UA65854A - Method for protecting anti-aircraft rocket complexes from anti-radar rockets - Google Patents

Abstract

A method for protecting anti-aircraft rocket complexes from anti-radar rockets in which one detects the anti-radar rocket, follows the anti-radar rocket in automated mode or tracking, with performing pre-start operations, determining the instant of the anti-radar rocket entrance to the zone of the anti-aircraft rocket complex launch; and at the end stage, at the anti-radar rocker entering to the launch zone, one performs firing on it by the anti-aircraft rocket complex. Main point of the method is in the fact that first one determines through the tracking data additional information on the trajectory of movement of the anti-radar rocket, with implementation of operation on calculation, from the data of information on the trajectory, of the coordinates of the end point of the anti-radar rocket motion; one adjusts in time the coordinates of the anti-radar rocket motion, adjusts the coordinates of the end point of the anti-radar rocket motion, switches on the transmitter of the radar station of the anti-aircraft radar complex, with switching the radar station of the anti-aircraft complex to passive mode of operation; the rocket is followed in passive mode of operation of the radar station of the anti-aircraft radar complex at place angle and the radius only till the anti-radar rocket enters the zone of the anti-aircraft radar station launch; the entrance of the anti-radar rocket to the zone of the anti-aircraft radar station launch is controlled, and at entrance of the anti-radar rocket to the launch zone one performs its firing by the anti-aircraft rocket complex. This invention improves protection of functionally linked means of tracking and fire hitting of air targets of anti-aircraft rocket complexes in case those are attacked by antiradar rockets.

Description

The invention relates to the field of armaments and military equipment, in particular, to methods of protection of functionally connected means of support and fire damage to air targets of anti-aircraft missile systems, the use of which increases the probability of not hitting these means when anti-radar missiles are used by an aerial enemy, namely, to methods protection of anti-aircraft missile systems from anti-radar missiles.

There is a known method of protecting anti-aircraft missile systems from anti-radar missiles, in which the radio transmitters of the air target tracking radar stations of functionally connected means of support and fire damage to air targets of anti-aircraft missile systems are turned off for a specified time /17.

Disabling the radio radiation of radar stations leads to an increase in targeting errors of anti-radar missiles when the stations operate in radio silence mode.

The disadvantages of the known method of protecting anti-aircraft missile systems from anti-radar missiles include the fact that the use of the method does not allow to ensure the required level of protection of functionally connected means of support and fire damage to air targets of anti-aircraft missile systems when they work in autonomous mode against anti-radar missiles. This is explained by the fact that the guidance system of modern anti-radar missiles includes an inertial system, the presence of which allows the missile to be guided in the event of the disappearance of the radio signal from the radar station according to the memorized coordinates, with minimal errors (2-495 from the traveled path). In addition, there is a tendency to use anti-radar missiles with a passive-active guidance head in the future, which practically makes it impractical to use a passive method of protection /2/.

The closest technical solution, both in essence and in terms of the result to be achieved, which was chosen as a prototype, is a method of protecting anti-aircraft missile systems from anti-radar missiles, in which an anti-radar missile is detected, the anti-radar missile is accompanied in automatic tracking mode, pre-launch operations determine the moment entry of an anti-radar missile into the launch zone of an anti-radar missile complex, and at the final stage, when an anti-radar missile enters the launch zone, the said anti-radar missile is fired with an anti-radar missile complex /Z/.

The disadvantages of the well-known method of protecting anti-aircraft missile systems from anti-radar missiles, which is chosen as a prototype, are the low probability of not hitting functionally connected means of support and fire damage to air targets of anti-aircraft missile systems attacked by anti-radar missiles (air targets with a small effective reflective surface) when using it, which is Ru -(0.25-0.5).

The invention is based on the task, by eliminating the shortcomings of the prototype, to ensure an increase in the probability of non-damage of functionally connected means of support and fire damage to air targets of anti-aircraft missile systems in the event of their attack by anti-radar missiles.

