RU2468381C1 - Method of striking target producing coherent interference with missiles fitted with active radar seekers - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method of striking a target producing coherent interference by launching and guiding missiles fitted with an active radar seeker involves emitting a probe signal and receiving the signal reflected by the target, wherein two missiles are simultaneously directed onto the target, and emission of the probe signal and reception of the signal reflected by the target are reassigned between the missiles alternately; before launching missiles, the intervals for emitting probe signals and receiving reflected signals are synchronised such that intervals for emitting the signal of one missile match intervals for receiving the signal reflected from the target of the other missile. Switching intervals for emitting the signal and receiving the reflected signal is carried out with frequency higher than the bandwidth of the guidance system, and the frequency of switching emission and reception intervals is set primarily alternating. The missiles are guided into the target on "pliers" type maximally divergent trajectories.

EFFECT: improved method.

4 cl, 2 dwg

Description

The invention relates to the field of aviation weapons, in particular to methods of guiding air-to-air guided missiles with active homing radar heads for hitting targets - directors of active coherent interference, mainly jamming aircraft.

There are various methods of hitting targets by pointing guided missiles on them and missile guidance systems that implement them, for example, described in [1, 2, 3]. Currently, the main of the above methods is taken as a prototype of active radar homing missiles [1], the distinguishing feature of which is that both the source of the probing signal and the receiver of the signal reflected from the target are on board the guided missile. Such a construction ensures the fulfillment of the basic requirement for modern aircraft weapon control systems - the autonomy of the missile in the guidance process, i.e. implementation of the “let-forget” principle.

In the implementation of radar homing, the direction to the target, information about which is necessary for the formation of missile control signals, is determined by the angular discriminator of the guidance system. However, since radar goniometric systems determine the direction to the radiation source (in this case, to the target, as the source of the reflected signal) as the position of the normal to the phase front of the radar wave, characterizing the position of some effective center of reflection [4], the distortions of the wave front (with respect to spherical) lead to measurement errors, including abnormal ones. Such distortions of the front and the corresponding measurement errors can be of natural origin due to the nature of the nature of the reflection of the signal, or they can be artificially organized. As shown in [4], the radar perceives simultaneous radiation from several sources at the same frequency as radiation from some effective center, the location of which in the general case does not coincide with any of the real sources.

Organized interference, leading to phase front distortion and generated by the goal of producing interference by radiation from several points (at least two) of signals that are interconnected in amplitude and phase, is called coherent. The impact of such interference on the radar guidance system leads to unacceptable misses and a decrease in the probability of hitting the target down to zero.

In particular, if the amplitudes of the signals of the two interference emitters E ₁ and E _{2 are} approximately equal, and the phase shift at the receiving point is close to 180 °, the effective center of reflection will lie outside the base L (where L is the distance between the emitters installed at the ends of the wings), those. Outside of the target outline. Since the guidance on radar measurements will be carried out at some non-material point of the effective center of reflection, the real goal - the jammer will not be affected. Thus, with the correct selection of the amplitude and phase ratios of the interfering signals by the jammer, the efficiency of coherent interference is very high and the probability of failure of pointing to the target approaches 1, i.e. the probability of hitting a target tends to 0.

Distortions of the phase front of radio waves also occur when reflected from complex targets that have a multi-point nature of reflection, and are called “angular noise” [5]. However, the angular noise is random in nature, and the anomalous errors caused by it, when accompanied by typical targets, are acceptable taking into account the filtering properties of the guidance loop. In addition, a sufficiently large number of methods have been developed to further reduce the influence of angular noise, for example, in [6], [7]. However, if the distortions of the phase front of the radio waves are not random but constant focused in nature, as in the case of coherent fields, the methods mentioned above and the like are ineffective, and either do not protect against redirection to an imaginary source, or lead to the opening of the guidance loop, which leads to As a result, to one result - not to hit the target.

