Abstract
This article, based on a paper heard at a meeting of the RAS Presidium, analyzes the main problems of and trends in the intellectualization of state-of-the-art aviation complexes. The obtaining and intelligent processing of heterogeneous information, intelligent management, and aircraft “self-sensing,” as well as intelligent interaction within the pilot–aircraft contour, are highlighted as key functional objectives for the foreseeable future. The primary focus is made on the intelligent processing of measuring and video information, including the automatic mutual referencing and uniting of measuring and geospatial information into a visual complex; continuous provision of an accurate, authentic, and holistic image of the surroundings to the crew, regardless of weather and time conditions; recognition and prediction of dangerous combinations of factors considering the flight path; assessment of the crew’s psychophysiological condition; changes in the external environment and technical condition of the aircraft; and recommendations for the crew to escape or prevent abnormal situations.
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E. A. Fedosov, G. A. Chuyanov, V. V. Kos’yanchuk, and N. I. Sel’vesyuk, “Prospective concepts and design technologies for aircraft onboard equipment complexes,” Polet, No. 8, 41–52 (2013).
G. A. Chuyanov, V. V. Kos’yanchuk, and N. I. Sel’-vesyuk, “Problematic issues of developing a military aircraft onboard equipment technology,” Vooruzh. Ekon., No. 4, 42–48 (2013).
E. A. Fedosov, “21 century aviation,” Aviats. Sistemy, No. 5, 6–9 (2016).
E. A. Fedosov, “High accuracy weapons: 21 century weapons,” Aviats. Sistemy, No. 5, 9–13 (2016).
S. Yu. Zheltov, V. V. Kos’yanchuk, and N. I. Sel’-vesyuk, “Prospects for intellectualization of state-ofthe-art aviation complexes,” Aviats. Sistemy, No. 5, 38–45 (2016).
E. Yu. Zybin, V. V. Kos’yanchuk, and N. I. Sel’vesyuk, “Electrification and intellectualization: The main trend in the development of the aircraft energy complex,” Aviats. Sistemy, No. 5, 45–51 (2016).
E. A. Fedosov, “The Russian project of a new-generation integrated modular open-architecture avionics: Status and Prospects,” Fazotron, Nos. 1–2, 22–26 (2011).
G. A. Chuyanov, V. V. Kos’yanchuk, and N. I. Sel’-vesyuk, “Prospects for the development of onboard equipment complexes based on integrated modular avionics,” Izv. YuFU. Tekh. Nauki, No. 3, 55–62 (2013).
G. A. Chuyanov, V. V. Kosyanchuk, N. I. Selvesyuk, and E. Y. Zybin, “Advanced avionics equipment on the basis of second generation integrated modular avionics,” in 29th Congress of the International Council of the Aeronautical Sciences. ICAS 2014 CD-ROM Proceedings (2014).
E. A. Fedosov, “The project of new-generation openarchitecture integrated modular avionics,” Aviats. Sistemy, No. 5, 24–29 (2016).
E. Yu. Zybin and V. V. Kos’yanchuk, “Evolution of the architecture of aircraft onboard equipment complex,” in Aviation Systems in the 21st Century: A Collection of Paper Abstracts (Gos. Nauchno-Issled. Inst. Aviats. Sistem, Moscow, 2016), p. 198 [in Russian].
S. Yu. Zheltov and Yu. V. Vizil’ter, “Prospects for intellectualizing control systems (using computer vision technology),” Proceedings of the Moscow Physicotechnical Institute 1 (4), 164–181 (2009) [in Russian].
Yu. V. Vizil’ter and S. Yu. Zheltov, “Problems of technical vision in state-of-the-art aviation systems,” Mekh., Upr. Inform., No. 6, 11–44 (2011).
S. Yu. Zheltov, O. V. Vygolov, and Yu. V. Vizil’ter, “Aviation systems of enhances and synthetic vision of cockpit external environment,” Polet, No. 1, 33–39 (2013).
S. Yu. Zheltov, Yu. V. Vizil’ter, and O. V. Vygolov, “The development of an enhanced and synthetic vision system on the platform of integrated modular avionics,” Aviats. Sistemy, No. 5, 29–38 (2016).
S. Yu. Zheltov and B. E. Fedunov, “Intellectualization of the aircraft system-forming core,” in XII All-Russia Conference on VSPU-2014 Control Problems (Institut Problem Upravleniya im. V.A. Trapeznikova RAN, Moscow, 2014), pp. 3867–3875 [in Russian].
G. A. Chuyanov, V. V. Kos’yanchuk, N. I. Sel’vesyuk, and S. V. Kravchenko, “Vectors of improving onboard equipment to increase the safety of aircraft flights,” Izv. YuFU. Tekh. Nauki, No. 6, 219–229 (2014).
L. V. Vishnyakova, “Computer simulation software for aviation systems and problems solved using it,” in Aviation Systems in the 21st Century: A Collection of Paper Abstracts (Gos. Nauchno-Issled. Inst. Aviats. Sistem, Moscow, 2016), pp. 10–11 [in Russian].