The essence of the invention is a method of protecting anti-aircraft missile systems from anti-radar missiles, in which an anti-radar missile is detected, the anti-radar missile is accompanied in automatic escort mode, pre-launch operations are performed, the moment of entry of the anti-radar missile into the launch zone of the anti-radar missile system is determined, and at the final stage when the anti-radar missile enters in the launch zone, the mentioned anti-radar missile is fired with an anti-aircraft missile system, consists in determining additional information on the anti-radar missile flight trajectory from the escort data, performing operations to calculate the coordinates of the end point of the anti-radar missile flight from the trajectory information, specifying the flight coordinates of the anti-radar missile by time missiles, specify the coordinates of the end point of the flight of the anti-radar missile, turn off the transmitter of the radar station of the anti-aircraft radar complex and transfer the radar well, the station of the anti-aircraft radar complex is in passive mode of operation, they accompany the radar station of the anti-aircraft radar complex in the passive mode of operation only along the angle of the site and along the radius to the entrance of the anti-radar missile into the launch zone of the anti-aircraft radar complex, control the entrance of the anti-radar missile into the launch zone of the anti-aircraft radar complex, and when an anti-radar missile enters the launch zone, the mentioned anti-radar missile is fired with an anti-aircraft missile system. The essence of the invention is that the anti-radar missile is fired with an anti-aircraft missile system if the coordinates of the end point of the anti-radar missile's flight coincide with the coordinates of the anti-aircraft missile system on the ground.

A comparative analysis of the technical solution with the prototype shows that the proposed method of protecting anti-aircraft missile systems from anti-radar missiles differs in that additional information on the flight path of the anti-radar missile is determined from the tracking data, and operations are performed to calculate the coordinates of the end point of the anti-radar missile flight from the trajectory information missiles, specify the coordinates of the flight of the anti-radar missile in time, specify the coordinates of the end point of the flight of the anti-radar missile, turn off the transmitter of the radar station of the anti-aircraft radar complex and switch the radar station of the anti-aircraft radar complex to the passive mode of operation, accompany the radar station of the anti-aircraft radar complex only in the passive mode of operation place and along the radius to the entrance of the anti-radar missile into the launch zone of the anti-aircraft radar complex, control the entry of the anti-radar missile into the launch zone of the anti-aircraft radar complex, and when an anti-radar missile enters the launch zone, the said anti-radar missile is fired with an anti-aircraft missile system, while the anti-radar missile is fired with an anti-aircraft missile system if the coordinates of the end point of the anti-radar missile flight coincide with the coordinates of the anti-aircraft missile system on the ground.

Thus, the method of protecting anti-aircraft missile systems from anti-radar missiles, which is claimed, meets the criterion of the invention "novelty".

The essence of the invention is explained with the help of illustrations, where Fig. 1 shows a structural diagram of the implementation of the method of protection of functionally connected means of support and fire damage to air targets of anti-aircraft missile systems from anti-radar missiles, which is claimed, Figs. 2-5 show the stages of implementation of the method protection of these means of anti-aircraft missile systems from anti-radar missiles, which is declared.

The proposed method of protecting anti-aircraft missile systems from anti-radar missiles is carried out as follows.

Anti-aircraft missile system 1 is pre-placed in a combat position. Turn on the complex and use the radar stations of 2 anti-aircraft missile systems to scan the airspace. With the help of the mentioned radar station 2 of the anti-aircraft missile complex, an anti-radar missile 3 is detected. When an anti-radar missile C is detected, it is accompanied in the automatic escort mode.

Automatic tracking of anti-radar missile Z is carried out based on the results of measurement by radar station 2 of its complete vector of coordinates (range, rate of change of range, azimuth, elevation angle).

