RU2698569C1 - Method for concealing optical-electronic means - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: invention relates to the field of optoelectronic equipment and can be used in laser location systems, optoelectronic countermeasures systems, as well as systems of optoelectronic equipment protection from powerful laser radiation. Method for concealing an optoelectronic device (OED) is based on absorbing a portion of the energy of optical radiation incident on an optoelectronic device, installing two matrix optical-electronic coordinator (MOEC) such that their receiving planes are perpendicular to each other and underlying the surface, and their field of vision included an OED location point, performing coordinate fixing and time synchronization of photosensitive elements operation MOEC, receiving MOEC of radiation of a source of directed optical radiation scattered by the atmosphere and determining, based on the coordinates of the photosensitive elements with maximum output signals and from the values of the time of their recording the space-time parameters of the trajectory of the beam of the source of the directed optical radiation of the underlying surface, calculating parameters of the spatial location of the OED and the time spent on reducing the effective scattering area (ESA) of the OED to the required value, critical spatial parameters of the beam of the source of directed optical radiation relative to the spatial parameters of the location of the OED, when the spatial parameters of the beam of the source of directed optical radiation are reached, critical values of reducing the ESA to the required value are achieved.

EFFECT: invention provides an increase in the effectiveness of concealing the OED.

1 cl, 2 dwg

Description

The invention relates to the field of optoelectronic technology and can be used in laser location systems, optoelectronic counteraction systems, as well as systems for protecting optoelectronic devices from powerful laser radiation.

The closest in technical essence and the achieved result (prototype) is a method (see, for example, [1]) of masking an optoelectronic means (OES), based on applying a light-absorbing coating to the reflective surfaces of the forming optics of the OES and. absorption of part of the location of the optical radiation. The disadvantage of this method is the low efficiency of the removal of the ECO at a high level of exposure, as well as the inability to reduce the level of effective dispersion area (EPR) of the ECO to a "zero" value. This disadvantage is due to the fact that the ESR is reduced by direct optical “contact” of the reflecting surfaces of the ECO with probing radiation. Moreover, in the prototype method, the decrease in the ESR of the OES is constant fixed in nature, without adapting to the value of the radiation density incident on the main reflective surface. In addition, the possibility of using light-absorbing coatings is limited by the need to preserve the throughput of the forming optics of the ECO.

The technical result, the achievement of which the invention is directed, is to increase the efficiency of hiding the ECO.

The essence of the invention is to provide the required temporary resource for hiding the ECO due to spatial monitoring along the scattered component of the scanning path of the beam of the laser ranging means (LLS).

The technical result is achieved by the fact that in the known method of hiding the ECO, based on the absorption of part of the energy of the optical radiation incident on the ECO, two matrix optoelectronic coordinators (MOECs) are installed so that their receiving planes are perpendicular to each other and the underlying surface, and in their field of view included the location point of the ECO, coordinate and temporarily synchronize the operation of the photosensitive elements of the MOEK, receive MOEK-scattered radiation from the source, for example optical radiation and the coordinates of the photosensitive elements with maximum output signals and the values of the time moments of their registration determine the spatio-temporal parameters of the scanning path of the beam of the source of the directed optical radiation of the underlying surface, the values of which, the values of the parameters of the spatial location of the ECO and the time spent on reducing the EPR ECO to the desired value, calculate the critical spatial parameters of the beam source direction radial optical radiation relative to the spatial parameters of the location of the ECO, when the spatial parameters of the beam of the source of directional optical radiation of critical values are achieved, the EPR is reduced to the desired value.

The main unmasking sign of the ECO is the EPR, which allows the location tool to detect and determine its location by the magnitude of the reflected signal (see, for example, [2, 4]). In the ECO, ESR reduction is ensured by the use of optical filters, the choice of the type of forming optics, the application of light-absorbing coatings, etc. (see, for example, [1, 3]). However, the effectiveness of such measures is constant and in the dynamics of changes in the power of the probing directed optical radiation it can be quite low and not ensure a reduction in the ESR of the ECO to a “zero” value. Moreover, the “zero" level of EPR should be understood as the identity of the magnitude of the reflected signals from the ECO and from the surrounding background. In this regard, it is proposed to hide the ECO by reducing its EPR to the level of the surrounding background due to preliminary spatial monitoring of the path of the radar beam.

