RU194453U1 - Device for protecting optoelectronic and visual-optical devices from laser interference - Google Patents

Abstract

The invention relates to devices for protecting optoelectronic and visual-optical devices from laser interference. The technical result consists in providing inertia-free selective attenuation of interference of laser signals in optoelectronic and visual-optical devices. The device consists of a sealed instrument case with an input window that is optically transparent in the spectral range of the device’s operation, inside which an optical filter is located in the space between the input window and the radiant energy receiver (photodetector or observer’s eye), which attenuates the energy of the radiant flux entering through the input window. In this case, a gas medium is used as a protective optical filter, which has a maximum selective absorption at the wavelength of the laser interfering signal and minimal attenuation of radiation in all other parts of the spectral range of the suppressed device. 1 s.p. f-ly.

Description

The device relates to the field of ensuring noise immunity of optical-electronic and visual-optical means of monitoring and controlling weapons, and more particularly, to devices for protecting means operating in the optical range of the spectrum from the effects of laser means of functional suppression.

The invention of lasers served as the reason for the development in different countries of research and development in the field of creating specialized laser-based counteraction devices based on lasers for optoelectronic and visual-optical weapons surveillance and control systems. For example, inventions [1, 2]. In addition, there are widespread cases of interference with vehicle control operators using laser pointers, as well as dazzling effects on people using laser projection devices.

At present, a number of countries are armed with laser systems designed for the functional suppression [3] of optoelectronic (thermal imaging, laser, television) and visual-optical weapon surveillance and control systems, which is understood to mean suppression conducted in the optical range and consisting in reducing the effectiveness of the operation of enemy optoelectronic devices by exposing them to deliberate optoelectronic interference. The effect of functional suppression when using laser means of creating interference is ensured by the use of lasers operating in the spectral sensitivity ranges of radiant energy detectors used in such systems (various types of photodetectors and the human eye).

Most existing jamming systems use lasers with radiation wavelengths of 0.53, 0.69, 1.06, and 10.6 μm, since quite powerful, compact, reliable lasers with relatively high efficiency operate at these radiation wavelengths. In the future, the possibility of using lasers with other radiation wavelengths corresponding to the spectral sensitivity ranges of suppressed devices is not ruled out if such lasers with acceptable mass, energy, and operational characteristics are created.

These circumstances necessitated the development of methods and devices for protecting optoelectronic and visual-optical devices from the effects of laser means of functional suppression. Currently, various types of light filters, shutters, and diaphragm devices are widely used for this purpose, which reduce or interrupt the light flux at the input of the radiant energy receiver. The practice of using these devices has revealed a number of fundamental disadvantages inherent in each of them, limiting the use of optical-electronic and visual-optical devices from laser means of functional suppression for protection.

The use of filters made of glass and plastic is most common for the protection of infrared devices and eyes (in the form of goggles) [4, 5, 6, 7]. Common disadvantages of the known methods and devices for the use of light filters are their large mass and dimensions, a decrease in the level of the input stream in a wide spectral range regardless of the presence or absence of an interfering signal, insufficient dynamic range of the brightness of optical noise sources, the non-selective nature of the absorption of the transmitted stream, the complexity of manufacturing and relatively high price.

Unlike continuous filters, optical shutters only block transmission of interfering light flux during the duration of the interference. However, the response rate of optical shutters, determined by the inertia of the moving elements used in them, is in the best cases 10 ^-4 s [8]. Such inertia does not provide protection against pulsed laser noise, the pulse duration of which can be 3 ... 4 orders of magnitude less than the shutter response time. In addition, optical shutters block not only the interfering, but also the useful signal.

Similar disadvantages are possessed by automatic diaphragm devices, the principle of which is based on negative electronic-mechanical feedback between the signal level at the input of the optoelectronic device and the diameter of the diaphragm [9, 10]. The difference from the optical shutter is that the diaphragm does not completely block the light flux at the input of the photodetector, but only partially attenuates it. At the same time, not only the interfering, but also the useful signal is attenuated.