At the same time, they provide support for the trajectory of the Z anti-radar missile (in its individual sections) with the necessary accuracy in the space of the incomplete vector of measurements of the radar station 2 coordinates of the Z anti-radar missile (azimuth, elevation angle). Escort, with the accuracy necessary for the further firing of an air target (position 3) by anti-aircraft guided missiles 4, is impossible without information about the range О to the anti-radar missile 3. The solution to this problem requires the search for additional trajectory information about the movement of the missile (position 3) of the air adversary, as which is proposed to use the coordinates of the end point of the flight of the anti-radar missile 3. Obtaining this information can be carried out when using the decisive rule about the attack by an anti-radar missile From this radar station 2, built on the basis of the likelihood ratio criterion /4/. Supplementing the algorithmic apparatus of on-board digital computer systems of radar stations of functionally connected means of escorting and fire damage to air targets of anti-aircraft missile systems with modified algorithms for filtering the parameters of the trajectories of air targets, taking into account additional trajectory information about the movement of an anti-radar missile (coordinates of the end point of the missile's flight) , allows you to determine additional information about the flight path of an anti-radar missile based on tracking data. Operations to calculate the coordinates of the end point of the anti-radar missile flight /5/, /6/ from the data of the trajectory information are performed sequentially.

Further, during the course of tracking the target (anti-radar missile 3), the flight coordinates of the anti-radar missile 3 are specified. After that, the transmitter of the radar station 2 of the anti-aircraft missile complex 1 is turned off and the station is switched to passive mode of operation. Having performed the specified operations, in the passive mode of operation of the radar station 2 of the anti-aircraft missile complex 1, the anti-radar missile Z is accompanied only by azimuth and elevation to the entrance of the anti-radar missile Z into the launch zone of the anti-aircraft missile complex 1. Knowing the tactical and technical characteristics of the anti-aircraft missile complex

They control the entrance of anti-radar missile Z to the launch zone of anti-aircraft missile complex 1. On the approach of anti-radar missile Z to the launch zone of anti-aircraft missile complex 1, pre-launch operations are performed. At the same time, the moment of entry of the Z anti-radar missile into the launch zone of the anti-aircraft missile complex 1 is determined.

At the final stage, namely, when the Z anti-radar missile enters the launch zone, the Z anti-radar missile is fired with anti-aircraft guided missiles 4 of the anti-aircraft missile complex 1.

Attacking anti-radar missiles With anti-aircraft guided missiles 4 of the anti-aircraft missile complex 1 when using an active method of protection is carried out when the radar station 2 accompanying air targets receives constantly complete radar information about its coordinates (range to the target, rate of change of the range to the target, azimuth of the target, angle of the target location ).

The solution to the technical problem for the implementation of the proposed method of protecting anti-aircraft missile systems from anti-radar missiles is really possible by ensuring the tracking of the trajectory of the anti-radar missile in its individual sections, with the necessary accuracy in the space of the incomplete vector of measurements of the radar station coordinates of the missile (azimuth, bearing) using passive means radar station (television optical sights, or thermal imagers). Achieving the necessary accuracy of tracking the trajectory of an anti-radar missile in the conditions of incomplete trajectory information about it (at short time intervals) is carried out by using additional information about the coordinates of the final point of the missile's flight in the algorithmic apparatus of on-board computer systems of radar stations. The method of protecting anti-aircraft missile systems from anti-radar missiles, which is claimed, is implemented by performing sequential actions (ensuring the sequence of the following phases of the combat process): radar detection of an anti-radar missile, automatic tracking of an anti-radar missile based on the results of measurement by a radar station of the full vector of its coordinates (range, speed changes in range, azimuth, angle of elevation), determination of additional trajectory information about the coordinates of the end point of the missile flight, clarification of its coordinates due to the use of additional trajectory information, disconnection of the radio transmitter and further tracking of the anti-radar missile only by angular coordinates (azimuth, angle of elevation) by passive means of the station , solving pre-launch tasks, launching an anti-aircraft guided missile of an anti-aircraft missile complex to defeat an anti-radar missile when it enters the launch zone of the complex.