However, coherent jamming capabilities have fundamental physical limitations that can be used to protect active radar systems and missile guidance systems with active radar systems. The fact is that the region of space in which the phase relations of the signals of the interfering emitters necessary for the occurrence of phase-front distortions are fulfilled, is relatively small due to the difference in the path of the radio waves from different points, and practically amounts to about 0.001 rad angles (or units, or several tens of meters) depending on the distance to the target in linear coordinates).

And if modern radio countermeasures are able to create the necessary ratios of amplitudes and phases at the location of the active radar homing head (unmasking its location with its radiation), then already at a small distance from this place the necessary ratios are not satisfied, and the front distortions are so insignificant that they do not represent threats. For this reason, coherent interference is ineffective against multi-position, in particular bistatic (i.e., two-position) radar systems, when the transmitter of the probing signal is in one place and the receiver is in another, and there is a significant bistatic angle between them.

This property of resistance to coherent interference when transmitting and receiving spatially distributed, inherent in multi-position systems, can be realized in missile systems with active radar guidance of missiles due to the special organization of the process of guiding two missiles and their interaction with each other.

The present invention is directed to solving the problem of increasing the efficiency of hitting a coherent jamming target by launching and guiding missiles with active radar homing.

The problem is solved due to the fact that in order to hit the coherent jamming target by launching and guiding missiles with active radar homing, including the sounding of the sounding signal and receiving the signal reflected from the target, two missiles are pointing simultaneously at the target, and the sounding signal and reception the signal reflected from the target is redistributed between the missiles alternately, while prior to launching the missiles, the emission intervals of the probing signals and the reception of the reflected signals are synchronized so that the intervals of radiation from the signal of one rocket correspond to the intervals of reception of the signal reflected from the target of another rocket.

In addition, switching the intervals of signal emission and reception of the reflected signal is carried out with a frequency exceeding the bandwidth of the guidance system. The switching frequency of the emission and reception intervals is set by a variable. In this case, missile guidance is carried out along maximally diverging trajectories of the "tick" type.

The proposed method allows you to maintain such an advantage of the active radar system as autonomy, but provides conditions for diversity in the space of signal transmission and reception, which makes the method resistant to interference, such a missile that emits a signal at any time and, accordingly, is potentially exposed to interference It doesn’t receive, but is induced based on measurements taken at times when it received signals generated by radiation from another rocket. Then the rocket functions change, and thus, at each moment of time, the system is similar to a two-position guidance system with the only difference that the receiver and transmitter are periodically interchanged.

To ensure the continuity of formation of missile control signals, it is proposed that the intervals of signal emission and reception be switched at a frequency exceeding the bandwidth of the guidance system.

Moreover, to create additional difficulties in creating a response interference, the switching frequency of the intervals can be set by a variable.

The proposal to guide the missiles along the “tongs” -type paths diverging as much as possible in the initial and middle sections is aimed at ensuring that most of the flight paths of the rocket are maximally distant from one another and do not enter the area of space in which coherent interference is effective.

The essence of the proposed method is illustrated by the diagrams presented in figure 1 and figure 2.

Figure 1 illustrates the correspondence of the emission interval of the probe pulse of one rocket to the reception interval of the reflected signal of another rocket. Figure 2 presents a generalized block diagram of the equipment of missiles, communication with the carrier, between themselves and with the goal. To implement the method, additional inclusion of special switches in the structure of the missile equipment, and in the composition of the synchronizer carrier equipment to synchronize the operation of these switches in accordance with their cyclogram, is required.

