Mechanisms of Homing and Migration in Birds. URL: http://www.pigeon. psy.tufts.edu/asc/Bingman/Default.htm (addressing date: 11.07.2017).
21. Dacke M., Baird E., Byrne M., Scholtz C.H., Warrant E.J. Dung Beetles Use the Milky Way for Orientation // Current Biology. 2013. DOI: 10.1016/j. cub.2012.12.034.
22. Panyushin S.K. Ultraviolet light as an operator of hormonal biorhythms // Electronic scientific and educational bulletin УHealth and education in the 21st centuryФ. 2012, V. 14, #10., pp. 289Ц291.URL: https://elibrary.ru/download/elibrary_21484245_44344308.pdf (Addressing date: 7/11/2017).
23. Cuba C.C.M., Ruhtz T., Fischer J., Holker F. Lunar Skylight Polarization Signal Polluted by Urban Lighting // Journal of Geophysical Research. 2011, Vol.116, D24106. DOI:10.1029/2011JD016698.
24. Starovoytov E. I., Poklad M.N. Problems of orbital earth surface illumination system implementation // Engineering journal: science and innovations. Electronic scientific and technical publishing. 2017, #5 (65). DOI: 10.18698/2308Ц6033Ц2017Ц5Ц1622. URL: http://engjournal.ru/articles/1622/1622.pdf (Addressing date: 7/11/2017).
25. Starovoytov E.I. Metallisation choice for reflectors of an earth surface orbital illumination space system // Trudy MAI Electronic journal. 2017, Issue 94, URL: http://trudy.mai.ru/upload/iblock/477/starovoytov_ rus.pdf (Addressing date: 7/11/2017).
26. Dinevich L., Kaplan L., Badakhova G., Kaplan G. Concerning the question of climate change // Modern science-intensive technologies. 2013, #2, pp. 60Ц63.
27. Starovoytov E.I. Evaluation of earth surface illuminance using a space reflector intended for stabilisation of atmosphere temperature mode // Engineering journal: science and innovations. Electronic scientific and technical publishing. 2017, #4 (64). DOI: 10.18698/2308Ц 6033Ц2017Ц4Ц1605. URL: http://engjournal.ru/articles/1605/1605.pdf (Addressing date: 7/11/2017).
28. Lior N. Mirrors in the sky: Status, sustainability, and some supporting materials experiments // Renewable and Sustainable Energy Reviews. 2013, Vol. 18, pp. 401Ц415.
29. Mukhamedzhanov M. Zh., Chekalin S.V. Prospectives of space isolation of especially dangerous waste of nuclear power engineering // Space and ecology. 1991, #7, pp. 42Ц55.
30. Lei Lan, Jingyang Li, Hexi Baoyin. Debris Engine: A Potential Thruster for Space Debris Removal. URL: https://arxiv.org/vc/arxiv/papers/1511/1511.07246v1.pdf (Addressing date: 11.07.2017).

1. Farahat A, Florea A, Lastra J L M, et al. Energy efficiency considerations for LED­based lighting of multipurpose outdoor environments. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2015. V3, #3, pp.599–608.
2. Leccese F. Remotecontrol system of high efficiency and intelligent street lighting using a ZigBee network of devices and sensors. IEEE transactions on power delivery, 2013. V28, #1, pp.21–28.
3. Xu, X., Xie, L., Li, H., & Qin, L. Learning the route choice behaviour of subway passengers from AFC data. Expert Systems with Applications, 2018. #95, pp. 324–332.
4. Basker D K, Cortes O A H, Brook M A, et al. 3D Nonlinear Inscription of Complex Microcomponents (3D NSCRIPT): Printing Functional Dielectric and Metallodielectric Polymer Structures with Nonlinear Waves of Blue LED Light. Advanced Materials Technologies, 2017. V2, #5, p.1600236.
