RU91421U1 - COMPLEX OF OPTICAL-ELECTRONIC PROTECTION-COEZ - Google Patents

Abstract

1. A complex of optoelectronic protection of objects from high-precision weapons (WTO) with laser guidance, containing a set of laser illumination sensors for installation on the defense object and / or in the immediate vicinity of it, a set of radiation sources to create a false optical field away from the object being covered , a control unit for radiation sources, and also containing a set of communication tools for connecting radiation sources with laser illumination sensors through a control unit, characterized in that the radiation sources In order to create a false optical field away from the object to be covered, they are made in the form of pulsed gas discharge lamps with scattering optics, and the control unit is configured to generate synchronous pulsed ignition lamps for gas discharge lamps to simultaneously hit their radiation in the strobe of temporary selection of the optoelectronic guidance system of the attacking WTO on every detected pulse of laser illumination. ! 2. The complex according to claim 1, characterized in that the pulsed discharge lamps are made of xenon or quartz. ! 3. The complex according to claim 1, characterized in that the control unit, configured to generate synchronous pulses of ignition of gas discharge lamps to simultaneously hit their radiation in the strobe of temporary selection of the optoelectronic guidance system of the attacking WTO on each detected laser illumination pulse, is made analog and / or digital. ! 4. The complex according to claim 3, characterized in that the analog control unit contains a series-connected detector, a signal delay meter and a synchronous pulse generator. ! 5. Complex p

Description

The utility model relates to defense means, specifically to devices for passive protection of objects from high-precision weapons (WTO) with laser guidance and is based on the creation of a false signal situation on the photodetector of the homing head of the WTO, providing a shift of the aiming point towards a group of radiation sources creating a false optical field in side of the covered object.

Known devices for optoelectronic protection of objects from the WTO with laser guidance [WO 2005056384, IPC: B64D 7/00; B64D 47/00; F41J 2/00; F41J 9/00; 2005; IP 2249172 IPC: F41J 2/02, 2005; RU 99118102, IPC: F41H 11/02, 2001], based on the detection of pulses of laser illumination of the defense object and the emission of response laser pulses from points of space remote from the defense at a safe distance.

A common drawback of these devices is the insufficient reliability of object protection associated with narrow-band lasers and the difficulty of tuning their frequency in real time.

The closest of these protection devices is a complex of optoelectronic protection of objects from the WTO with laser guidance [RU 99118102, IPC: F41H 11/02, 2001], containing a block of laser illumination sensors for installation on and / or in the immediate vicinity of the defense , a block of radiation sources for creating a false optical field away from the object to be covered, a control unit for radiation sources, and also containing a set of communication tools for connecting radiation sources with laser illumination sensors through the control unit Nia, the radiation sources are in the form of lasers with a wavelength corresponding to the wavelength of the laser illumination, or lying in the spectral range of the electro-optical guidance system WTO.

The disadvantage of this complex of optoelectronic protection is the lack of reliability of object protection, associated with the difficulty of suppressing the optoelectronic tracking system of the WTO due to the narrow cavity of the lasers and the difficulty of tuning their frequency in real time. Another disadvantage of the known complex is the difficulty of its use in real combat, since the specific value of the frequency of the laser illumination pulses and the spectral range of the optoelectronic guidance system of the WTO may not be known in advance. In addition, the high cost of laser simulators also limits the possibility of using the well-known complex of optoelectronic protection of objects from WTO with laser guidance.

The objective of the utility model is to increase the reliability of protection of objects from the WTO with laser guidance while reducing the cost of defense of objects from these WTOs.

The technical result that provides the solution of the technical problem is to increase the reliability of the shift of the line of sight of the optoelectronic tracking system of the WTO away from the defended object by expanding the spectrum of the radiation of imitation optical signals and compensating for the difference in the time of their propagation to the WTO.