So, the equipment of rocket 1 includes a radar signal receiver 1.1, the output signals of the angular discriminator of which in the form of estimates of the coordinates of the target are sent to the missile control system (not shown in Fig. 2), transmitter 1.2, controllable switch 1.3, and transceiver antenna 1.4 connected through the switch depending on its state to the output of the transmitter 1.2 or to the input of the receiver 1.1. The composition of the rocket 2 similarly includes a receiver 2.1, a transmitter 2.2, a switch 2.3 and a transceiver antenna 2.4. The composition of the equipment of the carrier aircraft 3 additionally includes a synchronizer 3.1, the outputs of which are connected to the sync inputs of the managed switches 1.3 and 2.3 before the missile launch, and the signals at the outputs of the synchronizer connected to each of the switches must be out of phase.

After target 4 is detected by carrier aircraft 3, a reception and transmission sequence diagram of active radar homing heads of both missiles is generated and transmitted to rockets 1, 2, their switches 1.3 and 2.3 are synchronized, for example, by supplying a pulsed clock signal in antiphase to the switches of each of two rockets. After launching the missiles, the switching sequence is remembered and implemented without additional external synchronization. In addition, in the rocket calculators (not shown in FIG. 2), a program is launched for diluting the rockets to the sides in the initial and middle sections of the trajectory for organizing further targeting of the “tick” type.

After the launch and capture of the target - the jammer by the active radar homing heads of both missiles for each of them, conditions are alternately created for determining the coordinates of the target and pointing at it for its destruction, since the signal radiated by one missile and reflected from the target is received by another missile. Moreover, due to the fact that the frequency of switching the intervals of reception and transmission of signals on each of the missiles is made with a frequency exceeding the bandwidth of the guidance system, the formation of missile control signals is carried out in the same way as with the continuous flow of information.

As a result, on the basis of two missiles with active radar homing, a two-position radar system is implemented with the maximum possible (due to the use of "tick" trajectories) under the conditions of pointing at a bistatic angle, not subject to coherent interference.

All of the above regarding the method of using air-to-air guided missiles with active homing radar for hitting coherent jamming targets is equally applicable to anti-aircraft guided missiles with active homing radar, with the only difference being that the synchronizer is included in the composition of the equipment of the anti-aircraft missile system.

Information sources

1. "Fundamentals of radio control" Ed. V.A. Weitel and V.N.Tipugin, Moscow: Sov. Radio, 1973, p. 303.

2. MV Maksimov, GI Gorgonov “Aviation radio-control systems” authors, VVIA im. Prof. N.E. Zhukovsky, 1973, p. 54.

3. M.V. Maksimov, G.I. Gorgonov "Radio-electronic homing systems", M .: Radio and communications, 1982, pp. 222-223.

4. "Theoretical Foundations of Radar" Ed. Y.D. Shirman, Moscow: Sov. Radio, 1970, p. 31.

5. "Reference radar" under. ed. M. Skolnik, Moscow: Sov Radio, 1976, Volume 1, pp. 405-412.

6. Javadov G.G. “Compensation of angularity errors caused by distortions of the wave front”, “Radio Engineering” No. 1, 1986

7. Greene M., Stensby J., Radar target pointing error reduction using extended Kalman filtering. JEEE Trans., Vol. AES-23, No. 2, 1987, pp 273-278.

Claims (4)

1. A method of hitting a coherent jamming target by missiles with active homing radars, including emitting a sounding signal and receiving a signal reflected from the target, characterized in that two missiles are aimed at the target simultaneously, the sounding signal is received and the signal reflected from the target is redistributed between missiles alternately, while before launching the missiles, the intervals of emission of the probing signals and the reception of reflected signals are synchronized so that the intervals the teachings of the signal of one rocket corresponded to the intervals of reception of the signal reflected from the target of another rocket. 2. The method of destruction according to claim 1, characterized in that the switching intervals of the radiation of the signal and receiving the reflected signal is carried out with a frequency exceeding the bandwidth of the guidance system. 3. The defeat method according to claim 2, characterized in that the switching frequency of the radiation and reception intervals is set to a variable. 4. The method of destruction according to claim 1, characterized in that the guidance of the missiles is carried out along maximally diverging trajectories of the "tick" type.

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