5. Haiying Li, Xian Li, Xinyue Xu, Jun Liu, Bin Ran. Modeling departure time choice of metro passengers with a smart corrected mixed logit model – A case study in Beijing. Transport Policy. 2018, #69, pp.106–121.
6. Pimputkar S, Speck J S, DenBaars S P, et al. Prospects for LED lighting. Nature photonics, 2009. V3, #4, p. 180.
7. De Rossi F, Pontecorvo T, Brown T M. Characterization of photovoltaic devices for indoor light harvesting and customization of flexible dye solar cells to deliver superior efficiency under artificial lighting. Applied Energy, 2015. V156, pp.413–422.
8. Wang L, Wang X, Kohsei T, et al. Highly efficient narrowband green and red phosphors enabling wider colorgamut LED backlight for more brilliant displays. Optics Express, 2015. V23, #22, pp.28707–28717.

1. Chen J F., Hsieh H N., Do Q H. Evaluating teaching performance based on fuzzy AHP and comprehensive evaluation approach. Applied Soft Computing, 2015. V28, pp.100Ц108.
2. Zhang H., Sun X. Research on low carbon supply chain performance evaluation based on AHP and fuzzy comprehensive evaluation method. Journal of Shandong University of Technology (Natural Science Edition), 2016. V1, p.16.
3. Zhaoben F., Peijie Y., Ganlin P. Empirical research on credit risk management for electric power clients. Automation of Electric Power Systems, 2005. V1, p. 17.
4. Li X., Yang S., Zhang H. Research on assessment method for power supply service quality. Power System Technology, 2004. V12, p. 8.
5. Bentaleb, Fatimazahra., Charif Mabrouki., Alami Semma. УA multi-criteria approach for risk assessment of dry port≠seaport system.Ф Supply Chain Forum: An International Journal, 2015. V16, #4, pp.32Ц49.
6. Huanhuan, Wei., Lu Yuan. УEvaluation of auto dealers credit based on AHP and fuzzy comprehensive evaluation method.Ф Modern Manufacturing Engineering, 2017. V3, p. 4.
7. Zhang N., Tao Q. Engineering Project Risk Evaluation Based on Grades Fuzzy Comprehensive Evaluation. Construction Economy, 2009. pp.S1.
8. Zhengrong, Nie. УOn the Appraisal of Xincheng Tourism Resources Based on AHP≠Fuzzy Comprehensive Evaluation Method.Ф Journal of Tourism College of Zhejiang, 2016. V3, p. 6.

1. Gerloff T., Lindemann M., Shirokov S., Taddeo M., Pendsa S., and Sperling A. Development of a New High-Power LED Transfer Standard// Light & Engineering #2. 2013, pp.41–46.
2. Agafonov D.R., Sapritsky V.I., Stolyarevskaya R.I., and Tolstikh G.N. Luminous Intensity LED Working Gage// Light & Engineering, V.8, 2000, #2, pp.74–80.
3. Sildoja M. et al. Predictable Quantum Efficient Detector I. Photodiodes and predicted responsivity//Metrologia, 2013, V. 50, pp. 385–394.
4. Muller I. et al. Predictable Quantum Efficient Detector II. Characterization Results// Metrologia, 2013, 50, V.50, pp. 395–401.
5. Krueger, U. 2001. Technological aspect of the spectral correction adjustment of space-resolved radiation detectors. Light & Engineering, V.9; No.3, pp.61–71.
6. Wei?haar Jurgen P. Next Generation Goniophotometry// Light & Engineering, 2015, V.23, #4, pp.75–80.
7. URL: http://www.instrumentsystems.com. (дата обращения 24.01.2017)
8. Zwinkels J.C., Ikonen E., Fox N.P., Ulm G., and Rastello M.L., Photometry, radiometry and “the candela”: evolution in the classical and quantum world, Metrologia, 2010, 47, № 5, R15-R32.
9. Petsky B.W. The Atomic Units, the Kilogram and the Other Proposed Changes to the SI//, Metrologia, 2007, V44, #1, pp.69–72.