Reducing the energy illuminance of the main reflective surfaces, which determines the ESR value of the OES, can be done by blocking the entire input optical flux or by changing the orientation of the field of view. For these procedures, time is required, which, with direct optical “contact” of the reflecting surfaces of the ECO with the probing radiation of the location tool, does not allow achieving the desired result. Therefore, it is necessary to provide a temporary resource for hiding the ECO. A temporary resource can be obtained by spatial monitoring along the scattered component of the path of the radar beam (see, for example, [4-6]).

The claimed method is illustrated by the scheme shown in figure 1, where the following notation: 1 - ECO; 2 - LLS; 3-MOEK; 4 - scanning path of the underlying surface of the radar; 5 - beam LLS; 6 - field of view of the ECO; (x _O , y _O ), (x _cr , y _cr ) - coordinates of the locations of the ECO and the center of the spot of illumination of the underlying surface of the radar; L is the distance between the coordinates of the ECO locations and the center of the spot illumination of the underlying surface of the LLS. In accordance with figure 1, two MOEK 3 are installed so that their receiving planes are perpendicular to each other and to the underlying surface, and the location point of ECO 1 enters into their field of view. At the same time, the operation of photosensitive elements of MOEK 3 is coordinated and synchronized. search for ECO 1 by scanning a region of space with beam 5 along a predetermined path 4. MOEK 3 receive radiated radiation from the radar system 2. According to the coordinates of the photosensitive elements, the output signals of which have a poppy imalnye values MIPC 3 determine the spatio-temporal parameters of the trajectory scanning beam 4 5 LLS underlying surface 2 (see., e.g., [4]). At the same time, as the spatio-temporal parameters of the trajectory of movement 4 of the beam 5 of the LLS 2, the measured MOEC 3 coordinates and the speed of the spot illumination on the underlying surface v _{L are used} , which allow determining the time point of intersection of the ECO 1 location point (see, for example, [4]) . Based on the spatio-temporal parameters of the scanning path 4 of beam 5, the coordinate values (x _O , y _O ) of the location of ECO 1 and the time t _C spent on reducing the ESR of ECO 1 to the required value, the critical coordinates (x _cr , y _cr ) of the spot cent are calculated illumination of beam 5 of LLS 2 relative to the coordinates (x _O , y _O ) of the location of ECO 1. The calculation of coordinates (x _cr , y _cr ) follows from the task of hiding ECO 1, which requires time. Therefore, in a simplified form, it is necessary to determine a point on the trajectory 4, remote from the coordinates (x _O , y _O ), as L≥v _L t _C , upon reaching which the spot illumination of beam 5 of LLS 2 reduces the ESR of ECO 1 to the required value. Reducing the ESR of ECO 1 to the desired value can, for example, be achieved by changing the orientation of the field of view of ECO 6.

The figure 2 presents a block diagram of a device with which the proposed method can be implemented. The block diagram of the device includes a data processing and control unit 7, receiving matrices OEC 8, photosensitive elements, the output signals of which have a maximum value of 9 at different times t ₁ , t ₂ , the remaining designations correspond to figure 1.

The device operates as follows. LLS 2 searches for ECO 1. MOEK 3 receive the radiation of LLS 2 scattered by the atmosphere and determine the coordinates of the photosensitive elements 9 of their matrices 8, the signals at the output of which have maximum values, as well as the moments of their registration, the values of which are transmitted to the data processing and control unit 7. The data processing and control unit 7 also receives the coordinates of the location of the ECO 1 and the time taken to reduce its ESR to the required value. The data processing and control unit 7 according to the received data controls the movement of the cent of the spot of the spot illumination of the LLS 2 beam, calculates the critical coordinates of its location and, upon reaching which, transmits a signal of ECO 1 to reduce its EPR. ECO 1 receives the signal and reduces the ESR of ECO 1 to the desired value.

