RU2707426C1 - Method of increasing noise immunity of guided ammunition - Google Patents

Abstract

FIELD: military equipment.

SUBSTANCE: invention relates to military equipment and method of increasing noise immunity of controlled ammunition. Method consists in determination of coordinates of target, illumination of area of target location, capture and homing of ammunition by reflected optical radiation from illumination area. At that radiation of all optical sources is received from area of target location, their frequency, energy, time and spatial parameters are measured, by values of which coordinates of sources and their location are determined. Reflected emission of target illumination is separated from optical sources, and the rest are classified as false. Among the false sources are determined sources, radiation of which can lead to failure of guidance of the ammunition on the target, and radiation sources alternative to these false sources are formed by illumination of the underlying area of the surface. At that, each alternative source of optical radiation is identical in its frequency, energy and time parameters to the corresponding false source of optical radiation, and by position relative to the location of the target illumination area is symmetrically opposite.

EFFECT: technical result is improved noise immunity of controlled ammunition.

1 cl, 3 dwg

Description

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

A known method of guiding a guided missile [see, for example, 1, p. 142-143, 2, p. 69-70], based on the illumination of the target directional optical radiation, capture and guidance of a homing ammunition (SBP) on the reflected optical radiation from the target . 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 the radiation from the laser and to take further countermeasures in the form of false sources of optical radiation, leading to the failure of the SPB guidance.

There is a method of guided munition guidance [see, for example, 3], which allows to increase the noise immunity of the SBP, which is based on illuminating the area of the underlying surface with directional optical radiation, capturing and pointing the SBP along the reflected optical radiation from the area of lighting of the underlying surface, choosing at least two areas of illumination of the underlying surface symmetrical with respect to the coordinates of the target and located in the field of view of the homing ammunition, periodic illumination by directional optics eskim radiation of selected areas of the underlying surface at a frequency at the time constant inverse value accumulation photoreception optical radiation photons SBP device. The disadvantage of this method is the high probability of disruption guidance SBP when in its field of view of false sources of optical radiation (LIOI).

A known method of guidance guided ammunition [see, for example, 4], which allows to increase the noise immunity of the SBP, which is based on determining the coordinates of the target, illuminating the area of the underlying surface with laser radiation, capturing and pointing the air-to-surface SBP by reflected laser radiation from the area of illumination of the underlying surface , moving the illumination region of the underlying surface by laser radiation along a path defined with respect to the coordinates of the target, excluding the illumination by the laser radiation of the target itself, op the determination of the parameters for pointing the SBP to the target, taking into account the parameters of the trajectory of the area of illumination of the underlying surface by laser radiation, and transferring their values to the SBP. The disadvantage of this method is the high probability of disruption guidance SBP when in its field of view LIOI.

The technical result, the achievement of which the invention is directed, is to increase the noise immunity of the UPS.

The technical result is achieved by the fact that in the known method of increasing the noise immunity of guided munitions, based on determining the coordinates of the target, highlighting the target location area, capturing and pointing the SBP from the reflected optical radiation from the highlight area, the emissions of all optical sources from the target location area are received, their frequency is measured , energy, temporal and spatial parameters, the values of which determine N the number of optical sources and the coordinates of their location, if N > 1, then the reflected illumination radiation of the target is extracted from N emissions of optical sources, and the remaining N-1 emissions of optical sources are classified as false, among N-1 false K the number of optical sources, the radiation of which by their parameters will lead to the failure of pointing the SBP to the target form the number of alternative LIOIs by highlighting the underlying surface area M, with K = M and each mth alternative source of optical radiation in their frequency, energy and time parameters being identical to each kth LIOI, and p about the location relative to the location of the target illumination area is symmetrically opposite.

Damage to objects can be carried out by guided ammunition that uses directional optical radiation to illuminate the target for guidance [see, for example, 1, p. 142-143, 2, p. 69-70, 3, 4]. The inclusion of LIOI in the complex of object protection with the characteristics of the backlight radiation of the LCC allows you to make adjustments to the flight path of the SBP and disrupt its guidance on the target [see, for example, 5, p. 77, 6, p. 476-483]. Therefore, in the interest of increasing the noise immunity of an SBP with a laser homing head, it becomes necessary to reduce the likelihood of disruption of guidance when LIOI appears in its field of view. This can provide "compensation" of the optical radiation of the false source with additional radiation with similar parameters, but located symmetrically in the opposite direction relative to the target.