A device is known, adopted as a prototype [11]. The device is designed to protect night vision devices from exposure to both polychromatic and monochromatic (laser) interfering signals. For this, the night-vision device is equipped with an optical filter made of electrochromic material, which changes its transmittance of optical radiation under the influence of a control voltage coming from the measuring channel and proportional to the level of illumination at the input of the device. The disadvantages of the prototype are its inertia, due to the presence of feedback through the measuring channel, as well as the attenuation of the input light flux in the entire spectral sensitivity band of the device even in cases where the interfering signal is narrow-band monochromatic. The inability to selectively attenuate the signal only at the radiation wavelength of the interfering laser, due to the broadband frequency of the electrochromic filter, leads to paralysis of the device over the entire range of its spectral sensitivity.

The inventive device is aimed at achieving a technical result, which consists in providing inertia-free selective attenuation of interfering laser signals in optoelectronic and visual-optical weapons monitoring and control devices, mainly at radiation wavelengths of interfering lasers, provided that these facilities remain operational in the remaining parts of their spectral range sensitivity.

To achieve the specified technical result, it is planned to use absorbing optical filters in the form of gas or liquid media with selective absorption in optical-electronic (thermal imaging, television, laser) and visual-optical (binoculars, optical sights, optical rangefinders, etc.) at the wavelengths of radiation from interfering lasers and transmitting radiation almost unhindered in the remaining spectral sensitivity wavelength ranges of the suppressed device. The basis for the prerequisites for the use of such selective filters is the use of the effect of Raman scattering of optical radiation in gases and liquids [12]. It has been theoretically and experimentally established that almost all liquids and gases have intense absorption spectral lines. In many cases, such lines coincide with the radiation wavelengths of various lasers, which are used or can be used for functional suppression [13]. In this case, the width of the absorption lines can be several tens of Angstroms, and the total attenuation of radiation in the spectral range of the operation of an optoelectronic or visual-optical device does not exceed 10%. In this regard, the use of such a filter leads to absorption of radiation from the interfering laser and only a slight weakening of the received flux of radiant energy outside the operating wavelength of the interfering laser.

Figure 1, borrowed from [14], illustrates Raman spectra for gases of the acetylene group as an example. The wavelength scale of spectral lines is given in inverse centimeters - cm ^-1 (the reduced range from 200 to 3000 cm ^-1 corresponds to the wavelength range from 50 to 3.3 μm).

As can be seen from the above figure, at the wavelength of the radiation of a gas laser on CO ₂ , 10.6 μm (943 cm ^-1 ), promising from the point of view of creating interference to thermal imaging devices operating in the spectral range of 8 ... 14 μm, there are a number of selective absorption bands phenylacetylenes (lines 8 ... 10).

In [13], for 153 elements, more than 60,000 spectral lines are determined, determined with an accuracy of 0.01 Angstroms. From this variety of elements and their spectral absorption lines, an element can always be selected having a spectral absorption line corresponding to

the radiation wavelength of the laser jamming device. This wavelength, as a rule, is known from the data on the tactical and technical characteristics of the means of functional suppression of the enemy. Moreover, the possible set of radiation wavelengths of interfering lasers is limited to no more than 10. If the radiation wavelength of the enemy interference laser is not known in advance, a mixture of elements whose absorption spectral lines cover the expected laser radiation wavelengths can be used as a filter. In addition, it should be borne in mind that in the case of not absolute coincidence of the laser radiation wavelength and the absorption line of the selected medium, such coverage can be achieved by using the effect of the expansion of the selective absorption band with increasing pressure. Thus, an increase in pressure to 50 atm leads to an expansion of the absorption band by at least 2 times [12].

To create an absorbing filter based on liquid media, a cuvette made of glass or plastic can be used, which is transparent in the spectral range of the optical-electronic or visual-optical device, filled with the corresponding selectively absorbing liquid composition and placed in front of the radiant energy receiver.

