RU2698466C1 - False optical target generating method - Google Patents

Abstract

FIELD: electronic equipment.

SUBSTANCE: invention relates to the field of optoelectronic equipment and can be used in laser location systems, systems of optoelectronic countermeasures, as well as protection systems of optoelectronic devices (OD) from powerful laser radiation. Method of forming a false optical target is based on an apparatus in the search sector of the OD of a reflector with generalized reflection parameters, which repeat the generalized reflection parameters of the OD, introduction into the reflector of a thermal substance with an ignition limit equal to the ignition threshold of an element from the composition of an optoelectronic device with a minimum ignition limit at exposure to laser radiation, arson of the thermal substance by laser radiation when the ignition threshold is exceeded.

EFFECT: high efficiency of generating a false optical target.

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 the method (see, for example, [1]) of creating a false optical target (LOC), based on the installation of an optical reflector with generalized reflection parameters in the search field of optoelectronic devices (OES) repeating the generalized reflection parameters of the ECO. The disadvantage of this method is to simulate the properties of the ECO only in the interests of misleading location tools at the search stage. In the case of the use of damaging laser radiation in the LOC with the control of its effectiveness, the absence of effects of powerful laser radiation can lead to its recognition.

The technical result, the achievement of which the present invention is directed, is to increase the efficiency of the formation of the LOTs.

The essence of the invention is to further simulate the effect of a powerful laser study on the ECO by forming a plasma formation.

The technical result is achieved by the fact that in the known LOC formation method, based on the installation of a reflector in the OEC search sector with generalized reflection parameters that repeat the generalized reflection parameters of the ECO, a thermal substance with an ignition threshold equal to the ignition threshold of an element from the ECO composition with a minimum the ignition threshold when exposed to laser radiation, set fire to a thermal substance with laser radiation when the ignition threshold is exceeded.

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, [2,3]). In the interests of simulating ECO, false targets that reproduce EPR are used. Reflectors of various designs are used as such LOCs, the reflection parameters of the optical radiation of which are close to real OES (see, for example, [1,3]). However, in the case of using high-power laser radiation in the LOC with subsequent monitoring of the results of exposure, the absence of signs of damage can lead to its recognition (see, for example, [3]). This is due to the fact that the LOCs are more (an order of magnitude) more resistant to high-power optical radiation and, accordingly, the reaction processes will differ significantly from the real OES. This is due to the fact that materials for the manufacture of LOC elements withstand higher laser radiation powers than in ECOs (see, for example, [4]). In an ECO, the most vulnerable element when exposed to high-power laser radiation is an element located near the focus; as a rule, it is a photodetector or a filter in front of it, which has a significantly lower ignition threshold with respect to the LOC (see, for example, [5]). Consequently, the reproduction of an additional feature, which determines the simulation of the results by the action of powerful optical radiation on the VOC, will increase its efficiency.

The claimed method is illustrated by the scheme shown in figure 1, where the following notation: 1 - a complex of laser exposure; 2 - LOTS; 3 - radiation reflected and formed by the LOC; 4 - damaging laser radiation; 5 - plasma formation.

The laser exposure complex 1, which includes a location tool and a powerful laser study tool, searches for an OES. When receiving the reflected 3 from the LOC 2 study, the complex of laser exposure 1 identifies as a target and uses its own means of powerful laser study. A striking laser study 4 falls on LOC 2. A thermal substance with an ignition threshold equal to the ignition threshold of the most unstable element of the ECO is introduced into LOT 2. Under the influence of a damaging laser study at LOTS 2, the thermal substance ignites, forming a plasma formation 5. The complex of laser exposure 1 receives the radiation of the plasma or reflected from it, and on the basis of which it makes a false decision about the successful conclusion of the operational state of the ECO.

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 forming optics (lens) 6, a reflecting surface 7, which includes thermal substance 8 with the required ignition threshold under the action of laser radiation.

The device operates as follows. Optical radiation is focused by the forming optics (lens) 6 onto the reflective surface 7. If the optical study of the ignition threshold of the thermal substance 8 is not exceeded, incident optical radiation is reflected by the reflective surface 7. When the optical study of the ignition threshold of the thermal substance 8 is exceeded, the thermal substance 8 is set on fire by optical radiation .

Thus, the proposed method has properties consisting in increasing the efficiency of the formation of the LOC due to additional imitation of the effects of powerful laser studies on the ECO. Thus, the method proposed by the authors eliminates the disadvantages of the prototype.

The proposed technical solution is new, because the method for forming a LOC based on the installation of a reflector in the ECO search sector with generalized reflection parameters repeating the generalized reflection parameters of the ECO, introducing a thermal substance into the reflector with an ignition threshold equal to the ignition threshold of an element from the composition ECO with a minimum ignition threshold when exposed to laser radiation, arson of a thermal substance by laser radiation when the pore is exceeded and ignition.

The proposed technical solution is practically applicable, since typical substances can be used for its implementation, the physical properties of the interaction with laser radiation of which allow the formation of plasma structures of the required structure.

1. Copyright certificate SU No. 1840937. A device to simulate a target. Pasko A.B., Danevich V.A. IPC G01S 7/40. 15 sec Registration 01.10.85. Publ. 09/10/14, Bull. 25.

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

3. 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. 12-17, 264-266.

4. Koroteev N.I., Shumai I.L. Physics of high-power laser radiation. M .: "Science", 1991, p. 114.

5. Olgin S. Problems of optoelectronic counteraction // Foreign Military Review. No. 9. 2002.S. 35-41.

Claims (1)

A method for generating a false optical target, based on the installation in the search sector of optoelectronic means of a reflector with generalized reflection parameters, repeating the generalized reflection parameters of optoelectronic means, characterized in that a thermal substance with an ignition threshold equal to the ignition threshold of an element from of the composition of optoelectronic devices with a minimum ignition threshold when exposed to laser radiation, ignite the thermal substance with laser radiation when shenii ignition threshold.

Images