A.S. Zakharov1, V.V. Shamanov2, V.Yu. Pozdyushev3, K.S. Sokolov4, A.Yu. Perlov5

1 Lomonosov Moscow State University (Moscow, Russia)

2 MIPT (Moscow, Russia)

3 STC SC Concern VKO “Almaz-Antey” (Moscow, Russia)

4 JSC “Scientific and Production Association of Long-range Radar named after A.L. Mints” (Moscow, Russia)

5 Military Training Center of Moscow State University named after M.V. Lomonosov (Moscow, Russia)

1 zakharov.as17@physics.msu.ru; 2 shamanovvitalii@gmail.com; 3 laperlov@yandex.ru; 5 pozvalerij@yandex.ru

The article presents a hypothesis about the possibility of reducing the risks of suboptimal choice of technical solutions when creating promising intelligence and information complexes (RICS), which is an urgent task both in the development of a space monitoring radar station (MCP radar) and in the creation of electronic warfare (EW).

It is shown that when formalizing the RIC design process in the form of multiparametric optimization of parameters based on the ontological analysis of technical solutions, which ensures the formation of an optimal list of technical solutions while maximizing functional characteristics and minimizing cost.

A three-dimensional matrix of functional characteristics values is compiled during design, taking into account the set values of cost and production time for each technical solution with its own unification coefficient. Using this matrix allows you to choose the optimal technical solution of the radar, taking into account the coefficient of unification and the quality of the element base - such a matrix is compiled for each technical solution.

The main advantage of the proposed optimization is the ability to evaluate an unlimited number of radar layout options and assess the risks of a suboptimal choice for each technical solution.

Zakharov A.S., Shamanov V.V., Pozdyshev V.Yu., Sokolov К.С., Perlov A.Yu. Parametric optimization of the process of engineering a space monitoring radar based on an ontological analysis of functional characteristics for various technical solutions. Radiotekhnika. 2024. V. 88.
№ 10. P. 110−117. DOI: https://doi.org/10.18127/j00338486-202410-12 (In Russian)

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