RU2660777C1 - Guidance method of the managed ammunition - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to weapons, in particular, to systems of fire destruction of objects with controlled ammunition. Essence of the method for directing a guided munition is to highlight the region of the underlying surface with directed optical radiation in accordance with known target coordinates, detection, capture and homing of a homing ammunition along the reflected optical radiation from the area of illumination of the underlying surface, at least two regions of the illumination of the underlying surface are selected, symmetrical with respect to the target coordinates and are in the field of view of homing ammunition, illumination of selected areas of the underlying surface is carried out with a period, smaller than the time constant for the accumulation of a homing ammunition receiver.

EFFECT: technical result is a decrease in the probability of counteracting ammunition sent to the target designation.

1 cl, 2 dwg

Description

The invention relates to weapons, in particular to systems for the destruction of weapons by guided munitions.

A known method of guiding guided ammunition [see, for example, Sidorin V.M., Sukhar I.M., Salakhov TR, Ponamarev V.G. and other Means and systems of optoelectronic suppression. Part 1. - M .: Publishing house VVIA them. Prof. NOT. Zhukovsky, 2008, pp. 142-143, Antonov D.A., Babich P.M., Balyko Yu.P. et al. Edited by Fedosov EA. Russian Air Force aviation and scientific and technological progress. Combat systems and systems yesterday, today, tomorrow. - M .: Drofa, 2005, pp. 69-70], which includes: determining the coordinates of the target, highlighting the area of the underlying surface, on which the target is placed, by directed optical radiation, capturing and guiding the homing ammunition (SBP) from the reflected optical radiation from the illumination area underlying surface. The disadvantage of this method is the high information content of the attack target SBP, due to the possibility of direct registration of the fact of illumination by a laser target designator (LC) at the target. So, the installation of backlight sensors at the target allows almost instantly detecting radiation from the laser control unit and in the future take countermeasures both to the SBP itself and to the damage complex as a whole.

The technical result, the achievement of which the present invention is directed, is to reduce the likelihood of counteracting ammunition homing on the radiation of target designation.

The technical result is achieved in that in the guided munition guidance method based on illuminating the underlying surface area with directional optical radiation in accordance with known target coordinates, detecting, capturing and aiming the homing ammunition from reflected optical radiation from the underlying surface illumination area, at least at least at least two areas of illumination of the underlying surface, symmetrical with respect to the coordinates of the target and in the field of view with ammunition ammunition, carry out the illumination of selected areas of the underlying surface with a period less than the time constant of the accumulation of the receiver of the homing ammunition.

Objects can be defeated by guided munitions that use target illumination radiation [see, for example, Sidorin V.M., Sukhar I.M., Salakhov TR, Ponamarev V.G. and other Means and systems of optoelectronic suppression. Part 1. - M .: Publishing house VVIA them. Prof. NOT. Zhukovsky, 2008, pp. 142-143]. This leads to the fact that the object of defeat gives the opportunity to register the fact of its illumination of the LTC and the subsequent SBP attack [see, for example, Volzhin A.V., Sizan I.G. Fight against homing missiles. - M .: Military Publishing House, 1983, p. 9, Evdokimov V.I., Gumelyuk G.A., Andryushchenko M.S. Non-contact protection of military equipment. - St. Petersburg: Renome, 2009, p. 78-88]. The use of LCC radiation detection means as a part of the facility’s protection complex allows, based on the assessment of the backlight signal parameters, countermeasures both for the SBP itself and the WTO complex as a whole [see, for example, Evdokimov VI, Gumelyuk GA, Andryushchenko M.S. Non-contact protection of military equipment. - St. Petersburg: Renome, 2009, p. 78-88]. Such countermeasures include fire destruction of elements of the construction of the WTO complex, the use of various kinds of interference, redirecting the SBP or reducing the energy of the backlight signal, etc. [see, for example, Volzhin A.V., Sizan I.G. Fight against homing missiles. - M.: Military Publishing, 1983, pp. 71-78]. Therefore, in the interest of reducing the likelihood of counteraction against guided munitions with active and semi-active homing systems, there is a need to reduce the likelihood of detecting LSC signals at the target. This can provide a shift in the area of illumination of the laser relative to the target. In this case, the electromagnetic accessibility by means of registering the backlight signals of the LCU is significantly reduced. At the same time, in order to preserve the accuracy parameters of the SBP, the period of alternating illumination of the LCC of the displaced areas of the underlying surface should be less than the time constant of accumulation of the receiver of the homing ammunition.

