RU2744507C1 - Method for protecting optical-electronic means from powerful laser complexes - Google Patents

Abstract

FIELD: radio engineering

SUBSTANCE: invention relates to radio engineering and can be used for protecting optical-electronic means from powerful optical radiation. To achieve a technical result, optical radiation is received by an optical-electronic means, optical radiation is received by an optical-electronic means via an additional lens which is installed in the plane of the optical-electronic means location at a distance from the main lens of the optical-electronic means R≥R_min where R≥R_min is the minimum value of the radius of the zone relative to the location of the main lens of the optical-electronic means, beyond which the influx of heavy laser radiation will not affect the optical-electronic means at a specified distance of deflection, the location radiation of a powerful laser complex is received via an additional lens by the optical-electronic means and the parameters thereof are measured, the moment when the optical-electronic means is exposed to powerful laser radiation by a powerful laser complex is determined by the parameters of location radiation of a powerful laser complex and at the time of the exposure of the optical-electronic means to a powerful laser radiation of a powerful laser complex the optical radiation of the optical-electronic means is received via the main lens.

EFFECT: improved quality of protection of optical-electronic means.

1 cl, 2 dwg

Description

The invention relates to the field of protection of optoelectronic devices (OES) from powerful optical radiation.

There is a known method of protecting a photodetector (see, for example, [1]), based on local burning with laser radiation when the threshold radiation resistance of a metal mirror film is exceeded with a thickness commensurate with the penetration depth of radiation and the removal of part of the laser radiation through the formed hole. The disadvantage of this method is the disposability of the protective element, which excludes the number of cycles of repeated protection of the OES without replacing the protective element.

- номер ЧЭ МФПУ, N - количество ЧЭ в МФПУ, и сравнении ее значения с пороговым i_П, закрытии при превышении величины i_j выходного сигнала j-ого ЧЭ МФПУ порогового значения i_n j-ой части входного оптического потока, где

номер ЧЭ МФПУ, выходной сигнал которого превысил пороговое значение и номер части входного оптического потока падающего на этот ЧЭ МФПУ, периодическом открытии 7-ой части входного оптического потока и измерении величины i_j выходного сигнала j-го ЧЭ МФПУ, закрытии при i_j≥i_П j-ой части входного оптического потока, оставлении при i_j≥i_П j-ой части входного оптического потока открытой. Недостатком способа является низкий порог лучевой стойкости, не исключающий «прожиг» защитного элемента и дальнейшее поражения ОЭС.There is a known method of protecting an optical radiation receiver (see, for example, [2]), based on the reception of the input optical flow by a matrix photodetector (MPD), measuring the value of i _{i of the} output signal of each i-th sensitive element (SE) of the MPD, where

- number of SE MFP, N - number of SE in MFP, and comparing its value with the threshold i _P , closing when the value i _{j of the} output signal of the j-th SE MFP exceeds the threshold value i _{n of the} j-th part of the input optical flow, where

the number of the SE MFP, the output signal of which has exceeded the threshold value and the number of the part of the input optical flow incident on this SE MFP, periodically opening the 7th part of the input optical flow and measuring the value i _{j of the} output signal of the j-th SE MFP _{, closing at i j ≥i P} j-th part of the input optical flow, leaving at i _j ≥i _P j-th part of the input optical flow open. The disadvantage of this method is the low threshold of radiation resistance, which does not exclude the "burning" of the protective element and further damage to the OES.

The technical result, the achievement of which the present invention is directed, is to increase the efficiency of protecting the OES from damage by optical radiation.

The technical result is achieved by the fact that in the known method of protecting the OES from MLK, based on the reception of optical radiation of the OES, the optical radiation of the OES is received through an additional lens installed in the plane of the OES at a distance from the main lens of the OES R≥R _min , where R _min is the minimum value of the zone radius relative to the position of the main lens of the OES, outside of which the flow of incident powerful laser radiation (MLI) will not hit the OES at a given distance of non-damage, the locating radiation of the MLK is received through the additional lens of the OES and its parameters are measured, the moment is determined by the values of the parameters of the locating radiation of the MLK the time of irradiation of the OES MLI MLK and at the time of irradiation of the OES MLI MLK carry out the reception of optical radiation of the OES through the main lens.

The essence of the proposed method is as follows. The guaranteed protection of the OES against damage by optical radiation is provided by the OES by shifting the targeting point of the MLI based on the use of the remote elements of the forming optics of the OES to the required distance.