When applying the method of protecting anti-aircraft missile systems from anti-radar missiles, two hypotheses of non-destruction of the weapon sample under consideration are possible:

No - the weapon sample is not affected if the anti-radar missile is not hit by the warhead of the anti-aircraft guided missile;

No" - the weapon sample is not affected in the event of defeat of an anti-radar missile by the warhead of an anti-aircraft guided missile.

Therefore, it is legitimate to use the expression (1) obtained on the basis of the full probability formula /4/ as a criterion for assessing the effectiveness of the security of the sample of weapons under consideration;

Rnui«Rnuzh (1-RU; X1-Rug), (1) where: Ru; - conditional probability of hitting the |th anti-radar missile by an anti-aircraft guided missile when using an active protection method;

Ru:- conditional probability of damage to the i-th radar station when using a passive method of protection.

The increase in the effectiveness of the protection of anti-aircraft missile systems against anti-radar missiles, which is claimed, in comparison with the prototype, is achieved by the fact that technological operations have been introduced into it, which make it possible to increase the probability of not hitting functionally connected means of support and fire damage to air targets of anti-aircraft missile systems, which are attacked by anti-radar missiles.

SOURCES

1. Klyshevych M.Ya., Reshtanenko Yu.Ch., Solonnikov V.G. Principles of building anti-aircraft complexes:

Tutorial. Kyiv: ed. Air Defense Forces of the SV. 1987. 387p. -analog. 2. Initial data on the characteristics and tactics of using the enemy's anti-radar missiles (for the period 1981-1995). - Kalinin, 1985. - bbs. 3. Manual for studying the rules of firing at anti-aircraft missile systems of the air defense forces of the Soviet Union. Part 6. SAM ""BUK" - MI1 BUK"): - M.: Voennoie izdatelstvo, 1988, pp. 122-148 - prototype. 4. Druzhynin V. A. Recognition of the trajectory of the PRR, which carry a threat of radar. Proceedings of the Academy. Collection of scientific papers Me17. Inv. 6610 - Kyiv. National Academy of Defense of Ukraine, 1999. pp. 50-52. 5. Druzhynin, V. A. Evaluation of the parameters of the trajectory of the missile attacking the radar, based on the results of the measurement of the angular coordinates of the missile by the station. Proceedings of the Academy . Collection of scientific papers Me16. Inv. 36457. - Kyiv. National Academy of Defense of Ukraine, 1999. p. 67-70. 6. Druzhynin, V. A., Vysikan, O. O. Passive-active method of defense of air defense missile defense systems from PRR. Collection scientific papers

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Claims (2)

1. The method of protecting anti-radar missile systems from anti-radar missiles, in which an anti-radar missile is detected, the anti-radar missile is accompanied in the automatic escort mode, pre-launch operations are performed, the moment of the anti-radar missile’s entry into the anti-radar missile complex’s launch zone is determined, and at the final stage when the anti-radar missile enters the the launch zone is bombarded with an anti-radar missile complex, which is distinguished by the fact that additional information on the anti-radar missile flight trajectory is determined from the escort data, operations are performed to calculate the coordinates of the end point of the anti-radar missile flight from the trajectory information, the coordinates of the anti-radar missile flight are specified by time, coordinates of the end point of the flight of the anti-radar missile, turn off the transmitter of the radar station of the anti-aircraft radar complex and transfer the radar station of the anti-aircraft radar complex to the passive mode of operation, accompany the missile in the passive mode of operation of the radar station of the anti-aircraft radar complex only along the angle of the site and along the radius to the entrance of the anti-radar missile into the launch zone of the anti-aircraft radar complex, monitor the entrance of the anti-radar missile into the launch zone of the anti-aircraft radar complex, and at the entrance of the anti-radar rockets to the launch zone are bombarded with an anti-aircraft missile complex. 2. The method of protecting anti-radar missile systems from anti-radar missiles according to claim 1, which differs in that the anti-radar missile is fired with an anti-radar missile system in the event that the coordinates of the end point of the anti-radar missile flight coincide with the coordinates of the anti-radar missile system on the ground.