Active-Passive System of Safe Nap-of-the-Earth Piloting
Control Systems of Moving Objects
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Abstract
The problem of the synthesis, analysis, and information support of a semiautomatic aircraft control system during a nap-of-the-earth (NOE) flight is solved. It is assumed that laser-ranging (LR), television (TV), and thermal imaging (TI) methods are used to remotely sense the underlying surface (US). The algorithm for integrated information processing and displaying images is proposed. The control system is synthesized, the parameters are optimized, and the real-time simulation is carried out using the full-scale registration of LR and TV images of industrial-urban scenes with forestpark zones. It is proved that the system can ensure safe piloting at an altitude of less than 10 m over a difficult terrain at flight velocities of 200 to 400 km/h.
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References
- 1.D. C. Foyl, A. J. Ahumada, J. Larimer, and B. T. Sweet, “Enhanced/synthetic vision systems: human factors research and implications for future systems,” J. Aerospace 101, 1734–1741 (2007).Google Scholar
- 2.S. I. Babaev and M. B. Nikiforov, “Joint processing of information from aircraft vision systems,” Vestn. RGRTU, No. 1 (1), 14–18 (2012).Google Scholar
- 3.V. M. Lisitsyn, K. V. Obrosov, and G. G. Sebryakov, “Using of laser locators in perspective information systems of aircrafts,” in Lasers in the Science, Engineering, Medicine, Collection of Articles, Ed. by V. A. Petrov and A. S. Popov (MNTORES im. A. S. Popova, Moscow, 2010), Vol. 21, pp. 16–20 [in Russian].Google Scholar
- 4.V. N. Danovskii, V. Ya. Kim, V. M. Lisitsyn, K. V. Obrosov, and S. V. Tikhonova, “Information support of lowaltitude flight safety,” J. Comput. Syst. Sci. Int. 46, 651 (2007).CrossRefMATHGoogle Scholar
- 5.K. R. Schulz, S. Scherbarth, and U. Fabry, “Hellas: obstacle warning system for helicopters,” in Laser Radar Technology and Applications VII, Proc. SPIE 4723, 1–8 (2002).CrossRefGoogle Scholar
- 6.V. M. Lisitsyn, K. V. Obrosov, and V. Ya. Kim, “Visualization principles of laser-locational information in aircraft information systems,” in Lasers in the Science, Engineering, Medicine, Collection of Articles, Ed. by V. A. Petrov and A. S. Popov (MNTORES im. A. S. Popova, Moscow, 2011), Vol. 22, pp. 32–37 [in Russian].Google Scholar
- 7.S. M. Muzhichek, K. V. Obrosov, V. Ya. Kim, et al., “Determining the direction of flight by signals of the forward looking optoelectronic system,” Vestn. Komp’yut. Inform. Tekhnol., No. 5, 8–14 (2013).Google Scholar
- 8.S. M. Muzhichek, K. V. Obrosov, V. M. Lisitsyn, et al., “Method of measuring course of the aircraft,” RF Patent No. 2556286, Byull. Izobret. No. 19 (2015).Google Scholar
- 9.M. N. Krasil’shchikov, D. A. Kozorez, and K. I. Sypalov, “Functional-software prototype of the integrated onboard system of a prospective unmanned helicopter in low-altitude flight mode,” in Proceedings of the 15th SPb. International Conference on Integrated Navigation Systems, St. Petersburg, 2008.Google Scholar
- 10.Navigation and Guidance of Unmanned Maneuverable Flying Vehicles Based on Modern Information Technologies, Ed. by M. N. Krasil’shchikov and G. G. Sebryakov (Fizmatlit, Moscow, 2003) [in Russian].Google Scholar
- 11.A. P. Batenko, Control of Moving Object Finite State (Sov. Radio, Moscow, 1977) [in Russian].MATHGoogle Scholar
- 12.P. D. Krut’ko, Inverse Problems of Control System Dynamics: Nonlinear Models (Fizmatlit, Moscow, 1988) [in Russian].MATHGoogle Scholar
- 13.V. M. Lisitsyn and V. Ya. Kim, “Active-passive multispectral remote sensing complex,” in Lasers in the Science, Engineering, Medicine, Collection of Articles, Ed. by V. A. Petrov and A. S. Popov (MNTORES im. A. S. Popova, Moscow, 2012), Vol. 23, pp. 16–21 [in Russian].Google Scholar
- 14.A. S. Mirzoyan, I. M. Khmarov, N. G. Kondrashov, and S. V. Shakhov, “Methods for selecting terrestrial objects against the background of the underlying surface in the on-board 3D laser channel,” Vestn. MAI 20 (4), 118–127 (2013).Google Scholar
- 15.I. N. Beloglazov, S. N. Kazarin, and V. V. Kos’yanchuk, Information Processing in Iconic Systems of Navigation, Guidance and Remote Sensing of the Terrain (Fizmatlit, Moscow, 2012) [in Russian].Google Scholar
- 16.S. M. Muzhichek, K. V. Obrosov, V. Ya. Kim, et al., “Laser locator action range in information support mode of low-altitude flight,” Vestn. Komp’yut. Inform. Tekhnol., No. 2, 3–10 (2017).Google Scholar
- 17.S. M. Muzhichek, K. V. Obrosov, V. Ya. Kim, et al., “Dependence of laser locator range on atmosphere state in information support mode of low-altitude flight,” in Transmission, Reception, Processing and Display of Fast Processes Information, Proc. of the 27th All-Russia School-Seminar (Akad. im. N. E. Zhukovskogo, Moscow, 2016), pp. 310–316.Google Scholar
- 18.S. M. Muzhichek, V. Ya. Kim, V. M. Lisitsyn, and K. V. Obrosov, “An experimental estimate of the dependence of wires detection probability by a laser locator on the scanning angular rate of laser beam pattern,” in Lasers in the Science, Engineering, Medicine, Collection of Articles, Ed. by V. A. Petrov and A. S. Popov (MNTORES im. A. S. Popova, Moscow, 2016), Vol. 27, pp. 72–76 [in Russian].Google Scholar
- 19.V. M. Lisitsyn, “Evaluation of the efficiency of a complex optical-electronic flight system during low-altitude flight,” in Lasers in the Science, Engineering, Medicine, Collection of Articles, Ed. by V. A. Petrov and A. S. Popov (MNTORES im. A. S. Popova, Moscow, 2014), Vol. 25, pp. 16–21 [in Russian].Google Scholar
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