RU2553407C1 - Adaptive method of object protection against laser operated missile - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: according to the adaptive method of object protection against laser operated missile a missile laser signal is detected. Coordinates of the source of such radiation are identified. The interfering laser is oriented using these coordinates. The missile control laser signals reflected by its body are detected. Their power gradient is determined and compared with the pre-set threshold. An interfering signal of the pulse-frequency interfering laser is formed by change of its frequency to the value exceeding the pre-set value of the threshold by the gradient of power of laser control signals reflected by the rocket body.

EFFECT: high efficiency of object protection of against laser-operated missiles.

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Description

The invention relates to military equipment, namely to the protection of military equipment from high-precision weapons (WTO), and can be used in systems for protecting objects from the WTO with laser-beam telecontrol systems (laser-beam guidance systems (LLSN) missiles), which are currently finding increasing application. The main objects of protection are objects of armored vehicles.

The principle of operation of the WTO with laser-beam telecontrol systems is to form a missile control field with modulated, in particular, laser radiation, receive control radiation (on-board photodetector) of the missile of this radiation and convert it into electrical signals for issuing missile control commands. After launch, the rocket “shoots” into the control field (modulated laser beam or raster formed as a result of scanning the beam in the rocket control field) and flies to the target in this beam (raster).

Significant interest in laser-beam telecontrol systems, also called LLSN, is associated with their high noise immunity. The main measures to ensure high noise immunity of the VLBF are:

placement of a photodetector (FPU) for receiving and processing control signals on a rocket;

orientation of the FPU field of view in the direction of the laser radiation source of the telecontrol system;

use of a laser line to transmit missile control commands;

the use of spectral selection of missile control signals due to the use of narrow-band filters in the FPU with a bandwidth of several tens of angstroms;

the use of temporary gating missile control signals,

remembering the coordinates of the target before the start of remote control and predicting the trajectory of the target, including the masked one.

The method of protecting objects from guided missiles using an aerosol curtain is widely known, which consists in detecting laser radiation from the illumination of the protected object with a laser beam, determining the direction to the laser light source, shooting the aerosol ammunition in this direction and creating an aerosol curtain masking the protected object [see, for example , proceedings of the 8th All-Russian Scientific and Practical Conference “Actual Problems of Protection and Security”. - T.3. - 2005. - St. Petersburg. - S. 108-112].

The disadvantage of this method is the low efficiency of protecting the object from guided missiles with laser beam telecontrol systems because of the ability to remember the coordinates of the target before the telecontrol and predicting the trajectory of its movement, even if the target is masked with an aerosol curtain. In addition, the use of this protection method reduces the maneuverability of the protected object.

A known method of protecting objects from guided missiles [see RF patent No. 2129288 dated 04/20/1999, according to the application No. 97115874 dated 09/17/1997]. The method consists in detecting laser radiation, determining the coordinates of the source of this radiation, orienting the pulse-frequency jamming laser in the direction of the laser source, and emitting jamming laser pulses in this direction. For the effective influence of interference on the LLSN, the interfering radiation of a frequency-pulse laser reflected from the elements of the forming optics of the laser-beam telecontrol system should reach the input of the onboard FPU of the rocket at the moments of formation of temporary gates and exceed the threshold sensitivity of this device. Compliance with these conditions will lead to the appearance of spurious missile control signals and, as a consequence, to its deviation from the aiming line. In this case, the number of false rocket control pulses during its flight to the target is determined by the frequencies and durations of the strobe and jamming pulses.

The disadvantage of this method is the low efficiency of protecting the object from guided missiles with laser beam guidance systems due to the mismatch of the moments of arrival of jamming pulses with the moments of formation of the signal pulses of the missile control (time gates of the onboard photodetector device (FPU) of the rocket).

Closest to the proposed method (prototype) in technical essence and the achieved positive effect is a method of protecting an object from a guided missile [see RF patent No. 2320949 dated 05/18/2008 according to the application No. 2006117131 dated 06/18/2006]. This method consists in detecting the laser radiation of the VLBF, determining the coordinates of the source of this radiation, preliminary measuring the repetition frequency of the signal pulses of rocket control, orienting the frequency-pulse jamming laser in the direction of the laser radiation source and emitting interference pulses in this direction at a repetition frequency equal to or a multiple of sending signal pulses of rocket control, and the power of the jamming pulses exceeds the threshold sensitivity of the onboard FPU ra chum.