In FIG. 1 is a diagram explaining the essence of the method, where the following notation is adopted: 1 - guidance point - target, 2 - carrier-launch vehicle SBP, 3 - SBP, 4 - LCC, 5 - reflected radiation in the direction of the SBP, 6 - radiation backlight LCC , 7 - geometry of the location of the areas of illumination of the underlying relative to the target, 8 - the portion of the illumination of the underlying surface.

The proposed method provides the following procedure. Initially, the coordinates of the guidance point — target 1 are determined. With respect to the coordinates of the target point — target 1, the highlight area of the underlying surface 8 is programmed at LCP 4. In this case, the geometry 7 of the selection of the highlight areas of the underlying surface 8 is symmetrical with respect to the coordinates of the location of the target 1, and also provides an exception electromagnetic accessibility by the registration elements of the signals of the LCH 4 at the target 1 and the location of the backlight 8 in the field of view of the SBP. LCC 4 illuminates with rays 6 sections of the underlying surface 8 relative to the target 1 with a programmed frequency. The cycle time of the illumination of sections of the underlying surface 8 is less than the constant time of accumulation of the receiver of the homing ammunition [see, for example, Krasnov A.M., Dongaev GA, Maslov II. and other Optoelectronic systems of aircraft weapons. M .: Publishing house VVIA them. Prof. NOT. Zhukovsky, 2007, p. 599]. The most common are quadrant radiation pickup coordinators. In this case, when the center of the image of the object coincides with the center of the receiver, the radiation flux is evenly distributed between the quadrants, and the coordinator's output signal proportional to the difference in the fluxes perceived by the oppositely located quadrants is zero. When the image is shifted relative to the zero position, redistribution of the radiation fluxes between the individual quadrants occurs and at the output of the balanced circuits there appear signals proportional to the difference of the fluxes [see, for example, L. Kriksunov Tracking systems with optoelectronic coordinators. K .: Technique, 1991, p. 75 and Kazakov I.E., Mishakov A.F. Aircraft guided missiles, part 2. Moscow: VVIA Publishing House Prof. NOT. Zhukovsky, 1985, p. 96, 106].

To implement the method, it is necessary to correct the operation mode of the target illumination device in accordance with the block diagram shown in FIG. 2 and comprising: a scanning drive 9, a control unit for the scanning drive 10, the remaining symbols correspond to figure 1.

The device operates as follows. After the coordinate reference of the LCU 4 and the target, the LCU 4 generates backlight radiation and generates a control signal, which transmits to the control unit of the scanning drive 10. The control unit of the scanning drive 10 generates temporal parameters of the spatial switching in the direction of the backlight relative to the coordinates of the target and transmits control signals to the scanning drive 9. The scanning drive 9 generates the required spatial and temporal radiation parameters of the LCC 4.

Thus, by selecting at least two areas of illumination that are symmetrical with respect to the coordinates of the target and are in the field of view of the homing ammunition, and their illumination with a period shorter than the accumulation time of the receiver of the homing ammunition, the claimed method obtains a property to reduce the likelihood of countering homing target radiation ammunition, which consists in the possibility of reducing the electromagnetic availability of backlight signals at the target. Thus, the proposed method eliminates the disadvantages of the prototype.

The proposed technical solution is new, because from publicly available information there is no known method of guided munition guidance based on illuminating the area of the underlying surface with directional optical radiation in accordance with the known coordinates of the target, detecting, capturing and aiming the homing ammunition by reflected optical radiation from the area of illumination of the underlying surface, characterized in that at least two areas of illumination of the underlying surface, symmetrical with respect to itelno target coordinates and remain in sight homing munition carried illumination selected regions of the underlying surface with a period less than the time constant receiving device accumulation homing munition.

The proposed technical solution is practically applicable, since for its implementation typical electrical components and devices can be used.

Claims (1)

The guided munition guidance method, which consists in illuminating the area of the underlying surface with directional optical radiation in accordance with the known coordinates of the target, detecting, capturing and pointing the homing ammunition by reflected optical radiation from the area of illumination of the underlying surface, characterized in that at least two areas of illumination of the underlying surfaces symmetrical with respect to the coordinates of the target and located in the field of view of the homing ammunition carry out dsvet selected areas of the underlying surface with a period less than the time constant receiving device accumulation homing munition.

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