Joint Use of Mechatronic Systems to Organize Effective Counteraction to the Coordinated Action of Enemy Torpedoes

The article proposes an approach to the organization of counteraction to the probable enemy on the basis of the joint use of mechatronic devices using the phenomenon of electric explosion to counteract homing systems and solving a group control task in order to protect the target from defeat. The above class of tasks involves the use by the attacked of mechatronic devices that play the role of mobile defenders, in the quality of which can act as a self-propelled source of interference, distracting the attacking object (missile or torpedo) by intercepting it, and a shock RTK aimed at destroying a dangerous object. A characteristic feature of the considered tasks is the incompleteness of a priori information about the distance to the attacking object and the possibility of instant use of active means. It is shown that the presence of even only a second defender is advisable, since it significantly increases the interception time compared to the case of only one defender. Also, an additional defender increases the probability of choosing one of the defenders for the intermediate pursuit instead of the main target. Under the conditions set in the considered models for starting positions, speeds and power reserve, in the case of a real torpedo attack on defenders, when following the constructed schemes for the release of defenders, the torpedo will not have enough fuel to defeat the main target. The methods of interference formation based on electric explosion are considered. It is proposed to use mechatronic hydroacoustic counteraction devices capable of moving in an aquatic environment and creating broadband interference of a given intensity as such sources. A model example of the use of mechatronic devices in a given scenario is considered.

1. Military Doctrine of the Russian Federation (approved by the President of the Russian Federation on December 25, 2014 N Pr-2976) (in Russian).

2. Anichkina T. B., Esin V. I. Strategic nuclear weapons of the Russian Federation, Russia and America in the XXI century, 2015, no. 1, pp. 1 (in Russian).

3. Savin L. V. Network-centric and network warfare. Introduction to the concept , Moscow, Eurasian Movement, 2011, 130 p. (in Russian).

4. Zhemchuzhin E. F., Silnikov M. V. Torpedo weapon guidance systems of the US Navy, Issues of defense technology, 2020, vol. 16, no. 9—10, pp. 88—93 (in Russian).

5. Kislov F. The main trends in the development of torpedo weapons of the Navy of NATO countries, Foreign Military Review, 2002, no. 7, pp. 46—52 (in Russian).

6. Lutskoy A. On anti-torpedo protection of Russian submarines, available at: topwar.ru (date of access December 10, 2013) (in Russian).

7. Klimov M. About the appearance of modern torpedoes of submarines, Arsenal of the Fatherland, 2015, no. 1 (15) (in Russian).

8. Building up the means of "underwater warfare", Militaryindustrial courier, 30.01.2012 (in Russian).

9. AN/SQR-19 Hydroacoustic complex, Military weapons and armies of the world, available at: http://warfor.me (in Russian).

10. Klimov M. Marine underwater weapons: problems and opportunities, Military-industrial courier, part I. 06.06.2011; part II. 09.06.2010 (in Russian).

11. Stepanov A. The main directions of the use of artificial intelligence in the armed forces of leading foreign countries, Foreign Military Review, 2021, no. 1, pp. 30—35 (in Russian).

12. Lavrentiev E. V., Kuzyan O. I. Explosions at sea, Leningrad, Shipbuilding, 1977, 157 p.

13. Yutkin L. A. Electrohydraulic effect and its application in industry, Leningrad, Mechanical Engineering, 1986, 253 p.

14. Kalyaev I. A. Dognat’ i peregnat’. O gonke superkomp’terov v mire, Nauchnaya Rossiya. available at: Scientificrussia.ru (date of access 03 may 2021) (in Russian).

15. Small-sized anti-submarine complex "Package -E/NK" with an anti-torpedo, available at: http://bastion-karpenko.ru/paket/

16. Small-sized thermal anti-submarine torpedo MM / torpedo is a component of the Package complex, available at: http:// militaryrussia.ru/blog/topic-482.html.

17. Galyaev A. A, Lysenko P. V, Yakhno V. P. 2D Optimal Trajectory Planning Problem in Threat Environment for UUV with Non-Uniform Radiation Pattern, Sensors, 2021, vol. 21, iss. 2, p. 396.

18. Palumbo N. F., Blauwkamp R. A., Lloyd J. M. Modern Homing Missile Guidance Theory and Techniques, HOMING MISSILE GUIDANCE AND CONTROL, 2010, vol. 29, p. 1.

19. Rubinovich E. Ya. Two Targets Pursuit-Evasion Differential Game with a Restriction on the Targets Turning, IFACPapersOnLine, 2018, pp. 503—508.

20. Rubinovich E. Ya. Missile-Target-Defender Problem with Incomplete a priori Information, Dynamic Games and Applications, 2019, vol. 9, pp. 851—857.

21. Eloy G., Casbeer D. W., Pachter M. Active Target Defense Differential Game with a Fast Defender, IET Control Theory and Applications, 2017, vol. 17, no. 11, pp. 2985—2993.

22. Galyaev A. A, Lysenko P. V., Rubinovich E. Y. Optimal Stochastic Control in the Interception Problem of a Randomly Tacking Vehicle, Mathematics, 2021, no. 9(19), p. 2386.

23. Buzikov M. E., Galyaev A. A. Minimum-time lateral interception of a moving target by a Dubins car, Automatica, 2022, vol. 135, p. 109968.