Achieving the claimed technical result and, as a result, solving the problem is provided by the fact that the complex of optoelectronic protection of objects from high-precision weapons (WTO) with laser guidance, containing a set of laser illumination sensors for installation on the defense object and / or in the immediate vicinity of it , a set of radiation sources for creating a false optical field away from the object to be covered, a control unit for radiation sources, and also containing a set of communication tools for connecting radiation sources with laser illumination sensors through the control unit, according to a useful model, radiation sources for creating a false optical field away from the object to be covered are made in the form of pulsed discharge lamps with scattering optics, and the control unit is capable of generating synchronous ignition pulses of discharge lamps for simultaneous hit their radiation in the strobe of the temporary selection of the optoelectronic guidance system of the attacking WTO on each detected pulse of laser illumination .

In this case, pulsed discharge lamps are made of xenon or quartz. The control unit is made analog and / or digital. The analog control unit contains a series-connected detector, a signal delay meter and a synchronous pulse generator. The digital control unit is designed as a reprogrammable microcomputer based on the ATMega128 microcontroller (ATMEL) and contains a serial interface of a universal synchronous asynchronous transceiver (USAP), a central processor (CPU) with reprogrammable (EPROM) and operational (RAM) memory devices and an input-output controller no less than five channels, while the USAP interface contains a USB-2.0 interface chip for connection via the first digital communication line with laser illumination sensors, and the input-output controller is a mic RS-232 circuitry to connect via a second digital line connection to the control inputs of discharge lamps.

The implementation of radiation sources to create a false optical field away from the object to be covered in the form of pulsed gas-discharge lamps, for example xenon or quartz, having a broadband emission spectrum, instead of narrow-band lasers, allows you to automatically block the spectrum of all existing and promising infrared beam guidance systems with a single-discharge lamp up to the ultraviolet range of electromagnetic waves. This ensures not only an increase in the reliability of defense of the defense object through the use of broadband radiation sources (simulators), but also a reduction in the cost of defense of the objects. This is because the cost of gas-discharge broadband lamps, for example xenon, is several orders of magnitude lower than the cost of laser simulators. The execution of the control unit digital or analog with the possibility of generating synchronous pulses of ignition of gas discharge lamps for simultaneous hit of their radiation in the strobe of temporary selection of the optoelectronic guidance system of the attacking WTO on each detected laser illumination pulse allows you to create a false signal situation on the photodetector of the homing head of the WTO, to provide a point offset aiming towards a group of radiation sources creating a false optical field away from the object being covered , and, thereby, increase the reliability of the protection of the object from the defeat of the WTO. At the same time, in the control unit, the difference in distances from the defense object to each individual point of simulation of reflected signals (compensation of the difference in the time delays of the signals in the communication lines) for the simultaneous incident of the radiation of the simulators in the strobe of temporary selection of the optoelectronic guidance system of the attacking WTO (for the duration of the WTO photodetector on reception) allows you to ensure the withdrawal of the attacking WTO in the equal-signal area between the locations of the reflected signal simulators. This increases not only the reliability of defense of the defense against the WTO, but also increases the survivability of simulators, providing an additional increase in the reliability and time of defense of the defense.

Figure 1 presents a functional diagram of a complex of optoelectronic protection of objects from the WTO with laser guidance, figure 2 is a drawing explaining the principle of operation of the complex, figure 3 is a temporary strobe of the selection of the WTO photodetector, figure 4 is a temporary position of simulated the signals falling into the range gate of the optoelectronic tracking system of the WTO in FIG. 5 are the amplitude-frequency characteristics of typical WTO target designators, and FIG. 6 is the emission spectrum of gas discharge lamps.