From the system point of view, a powerful laser complex (MLK) includes two main subsystems (see, for example, [3, pp. 254-256]): a subsystem for searching, detecting, evaluating parameters and recognizing OES (information support); a subsystem for the formation, generation and guidance of damaging radiation (damage). Each of the subsystems, due to external and internal factors, contributes to the accuracy of aiming a narrow beam of the striking channel and keeping it in the required direction. Accordingly, the accuracy of the MLI beam guidance affects the magnitude of the optical radiation flux at the input of the OES [4, 5]. Consequently, the shift of the aiming point will reduce the radiation flux at the input of the OES to the required level. The main unmasking feature of the OES is the EPR, which allows the MLK to detect and determine the location of the OES (see, for example, [6, pp. 11-36]). In the OES, the most informative for its location (and vulnerable to its destruction) is the element located near the focus, as a rule, it is a photodetector. In an equivalent form, an OES, as an object of location, can be represented as a lens with a focal length and transmittance and a reflective surface with a reflectivity located in the area of the focal plane of the lens (see, for example, [6, pp. 26-28]). The position of the lens relative to the reflective surface affects both the magnitude of the reflected signal and the direction of its arrival. Changing the position of the lens relative to the reflecting surface will lead to a change in the direction of arrival of the reflected signal and to additional MLI pointing errors.

The claimed method is illustrated by the diagram shown in figure 1, where the following designations are adopted: 1 - OES carrier; 2 - OES, including: 5 - additional lens of OES, 6 - main lens of OES; 7 - photodetector (FPU) of the OES; 3 - underlying surface; 4 - ground MLK; 8 - sector of viewing the underlying surface of the OES; 9 - illumination spot of the carrier of the OES and OES MLI. In figure 1, elements that do not carry a semantic load are excluded to disclose the essence of the invention.

Let us consider the situation when OES 2 is elements of an air surveillance complex performing a task in the coverage area of ground MLK 4. OES 2 from the air carrier 1 through an additional lens 5 monitors the underlying surface in sector 8. MLK 4 carries out a location search for OES 2 and in the direction of arrival the reflected signal determines its location. Based on the results of the coordinate assessment of the OES 2, MLK 4 forms the spatial parameters of the radiation of its damaging channel. As a result, the targeting error of the MLK 4 striking channel will include a target designation error, which will include the angular mixing of the target designation point due to the use of an additional lens 5 installed from the main 6 at a distance R. Then the method includes the following procedures: at the stage of searching and detecting MLK 4 OES 2 - FPU 7 receives optical radiation through an additional lens 5, at the stage of destruction of MLK 4 OES 2 - FPU 7 receives optical radiation through the main objective 6. The implementation of these procedures ensures the switching of optical flows during the time between the end of the location and the beginning of destruction of OES 2 MLK 4. When the distance between the lenses 5 and 6 ensures a decrease in the flow of powerful laser radiation MLK 4 to a "safe level", since the lens 6 is located at the edge of the illumination region 9. In accordance with the claimed technical result, the method implies the following procedures: an object iv 5, installed in the plane of placement of OES 2 at a distance from the main lens 6 OES 2 R> R _min , where R _min is the minimum value of the radius of the zone relative to the position of the main lens of OES 2, outside of which the flux of incident powerful laser radiation "will not hit" the OES 2 at a given minimum distance of non-damage L _mjn , the location radiation of MLK 4 is received through an additional lens of OES 2 and its parameters are measured, the moment of irradiation of OES 2 MLI MLK 2 is determined by the values of the parameters of the locating radiation MLK 2 and at the time of irradiation of OES 2 MLI MLK 2 carry out the reception of optical radiation of the OES 2 through the main lens 6.

For example, the minimum value of R _min , which ensures effective protection of the OES from MLK by the method under consideration, provided that the intensity of high-power laser radiation has a Gaussian distribution and the Rayleigh-type pointing error law, can be determined using the expression

where Р ₀ is the known value of the flow power of the MLI MLK; L _min - the specified minimum distance of protection of the OES from the MLK; β is the known angular mean square error of the MLI MLK beam pointing; I _P is the known threshold value of the MLI intensity at the input of the OES, at which the OES is damaged; α _Σ - total indicator of energy attenuation (losses) of MLI in the atmosphere; p _s - the given probability of the protection of the OES from the MLK.

So, for example, for typical initial values P ₀ = 10 W, L _min = 200 m, p _pore = 0.95 β = 2 × 10 ^-4 rad, I _P = 10 W / m ² , α _Σ ≈min, will be R _mia = 0.526 m, and with a twofold increase P ₀ = 20 W - R _min = 0.744 l /, which is realizable on almost any OES carrier.

Figure 2 shows a block diagram of an embodiment of a device that implements the method. The block diagram includes: an optical flow switch 10, a unit for detecting MLC radiation and evaluating their parameters 11, a control unit 12, the rest of the designations correspond to figure 1.

