RU2361233C1 - Method of delivering radio jammer - Google Patents

Abstract

FIELD: physics; radio.

SUBSTANCE: invention relates to counteracting radioelectronic objects and can be used in planning and organising interference with different types of radio equipment. The said method is based on preliminary delivery in the region of location of radioelectronic equipment using an uncontrolled carrier of a source of infrared radiation and a navigation receiver. Coordinates of the location the source of infrared radiation are determined from the signal from the navigation receiver. From known values of coordinates of the points of delivering the radio jammer and location of the source of infrared radiation, values of angular deviation of the flight of the self-guided carrier of the radio jammer from the direction of the source of infrared radiation are determined. These values are introduced into the homing system on infrared radiation of the carrier of the radio jammer. The self-guided carrier of the radio jammer is launched and delivered to a precalculated point.

EFFECT: interference with different types of radio equipment.

2 dwg

Description

The invention relates to the field of counteraction against radio electronic means (RES) and can be used in the planning and organization of interference effects on radio equipment for various purposes.

The closest in technical essence and the achieved result (prototype) is the method (see, for example, N. Grishin. 155-mm artillery shell - radio interference director. - M.: "Foreign Military Review", 1984, No. 8, p. 76 -77) delivery of the director of radio interference (PRP), based on the launch of uncontrolled artillery or rocket launchers (shells) in the area where the RES is located. The disadvantage of this method is the lack of accuracy in the delivery of the PRP to the distribution area of the RES, leading to possible loss of operability (failure) of the transmitter or to a decrease in the power of the interfering signal associated with the terrain and the distance to the RES.

The technical result, the achievement of which the present invention is directed, is to increase the accuracy of the delivery of PRP to the region where the RES is located.

The technical result is achieved by the fact that in the known method for the delivery of PRP, which consists in launching an uncontrolled carrier of PRP in the area of the location of the RES, pre-delivery to the area of the location of the RES with an uncontrolled carrier of an infrared radiation source (IIII) and a navigation receiver, determining the coordinates of the IIII from the navigation receiver , determination of the angular deviations of the homing PRP flight from the eniya on IIKI, making the values of the angular deviation in homing in on the infrared radiation EDP media, implementation of ERP start homing vehicle and deliver it to the calculated point.

The essence of the invention lies in the preliminary delivery to the area of the radio electronic equipment of the navigation receiver and IIKI. According to the coordinates of the navigation receiver, determined by the satellite navigation system, the radio interference is delivered to the calculated point of the transmitter by homing its carrier on the IIMI signal. At the same time, an angular correction (offset) is introduced in advance in the homing system of the carrier in accordance with the coordinates of the location of the delivered PRP to the area where the RES is located.

The calculation of the impact zone and the choice of the point (place) of placement of an abandoned PDP in order to create an effective jamming effect of radio electronic equipment is made depending on the terrain and technical characteristics of the PDP (power, antenna type, operating frequency range, etc.) that affect the power of the jamming signal at the entrance of the radio. After the calculations, it is necessary to mark the PDP at the delivery point.

In General, the task of delivering an abandoned PRP in the proposed method is as follows (see figure 1). Preliminarily, in an area of location 6 RES 1 is delivered by an uncontrolled carrier 7 (for example, an artillery or rocket projectile) made in a single cassette version of the IIKI 4 and navigation receiver 4, which, after being fixed in the ground, are automatically brought into working condition. Navigation receiver 4 transmits via satellite navigation system 3 (see, for example, Yu.P. Grishin, V.P. Ipatov, Yu.M. Kazarinov et al. Radio engineering systems. - M.: Higher School, 1990, p. .306-311) at the launch site of carriers 5, their coordinates and, respectively, the coordinates of IIII 4. At the launching point of carrier 5, the angular deviations of the flight of carrier 8 to the delivery point of PRP 2 relative to the coordinates of IIII 4 are calculated. correction signals corresponding to the angular deviation are introduced Niyam, and carry out its launch. The homing system on the signal PIKI 4 sends the carrier PRP 8, taking into account the introduced corrections to the delivery point of PRP 2.

A homing carrier incorporating an angular discriminator (for example, a four-area photodetector), in combination with signal processing and control elements of electrodynamic rudders (see, for example, I.N. Goncharov, V.N. Dezhin, V.P. Kutakhov and other lasers in aviation. - M.: “Voenizdat”, 1982, pp. 43-47) performs homing on equal-signal values of photocurrents (signals) in each element of the photodetector. At the same time, the homing process is described by expressions (see, for example, V.V. Zaikin. Homing. - M.: SAYNS-PRESS, 2002, pp. 75-77)

where U _β is the normalized signal for controlling the movement of a homing carrier in a vertical plane (elevation);

U _α is the normalized signal for controlling the movement of a homing carrier in the lateral plane (in azimuth);

U ₁ , U ₂ , U _3, U ₄ are the signal values taken from the sensitive elements of the four-area photodetector (1, 2, 3, 4 are the numbers of photosensitive sites).

, где U_Σ=U₁+U₂+U₃+U₄ - суммарный сигнал. Что в свою очередь с учетом шумовой составляющей сигналов соответствует минимальным значениям U_β и U_α.Finding the IIKI image in the center of the angular discriminator (aiming at the target) is determined by the condition U ₁ = U ₂ = U ₃ = U ₄ =

where U _Σ = U ₁ + U ₂ + U ₃ + U ₄ is the total signal. Which in turn, taking into account the noise component of the signals, corresponds to the minimum values of U _β and U _α .