10. Mills Ian M., Mohr Peter J., Quinn Terry J., Taylor Barry N., and Williams Edwin R. Redefinition of the Kilogram, Ampere, Kelvin and Mole: A Proposed Approach to Implementing CIPM Recommendation 1 (CI-2005), Metrologia, 2006, V. 43, N3, pp.227–246.
11. Mills Ian M., Mohr Peter J., Quinn Terry J., Taylor Barry N., and Williams Edwin R. Redefinition of the Kilogram: A Decision Whose Time Has Come// Metrologia, 2005, V. 42, #2, pp.71–80.
12. BIPM SI Brochure, Appendix 2. “Mise en pratique for the definition of the candela and associated derived units for photometric and radiometric quantities in the International System of Units (SI)”, CCPR (BIPM), 2015.
13. BIPM SI Brochure: The International System of Units (SI), 8th edition, 2006; updated in 2014, Bureau International des Poids et Mesures, F-92310 Sevres, France.
14. CIE TN004:2016 The Use of Terms and Units in Photometry – Implementation of the CIE System for Mesopic Photometry.
15. CIE TN “ Interim Recommendation for Practical Application of the CIE System for Mesopic Photometry in Outdoor Lighting “. Enquiry Draft, 2017.
16. Kuzmin V.N. and Nikolaev S.E. Methods and Devices for Quick Evaluation of Optical Radiation Energy Efficiency// Light & Engineering. –2016. #4, pp. 103–104.
17. Khan T.K., Shpentyes N., Yeltse T. Proposals on evaluation of radiation being physiologically active for plants// Svetotekhnika.-2003. #1. – P. 40–41.
18. Fox N.P. Radiometry with cryogenic radiometers and semiconductor photodiodes. Metrologia, 1995, V.32, #6, pp. 535–544.
19. Gardner J.L. A Four-element Transmission Trap Detector// Metrologia, 1995, V.32, #6, pp. 411–418.
20. Sapritsky V.I. Black-body Radiometry. Metrologia, 19995, V.32, #6, pp.411–418.
21. Sapritsky V.I. and Stolyarevskaya R.I. Realization of the Lumen on the Basis of a Large-aperture High Temperature Black Body// Metrologia, 1995, V.32, #6, pp.455–458.
22. Klein R. Validation of the Probability Concentration Function for the Calculated Radiant Power of Synchrotron Radiation According to the Schwinger Formalism// Metrologia, 2016, V.53, #3, pp. 927–932.
23. Anevsky S.I., Zolotarevsky Yu. M., Krutikov V.N., Minayeva O.A., Minayev R.V., Senin D.S.. Development of spectroradiometry unit reproduction and transmission methods using synchrotron radiation // Measuring engineering, 2015, #3, p. 31–33.
24. Castelletto S., Godone A., Novero C. and Rastello M.L. Biphoton Fields for Quantum-efficiency Measurements// Metrologia, V. 32, #6, pp.501–504.
25. Gavrilov V.R., Dunayev A. Yu., Morozova S.P., Otryaskin D.A., Sapritsky V.I., Hlevnoi B.B.. State primary standard of absolute spectral sensitivity in wave length µinterval from 0.25 to 14.00 µ// Measuring engineering, 2015, #11, рp. 15–17.
26. CIE210: 2014 Photometry Using V(?)-corrected Detectors as Standard and Transfer Standards.
27. “Solid State Lighting Annex 2013 Interlaboratory Comparison Final Report”. 10.09.2014 //http://ssl.iea-4e.org/files/otherfiles/0000/0067/IC2013_Final_ Report_final_10.09.2014 a.pdf.
28. Bartsev A.A., Belyaev R.I., and Stolyarevskaya R.I. International Interlaboratory Comparison IC2013 Experience and Participation Results of the VNISI Testing Centre// Light & Engineering, 2015, V.23, #3, pp.55–64.
