1 - 2024 (21)
DOI: https://doi.org/10.37129/2313-7509.2024.21.209-218
DATA CALCULATION METHODOLOGY FOR PRECISE DELIVERY OF SMALL LOADS USING UAV LANDING ON UNCONTROLLED SYMMETRICAL AEROSPRING SYSTEMS
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S. Hatsenko1 |
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S. Mordvinov1 |
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V. Heorhiiev2 |
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О. Ivanov1 |
https://orcid.org/0000-0003-0878-7939 |
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M. Adamenko1 |
https://orcid.org/0000-0002-1345-8833 |
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1National University of Defense of Ukraine 2Odesa Military Academy |
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Abstract
The development of modern technologies in the field of unmanned aviation determines the development of new forms and methods of their application. Trends in the automation of war initiate the development of new forms and methods of conducting combat operations. At the same time, the use of manned aircraft (especially in the conditions of a limited number of units and a limit of flight resource) to provide special tasks (not striking) is generally considered not rational. However, the importance and necessity of their implementation does not decrease. In the article, a preliminary analysis of the areas of application of unmanned aerial vehicles and justification of the expansion of the spectrum of their application is carried out.In order to implement the specified task, the article considers the method of calculating data for accurate delivery (point landing) of small and ultra-small loads of various purposes on unguided symmetrical parachutes. The possibility of using the technique can be applied to other aircraft as well. Calculations of the probability accuracy of cargo delivery were carried out under the condition of partial (full) automation of the landing process, taking into account external factors and admissible variables (such as the combat course (magnetic), speed, drop height, parachute system insertion height, payload weight). The given technique will make it possible to: acquire new capabilities with unmanned aerial vehicles of various classes, use them to perform specific tasks. In turn, the acquisition of these capabilities by unmanned systems, which take over part of the functions of aviation units, undoubtedly lead to strengthening and increasing the combat potential of units equipped with these systems. The multifunctionality of unmanned systems can become the component that will enable the acquisition of asymmetric potential.
Keywords: delivery, landing, unmanned aerial vehicles, symmetrical aeroelastic systems.
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The article was submitted 04.04.2024.
S. Hatsenko, S. Mordvinov, V. Heorhiiev, О. Ivanov, M. Adamenko ©
Creative Commons Attribution 4.0 International License (CC BY 4.0)