The ambiguity of the signals of the photocells of the four-area photodetector is proportional to the magnitude of the displacement of the IIAI image from the axial position (equal to the signal) on the photosensitive area, which is described by the expressions (see, for example, M.S. Malashin, R.P. Kaminsky, Yu.B. Borisov. Basics of laser design location systems. -M.: "Higher School", 1983, pp. 150-155)

where ΔX, ΔY is the image offset along the coordinate axes of the four-area photodetector;

F is the focal length of the input optics;

Δβ, Δα are the angular deviations of the axis of the homing carrier from the direction to the IIKI.

Changes in the magnitude of the signals of the sum of each pair of photocells of a four-area photodetector depending on the offset are represented by

where d _C - the size of the image IIKI in the plane of the four-area photodetector;

ΔU ₁₂ , ΔU ₃₄ , ΔU ₁₃ , ΔU ₂₄ - the total values of the output signals of the four-area photodetector, proportional to the angular deviations of the axis of the carrier from the direction to the IIMI.

Expressions (5) and (6) taking into account (3) and (4) are presented in the form

where ΔU _βkop , ΔU _αkop are correction signals in elevation and azimuth, respectively.

), пропорциональные угловым отклонениям оси носителя ПРП от направления на ИИКИ, приводят к изменению курса полета носителя. При этом система наведения будет стремиться скомпенсировать путем смещения изображения на поверхности фотоприемника величины корректирующих сигналов. Это приводит к выработке сигналов в блоке управления электродинамическими рулями на отклонение носителя в направлении расчетных координат доставки ПРП. Тогда выражения обработки сигналов с учетом корректирующих сигналов для изменения направления полета носителя ПРП в направление расчетной точки представляются в видеAccordingly, deliberately made adjustments to the total signals (taking into account the signs ± and

), proportional to the angular deviations of the axis of the PRP carrier from the direction to the IIMS, lead to a change in the flight path of the carrier. In this case, the guidance system will seek to compensate by shifting the image on the surface of the photodetector for the values of the correcting signals. This leads to the generation of signals in the control unit of the electrodynamic rudders for the deflection of the carrier in the direction of the estimated coordinates of the delivery of PRP. Then the signal processing expressions taking into account the correcting signals for changing the direction of flight of the PRP carrier in the direction of the calculated point are presented in the form

where U _Δβ , U _Δα are signals for controlling the movement of a homing carrier in vertical and horizontal planes (elevation and azimuth) in the direction of delivery of the PRP.

From the expressions (9) and (10) it follows that the guidance of the self-governing PDP carrier in the direction (when U _Δβ , U _Δα are minimal) of the calculated PDP delivery point is achieved by decreasing or increasing the values of the output signals (U ₁ , U ₂ U ₃ , U ₄ ) a four-area photodetector, depending on the signs of the correcting signals, which corresponds to the displacement of the image of IIKI on the surface of the four-area receiver.

Figure 2 presents a block diagram of a device with which the proposed method can be implemented.

Block diagram of the device contains a four-area photodetector 1, first 2, second 3, third 4 and fourth 5 adders, the first 6, second 7, third 8 and fourth 9 correction amplifiers, the first 10 and second 11 blocks of subtraction.

The device operates as follows. The radiation of the IIMS is received by a four-area photodetector 1, from the outputs of which the signals are fed to the first 2, second 3, third 4 and fourth 5 adders corresponding to the processing algorithm (expressions (1) and (2)). The signals from the outputs of each adder are supplied to the corresponding first 6, second 7, third 8 and fourth 9 correction amplifiers. Correction amplifiers reduce or increase the values of the corresponding total signals depending (expressions (7) and (8)) on the required angular deviation of the flight of the PRP carrier. From the outputs of the first 6 and fourth 9 correction amplifiers, the signals are fed to the inputs of the first subtraction block 10, which generates a signal for controlling the flight of the PRP carrier in a vertical plane (elevation (expression (9)). From the outputs of the second 7 and third 8 correction amplifiers, the signals arrive at the inputs of the second subtraction unit 11, which generates a signal for controlling the flight of the PRP carrier in the horizontal plane (in azimuth (expression (10)).

Thus, the proposed method allows, through the use of an additional IIKI installed in the region of the RES with known coordinates and the use of a high-precision homing carrier for infrared radiation, to increase the accuracy of the delivery of PRP to the calculated coordinates.

The proposed technical solution is new, because the publicly available information does not know the method of delivery of the PDP, which consists in pre-delivery to the region of the location of the radio electronic station by the unmanaged IIKI carrier and the navigation receiver, determining the coordinates of the IIKI from the navigation receiver, determining from the known values of the coordinates of the PDP delivery point and the PIKI location the values of the angular deviations of the flight of the homing carrier PRP from the direction to the IIKI, entering angular deviations Homing in on the infrared radiation EDP media, implementation of ERP start-homing medium and deliver it to the calculated point.

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

Claims (1)

A method for delivering a radio interference director to the area where the radio electronic equipment is located, which consists in using an uncontrolled medium, characterized in that before starting the homing carrier of the radio interference director, an infrared radiation source and a navigation receiver are delivered to the area where the radio electronic means are located and the navigation receiver is made in a single cassette design, which, after fixing in the ground, are automatically brought into working condition, while the navigation receiver transmits through the satellite navigation system to the launch site of the uncontrolled and homing carriers the coordinates of the location of the infrared radiation source, from the known coordinates of the delivery point of the radio interference director and the location of the infrared radiation source, determine the angular deviations of the flight of the homing carrier of the radio interference producer from the direction to the infrared radiation source, values of angular deviations in the homing system for inf akrasnoe radiation homing director carrier interference is performed then start homing carrier interference director and its delivery zone on exposure to EW means.

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