29. CIE S025/E:2015: Test Method for LED Lamps, LED Luminaires and LED Modules.
30. CIE S009 / E:2002 / IEC62471:2006 Photobiological Safety of Lamps and Lamp Systems.
31. Bartsev Alexei A, Belyaev Roman I., and Stolyarevskaya Raisa I. Methodology of LED Luminaire BLH Radiance Measurements// Light&Engineering, 2013, #1, pp.53–59.
32. CIE202:2011 Spectral Responsivity Measurement of Detectors, Radiometers, and Photometers.
33. ISO/CIE19476:2011(E) Characterisation of the Performance of Illuminance Meters and Luminance Meters.
34. CIE198:2011 Determination of Measurement Uncertainties in Photometry.
35. GOST P 8.332–78 SSEUM, Light measurements. Values of relative spectral luminous efficiency of monochromatic radiation for day time sight.
36. GOST P 8.023 SSEUM, State calibration circuit for measuring instruments of continuous and pulse radiation light values.
37. IESNA LM-78, 2007. “IESNA Approved Method for Total Luminous Flux Measurement of Lamps Using an Integrating Sphere Photometer”.
38. GOST P 8–195 SSEUM. State calibration circuit for measuring instruments of spectral concentration of radiance, spectral concentration of radiant intensity and spectral concentration of irradiance within wavelength interval from 0.25 to 25.00 µ; radiant intensity and irradiance within wavelength interval from 0.2 to 25.0 µ.
39. GOST P 8.850 SSEUM. Characteristic of luxmeters and luminance meters, 2013.
40. Kruger U., Ruggaber B., and Schmidt F. Spectral Properties of Imaging Luminance Measuring Devices Considering the Angular Dependence of the Spectral Transmission of Filters// Light & Engineering, 2012, #2, pp.72–77.
41.CIE Draft 2.55, NC2–59, WD03: Сharacterization of Imaging Luminance Measurement Devices (ILMDS).
42. СIE, TC2–62: Imaging-Photometer-Based Near-Field Goniophotometry, 2009, Draft WD00.
43. Budak V.P., Smirnov P.A.. A Ray of light in the Light Field Theory. Mathematical Simulation of Light Fields, Moscow, The Moscow Power Institute Publishing House, 2016.
44. ISO/IEC GUIDE98–4.
45. CIE121–1996. Photometry and Goniophotometry of Luminaires.
46. CIE13.3.:1995. Method of Measuring and Specifying Colour Rendering of Light Sources.
47. CIE15:2004. Colorimetry, 3rd Edition.
48. CIE TN001:2014.
49. CIE198:2011. Determination of Measurement Uncertainties in Photometry – Supplement1: Modules and Examples for the Determination of Measurement Uncertainties.

1. Ahn H A, Hong S K, Kwon O K. An Active Matrix MicroPixelated LED Display Driver for High Luminance Uniformity Using Resistance Mismatch Compensation Method. IEEE Transactions on Circuits and Systems II: Express Briefs, 2018. V65, #6, pp.724–728.
2. Chun J, Lee M. Developing a SEIL (Smart Enjoy Interact Light) bag utilizing LED display. International Journal of Clothing Science and Technology, 2016. V28, #2, pp.233–253.
3. Delabrida S, D’Angelo T, Oliveira R A R, et al. Wearable HUD for Ecological Field Research Applications. Mobile Networks and Applications, 2016. V21, #4, pp.677–687.
4. Bai Y, Welk G J, Nam Y H, et al. Comparison of consumer and research monitors under semistructured settings. Medicine & Science in Sports & Exercise, 2016. V48, #1, pp.151–158.
5. Ellis B J, Volk A A, Gonzalez J M, et al. The meaningful roles intervention: An evolutionary approach to reducing bullying and increasing prosocial behavior. Journal of research on adolescence, 2016. V26, #4, pp.622–637.