The device works as follows. The FPU 7 receives optical radiation through the remote lens 5. The unit for detecting the MLK radiation and assessing their parameters 11 records the fact of learning by the OES location signal, measures its parameters, determines the MLK location and transmits their values to the control unit 12, which, based on a priori specified accuracy parameters guidance and power MLK estimates the possible flow of MLI to FPU 7. If the calculated value of the MLI flux exceeds the threshold value, the control unit 12 at the required time transmits a control signal to the optical flow switch 10 to connect FPU 7 to the main lens 6.

Thus, the proposed method has the properties of increasing the efficiency of protecting the OES from damage by optical radiation by shifting the target point of the MLI based on the use of the removed elements of the forming optics of the OES to the required distance. Thus, the method proposed by the authors eliminates the disadvantages of the prototype.

The proposed technical solution is new, since the publicly available information does not know the protection of the OES from MLK, based on the reception of optical radiation of the OES, the implementation of the reception of optical radiation of the OES through an additional lens installed in the plane of the OES at a distance from the main lens of the OES R≥R _min , where R _min is the minimum value of the radius of the zone relative to the position of the main lens of the OES, outside of which the flow of the incident MLI will not hit the OES at a given distance of non-damage, receiving the locating radiation of the MLK through the additional lens of the OES and measuring its parameters, determining the moment of time of the OES irradiation by the values of the parameters of the locating radiation of the OES MLI MLK and the implementation at the time of irradiation of the OES MLI MLK reception of optical radiation of the OES through the main lens.

The proposed technical solution is practically applicable, since optical and optoelectronic units and devices can be used for its implementation.

Literature

1 Chesnokov V.V., Chesnokov D.V., Shlishevsky V.B. Film passive optical shutters to protect image receivers from glare / V.V. Chesnokov, D.V. Chesnokov, V.B. Shlishevsky // Optical Journal. 2011. - No. 78.6. - S. 39-46.

2 Pat. 2363017 RU, IPC H04N 5/238, H01L 31/0232. Method of protection of the optical radiation receiver / Yu.L. Koziratsky, A. Yu. Koziratsky, P.E. Kuleshov, R.G. Khilchenko, D.V. Prokhorov, D.E. Stolyarov; applicant and patentee VUNC VVS "VVA im. prof. NOT. Zhukovsky and Yu.A. Gagarin ". - No. 2016107511; declared 03/01/16; publ. 11/16/17, Bul. No. 32. - 11 p.

3 Dobynkin V.D., Kupriyanov A.I., Ponomarev V.G., Shustov L.N. Electronic warfare. Power defeat of electronic systems / V.D. Dobynkin, A.I. Kupriyanov, V.G. Ponomarev, L.N. Shustov. Ed. A.I. Kupriyanov. M .: Vuzovskaya kniga, 2007.468 p.

4 Koziratsky Yu.L. Optimization of the angle of divergence of the radiation of a laser location system in conditions of interference / Yu.L. Koziratsky // Radio engineering. - 1994. - No. 3. - P.6-10.

5 Koziratskiy Yu.L., Koziratskiy A.Yu., Kuleshov P.E. et al. Modeling of spatial distribution of laser radiation with multimode type of oscillations / Yu.L. Koziratsky, A. Yu. Koziratsky, P.E. Kuleshov et al. // Antennas. - 2007. - No. 4 (119). - S. 54-56.

6 Koziratsky Yu.L., Grevtsev A.I., Dontsov A.A., Ivantsov A.V., Kuleshov P.E. et al. Detection and coordinateometry of optoelectronic devices, evaluation of the parameters of their signals / Yu.L. Koziratsky, A.I. Grevtsev, A.A. Dontsov, A.V. Ivantsov, P.E. Kuleshov et al. M .: "ZAO" Publishing house "Radiotekhnika", 2015, 456 p.

Claims (1)

A method of protecting optoelectronic devices from powerful laser systems based on the reception of optical radiation by an optoelectronic device, characterized in that optical radiation is received by an optoelectronic device through an additional lens installed in the plane of placement of the optoelectronic device at a distance from the main lens of the optoelectronic device R≥R _min , where R _min is the minimum value of the radius of the zone relative to the position of the main lens of the optoelectronic device, outside of which the flow of incident powerful laser radiation will not hit the optoelectronic device at a given distance of non-damage, is taken through an additional lens optic -electronic means, the radar radiation of a powerful laser complex is measured and its parameters are measured, according to the values of the parameters of the radar radiation of a powerful laser complex, the time instant of irradiation of the optoelectronic device with powerful laser radiation of a powerful laser computer is determined Lex and at the moment of irradiation of the optical-electronic device with powerful laser radiation of a powerful laser complex, optical radiation is received by the optical-electronic device through the main lens.

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