L. V. Vishnyakova, V. Yu. Sikachev, and A. S. Popov, “Simulating an Air Traffic System,” in All-Russia Scientific and Practical Conference “Simulation Modeling: Theory and Practice”: Conference Proceedings, Ed. by S. N. Vasil’ev and R. M. Yusupov (Inst. Probl. Upr. im. V.A. Trapeznikova RAN, Moscow, 2015), pp. 23–24 [in Russian].
E. A. Fedosov, V. V. Kos’yanchuk, and N. I. Sel’vesyuk, “Integrated modular avionics,” Radioelektron. Tekhnol., No. 1, 66–71 (2015).
M. A. Bomer, S. V. Dvoretskii, O. V. Sokolov, and E. G. Chuyanova, “Assessing the fault-tolerance of systems with possible structure reconfiguration,” Tr. Gos-NIIAS. Ser.: Vopr. Avioniki, No. 2, 37–48 (2015).
V. V. Kos’yanchuk, S. V. Konstantinov, T. A. Kolodyazhnaya, et al., “The perspective concept of fault-tolerant digital systems to control maneuverable aircraft,” Polet, No. 2, 20–27(2010).
E. Yu. Zybin and V. V. Kos’yanchuk, “Analytical synthesis of MIMO fault-tolerant control systems with simplified circuit implementation,” J. Comput. Syst. Sci. Int. 49 (1), 105–114 (2010).
E. Yu. Zybin, V. V. Kos’yanchuk, and A. M. Kul’chak, “Analytical solution of the problem of optimal reconfiguration of an aircraft control system as several controls fail,” Mekhatronika, Avtomatizatsiya, Upravlenie, No. 7, 59–66 (2014).
E. Yu. Zybin, V. V. Kos’yanchuk, N. I. Sel’vesyuk, et al., “Robust-to-flight-mode-changes aircraft control reconfiguration as drivers fail,” Nauch. Chteniya Aviats., Posvyashch. Pamyati N.E. Zhukovskogo, No. 2, 331–336 (2014).
V. V. Kosyanchuk, N. I. Selvesyuk, and A. M. Kulchak, “Aircraft control law reconfiguration,” Aviation 19 (1), 14–18 (2015).
O. S. Titkov, “Promising trends in the design of onboard sensor devices,” Aviats. Sist., No. 1, 20–23 (2017).
A. N. Udodov, “Analysis of possibilities to build energy-efficient wireless sensor networks to monitor engine operation,” Tr. MAI, No. 74, p. 19 (2014).
S. Yu. Zheltov, Automatic Identification in Supply Chain Control (Mashinostroenie, Moscow, 2010) [in Russian].
S. Yu. Zheltov, Yu. I. Buryak, and M. P. Lyubovnikov, “Developing methodological solutions for a complex of software–hardware tools that help monitor continuously the operation of promising aviation equipment samples,” Izv. Samar. Nauch. Tsentra RAN 16 (1–5), 1385–1393 (2014).
B. E. Fedunov, “21st-century technologies to improve the crew’s situational awareness,” Aviats. Sist., No. 9, 23–27 (2013).
V. V. Galushkin, D. I. Katkov, V. V. Kos’yanchuk, and N. I. Sel’vesyuk, “The through technology of designing promising aircraft onboard equipment complexes,” Izv. YuFU. Tekh. Nauki, No. 3, 201–209 (2012).
S. Yu. Zheltov, A. M. Zherebin, and V. A. Popov, “Systems analysis and external design of aviation complexes as the main research stage in creating aviation equipment,” Polet, No. 8, 65–71 (2013).
S. Yu. Zheltov, “Technologies of tuning in aircraft onboard equipment and air-to-surface weapons,” Tr. GosNIIAS. Ser.: Vopr. Avioniki, No. 4, 3–20 (2016).
S. Yu. Zheltov, “The present state of and prospects for the development of aviation complex simulation technologies,” in Aviation Systems in the 21st Century: A Collection of Paper Abstracts (Gos. Nauch.-Issled. Inst. Aviats. Sist., Moscow, 2016), pp. 3–4 [in Russian].
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Original Russian Text © S.Yu. Zheltov, V.V. Kos’yanchuk, 2018, published in Vestnik Rossiiskoi Akademii Nauk, 2018, Vol. 88, No. 2, pp. 107–117.
RAS Academician Sergei Yur’evich Zheltov is Director General of the State Scientific Research Institute of Aviation Systems (GosNIIAS). Vladislav Viktorovich Kos’yanchuk, Dr. Sci. (Eng.), is a Deputy Director General of GosNIIAS.
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Zheltov, S.Y., Kos’yanchuk, V.V. Prospects for the Intellectualization of State-of-the-Art Aviation Systems. Her. Russ. Acad. Sci. 88, 28–36 (2018). https://doi.org/10.1134/S1019331618010136
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DOI: https://doi.org/10.1134/S1019331618010136