6. Roy R, Hebden L, Kelly B, et al. Description, measurement and evaluation of tertiaryeducation food environments. British Journal of Nutrition, 2016. V115, #9, pp.1598–1606.
7. Konstantinidis E I, Billis A S, Mouzakidis C A, et al. Design, implementation, and wide pilot deployment of FitForAll: an easy to use exergaming platform improving physical fitness and life quality of senior citizens. IEEE journal of biomedical and health informatics, 2016. V20, #1, pp.189–200.
8. Xu, X., Xie, L., Li, H., & Qin, L. Learning the route choice behavior of subway passengers from AFC data. Expert Systems with Applications, 2018. #95, pp. 324–332.

1. Zhang Y., Li B., Su X., et al. A Study of Schoolroom Lighting Fuzzy Control System. International Journal of Control and Automation, 2015. V8, #1, pp.189Ц196.
2. Morey M S., Virulkar V B., Dhomane G A. MRAS based Speed identification and online updating of rotor time constant for sensorless field oriented controlled induction motor. Emerging Trends in Electrical Electronics & Sustainable Energy Systems (ICETEESES), International Conference on. IEEE, 2016. pp.179Ц185.
3. Kirkby, J. L., Deng, S. "Static hedging and pricing of exotic options with payoff frames." Available at SSRN2501812, 2017.
4. Zumbrunn S., McKim C., Buhs E., et al. Support, belonging, motivation, and engagement in the college classroom: A mixed method study. Instructional Science, 2014. V42, #5, pp.661Ц684.
5. Biddix J P., Chung C J., Park H W. The hybrid shift: Evidencing a student-driven restructuring of the college classroom. Computers & Education, 2015. V80, pp.162Ц175.
6. Berry M J., Westfall A. Dial D for distraction: The making and breaking of cell phone policies in the college classroom. College Teaching, 2015. V63, #2, pp.62Ц71.
7. Georgieva D., Schledermann K M., Nielsen S M L., et al. Designing User Centred Intelligent Classroom Lighting. Interactivity, Game Creation, Design, Learning, and Innovation. Springer, Cham, 2017. pp.314Ц323.
8. Wei W., Tao Y., Baosen T., et al. Design of intelligent multifunctional LED lighting system. Microcomputer & Its Applications, 2016. V15, p. 31.

1. Zwinkels, L.C. CCPR Activities Related to LEDbased Calibration Standards // CIE Lighting Quality and Energy Efficiency Conference. Melbourne, Australia, 2016. https://www.researchgate.net/publication/298212170_CCPR_Activities_Related_to_LEDbased_Calibration_Standards
2. Blattner, P. CIE report to CCPR2016. https://www.bipm.org/cc/CCPR/Allowed/23/CCPR16_42_CIE_report_to_CCPR.pdf
3. Ohno, Y. et al. LED Sources in Photometry at NIST // Report to CCPR2016. https://www.bipm.org/cc/CCPR/Allowed/23/CCPR16_47_Y_Ohno_LED_sources_ in_photometry_at_NIST_for_CCPR_2016Ц11Ц07.pdf
4. Zama, T. NMIJ Research Activities relevant to LED Sources for Photometry // Report to CCPR2016. https://www1.bipm.org/cc/CCPR/Allowed/23/CCPR16_46_NMIJ_Activities_LED_soureces_Photometry.pdf
5. Gerloff, T., Lindemann, M., Shirokov, S., Taddeo, M., Pendsa, S., Sperling, A. Development of a new high-power LED transfer standard // CIE Proceedings 2012. https://www.researchgate.net/publication/293172050_Development_of_a_new_high-power_LED_transfer_standard.
6. Lindemann, M., Maass, M. Photometry and Colorimetry of Reference LEDs by Using a Compact Goniophotometer // MAPAN, Journal of Metrology Society of India, Vol. 24, No. 3.