The effectiveness of the application of this method, based on the destruction of information using laser imitating interference in automatic laser-beam telecontrol systems, is largely determined by the accuracy of tuning the temporal parameters of the interference (repetition frequency of interfering pulses and the duration of their radiation).

The disadvantage of the prototype is the low efficiency of protecting an object from a guided missile with a laser-beam guidance system in the event of even a slight change in the repetition rate of signal pulses of rocket control during its flight to the target. So, for example, when the frequency detuning between the signal pulses of the rocket control and the interfering pulses of the frequency-pulse interfering laser is more than ± 200 ... 300 Hz, the effect of the interference is significantly reduced due to the increased influence of the selectivity of the reception of pulses due to the temporary gating of the signals in the laser beam guidance system [see, for example, the journal “Bulletin of the Voronezh State Technical University”. - 2009. - T. 5. - No. 5. - S. 172-175].

The technical result of the proposed method is to increase the efficiency of object protection due to adaptive control of the repetition frequency of interfering pulses of a frequency-pulse laser (CHIL).

The technical result is achieved due to the fact that in the known method of protecting an object from a guided missile, which consists in detecting the radiation of a laser missile control signal, determining the coordinates of the source of this radiation, orienting the pulse-frequency jamming laser in the direction of the laser radiation source, generating a jamming laser signal and radiation it in the direction of the laser radiation source, in addition to the emission of interfering pulses of a pulse-frequency interfering laser The laser missile control signals reflected by its body are determined, the power gradient of these signals is determined, it is compared with a predetermined threshold, and then an interfering signal of a pulse-frequency jamming laser is generated by changing its radiation frequency in such a way as to ensure that the predetermined threshold is exceeded by the power gradient reflected by the rocket body laser control signals.

The essence of the invention lies in the adaptive control of the repetition frequency of interfering pulses depending on the power level of the laser signals reflected by the missile body, by means of which the missile is aimed at the target. At the same time, although the unknown temporal characteristics of the radiation of the telecontrol system are not directly determined, the choice of interference parameters is provided that is best coordinated with these characteristics according to the effect of the interference on the VLF.

A comparative analysis of the claimed technical solution with the prototype shows that the proposed method differs from the known one by the presence of, firstly, new actions on the signal (additionally, laser control signals reflected by the missile body are detected and their power is measured) and, secondly, new conditions for performing actions ( control the frequency of the repetition of interfering pulses of the NRM depending on the degree of change in the power of the laser control signals reflected by the missile body in such a way as to provide a given miss x rockets).

Thus, the use of the features of part of the operations performed on the signals in the known method, accounting for information about the power of the laser control signals reflected by the missile body in accordance with the proposed new actions and the conditions for their implementation, allow us to conclude that there are significant differences of the proposed method. These actions provide an increase in the efficiency of protecting the object from laser-guided missiles due to adaptive control of the repetition frequency of interfering pulses of a pulse-frequency laser.

The proposed method can be implemented, for example, using the device shown in FIG. one.

In FIG. 1 is indicated: 1 - VLFL consisting of a laser 2 and forming optics (FO) 3 for creating an information field 4 for controlling a rocket 5 with a photodetector (FPU) 6, the field of view of which is directed to a VLFL 1, connected in series to a photodetector 7 with a lens 8 for detecting and determining the power of both direct radiation 9 of the laser-beam guidance system, and the control signal 10 reflected by the rocket 5 per scanning cycle of the guidance raster, unit for estimating the sending moments and power of laser radiation pulses 11, comparator 12 d To compare the power of laser radiation reflected by the rocket with a threshold value, the control unit 13 of the frequency-pulse jamming laser 14 with its orientation system in the direction of the laser radiation source 1, as well as the coordinate determination unit 15 of the automatic VLF coupled to the output of the photodetector 7 and connected to the input control unit 13.

A device that implements the proposed method of protecting an object from missiles guided by a laser beam works as follows.