In the case of using a filter based on gaseous media, the issue can be solved even more simply. All optical-electronic and visual-optical devices for military use are structurally placed in sealed enclosures filled with dry air to avoid fogging. Therefore, it is sufficient to fill such a sealed enclosure of the device not with air, but with the selected absorbing gas or gas mixture. For this, such a housing must be equipped with a filling nozzle with a check valve, which ensures that the corresponding gas is pumped into the housing and prevents its leakage.

Thus, the proposed technical solution allows for inertialess absorption of radiation from an interfering laser, so

as it does not require any feedback or electromechanical components. This attenuates not only the entire input flux of radiant energy, but mainly radiation at the operating wavelength of the generated interference. As a result, the optical-electronic or visual-optical device exposed to the laser means of functional suppression, does not lose performance during such exposure.

As follows from the foregoing, the claimed device is quite feasible on the basis of existing optoelectronic and visual-optical devices. There are all the necessary prerequisites for this. The absorption spectra of gas and liquid media are sufficiently studied and allow one to choose a medium with selective absorption at the desired wavelength. All optical-electronic and visual-optical military devices are made in the form of structures placed in sealed enclosures inside which an absorbing medium can be placed in front of the radiant energy receiver. Thus, the task of achieving a technical result based on the claimed device is practically achievable with the current level of technological development.

Literature

1. The method of illumination of optoelectronic devices of small-sized unmanned aerial vehicles. Patent for invention RU 2678256.

2. The method of illumination of optoelectronic devices of small-sized unmanned aerial vehicles. Patent for invention RU 2578722.

3. GOST RV. 0158-002 = 2008 “Electronic warfare. Terms and Definitions".

4. Voronkova E.M. et al., “Optical Materials for Infrared Technology,” ed. "Science", Moscow, 1965, p. 335.

5. Eye protection from laser radiation. http://www.laser-portal.ru/content 542 (accessed 02.03.2019).

6. In Russia, developed protection against laser exposure. https://army-news.ru/2014/02/v-rossii-rasrabotali-zashitu-otzasvttki-laserom/ (accessed 03.03.2019).

7. Laser glasses. Eye protection from laser radiation. http://jlaser.ru/category/zashitnye-ochki/ (accessed February 27, 2019).

8. Physical encyclopedia. Optical shutter. http://femto.com.ua/articles/part_2/2638.html (accessed 03.03.2019).

9. Arsentiev M.Yu. “Auto iris lenses. Technical Review. ” http://secuteck.ru/articles2/videonabl/obectivy-s-avtomaticheskoi-diafragmoi/ (accessed 02.03.2019).

10. HLC - backlight compensation function used in modern video surveillance cameras, http://www.delc.ru/tehpodderzhrf/glossarij/ hic_funkciyf_kamery_videonablydeniyf_kompensaciya_zasvetki / (accessed 02.03.2019).

11. A device for protecting night vision devices from optical interference. Patent for invention RU 2344499.

12. “Spectroscopy of Raman scattering of light in gases and liquids,” ed. A. Weber, ed. "World", M., 1982, p. 373.

13. Seidel A.P. et al., “Tables of Spectral Lines,” ed. Technical and theoretical literature, M., 1952, p. 560.

14. Kohlrausch K. “Spectra of Raman scattering”, ed. Foreign Literature, M., 1952, p. 464.

Claims (2)

1. A device for protecting optoelectronic and visual-optical devices from laser noise, consisting of a sealed device case with an input window that is optically transparent in the spectral range of the device, inside of which is located in the space between the input window and the radiant energy receiver (photodetector or observer's eye) an optical filter attenuating the energy of the radiant flux entering through the input window, characterized in that a gas medium having a maxim lnym selective absorption at the wavelength of the laser interference signal and the minimum attenuation of radiation in all other parts of the spectral range of the instrument suppressed. 2. The device according to claim 1, characterized in that when using a gas selectively absorbing medium, an optical attenuation filter is filled with this gas through the fitting with a non-return valve located on the device’s body and the internal volume of the device’s sealed housing.

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