7. CIE127; 2007 (2nd edition); Measurement of LEDs.
8. Reference book on lighting engineering. Under the editorship of Yu.B. Aysenberg. / Moscow: Znak, 2006, 972 p.
9. Tikhodeev P.M. Light measurements in the light engineering / Moscow-Leningrad: State energy publishing house, 1962, 464 p.

1. Kozacki T, Chlipala M, Makowski P L. Color Fourier orthoscopic holography with laser capture and an LED display. Optics express, 2018. V26, #9, pp.12144–12158.
2. Ahn H A, Hong S K, Kwon O K. An Active Matrix MicroPixelated LED Display Driver for High Luminance Uniformity Using Resistance Mismatch Compensation Method. IEEE Transactions on Circuits and Systems II: Express Briefs, 2018. V65, #6, pp.724–728.
3. Kim D S, Im S K, Shigeta T, et al. High resolution LED display using a new rendering method with color subpixel architecture. Electronic Imaging, 2016, #20, pp.1–4.
4. Xu, X., Xie, L., Li, H., & Qin, L. Learning the route choice behavior of subway passengers from AFC data. Expert Systems with Applications, 2018. #95, pp. 324–332.
5. Lv X, Loo K H, Lai Y M, et al. EnergySaving Driver Design for FullColor LargeArea LED Display Panel Systems. IEEE Trans. Industrial Electronics, 2014. V61, #9, pp.4665–4673.
6. Zhang K, Peng D, Lau K M, et al. 25‐5: Distinguished Student Paper: Fully‐Integrated Active Matrix Programmable UV and Blue Micro‐LED Display System‐on‐Panel (SoP). SID Symposium Digest of Technical Papers. 2017. V48, #1, pp.357–361.
7. Hong Y, Lee B, Byun J, et al. 19‐3: Invited Paper: Key Enabling Technology for Stretchable LED Display and Electronic System. SID Symposium Digest of Technical Papers. 2017. V48, #1, pp.253–256.
8. Ejzak G A, Dickason J, Marks J A, et al. 512$\ times $512, 100 Hz MidWave Infrared LED Microdisplay System. Journal of Display Technology, 2016. V12, #10, pp.1139–1144.

1. H. Pihlajaniemi, ТDesigning and experiencing adaptive lighting. Case studies with adaptation, interaction and participation,У Doctoral thesis, University of Oulu, Acta Universitatis Ouluensis, H3 Architectonica, 2016 [Online]. Available: http://jultika.oulu.fi/ Record/isbn978Р952Р62Р1090Р2.
2. H. Pihlajaniemi, E. Juntunen, A. Luusua, M. Tarkka?Salin and J. Juntunen, ТSenCity Р Piloting Intelligent Lighting and User-Oriented Services in Complex Smart City Environments,У in Proceedings of eCAADe 2016, pp. 669Р680.
3. V. Vili?nas, et al. ТSubjective evaluation of luminance distribution for intelligent outdoor lighting,У Lighting Research & Technology, 2014, 46(4), pp. 421Р433.
4. A. Haans and Y. A. de Kort, ТLight distribution in dynamic street lighting: Two experimental studies on its effects on perceived safety, prospect, concealment, and escape,У Journal of Environmental Psychology, 2012, 32(4), pp. 342Р352.
5. D. Casciani, ТUrban social lighting. Exploring the social dimension of urban lighting for more sustainable urban nightscapes,У Doctoral dissertation. Politecnico di Milano, Dipartimento di design, 2014.
6. E.S. Poulsen, A. Morrison, H.J. Andersen and O.B. Jensen, ТResponsive lighting: the city becomes alive, Т in Proceedings of the 15th international conference on Human-computer interaction with mobile devices and services 2013, ACM, pp. 217Р226.
7. S. Seitinger, ТLiberated pixels: alternative narratives for lighting future cities,У Doctoral dissertation, MIT, 2010.
8. A. Wiethoff and S. Gehring, ТDesigning interaction with media fasades: a case study,У in Proceedings of the Designing Interactive Systems Conference 2012. ACM, pp. 308Р317.