The optical-electronic protection complex contains a set of 1 autonomous photodetectors 2, a control unit 3, a set of 4 broadband sources 5 of optical radiation of the electromagnetic wave range and equipment of digital communication lines 6 and 7 for connecting the photodetectors 2 with radiation sources 5 through the control unit 3. Kits 1, 4 and control unit 3 are made in the form of separate structural elements, are equipped with quick-detachable electrical connectors for interconnection with the corresponding communication lines 6, 7, a navigation positioning system, and are also equipped with autonomous power sources, for example, batteries or electric batteries (not shown in the figures shown). Photodetectors 2 are made with a digital output, equipped with tripods or suspension means for placing them at the defense object or in the immediate vicinity of it. The control unit 3 is made analog or digital. The analog unit 3 contains a series-connected detector 8, a meter 9 delay synchronizing pulses and a generator 10 of synchronizing pulses with an analog-to-digital Converter. In digital design, the control unit 3 is made in the form of a reprogrammable microcomputer based on the ATMega128 microcontroller (ATMEL) and contains a serial interface of a universal synchronous asynchronous transceiver (USAP), a central processor (CPU) with reprogrammable (EPROM) and operational (RAM) memory devices and a controller I / O on at least five channels. At the same time (USAP) contains a USB-2.0 interface microcircuit for connecting via the first digital communication line with laser illumination sensors, and an input-output controller - an RS-232 microcircuit for connecting via a second digital communication line with the control inputs of discharge lamps. When digitally executed, the control unit 3 can be structurally combined with one of the standalone photodetectors 2 and installed in its housing. To quickly connect the unit 3 control lines of communication 7 with sources 5 of broadband radiation, it is equipped with quick connectors. Source 5 is made in the form of a powerful pulsed gas discharge lamp (for example, quartz or krypton) equipped with scattering optics. The complex of optoelectronic protection is equipped with a mobile means of storage and deployment of equipment in the form of a van mounted on the chassis of a car or automobile trailer (not shown in the figures).

The complex of optoelectronic protection of objects from the WTO with laser guidance in mobile design works as follows. In the threatened period, the complex is transported to the defense facility 11 and its equipment is deployed on the ground. In this case, the photodetectors 2 are installed in the immediate vicinity of the defense object 11. At the same time, at a distance from the defense object 11, not less than the double radius of action of the striking elements of the WTO warhead 12, sources 5 of broadband radiation are installed on the ring. The minimum diameter of the ring and the distance between the sources 5 is chosen from a similar condition for eliminating the damage of sources 5 when the WTO ammunition explodes in the center of the ring or when it enters one of the sources 5 simulating broadband signals. The maximum diameter of the location ring of sources 5 is selected from the condition that all sources 5 fall into the field of view of the optoelectronic guidance system of the WTO 12 from the direction of its probable approach. After the deployment of elements 2, 3, 5 of the complex on the ground, connect them with the corresponding communication lines 6, 7 and turn on the positioning equipment located on these elements. At the same time, in the delay meter 9, corrective time corrections of the start of the synchronous pulse generator 10 are automatically introduced, taking into account the different spatial position of the simulators (sources 5) relative to the location of the defense object 11. At the end of positioning, the complex of optoelectronic protection is ready for combat use. When the target indicator 13 irradiates the defense object 11, the scattered signal 14 of the laser illumination is received by the photodetectors 2, and transmitted to the detector 8 of the control unit 3. The detector 8 performs correlation processing of the received signals and compares their amplitudes with the detection threshold value. If the amplitude of the signal 14 of the threshold value is exceeded, a signal is issued to the meter 9 for a single adjustment of the time delays of the emissions of the simulators 5 relative to the moment of arrival of the signal 14 from expression (1) .:

Where:

ti, tij - current propagation time of electromagnetic waves from EKR 2 to the object 1 of protection and to the j-th point of radiation (to the j-th simulator 8);

Ri is the distance from the object of protection 1 to the WTO at the i-th moment of time;

Lj - the total length of the communication lines 5 and 6, for example, cable or radio lines, from the object of protection to the j-th point of radiation;

C is the speed of light (3 × 10 8 m / s);

Δt - strobe length 15 of the selection of the optoelectronic guidance system of the attacking WTO.