The figure 1 presents a diagram explaining the essence of the method (where the following notation is adopted: 1 - pointing point - the target of the lesion; 2 - complex WTO (CTW), including: launch vehicle-trigger SBP 3, SBP 4, LCC 5; 6, 7 - LIOI; 8 - additional area of illumination, with the parameters of LIOI; 9 - beam of the LCC; 10 - beam of additional illumination of the LCC; 11 - radiation of LIOI in the direction of the HVAC; 12 - reflected radiation of the LCC in the direction of the WTO complex; 13 - reflected radiation of additional illumination in the direction of KVTO; (-x _LIOI1 , 0,0), (-x _LIOI2 , y _LIOI2 , 0) - location coordinates of the LIOI; (x _DOPLES , 0,0) are the coordinates of the area of illumination by the additional radiation of the target laser and L; the distance between the LIOI and the area of illumination of the target laser and the area of illumination of the additional radiation of the target)).

In accordance with the scheme, the procedure in the proposed method is as follows. To simplify the description of the method, the guidance point - the target 1 is located in the center of the Cartesian coordinate system, and LIOI 6 on the 0x axis at the point with coordinates (x _LIOI1 , 0,0) at a distance L from the center of the Cartesian coordinate system, LIOI 7 at the point with coordinates (-x _LIOI2 , y _LIOI2 , 0). Initially, KVTO 2 determines the coordinates of the guidance point - the target of defeat 1. The coordinates of the guidance point - the target of defeat 1 KVTO 2 directs the LCC 5, illuminates it with laser radiation 9 and launches the SBP 4. The KVTO 2 receives radiation from all optical sources from the location of the target 1 and measures their frequency, energy, temporal and spatial parameters. According to the values of the parameters, the CTEC 2 determines the total N number of optical sources and the coordinates of their location in the area of location of the target 1 (in figure 1: N = 3, initially the sources of optical radiation are 12, 6, 7). If N = 1, then at KVTO 2 a decision is made on the absence of LIOI in the area of location of the object of defeat 1. If N> 1, then KVTO 2 extracts from the N radiation of optical sources the reflected radiation 12 of the target’s illumination LCC 5, and the remaining N-1 optical radiation sources classified as LIOI 6, 7 (in figure 1: N-1 = 2). CTO 2 determines among LIOI 6, 7 LIOI 6, the radiation 11 of which in its parameters will lead to the failure of pointing SBP 4 to target 1 (in figure 1: K = 1, the source affecting SBP 4 is LIOI 6). Next, the CTWO 2 using LCC 5 at a distance L from the coordinates of the guidance point 1 symmetrically in the opposite direction relative to the coordinates of the center of the guidance point - the target 1 forms an alternative source of LIOI 6 by illumination 10 of the underlying surface area 6. For figure 1, the coordinates (x _DOPLES , 0 , 0) there are:

(x _DOPLES , 0,0) = (- x _LIOI1 + 2L, 0,0).

In this case, the reflected radiation 13 from the illumination region 8 in its frequency, energy and time parameters is identical to LIOI 6.