9. J. Fritsch & M. Brynskov, ТBetween experience, affect, and information: Experimental urban interfaces in the climate change debate,У in From Social Butterfly to Engaged Citizen: Urban Informatics, Social Media, Ubiquitous Computing, and Mobile Technology to Support Citizen Engagement, M. Foth, L. Forlano, C. Satchell and M. Gibbs, Eds. The MIT Press, 2011, pp. 115Р134.
10. A. Luusua, H. Pihlajaniemi, J. Ylipulli, ТNorthern Urban Lights: Emplaced Experiences of Urban Lighting as Digital Augmentation,У in Architecture and Interaction, N. Dalton, H. Schnsdelbach, M. Wiberg and T. Varoudis, Eds. HumanРComputer Interaction Series, Springer, Cham, 2016, pp. 275Р 297 [Online]. Available: https://link.springer.com/ chapter/10.1007/978Р3Р319Р30028Р3_13.
11. H. Pihlajaniemi, A. Luusua, M. Teiril?, T. ?sterlund and T. Tanska, ТExperiencing participatory and communicative urban lighting through LightStories,У in Proceedings of the 4th Media Architecture Biennale Conference 2014: Participation, ACM, pp. 65Р74.
12. H. Pihlajaniemi, A. Luusua, E.?M. Sarjanoja, R. V??r?niemi, E. Juntunen and S. Kourunen, ТSenCity City Monitor as a platform for user involvement, innovation and service development,У in Proceedings of eCAADe 2017, in press.13.
13. H. Pihlajaniemi, S. Huuskonen, L? Anh H. and E. Juntunen, ТSmart Lighting for Urban Experiences Р Engaging Users for Better Services,У in Proceedings of PLDC6th Professional Lighting Design Convention 2017, in press. 14. A. Luusua, J. Ylipulli, M. Jurmu, H. Pihlajaniemi, P. Markkanen and T. Ojala, ТEvaluation probes,У in Proceedings SIGCHI Conference on Human Factors in Computing Systems 2015, New York, NY, USA, ACM Press.
15. W. Gaver, T. Dunne and E. Pacenti, (1999) ТCultural probes,У Interactions, 1999, 6(1), pp. 21Р29.

Light Emitting Diodes (LEDs) are fast replacing incandescent lamps and CFLs in most of the developing nations. The reason can be attributed mainly to the enhanced lifetime and less energy consumption as compared to the other mentioned types. However one important aspect needs attention, the impact of driver on LEDs. LEDs are current controlled devices and hence emit maximum light with increase in current input to the device. This feature, boost up the light output but it increases the junction temperature of the device. Hence additional heat sinks are required to vent out the excessive heat generated due to increase current input to the LEDs. Those additional heat sinks are at times difficult to accommodate. So, designers have made arrangements to vent out the heat from the device. This is achieved by designing fins. However this arrangement is not suitable in places where the ambient temperature is more than normal. Thus, design of LED driver with controlled current input is essential in order to maintain the thermal limit of the device. Secondly, the AC-DC LEDs driver circuits, which are available in the market, are seldom equipped with input power factor and THD improvement circuitry as prescribed in IEC61000– 3–2. This is essential for maintaining the energy efficiency of the nearest utility services and in addition also improves on the current drawn by the device. The following work envisages these issues and proposes corrective driver circuit based on two different driver topologies, buck-boost topology and flyback topology. Both these topologies are proposed in order to address the aspects of power quality and its impact on the life of the device. The simulation were done using Green Point simulation tool from On Semiconductors.

1. Liu Yu, Jinmin Yang, “The topologies of white LED lamps’ power drivers,”3rd IEEE Conference on Power Electronics Systems and Applications (PESA), 2009, 20th –22nd May 2009, Hong Kong, pp.1–6.