Thus, the proposed method has the properties of increasing the efficiency of hiding the ECO due to spatial monitoring of the scattered component of the scanning path of the radar beam, which provides a temporary resource for reducing EPR. Thus, the method proposed by the authors eliminates the disadvantages of the prototype.

The proposed technical solution is new, because from publicly available information there is no known method of hiding the ECO, based on the absorption of part of the optical radiation energy incident on the ECO, installing two MOECs so that their receiving planes are perpendicular to each other and the underlying surface, and a point enters their fields of view the location of the ECO, the implementation of coordinate referencing and time synchronization of the photosensitive elements of the MOEK, the reception of the MOEK by the atmospheric radiation of a directional source optical radiation and determining from the coordinates of photosensitive elements with maximum output signals and from the values of the times of their registration of the spatiotemporal parameters of the scanning path of the beam of the source of the directed optical radiation of the underlying surface, the calculation of which, the values of the parameters of the spatial location of the ECO and the time spent on reducing the EPR ECO to the required value, critical spatial parameters of the beam source directional about optical radiation relative to the spatial parameters of the location of the ECO, the implementation, when the spatial parameters of the beam of the source of directional optical radiation, achieve critical values of reducing the EPR to the desired value.

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

1 Parkhomenko V.A., Rybakov A.N., Ustinov E.M. and other Patent RU No. 2350992. Masking device for optoelectronic devices from laser direction finding devices. M .: ROSPATENT, 2009.

2 Malashin M.S., Kaminsky R.P., Borisov Yu.B. Basics of designing laser location systems. M: "Higher School", 1983, pp. 26-27

3 Pervuliusov Yu.B., Rodionov S.A., Soldatov V.P. Under. Edited by Yakushenkov Yu.G. Design of optoelectronic devices. M .: "Logos", 2000, pp. 249-253.

4 Koziratsky Yu.L., Grevtsev A.I., Dontsov A.A., Ivantsov A.V., Kuleshov P.E. et al. Detection and coordinate measurement of optoelectronic devices, estimation of parameters of their signals. M .: "CJSC" Publishing House "Radio Engineering", 2015, pp. 17-26, 240-247, 353-362.

5 Koziratsky Yu.L., Koziratsky A.Yu., Kuleshov P.E. et al. Patent RU No. 2285275. A method for determining the direction of the optical radiation source from the component scattered in the atmosphere and the device for its implementation. M: ROSPATENT, 2006.

6 Koziratsky Yu.L., Koziratsky A.Yu., Kuleshov P.E. and other Patent RU No. 2357272. A method for determining directions to optical radiation sources by a component scattered in the atmosphere. M .: ROSPATENT, 2009.

Claims (1)

A method of hiding optoelectronic devices (OES), based on the absorption of part of the energy of optical radiation incident on the OES, characterized in that two matrix optoelectronic coordinators are installed so that their receiving planes are perpendicular to each other and the underlying surface, and in their the field of view included the ECO location point, coordinate and temporarily synchronize the operation of the photosensitive elements of the matrix optoelectronic coordinators, receive matrix optoelectronic the coordinators, the atmospheric radiation of the source of directional optical radiation scattered by the atmosphere, and the coordinates of the photosensitive elements with maximum output signals and the time values of their registration determine the spatio-temporal parameters of the path of the scanning beam of the source of directional optical radiation of the underlying surface, the values of which, the values of the spatial location parameters of the ECO and the time taken to reduce the effective dispersion area of the MA to a desired value, calculating the critical parameters of the spatial beam source of optical radiation directed relative spatial parameters ECO location at achieving spatial parameters directional beam source of optical radiation carried critical values decrease in the effective dissipation area to the desired value.

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