The figure 2 presents a diagram on the example of a four-quadrant optical radiation receiver (POI) homing head, explaining the operation of the SBP 4 in the mode of analysis of incoming images in accordance with the method [see, for example, 6, p. 148-155] (where 14 is a photosensitive surface ( PSF) of a four-quadrant POI; 11, 13 - (in accordance with figure 1) images of the reflected signals of the target illumination area and the additional illumination area of the LOC 5 on the PSI PSI; 11 - (in accordance with figure 1) the image of LIOI 6 on the PSI POI, 15, 16, 17 - functional stages Bani POI). At stage 15, SBP 4 receives reflected radiation 12 from the target of the illuminated LCR 5 and an image 12 is formed on its PSF 14. At this stage 15, a further algorithm for processing the POI signals allows SBP 4 to aim at target 1 with a predetermined accuracy. At stage 16, SBP 4 receives both radiation 12 of LCC 5 and radiation 11 of LIOI 6. The total processing of their images 11, 12 on the PSP 14 leads to a distortion of the direction-finding characteristic of target 1 and, accordingly, a miss of SBP 4. At stage 17, in accordance with the above description, an additional source is formed in the form of a spot of illumination 8, the radiation of which compensates for the distortion of the image of the true illumination 12 by radiation 11 of the LIOI 6 image 13, the total processing of which on the PSF 14 restores the direction-finding characteristic of target 1 and, accordingly, etstvenno pointing at her SBP 4.

The figure 3 presents a block diagram of a device with which the method can be implemented. The block diagram of the device includes: a unit for processing and analysis of optical radiation 18, a control unit 19, a multi-channel laser 20, the remaining symbols correspond to figure 1.

The device operates as follows. After coordinate fixation, the start of target illumination, the LCC 5 carries out the optical radiation processing and analysis unit 18, receives optical radiation, measures their parameters and analyzes, which, according to the results, generates control signals in the control unit 19. The control unit 19 makes settings for the parameters of multi-channel laser 20. Multi-channel the laser 20 generates and emits an additional number of optical signals with predetermined frequency, energy, spatial and temporal parameters.

Thus, due to the additional illumination of the underlying surface area with optical radiation with energy, frequency and time parameters identical to the LIOI and the location relative to the location of the target illumination area symmetrically opposite, the proposed method has the properties of increasing the efficiency of the use of SBP for LCC radiation. Thus, the proposed method eliminates the disadvantages of the prototype.

а по местоположению относительно местоположения области подсвета цели симметрично противоположен.The proposed technical solution is new, since the method of noise immunity of the guided munition based on determining the coordinates of the target, highlighting the target location area, capturing and pointing the SBP from the reflected optical radiation from the highlight area, receiving radiation from all optical sources from the target location area, measuring, is unknown from publicly available information. their frequency, energy, temporal and spatial parameters, the determination of which N is the number of optical sources and the location of their location, the allocation, if N> 1, from N emissions of optical sources, the reflected radiation of the target illumination, the classification of the remaining N-1 emissions of optical sources as false, the determination among N-1 false K of the number of optical sources, the radiation of which in its parameters leads to disruption of pointing the SBP to the target, the formation of the highlighted region of the underlying surface M of the number of alternative LIOIs, with K = M and every mth alternative source of optical radiation in its frequency, energy and time parameters t zhdestvenen to each k-th LIOI, k = m,

and the location relative to the location of the target illumination area is symmetrically opposite.

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

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4. Pat. 2635299 RU, IPC F41G 9/00. Guided ammunition guidance method / Koziratsky Yu.L., Kuleshov P.E., Parinov M.L., Balain S.E., Levshin E.A., Dontsov A.A .; Applicant and patent holder VUNC Air Force "VVA" (Voronezh). - 2016119419; declared 05/19/2016; publ. 11/09/2017, Bull. No. 31. - 8 p.

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Claims (1)

A way to increase the noise immunity of guided munitions, which consists in determining the coordinates of the target, highlighting the target location area, capturing and pointing the homing ammunition by reflected optical radiation from the illumination area, characterized in that they receive radiation from all optical sources from the target location area, measure their frequency, energy, temporal and spatial parameters, the values of which determine N the number of optical sources and the coordinates of their location, if N> 1, then you the reflected radiation of the target illumination is divided from N emissions of optical sources, and the remaining N-1 emissions of optical sources are classified as false, among the N-1 false K the number of optical sources, the emission of which by their parameters will lead to the failure of homing ammunition to the target, form backlight the area of the underlying surface M is the number of alternative false sources of optical radiation, with K = M and each mth alternative source of optical radiation in its frequency, energy and belt parameters identical to each k-th a false source of optical radiation, k = m,

and the location relative to the location of the target illumination area is symmetrically opposite.

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