2. Huang-Jen Chiu et. al., “A High Efficiency dimmable LED driver for low power lighting applications,” IEEE Transactions on Industrial Electronics, Vol. 57, # 2, February 2010, pp.735–743.
3. D. Aguilar, C.P. Henze, “LED driver circuit with inherent PFC,” Twenty-Fifth IEEE Annual Conference on Applied Power Electronics and Exposition (APEC) 2010, 21st –25th February 2010, Palm Springs, CA, pp.605–610.
4. Tzuen-Lih Chern et. al., “Design of LED driver circuits with single stage PFC in CCM and DCM,” 6th IEEE Conference on Industrial Electronics and Applications (ICIEA) 2011, 21st-23rd June 2011, Beijing, pp.2358–2363.
5. Hu Yuequan, L. Huber, M.M. Jovanovic, “Single Stage, Universal Input AC/DC LED driver with current controlled variable PFC boost inductor,” IEEE Transactions on Power Electronics, Vol. 27, # 3, March 2012, pp. 1579–1588.
6. Ashis Srivastava, Bhim Singh, “Improved Power Quality based high brightness LED lamp driver,” International journal of Engineering, Science and Technology, Vol.4, # 1, March 2012, pp.135–141.
7. Chun-An Cheng et. al., “A single stage LED driver for street lighting applications with interleaving PFC feature,” IEEE International Symposium on Next Generation Electronics (ISNE) 2013, 25th –26th February 2013, Kaoshiung, pp.150–152.
8. N. Narendran, J.D. Bullough, N. Maliyagoda and A. Bierman, “What is the useful life for white LEDs?” Journal Illuminating Engineering Society, 2001, Vvol. 30, # 1, pp. 57–67.
9. N. Narendran and Y. Gu, “Life of LED based white light sources”, IEEE / OSA Journal of display technology, 2005, Vol.1, #.1, pp. 167–171.
10. A. Jayawardena, Yi-Wei Liu, N. Narendran, “Methods for estimating the junction temperature of AC LEDs”, Council for Optical Radiation Measurements (CORM) 2012 Annual Technical Conference Ottawa, Ontario, 29 May – 1 June 2012.
11. IEC-61000–3–2, “Electromagnetic compatibility Part 3–2: Limits-Limits for harmonic current emissions”, International Electrotechnical Commission, May 2014.
12. G. Meneghesso, S. Levada, R. Pierobon, F. Rampazzo, E. Zanoni, A. Cavallini, A. Castaldini, G. Scamarcio, S. Du, and I. Eliashevich, “Degradation mechanisms of GaN-based LEDs after accelerated DC current aging,” in IEDM Tech. Dig., 2005, pp. 103–106.
13. L. Trevisanello, M. Meneghini, G. Mura, M. Vanzi, M. Pavesi, G. Meneghesso, and E. Zanoni, “Accelerated life test on high brightness Light Emitting Diode”, IEEE Transactions on Device and Materials Reliability, 2008, Vol. 8, # 2, pp. 304–311.
14. E.Hong, N. Narendran, “A method of projecting useful life of LED lighting systems”, Third International Conference on Solid State Lighting, Proceedings of Photo-Optical Instrumentation Engineers, SPIE:5187, 2004, pp. 93–99.
15. C. H. Chen, W.L. Tsai, M.Y. Tsai, “Thermal resistance and reliability of low cost and high power LED packages under WHTOL test”, Electronics materials and packaging, EMAP2008, Taipei, 22–24 Oct., 2008., pp.271–276.
16. G. Farkas, Q. Van Voorst Vader, A. Poppe, and G. Bogna, “Thermal investigation of high power optical devices by transient testing,” IEEE Transaction Components Packaging Technology, 2005, Vol. 28, # 1, pp. 45–50.
17. Sujit Golder, Kalyan Kumar Ray, Saswati Mazumdar, “High Efficient DC to DC Boost Converter for White LED Based Lighting system”, “Lighting & Engineering”, 2006, Vol.14, #1, pp 53–59.