Direct laser radiation 9 of the laser beam guidance system 1 of the laser 2 through the forming optics 3, modulated with a pulse repetition frequency of the control pulses of the rocket 5 in the information field 4, is incident on the FPU 6 of the rocket 5. At the same time, the same radiation 9 is collected by the lens 8 and recorded by a photodetector 7. Then, in block 15, the coordinates of the automatic LLF are determined. The photodetector 7 also records the control signal 10 reflected by the rocket 5 during the scanning cycle of the guidance raster. From the output of the FPU 7, electric pulses corresponding to the moments of reception of the rocket control signal pulses are fed to the input of block 11, which determines the moment of sending and the power of the laser radiation pulses reflected by the rocket, which is compared in the comparator 12 with a threshold value at which a given miss miss ( the likelihood of it not falling into the protected object). From the output of the comparator 12 through the control unit 13, the time parameters of the radiation of the frequency-pulse jamming laser 14 are changed, which generates jamming pulses arriving at the FO 3 of the laser beam guidance system 1. These pulses are reflected by the FO 3 in the direction of the guided missile 5, it is received onboard FPU 6 and generate false control signals for missile 5 in such a way as to provide a given miss miss (the probability of missing the missile in a protected object).

The effectiveness of the invention is expressed in increasing the efficiency of protecting the object from laser-guided missiles due to adaptive control of the repetition frequency of interfering pulses of a pulse-frequency laser.

Providing effective protection is confirmed by the simulation data of the process of pointing the rocket at the protected object in the conditions of application of the proposed method. As the main indicator determined by the simulation results, we used the probability of recognizing the missile’s withdrawal from the aiming line P _r , which ensures the probability of missiles not entering the protected object is more than 0.9.

The results of calculating the probability P _p are shown in FIG. 2 in the form of the dependence of the probability of recognition of the missile’s withdrawal from the aiming line on time t, counted from the moment the jamming was made. The calculations were carried out for the case of jamming from a distance of 5 km corresponding to the maximum launch range of the rocket, and the angular position of the rocket in its guidance raster was determined with an accuracy of ~ 1 mrad (to the angular dimensions of one element of the RLSN missile guidance raster).

The analysis of FIG. 2 dependences allows us to draw the following conclusions.

When exploring the angular position of the rocket in the raster with an accuracy of the order of ~ 1 mrad, the proposed method allows us to make the right decision on the effective action of interference on the VLF with a probability of P _p > 0.8 after 1.5 s. At the same time, the probability of a missile not entering the protected object is more than 0.9, and the probability of false alarm and signal skipping will not exceed 10 ^-2 ... 10 ^-3 per scanning cycle of the guidance raster (t = 0.1 s).

A preliminary analysis of the prior art allows us to establish that technical solutions characterized by a combination of features identical to all the features contained in the claims proposed by the applicant are absent, which indicates the compliance of the proposed method with the eligibility criterion of "novelty".

The results of the search for known solutions in this and related fields of technology in order to identify signs that match the distinguishing features of the proposed method showed that no solutions having signs matching the distinctive features of the proposed method were found in publicly available information sources. The prior art also does not confirm the popularity of the influence of the distinctive features of the claimed invention on the technical result indicated by the applicant. Therefore, the claimed invention meets the condition of "inventive step".

The proposed technical solution is “industrially applicable”, because the set of characteristics characterizing it provides the possibility of its implementation, performance and reproducibility, since known materials and equipment can be used to implement the method. So, for example, to control the repetition frequency of interfering laser pulses, generators of a series of these pulses can be used [see, for example, the journal “Instruments and Experimental Techniques”. - 1979. - No. 5. - S. 243-244].

In the study of other well-known technical solutions in this technical field, the specified set of features that distinguish the invention from the prototype, is not revealed.

Claims (1)

An adaptive method of protecting an object from a laser-guided missile, which consists in detecting the radiation of a laser missile control signal, determining the coordinates of the source of this radiation, orienting the pulse-frequency jamming laser in the direction of the laser radiation source, generating an interfering laser signal and emitting it in the direction of the laser radiation source characterized in that before the emission of interfering pulses by a frequency-pulse interfering laser, laser systems are additionally detected rocket control axes reflected by its hull determine the power gradient of these signals, compare it with a predetermined threshold, and then an interference signal of a pulse-frequency jamming laser is generated by changing its radiation frequency so as to ensure that the specified threshold is exceeded by the power gradient of the laser signals reflected by the missile hull management.

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