In this case, to calculate the time delays, the numerical value of Ri in expression 1 is selected from the external target designation data, and in the absence of one, it is selected from the memory of meter 9 as the maximum launch range of the WTO 12 from the carrier aircraft 16. Next, the calculated values of the signal delays are entered into the memory of the synchronous generator 9 pulses, which for each pulse of the laser 14 backlight produces a group of clock pulses issued for the ignition of pulsed discharge lamps (source 5 of broadband optical radiation It electromagnetic waves). Moreover, each lamp 5 with an appropriate delay emits a broadband pulse 17 for almost the simultaneous emission of radiation from all simulators (lamps 5) in the strobe of temporary selection (opening time for receiving the photodetector) of the optoelectronic guidance system of the WTO 12. Moreover, due to the emission of radiation 17 from all simulators in gate 18 of temporary selection of the WTO 12 and the excess of signal power 17 simulators 5 power of the scattered signals 14 laser illumination optical tracking system WTO 12 receives signals 17 of the group of simulators 5 as dyn signal and directs the WTO to the direction of the equal-signal zone created by the simulators 5, i.e. - to the center of the circle on which the simulators are located 5. Since the radius of this circle exceeds the size of the zone 19 of the destruction of the WTO warhead 12, and all the simulators 5 are removed at a safe distance from the object 11, the defeat of the object 11 does not occur. Moreover, due to the fact that the spectrum of 20 discharge lamps 5 covers the spectral range F ₁ ... F _{5 of} known sources 13 of the pulses 14 of the laser illumination (Fig. 5), the reliability of defense of defense objects 11 is further enhanced due to the versatility of the combat use of the complex.

The utility model is developed at the level of technical proposal, physical and mathematical modeling. The simulation results showed that the proposed complex of optoelectronic protection can be used to protect stationary and mobile objects from the attack of guided and adjusted ammunition (shells, mines, bombs, missiles) with a semi-active laser guidance system.

Claims (5)

1. A complex of optoelectronic protection of objects from high-precision weapons (WTO) with laser guidance, containing a set of laser illumination sensors for installation on the defense object and / or in the immediate vicinity of it, a set of radiation sources to create a false optical field away from the object being covered , a control unit for radiation sources, and also containing a set of communication tools for connecting radiation sources with laser illumination sensors through a control unit, characterized in that the radiation sources In order to create a false optical field away from the object to be covered, they are made in the form of pulsed gas discharge lamps with scattering optics, and the control unit is configured to generate synchronous pulsed ignition lamps for gas discharge lamps to simultaneously hit their radiation in the strobe of temporary selection of the optoelectronic guidance system of the attacking WTO on every detected pulse of laser illumination. 2. The complex according to claim 1, characterized in that the pulsed discharge lamps are made of xenon or quartz. 3. The complex according to claim 1, characterized in that the control unit, configured to generate synchronous pulses of ignition of gas discharge lamps to simultaneously hit their radiation in the strobe of temporary selection of the optoelectronic guidance system of the attacking WTO on each detected laser illumination pulse, is made analog and / or digital. 4. The complex according to claim 3, characterized in that the analog control unit contains a series-connected detector, a signal delay meter and a synchronous pulse generator. 5. The complex according to claim 3, characterized in that the digital control unit is made in the form of a reprogrammable microcomputer based on the ATMega128 microcontroller (ATMEL) and contains a serial interface of a universal synchronous asynchronous transceiver (USAP), a central processor (CPU) with a reprogrammable (EPROM) and operational (RAM) storage devices and an input-output controller for at least five channels, while the interface of a universal synchronous-asynchronous transceiver contains a USB-2.0 interface chip for connection via ervuyu digital communication link with the sensors of the laser illumination, and the input-output controller - RS-232 chip to connect via a second communication link with the digital control inputs of the discharge lamp.