УДК: 28.835.042.3
Hyperspectrometer for the 900–1700 nm near-infrared region
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Publication in Journal of Optical Technology
Виноградов А.Н., Егоров В.В., Калинин А.П., Родионов А.И., Родионов И.Д. Гиперспектрометр ближнего инфракрасного диапазона 900–1700 нм // Оптический журнал. 2017. Т. 84. № 10. С. 42–47.
Vinogradov A.N., Egorov V.V., Kalinin A.P., Rodionov A.I., Rodionov I.D. Hyperspectrometer for the 900–1700 nm near-infrared region [in Russian] // Opticheskii Zhurnal. 2017. V. 84. № 10. P. 42–47.
A. N. Vinogradov, V. V. Egorov, A. P. Kalinin, A. I. Rodionov, and I. D. Rodionov, "Hyperspectrometer for the 900–1700 nm near-infrared region," Journal of Optical Technology. 84(10), 683-687 (2017). https://doi.org/10.1364/JOT.84.000683
We describe a short-wavelength infrared (900–1700 nm) hyperspectrometer for a variety of pure and applied research applications involving the environment, remote Earth sensing, agricultural/forest monitoring, etc. This spectrometer can be used in the laboratory, in ground-based applications, and from aircraft. Laboratory and flight testing of the hyperspectrometer confirmed that the basic engineering design solutions used were valid and enabled us to assess the specifications and functionality of the spectrometer.
hyperspectrometer, near-infrared region, image, spectrum, monitoring, condition, resolution, ecology
OCIS codes: 280.0280, 110.4234
References:1. A. Ishimaru, Wave Propagation and Scattering in Random Media, Vol. 1 (Academic, New York, 1980; Mir, Moscow, 1980).
2. G. A. Avanesov and N. I. Snetkova, “Problems of aerospace spectrometry of the Earth’s surface,” Issled. Zemli Kosmosa (2), 66–75 (1980).
3. S. A. Arkhipov, A. Yu. Lyakhov, and A. P. Tarasov, “Experimental research on hyperspectral remote-sensing at the OAO S. A. Zverev Krasnogorsk Plant,” in Abstracts of Papers from the Scientific and Engineering Conference on Hyperspectral Instruments and Technologies (KONTENANT, Krasnogorsk, 2013), pp. 25–30 [available (in Russian) from http://www.contenant.ru/1electron_mag/tezis/yan2013.pdf].
4. G. G. Gorbunov, V. B. Zharnikov, K. N. Chikov, and V. B. Shlishevskii, “Hyper- and ultra-video spectroscopy in remote sensing,” Izv. Vyssh. Uchebn. Zaved. Geod. Aerofotos’emka (5), 188–198 (2015).
5. I. D. Rodionov, A. I. Rodionov, L. A. Vedeshin, A. N. Vinogradov, V. V. Egorov, and A. P. Kalinin, “Airborne hyperspectral systems for solving remote sensing problems,” Izv. Acad. Sci. USSR Atmos. Oceanic Phys. 50(9), 983–1003 (2014) [Issled. Zemli Kosmosa (6), 81–93 (2013)].
6. A. N. Vinogradov, V. V. Egorov, A. P. Kalinin, A. I. Rodionov, and I. D. Rodionov, “A line of aviation hyperspectrometers in the UV, visible, and near-IR ranges,” J. Opt. Technol. 83(4) 237–243 (2016) [Opt. Zh. 83(4), 54–62 (2016)].
7. G. J. Zissis, ed., Sources of Radiation, Vol. 1, The Infrared and Electro-Optical Systems Handbook (SPIE, Bellingham, Washington, 1993).
8. R. N. Clark, G. A. Swayze, R. Wise, K. E. Livo, T. M. Hoefen, R. F. Kokaly, and S. J. Sutley, “USGS Digital Spectral Library splib06a,” U.S. Geological Survey Digital Data Series 231, 2007.