The Features of the National School of Radar Space Control Systems

Authors

  • Yu.M. Lavrich Transmag Institute of Transport Systems and Technologies, the NAS of Ukraine
  • B.B. Netak Transmag Institute of Transport Systems and Technologies, the NAS of Ukraine
  • S.V. Plaksin Transmag Institute of Transport Systems and Technologies, the NAS of Ukraine
  • D.V. Pyaskovsky Transmag Institute of Transport Systems and Technologies, the NAS of Ukraine

DOI:

https://doi.org/10.15407/scine15.02.074

Keywords:

Chief Designer design documentation, open architecture, radar, space control

Abstract

Introduction. Ukraine has a space monitoring system implemented based on the Dnieper radar that provides continuous space monitoring.
Problem Statement. Radars of this type are large complicated high-tech engineering systems. The novelty of applied R&D solutions, long terms of radar station design and manufacture unable applying the existing development and production standards and, therefore, require creating new ones.
Purpose. The purpose is to analyze and to summarize the features of development and manufacture of space control systems based on national radar facilities.
Materials and Methods. The systematic analysis of the peculiarities of the Ukrainian school of radar control systems for outer space has been applied using the R&D and the Chief Designer tools for more effectively solving specific problems related to creating new generations of radar stations.
Results. It has been shown that in order to realize the information received by the existing radar, it is necessary to ensure its competitiveness in the growing market of such services, which is possible through both upgrading the existing facilities and developing new ones. Taking into consideration the specific features that inevitably manifest themselves at different stages of the radar life cycle, the sufficient R&D groundwork and the experience of creating radars of both the current and the future generations, a number of proposals on effective solution of problems concerning the space monitoring with radar facilities have been presented.
Conclusions. To ensure the integration and to supply domestic science-intensive radars to international structures for monitoring outer space (MOS) is impossible unless the existing R&D groundwork is effectively used and the capacity of existing facilities is permanently built up, taking into account the MOS radar specific features. The outlined peculiarities of possible problems and ways of their effective solution can be useful to designers of complex high-tech systems.

References

Andreev, F. M. Statkus, A. V. (2013). Analysis of the possibility of using the analytical approximation to estimate the second and third derivative of the range. Systemy obrobky informatsiyi (Information processing systems), 7 (114), 171-176 [in Russian].

Andreev, F. M., Kovbasyuk, S. V. (2009). Possibilities of a multiposition complex created on the basis of national radar systems for the above-horizon detection of ballistic and space objects. Kosmichna nauka i tekhnolohiya (Space science and technology), 15(5), 74-81 [in Russian].

https://doi.org/10.15407/knit2009.05.074

Drobakhin, O. O., Plaksin, S. V., Ryabchii, V. D., Saltykov, D. Yu. (2013). Technology and Semiconductor Microwave Electronics. Sevastopol: Weber [in Russian].

Plaksin, S. V., Sokolovsky, I. I. (2006). Physical basis for the construction of high-speed information-control systems based on semiconductor elements with hot electrons. Sevastopol: Weber [in Russian].

Lavrich, Yu. N. (2018). Features of scientific support for the creation of promising samples of radio electronic equipment. Nauka innov., 1, 15-25 [in Russian].

https://doi.org/10.15407/scin14.01.015

Danilin, N., Belosludtsev, S. (2007). Problems of applying the modern element base of foreign production in rocket and space technology. Modern electronics, 7, 8–12 [in Russian].

Nicholas J. Willis, Hugh D. Griffiths (2007). Advances in bistatic radar. New York: SciTech Publishing.

Lazarevich, E. G., Semak, Sh. B., Amzeev, E. G., Lazarevich, Yu. I. (2013). Virtual electronic component base of radio electronic equipment. System analysis and applied informatics, 1–2, 39–47 [in Russian].

Lavrich, Yu. N. (2015, May). Features of the thermal regime for powerful radio transmission systems. Proceedings of the 16th Intern. scientific-practical. conf. «Modern informational and electronic technologies», Odessa [in Russian].

Lavrich, Yu. N., Plaksin, S. V., Pogorelaya, L. M. (2017, November). Features of designing systems for ensuring the thermal regime of REA in microelectronic design. Proceedings of the 2nd All-Ukr. scientific-practical. conf. «Perspective tendencies in the electronics, informational and computer systems», Dnepr [in Russian].

Lavrich, Yu. N. (2012, June). Features of monitoring the reliability of the control system for high-speed ground transportation. Proceedings of the 1st Intern. scientific-practical. сonf. «Modern informational and electronic technologies», Odessa [in Russian].

INTERNATIONAL STANDARD (2011) ISO/IEC/IEEE 42010:2011(E)(E) Systems and software engineering — Architecture description

Downloads

Published

2024-09-04

How to Cite

Lavrich, Y., Netak, B., Plaksin, S., & Pyaskovsky, D. (2024). The Features of the National School of Radar Space Control Systems. Science and Innovation, 15(2), 74–82. https://doi.org/10.15407/scine15.02.074

Issue

Section

The World of Innovation